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ArsB and ArsAB transporters

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Arsenite and Antimonite Efflux Pump
Identifiers
SymbolArsA
PfamPF02374
InterProIPR027541
SMARTSM00382
TCDB3.A.4
OPM superfamily124
OPM protein3sja
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
PDBIF48
Arsenical pump membrane protein
Identifiers
SymbolArsB
PfamPF02040
InterProIPR000802
TCDB2.A.45
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary

Arsenite resistance (Ars) efflux pumps of bacteria may consist of two proteins, ArsB (TC# 2.A.45.1.1; the integral membrane constituent with twelve transmembrane spanners) and ArsA (TC# 3.A.4.1.1; the ATP-hydrolyzing, transport energizing subunit, as for the chromosomally-encoded E. coli system), or of one protein (just the ArsB integral membrane protein of the plasmid-encoded Staphylococcus system).[1][2][3] ArsA proteins have two ATP binding domains and probably arose by a tandem gene duplication event. ArsB proteins all possess twelve transmembrane spanners and may also have arisen by a tandem gene duplication event. Structurally, the Ars pumps resemble ABC-type efflux pumps, but there is no significant sequence similarity between the Ars and ABC pumps. When only ArsB is present, the system operates by a pmf-dependent mechanism, and consequently belongs in TC subclass 2.A (i.e.,TC# 2.A.45). When ArsA is also present, ATP hydrolysis drives efflux, and consequently the system belongs in TC subclass 3.A (i.e., TC# 3.A.4). ArsB therefore appears twice in the TC system (ArsB and ArsAB) but ArsA appears only once. These pumps actively expel both arsenite and antimonite.[1][2][3][4]

Homology

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Homologues of ArsB are found in Gram-negative and Gram-positive bacteria as well as cyanobacteria. Homologues are also found in archaea and eukarya. Several paralogues may sometimes be found in a single organism. Among the distant homologues found in eukaryotes are members of the DASS family (TC# 2.A.47) including the rat renal Na+:sulfate cotransporter (Q07782) and the human renal Na+:dicarboxylate cotransporter (gbU26209[permanent dead link]). ArsB proteins are therefore members of a superfamily (called the IT (ion transporter) superfamily).[5][6] However, ArsB has uniquely gained the ability to function in conjunction with ArsA in order to couple ATP hydrolysis to anion efflux. ArsAB belongs to the ArsA ATPase Superfamily.

Debatably, a unique member of the ArsB family is the rice silicon (silicate) efflux pump, Lsi2 (TC# 2.A.45.2.4). The silicon uptake systems, Lsi1 (TC# 1.A.8.12.2), and Lsi2 are expressed in roots, on the plasma membranes of cells in both the exodermis and the endodermis. In contrast to Lsi1, which is localized on the distal side, Lsi2 is localized on the proximal side of the same cells. Thus these cells have an influx transporter on one side and an efflux transporter on the other side of the cell to permit the effective transcellular transport of the nutrient.[7][8]

ArsA proteins are homologous to nitrogenase iron (NifH) proteins 2 of bacteria and to protochlorophyllide reductase iron sulfur ATP-binding proteins of cyanobacteria, algae and plants.

Mechanism

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ArsA homologues are found in bacteria, archaea and eukarya (both animals and plants), but there are far fewer of them in the databases than ArsB proteins, suggesting that many ArsB homologues function by a pmf-dependent mechanism, probably an arsenite:H+ antiport mechanism.[9]

In the E. coli ArsAB transporter, both ArsA and ArsB recognize and bind their anionic substrates. A model has been proposed in which ArsA alternates between two virtually exclusive conformations.[10] In one, (ArsA1) the A1 site is closed but the A2 site is open, but in the other (ArsA2) the opposite is true. Antimonite [Sb(III)] sequesters ArsA in the ArsA1 conformation which catalyzes ATP hydrolysis at A2 to drive ArsA between conformations that have high (nucleotide-bound ArsA) and low (nucleotide-free ArsA) affinity for antimonite. It is proposed that ArsA uses this process to sequester Sb(III) and eject it into the ArsB channel.[10][9][11]

In the case of ArsAB, at the interface of these two halves are two nucleotide-binding domains and a metalloid-binding domain.[12] Cys-113 and Cys-422 have been shown to form a high-affinity metalloid binding site. The crystal structure of ArsA shows two other bound metalloid atoms, one liganded to Cys-172 and His-453, and the other liganded to His-148 and Ser-420. There is only a single high-affinity metalloid binding site in ArsA. Cys-172 controls the affinity of this site for metalloid and hence the efficiency of metalloactivation of the ArsAB efflux pump.[12]

Transport Reaction

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The overall reaction catalyzed by ArsB (presumably by uniport) is:

Arsenite or Antimonite (in) → Arsenite or Antimonite (out).

