WordNet

to remain unmolested, undisturbed, or uninterrupted -- used only in infinitive form; "let her be"
work in a specific place, with a specific subject, or in a specific function; "He is a herpetologist"; "She is our resident philosopher" (同)follow
have life, be alive; "Our great leader is no more"; "My grandfather lived until the end of war" (同)live
be identical to; be someone or something; "The president of the company is John Smith"; "This is my house"
happen, occur, take place; "I lost my wallet; this was during the visit to my parents house"; "There were two hundred people at his funeral"; "There was a lot of noise in the kitchen"
have the quality of being; (copula, used with an adjective or a predicate noun); "John is rich"; "This is not a good answer"
occupy a certain position or area; be somewhere; "Where is my umbrella?" "The toolshed is in the back"; "What is behind this behavior?"
spend or use time; "I may be an hour"
stake on the outcome of an issue; "I bet $100 on that new horse"; "She played all her money on the dark horse" (同)wager, play
the act of gambling; "he did it on a bet" (同)wager
maintain with or as if with a bet; "I bet she will be there!" (同)wager
second in order of importance; "the candidate, considered a beta male, was perceived to be unable to lead his party to victory"
the 2nd letter of the Greek alphabet
preliminary or testing stage of a software or hardware product; "a beta version"; "beta software"
beets (同)genus Beta

PrepTutorEJDIC

《連結語として補語を伴なって…『である』,…だ,…です / 《位置・場所を表す語句を伴って》(…に)『ある』,いる(occupy a place or situation) / 〈物事が〉『存在する』,ある(exist);〈生物が〉生存する,生きている(live) / 行われる,起こる,発生する(take place, occur) / 存続する,そのままでいる(remain as before) / 《『be to』 do》 / …する予定である,…することになっている / …すべきだ / 《受動態の不定詞を伴って》…できる / 《命令》…するのだ / 《条件節に》…する意図がある / 《『if…were to』 do》…するとしたなら / 《『be』 do『ing』》《進行形》 / 《進行中の動作》…している,しつつある / 《近い未来》…しようとしている,するつもり / 《動作の反復》(いつも)…している / 《『be』+『他動詞の過去分詞』》《受動態》…される,されている / 《『be』+『自動詞の過去分詞』》《完了形》…した[状態にある]
『かけ』・(…との)かけ《+『with』+『名』》 / かけた物(金) / かけの対象 / 〈金・物〉'を'『かける』 / (かけ事・ゲームなどで)〈人〉‘と'『かけをする』《+『名』〈人〉+『on』+『名』》 / (…に)『かける』《+『on』(『against』)+『名』(one's do『ing』)》
ベータ(ギリシア語アルファベットの第2文字;B,β;英語のB,b に遭当)

Wikipedia preview

出典(authority):フリー百科事典『ウィキペディア（Wikipedia）』「2015/06/12 01:47:47」(JST)

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Core structure of penicillins (top) and cephalosporins (bottom). β-lactam ring in red.

Escherichia coli bacteria on the right are sensitive to two beta-lactam antibiotics, and do not grow in the semi-circular regions surrounding the antibiotics. E. coli bacteria on the left are resistant to beta-lactam antibiotics, and grow next to one antibiotic (bottom) and are less inhibited by another antibiotic (top).

Beta-lactamases are enzymes (EC 3.5.2.6) produced by some bacteria that provide resistance to β-lactam antibiotics like penicillins, cephamycins, and carbapenems (ertapenem), although carbapenems are relatively resistant to beta-lactamase. Beta-lactamase provides antibiotic resistance by breaking the antibiotics' structure. These antibiotics all have a common element in their molecular structure: a four-atom ring known as a β-lactam. Through hydrolysis, the lactamase enzyme breaks the β-lactam ring open, deactivating the molecule's antibacterial properties.

Beta-lactam antibiotics are typically used to treat a broad spectrum of Gram-positive and Gram-negative bacteria.

Beta-lactamases produced by Gram-negative organisms are usually secreted, especially when antibiotics are present in the environment.^[1]

1 Structure
2 Penicillinase
3 Classification
- 3.1 Functional classification
  - 3.1.1 Group 1
  - 3.1.2 Group 2
  - 3.1.3 Group 3
  - 3.1.4 Group 4 (no longer current)
- 3.2 Molecular classification
4 Resistance in Gram-negative bacteria
- 4.1 Extended-spectrum beta-lactamase (ESBL)
- 4.2 Types
  - 4.2.1 TEM beta-lactamases (class A)
  - 4.2.2 SHV beta-lactamases (class A)
  - 4.2.3 CTX-M beta-lactamases (class A)
  - 4.2.4 OXA beta-lactamases (class D)
  - 4.2.5 Others
  - 4.2.6 Treatment
- 4.3 Inhibitor-resistant β-lactamases
- 4.4 AmpC-type β-lactamases (Class C)
- 4.5 Carbapenemases
  - 4.5.1 IMP-type carbapenemases (metallo-β-lactamases) (Class B)
  - 4.5.2 VIM (Verona integron-encoded metallo-β-lactamase) (Class B)
  - 4.5.3 OXA (oxacillinase) group of β-lactamases (Class D)
  - 4.5.4 KPC (K. pneumoniae carbapenemase) (Class A)
  - 4.5.5 CMY (Class C)
  - 4.5.6 SME, IMI, NMC and CcrA
  - 4.5.7 NDM-1 (New Delhi metallo-β-lactamase) (Class B)
5 Treatment of ESBL/AmpC/carbapenemases
- 5.1 General overview
- 5.2 According to genes
  - 5.2.1 ESBLs
  - 5.2.2 Inhibitor-Resistant β-lactamases
  - 5.2.3 AmpC
  - 5.2.4 Carbapenemases
- 5.3 According to species
  - 5.3.1 Escherichia coli or Klebsiella
  - 5.3.2 Pseudomonas aeruginosa
6 Detection
7 Evolution
8 See also
9 References
10 External links

Structure

The structure of a Streptomyces β-lactamase is given by 1BSG.

Penicillinase

Penicillinase is a specific type of β-lactamase, showing specificity for penicillins, again by hydrolysing the β-lactam ring. Molecular weights of the various penicillinases tend to cluster near 50 kiloDaltons.

Penicillinase was the first β-lactamase to be identified: It was first isolated by Abraham and Chain in 1940 from Gram-negative E. coli even before penicillin entered clinical use,^[2] but penicillinase production quickly spread to bacteria that previously did not produce it or produced it only rarely. Penicillinase-resistant beta-lactams such as methicillin were developed, but there is now widespread resistance to even these.

Classification

Functional classification

The following functional classification for beta lactamases has been proposed:^[3]

Group 1

CEPHALOSPORINASE, Molecular Class C (not inhibited by clavulanic acid): Group 1 are cephalosporinases not inhibited by clavulanic acid, belonging to the molecular class C

Group 2

Group 2 are penicillinases, cephalosporinases, or both inhibited by clavulanic acid, corresponding to the molecular classes A and D reflecting the original TEM and SHV genes. Additionally, many class A TEM β-lactamases are inhibited by β-lactamase inhibitor protein (BLIP). Because of the increasing number of TEM- and SHV-derived β-lactamases, they were divided into two subclasses, 2a and 2b.

GROUP 2a: PENICILLINASE, Molecular Class A; The 2a subgroup contains just penicillinases.

GROUP 2b: BROAD-SPECTRUM, Molecular Class A; 2b Opposite to 2a, 2b are broad-spectrum β-lactamases, meaning that they are capable of inactivating penicillins and cephalosporins at the same rate. Furthermore, new subgroups were segregated from subgroup 2b:

GROUP 2be: EXTENDED-SPECTRUM, Molecular Class A; Subgroup 2be, with the letter "e" for extended spectrum of activity, represents the ESBLs, which are capable of inactivating third-generation cephalosporins (ceftazidime, cefotaxime, and cefpodoxime) as well as monobactams (aztreonam)

GROUP 2br: INHIBITOR-RESISTANT, Molecular Class A (diminished inhibition by clavulanic acid); The 2br enzymes, with the letter "r" denoting reduced binding to clavulanic acid and sulbactam, are also called inhibitor-resistant TEM-derivative enzymes; nevertheless, they are commonly still susceptible to tazobactam, except where an amino acid replacement exists at position met69.^{[citation needed]}

GROUP 2c: CARBENICILLINASE, Molecular Class A; Latersubgroup 2c was segregated from group 2 because these enzymes inactivate carbenicillin more than benzylpenicillin, with some effect on cloxacillin.

GROUP 2d: CLOXACILLINASE, Molecular Class D or A; Subgroup 2d enzymes inactivate cloxacillin more than benzylpenicillin, with some activity against carbenicillin; these enzymes are poorly inhibited by clavulanic acid, and some of them are ESBLs

the correct term is "OXACILLINASE". These enzymes are able to inactivate the oxazolylpenicillins like oxacillin, cloxacillin, dicloxacillin. The enzymes belong to the molecular class D not molecular class A.

GROUP 2e: CEPHALOSPORINASE, Molecular Class A; Subgroup 2e enzymes are cephalosporinases that can also hydrolyse monobactams, and they are inhibited by clavulanic acid

GROUP 2f: CARBAPENEMASE, Molecular Class A; Subgroup 2f was added because these are serine-based carbapenemases, in contrast to the zinc-based carbapenemases included in group 3

Group 3

METALLOENZYME, Molecular Class B (not inhibited by clavulanic acid): Group 3 are the zinc-based or metallo {beta}-lactamases, corresponding to the molecular class B, which are the only enzymes acting by the metal ion zinc, as discussed above. Metallo B-lactamases are able to hydrolyse penicillins, cephalosporins, and carbapenems. Thus, carbapenems are inhibited by both group 2f (serine-based mechanism) and group 3 (zinc-based mechanism)

Group 4 (no longer current)

PENICILLINASE, No Molecular Class (not inhibited by clavulanic acid): Group 4 are penicillinases that are not inhibited by clavulanic acid, and they do not yet have a corresponding molecular class.; This group has been omitted from the current scheme, as when it was described originally it included enzymes not classifiable into other groups. It has been concluded that the enzymes that made up this classification in 1995 would be included in one of the other groups once more information becomes available on them and that it was not informative to have a separate group for them.^[4]

Molecular classification

The molecular classification of β-lactamases is based on the nucleotide and amino acid sequences in these enzymes. To date, four classes are recognised (A-D), correlating with the functional classification. Classes A, C, and D act by a serine-based mechanism, whereas class B or metallo-β-lactamases need zinc for their action^[5]

"Penicillinase" was discovered in 1940 and renamed Beta-lactamase when the structure of the Beta-lactam ring was finally elucidated.

