TCID | Name | Domain | Kingdom/Phylum | Protein(s) |
---|---|---|---|---|
2.A.85.1.1 | Inner membrane protein, YccS, of unknown specificity but of 717 aas and 12 TMSs in a 6 + 6 TMS arrangement, each followed by an ~ 200 aa hydrophilic domain. | Bacteria |
Pseudomonadota | YccS of E. coli (717 aas) (P75870) |
2.A.85.1.2 | p-hydroxybenzoate efflux carrier, AaeB (Van Dyk et al., 2004). Several aromatic carboxylic acids serve as inducers of yhcRQP operon expression. | Bacteria |
Pseudomonadota | AaeB (YhcP) of E. coli (655 aas) (P46481) |
2.A.85.1.3 | YhfK of unknown specificity | Bacteria |
Pseudomonadota | YhfK of E. coli (P45537) |
2.A.85.1.4 | Fusaric acid resistance protein | Bacteria |
Pseudomonadota | Fusaric acid resistance protein of Pantoea sp. aB (E0M081) |
2.A.85.1.5 | Uncharacterized transporter YdhK | Bacteria |
Pseudomonadota | YdhK of Salmonella typhimurium |
2.A.85.1.6 | Uncharacterized transporter YdhK | Bacteria |
Pseudomonadota | YdhK of Escherichia coli O157:H7 |
2.A.85.1.7 | Uncharacterized protein of 635 aas and 9 or 10 TMSs in a 5 (or 6) + hydrophilic domain + 4 TMSs + another hydrophilic domain. The protein shows very little sequence similarity with other members of this family. | Archaea |
Euryarchaeota | UP of Methanosphaera stadtmanae |
2.A.85.2.1 | An inorganic anion (Cl-/NO3-) transporter, ALMT12 or QUAC1 (Quickly activating Anion Channel 1), reported to be incapable of transporting organic anions, is involved in stomatal closure (Sasaki et al, 2010). It is an R-type inorganic anion channel required for stomatal movement in Arabidopsis guard cells (Meyer et al., 2010). The C-terminal cytosolic domain mediates voltage gating (Mumm et al. 2013). QUAC1 regulates stomatal closure in response to environmental stimuli (Qin et al. 2022). See Dabravolski and Isayenkov 2023 for a review of the ALMT subfamiily. | Eukaryota |
Viridiplantae, Streptophyta | Orf1 of Arabidopsis thaliana (560 aas) (O49696) |
2.A.85.2.2 | Putative transport protein, Orf5, of 533 aas and 7 or 8 TMSs in a 5 or 6 TMS bundle near the N-terminus, one more putative TMS near the middle, and one more near the C-terminus. | Eukaryota |
Viridiplantae, Streptophyta | Orf5 of Arabidopsis thaliana (533 aas) (Q9SX23) |
2.A.85.2.3 | The root aluminum-activated malate efflux transporter, ALMT1 (required for aluminum tolerance) (Hoekenga et al., 2006). Also called Quick Anion Channel, QUAC, based on activation kinetics of anion channel currents in response to voltage changes. Evolutionary studies have been reported (Dreyer et al. 2012). Plants respond to aluminum (Al) ions by releasing malate from their root apices via ALMT1 with malate bound to the toxic Al ions, contributing to Al tolerance (Sasaki et al. 2014). ALMT1 mediates the efflux of malate to chelate the Al3+ in acidic soils and underlies the plant's Al resistance. Wang et al. 2021 presented cryo-EM structures of AtALMT1 in the apo, malate-bound, and Al-bound states at up to 3.0 Å resolution. The AtALMT1 dimer assembles an anion channel, and each subunit contains six transmembrane helices (TMSs) as well as six cytosolic α-helices. Two pairs of Arg residues are located in the center of the channel pore and contribute to malate recognition. Al binds at the extracellular side of AtALMT1 and induces conformational changes of the TMS 1-2 loop and the TMS 5-6 loop, resulting in the opening of the extracellular gate (Wang et al. 2021). Qin et al. 2022 provided insight into the gating and modulation of the ALMT12/QUAC1 anion channel in Glycine max (soybean). Picrotoxin inhibits anion flux but not GABA flux (Ramesh et al. 2022). | Eukaryota |