The overall reaction catalyzed by ArsB-ArsA is:

Arsenite or Antimonite (in) + ATP ⇌ Arsenite or Antimonite (out) + ADP + Pi.

See also

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References

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  1. ^ a b Rensing C, Ghosh M, Rosen BP (October 1999). "Families of soft-metal-ion-transporting ATPases". Journal of Bacteriology. 181 (19): 5891–7. doi:10.1128/JB.181.19.5891-5897.1999. PMC 103614. PMID 10498699.
  2. ^ a b Rosen BP (1999-01-01). "The role of efflux in bacterial resistance to soft metals and metalloids". Essays in Biochemistry. 34: 1–15. doi:10.1042/bse0340001. PMID 10730185.
  3. ^ a b Xu C, Zhou T, Kuroda M, Rosen BP (January 1998). "Metalloid resistance mechanisms in prokaryotes". Journal of Biochemistry. 123 (1): 16–23. doi:10.1093/oxfordjournals.jbchem.a021904. PMID 9504403.
  4. ^ "2.A.45 The Arsenite-Antimonite (ArsB) Efflux Family". Transporter Classification Database. Retrieved 2016-03-03.
  5. ^ Prakash S, Cooper G, Singhi S, Saier MH (December 2003). "The ion transporter superfamily". Biochimica et Biophysica Acta (BBA) - Biomembranes. 1618 (1): 79–92. doi:10.1016/j.bbamem.2003.10.010. PMID 14643936.
  6. ^ Rabus R, Jack DL, Kelly DJ, Saier MH (December 1999). "TRAP transporters: an ancient family of extracytoplasmic solute-receptor-dependent secondary active transporters". Microbiology. 145 ( Pt 12) (12): 3431–45. doi:10.1099/00221287-145-12-3431. PMID 10627041.
  7. ^ Ma JF, Yamaji N, Mitani N, Tamai K, Konishi S, Fujiwara T, Katsuhara M, Yano M (July 2007). "An efflux transporter of silicon in rice". Nature. 448 (7150): 209–12. Bibcode:2007Natur.448..209M. doi:10.1038/nature05964. PMID 17625566. S2CID 4406965.
  8. ^ Ma JF, Yamaji N, Tamai K, Mitani N (November 2007). "Genotypic difference in silicon uptake and expression of silicon transporter genes in rice". Plant Physiology. 145 (3): 919–24. doi:10.1104/pp.107.107599. PMC 2048782. PMID 17905867.
  9. ^ a b Meng YL, Liu Z, Rosen BP (April 2004). "As(III) and Sb(III) uptake by GlpF and efflux by ArsB in Escherichia coli". The Journal of Biological Chemistry. 279 (18): 18334–41. doi:10.1074/jbc.M400037200. PMID 14970228.
  10. ^ a b Walmsley AR, Zhou T, Borges-Walmsley MI, Rosen BP (March 2001). "A kinetic model for the action of a resistance efflux pump". The Journal of Biological Chemistry. 276 (9): 6378–91. doi:10.1074/jbc.M008105200. PMID 11096086.
  11. ^ Yang J, Rawat S, Stemmler TL, Rosen BP (May 2010). "Arsenic binding and transfer by the ArsD As(III) metallochaperone". Biochemistry. 49 (17): 3658–66. doi:10.1021/bi100026a. PMC 2920133. PMID 20361763.
  12. ^ a b Ruan X, Bhattacharjee H, Rosen BP (January 2008). "Characterization of the metalloactivation domain of an arsenite/antimonite resistance pump". Molecular Microbiology. 67 (2): 392–402. doi:10.1111/j.1365-2958.2007.06049.x. PMID 18067540. S2CID 8472652.

Further reading

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