Resistance in Gram-negative bacteria

Among Gram-negative bacteria, the emergence of resistance to expanded-spectrum cephalosporins has been a major concern. It appeared initially in a limited number of bacterial species (E. cloacae, C. freundii, S. marcescens, and P. aeruginosa) that could mutate to hyperproduce their chromosomal class C β-lactamase. A few years later, resistance appeared in bacterial species not naturally producing AmpC enzymes (K. pneumoniae, Salmonella spp., P. mirabilis) due to the production of TEM- or SHV-type ESBLs. Characteristically, such resistance has included oxyimino- (for example ceftizoxime, cefotaxime, ceftriaxone, and ceftazidime, as well as the oxyimino-monobactam aztreonam), but not 7-alpha-methoxy-cephalosporins (cephamycins; in other words, cefoxitin and cefotetan); has been blocked by inhibitors such as clavulanate, sulbactam, or tazobactam, and did not involve carbapenems and temocillin. Chromosomal-mediated AmpC β-lactamases represent a new threat, since they confer resistance to 7-alpha-methoxy-cephalosporins (cephamycins) such as cefoxitin or cefotetan are not affected by commercially available β-lactamase inhibitors, and can, in strains with loss of outer membrane porins, provide resistance to carbapenems.^[6]

Extended-spectrum beta-lactamase (ESBL)

Members of the family Enterobacteriaceae commonly express plasmid-encoded β-lactamases (e.g., TEM-1, TEM-2, and SHV-1). which confer resistance to penicillins but not to expanded-spectrum cephalosporins. In the mid-1980s, a new group of enzymes, the extended-spectrum β-lactamases (ESBLs), was detected (first detected in 1979).^[7] ESBLs are beta-lactamases that hydrolyze extended-spectrum cephalosporins with an oxyimino side chain. These cephalosporins include cefotaxime, ceftriaxone, and ceftazidime, as well as the oxyimino-monobactam aztreonam. Thus ESBLs confer resistance to these antibiotics and related oxyimino-beta lactams. In typical circumstances, they derive from genes for TEM-1, TEM-2, or SHV-1 by mutations that alter the amino acid configuration around the active site of these β-lactamases. A broader set of β-lactam antibiotics are susceptible to hydrolysis by these enzymes. An increasing number of ESBLs not of TEM or SHV lineage have recently been described.^[8] The ESBLs are frequently plasmid encoded. Plasmids responsible for ESBL production frequently carry genes encoding resistance to other drug classes (for example, aminoglycosides). Therefore, antibiotic options in the treatment of ESBL-producing organisms are extremely limited. Carbapenems are the treatment of choice for serious infections due to ESBL-producing organisms, yet carbapenem-resistant isolates have recently been reported. ESBL-producing organisms may appear susceptible to some extended-spectrum cephalosporins. However, treatment with such antibiotics has been associated with high failure rates. Recent publications have reported cases of resistance of ESBL-producing organisms to the carbapenems, primarily ertapenem .

Types

TEM beta-lactamases (class A)

TEM-1 is the most commonly encountered beta-lactamase in Gram-negative bacteria. Up to 90% of ampicillin resistance in E. coli is due to the production of TEM-1.^[9] Also responsible for the ampicillin and penicillin resistance that is seen in H. influenzae and N. gonorrhoeae in increasing numbers. Although TEM-type beta-lactamases are most often found in E. coli and K. pneumoniae, they are also found in other species of Gram-negative bacteria with increasing frequency. The amino acid substitutions responsible for the extended-specttrum beta lactamase (ESBL) phenotype cluster around the active site of the enzyme and change its configuration, allowing access to oxyimino-beta-lactam substrates. Opening the active site to beta-lactam substrates also typically enhances the susceptibility of the enzyme to b-lactamase inhibitors, such as clavulanic acid. Single amino acid substitutions at positions 104, 164, 238, and 240 produce the ESBL phenotype, but ESBLs with the broadest spectrum usually have more than a single amino acid substitution. Based upon different combinations of changes, currently 140 TEM-type enzymes have been described. TEM-10, TEM-12, and TEM-26 are among the most common in the United States.^[10]^[11]^[12]

SHV beta-lactamases (class A)

SHV-1 shares 68 percent of its amino acids with TEM-1 and has a similar overall structure. The SHV-1 beta-lactamase is most commonly found in K. pneumoniae and is responsible for up to 20% of the plasmid-mediated ampicillin resistance in this species. ESBLs in this family also have amino acid changes around the active site, most commonly at positions 238 or 238 and 240. More than 60 SHV varieties are known. SHV-5 and SHV-12 are among the most common.^[10]

CTX-M beta-lactamases (class A)

These enzymes were named for their greater activity against cefotaxime than other oxyimino-beta-lactam substrates (e.g., ceftazidime, ceftriaxone, or cefepime). Rather than arising by mutation, they represent examples of plasmid acquisition of beta-lactamase genes normally found on the chromosome of Kluyvera species, a group of rarely pathogenic commensal organisms. These enzymes are not very closely related to TEM or SHV beta-lactamases in that they show only approximately 40% identity with these two commonly isolated beta-lactamases. More than 80 CTX-M enzymes are currently known. Despite their name, a few are more active on ceftazidime than cefotaxime. They have mainly been found in strains of Salmonella enterica serovar Typhimurium and E. coli, but have also been described in other species of Enterobacteriaceae and are the predominant ESBL type in parts of South America. (They are also seen in eastern Europe) CTX-M-14, CTX-M-3, and CTX-M-2 are the most widespread. CTX-M-15 is currently (2006) the most widespread type in E. coli the UK and is widely prevalent in the community.^[13] An example of beta-lactamase CTX-M-15, along with ISEcp1, has been found to have recently transposed onto the chromosome of Klebsiella pneumoniae ATCC BAA-2146.^[14]

OXA beta-lactamases (class D)

OXA beta-lactamases were long recognized as a less common but also plasmid-mediated beta-lactamase variety that could hydrolyze oxacillin and related anti-staphylococcal penicillins. These beta-lactamases differ from the TEM and SHV enzymes in that they belong to molecular class D and functional group 2d . The OXA-type beta-lactamases confer resistance to ampicillin and cephalothin and are characterized by their high hydrolytic activity against oxacillin and cloxacillin and the fact that they are poorly inhibited by clavulanic acid. Amino acid substitutions in OXA enzymes can also give the ESBL phenotype. While most ESBLs have been found in E. coli, K. pneumoniae, and other Enterobacteriaceae, the OXA-type ESBLs have been found mainly in P. aeruginosa. OXA-type ESBLs have been found mainly in Pseudomonas aeruginosa isolates from Turkey and France. The OXA beta-lactamase family was originally created as a phenotypic rather than a genotypic group for a few beta-lactamases that had a specific hydrolysis profile. Therefore, there is as little as 20% sequence homology among some of the members of this family. However, recent additions to this family show some degree of homology to one or more of the existing members of the OXA beta-lactamase family. Some confer resistance predominantly to ceftazidime, but OXA-17 confers greater resistance to cefotaxime and cefepime than it does resistance to ceftazidime.

Others

Other plasmid-mediated ESBLs, such as PER, VEB, GES, and IBC beta-lactamases, have been described but are uncommon and have been found mainly in P. aeruginosa and at a limited number of geographic sites. PER-1 in isolates in Turkey, France, and Italy; VEB-1 and VEB-2 in strains from Southeast Asia; and GES-1, GES-2, and IBC-2 in isolates from South Africa, France, and Greece. PER-1 is also common in multiresistant acinetobacter species in Korea and Turkey. Some of these enzymes are found in Enterobacteriaceae as well, whereas other uncommon ESBLs (such as BES-1, IBC-1, SFO-1, and TLA-1) have been found only in Enterobacteriaceae.

Treatment

While ESBL-producing organisms were previously associated with hospitals and institutional care, these organisms are now increasingly found in the community. CTX-M-15-positive E. coli are a cause of community-acquired urinary infections in the UK,^[13] and tend to be resistant to all oral β-lactam antibiotics, as well as quinolones and sulfonamides. Treatment options may include nitrofurantoin, fosfomycin, mecillinam and chloramphenicol. In desperation, once-daily ertapenem or gentamicin injections may also be used.

Inhibitor-resistant β-lactamases

Although the inhibitor-resistant β-lactamases are not ESBLs, they are often discussed with ESBLs because they are also derivatives of the classical TEM- or SHV-type enzymes. These enzymes were at first given the designation IRT for inhibitor-resistant TEM β-lactamase; however, all have subsequently been renamed with numerical TEM designations. There are at least 19 distinct inhibitor-resistant TEM β-lactamases. Inhibitor-resistant TEM β-lactamases have been found mainly in clinical isolates of E. coli, but also some strains of K. pneumoniae, Klebsiella oxytoca, P. mirabilis, and Citrobacter freundii. Although the inhibitor-resistant TEM variants are resistant to inhibition by clavulanic acid and sulbactam, thereby showing clinical resistance to the beta-lactam—lactamase inhibitor combinations of amoxicillin-clavulanate (co-amoxiclav), ticarcillin-clavulanate (co-ticarclav), and ampicillin/sulbactam, they normally remain susceptible to inhibition by tazobactam and subsequently the combination of piperacillin/tazobactam,^{[citation needed]} although resistance has been described. This is no longer a primarily European epidemiology, it is found in northern parts of America often and should be tested for with complex UTI's.^[11]

AmpC-type β-lactamases (Class C)

AmpC type β-lactamases are commonly isolated from extended-spectrum cephalosporin-resistant Gram-negative bacteria. AmpC β-lactamases (also termed class C or group 1) are typically encoded on the chromosome of many Gram-negative bacteria including Citrobacter, Serratia and Enterobacter species where its expression is usually inducible; it may also occur on Escherichia coli but is not usually inducible, although it can be hyperexpressed. AmpC type β-lactamases may also be carried on plasmids.^[6] AmpC β-lactamases, in contrast to ESBLs, hydrolyse broad and extended-spectrum cephalosporins (cephamycins as well as to oxyimino-β-lactams) but are not inhibited by β-lactamase inhibitors such as clavulanic acid.

Carbapenemases

Carbapenems are famously stable to AmpC β-lactamases and extended-spectrum-β-lactamases. Carbapenemases are a diverse group of β-lactamases that are active not only against the oxyimino-cephalosporins and cephamycins but also against the carbapenems. Aztreonam is stable to the metallo-β-lactamases, but many IMP and VIM producers are resistant, owing to other mechanisms. Carbapenemases were formerly believed to derive only from classes A, B, and D, but a class C carbapenemase has been described.

IMP-type carbapenemases (metallo-β-lactamases) (Class B)

Plasmid-mediated IMP-type carbapenemases, 17 varieties of which are currently known, became established in Japan in the 1990s both in enteric Gram-negative organisms and in Pseudomonas and Acinetobacter species. IMP enzymes spread slowly to other countries in the Far East, were reported from Europe in 1997, and have been found in Canada and Brazil.

VIM (Verona integron-encoded metallo-β-lactamase) (Class B)

A second growing family of carbapenemases, the VIM family, was reported from Italy in 1999 and now includes 10 members, which have a wide geographic distribution in Europe, South America, and the Far East and have been found in the United States. VIM-1 was discovered in P. aeruginosa in Italy in 1996; since then, VIM-2 - now the predominant variant - was found repeatedly in Europe and the Far East; VIM-3 and -4 are minor variants of VIM-2 and -1, respectively. VIM enzymes occur mostly in P. aeruginosa, also P. putida and, very rarely, Enterobacteriaceae.

Amino acid sequence diversity is up to 10% in the VIM family, 15% in the IMP family, and 70% between VIM and IMP. Enzymes of both the families, nevertheless, are similar. Both are integron-associated, sometimes within plasmids. Both hydrolyse all β-lactams except monobactams, and evade all β-lactam inhibitors.