Viridiplantae, Streptophyta | ALMT1 of Arabidopsis thaliana (Q15EV0) |
2.A.85.2.4 | The anion-selective transporter ALMT1 (transports anions) (35% identical to 2.A.85.2.3) (Pineros et al., 2008) | Eukaryota |
Viridiplantae, Streptophyta | ALMT1 of Zea mays (A1XGH3) |
2.A.85.2.5 | Aluminum-stimulated anion (Malate >> NO3- > Cl-; Malate/Cl- ≈ 20) channel (Zhang et al., 2008) (67% identical to 2.A.85.2.4). Confers Al+3 resistance (Ryan et al., 2011). May also transport a variety of organic and inorganic anions (Piñeros et al. 2008). It can also transport GABA (Ramesh et al. 2018). ALMT1 has 6 TMSs with the N- and C-termini being on the external surface of the plasma membrane (Motoda et al. 2007). | Eukaryota |
Viridiplantae, Streptophyta | ALMT1 of Triticum aestivum (Q76LB2) |
2.A.85.2.6 | Putative aluminum-activated malate transporter 3 (AtALMT3) | Eukaryota |
Viridiplantae, Streptophyta | ALMT3 of Arabidopsis thaliana |
2.A.85.2.7 | The vacuolar malate "channel", ALMT9, of 598 aas and 6 - 8 TMSs. TMSs 1 - 6 occur together near the N-terminus; putatives TMS 7 is near the middle of the protein, and putative TMS 8 is near the C-terminus. Citrate is an open channel blocker. There are probably four subunits, and TMS5 contributes to pore formation (Zhang et al. 2013). It has higher selectivity for malate than for fumarate and exhibits weak chloride conductance (Kovermann et al. 2007). The apple ALMT9 requires a conserved C-terminal domain for malate transport, underlying fruit acidity (Li et al. 2020). | Eukaryota |
Viridiplantae, Streptophyta | ALMT9 of Arabidopsis thaliana |
2.A.85.2.8 | Aluminum-activated malate transporter 7, ALMT7, of 462 aas and 6 or 7 TMSs in a 5 or 6 (N-terminal) + 1 or 2 TMS (C-terminal) TMS arrangement. Multiple ALMT subunits combine to form functional anion channels in rice (Zhou et al. 2022). | Eukaryota |
Viridiplantae, Streptophyta | ALMT7 of Saccharum hybrid cultivar
|
2.A.85.3.1 | Hypothetical protein | Eukaryota |
Fungi, Ascomycota | Ydg8 of Schizosaccharomyces pombe (977 aas) (Q10495) |
2.A.85.3.2 | Uncharacterized protein of 1125 aas | Eukaryota |
Fungi, Ascomycota | UP of Saccharomyces cerevisiae |
2.A.85.3.3 | Uncharacterized protein of 1219 aas | Eukaryota |
Fungi, Ascomycota | UP of Saccharomyces cerevisiae |
2.A.85.3.4 | Protein required for ubiquinone biosynthesis of 1035 aas and 14 putative TMSs | Eukaryota |
Fungi, Ascomycota | Protein of Komagataella pastoris |
2.A.85.3.5 | Uncharacterized protein of 1040 aas | Eukaryota |
Fungi, Basidiomycota | UP of Gloeophyllum trabeum (Brown rot fungus) |
2.A.85.4.1 | Lantibiotic protection protein, MutG | Bacteria |
Bacillota | MutG of Aerococcus viridans (D4YEF0) |
2.A.85.4.2 | YgaE | Bacteria |
Bacillota | YgaE of Bacillus subtilis (P71083) |
2.A.85.4.3 | DUF939 (N-terminus) with C-terminal HAD hydrolase (Cof or haloacid dehydrogenase) family IIB domain; 450 aas. | Bacteria |
Bacillota | DUF939 protein of Clostridium methylpentosum |
2.A.85.4.4 | 5 or 6 TMS 'half sized', YqjA | Bacteria |
Bacillota | YqjA of Bacillus subtilis (322 aas) (P54538) |
2.A.85.6.1 | MdtO (YjcQ), Multidrug resistance protein (involved in resistance to puromycin, acriflavin and tetraphenyl arsonium chloride; acts with MdtN (TC# 8.A.1.1.3) and MdtP (TC# 1.B.17.3.9)) (Sulavik et al., 2001). | Bacteria |
Pseudomonadota | MdtO of E. coli (P32715) |
2.A.85.6.2 | FUSC family protein of 751 aas and 10 or 12 TMSs. | Bacteria |
Pseudomonadota | FUSC family protein of Burkholderia gladioli |
2.A.85.6.3 | FUSC family protein of 517 aas and 12 TMSs. | Bacteria |
Pseudomonadota | FUSC family protein of Gemmobacter intermedius
|
