Biology:Substrate-level phosphorylation

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Short description: Metabolic reaction
Substrate-level phosphorylation exemplified with the conversion of ADP to ATP

Substrate-level phosphorylation is a metabolism reaction that results in the production of ATP or GTP supported by the energy released from another high-energy bond that leads to phosphorylation of ADP or GDP to ATP or GTP (note that the reaction catalyzed by creatine kinase is not considered as "substrate-level phosphorylation"). This process uses some of the released chemical energy, the Gibbs free energy, to transfer a phosphoryl (PO3) group to ADP or GDP. Occurs in glycolysis and in the citric acid cycle.[1]

Unlike oxidative phosphorylation, oxidation and phosphorylation are not coupled in the process of substrate-level phosphorylation, and reactive intermediates are most often gained in the course of oxidation processes in catabolism. Most ATP is generated by oxidative phosphorylation in aerobic or anaerobic respiration while substrate-level phosphorylation provides a quicker, less efficient source of ATP, independent of external electron acceptors. This is the case in human erythrocytes, which have no mitochondria, and in oxygen-depleted muscle.

Overview

Adenosine triphosphate (ATP) is a major "energy currency" of the cell.[2] The high energy bonds between the phosphate groups can be broken to power a variety of reactions used in all aspects of cell function.[3]

Substrate-level phosphorylation occurs in the cytoplasm of cells during glycolysis and in mitochondria either during the Krebs cycle or by MTHFD1L (EC 6.3.4.3), an enzyme interconverting ADP + phosphate + 10-formyltetrahydrofolate to ATP + formate + tetrahydrofolate (reversibly), under both aerobic and anaerobic conditions. In the pay-off phase of glycolysis, a net of 2 ATP are produced by substrate-level phosphorylation.

Glycolysis

Main page: Biology:Glycolysis

The first substrate-level phosphorylation occurs after the conversion of 3-phosphoglyceraldehyde and Pi and NAD+ to 1,3-bisphosphoglycerate via glyceraldehyde 3-phosphate dehydrogenase. 1,3-bisphosphoglycerate is then dephosphorylated via phosphoglycerate kinase, producing 3-phosphoglycerate and ATP through a substrate-level phosphorylation.

The second substrate-level phosphorylation occurs by dephosphorylating phosphoenolpyruvate, catalyzed by pyruvate kinase, producing pyruvate and ATP.

During the preparatory phase, each 6-carbon glucose molecule is broken into two 3-carbon molecules. Thus, in glycolysis dephosphorylation results in the production of 4 ATP. However, the prior preparatory phase consumes 2 ATP, so the net yield in glycolysis is 2 ATP. 2 molecules of NADH are also produced and can be used in oxidative phosphorylation to generate more ATP.

Mitochondria

ATP can be generated by substrate-level phosphorylation in mitochondria in a pathway that is independent from the proton motive force. In the matrix there are three reactions capable of substrate-level phosphorylation, utilizing either phosphoenolpyruvate carboxykinase or succinate-CoA ligase, or monofunctional C1-tetrahydrofolate synthase.

Phosphoenolpyruvate carboxykinase

Mitochondrial phosphoenolpyruvate carboxykinase is thought to participate in the transfer of the phosphorylation potential from the matrix to the cytosol and vice versa.[4][5][6][7][8] However, it is strongly favored towards GTP hydrolysis, thus it is not really considered as an important source of intra-mitochondrial substrate-level phosphorylation.

Succinate-CoA ligase

Succinate-CoA ligase is a heterodimer composed of an invariant α-subunit and a substrate-specific ß-subunit, encoded by either SUCLA2 or SUCLG2. This combination results in either an ADP-forming succinate-CoA ligase (A-SUCL, EC 6.2.1.5) or a GDP-forming succinate-CoA ligase (G-SUCL, EC 6.2.1.4). The ADP-forming succinate-CoA ligase is potentially the only matrix enzyme generating ATP in the absence of a proton motive force, capable of maintaining matrix ATP levels under energy-limited conditions, such as transient hypoxia.

