DNA primase is an enzyme involved in the replication of DNA and is a type of RNA polymerase. Primase catalyzes the synthesis of a short RNA (or DNA in some organisms [1]) segment called a primer complementary to a ssDNA template. Primase is of key importance in DNA replication because no known replicative DNA polymerases can initiate the synthesis of a DNA strand without an initial RNA or DNA primer (for temporary DNA elongation). After this elongation the RNA piece is removed by a 5' to 3' exonuclease and refilled with DNA.
Contents
- 1 Function
- 2 Multifunctional primases
- 3 Types
- 4 External links
- 5 References
Function
In bacteria, primase binds to the DNA helicase forming a complex called the primosome. Primase is activated by DNA helicase where it then synthesizes a short RNA primer approximately 11 ±1 nucleotides long, to which new nucleotides can be added by DNA polymerase.
The RNA segments are first synthesized by primase and then elongated by DNA polymerase.[2] Then the DNA polymerase forms a protein complex with two primase subunits to form the alpha DNA Polymerase primase complex. Primase is one of the most error prone and slow polymerases.[2] Primases in organisms such as E. coli, synthesize around 2000 to 3000 primers at the rate of one primer per second.[3] Primase also acts as a halting mechanism to prevent the leading strand from outpacing the lagging strand by halting the progression of the replication fork.[4] The rate determining step in primase is when the first phosphodiester bond is formed between two molecules of RNA.[2] The crystal structure of primase in E. coli with a core containing the DnaG protein was determined in the year 2000.[3] The DnaG and primase complex is cashew shaped and contains three subdomains.[3] The central subdomain forms a toprim fold which is made of a mixture five beta sheets and six alpha helices.[3] The toprim fold is used for binding regulators and metals. The primase uses a phosphotransfer domain for the transfer coordination of metals, which makes it distinct from other polymerases.[3] The side subunits contain a NH2 and COOH terminal made of alpha helixes and beta sheets.[3] The NH2 terminal interacts with a zinc binding domain and COOH-terminal region which interacts with DnaB-ID.[3] The replication mechanisms differ between different bacteria and viruses where the primase covalently link to helicase in viruses such as the T7 bacteriophage.[4] In viruses such as herpes simplex virus (HSV-1), primase can form complexes with helicase.[5] The primase-helicase complex is used to unwind dsDNA and synthesizes the lagging strand using RNA primers[5] The majority of primers synthesized by primase are two to three nucleotides long.[5]
Multifunctional primases
In addition to priming DNA during replication, primases may have additional functions in the DNA replication process, such as polymerization of DNA or RNA, terminal transfer, translesion synthesis (TLS), non-homologous end joining (NHEJ)[6] and may also be involved in restarting stalled replication forks.[7] Primases typically synthesize primers from ribonucleotides (NTPs); however, primases with polymerase capabilities also have an affinity for deoxyribonucleotides (dNTPs).[8][9] Primases with terminal transferase functionality are capable of adding nucleotides to the 3’ end of a DNA strand independently of a template. Other enzymes involved in DNA replication, such as helicases, may also exhibit primase activity.[10]
Eukaryote and archaeal primases tend to be more similar to each other, in terms of structure and mechanism, than they are to bacterial primases.[9] The archaea-eukaryotic primase (AEP) superfamily, which most eukaryal and archaeal primases belong to, has recently been redefined as a primase-polymerase family in recognition of the many roles played by enzymes in this family.[6] This classification also emphasizes the broad origins of AEP primases; the superfamily is now recognized as transitioning between RNA and DNA functions.[11] While bacterial primases (DnaG-type) are composed of a single protein unit (a monomer) and synthesize RNA primers, AEP primases are usually composed of two different primase units (a heterodimer) and synthesize two-part primers with both RNA and DNA components.[12]
Figure 1. Select multifunctional primases across three domains of life (eukaryota, archaea, and bacteria). The ability of a primase to perform a particular activity is indicated by a check mark. Adapted from [6].