2.A.85.7.1 | Fusaric acid resistance protein, FusC (YeeA; 352aas; 6 N-terminal TMSs plus a hydrophilic C-terminal cytoplasmic domain). | Bacteria |
Pseudomonadota | FusC of E. coli (P33011) |
2.A.85.7.2 | MutG lantibiotic protection protein with 6 N-terminal TMSs and a hydrophilic C-terminal domain. | Bacteria |
Pseudomonadota | MutG of Psychrobacter sp. 1501 (F5SU14) |
2.A.85.8.1 | Putative integral membrane protein
| Bacteria |
Actinomycetota | Putative integral membrane protein of Streptomyces coelicolor |
2.A.85.8.2 | FUSC family protein of 460 aas and probably 12 TMSs. | Bacteria |
Actinomycetota | FUSC family protein of Gordonia paraffinivorans |
2.A.85.8.3 | FUSC family protein of 383 aas and 11 or 12 TMSs, with no large hydrophilic domain. | Bacteria |
Pseudomonadota | FUSC family protein of Psychrobacter faecalis |
2.A.85.8.4 | Uncharacterized protein of 376 aas and 12 probable TMSs with no hydrophilic domain. | Eukaryota |
Metazoa, Chordata | UP of Enterococcus faecium |
2.A.85.8.5 | FUSC family protein of 361 aas and 12 probable TMSs. | Bacteria |
Actinomycetota | Fusc family protein of Demequina subtropica |
2.A.85.9.1 | Putative integral membrane protein | Bacteria |
Actinomycetota | Putative integral membrane protein of Streptomyces coelicolor |
2.A.85.9.2 | FUSC family protein of 423 aas and 6 TM | Bacteria |
Actinomycetota | FUSC family protein of Marmoricola scoriae |
2.A.85.9.3 | FUSC family protein of 338 aas and 5 or 6 N-terminal TMSs plus a large C-terminal hydrophilic domain. | Bacteria |
Bacillota | FUSC family protein of Bacillus velezensis |
2.A.85.9.4 | FUSC family protein of 374 aas and 6 N-terminal TMSs. | Bacteria |
Actinomycetota | FUSC family protein of Microbacterium oxydans |
2.A.85.10.1 | Fusaric acid resistance protein homologue | Bacteria |
Actinomycetota | FusB homologue of Streptomyces coelicolor |
2.A.85.10.2 | FusB homologue | Bacteria |
Actinomycetota | FusB homologue of Streptomyces coelicolor |
2.A.85.11.1 | Uncharacterized protein of 1406 aas | Eukaryota |
Rhodophyta | UP of Galdieria sulphuraria |
2.A.85.11.2 | Uncharacterized protein of 1365 aas | Eukaryota |
Rhodophyta | UP of Galdieria sulphuraria |
2.A.85.11.3 | Uncharacterized protein of 1638 aas | Eukaryota |
Rhodophyta | UP of Galdieria sulphuraria |
2.A.85.11.4 | Uncharacterized protein of 1269 aas and 11 - 14 TMSs. | Eukaryota |
Viridiplantae, Chlorophyta | UP of Chlamydomonas reinhardtii (Chlamydomonas smithii) |
2.A.85.12.1 | Integral 6 TMS membrane protein which has been assigned to the FusC (fusaric acid) family. It's function is not clear. | Archaea |
Euryarchaeota | FusC of Methanoregula boonei
|
2.A.85.12.2 | Uncharacterized membrane protein of 173 aas and 6 TMSs. | Bacteria |
Pseudomonadota | UP of Halothiobacillus neapolitanus (Thiobacillus neapolitanus)
|
2.A.85.12.3 | Uncharacterized membrane protein of 183 aas and 6 TMSs. | Bacteria |
Bacteroidota | UP of Odoribacter sp. |
2.A.85.12.4 | Uncharacterized membrane protein of 232 aas and probably 6 TMSs. | Bacteria |
Pseudomonadota | UP of Magnetospirillum fulvum |
2.A.85.12.5 | Uncharacterized FUSC family protein of 181 aas and 6 TMSs in a 2 + 2 + 2 TMS arrangement. | Bacteria |
Bacteroidota | UP of Alistipes communis |
2.A.85.12.6 | Uncharacterized FUSC family protein of 173 aas and 6 TMSs. | Archaea |
Euryarchaeota | UP of Methanomicrobiales archaeon |
2.A.85.12.7 | Uncharacterized FUSC family protein of 171 aas and 6 TMSs. | Bacteria |
Pseudomonadota | UP of Pseudofrancisella aestuarii |
2.A.85.12.9 | Uncharacterized FUSC family protein of 106 aas and 6 TM | Bacteria |
Acidobacteriota | UP of Candidatus Acidoferrum sp. |