OXA (oxacillinase) group of β-lactamases (Class D)

The OXA group of β-lactamases occur mainly in Acinetobacter species and are divided into two clusters. OXA carbapenemases hydrolyse carbapenems very slowly in vitro, and the high MICs seen for some Acinetobacter hosts (>64 mg/L) may reflect secondary mechanisms. They are sometimes augmented in clinical isolates by additional resistance mechanisms, such as impermeability or efflux. OXA carbapenemases also tend to have a reduced hydrolytic efficiency towards penicillins and cephalosporins.^[15]

KPC (K. pneumoniae carbapenemase) (Class A)

A few class A enzymes, most noted the plasmid-mediated KPC enzymes, are effective carbapenemases as well. Ten variants, KPC-2 through KPC-11 are known, and they are distinguished by one or two amino acid substitutions (KPC-1 was re-sequenced in 2008 and found to be 100% homologous to published sequences of KPC-2). KPC-1 was found in North Carolina, KPC-2 in Baltimore and KPC-3 in New York. They have only 45% homology with SME and NMC/IMI enzymes and, unlike them, can be encoded by self-transmissible plasmids.

The class A Klebsiella pneumoniae carbapenemase (KPC) is currently the most common carbapenemase, which was first detected in North Carolina, US, in 1996 and has since spread worldwide.^[16] A later publication indicated that Enterobacteriaceae that produce KPC were becoming common in the United States.^[17]

CMY (Class C)

The first class C carbapenemase was described in 2006 and was isolated from a virulent strain of Enterobacter aerogenes.^[18] It is carried on a plasmid, pYMG-1, and is therefore transmissible to other bacterial strains.^[19]

SME, IMI, NMC and CcrA

In general, these are of little clinical significance.

CcrA (CfiA). Its gene occurs in c. 1-3% of B. fragilis isolates, but fewer produce the enzyme since expression demands appropriate migration of an insertion sequence. CcrA was known before imipenem was introduced, and producers have shown little subsequent increase.

NDM-1 (New Delhi metallo-β-lactamase) (Class B)

Originally described from New Delhi in 2009, this gene is now widespread in Escherichia coli and Klebsiella pneumoniae from India and Pakistan. As of mid-2010, NDM-1 carrying bacteria have been introduced to other countries (including the United States and UK), most probably due to the large number of tourists travelling the globe, who may have picked up the strain from the environment, as strains containing the NDM-1 gene have been found in environmental samples in India.^[20]

Treatment of ESBL/AmpC/carbapenemases

General overview

In general, an isolate is suspected to be an ESBL producer when it shows in vitro susceptibility to the second-generation cephalosporins (cefoxitin, cefotetan) but resistance to the third-generation cephalosporins and to aztreonam. Moreover, one should suspect these strains when treatment with these agents for Gram-negative infections fails despite reported in vitro susceptibility. Once an ESBL-producing strain is detected, the laboratory should report it as "resistant" to all penicillins, cephalosporins, and aztreonam, even if it is tested (in vitro) as susceptible.^{[citation needed]} Associated resistance to aminoglycosides and trimethoprim-sulfamethoxazole, as well as high frequency of co-existence of fluoroquinolone resistance, creates problems. Beta-lactamase inhibitors such as clavulanate, sulbactam, and tazobactam in vitro inhibit most ESBLs, but the clinical effectiveness of beta-lactam/beta-lactamase inhibitor combinations cannot be relied on consistently for therapy. Cephamycins (cefoxitin and cefotetan) are not hydrolyzed by majority of ESBLs, but are hydrolyzed by associated AmpC-type β-lactamase. Also, β-lactam/β-lactamase inhibitor combinations may not be effective against organisms that produce AmpC-type β-lactamase. Sometimes these strains decrease the expression of outer membrane proteins, rendering them resistant to cephamycins. In vivo studies have yielded mixed results against ESBL-producing K. pneumoniae. (Cefepime, a fourth-generation cephalosporin, has demonstrated in vitro stability in the presence of many ESBL/AmpC strains.) Currently, carbapenems are, in general, regarded as the preferred agent for treatment of infections due to ESBL-producing organisms. Carbapenems are resistant to ESBL-mediated hydrolysis and exhibit excellent in vitro activity against strains of Enterobacteriaceae expressing ESBLs.^{[citation needed]}

According to genes

ESBLs

Strains producing only ESBLs are susceptible to cephamycins and carbapenems in vitro and show little if any inoculum effect with these agents.

For organisms producing TEM and SHV type ESBLs, apparent in vitro sensitivity to cefepime and to piperacillin/tazobactam is common, but both drugs show an inoculum effect, with diminished susceptibility as the size of the inoculum is increased from 10⁵ to 10⁷ organisms.

Strains with some CTX-M–type and OXA-type ESBLs are resistant to cefepime on testing, despite the use of a standard inoculum.

Inhibitor-Resistant β-lactamases

Although the inhibitor-resistant TEM variants are resistant to inhibition by clavulanic acid and sulbactam, thereby showing clinical resistance to the beta-lactam—beta lactamase inhibitor combinations of amoxicillin-clavulanate (Co-amoxiclav), ticarcillin-clavulanate, and ampicillin/sulbactam, they remain susceptible to inhibition by tazobactam and subsequently the combination of piperacillin/tazobactam.

AmpC

AmpC-producing strains are typically resistant to oxyimino-beta lactams and to cephamycins and are susceptible to carbapenems; however, diminished porin expression can make such a strain carbapenem-resistant as well.

Carbapenemases

Strains with IMP-, VIM-, and OXA-type carbapenemases usually remain susceptible. Resistance to non-beta-lactam antibiotics is common in strains making any of these enzymes, such that alternative options for non-beta-lactam therapy need to be determined by direct susceptibility testing. Resistance to fluoroquinolones and aminoglycosides is especially high.

According to species

Escherichia coli or Klebsiella

For infections caused by ESBL-producing Escherichia coli or Klebsiella species, treatment with imipenem or meropenem has been associated with the best outcomes in terms of survival and bacteriologic clearance. Cefepime and piperacillin/tazobactam have been less successful. Ceftriaxone, cefotaxime, and ceftazidime have failed even more often, despite the organism's susceptibility to the antibiotic in vitro. Several reports have documented failure of cephamycin therapy as a result of resistance due to porin loss. Some patients have responded to aminoglycoside or quinolone therapy, but, in a recent comparison of ciprofloxacin and imipenem for bacteremia involving an ESBL-producing K. pneumoniae, imipenem produced the better outcome

Pseudomonas aeruginosa

There have been few clinical studies to define the optimal therapy for infections caused by ESBL producing Pseudomonas aeruginosa strains.

Detection

Beta-lactamase enzymatic activity can be detected using nitrocefin, a chromogenic cephalosporin substrate which changes color from yellow to red upon beta-lactamase mediated hydrolysis.^[21]

Evolution

Beta-lactamases are ancient bacterial enzymes. The class B beta-lactamases (the metallo-beta-lactamases) are divided into three subclasses: B1, B2 and B3. Subclasses B1 and B2 are theorized to have evolved about one billion years ago and subclass B3s is theorized to have evolved before the divergence of the Gram-positive and Gram-negative eubacteria about two billion years ago.^[22]

The other three groups are serine enzymes that show little homology to each other. Structural studies have shown that groups A and D are sister taxa and that group C diverged before A and D.^[23] These serine-based enzymes, like the group B betalactamases, are of ancient origin and are theorized to have evolved about two billion years ago.^[24]

The OXA group (in class D) in particular is theorized to have evolved on chromosomes and moved to plasmids on at least two separate occasions.^[25]

References

^ Neu HC (June 1969). "Effect of beta-lactamase location in Escherichia coli on penicillin synergy". Appl Microbiol 17 (6): 783–6. PMC 377810. PMID 4894721.
^ Abraham EP, Chain E (1940). "An enzyme from bacteria able to destroy penicillin". Nature 46 (3713): 837–837. doi:10.1038/146837a0.
^ Bush K, Jacoby GA, Medeiros AA (June 1995). "A functional classification scheme for beta-lactamases and its correlation with molecular structure". Antimicrob. Agents Chemother. 39 (6): 1211–33. doi:10.1128/AAC.39.6.1211. PMC 162717. PMID 7574506.
^ Bush K, Jacoby GA (2010). "Updated functional classification of beta-lactamases". Antimicrob. Agents Chemother. 54 (3): 969–76. doi:10.1128/AAC.01009-09. PMC 2825993. PMID 19995920.
^ Ambler RP (May 1980). "The structure of beta-lactamases". Philos. Trans. R. Soc. Lond., B, Biol. Sci. 289 (1036): 321–31. doi:10.1098/rstb.1980.0049. PMID 6109327. .
^ ^a ^b Philippon A, Arlet G, Jacoby GA (January 2002). "Plasmid-determined AmpC-type beta-lactamases". Antimicrob. Agents Chemother. 46 (1): 1–11. doi:10.1128/AAC.46.1.1-11.2002. PMC 126993. PMID 11751104.
^ Sanders CC, Sanders WE (June 1979). "Emergence of resistance to cefamandole: possible role of cefoxitin-inducible beta-lactamases". Antimicrob. Agents Chemother. 15 (6): 792–7. doi:10.1128/AAC.15.6.792. PMC 352760. PMID 314270.
^ Emery CL, Weymouth LA (August 1997). "Detection and clinical significance of extended-spectrum beta-lactamases in a tertiary-care medical center". J. Clin. Microbiol. 35 (8): 2061–7. PMC 229903. PMID 9230382.
^ Cooksey R, Swenson J, Clark N, Gay E, Thornsberry C (May 1990). "Patterns and mechanisms of beta-lactam resistance among isolates of Escherichia coli from hospitals in the United States". Antimicrob. Agents Chemother. 34 (5): 739–45. doi:10.1128/AAC.34.5.739. PMC 171683. PMID 2193616.
^ ^a ^b Paterson DL, Hujer KM, Hujer AM, Yeiser B, Bonomo MD, Rice LB et al. (November 2003). "Extended-spectrum beta-lactamases in Klebsiella pneumoniae bloodstream isolates from seven countries: dominance and widespread prevalence of SHV- and CTX-M-type beta-lactamases". Antimicrob. Agents Chemother. 47 (11): 3554–60. doi:10.1128/AAC.47.11.3554-3560.2003. PMC 253771. PMID 14576117.
^ ^a ^b Bradford PA (October 2001). "Extended-spectrum beta-lactamases in the 21st century: characterization, epidemiology, and detection of this important resistance threat". Clin. Microbiol. Rev. 14 (4): 933–51, table of contents. doi:10.1128/CMR.14.4.933-951.2001. PMC 89009. PMID 11585791.
^ Jacoby GA, Munoz-Price LS (January 2005). "The new beta-lactamases". N. Engl. J. Med. 352 (4): 380–91. doi:10.1056/NEJMra041359. PMID 15673804.
^ ^a ^b Woodford N, Ward E, Kaufmann ME et al. "Molecular characterisation of Escherichia coli isolates producing CTX-M-15 extended-spectrum β-lactamase (ESBL) in the United Kingdom" (PDF). Health Protection Agency. Retrieved 2006-11-19.
^ Hudson CM, Bent ZW, Meagher RJ, Williams KP (June 7, 2014). "Resistance determinants and mobile genetic elements of an NDM-1-encoding Klebsiella pneumoniae strain". PLoS ONE 9 (6): e99209. doi:10.1371/journal.pone.0099209. PMID 24905728.
^ Santillana E, Beceiro A, Bou G, Romero A (March 2007). "Crystal structure of the carbapenemase OXA-24 reveals insights into the mechanism of carbapenem hydrolysis". Proc. Natl. Acad. Sci. U.S.A. 104 (13): 5354–9. doi:10.1073/pnas.0607557104. PMC 1838445. PMID 17374723.
^ Nordmann P, Cuzon G, Naas T (April 2009). "The real threat of Klebsiella pneumoniae carbapenemase-producing bacteria". Lancet Infect Dis 9 (4): 228–36. doi:10.1016/S1473-3099(09)70054-4. PMID 19324295.
^ Cuzon G, Naas T, Nordmann P (February 2010). "[KPC carbapenemases: what is at stake in clinical microbiology?]". Pathol. Biol. (in French) 58 (1): 39–45. doi:10.1016/j.patbio.2009.07.026. PMID 19854586.
^ Kim JY, Jung HI, An YJ, Lee JH, Kim SJ, Jeong SH et al. (May 2006). "Structural basis for the extended substrate spectrum of CMY-10, a plasmid-encoded class C beta-lactamase". Mol. Microbiol. 60 (4): 907–16. doi:10.1111/j.1365-2958.2006.05146.x. PMID 16677302.
^ Lee JH, Jung HI, Jung JH, Park JS, Ahn JB, Jeong SH et al. (2004). "Dissemination of transferable AmpC-type beta-lactamase (CMY-10) in a Korean hospital". Microb. Drug Resist. 10 (3): 224–30. doi:10.1089/mdr.2004.10.224. PMID 15383166.
^ Walsh TR, Weeks J, Livermore DM, Toleman MA (May 2011). "Dissemination of NDM-1 positive bacteria in the New Delhi environment and its implications for human health: an environmental point prevalence study". Lancet Infect Dis 11 (5): 355–62. doi:10.1016/S1473-3099(11)70059-7. PMID 21478057.
^ O'Callaghan CH, Morris A, Kirby SM, Shingler AH (April 1972). "Novel method for detection of beta-lactamases by using a chromogenic cephalosporin substrate". Antimicrob. Agents Chemother. 1 (4): 283–8. doi:10.1128/AAC.1.4.283. PMC 444209. PMID 4208895.
^ Hall BG, Salipante SJ, Barlow M (July 2004). "Independent origins of subgroup Bl + B2 and subgroup B3 metallo-beta-lactamases". J. Mol. Evol. 59 (1): 133–41. doi:10.1007/s00239-003-2572-9. PMID 15383916.
^ Hall BG, Barlow M (September 2003). "Structure-based phylogenies of the serine beta-lactamases". J. Mol. Evol. 57 (3): 255–60. doi:10.1007/s00239-003-2473-y. PMID 14629035.
^ Hall BG, Barlow M (April 2004). "Evolution of the serine beta-lactamases: past, present and future". Drug Resist. Updat. 7 (2): 111–23. doi:10.1016/j.drup.2004.02.003. PMID 15158767.
^ Barlow M, Hall BG (September 2002). "Phylogenetic analysis shows that the OXA beta-lactamase genes have been on plasmids for millions of years". J. Mol. Evol. 55 (3): 314–21. doi:10.1007/s00239-002-2328-y. PMID 12187384.

