膜輸送タンパク質

関: membrane transporter、permease

WordNet

move something or somebody around; usually over long distances
an exchange of molecules (and their kinetic energy and momentum) across the boundary between adjacent layers of a fluid or across cell membranes
move while supporting, either in a vehicle or in ones hands or on ones body; "You must carry your camping gear"; "carry the suitcases to the car"; "This train is carrying nuclear waste"; "These pipes carry waste water into the river" (同)carry
transport commercially (同)send, ship
any of a large group of nitrogenous organic compounds that are essential constituents of living cells; consist of polymers of amino acids; essential in the diet of animals for growth and for repair of tissues; can be obtained from meat and eggs and milk and legumes; "a diet high in protein"
a thin pliable sheet of material
a pliable sheet of tissue that covers or lines or connects the organs or cells of animals or plants (同)tissue layer

PrepTutorEJDIC

(ある場所からある場所へ)…‘を'『輸送する』,運搬する《+名+from+名+to+名》 / 《文》《受動態で》(…で)…‘を'夢中にする,有頂天にする《+名+with+名》 / 〈罪人〉‘を'流刑にする / 〈U〉輸送,運送,輸送(交通)機関(transportation) / 〈C〉(軍隊や軍需品を運ぶ)輸送船,輸送機
蛋白(たんばく)質
(生物の)膜,皮膜

Wikipedia preview

出典(authority):フリー百科事典『ウィキペディア（Wikipedia）』「2019/10/25 19:57:20」(JST)

wiki en

[Wiki en表示]

A membrane transport protein (or simply transporter) is a membrane protein^[1] involved in the movement of ions, small molecules, and macromolecules, such as another protein, across a biological membrane. Transport proteins are integral transmembrane protein; that is they exist permanently within and span the membrane across which they transport substances. The proteins may assist in the movement of substances by facilitated diffusion or active transport. The two main types of proteins involved in such transport are broadly categorized as either channels or carriers. The solute carriers and atypical SLCs^[2] are secondary active or facilitative transporters in humans.^[3]^[4]

1 Difference between channels and carriers
2 Active diffusion
3 Facilitated diffusion
4 Reverse diffusion
5 Types
- 5.1 1: Channels/pores
- 5.2 2: Electrochemical potential-driven transporters
- 5.3 3: Primary active transporters
- 5.4 4: Group translocators
- 5.5 5: Electron carriers
6 Examples
7 Pathology
8 See also
9 References
10 External links

Difference between channels and carriers

A carrier is not open simultaneously to both the extracellular and intracellular environments. Either its inner gate is open, or outer gate is open. In contrast, a channel can be open to both environments at the same time, allowing the molecules to diffuse without interruption. Carriers have binding sites, but pores and channels do not.^[5]^[6]^[7] When a channel is opened, millions of ions can pass through the membrane per second, but only 100 to 1000 molecules typically pass through a carrier molecule in the same time.^[8] Each carrier protein is designed to recognize only one substance or one group of very similar substances. Research has correlated defects in specific carrier proteins with specific diseases.^[9]

Active diffusion

The action of the sodium-potassium pump is an example of primary active transport. The two carrier proteins on the left are using ATP to move sodium out of the cell against the concentration gradient. The proteins on the right are using secondary active transport to move potassium into the cell.

Active transport is the movement of a substance across a membrane against its concentration gradient. This is usually to accumulate high concentrations of molecules that a cell needs, such as glucose or amino acids. If the process uses chemical energy, such as adenosine triphosphate (ATP), it is called primary active transport. Secondary active transport involves the use of an electrochemical gradient, and does not use energy produced in the cell.^[10] Unlike channel proteins which only transport substances through membranes passively, carrier proteins can transport ions and molecules either passively through facilitated diffusion, or via secondary active transport.^[11] A carrier protein is required to move particles from areas of low concentration to areas of high concentration. These carrier proteins have receptors that bind to a specific molecule (substrate) needing transport. The molecule or ion to be transported (the substrate) must first bind at a binding site at the carrier molecule, with a certain binding affinity. Following binding, and while the binding site is facing the same way, the carrier will capture or occlude (take in and retain) the substrate within its molecular structure and cause an internal translocation so that the opening in the protein now faces the other side of the plasma membrane.^[12] The carrier protein substrate is released at that site, according to its binding affinity there.

