| 2.A.6 The Resistance-Nodulation-Cell Division (RND) Superfamily
Characterized members of the RND superfamily all probably catalyze substrate efflux via an H+ antiport mechanism. These proteins are found ubiquitously in bacteria, archaea and eukaryotes. They fall into eight recognized phylogenetic families, three primary phylogenetic families that are restricted largely to Gram-negative bacteria (families 1-3, see below), the SecDF family (family 4) that is represented in both Gram-negative and Gram-positive bacteria as well as archaea, the HAE2 family (family 5) that is restricted to Gram-positive bacteria, one very diverse eukaryotic family (family 6), one archaeal plus spirochete family (family 7) (Tseng et al., 1999), and a recently identified family that includes a probable pigment exporter in Gram-negative bacteria (TC #2.A.6.8.1; Goel et al., 2002). Clustering pattern in the Gram-negative bacterial families of the RND superfamily correlates with substrate specificity with family 1 catalyzing export of heavy metals, family 2 catalyzing export of multiple drugs, cluster 3 probably catalyzing export of lipooligosaccharides concerned with plant nodulation for the purpose of symbiotic nitrogen fixation and cluster 8 catalyzing pigment export. Within family 2, MdtABC, consisting of an MFP (TC #8.A.1) and two RND family proteins (MdtB [TC #2.A.6.2.12] and MdtC [TC #2.A.6.2.14]) may form a complex exhibiting broader specificity than either MdtAB or MdtAC (Baranova and Nikaido, 2002; Nagakubo et al., 2002). The ActII3 protein, one of the two partially characterized member of family 5, has been implicated in drug resistance. The MmpL7 protein, also of this family, catalyzes export of an outer membrane lipid, phthiocerol dimycocerosate (PDIM) in M. tuberculosis. The SecDF proteins (family 5) function as nonessential constituents of the IISP protein secretory system (TC #3.A.5). They seem to allow coupling of substrate protein translocation to the proton motive force by facilitating deinsertion of the SecA component of the IISP system, thus rendering this system partially ATP-independent. Some or all of the eukaryotic proteins (family 6) may function in cholesterol/lipid/steroid hormone transport, reception, regulation or catalysis. One such protein complex includes the RND family disease protein, Niemann-Pick C1, which may function in the export of cholesterol and lipids from lysosomes in conjunction with a soluble lysosomal protein with cholesterol binding properties, NPC2 (TC #2.A.6.6.1; Sleat et al., 2004). Non-transporter homologues possess the sterol recognition domain and do not exhibit typical RND family internal duplication (see below). The functions of the archaeal and spirochete proteins of family 7 have not been investigated.
Most of the RND superfamily transport systems consist of large polypeptide chains (700-1300 amino acyl residues long). These proteins possess a single transmembrane spanner (TMS) at their N-termini followed by a large extracytoplasmic domain, then six additional TMSs, a second large extracytoplasmic domain, and five final C-terminal TMSs. In the case of one system (NolGHI) the system may consist of three distinct polypeptide chains, and most of the SecDF homologues consist of two polypeptide chains. Most others probably consist of a single polypeptide chain. The first halves of RND family proteins are homologous to the second halves, and the proteins therefore probably arose as a result of an intragenic tandem duplication event that occurred in the primordial system prior to divergence of the family members. One protein homologue from Methanococcus jannaschii is of half size and has no internal duplication. It can be postulated to function as a homo- or heterodimer in the membrane. The same is true of the eukaryotic RND family homologues that do not appear to function in transport. Some of the eukaryotic proteins have hydrophilic C-terminal domains.