In eukaryotes
Eukaryotic primases belong to the AEP superfamily.[6]
Human PrimPol (ccdc111[8]) serves both primase and polymerase functions, like many archaeal primases; exhibits terminal transferase activity in the presence of manganese; and plays a significant role in translesion synthesis[13] and in restarting stalled replication forks. PrimPol is actively recruited to damaged sites through its interaction with RPA, an adapter protein that facilitates DNA replication and repair.[7]
PrimPol has a zinc finger domain similar to that of some viral primases, which is essential for translesion synthesis and primase activity and may regulate primer length.[13] Unlike most primases, PrimPol is uniquely capable of starting DNA chains with dNTPs.[8]
In archaea
Archaeal primases tend to belong to the AEP superfamily, although some DnaG-like (bacteria-like) primases have been found in archaeal genomes.[6]
PriS, the archaeal primase small subunit, has a role in translesion synthesis (TLS) and can bypass common DNA lesions. Most archaea lack the specialized polymerases that perform TLS in eukaryotes and bacteria.[14] PriS alone preferentially synthesizes strings of DNA; but in combination with PriL, the large subunit, RNA polymerase activity is increased.[15]
In Sulfolobus solfataricus, the primase heterodimer PriSL can act as a primase, polymerase, and terminal transferase. PriSL is thought to initiate primer synthesis with NTPs and then switch to dNTPs. The enzyme can polymerize RNA or DNA chains, with DNA products reaching as long as 7000 nucleotides (7 kb). It is suggested that this dual functionality may be a common feature of archaeal primases.[9]
Archaeal primase PolpTN2, a fusion of domains homologous to PriS and PriL, exhibits both primase and DNA polymerase activity, as well as terminal transferase function. Unlike most primases, PolpTN2 forms primers composed exclusively of dNTPs.[11]
In bacteria
Bacterial primases belong to a superfamily of DnaG-type primases, which are structurally distinct from primases in the AEP superfamily. While functionally similar, the two primase superfamilies evolved independently of each other.
Bacterial LigD, primarily involved in non-homologous end joining repair pathways, is also capable of primase, DNA and RNA polymerase, and terminal transferase activity. DNA polymerization activity can produce chains over 7000 nucleotides (7 kb) in length, while RNA polymerization produces chains up to 1 kb long.[16]
BcMCM is a bacterial multifunctional complex composed of fused helicase and primase domains. The enzyme has both primase and polymerase functions in addition to helicase function.[10]
Types
External links
- Overview article on primase structure and function (1995)
- DNA Primase at the US National Library of Medicine Medical Subject Headings (MeSH)
- Proteopedia: Helicase-binding domain of Escherichia coli primase
- Proteopedia: Complex between the DnaB helicase and the DnaG primase
References
- ^ Bocquier, Arnaud A. (2001). "Archaeal primase". Current Biology. 11 (6): 452–456. doi:10.1016/s0960-9822(01)00119-1.
- ^ a b c Griep, Mark A. (1995). "Primase Structure and Function". Indian Journal of Biochemistry & Biophysics. 32 (4): 171–8. PMID 8655184.
- ^ a b c d e f g Keck, James L. , and Daniel D. Roche, A. Simon Lynch, James M. Berger. (2000). "Structure of the RNA Polymerase Domain of E. coli Primase". Science. 282 (5462): 2482–6. doi:10.1126/science.287.5462.2482. PMID 10741967.
- ^ a b Lee, Jong-Bong , and Richard K. Hite, Samir M. Hamdan; et al. (2006). "DNA primase acts as a molecular brake in DNA replication". Nature. 439 (7076): 621–624. doi:10.1038/nature04317. PMID 16452983.
- ^ a b c Cavanaugh, Nisha A.; Robert D. Kuchta (2009). "Initiation of New DNA Strands by the Herpes Simplex Virus-1 Primase-Helicase Complex and Either Herpes DNA Polymerase or Human DNA Polymerase alpha". J. Biol. Chem. 284 (3): 1523–1532. doi:10.1074/jbc.M805476200. PMC 2615532. PMID 19028696.
- ^ a b c d Guilliam, Thomas A.; Keen, Benjamin A.; Brissett, Nigel C.; Doherty, Aidan J. (2015-08-18). "Primase-polymerases are a functionally diverse superfamily of replication and repair enzymes". Nucleic Acids Research. 43 (14): 6651–6664. doi:10.1093/nar/gkv625. ISSN 0305-1048. PMC 4538821. PMID 26109351.
- ^ a b Wan, Li; Lou, Jiangman; Xia, Yisui; Su, Bei; Liu, Ting; Cui, Jiamin; Sun, Yingying; Lou, Huiqiang; Huang, Jun (2013-12-01). "hPrimpol1/CCDC111 is a human DNA primase-polymerase required for the maintenance of genome integrity". EMBO reports. 14 (12): 1104–1112. doi:10.1038/embor.2013.159. PMC 3981091. PMID 24126761.