Facilitated diffusion

Facilitated diffusion in the cell membrane, showing ion channels (left) and carrier proteins (three on the right).

Facilitated diffusion is the passage of molecules or ions across a biological membrane through specific transport proteins and requires no energy input. Facilitated diffusion is used especially in the case of large polar molecules and charged ions; once such ions are dissolved in water they cannot diffuse freely across cell membranes due to the hydrophobic nature of the fatty acid tails of the phospholipids that make up the bilayers. The type of carrier proteins used in facilitated diffusion is slightly different from those used in active transport. They are still transmembrane carrier proteins, but these are gated transmembrane channels, meaning they do not internally translocate, nor require ATP to function. The substrate is taken in one side of the gated carrier, and without using ATP the substrate is released into the cell. They may be used as potential biomarkers.

Reverse diffusion

Reverse transport, or transporter reversal, is a phenomenon in which the substrates of a membrane transport protein are moved in the opposite direction to that of their typical movement by the transporter.^[13]^[14]^[15]^[16]^[17] Transporter reversal typically occurs when a membrane transport protein is phosphorylated by a particular protein kinase, which is an enzyme that adds a phosphate group to proteins.^[13]^[14]

Types

(Grouped by Transporter Classification database categories)

1: Channels/pores

α-helical protein channels such as voltage-gated ion channel (VIC), ligand-gated ion channels(LGICs)
β-barrel porins such as aquaporin
channel-forming toxins, including colicins, diphtheria toxin, and others
Nonribosomally synthesized channels such as gramicidin
Holins; which function in export of enzymes that digest bacterial cell walls in an early step of cell lysis.

Facilitated diffusion occurs in and out of the cell membrane via channels/pores and carriers/porters.

Note:

Channels:

Channels are either in open state or closed state. When a channel is opened with a slight conformational switch, it is open to both environment simultaneously (extracellular and intracellular)

This picture represents symport. The yellow triangle shows the concentration gradient for the yellow circles while the green triangle shows the concentration gradient for the green circles and the purple rods are the transport protein bundle. The green circles are moving against their concentration gradient through a transport protein which requires energy while the yellow circles move down their concentration gradient which releases energy. The yellow circles produce more energy through chemiosmosis than what is required to move the green circles so the movement is coupled and some energy is cancelled out. One example is the lactose permease which allows protons to go down its concentration gradient into the cell while also pumping lactose into the cell.
Pores:

Pores are continuously open to these both environment, because they do not undergo conformational changes. They are always open and active.

2: Electrochemical potential-driven transporters

Also named carrier proteins or secondary carriers.

2.A: Porters (uniporters, symporters, antiporters), SLCs.^[4]
- The picture represents uniport. The yellow triangle shows the concentration gradient for the yellow circles and the purple rods are the transport protein bundle. Since they move down their concentration gradient through a transport protein, they can release energy as a result of chemiosmosis. One example is GLUT1 which moves glucose down its concentration gradient into the cell.
  Excitatory amino acid transporters (EAATs)
  - EAAT1
  - EAAT2
  - EAAT3
  - EAAT4
  - EAAT5
- Glucose transporter
- Monoamine transporters, including:
  - Dopamine transporter (DAT)
  - Norepinephrine transporter (NET)
  - Serotonin transporter (SERT)
  - Vesicular monoamine transporters (VMAT)
- Adenine nucleotide translocator (ANT)
2.B: Nonribosomally synthesized porters, such as:
- The Nigericin family
- The Ionomycin family
2.C: Ion-gradient-driven energizers

