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Catalysis of the transfer of a solute or solutes from one side of a membrane to the other according to the reaction: K+(in) + H+(out) = K+(out) + H+(in), where glutathione maintains the closed state. Catalysis of the transfer of a solute or solutes from one side of a membrane to the other according to the reaction: phenyl propionate(out) = phenyl propionate(in). Catalysis of the transfer of proteins from one side of the membrane to the other. Transportation is dependent on pH gradient across the membrane. Catalysis of the transfer of potassium from the outside of a cell to the inside of the cell across a membrane: K+(out) + energy = K+(in). null Catalysis of the transfer of a solute or solutes from one side of a membrane to the other according to the reaction: cyanate(out) = cyanate(in). Catalysis of the transfer of a specific substance or related group of substances from one side of a membrane to the other, up the solute's concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction. Catalysis of the transfer of peptide-acetyl-CoA from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. null Catalysis of the transfer of an oligopeptide or oligopeptides from one side of the membrane to the other, up the solute's concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction. Enables the active transport of a solute across a membrane by a mechanism whereby two or more species are transported in opposite directions in a tightly coupled process not directly linked to a form of energy other than chemiosmotic energy. Catalysis of the transfer of pyruvate from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the transfer of a zinc ion or zinc ions from the inside of the cell to the outside of the cell across a membrane: Zn2+(out) = Zn2+(in). The activity is driven by proton motive force. null Catalysis of the transfer of tricarboxylate from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the transport of a single molecular species across a membrane; transport is independent of the movement of any other molecular species. Catalysis of the transfer of a solute from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Enables the directed movement of fully folded proteins into, out of, within or between cells by targeting the proteins to the transporter via a specialized N-terminal twin arginine signal peptide. Enables the active transport of a solute across a membrane by a mechanism whereby two or more species are transported together in the same direction in a tightly coupled process not directly linked to a form of energy other than chemiosmotic energy. Catalysis of the transfer of a single solute from one side of the membrane to the other by a mechanism involving conformational change, either by facilitated diffusion or in a membrane potential dependent process if the solute is charged. Catalysis of the transfer of nitrite from the outside of a cell to the inside of the cell across a membrane. Catalysis of the transfer of a peptide from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by proton movement. null Catalysis of the transfer of ammonium from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. In high affinity transport the transporter is able to bind the solute even if it is only present at very low concentrations. Catalysis of the transfer of nitrite from the inside of the cell to the outside of the cell across a membrane. Catalysis of the transfer of a nucleoside, from one side of a membrane to the other, up a concentration gradient. Catalysis of the transfer of organic anions from one side of a membrane to the other, in a sodium independent manner. Catalysis of the transfer of ammonium from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. In low affinity transport the transporter is able to bind the solute only if it is present at very high concentrations. Catalysis of the transfer of a nucleoside, from one side of a membrane to the other, down the concentration gradient. Catalysis of the transfer of a neutral L-amino acid from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the transfer of thyroid hormones from one side of the membrane to the other. Thyroid hormone are any of the compounds secreted by the thyroid gland, largely thyroxine and triiodothyronine. Enables the transfer of a substance from one side of a membrane to the other. Catalysis of the transfer of reduced folate from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the transfer of oxaloacetate from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the transfer of arsenite from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the transfer of antimonite from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the secondary active transfer of sulfate from one side of the membrane to the other. Secondary active transport is catalysis of the transfer of a solute from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the movement of a monocarboxylate, any compound containing a single carboxyl group (COOH or COO-), by uniport, symport or antiport across a membrane by a carrier-mediated mechanism. Catalysis of the transfer of a inorganic phosphate from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the transfer of bilirubin from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport. Catalysis of the transfer of sterol from one side of the membrane to the other, up the solute's concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction.

View Gene Ontology (GO) Term

GO TERM SUMMARY

Name: secondary active transmembrane transporter activity
Acc: GO:0015291
Aspect: Molecular Function
Desc: Catalysis of the transfer of a solute from one side of a membrane to the other, up its concentration gradient. The transporter binds the solute and undergoes a series of conformational changes. Transport works equally well in either direction and is driven by a chemiosmotic source of energy. Chemiosmotic sources of energy include uniport, symport or antiport.
Synonyms:
  • heavy metal ion porter activity
  • coupled carrier
  • nitrite/nitrate porter activity
  • GO:0015353
  • multidrug endosomal transmembrane transporter activity
  • galactose/glucose (methylgalactoside) porter activity
  • porters
  • porter activity
  • electrochemical potential-driven transporter activity
  • GO:0015290
  • secondary carrier-type facilitators
  • active transporter
Proteins in PDR annotated with:
   This term: 1 [Search]
   Term or descendants: 1723 [Search]


[geneontology.org]
INTERACTIVE GO GRAPH

GO:0015291 - secondary active transmembrane transporter activity (interactive image map)

YRC Informatics Platform - Version 3.0
Created and Maintained by: Michael Riffle