- ^ a b c García-Gómez, Sara; Reyes, Aurelio; Martínez-Jiménez, María I.; Chocrón, E. Sandra; Mourón, Silvana; Terrados, Gloria; Powell, Christopher; Salido, Eduardo; Méndez, Juan (2013-11-21). "PrimPol, an Archaic Primase/Polymerase Operating in Human Cells". Molecular Cell. 52 (4): 541–553. doi:10.1016/j.molcel.2013.09.025. ISSN 1097-2765. PMC 3899013. PMID 24207056.
- ^ a b c Lao-Sirieix, Si-houy; Bell, Stephen D. (2004-12-10). "The Heterodimeric Primase of the Hyperthermophilic Archaeon Sulfolobus solfataricus Possesses DNA and RNA Primase, Polymerase and 3′-terminal Nucleotidyl Transferase Activities". Journal of Molecular Biology. 344 (5): 1251–1263. doi:10.1016/j.jmb.2004.10.018.
- ^ a b Sanchez-Berrondo, June; Mesa, Pablo; Ibarra, Arkaitz; Martínez-Jiménez, Maria I.; Blanco, Luis; Méndez, Juan; Boskovic, Jasminka; Montoya, Guillermo (2012-02-01). "Molecular architecture of a multifunctional MCM complex". Nucleic Acids Research. 40 (3): 1366–1380. doi:10.1093/nar/gkr831. ISSN 0305-1048. PMC 3273815. PMID 21984415.
- ^ a b Gill, Sukhvinder; Krupovic, Mart; Desnoues, Nicole; Béguin, Pierre; Sezonov, Guennadi; Forterre, Patrick (2014-04-01). "A highly divergent archaeo-eukaryotic primase from the Thermococcus nautilus plasmid, pTN2". Nucleic Acids Research. 42 (6): 3707–3719. doi:10.1093/nar/gkt1385. ISSN 0305-1048. PMC 3973330. PMID 24445805.
- ^ Keck, J. L.; Berger, J. M. (2001-01-01). "Primus inter pares (first among equals)". Nature Structural Biology. 8 (1): 2–4. doi:10.1038/82996. ISSN 1072-8368. PMID 11135655.
- ^ a b Keen, Benjamin A.; Jozwiakowski, Stanislaw K.; Bailey, Laura J.; Bianchi, Julie; Doherty, Aidan J. (2014-05-14). "Molecular dissection of the domain architecture and catalytic activities of human PrimPol". Nucleic Acids Research. 42 (9): 5830–5845. doi:10.1093/nar/gku214. ISSN 0305-1048. PMC 4027207. PMID 24682820.
- ^ Jozwiakowski, Stanislaw K.; Gholami, Farimah Borazjani; Doherty, Aidan J. (2015-02-17). "Archaeal replicative primases can perform translesion DNA synthesis". Proceedings of the National Academy of Sciences. 112 (7): E633–E638. doi:10.1073/pnas.1412982112. ISSN 0027-8424. PMC 4343091. PMID 25646444.
- ^ Barry, Elizabeth R.; Bell, Stephen D. (2006-12-01). "DNA Replication in the Archaea". Microbiology and Molecular Biology Reviews. 70 (4): 876–887. doi:10.1128/MMBR.00029-06. ISSN 1092-2172. PMC 1698513. PMID 17158702.
- ^ Lao-Sirieix, Si-houy; Pellegrini, Luca; Bell, Stephen D. (2005-10-01). "The promiscuous primase". Trends in Genetics. 21 (10): 568–572. doi:10.1016/j.tig.2005.07.010. ISSN 0168-9525. PMID 16095750.