3: Primary active transporters

3.A: P-P-bond-hydrolysis-driven transporters :
- ATP-binding cassette transporter (ABC transporter), such as MDR, CFTR
- V-type ATPase ; ( "V" related to vacuolar ).
- P-type ATPase ; ( "P" related to phosphorylation), such as :
  - Na⁺/K⁺-ATPase
  - Plasma membrane Ca²⁺ ATPase
  - Proton pump
- This picture represents antiport. The yellow triangle shows the concentration gradient for the yellow circles while the blue triangle shows the concentration gradient for the blue circles and the purple rods are the transport protein bundle. The blue circles are moving against their concentration gradient through a transport protein which requires energy while the yellow circles move down their concentration gradient which releases energy. The yellow circles produce more energy through chemiosmosis than what is required to move the blue circles so the movement is coupled and some energy is cancelled out. One example is the sodium-proton exchanger which allows protons to go down their concentration gradient into the cell while pumping sodium out of the cell.
  F-type ATPase; ("F" related to factor), including: mitochondrial ATP synthase, chloroplast ATP synthase1
3.B: Decarboxylation-driven transporters
3.C: Methyltransfer-driven transporters
3.D: Oxidoreduction-driven transporters
3.E: Light absorption-driven transporters, such as rhodopsin

4: Group translocators

The group translocators provide a special mechanism for the phosphorylation of sugars as they are transported into bacteria (PEP group translocation)

5: Electron carriers

The transmembrane electron transfer carriers in the membrane include two-electron carriers, such as the disulfide bond oxidoreductases (DsbB and DsbD in E. coli) as well as one-electron carriers such as NADPH oxidase. Often these redox proteins are not considered transport proteins.

Examples

Each carrier protein, even within the same cell membrane, is specific to one type or family of molecules. For example, GLUT1 is a named carrier protein found in almost all animal cell membranes that transports glucose across the bilayer. Other specific carrier proteins also help the body function in important ways. Cytochromes operate in the electron transport chain as carrier proteins for electrons.^[10]

Pathology

A number of inherited diseases involve defects in carrier proteins in a particular substance or group of cells. Cysteinuria (cysteine in the urine and the bladder) is such a disease involving defective cysteine carrier proteins in the kidney cell membranes. This transport system normally removes cysteine from the fluid destined to become urine and returns this essential amino acid to the blood. When this carrier malfunctions, large quantities of cysteine remain in the urine, where it is relatively insoluble and tends to precipitate. This is one cause of urinary stones.^[18] Some vitamin carrier proteins have been shown to be overexpressed in patients with malignant disease. For example, levels of riboflavin carrier protein (RCP) have been shown to be significantly elevated in people with breast cancer.^[19]