The crystal structure of the RND drug exporter of E. coli, AcrB (TC #2.A.6.2.2), has been solved at 3.5 Å resolution (Murakami et al., 2002). Three AcrB protomers are organized as a homotrimer in the shape of a jellyfish. Each protomer consists of a 50 Å thick transmembrane domain and a 70 Å headpiece, protruding from the external membrane surface. The top of the headpiece opens like a funnel, and this may be a site of interaction with the MFP, AcrA (TC #8.A.1.6.1) and the OMF, TolC (TC #1.B.17.1.1). A pore formed by the three α-helices connects the funnel with a central cavity at the bottom of the headpiece. The 12 TMSs in the membrane domain are visible. Substrates are presumably successively transported through the channels of AcrB and TolC (Murakami et al., 2002). An MFP such as MexF of P. aeruginosa facilitates proper assembly of the RND permease as well as stabilization of the OMF such as OprN (Maseda et al., 2002).
The large external cavity is of 5000 cubic angstroms. Several different hydrophobic and amphipathic ligands can bind in different positions within the cavity simultaneously. Binding involves hydrophobic forces, aromatic (π) stacking and van der Waals interactions (Yu et al., 2003).
The RND members of families 1-3 function in conjunction with a 'membrane fusion protein' (MFP; TC #8.A.1) and an 'outer membrane factor' (OMF; TC #1.B.17) to effect efflux across both membranes of the Gram-negative bacterial cell envelope in a single energy-coupled step. They may also pump hydrophobic substances from the cytoplasmic membrane, and toxic hydrophilic substances (i.e., heavy metals) from the periplasm to the external medium. The large periplasmic domains of RND pumps are involved in substrate recognition and form a cavity that can accommodate multiple drugs simultaneously (Mao et al., 2002). The precise biochemical functions of most RND family members (families 4-7) are not known.
Recently a novel member of the RND superfamily, very distantly related to other established members of the superfamily, was shown to be a pigment (xanthomonadin) exporter in Xanthomonas oryzae (Goel et al., 2002). This protein (TC #2.A.6.8.1) has close homologues in various species of Xanthomonas as well as Xylella, Ralstonia and E. coli (AAG58596). These proteins comprise the eighth recognized family in the RND superfamily.
The generalized transport reaction catalyzed by functionally characterized RND proteins is:
Substrates (in) + nH+ (out) → Substrates (out) + nH+ (in).
Substrates: (a) heavy metals, (e.g., Co2+, Zn2+, Cd2+, Ni2+, Cu+ and Ag+; family 1); (b) multiple drugs (e.g., tetracycline, chloramphenicol, fluoroquinolones, β-lactams, etc.; family 2); (c) lipooligosaccharides (nodulation factors; family 3); lipids and possibly antibiotic drugs (e.g., actinorhodin; family 5), and possibly sterols in eukaryotes (family 6).
|
| Macromolecular structures of proteins in this family: 2.A.6.2.2 - 1IWG
2.A.6.2.2 - 1OY8
2.A.6.2.2 - 1OY9
2.A.6.2.2 - 1OYD
2.A.6.2.2 - 1OYE
2.A.6.2.2 - 1OY6
|
| References: |
Altmann, S.W., H.R. Davis, Jr., L.-J. Zhu, X. Yao, L.M. Hoos, G. Tetzloff, S.P.N. Iyer, M. Maguire, A. Golovko, M. Zeng, L. Wang, N. Murgolo, and M.P. Graziano. (2004). Niemann-Pick C1 like 1 protein is critical for intestinal cholesterol absorption. Science 303: 1201-1204.
|
Baranova, N. and H. Nikaido. (2002). The BaeSR two-component regulatory system activates transcription of the yegMNOB (mdtABCD) transporter gene cluster in Escherichia coli and increases its resistance to novobiocin and deoxycholate. J. Bacteriol. 184: 4168-4176.
|
Bolhuis, A., C.P. Broekhuizen, A. Sorokin, M.L. van Roosmalen, G. Venema, S. Bron, W.J. Quax, and J.M. van Dijl. (1998). SecDF of Bacillus subtilis, a molecular siamese twin required for the efficient secretion of proteins. J. Biol. Chem. 273: 21217-21224.
|
Carstea, E.D., J.A. Morris, K.G. Coleman, S.K. Loftus, D. Zhang, C. Cummings, J. Gu, M.A. Rosenfeld, W.J. Pavan, D.B. Krizman et al. (1997). Niemann-Pick C1 disease gene: homology to mediators of cholesterol homeostasis. Science 277: 228-231.