External links

Online ESBL genotyping tool (EGT)
Online Amino Acid Sequences for ESBL enzymes
beta-Lactamases at the US National Library of Medicine Medical Subject Headings (MeSH)

UpToDate Contents

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1. 基質特異性拡張型β-ラクタマーゼ extended spectrum beta lactamases
2. Overview of carbapenemase-producing gram-negative bacilli
3. β-ラクタマーゼ阻害剤、カルバペネム系、およびモノバクタム系抗菌薬の併用 combination beta lactamase inhibitors carbapenems and monobactams
4. β-ラクタム系抗生物質：作用機序、耐性および有害作用 beta lactam antibiotics mechanisms of action and resistance and adverse effects
5. セフェム系 cephalosporins

English Journal

A Case Study Comparing Quantitative Stability-Flexibility Relationships Across Five Metallo-β-Lactamases Highlighting Differences Within NDM-1.

Brown MC, Verma D, Russell C, Jacobs DJ, Livesay DR.SourceDepartment of Bioinformatics and Genomics, University of North Carolina, Charlotte, NC, USA.
Methods in molecular biology (Clifton, N.J.).Methods Mol Biol.2014;1084:227-38. doi: 10.1007/978-1-62703-658-0_12.
The Distance Constraint Model (DCM) is an ensemble-based biophysical model that integrates thermodynamic and mechanical viewpoints of protein structure. The DCM outputs a large number of structural characterizations that collectively allow for Quantified Stability-Flexibility Relationships (QSFR) to
PMID 24061924

Epidemiology and acquisition of extended-spectrum beta-lactamase-producing Enterobacteriaceae in a septic orthopedic ward.

Agostinho A, Renzi G, Haustein T, Jourdan G, Bonfillon C, Rougemont M, Hoffmeyer P, Harbarth S, Uçkay I.SourceInfection Control Program, University of Geneva Hospitals and Faculty of Medicine, Geneva, Switzerland.
SpringerPlus.Springerplus.2013 Dec;2(1):91. Epub 2013 Mar 8.
Wards cohorting infected orthopaedic patients may be particularly prone to transmitting extended-spectrum beta-lactamase-producing Enterobacteriaceae (ESBL-E). We analyze their epidemic pattern by performing molecular typing of ESBL-E isolated from patients and healthcare workers (HCW) from our sept
PMID 23539506

7th International Symposium on Enabling Technologies for Life Sciences (ETP).