References

^ Membrane+transport+proteins at the US National Library of Medicine Medical Subject Headings (MeSH)
^ Perland, Emelie; Bagchi, Sonchita; Klaesson, Axel; Fredriksson, Robert (2017-09-01). "Characteristics of 29 novel atypical solute carriers of major facilitator superfamily type: evolutionary conservation, predicted structure and neuronal co-expression". Open Biology. 7 (9): 170142. doi:10.1098/rsob.170142. ISSN 2046-2441. PMC 5627054. PMID 28878041.
^ Hediger, Matthias A.; Romero, Michael F.; Peng, Ji-Bin; Rolfs, Andreas; Takanaga, Hitomi; Bruford, Elspeth A. (February 2004). "The ABCs of solute carriers: physiological, pathological and therapeutic implications of human membrane transport proteinsIntroduction". Pflügers Archiv: European Journal of Physiology. 447 (5): 465–468. doi:10.1007/s00424-003-1192-y. ISSN 0031-6768. PMID 14624363.
^ ^a ^b Perland, Emelie; Fredriksson, Robert (March 2017). "Classification Systems of Secondary Active Transporters". Trends in Pharmacological Sciences. 38 (3): 305–315. doi:10.1016/j.tips.2016.11.008. ISSN 1873-3735. PMID 27939446.
^ Sadava, David, et al. Life, the Science of Biology, 9th Edition. Macmillan Publishers, 2009. ISBN 1-4292-1962-9. p. 119.
^ Cooper, Geoffrey (2009). The Cell: A Molecular Approach. Washington, DC: ASM Press. p. 62. ISBN 9780878933006.
^ Thompson, Liz A. Passing the North Carolina End of Course Test for Biology. American Book Company, Inc. 2007. ISBN 1-59807-139-4. p. 97.
^ Assmann, Sarah (2015). "Solute Transport". In Taiz, Lincoln; Zeiger, Edward (eds.). Plant Physiology and Development. Sinauer. p. 151.
^ Sadava, David, Et al. Life, the Science of Biology, 9th Edition. Macmillan Publishers, 2009. ISBN 1-4292-1962-9. p. 119.
^ ^a ^b Ashley, Ruth. Hann, Gary. Han, Seong S. Cell Biology. New Age International Publishers. ISBN 8122413978. p. 113.
^ Taiz, Lincoln. Zeigler, Eduardo. Plant Physiology and Development. Sinauer Associates, 2015. ISBN 978-1-60535-255-8. pp. 151.
^ Kent, Michael. Advanced Biology. Oxford University Press US, 2000. ISBN 0-19-914195-9. pp. 157–158.
^ ^a ^b Bermingham DP, Blakely RD (October 2016). "Kinase-dependent Regulation of Monoamine Neurotransmitter Transporters". Pharmacol. Rev. 68 (4): 888–953. doi:10.1124/pr.115.012260. PMC 5050440. PMID 27591044.
^ ^a ^b Miller GM (January 2011). "The emerging role of trace amine-associated receptor 1 in the functional regulation of monoamine transporters and dopaminergic activity". Journal of Neurochemistry. 116 (2): 164–176. doi:10.1111/j.1471-4159.2010.07109.x. PMC 3005101. PMID 21073468.
^ Scholze P, Nørregaard L, Singer EA, Freissmuth M, Gether U, Sitte HH (2002). "The role of zinc ions in reverse transport mediated by monoamine transporters". The Journal of Biological Chemistry. 277 (24): 21505–13. doi:10.1074/jbc.M112265200. PMID 11940571.
^ Robertson SD, Matthies HJ, Galli A (2009). "A closer look at amphetamine-induced reverse transport and trafficking of the dopamine and norepinephrine transporters". Molecular Neurobiology. 39 (2): 73–80. doi:10.1007/s12035-009-8053-4. PMC 2729543. PMID 19199083.
^ Kasatkina LA, Borisova TA (November 2013). "Glutamate release from platelets: exocytosis versus glutamate transporter reversal". The International Journal of Biochemistry & Cell Biology. 45 (11): 2585–2595. doi:10.1016/j.biocel.2013.08.004. PMID 23994539.
^ Sherwood, Lauralee. 7th Edition. Human Physiology. From Cells to Systems. Cengage Learning, 2008. p. 67
^ Rao, PN, Levine, E et al. Elevation of Serum Riboflavin Carrier Protein in Breast Cancer. Cancer Epidemiol Biomarkers Prev. Volume 8 No 11. pp. 985–990

External links

"Transport protein" at Dorland's Medical Dictionary

DDI Regulatory Guidance Request a guide to drug-drug interaction regulatory recommendations.

UpToDate Contents

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1. 腹膜透析における溶質クリアランスおよび限外濾過の機序 mechanisms of solute clearance and ultrafiltration in peritoneal dialysis
2. 維持腹膜透析における迅速なトランスポーター rapid transporters on maintenance peritoneal dialysis
3. 持続的腹膜透析の非感染性合併症 noninfectious complications of continuous peritoneal dialysis
4. 持続的腹膜透析における溶質クリアランスおよび限外濾過の問題 problems with solute clearance and ultrafiltration in continuous peritoneal dialysis
5. 小児における慢性腹膜透析 chronic peritoneal dialysis in children

English Journal

The Function of Arf-like Proteins ARL2 and ARL3 in Photoreceptors.