|
Chuanchuen, R., C.T. Narasaki, and H.P. Schweizer. (2002). The MexJK efflux pump of Pseudomonas aeruginosa requires OprM for antibiotic efflux but not for efflux of triclosan. J. Bacteriol. 184: 5036-5044.
|
Cox, J.S., B. Chen, M. McNeil, and W.R. Jacobs Jr. (1999). Complex lipid determines tissue-specific replication of Mycobacterium tuberculosis in mice. Nature 402: 79-83.
|
Dinh, D., I.T. Paulsen, and M.H. Saier, Jr. (1994). A family of extracytoplasmic proteins that allow transport of large molecules across the outer membranes of Gram-negative bacteria. J. Bacteriol. 176: 3825-3831.
|
Domenech, P., M.B. Reed, C.S. Dowd, C. Manca, G. Kaplan, and C.E. Barry, III. (2004). The role of MmpL8 in sulfatide biogenesis and virulence of Mycobacterium tuberculosis. J. Biol. Chem. 279: 21257-21265.
|
Evans, K., L. Passador, R. Srikumar, E. Tsang, J. Nezezon, and K. Poole. (1998). Influence of the MexAB-OprM multidrug efflux system on quorum sensing in Pseudomonas aeruginosa. J. Bacteriol. 180: 5443-5447.
|
Fernandez-Morena, M.A., J.L. Caballero, D.A. Hopwood, and F. Malpartida. (1991). The act cluster contains regulatory and antibiotic export genes, direct targets for translational control by the bldA tRNA gene of Streptomyces. Cell 66: 769-780.
|
Franke, S., G. Grass, and D.H. Nies. (2001). The product of the ybdE gene of the Escherichia coli chromosome is involved in detoxification of silver ions. Microbiology 147: 965-972.
|
Franke, S., G. Grass, and D.H. Nies. (2003). Molecular analysis of the copper-transporting efflux system CusCFBA of Escherichia coli. J. Bacteriol. 185: 3804-3812.
|
Goel, A.K., L. Rajagopal, N. Nagesh, and R.V. Sonti. (2002). Genetic locus encoding functions involved in biosynthesis and outer membrane localization of xanthomonadin in Xanthomonas oryzae pv. oryzae. J. Bacteriol. 184: 3539-3548.
|
Goldberg, M., T. Pribyl, S. Juhnke, and D. Nies. (1999). Energetics and topology of CzcA, a cation/proton antiporter of the resistance-nodulation-cell division protein family. J. Biol. Chem. 274: 26065-26070.
|
Grass, G. and C. Rensing. (2001). Genes involved in copper homeostasis in Escherichia coli. J. Bacteriol. 183: 2145-2147.
|
Guan, L., M. Ehrmann, H. Yoneyama, and T. Nakae. (1999). Membrane topology of the xenobiotic-exporting subunit, MexB, of the MexA,B-OprM extrusion pump in Pseudomonas aeruginosa. J. Biol. Chem. 274: 10517-10522.
|
Gupta, A., K. Matsui, J.-F. Lo, and S. Silver. (1999). Molecular basis for resistance to silver cations in Salmonella. Nature Med. 5: 183-188.
|
Hagman, K.E., C.E. Lucas, J.T. Balthazar, L. Snyder, M. Nilles, R.C. Judd, and W.M. Shafer. (1997). The MtrD protein of Neisseria gonorrhoeae is a member of the resistance/nodulation/division protein family constituting part of an efflux system. Microbiology 143: 2117-2125.
|
Hearn, E.M., J.J. Dennis, M.R. Gray, and J.M. Foght. (2003). Identification and characterization of the emhABC efflux system for polycyclic aromatic hydrocarbons in Pseudomonas fluorescens cLP6a. J. Bacteriol. 185: 6233-6240.
|
Hua, X., A. Nohturfft, J.L. Goldstein, and M.S. Brown. (1996). Sterol resistance in CHO cells traced to point mutation in SREBP cleavage-activating protein. Cell 87: 415-426.