[No authors listed]AbstractThe seventh in the series of ETP Symposia (see Rapid Communications in Mass Spectrometry 2012, 26, 1515-1518 for a description and report on the 6th Symposium) was held at the Metro Toronto Convention Centre, Toronto, Canada, on 30 April to 1 May, 2013, and was chaired by Professor Daniel Figeys, Ottawa Institute for Systems Biology, University of Ottawa. The purpose of these symposia is to convene meetings of scientists and engineers from universities, government laboratories, industry and manufacturers of scientific instrumentation, to discuss novel technologies and methodologies applicable to research in molecular biology. The speakers and the Abstracts of their presentations are listed alphabetically below. The program illustrates some significant changes from earlier versions (www.etpsymposium.org) that were devoted almost entirely to proteomics (the 'P' in 'ETP'). In addition to new techniques and applications related to that area, this symposium featured work related to nucleic acid characterization, biomaterials discovery, water disinfection byproducts, and metabolomics, as well as more fundamental developments in mass spectrometry (ionization techniques and quadrupole theory) and sample preparation. The symposium is now more truly international, with speakers from Canada, USA, Europe and China. It is hoped that the wide variety of topics and backgrounds of participants, together with the highly informal setting, will help promote cross-fertilization of ideas and unforeseen collaborations. Perdita E. Barran, Department of Chemistry, The University of Edinburgh, Edinburgh, UK Resolution of solution structures in the absence of solvent (Invited Talk) Gentle application of nano-electrospray to proteins buffered in solution to an appropriate pH allows us to use mass spectrometry to interrogate their solution conformations. This can be achieved directly with ion mobility mass spectrometry where we measure the rotationally averaged temperature dependent collision cross section of mass separated ions, or more indirectly with the use of dissociation methods. Data obtained from both methods provides insight to the structure and stability of the protein, and also detail on its interactions, especially when combined with atomistically resolved data from crystallography and/or computational approaches. Data were presented from two systems, the first was a peptide level model of the interaction between the transcription factor c-MYC and its partner MAX; the second was a detailed structural evaluation of the metamorphic protein Lymphotactin. Ronald Beavis, Beavis Informatics Ltd, Winnipeg, Canada False negatives in proteomics (Invited Talk) Proteomics experiments using tandem mass spectrometry to identify peptides and proteins are prone to various types of false negative identifications that can affect the utility of the information generated from the experiments, as well as their reproducibility. This talk discussed the classification of the most common types of false negatives as well as how they can be detected, remedied or avoided. John D. Brennan, Blake J. Helka and Elna D. Luckham, Department of Chemistry, McMaster University, Hamilton, Canada Imaging MALDI MS/MS of microarrays as a platform for high throughput biomaterials discovery (Invited Talk) This presentation highlighted recent work within the Biointerfaces Institute at McMaster University in the area of high throughput screening of biomaterials, with particular emphasis on the use of imaging MALDI for characterization of biomaterial microarrays. Using robotic handling systems and a combination of contact and noncontact microarray printing, we are able to produce several thousand biomaterials per day with a wide range of chemical compositions. Using sol-gel based materials as an example, the presentation showed the workflow utilized to develop new bioactive sol-gel materials for biosensing and small molecule screening applications. This includes methods to produce several thousand materials very rapidly, tools for rapid screening to identify " hits" that show a desired property (high biological activity, low non-specific binding, etc.), and further detailed material analysis using a range of imaging methods based on fluorescence, XPS, MALDI-MS/MS and SPR to fully characterize the properties of biologically active materials. In particular, this presentation emphasized the unique capabilities of MALDI-MS/MS for evaluating biomaterial properties and the interaction of materials with biological samples. Methods for cataloging, mining and analyzing large datasets within the Database of Biointerface Interactions were also discussed. Rui Chen, H. Zou and D. Figeys, Ontario Institute for Systems Biology, University of Ottawa, Ottawa, Canada Characterization of cell membrane N-glycosylation with integrated hydrophilic interaction chromatography solid phase extraction and LC/MS/MS Glycosylation of membrane proteins plays important roles in cellular behaviours such as cell-cell interaction, immunology recognition and cell signalling. Despite their importance the effective extraction of membrane protein, selective isolation of glycopeptides and mass spectrometric characterization of glycosylation are challenging current analytical techniques. In this study, a systematic approach was developed which combined an integrated hydrophilic interaction chromatography solid phase extraction (HILIC SPE) for simultaneous detergent removal and glycopeptides enrichment, and mass spectrometric identification of both protein N-glycosylation sites and site-specific glycan structure. The HILIC SPE condition was optimized to enable the use of high concentration of strong detergents, such as SDS and Triton X-100, to dissolve highly hydrophobic membrane proteins, thus increasing the yield of membrane protein extraction. We illustrated the performance of this approach for the study of membrane protein glycosylation from human embryonic kidney cell lines (HEK 293T). 200 µg total protein digest was processed using this approach, leading to the identification of 813 N-glycosylation sites from 568 proteins within two experimental replicates. Furthermore, 177 glycopeptides representing 82 N-glycosides with both glycan composition and peptide sequence were identified by high energy collision dissociation. Andrew Crowell, A. Doucette and S. Rudolph, Department of Chemistry, Dalhousie University, Halifax, NS, Canada. Disposable two-stage spin cartridges for protein purification in a top-down proteomics workflow Proper proteome analysis by mass spectrometry depends on upstream sample manipulations, including protein concentration and purification. Cleanup strategies typically rely on chromatography, not only for the relative high recovery and purification efficiency, but also for ease of use through automation. Unfortunately, with chromatographic approaches sample loss is an expected occurrence, especially for high molecular weight and/or hydrophobic (membrane) proteins. By contrast, organic solvent-assisted protein precipitation is extremely effective at protein purification with minimal sample loss. Quantitative protein recovery is possible, though it is highly dependent on the pipetting skills of the individual. It is desired to create a robust protein precipitation protocol by automating the process, thereby maximizing recovery and purity on a high throughput scale. This presentation introduces a disposable two-stage centrifugal cartridge, tailored to automate the precipitation process. The ProTrap XG comprises an upper filtration cartridge together with a removable reversed phase cartridge, attaching at its base. Protein samples are mixed with organic solvents in the upper filter chamber, which induces precipitation of proteins. The pellet is retained by the filter, while contaminants in the supernatant are discarded to waste through a brief spin in a desktop centrifuge. Multiple devices can be used simultaneously, improving throughput while maintaining consistency between samples. Following precipitation, protein pellets are re-solubilized and subject to final purification through the reverse phase cartridge which is re-attached to the base of the filter. The effectiveness of the ProTrap XG for recovery and purification of intact proteins in a top-down proteomics workflow was discussed. Alan Doucette, A. Crowell and S. Rudolph, Department of Chemistry, Dalhousie University, Halifax, NS, Canada Automated SDS removal, tryptic digestion and sample cleanup in a disposable two-stage spin cartridge Prior to MS analysis, bottom up proteomics relies on a significant number of sample manipulations including protein purification and preconcentration, fractionation, digestion, and subsequent cleanup. Each of these steps comes with a risk of loss of analyte and adds to the complexity of the proteomics workflow. The GELFrEE fractionation system is a mass-based electrophoretic platform which relies on an SDS-containing sample buffer to isolate protein fractions in solution. Our group has recommended the use of solvent-induced protein precipitation (acetone or chloroform/methanol/water) to eliminate the SDS ahead of LC/MS analysis. However, protein precipitation is a particularly tedious and highly variable technique for the recoverery of proteins in high yield. Subsequent resolubilization of the protein pellet is also challenging, and further jeopardizes the success of MS characterization. To facilitate protein precipitation we have developed a two-stage filtration and chromatographic extraction cartridge designed to work in a conventional benchtop centrifuge. The device automates the recovery of proteins, ensuring uniform purification on a high throughput scale. Protein samples are precipitated in an upper chamber, with residual contaminants (including SDS) flushed through the bottom filter. At this point the base filter is capped, trapping proteins in the upper vial for subsequent resolubilization. A combination of urea and trypsin ensures complete digestion of the pellet. The peptides are then subject to reversed phase purification; here we link a chromatographic cartridge to the base of the filter chamber. Key figures of merit of the device, including the purity of SDS removal, protein recovery, digestion efficiency and peptide recovery, were demonstrated through standard and complex proteome mixtures. Don Douglas1 , C. Gao1 , K. Kim1 , H. Qiao2 and N. Konenkov3 1 Department of Chemistry, University of British Columbia, Vancouver, Canada 2 Ionics Mass Spectrometry Group, Bolton, ON, Canada 3 Physical and Mathematical Department, Ryazan State University, Ryazan, Russia Space charge effects in linear quadrupole ion traps with mass selective axial ejection (Invited Talk) Experiments and ion trajectory calculations have been used to better understand and to reduce space charge effects in linear quadrupole ion traps operated with axial ejection. If too many ions are stored in a linear trap their mutual repulsion counteracts the trapping forces and the ion oscillation frequencies decrease. Consequently higher trapping radio frequency voltages are required to bring ions into resonance for ejection, and ions appear at higher apparent masses in a spectrum. At the same time the mass resolution decreases. For the experiments of interest here the mass shifts are about 1 at m/z 609, and the electric field from space charge is a small perturbation to the trapping field. Experiments show that a proper choice of operating conditions can reduce but not eliminate mass shifts. Trajectory calculations of ion motion with various models of the ion cloud provide additional insight, and show that the space charge field is nonlinear and that therefore the ion oscillation frequency depends on oscillation amplitude. Anything that expands the ion cloud produces lower electric fields from space charge, and hence lowers mass shifts. Experiments in progress show that using broadband excitation, dipole dc, or two-frequency excitation to expand the ion cloud gives modest reductions in mass shifts and improvements in resolution. Norman Dovichi, Department of Chemistry and Biochemistry, University of Notre Dame, South Bend, Indiana, USA Capillary electrophoresis for high throughput proteomics (Keynote Lecture) Most proteomics studies employ LC/ESI-MS/MS analysis of peptides. We are investigating capillary electrophoresis (CE)/ESI-MS/MS as an alternative technology for bottom-up proteomics. We first developed a rugged and sensitive CE/ESI interface based on electrokinetically pumped sheath-flow.[1] This interface operates in the nanospray domain, produces low-attomole detection limits for CE separation of peptides, and offers great flexibility in separation buffer conditions.[1,2] We then analyzed the secreted protein fraction of M. marinum.[3] We pre-fractionated the secretome to produce simpler samples that were better suited to the separation performance of capillary zone electrophoresis (CZE). The results of the analysis of 12 fractions were compared with conventional UPLC analysis of the unfractionated sample. CZE produced slightly more protein identifications in a slightly shorter time period than UPLC. 140 protein groups were identified by CZE/ESI-MS/MS in three hours from this sample. We have recently improved the system. In the single-shot analysis of the E coli proteome, we identified >1,300 peptides and >300 protein groups in a 50-min CZE separation.[4] We have employed this separation system to analyze seven fractions from the E. coli proteome.[5] This system produced 23,706 peptide spectra matches, 4,902 peptide IDs, and 871 protein group IDs in 350 min analysis time. In an alternative separations scheme, we employed capillary isoelectric focusing for the analysis of host-cell proteins in commercial biopharma products; this system identified 37 host cell proteins in a total sample preparation time of 4 hours.[6] [1] Wojcik et al. Rapid Communun. Mass Spectrom. 2010, 24, 2554. [2] Wojcik et al. Talanta 2012, 88, 324. [3] Li et al. Anal. Chem. 2012, 84, 1616. [4] Zhu et al. Anal. Chem. 2013, 85, 2569. [5] Yan et al. In revision [6] Zhu et al. Talanta 2012, 98, 253. Ann M. English, Department of Chemistry and Biochemistry, Concordia University, Montréal, Québec, Canada Platform development to monitor age- and oxidant-related protein post-translational modifications: The case of copper-zinc superoxide dismutase (Invited Talk) Non-enzymatic protein post-translational modifications (PTMs) increase with age and are frequently associated with age-dependent diseases. For example, copper-zinc superoxide dismutase (CuZnSOD) aggregation has been reported in patients with late onset neurodegenerative diseases such as sporadic or familial Amyotrophic Lateral Sclerosis (ALS) and Alzheimer's. Non-enzymatic PTMs in CuZnSOD are linked to its aggregation and hence to the development of ALS and Alzheimer's. Yeast is a widely used model of cellular and organismal aging that can be readily exploited in platforms to monitor age-related PTMs in a cellular environment. Furthermore, yeast and human CuZnSODs share high sequence homology but, since yeast ages much faster, we are exploring age-related PTMs in the yeast enzyme. By gel filtration of cell lysates we isolated a high-mass inactive form of CuZnSOD, and found by FT-MS that it is oxidized at cysteine 146 (C146) to the sulfonic acid. Importantly, C146 is also found in the sulfonic acid form in CuZnSOD isolated from the brains of Alzheimer's patients[1] and the C146R mutation has been reported in familial ALS.[2] Notably, C146 forms a C146-C55 disulfide bridge that is critical in stabilizing the native CuZnSOD homodimer. In high-mass CuZnSOD, we additionally observe oxidation of histidine 71 (H71) and H120, which ligate the active-site zinc and catalytic copper, respectively. We hypothesize that age-induced oxidation of C146, H71, and H120 contributes to the development of ALS as well as Alzheimer's by releasing the redox-active catalytic copper, which would probably increase oxidative stress and CuZnSOD aggregation. By monitoring the GFP (green fluorescent protein) fluorescence of CuZnSOD-GFP from an isogenic yeast strain expressing this fusion protein, we noted that the cellular content of high-mass CuZnSOD-GFP increases ~10-fold from day 3 to day 7. We are currently characterizing CuZnSOD and CuZnSOD-GFP from yeast cells over several weeks to establish if aggregated CuZnSOD continues to accumulate in old cells. CuZnSOD activity also is known to be inhibited by inflammatory processes in the airway epithelium, and C146 oxidation was reported in CuZnSOD purified from the erythrocytes of asthmatic patients.[3] To mimic the inflammatory state of asthma we are examining modification of CuZnSOD after challenging yeast cells with H2 O2 . Our highly sensitive LC/MS platform that tracks protein modification as yeast ages is providing in-depth information at the molecular level that is critical towards understanding the functional significance of PTMs in the cellular context. [1] Choi et al. J. Biol. Chem. 2005, 280, 11648. [2] Andersen et al. Amyotroph. Lateral Scler. Other Motor Neuron Disord. 