Hanke-Gogokhia C1,2, Zhang H3, Frederick JM4, Baehr W5,6,7.
Advances in experimental medicine and biology.Adv Exp Med Biol.2016;854:655-61. doi: 10.1007/978-3-319-17121-0_87.
Arf-like proteins (ARLs) are ubiquitously expressed small G proteins of the RAS superfamily. In photoreceptors, ARL2 and ARL3 participate in the trafficking of lipidated membrane-associated proteins and colocalize in the inner segment with UNC119A and PDEδ. UNC119A and PDEδ are acyl- and prenyl-bi
PMID 26427472

Eps15 homology domain containing protein of Plasmodium falciparum (PfEHD) associates with endocytosis and vesicular trafficking towards neutral lipid storage site.

Thakur V1, Asad M2, Jain S1, Hossain ME1, Gupta A1, Kaur I1, Rathore S3, Ali S4, Khan NJ5, Mohmmed A6.
Biochimica et biophysica acta.Biochim Biophys Acta.2015 Nov;1853(11 Pt A):2856-69. doi: 10.1016/j.bbamcr.2015.08.007. Epub 2015 Aug 15.
The human malaria parasite, Plasmodium falciparum, takes up numerous host cytosolic components and exogenous nutrients through endocytosis during the intra-erythrocytic stages. Eps15 homology domain-containing proteins (EHDs) are conserved NTPases, which are implicated in membrane remodeling and reg
PMID 26284889

From Homodimer to Heterodimer and Back: Elucidating the TonB Energy Transduction Cycle.

Gresock MG1, Kastead KA1, Postle K2.
Journal of bacteriology.J Bacteriol.2015 Nov 1;197(21):3433-45. doi: 10.1128/JB.00484-15. Epub 2015 Aug 17.
The TonB system actively transports large, scarce, and important nutrients through outer membrane (OM) transporters of Gram-negative bacteria using the proton gradient of the cytoplasmic membrane (CM). In Escherichia coli, the CM proteins ExbB and ExbD harness and transfer proton motive force energy
PMID 26283773

Japanese Journal

Identification and Characterization of Plasma Membrane Intrinsic Protein (PIP) Aquaporin Genes in Petals of Opening Carnation Flowers

The Horticulture Journal advpub(0), 2017
NAID 130005152905

ゴルジ体によるタンパク質輸送機構

生物物理 56(4), 201-206, 2016
NAID 130005165634

Vacuolar amino acid transporters upregulated by exogenous proline and involved in cellular localization of proline in Saccharomyces cerevisiae

The Journal of General and Applied Microbiology 62(3), 132-139, 2016
NAID 130005164753

「permease」

　　[★]

n.

パーミアーゼ、透過酵素、担体タンパク質

関: carrier protein、membrane transport protein、membrane transporter

「membrane transporter」

　　[★]

膜輸送体、膜トランスポーター

関: membrane transport protein、permease

「膜輸送タンパク質」

　　[★]

英: membrane transport protein

「glycine plasma membrane transport protein」

　　[★]

細胞膜グリシントランスポーター、細胞膜グリシン輸送体、グリシントランスポーター、グリシン輸送体

関: glycine transporter、glycine transporter 1、glycine transporter 2

「GABA plasma membrane transport protein」

　　[★]

細胞膜GABAトランスポーター、細胞膜GABA輸送体、GABAトランスポーター、GABA輸送体

関: GABA transporter、GABA transporter 1、GABA transporter 2

「glutamate plasma membrane transport protein」

　　[★]

細胞膜グルタミン酸トランスポーター、細胞膜グルタミン酸輸送体、興奮性アミノ酸トランスポーター

関: excitatory amino acid transporter

「serotonin plasma membrane transport protein」

　　[★]

セロトニントランスポーター、セロトニン輸送体、セロトニン細胞膜輸送タンパク質

関: serotonin transporter、SERT

「transport」

　　[★]

n.