|
Kieboom, J. and J.A.M. de Bont. (2001). Identification and molecular characterization of an efflux system involved in Pseudomonas putida S12 multidrug resistance. Microbiology 147: 43-51.
|
Kieboom, J., J.J. Dennis, J.A.M. de Bont, and G.J. Zylstra. (1998). Identification and molecular characterization of an efflux pump involved in Pseudomonas putida S12 solvent tolerance. J. Biol. Chem. 273: 85-91.
|
Loftus, S.K., J.A. Morris, E.D. Carstea, J.Z. Gu, C. Cummings, A. Brown, J. Ellison, K. Ohno, M.A. Rosenfeld, D.A. Tagle et al. (1997). Murine model of Niemann-Pick C disease: mutation in a cholesterol homeostasis gene. Science 277: 232-235.
|
Mao, W., M.S. Warren, D.S. Black, T. Satou, T. Murata, T. Nishino, N. Gotoh, and O. Lomovskaya. (2002). On the mechanism of substrate specificity by resistance nodulation division (RND)-type multidrug resistance pumps: the large periplasmic loops of MexD from Pseudomonas aeruginosa are involved in substrate recognition. Mol. Microbiol. 46: 889-901.
|
Maseda, H., M. Kitao, S. Eda, E. Yoshihara, and T. Nakae. (2002). A novel assembly process of the multicomponent xenobiotic efflux pump in Pseudomonas aeruginosa. Mol. Microbiol. 46: 677-686.
|
Murakami, S., R. Nakashima, E. Yamashita, and A. Yamaguchi. (2002). Crystal structure of bacterial multidrug efflux transporter AcrB. Nature 419: 587-593.
|
Nagakubo, S., K. Nishino, T. Hirata, and A. Yamaguchi. (2002). The putative response regulator BaeR stimulates multidrug resistance of Escherichia coli via a novel multidrug exporter system, MdtABC. J. Bacteriol. 184: 4161-4167.
|
Nishino, K. and A. Yamaguchi. (2001). Analysis of a complete library of putative drug transporter genes in Escherichia coli. J. Bacteriol. 183: 5803-5812.
|
Nishiyama, K., A. Fukuda, K. Morita, and H. Tokuda. (1999). Membrane deinsertion of SecA underlying proton motive force-dependent stimulation of protein translocation. EMBO J. 18: 1049-1058.
|
Palumbo, J.D., C.I. Kado, and D.A. Phillips. (1998). An isoflavonoid-inducible efflux pump in Agrobacterium tumefaciens is involved in competitive colonization of roots. J. Bacteriol. 180: 3107-3113.
|
Paulsen, I.T., M.H. Brown, and R.A. Skurray. (1996). Proton-dependent multidrug efflux pumps. Microbiol. Rev. 60: 575-608.
|
Pearson, J.P., C. van Delden, and B.H. Iglewski. (1999). Active efflux and diffusion are involved in transport of Pseudomonas aeruginosa cell-to-cell signals. J. Bacteriol. 181: 1203-1210.
|
Recht J, A. Martinez, S. Torello, and R. Kolter. (2000). Genetic analysis of sliding motility in Mycobacterium smegmatis. J. Bacteriol. 182: 4348-4351.
|
Rojas, A., E. Duque, G. Mosqueda, G. Golden, A. Hurtado, J.L. Ramos, and A. Segura. (2001). Three efflux pumps are required to provide efficient tolerance to toluene in Pseudomonas putida DOT-T1E. J. Bacteriol. 183: 3967-3973.
|
Rosenberg, E.Y., D. Ma, and H. Nikaido. (2000). AcrD of Escherichia coli is an aminoglycoside efflux pump. J. Bacteriol. 182: 1754-1756.
|
Rouquette, C., J.B. Harmon, and W.M. Shafer. (1999). Induction of the mtrCDE-encoded efflux pump system of Neisseria gonorrhoeae requires MtrA, an AraC-like protein. Mol. Micobiol. 33: 651-658.