2003, 4, 62. [3] Ghosh et al. Antioxid Redox Signal 2012. DOI: 10.1089/ars.2012.4566. Daniele Fabris, The RNA Institute, State University of New York, The University at Albany, Albany, NY, USA MS-based strategies for the elucidation of nucleic acid-ligand interactions (Invited Talk) Ribozymes and riboswitches have keenly demonstrated that the function of nucleic acids is not always linked to the genetic information coded in their sequence, but can also depend on their 3D structure and ability to interact with a variety of species present in the cell. Owing to the versatility afforded by mass spectrometry (MS) in RNA analysis this platform is rapidly assuming a prominent role in the investigation of structure-function relationships, which is realized by supporting the full characterization of natural and man-made RNAs as well as the elucidation of specific interactions with cognate nucleic acids, proteins, metals, and small molecule ligands. The talk illustrated strategies for accessing functional information for nucleic acid complexes and discussed possible hurdles and experimental pitfalls. Examples were provided in which MS-based techniques are employed to characterize relevant interactions that could represent new therapeutic targets. Other examples illustrated approaches for elucidating the effects of metals and common nucleic acid ligands on such interactions. The experimental design necessary to assess the strength of binding/inhibition in either comparative or absolute fashion was also discussed. The potential afforded by ion mobility spectrometry (IMS) techniques was evaluated in the investigation of possible conformational effects associated with ligand binding. Owing to the extremely low sample consumption and high speed of analysis, these capabilities will be expected to greatly increase the utilization of MS-based approaches in drug discovery and therapeutics development based on specific nucleic acid interactions. Bella Groisman, J. Petschnigg and I. Stagljar, Department of Biochemistry, University of Toronto, Toronto, Canada A novel mammalian split-ubiquitin proteomics approach as a tool for functional investigation of signaling pathways in human cells The membrane yeast two-hybrid system (MYTH) is a robust technique for the identification of protein partners of integral membrane proteins. However, its implementation for mammalian proteins is limited due to differences between mammalian and yeast cells. Here we present a novel split-ubiquitin-based mammalian membrane two-hybrid (MaMTH) technology that enables investigation of protein-protein interactions (PPIs) in human cells. Briefly, the specific interaction between membrane 'bait' and 'prey' proteins, coupled to ubiquitin halves, allows reconstitution of functional ubiquitin. Subsequently, deubiquitinating enzymes cleave off the transcription factor coupled to the bait, thus activating reporter gene transcription. Using the MaMTH technology we successfully confirmed known PPIs of membrane proteins from various cellular compartments. Here we focus on the ErbB members of receptor tyrosine kinases, mainly on the EGFR wild type (WT) versus the oncogenic kinase-active L858R version - dynamic interactomes and functional analysis. We demonstrate that MaMTH allows sensitive detection of phospho-dependent and drug-inhibited interactions. We show that EGFR WT recruits Shc1 adaptor in serum-dependent manner, while oncogenic L858R shows constitutively stimuli-independent binding. Furthermore, consistent with clinical data EGFR (L858R) interaction with Shc1 was efficiently inhibited by the EGFR small molecule inhibitor erlotinib (tarceva), while the secondary L858RT790M resistant mutant was not affected by the drug. In addition, we created a dynamic interactome of EGFR WT versus L858R with 200 predicted interactors, data which is of high importance for the cancer signaling scientific community. In summary, here we presented a novel powerful proteomics technology, which we are planning to develop as tool for high-throughput proteomic research as well as a drug screening platform. David Juncker, Department of Biomedical Engineering, McGill University, Montréal, Canada Antibody colocalization microarray (ACM): A scalable cross-reactivity free nano-ELISA platform for proteomics studies Quantification of proteins with high specificity in blood can be performed using sandwich immunossays (e.g. ELISA). Multiplex sandwich immunoassays (MSI) were developed to measure multiple proteins at once, but cross-reactivity among reagents is known to limit accuracy and reproducibility. Here we explain the origin of the cross-reactivity in MSI, experimentally show the consequences, and introduce a novel assay format called the antibody Colocalization Microarray (ACM) that eliminates it. In MSI a slide is patterned with an array of capture antibodies, incubated with a sample, followed by a mixture of detection antibodies. Here we analyze the combinatorial interactions between detection and capture antibodies and antigens, and find that it increases quadratically with the number of targets. In an array with 14 targets we found widespread cross-reactivity. To overcome the cross-reactivity we introduce the ACM where all detection antibodies are individually spotted with high accuracy onto their corresponding capture antibody spot. Each spot on the ACM replicates an ELISA but using only 1 nL of reagent, constituting a Nano-ELISA. An ACM with 50 targets was shown experimentally to overcome cross-reactivity and to rival the sensitivity of ELISA. The ACM was validated for biomarker studies by measuring proteins in the serum of breast cancer patients and controls, and a candidate biomarker panel was identified. It is currently being used to identify biomarkers for traumatic brain injury. As the number of targets on the ACM is increased easily, it may become a powerful tool for biomarker discovery and validation. John Klassen, Department of Chemistry, University of Alberta, Edmonton, Canada New MS tools for the discovery and characterization of protein-carbohydrate interactions (Invited Talk) The direct electrospray ionization mass spectrometry (ESI-MS) assay has emerged as a powerful tool for quantifying protein-ligand interactions in solution. The assay is based on the direct detection and quantification of free and ligand-bound protein ions by ESI-MS for solutions of known initial concentrations of protein and ligand. A brief overview of the ESI-MS assay was presented, along with recent methodological advances that overcome the major sources of error in the binding measurements. A high-throughput ESI-MS approach to library screening was also presented. The catch-and-release (CaR)-ESI-MS assay involves incubating a protein with a library of compounds in solution, detecting the protein-ligand complexes by ESI-MS, activating the complexes to release the ligand. The identities of ligands are determined from measured molecular weights and, if needed, the fragmentation spectra and ion mobility arrival time distributions. The CaR-ESI-MS assay allows for the sensitive, rapid (<1 min analysis time) and direct detection and quantification of specific interactions for libraries containing hundreds of compounds. An overview of the assay was presented followed by examples highlighting the application of the assay for the discovery of carbohydrate ligands for a variety of bacterial proteins. Finally, the extension of the CaR-ESI-MS assay for the discovery of host cell receptors was described. The assay involves direct ESI-MS analysis of aqueous solutions of soluble proteins and insoluble receptors, which are incorporated into nanodiscs. The application of this assay for the detection of interactions between bacterial toxins and glycosphingolipids was presented. X. Chris Le, H. Zhang, F. Li, B. Dever, X. Li, C. Wang, M. Wagner, Z. Wang and X.-F. Li, Departments of Chemistry and of Laboratory Medicine and Pathology, University of Alberta, Edmonton, Canada DNA-mediated binding assays for nucleic acids and proteins (Invited Talk) The detection of nucleic acids and proteins is fundamental for studying their functions and for the development of molecular diagnostics. Determining these biomolecules in complex systems requires exquisite analytical specificity and sensitivity. To meet these requirements we have devoted much effort to affinity binding assays that incorporate target recognition, signal transduction, and in situ amplification. Here we focus on homogeneous binding assays, which are carried out in solution, without the need for separation, immobilization, or washing steps. Such homogeneous binding assays can be performed in a single tube/vial or in live cells. They are potentially applicable to point-of-care diagnostics. For example, a binding-induced DNA assembly enables ultrasensitive detection of molecular targets and construction of unique target-dependent nanoreactors. Two DNA motifs that are conjugated to specific affinity probes assemble preferentially only when a specific target triggers a binding event. The binding-induced assembly of the DNA motifs results in the formation of a highly stable hairpin structure, enabling effective differentiation of the target-specific assembly from the background. This strategy pushes the limit of the state-of-art dynamic DNA nanotechnology to include molecules beyond DNA. The ability to generate dynamic DNA assembly by non-DNA molecules opens up opportunities for diverse potential applications, ranging from the construction of protein-induced nanodevices to the in situ detection of proteins and studies of molecular interactions. XingFang Li, W. Wang, Y. Quian and J. M. Boyd, Department of Laboratory Medicine and Pathology, University of Alberta, Edmonton, Canada. Mass spectrometry methods for characterization and determination of disinfection byproducts in tap water and swimming pools Protection of public health requires disinfection of drinking water and recreation pools to effectively prevent water-borne diseases. However, common disinfection treatments unavoidably generate byproducts resulting from reactions between natural organic matter in the source water and disinfectants. The majority (~70%) of disinfection byproducts (DBPs) in treated water remain unidentified. Potential adverse health effects observed in epidemiological studies drive analytical research to identify and determine what DBPs may contribute to these health risks. Here we present the separation of and mass spectrometry methods to characterize emerging DBPs of toxicological relevance, and investigate the occurrence of these DBPs in swimming pools. The research demonstrated that personal care products contributed to the formation of some emerging DBPs such as halobenzoquinones. Yueqiao Fu, Lily Mats, Graham T. T. Gibson and Richard Oleschuk, Department of Chemistry, Queens University, Kingston, Ontario, Canada Multi-nano ESI, in pursuit of enhanced robustness, stability and sensitivity (Invited Talk) Electrospray ionization (ESI) as a soft ionization technique has been critical to mass spectrometry for analyzing biological macromolecules. NanoESI, which is operated at lower flow rates (nL/min), exhibits both higher ionization efficiency and higher sensitivity since the smaller initial electrospray droplets from the emitter afford increased surface charge per analyte molecule. To improve sensitivity and signal without decreasing flow rate, multiple electrosprays have been generated from multiple emitters by splitting one larger flow into smaller flows in the nanoESI regime. Based upon theoretical prediction and experimental results, the measured spray current generated from an emitter producing multiple Taylor cones (Itotal ) is enhanced relative to the spray current from a single emitter (Is ) at the same overall flow rate by a factor of the square root of the number of emitters (n). We have developed a series of multi-channeled emitters based upon silica and polymer microstructured fibers (MSFs). Custom-designed MSFs having holes in a radial pattern were fabricated using a 'stack and draw' technique, allowing multiple electrosprays from a single fiber. Polymer nozzles have been included in the silica MSF design to enhance nanoESI performance. A layer of polymer is first formed on the inner wall of each of the MSF channels followed by etching with hydrofluoric acid to expose the nozzles. The protruding highly cross-linked divinylbenzene nozzles produce true multi-nanoESI over a wide range of flow rates and mobile phase compositions and are compatible with high-resolution liquid chromatographic separations. Anthony Pawson, Samuel Lunenfeld Research Institute, Mount Sinai Hospital, University of Toronto, Toronto, Canada Using synthetic biology to study protein signaling networks (Plenary Lecture) The proteins involved in the transmission of signals within cells are typically complex, in the sense that they often possess multiple interaction and/or catalytic domains, and are directly or indirectly connected to numerous distinct proteins and other biomolecules such as phospholipids. We have used a variety of synthetic biology and proteomics techniques to investigate the importance of the multiple protein- and lipid-binding domains of the Grb2 adaptor protein and its target, the Ras guanine nucleotide exchange factor Sos1, in controlling a key cell fate decision in early mammalian embryogenesis, namely the differentiation of primitive endoderm tissue. We find that these domains act cooperatively as a coincidence detector to ensure that fibroblast growth factor-dependent signals are transmitted at the right time and in the right place to elicit the appropriate formation of primitive endoderm. Guy Poirier, J.-P. Gagné, J. D. Chapman and D. R. Goodlett, Department of Molecular Biology, Medical Biochemistry and Pathology, Laval University, Québec, PQ, Canada High accuracy mass spectrometry provides direct evidence for site-specific auto-ADP-ribosylation of PARP-1 Poly(ADP-ribose) polymerase-1 (PARP-1) is an abundant chromatin-associated protein involved in a variety of pathways such as DNA damage response (DDR), transcription regulation, cell cycle progression and apoptotic cell death. Upon DNA damage induction, DNA-dependent PARPs synthesize an anionic poly(ADP-ribose) (pADPr) polymer to which several proteins bind with the subsequent formation of pADPr-associated multiprotein complexes. PARP hydrolyzes NAD + in the formation of pADPr on nuclear proteins such as DNA repair enzymes, chromatin remodelers, histones, transcription factors and PARP-1 itself. The covalent attachment of pADPr to a substrate protein alters its physicochemical characteristics, which results in functional consequences on its biological activity. The exact nature of the ADP-ribose linkage catalyzed by PARP-1 has been the subject of controversy and debate. To date, it is still unclear which of the amino acid side chains are directly targeted by the ADP-ribose transferase activity of PARP-1. Radiolabeled NAD + has been a cornerstone in research for tracking and visualizing PARP-catalyzed post-translational protein modification in vitro, but the ability of the negatively charged pADPr to strongly interact with proteins in a non-covalent manner is a cause of confusion when interpreting experimental results. To truly begin to understand the exact nature of the poly(ADP-ribosly)ation reaction, there is a need for more conclusive mass spectrometry evidence of PARP-catalyzed protein modifications. Mapping of these modifications to specific amino acid residues on PARP-1 and other protein substrates of poly(ADP-ribosyl)ation reactions presents significant challenges due to the complex structural heterogeneity of pADPr polymers as well as a loss of amino acid sequencing information that occurs during several mass spectrometry peptide activation techniques commonly implemented for fragmentation. Here, we demonstrate a novel method for the identification of PARP-1 auto-poly(ADP-ribosyl)ation sites utilizing high mass accuracy mass spectrometry. By employing an enzymatically driven simplification of the pADPr modifications, we reduce the corresponding complexity of analyzing modified tryptic peptides at the level of the tandem mass spectrum, which in turn enables us to effectively localize exact sites of PARP-1-catalyzed poly(ADP-ribosyl)ation. In conjunction with a phosphopeptide-like enrichment strategy that captures modified peptides, we are able to successfully locate numerous sites of PARP-1 automodification in a high-throughput proteomics screen suitable for universally available mass spectrometry and data analysis pipelines. Jeffrey Smith, K. Wasslen, S. Wood and J. Manthorpe, Department of Chemistry, Carleton University, Ottawa, Canada Trimethylation enhancement using diazomethane (TrEnDi): Rapid on-column methylation of peptides and proteins to permit quantitative analysis using tandem mass spectrometry Trimethylation enhancement using diazomethane (TrEnDi) is an inexpensive and rapid on-column chemical derivatization technique to permit peptide methylation and quantitation. TrEnDi produces trimethylated primary amines that enhance and simplify label-free quantitation strategies via improved ionization through the formation of fixed quaternary ammonium ions. TrEnDi has been optimized on a microfluidic platform to successfully derivatize peptides from a protein digest with nearly 100% complete N-terminal methylation. Other amino acid side chains with pKa values of approximately 10.5 or less were also methylated. MS/MS analysis confirmed that N-termini trimethylated peptides fragmented to preferentially form the a2 ion, permitting a significant increase in sensitivity when scanning in the MRM mode. This allowed us to perform label-free MRM scanning of candidate peptides without prior knowledge of their fragmentation patterns. The trimethylated peptide N-termini were found to be very stable. However, hydrolysis of the newly formed methyl esters occurred over time. Hydrolysis was assisted using base hydrolysis in order to drive the derivatized peptides to homogeneity. To test the analytical sensitivity of derivatized peptides via MRM scanning, several low concentrations of the modified peptides were spiked into a series of more complex peptide solutions and the ability of the MRM method to obtain quantitative data was assessed. Our results have revealed that the trimethylated peptide N-termini produced strong MRM transitions and were identifiable at low concentrations, even in the presence of highly concentrated interferences. E. Bonneil1 , F. Lamoliatte1,2 , J. Saba4 , O. Caron-Lizotte1 and Dr P. Thibault1,2,3 , Institute for Research in Immunology and Cancer1 , and Departments of Chemistry2 and of Biochemistry3 , Université de Montréal, Montréal, Canada, and Thermo Fisher Scientific4 Quantitative proteomics using FAIMS and isotopic labeling (Invited Talk) Isotopic labeling is a commonly used method in quantitative proteomics to profile changes in protein abundances across different cell conditions. Isotopic labeling can be performed using chemical reagents that target specific functional group on peptides (MS2 quantitation) or via metabolic labeling (stable isotope labeling of cell cultures, SILAC) where cells are cultured in media containing in either light or heavy isotopes of amino acids (MS quantitation). The predictable mass differences between peptides (or fragment ions) from two or more experimental conditions enable a direct quantification and provide precise functional information and temporal changes in the proteome. However, the dynamic range and precision of these quantitative measurements can be hampered by the increasing complexity of the mass spectra and the presence of co-eluting isobaric ions. In this context we evaluated the analytical potentials of high field asymmetric waveform ion mobility spectrometry (FAIMS) in large-scale quantitative proteomics experiments using stable isotope labeling on a LTQ-Orbitrap Elite mass spectrometer. The ability of FAIMS to separate multiply protonated compounds from singly charged background ions provided a unique advantage to extend the dynamic range of peptide detection while reducing the complexity of LC/MS peptide maps. FAIMS analyses performed on cell extracts derivatized with tandem mass tags (TMT)-6plex isotopic label reagent or grown under SILAC conditions provided improved quantitation and dynamic range compared with conventional nanoelectrospray. Quantitative proteomics analyses performed using FAIMS resulted in a reduction of mixed precursor ions and provided confident reporter ion measurements with increased peptide identification. Examples of application were presented for monitoring changes in the proteome of yeast and human cells. Ruijun Tian, Y. Shi, T. Hunter and T. Pawson, The Samuel Lunenfeld Research Institute, Mount Sinai Hospital, University of Toronto, Toronto, Canada Exploring bi-directional signaling in pancreatic tumor microenvironment by quantitative proteomics Pancreatic ductal adenocarcinoma (PDA) is one of the most lethal human cancers with resistance to many chemotherapeutic drugs. This drug resistance effect is believed to be partly caused by stromal-cancer cells interaction in pancreatic tumor microenvironment. Cell-cell interactions are often mediated by protein molecules expressed by one cell that are recognized by specific receptors present on