輸送、運搬

v.

輸送する、運搬する、運ぶ

関: bring、carriage、carry、convey、delivery、ship、traffic、trafficking、transportation

「transport protein」

　　[★]

輸送タンパク質、輸送体、トランスポーター

関: binding protein、carrier protein、translocator、transporter、transporter protein

「membrane」

　　[★]

n.

膜、メンブラン

「membrane transport」

　　[★]

関: See also spe cific mechanism

[1] Membrane+transport+proteins at the US National Library of Medicine Medical Subject Headings (MeSH)

[2] Perland, Emelie; Bagchi, Sonchita; Klaesson, Axel; Fredriksson, Robert (2017-09-01). "Characteristics of 29 novel atypical solute carriers of major facilitator superfamily type: evolutionary conservation, predicted structure and neuronal co-expression". Open Biology. 7 (9): 170142. doi:10.1098/rsob.170142. ISSN 2046-2441. PMC 5627054. PMID 28878041.

[3] Hediger, Matthias A.; Romero, Michael F.; Peng, Ji-Bin; Rolfs, Andreas; Takanaga, Hitomi; Bruford, Elspeth A. (February 2004). "The ABCs of solute carriers: physiological, pathological and therapeutic implications of human membrane transport proteinsIntroduction". Pflügers Archiv: European Journal of Physiology. 447 (5): 465–468. doi:10.1007/s00424-003-1192-y. ISSN 0031-6768. PMID 14624363.

[Perland_305–315-4] Perland, Emelie; Fredriksson, Robert (March 2017). "Classification Systems of Secondary Active Transporters". Trends in Pharmacological Sciences. 38 (3): 305–315. doi:10.1016/j.tips.2016.11.008. ISSN 1873-3735. PMID 27939446.

[5] Sadava, David, et al. Life, the Science of Biology, 9th Edition. Macmillan Publishers, 2009. ISBN 1-4292-1962-9. p. 119.

[6] Cooper, Geoffrey (2009). The Cell: A Molecular Approach. Washington, DC: ASM Press. p. 62. ISBN 9780878933006.

[7] Thompson, Liz A. Passing the North Carolina End of Course Test for Biology. American Book Company, Inc. 2007. ISBN 1-59807-139-4. p. 97.

[8] Assmann, Sarah (2015). "Solute Transport". In Taiz, Lincoln; Zeiger, Edward (eds.). Plant Physiology and Development. Sinauer. p. 151.

[9] Sadava, David, Et al. Life, the Science of Biology, 9th Edition. Macmillan Publishers, 2009. ISBN 1-4292-1962-9. p. 119.

[Ashley,_Ruth_p._113-10] Ashley, Ruth. Hann, Gary. Han, Seong S. Cell Biology. New Age International Publishers. ISBN 8122413978. p. 113.

[11] Taiz, Lincoln. Zeigler, Eduardo. Plant Physiology and Development. Sinauer Associates, 2015. ISBN 978-1-60535-255-8. pp. 151.

[12] Kent, Michael. Advanced Biology. Oxford University Press US, 2000. ISBN 0-19-914195-9. pp. 157–158.

[Kinase-dependent_transporter_regulation_review-13] Bermingham DP, Blakely RD (October 2016). "Kinase-dependent Regulation of Monoamine Neurotransmitter Transporters". Pharmacol. Rev. 68 (4): 888–953. doi:10.1124/pr.115.012260. PMC 5050440. PMID 27591044.