DNA replication (comparing Prokaryotic to Eukaryotic)
|
|
Initiation |
Prokaryotic
(initiation) |
|
|
Eukaryotic
(preparation in
G1 phase) |
- Origin recognition complex
- ORC1
- ORC2
- ORC3
- ORC4
- ORC5
- ORC6
- Minichromosome maintenance
- MCM2
- MCM3
- MCM4
- MCM5
- MCM6
- MCM7
- Autonomously replicating sequence
- Single-strand binding protein
|
|
Both |
- Origin of replication/Ori/Replicon
- Replication fork
- Lagging and leading strands
- Okazaki fragments
- Primer
|
|
|
Replication |
Prokaryotic
(elongation) |
- DNA polymerase III holoenzyme
- dnaC
- dnaE
- dnaH
- dnaN
- dnaQ
- dnaT
- dnaX
- holA
- holB
- holC
- holD
- holE
- Replisome
- DNA ligase
- DNA clamp
- Topoisomerase
- Prokaryotic DNA polymerase: DNA polymerase I
|
|
Eukaryotic
(synthesis in
S phase) |
- Replication factor C
- Flap endonuclease
- Topoisomerase
- Replication protein A
- Eukaryotic DNA polymerase:
- alpha
- delta
- epsilon
- Control of chromosome duplication
|
|
Both |
- Movement: Processivity
- DNA ligase
|
|
|
Termination |
|
Transferases: phosphorus-containing groups (EC 2.7)
|
|
2.7.1-2.7.4:
phosphotransferase/kinase
(PO4) |
2.7.1: OH acceptor |
- Hexo-
- Gluco-
- Fructo-
- Galacto-
- Phosphofructo-
- 1
- Liver
- Muscle
- Platelet
- 2
- Riboflavin
- Shikimate
- Thymidine
- NAD+
- Glycerol
- Pantothenate
- Mevalonate
- Pyruvate
- Deoxycytidine
- PFP
- Diacylglycerol
- Phosphoinositide 3
- Class I PI 3
- Class II PI 3
- Sphingosine
- Glucose-1,6-bisphosphate synthase
|
|
2.7.2: COOH acceptor |
- Phosphoglycerate
- Aspartate kinase
|
|
2.7.3: N acceptor |
|
|
2.7.4: PO4 acceptor |
- Phosphomevalonate
- Adenylate
- Nucleoside-diphosphate
- Uridylate
- Guanylate
- Thiamine-diphosphate
|
|
|
2.7.6: diphosphotransferase
(P2O7) |
- Ribose-phosphate diphosphokinase
- Thiamine diphosphokinase
|
|
2.7.7: nucleotidyltransferase
(PO4-nucleoside) |
Polymerase |
DNA polymerase |
- DNA-directed DNA polymerase
- I
- II
- III
- IV
- V
- RNA-directed DNA polymerase
- Reverse transcriptase
- Telomerase
- DNA nucleotidylexotransferase/Terminal deoxynucleotidyl transferase
|
|
RNA nucleotidyltransferase |
- RNA polymerase/DNA-directed RNA polymerase
- RNA polymerase I
- RNA polymerase II
- RNA polymerase III
- RNA polymerase IV
- Primase
- RNA-dependent RNA polymerase
- PNPase
|
|
|
Phosphorolytic
3' to 5' exoribonuclease |
|
|
Nucleotidyltransferase |
- UTP—glucose-1-phosphate uridylyltransferase
- Galactose-1-phosphate uridylyltransferase
|
|
Guanylyltransferase |
|
|
Other |
- Recombinase (Integrase)
- Transposase
|
|
|
2.7.8: miscellaneous |
Phosphatidyltransferases |
- CDP-diacylglycerol—glycerol-3-phosphate 3-phosphatidyltransferase
- CDP-diacylglycerol—serine O-phosphatidyltransferase
- CDP-diacylglycerol—inositol 3-phosphatidyltransferase
- CDP-diacylglycerol—choline O-phosphatidyltransferase
|
|
Glycosyl-1-phosphotransferase |
- N-acetylglucosamine-1-phosphate transferase
|
|
|
2.7.10-2.7.13: protein kinase
(PO4; protein acceptor) |
2.7.10: protein-tyrosine |
|
|
2.7.11: protein-serine/threonine |
- see serine/threonine-specific protein kinases
|
|
2.7.12: protein-dual-specificity |
- see serine/threonine-specific protein kinases
|
|
2.7.13: protein-histidine |
- Protein-histidine pros-kinase
- Protein-histidine tele-kinase
- Histidine kinase
|
|
Enzymes
|
|
Activity |
- Active site
- Binding site
- Catalytic triad
- Oxyanion hole
- Enzyme promiscuity
- Catalytically perfect enzyme
- Coenzyme
- Cofactor
- Enzyme catalysis
- Enzyme kinetics
- Lineweaver–Burk plot
- Michaelis–Menten kinetics
|
|
Regulation |
- Allosteric regulation
- Cooperativity
- Enzyme inhibitor
|
|
Classification |
- EC number
- Enzyme superfamily
- Enzyme family
- List of enzymes
|
|
Types |
- EC1 Oxidoreductases (list)
- EC2 Transferases (list)
- EC3 Hydrolases (list)
- EC4 Lyases (list)
- EC5 Isomerases (list)
- EC6 Ligases (list)
|