|
Saier, M.H., Jr., R. Tam, A. Reizer, and J. Reizer. (1994). Two novel families of bacterial membrane proteins concerned with nodulation, cell division and transport. Mol. Microbiol. 11: 841-847.
|
Sleat, D.E., J.A. Wiseman, M. El-Banna, S.M. Price, L. Verot, M.M. Shen, G.S. Tint, M.T. Vanier, S.U. Walkley, and P. Lobel. (2004). Genetic evidence for nonredundant functional cooperativity between NPC1 and NPC2 in lipid transport. Proc. Natl. Acad. Sci. USA 101: 5886-5891.
|
Tseng, T.-T., K.S. Gratwick, J. Kollman, D. Park, D.H. Nies, A. Goffeau, and M.H. Saier, Jr. (1999). The RND permease superfamily: an ancient, ubiquitous and diverse family that includes human disease and development proteins. J. Mol. Microbiol. Biotechnol. 1: 107-125.
|
White, D.G., J.D. Goldman, B. Demple, and S.B. Levy. (1997). The acrAB locus in organic solvent tolerance meditated by expression of marA, soxS, or robA in Escherichia coli. J. Bacteriol. 179: 6122-6126.
|
Yu, E.W., G. McDermott, H.I. Zgurskaya, H. Nikaido, and D.E. Koshland, Jr. (2003). Structural basis of multiple drug-binding capacity of the AcrB multidrug efflux pump. Science 300: 976-980.
|
Yu, E.W., J.R. Aires, and H. Nikaido. (2003). AcrB multidrug efflux pump of Escherichia coli: composite substrate-binding cavity of exceptional flexibility generates its extremely wide substrate specificity. J. Bacteriol. 185: 5657-5664.
|
Zgurskaya, H.I. and H. Nikaido. (2000). Cross-linked complex between oligomeric periplasmic lipoprotein AcrA and the inner-membrane-associated multidrug efflux pump AcrB from Escherichia coli. J. Bacteriol. 182: 4264-4267.
|
| Examples: |
| TC# | Name | Organismal Type | Example |
| 2.A.6.1 The Heavy Metal Efflux (HME) Family |
|
| 2.A.6.1.1 | Heavy metal efflux pump (Ni2+ and Co2+) | Gram-negative bacteria | CnrA of Ralstonia eutropha |
| |
| 2.A.6.1.2 | Heavy metal efflux pump (Co2+; Zn2+; Cd2+) | Gram-negative bacteria | CzcA of Ralstonia eutropha |
| |
| 2.A.6.1.3 | Silver ion (Ag+)-specific efflux pump | Gram-negative bacteria | SilA of Salmonella typhimurium |
| |
| 2.A.6.1.4 | Cu+/Ag+ efflux pump, CusABCF (may pump ions from the periplasm to the external medium); CusF is a periplasmic Cu+/Ag+ binding receptor essential for full resistance (Franke et al., 2003). | Gram-negative bacteria | CusCFBA of E. coli; CusA (RND); CusB (MFP); CusC (OMF); CusF (BP) |
| |
| 2.A.6.2 The (Largely Gram-negative Bacterial) Hydrophobe/Amphiphile Efflux-1 (HAE1) Family |
|
| 2.A.6.2.1 | Multidrug (acriflavin, doxorubicin, ethidium, rhodamine 6G, SDS, deoxycholate) resistance pump | Gram-negative bacteria | AcrF (EnvD) of E. coli |
| |
| 2.A.6.2.2 | Multidrug/dye/detergent resistance pump (substrates include: chloramphenicol, tetracycline, erythromycin, nalidixic acid, fusidic acid, fluoroquinolones, lipophilic β-lactams, norfloxacin, doxorubicin, novobiocin, rifampin, trimethoprim, acriflavin, crystal violet, ethidium, disinfectants rhodamine-6G, TPP, benzalkonium, SDS, Triton X-100, deoxycholate/bile salt/organic solvent (alkanes)/phospholipids) (Lateral entry of substrate from the lipid bilayer into AcrB and its homologues has been proposed.) (Yu et al., 2003) | Gram-negative bacteria | AcrB of E. coli |