[Miller-14] Miller GM (January 2011). "The emerging role of trace amine-associated receptor 1 in the functional regulation of monoamine transporters and dopaminergic activity". Journal of Neurochemistry. 116 (2): 164–176. doi:10.1111/j.1471-4159.2010.07109.x. PMC 3005101. PMID 21073468.

[pmid11940571-15] Scholze P, Nørregaard L, Singer EA, Freissmuth M, Gether U, Sitte HH (2002). "The role of zinc ions in reverse transport mediated by monoamine transporters". The Journal of Biological Chemistry. 277 (24): 21505–13. doi:10.1074/jbc.M112265200. PMID 11940571.

[pmid19199083-16] Robertson SD, Matthies HJ, Galli A (2009). "A closer look at amphetamine-induced reverse transport and trafficking of the dopamine and norepinephrine transporters". Molecular Neurobiology. 39 (2): 73–80. doi:10.1007/s12035-009-8053-4. PMC 2729543. PMID 19199083.

[pmid23994539-17] Kasatkina LA, Borisova TA (November 2013). "Glutamate release from platelets: exocytosis versus glutamate transporter reversal". The International Journal of Biochemistry & Cell Biology. 45 (11): 2585–2595. doi:10.1016/j.biocel.2013.08.004. PMID 23994539.

[18] Sherwood, Lauralee. 7th Edition. Human Physiology. From Cells to Systems. Cengage Learning, 2008. p. 67

[19] Rao, PN, Levine, E et al. Elevation of Serum Riboflavin Carrier Protein in Breast Cancer. Cancer Epidemiol Biomarkers Prev. Volume 8 No 11. pp. 985–990

v t e Proteins: carrier proteins
Fatty acid	FABP1 FABP2 FABP3 FABP4 FABP5 FABP6 FABP7
Hormone	peptide hormone: Follistatin Growth hormone binding protein Insulin-like growth factor binding protein IGFBP1 IGFBP2 IGFBP3 IGFBP4 IGFBP5 IGFBP6 IGFBP7 Neurophysins Neurophysin I II steroid hormone: Sex hormone binding globulin/Androgen binding protein Transcortin Thyroxine-binding globulin Transthyretin
Metal/element	calcium Calcium-binding protein Calmodulin-binding proteins copper Ceruloplasmin iron Iron-binding proteins Transferrin receptor
Vitamin	Retinol binding protein 1 2 3 4 Transcobalamin
Pigment	Plant Light-Harvesting Complex Orange Carotenoid Protein Phycobiliprotein Photosynthetic Reaction Centers Phytochrome Rhodopsin
Other	Acyl carrier protein Adaptor protein Cholesterylester transfer protein F-box protein GTP-binding protein Latent TGF-beta binding protein Major urinary proteins Membrane transport protein Odorant binding protein

v t e Membrane transport protein: neurotransmitter transporters (TC 2.A.1.2)
Vesicular	Vesicular monoamine VMAT1 VMAT2 Vesicular acetylcholine Vesicular glutamate Vesicular GABA
Other	Monoamine DAT NET SERT PMAT Excitatory amino-acid transporter GABA transporter

v t e Membrane proteins, carrier proteins: membrane transport proteins ABC-transporter (TC 3A1)
A	A1 A2 A3 A4 A7 A8 A12 A13
B	B1 B2-3 (B2 B3) B4 B5 B6 B7 B9 B11
C	C1 C2 C3 C4 C5 C6 C7 C8-9 (C8, C9) C10 C11 C13
D	D1 D2 D3 D4
E	E1
F	F1 F2
G	G1 G2 G4 Sterolin (G5, G8)
see also ABC transporter disorders

リンク元	「permease」「membrane transporter」「膜輸送タンパク質」
拡張検索	「glycine plasma membrane transport protein」「GABA plasma membrane transport protein」「glutamate plasma membrane transport protein」「serotonin plasma membrane transport protein」
関連記事	「transport」「transport protein」「membrane」「membrane transport」

匿名

検索

案内

membrane transport protein