Target Name: ATP5MC3
NCBI ID: G518
Other Name(s): ATP synthase, H+ transporting, mitochondrial F0 complex, subunit C3 (subunit 9) | ATP synthase F(0) complex subunit C3, mitochondrial (isoform A) | ATP synthase lipid-binding protein, mitochondrial | ATP5G3 | ATP synthase subunit 9 | ATP synthase proteolipid P3 | ATP synthase membrane subunit c locus 3, transcript variant 3 | ATPase subunit C | ATP5MC3 variant 3 | OTTHUMP00000205362 | ATP synthase membrane subunit c locus 3 | OTTHUMP00000205361 | P3 | ATP synthase lipid-binding protein | ATP synthase proton-transporting mitochondrial F(0) complex subunit C3 | DYTSPG | MGC125738 | ATPase protein 9 | AT5G3_HUMAN | dicyclohexylcarbodiimide (DCCD)-reactive proteolipid subunit | ATP synthase F(0) complex subunit C3, mitochondrial | ATP synthase, mitochondrial, C subunit-3 | ATP synthase, H+ transporting, mitochondrial F0 complex, subunit C3 (ATP5G3) | ATP synthase, H+ transporting, mitochondrial Fo complex subunit C3 (subunit 9) | ATPase subunit c | OTTHUMP00000163263

ATP5MC3: H+-ATPase Subunit C3 Regulates ATP Synthase and Maintain Proton Levels

ATP5MC3, also known as ATP synthase subunit C3, is a protein that plays a critical role in the function of ATP synthase, a protein complex that synthesizes ATP fromADP and phosphate ions. H+ transporting subunit (H+-ATPase) is an essential subunit of the ATP synthase complex that helps to maintain the proper pH level of the mitochondria. The subunit C3, also known as subunit 9, is a member of the H+-ATPase complex and is responsible for the H+ transporting subunit.

ATP synthase is a protein complex that consists of four subunits: subunit A, subunit B, subunit C, and subunit D. The subunit A is the ATP synthase enzyme, subunit B is the coenzyme Q, subunit C is the H+ transporting subunit, and subunit D is the ATP synthase subunit. The subunit C3, also known as subunit 9, is a member of the H+-ATPase complex and is responsible for the H+ transporting subunit.

The H+-ATPase complex is a critical subunit of the ATP synthase and is responsible for maintaining the proper pH level of the mitochondria. The H+-ATPase enzyme uses ATP as a source of energy to pump protons (H+) out of the mitochondria and into the cytosol. This process is essential for the proper functioning of many cellular processes, including metabolism, ion homeostasis, and signaling pathways.

ATP synthase is a complex that is highly regulated and is involved in many cellular processes. The activity of ATP synthase is regulated by various factors, including the concentration of ATP, the availability ofADP and phosphate, and the pH level of the cytosol. The H+ -ATPase subunit plays a critical role in maintaining the proper pH level of the cytosol and is responsible for regulating the activity of the ATP synthase.

The H+-ATPase subunit is composed of four subunits: subunit A, subunit B, subunit C, and subunit D. Subunit A is the ATP synthase enzyme and subunit B is a protein that binds to the coenzyme Q. Subunit C is the H+ transporting subunit and subunit D is a protein that binds to the ATP synthase subunit A.

The H+-ATPase enzyme is a proton pump that uses ATP as a source of energy to pump protons out of the mitochondria and into the cytosol. The H+-ATPase subunit is responsible for the H+ transporting subunit and is critical for the proper functioning of the ATP synthase. The activity of the H+-ATPase subunit is regulated by various factors, including the concentration of ATP, the availability ofADP and phosphate, and the pH level of the cytosol.

The H+-ATPase subunit is composed of four subunits: subunit A, subunit B, subunit C, and subunit D. Subunit A is the ATP synthase enzyme and subunit B is a protein that binds to the coenzyme Q. Subunit C is the H+ transporting subunit and subunit D is a protein that binds to the ATP synthase subunit A.

The H+-ATPase subunit plays a critical role in the regulation of the ATP synthase and is involved in many cellular processes. The activity of the H+-ATPase subunit is regulated by various factors, including the concentration of ATP, the availability ofADP and phosphate, and the pH level of the cytosol.

In conclusion, ATP5MC3, also known as ATP synthase subunit C3, is a protein that plays a critical role in

Protein Name: ATP Synthase Membrane Subunit C Locus 3

Functions: Mitochondrial membrane ATP synthase (F(1)F(0) ATP synthase or Complex V) produces ATP from ADP in the presence of a proton gradient across the membrane which is generated by electron transport complexes of the respiratory chain. F-type ATPases consist of two structural domains, F(1) - containing the extramembraneous catalytic core and F(0) - containing the membrane proton channel, linked together by a central stalk and a peripheral stalk. During catalysis, ATP synthesis in the catalytic domain of F(1) is coupled via a rotary mechanism of the central stalk subunits to proton translocation. Part of the complex F(0) domain. A homomeric c-ring of probably 10 subunits is part of the complex rotary element

More Common Targets

ATP5ME | ATP5MF | ATP5MG | ATP5MGL | ATP5MJ | ATP5MK | ATP5PB | ATP5PBP5 | ATP5PD | ATP5PDP3 | ATP5PF | ATP5PO | ATP6 | ATP6AP1 | ATP6AP1-DT | ATP6AP1L | ATP6AP2 | ATP6V0A1 | ATP6V0A2 | ATP6V0A4 | ATP6V0B | ATP6V0C | ATP6V0CP1 | ATP6V0CP3 | ATP6V0D1 | ATP6V0D1-DT | ATP6V0D2 | ATP6V0E1 | ATP6V0E1P1 | ATP6V0E2 | ATP6V0E2-AS1 | ATP6V1A | ATP6V1B1 | ATP6V1B2 | ATP6V1C1 | ATP6V1C2 | ATP6V1D | ATP6V1E1 | ATP6V1E2 | ATP6V1F | ATP6V1FNB | ATP6V1G1 | ATP6V1G1P1 | ATP6V1G2 | ATP6V1G2-DDX39B | ATP6V1G3 | ATP6V1H | ATP7A | ATP7B | ATP8 | ATP8A1 | ATP8A2 | ATP8B1 | ATP8B1-AS1 | ATP8B2 | ATP8B3 | ATP8B4 | ATP8B5P | ATP9A | ATP9B | ATPAF1 | ATPAF2 | ATPase | ATPSCKMT | ATR | ATRAID | Atrial natriuretic peptide (ANP) receptor | ATRIP | ATRN | ATRNL1 | ATRX | ATXN1 | ATXN10 | ATXN1L | ATXN2 | ATXN2L | ATXN3 | ATXN3L | ATXN7 | ATXN7L1 | ATXN7L2 | ATXN7L3 | ATXN7L3B | ATXN8OS | Augmin | AUH | AUNIP | AUP1 | AURKA | AURKAIP1 | AURKAP1 | AURKB | AURKC | Aurora Kinase | AUTS2 | AVEN | AVIL | AVL9 | AVP | AVPI1