| |
| 2.A.6.2.3 | Isoflavenoid efflux pump, IfeB | Gram-negative bacteria | IfeB of Agrobacterium tumefaciens |
| |
| 2.A.6.2.4 | Organic solvent (toluene) efflux pump, SrpB | Gram-negative bacteria | SrpB solvent efflux pump of Pseudomonas putida
|
| |
| 2.A.6.2.5 | Fatty acid; bile salt; gonadal steroid; antibacterial peptide efflux pump, MtrD | Gram-negative bacteria | MtrD of Neisseria gonorrhoeae |
| |
| 2.A.6.2.6 | Multiple drug; N-(3-oxododecanoyl)-
L-homoserine lactone autoinducer efflux pump | Gram-negative bacteria | MexB of Pseudomonas aeruginosa |
| |
| 2.A.6.2.7 | Multidrug efflux pump, AcrD (exports aminoglycosides (amikacin, gentamicin, neomycin, kanamycin and tobramycin) as well as anionic detergents (SDS and deoxycholate) | Gram-negative bacteria | AcrD of E. coli |
| |
| 2.A.6.2.8 | Multidrug efflux pump, ArpB (exports tetracycline, chloramphenicol, carbenicillin, streptomycin, erythromycin, novobiocin, etc.) | Gram-negative bacteria | ArpB of Pseudomonas putida |
| |
| 2.A.6.2.9 | Solvent efflux pump, TtgB (extrudes toluene, styrene, m-xylene, ethylbenzene and propylbenzene) | Gram-negative bacteria | TtgB of Pseudomonas putida |
| |
| 2.A.6.2.10 | Solvent efflux pump, TtgE (extrudes only toluene and styrene) | Gram-negative bacteria | TtgE of Pseudomonas putida |
| |
| 2.A.6.2.11 | Solvent and antibiotic efflux pump, TtgH (solvents extruded include toluene, styrene, m-xylene, ethylbenzene and propylbenzene) | Gram-negative bacteria | TtgH of Pseudomonas putida |
| |
| 2.A.6.2.12 | Multidrug/detergent resistance protein YegN (MdtB) (exports nalidixic acid, norfloxacin, enoxacin, kanamycin, benzalkonium, SDS and deoxycholate) | Bacteria | YegN of E. coli |
| |
| 2.A.6.2.13 | Multidrug/dye/detergent resistance protein, YhiV (exports erythromycin, doxorubicin, crystal violet, ethidium, rhodamine 6G, TPP, benzalkonium, SDS and deoxycholate) | Bacteria | YhiV of E. coli |
| |
| 2.A.6.2.14 | Bile salt exporter, MdtC (YegO) [Acts with MdtA, an MFP (TC #8.A.1) and possibly with MdtB (TC #2.A.6.2.12) to form a heterooligomeric complex with broad specificity.] | Bacteria | MdtC (YegO) of E. coli |
| |
| 2.A.6.2.15 | Multidrug efflux pump, MexD (exports levofloxacin, carbenicillin, aztreonam, ceftazidime, cefepime, cefoperazone, piperacillin, erythromycin, azithromyein, chloramphenicol, etc.; Mao et al., 2002) | Bacteria | MexD of Pseudomonas aeruginosa |
| |
| 2.A.6.2.16 | Multidrug efflux pump, MexE (exports xenobiotics and chloramphenicol; functions with MexF (MFP) and OprN (OMF)) | Bacteria | MexE of Pseudomonas aeruginosa |
| |
| 2.A.6.2.17 | Multidrug efflux pump, MexK (exports biocide triclosan [with MexJ but without OprM] as well as tetracycline, erythromycin [requiring both MexJ and OprM]; Chuanchuen et al., 2002) | Bacteria | MexK of Pseudomonas aeruginosa |