neighboring cells. This intercellular communication activates specific signaling pathways through the induction of dynamic post-translational modifications such as phosphorylation and by protein-protein interactions. Here, we present the development of unbiased quantitative proteomics approaches to characterize a dynamic secretome and critical intracellular signaling in a simulated pancreatic tumor microenviroment in culture. A number of secreted ligand/receptor pairs have been explored which have significant effects on cancer cells proliferation. Our work establishes a generally applicable strategy for studying stromal-cancer cells communication and provides valuable resources for systematically understanding dysfunctional signaling networks in tumor microenvironment in a context closer to physiological conditions than was previously possible. Sarah Trimpin, Department of Chemistry, Wayne State University, Detroit, MI, USA Matrix assisted ionization without a laser, heat, or voltage: identification of peptides and proteins directly from tissue (Invited Talk) A few years ago we introduced an ionization method for use in mass spectrometry (MS), applicable to volatile and nonvolatile compounds, which uses laser ablation of a matrix/analyte mixture similar to atmospheric pressure matrix-assisted laser desorption/ionization (MALDI) but which produces mass spectra nearly identical to electrospray ionization (ESI). This new technique called laserspray ionization (LSI) has advantages of speed of analysis, high spatial resolution for imaging, mass range extension, and improved fragmentation common with multiply charged ions. LSI using the proper matrix was also shown to be capable of imaging multiply charged ions using atmospheric pressure or vacuum MALDI sources. Crucial for the production of highly charged ions are desolvation conditions to remove matrix from charged matrix/analyte clusters. By using a matrix that readily sublimes, we have now extended matrix-assisted ionization by eliminating the need for a laser or even heat to initiate ionization. Ions are spontaneously formed from a solid matrix/analyte material when introduced to a vacuum MALDI source without need of a laser, or to a modified ESI source without use of voltage. This matrix assisted ionization vacuum (MAIV) method produces similar charge states and drift times of ions, as determined by ion mobility spectrometry-MS, to ESI. Compounds at least as large as bovine serum albumin (67 kDa) become converted into highly charged gas-phase ions when exposed in the MAIV matrix to vacuum conditions. Such a simple ionization method, requiring only the vacuum necessary for the proper functioning of the mass spectrometer, may prove useful for analysis of single cells and in clinical applications. A possible mechanism for ionization involving sublimation/evaporation and charge generation through the mechanism that produces triboluminescence was discussed. Dietrich Volmer, Institute of Bioanalytical Chemistry, Saarland University, Saarbrücken, Germany New methods for improved determination of metabolic markers using advanced analytical mass spectrometry techniques (Invited Talk) New developments in metabolomics and metabolic profiling techniques have led to the discovery of metabolic biomarkers indicative of physiological or pathological change, e.g. onset of disease or nutritional effects of a specific diet. Experimental approaches for discovering new biomarkers usually involve proteomics or metabolomics techniques that detect differences between sample sets rather than measuring specific compounds as performed in traditional hypothesis-driven research. Unfortunately, finding metabolites present in significantly different levels between sample sets is often complicated by experimental variables such as method reproducibility, types of tissue sampling technique, analytical sample preparation technique, ion suppression phenomena, person-to-person or animal-to-animal metabolic variations, isobaric or isomeric noise, etc. All these error sources, variations or artefacts can lead to false assignment of metabolites or biomarkers and random and systematic errors during quantification. This presentation focused on our research on metabolite profiling techniques and sources of analytical errors. It presented examples for applications such as quantitative analysis and fingerprinting of vitamin D metabolites, microcystin toxin biomarkers and lipids. In addition, novel technical solutions involving "magnetic" media (fluids and beads), ion mobility spectrometry and chemical labeling techniques were highlighted in this presentation. Fangjun Wang1 , H. Zou1 , M. Ye1 and Daniel Figeys2 1 Key Lab of Separation Science for Analytical Chemistry, National Chromatography R&A Center, Dalian Institute of Chemical Physics, The Chinese Academy of Science, Dalian, China; 2 Ottawa Institute of Systems Biology, Department of Biochemistry, Microbiology and Immunology, University of Ottawa, Ottawa, Canada. Recent development of technologies and methods for proteome analysis (Invited Talk) Technologies and methods play a highly important role for proteome analysis. Recent developments of technologies and methods for proteome analyses in our labs were presented:Combined technologies and methods, such as multi-enzyme digestion, different enrichment methods, multi-dimensional LC separation and different types of mass spectrometers, for comprehensive glycoproteome and phosphoproteome analysis of human liver; the largest dataset of protein phosphorylation and glycosylation for human liver was achieved.Solid-phase based technology by integrating all of the digestion, enrichment, and deglycosylation together with LC/MS analysis, was developed for glycoproteome analysis; both the identification sensitivity and the throughput were improved greatly.A solid-phase based labeling approach, by integration of glycopeptides and phosphopeptides enrichment and stable isotope labeling on adsorbent beads, was developed for relative quantification of protein glycosylation and phosphorylation.Six-plex stable isotope labeling was achieved by a two-stage stable isotope labeling strategy of SILAC and dimethylation isotope labeling, which allows six different protein samples (six-plex) to be reliably labeled and simultaneously quantified at MS1 level. This six-plex isotope labeling strategy was applied to investigate the dynamics of protein turnover, and the 50% turnover times of 1365 proteins within HeLa cells were successfully obtained. Hailin Wang, S. Liu, B. Zhao, D. Zhang, C. Li, State Key Laboratory of Environmental Chemistry and Ecotoxicology, Chinese Academy of Sciences, Beijing, China. Insights on Isotachophoresis Kinetics from Monitoring Non-uniform Motion of single DNA molecules (Invited Talk) Isotachophoresis (ITP) has wide applications in chemistry and life sciences due to its pre-concentration function. A simplified ITP system consists of a leading electrolyte (LE) and a terminating electrolyte (TE). For LE and TE to migrate at the same velocity (v), the respective E in each zone must adapt to their electrophoretic mobility (μ) according to Eqn. (1): [Formula: see text] The LE zone with a high electrophoretic mobility will have a low E, and the TE zone with a low electrophoretic mobility will have a high E. Current literature commonly assumes that the adaption of E is fast and is not the rate-limiting step. However, actual adaption kinetics of ITP has not been studied yet. Moreover, it is not clear how electroosmotic flow affects the kinetics of ITP. By taking advantage of single molecule imaging, we for the first time examined the changes in electric field and the resulting non-uniform motion of single DNA molecules in capillary isotachophoresis. The individual DNA molecules passing the detection window are consecutively imaged in real time at 50-millisecond intervals. Since the migration velocity of DNA is directly proportional to the applied electric field strength (E), imaging the movement of DNA provides necessary information for understanding the distribution of E throughout the capillary. This approach allows us to gain insights into the kinetics of varying-field ITP and enables us to develop a strategy for focusing and detecting single DNA molecules and DNA damages. John Wilkins, Departments of Internal Medicine, Biochemistry and Medical Genetics, University of Manitoba, Winnipeg, Canada Linking protein composition and functionality in biology and medicine (Invited Talk) The repertoire and functional state of proteins expressed by an organism ultimately determine their phenotype. Thus, the inclusion of measures of protein activity is an essential step to developing valid models of biological systems in disease and health. While genomics and proteomics provide detailed information on potential and current protein composition, these approaches generally offer limited insight regarding protein functional states. However, many proteins possess catalytic activities that are stringently controlled by mechanisms that restrict substrate accessibility to the active site. This is the central premise of activity-based protein profiling. The use of enzyme activity as a predictor of organ function or health offers several advantages in the clinical environment. The assays can be highly specific because of the structural features of their substrates. The high substrate turnover numbers of enzymes provides an amplification mechanism that increases assay sensitivity. Activity-based profiling offers a means of probing clinical samples for novel enzymatic activities as new reporters. Some of our experiences in the application of this approach profiling assessing renal function were presented. The identification of a protein, even an active one, does not necessarily address the questions of "What does the protein do?" and "Why is it needed?". These questions can be further complicated by the observations that function(s) are often context specific. We have used integrated proteomic, activity based protein profiling and functional genomics approaches in an effort to examine lymphocyte migration, a process that is central to normal immune function. Derek Wilson, T. Rob, D. Golemi-Kotra and P. Kama-Gill, Department of Chemistry, York University, Toronto, Canada Microfluidics-enabled, sub-second hydrogen/deuterium exchange pulse labeling reveals allosteric 'hotspots' in enzymes Regulation of metabolic pathways is achieved by modulation of enzyme activity, commonly via direct interactions at the active site. However, a substantial number of enzymes are also sensitive to changes at locations well removed from the site of catalysis. These 'allosteric' effects are easily detected, but are exceedingly difficult to characterize because they are usually driven by subtle changes in conformation or dynamics. In this work we use a new microfluidic chip that incorporates a bottom-up workflow with sub-second H/D exchange pulse labeling to probe time-dependent structural and dynamic changes in the beta-lactamase enzyme TEM-1 upon inhibitor binding. Changes in deuterium uptake were noted from the first time-point after acylation, corresponding to both increases and decreases in labeling ('loosening' and 'tightening' of the structure, respectively). As the acyl-enzyme was allowed to age, time-dependent changes in deuterium uptake were detected, indicating the presence of slow structural changes occurring up to 2 s after acylation. In general, peptides showing instantaneous changes in uptake were located near the active site, while peptides that exhibited time-dependent changes in deuterium uptake were located at the periphery of the enzyme. In the active site, patterns of increasing and decreasing rigidity explain the roles of Arg244 and Asn276 in the inhibitory mechanism. At the periphery, slow changes in uptake are observed specifically in allosteric 'hotspots' that include residues known from mutational analysis to play a role in TEM-1 catalytic efficiency. David Wishart, Departments of Biological Sciences and Computing Science, University of Alberta, Edmonton, Canada Clearing the biomarker barrier: Moving biomarkers from the bench to the bedside (Invited Talk) One of the great promises of the 'omics' era was the delivery of a gene or a protein to diagnose every disease. Unfortunately this hasn't quite happened. While our understanding of the etiology of disease has improved tremendously our ability to diagnose or predict disease has not. This has a lot to do with our inability to translate biomarkers from the bench to the bedside. Indeed, after nearly 20 years of work and more than $5 billion in investment, there have been only a few microarray tests and, as yet, no protein-array or proteomic tests approved by the FDA for diseases diagnosis. On the other hand, dozens of metabolomic biomarkers have successfully made the transition from the lab to the clinic. Why? This presentation discussed some of the secrets to the success of metabolomics in clearing the 'biomarker barrier'. In particular, some key guidelines for designing, performing and reporting biomarkers in a biomarker study, as well as some advice with regard to the process of moving biomarkers from the laboratory to the clinic, were provided. Some examples of how quantitative metabolomics is being used to identify biomarkers for a wide range of diseases, and the status of my lab's efforts to try to move some these biomarkers into clinical testing, were also discussed. THE KEN STANDING AWARD LECTURE (Sponsored by the University of Manitoba) Lars Konermann, Departments of Chemistry and of Biochemistry, The University of Western Ontario, London, ON, Canada Electrospray mass spectrometry as a readout of protein structure and function Proteins are nanomachines that carry out countless tasks in every living organism. To perform these functions, the linear amino acid chain of each protein has to fold into a highly specific three-dimensional structure. On the other hand, misfolding and aggregation are associated with diseases such as Alzheimer's and Parkinson's. X-ray crystallography remains the gold standard for obtaining high-resolution structural information. However, the data generated in this way do not properly reflect the highly dynamic nature of proteins, which is a key prerequisite for biological function. Electrospray ionization mass spectrometry (ESI-MS) provides a number of avenues for exploring protein structure, function, folding, and dynamics. Our laboratory specializes in the use of hydrogen exchange and covalent labeling techniques. This presentation discussed time-resolved investigations that provide detailed insights into the mechanisms of protein folding. The area of membrane protein structure and function, and the use of ESI-MS for probing biological self-assembly processes, were also discussed. In addition, recent advances in understanding the physical processes that allow the formation of gaseous biomolecular ions during ESI were presented. THE BILL DAVIDSON GRADUATE STUDENT TRAVEL AWARD (Sponsored by ABSciex) Feng Li, Department of Chemistry, University of Alberta, Edmonton, Canada Dr X. Chris Le, Department of Laboratory Medicine and Pathology, University of Alberta, Edmonton, Canada Dynamic DNA assemblies mediated by binding-induced DNA strand displacement Dynamic DNA assemblies have shown promising potential to regulate cell activities, deliver therapeutic compounds, and amplify detection signals for molecular diagnostics and imaging. However, such applications of dynamic DNA assembly systems have been limited to nucleic acids and a few small molecules. It is challenging to construct dynamic DNA assemblies that are responsive to proteins. We have developed a binding-induced DNA strand displacement strategy that can convert protein binding to the release of a predesigned output DNA at room temperature with high conversion efficiency and low background. This strategy allows us to construct dynamic DNA assembly systems that are able to respond to specific protein binding, opening an opportunity to expand the existing dynamic DNA nanotechnology to proteins for diverse applications. We have applied this strategy to design a binding-induced DNA strand displacement beacon and a binding-induced DNA circuit, both of which are triggered by protein binding. We have demonstrated the detection of platelet-derived growth factor (PDGF) and prostate specific antigen (PSA). Further applications could be in the area of point-of-care analysis of proteins that could be performed under ambient temperature and without requiring the use of enzymes for signal generation and/or amplification. POSTER PRESENTATIONS J. Anichina, A. Schreiber, R. Bonner and T. Sakuma High-resolution tandem mass spectrometry analysis of the interactions of oligonucleotides with selected river basin specific pollutants E. Forsberg and J. Brennan Bio-solid phase extraction and information dependent tandem mass spectrometry for the identification of enzyme inhibitors in complex mixtures H. Li, S. Bergeron, and D. Juncker Snap chip 2.0: Double microarray-to-microarray transfer for easy-to-use, high-density antibody colocalization microarrays P. Liuni and D. J. Wilson Investigating catalysis-linked dynamics in yeast alcohol dehydrogenase by measuring kinetic isotope effects using time-resolved ESI-MS with H/D exchange. P. S. Lo, V. Laforte, S. Bergeron, J. Marcoux and D. Juncker Using the antibody colocalization microarray to measure proteins in complex samples from severe traumatic brain injury patients Z. Ning, D. Seebun, B. Hawley, C.-K. Chiang and D. Figeys From cells to peptides: 'One-stop' integrated proteomic processing using Amphipols D.J. Orton, J.P. Rogers and A.A. Doucette A dual capillary nanospray interface for improved throughput in LC/MS A. Sardar iTRAQ coupled 2D-LC-MALDI-TOF/TOF analysis reveals proteome changes associated Leishmania donovani promastigote adaptation to oxidative and nitrosative stress A. M. Smith and J.D. Brennan Development of a multiplexed kinase assay via MALDI-MS/MS detection J. Song, X. Tang, L. Li, L.C. Palmer, D. Pinto and K. Chisholm OFFGEL peptide pre-fractionation is essential for proteomic approaches employing quantitative stable isotope dimethyl labeling and multiple reaction monitoring (MRM) in fruit proteomic research C. Stephan Pushing the frontier in ICP-MS applications: Counting and sizing nanoparticles using single particle ICP-MS D. Williams, S. Madler, L.V. DeSouza, A. Matta and K.W.M. Siu Intracellular signalling network expression profiling by LC/MS with a heavy isotope-labelled QconCAT internal standard Information about past and future symposia and conferences organized by ETP can be found at the website www.etpsymposium.org. Robert K. Boyd, Researcher Emeritus, National Research Council of Canada Chair, Science Advisory Committee, ETP.
Rapid communications in mass spectrometry : RCM.Rapid Commun Mass Spectrom.2013 Nov 30;27(22):2570-2580. doi: 10.1002/rcm.6724.
The seventh in the series of ETP Symposia (see Rapid Communications in Mass Spectrometry 2012, 26, 1515-1518 for a description and report on the 6th Symposium) was held at the Metro Toronto Convention Centre, Toronto, Canada, on 30 April to 1 May, 2013, and was chaired by Professor Daniel Figeys, Ot
PMID 24123647