| |
| 2.A.6.2.18 | The polycyclic aromatic hydrocarbon (phenanthrene; anthacene; fluoranthene)/drug (chloramphenicol; naldixic acid) exporter, EmhABC (Hearn et al., 2003) | Bacteria | EmhABC of Pseudomonas fluorescence
EmhA (AAQ92180)
EmhB (AAQ92181)
EmhC (AAQ92182) |
| |
| 2.A.6.3 The Putative Nodulation Factor Exporter (NFE) Family |
|
| 2.A.6.3.1 | Putative lipooligosaccharide nodulation factor exporter, NolGHI | Gram-negative bacteria | NolGHI of Rhizobium meliloti |
| |
| 2.A.6.4 The SecDF (SecDF) Family |
|
| 2.A.6.4.1 | The secretory accessory proteins, SecDF | Bacteria | SecDF of E. coli; SecD; SecF |
| |
| 2.A.6.5 The (Gram-positive Bacterial Putative) Hydrophobe/Amphiphile Efflux-2 (HAE2) Family |
|
| 2.A.6.5.1 | The antibiotic actinorhodin transport-associated protein, ActII3 | Gram-positive bacteria | ActII3 of Streptomyces coelicolor |
| |
| 2.A.6.5.2 | The phthiocerol dimycocerosate (PDIM) lipid exporter, MmpL7 | Gram-positive bacteria | MmpL7 of Mycobacterium tuberculosis |
| |
| 2.A.6.5.3 | The putative glycopeptidolipid exporter, TmtpC (most similar to MmpL of M. leprae; implicated in sliding motility) | Gram-positive bacteria | TmtpC of Myobacterium smegmatis |
| |
| 2.A.6.5.4 | 2,3-diacyl-α, α'-D-trehalose-2'-sulfate (sulfatide precursor) exporter, MmpL8 (Domenech et al., 2004) | Gram-positive bacteria | MmpL8 of Mycobacterium tuberculosis (CAB10022) |
| |
| 2.A.6.6 The Eukaryotic (Putative) Sterol Transporter (EST) Family |
|
| 2.A.6.6.1 | Niemann-Pick C1 AND C2 disease proteins (together to form a possible lipid/cholesterol exporter from lysosomes to other cellular sites) (Sleat et al., 2004). | Animals | NPC1 and NPC2 of Homo sapiens
NPC1 (AAH63302)
NPC2 (AAH02532) |
| |
| 2.A.6.6.2 | Patched (Ptc) segmentation polarity protein | Animals | "Patched" of Drosophila melanogaster |
| |
| 2.A.6.6.3 | Yeast membrane protein YPL006w | Protein, yeast | YPL006w of Saccharomyces cerevisiae |
| |
| 2.A.6.6.4 | SREBP cleavage-activating protein, SCAP | Animals | SCAP of Cricetulus griseus |
| |
| 2.A.6.6.5 | 3-hydroxy-3-methylglutaryl (HMG)-CoA reductase | Animals | HMG-CoA reductase of Homo sapiens |
| |
| 2.A.6.6.6 | Intestinal enterocyte brush border Niemann-Pick C1 like 1 (NPC1L1) protein; probably responsible for ezetimibe-sensitive absorption of luminal cholesterol (Altmann et al., 2004). | Animals | NPC1L1 of Homo sapiens (NP_037521) |
| |
| 2.A.6.7 The (Largely Archaeal Putative) Hydrophobe/Amphiphile Efflux-3 (HAE3) Family |
|
| 2.A.6.7.1 | Gene AF1229 | Archaea | ORF in Archeoglobus fulgidus |
| |
| 2.A.6.7.2 | Gene MJ1562 | Archaea | ORF in Methanococcus jannaschii |
| |
| 2.A.6.8 The Brominated, Aryl Polyene Pigment Exporter (ORF4) Family |
|
| 2.A.6.8.1 | Xanthomonadin (brominated, aryl polyene pigment) exporter (to its outer membrane site), ORF4 | Bacteria | ORF4 in the pig (pigment) gene locus of Xanthomonas oryzae pv. oryzae |
| |