Japanese Journal

糞便中におけるESBLとMBL産生腸内細菌科菌の検出状況

吉川耕平,長川隼也,園田美代子 [他]
日本臨床微生物学雑誌 = The journal of the Japanese Society for Clinical Microbiology 24(1), 9-16, 2014
NAID 40020069693

九州山口地区における基質拡張型βラクタマーゼ産生菌の検出状況と抗菌薬使用状況に関する合同調査

室高広,北原隆志,伊東弘樹 [他]
日本環境感染学会誌 = Japanese journal of environmental infecions 29(1), 32-40, 2014
NAID 40019974990

Lower Limb Infection in an Infant with Haemophilus influenzae Serotype b

Hagiya Hideharu,Otsuka Fumio
General Medicine 15(1), 56-58, 2014
… Beta-lactamase-negative ampicillin-resistant strains have been spreading throughout Japan, although the type of Hib in our case was cephalosporin-sensitive. …
NAID 130004543704

Related Pictures

Bêta-lactamase; beta-lactamhydrolase Model for regulation of AmpC β-lactamase induction by AmpR, AmpP and | Download beta lactamases BETA-LACTAM ANTIBIOTICS - ppt download Beta-lactamase - Wikipedia Lecture 6: Antimicrobials by beta - lactamase .jpg Beta-lactamases; Betalactamases; Beta Lactamases

★リンクテーブル★

リンク元	「βラクタマーゼ」
拡張検索	「beta-lactamase inhibitor」「染色体型AmpC beta-lactamase」「プラスミド型AmpC beta-lactamase」「AmpC beta-lactamase-producing bacteria」「chromosomal AmpC beta-lactamase」
関連記事	「lactamase」「beta」「be」

「βラクタマーゼ」

β-lactamase
	Action of β-lactamase and decarboxylation of the intermediate
Identifiers
EC number	3.5.2.6
CAS number	9073-60-3
Databases
IntEnz	IntEnz view
BRENDA	BRENDA entry
ExPASy	NiceZyme view
KEGG	KEGG entry
MetaCyc	metabolic pathway
PRIAM	profile
PDB structures	RCSB PDB PDBe PDBsum
Gene Ontology	AmiGO / EGO
Search
PMC	articles
PubMed	articles
NCBI	proteins

Available protein structures:
Pfam	structures
PDB	RCSB PDB; PDBe; PDBj
PDBsum	structure summary

Beta-lactamase
	Structure of a Streptomyces albus beta-lactamase
Identifiers
Symbol	β-lactamase domain
Pfam	PF00144
Pfam clan	CL0013
InterPro	IPR001466
PROSITE	PS00146
SCOP	56601
SUPERFAMILY	56601
Available protein structures:
Pfam	structures
PDB	RCSB PDB; PDBe; PDBj
PDBsum	structure summary

　　[★]

英: beta-lactamase, β-lactamase
同: β-ラクタマーゼ
関: セファロスポリナーゼ、ペニシリナーゼ

βラクタマーゼの種類と抗菌薬

ABM.150

TEM-1：(無効)アンピシリン、アモキシシリン
AmpC：(無効)[誘導発現]ペニシリン、アンピシリン、アモキシシリン、第一世代セフェム、[構成的発現]βラクタマーゼ阻害薬配合βラクタム薬を含めたほとんどのβラクタム薬。(有効)カルバペネム系抗菌薬。
ESBL：(無効)ほとんどのβラクタム薬。(有効)カルバペネム系抗菌薬、βラクタマーゼ阻害薬配合βラクタム薬。