Monofunctional C1-tetrahydrofolate synthase

This enzyme is encoded by MTHFD1L and reversibly interconverts ADP + phosphate + 10-formyltetrahydrofolate to ATP + formate + tetrahydrofolate.

Other mechanisms

In working skeletal muscles and the brain, Phosphocreatine is stored as a readily available high-energy phosphate supply, and the enzyme creatine phosphokinase transfers a phosphate from phosphocreatine to ADP to produce ATP. Then the ATP releases giving chemical energy. This is sometimes erroneously considered to be substrate-level phosphorylation, although it is a transphosphorylation.

Importance of substrate-level phosphorylation in anoxia

During anoxia, provision of ATP by substrate-level phosphorylation in the matrix is important not only as a mere means of energy, but also to prevent mitochondria from straining glycolytic ATP reserves by maintaining the adenine nucleotide translocator in ‘forward mode’ carrying ATP towards the cytosol.[9][10][11]

Oxidative phosphorylation

Main page: Biology:Oxidative phosphorylation

An alternative method used to create ATP is through oxidative phosphorylation, which takes place during cellular respiration. This process utilizes the oxidation of NADH to NAD+, yielding 3 ATP, and of FADH2 to FAD, yielding 2 ATP. The potential energy stored as an electrochemical gradient of protons (H+) across the inner mitochondrial membrane is required to generate ATP from ADP and Pi (inorganic phosphate molecule), a key difference from substrate-level phosphorylation. This gradient is exploited by ATP synthase acting as a pore, allowing H+ from the mitochondrial intermembrane space to move down its electrochemical gradient into the matrix and coupling the release of free energy to ATP synthesis. Conversely, electron transfer provides the energy required to actively pump H+ out of the matrix.

References

  1. Freeman, Scott (2020). Biological science. Quillin, Kim, Allison, Lizabeth A., 1958-, Black, Michael (Lecturer in biology), Podgorski, Greg, Taylor, Emily (Lecturer in biological sciences), Carmichael, Jeff. (Seventh ed.). Hoboken, NJ. ISBN 978-0-13-467832-0. OCLC 1043972098. https://www.worldcat.org/oclc/1043972098. 
  2. Skulachev, Vladimir P.; Bogachev, Alexander V.; Kasparinsky, Felix O. (15 December 2012). Principles of Bioenergetics. Springer Science & Business Media. p. 252. ISBN 978-3-642-33430-6. https://books.google.com/books?id=-IJg4rgwXJQC. 
  3. Agteresch, Hendrik J.; Dagnelie, Pieter C.; van den Berg, J Willem; Wilson, J H. (1999). "Adenosine Triphosphate". Drugs 58 (2): 211–232. doi:10.2165/00003495-199958020-00002. ISSN 0012-6667. PMID 10473017. 
  4. Lambeth, DO; Tews, KN; Adkins, S; Frohlich, D; Milavetz, BI (2004). "Expression of two succinyl-CoA synthetases with different nucleotide specificities in mammalian tissues". The Journal of Biological Chemistry 279 (35): 36621–4. doi:10.1074/jbc.M406884200. PMID 15234968. 
  5. Ottaway, JH; McClellan, JA; Saunderson, CL (1981). "Succinic thiokinase and metabolic control". The International Journal of Biochemistry 13 (4): 401–10. doi:10.1016/0020-711x(81)90111-7. PMID 6263728. 
  6. Lambeth, DO (2002). "What is the function of GTP produced in the Krebs citric acid cycle?". IUBMB Life 54 (3): 143–4. doi:10.1080/15216540214539. PMID 12489642. 
  7. Wilson, DF; Erecińska, M; Schramm, VL (1983). "Evaluation of the relationship between the intra- and extramitochondrial ATP/ADP ratios using phosphoenolpyruvate carboxykinase". The Journal of Biological Chemistry 258 (17): 10464–73. doi:10.1016/S0021-9258(17)44479-6. PMID 6885788. 
  8. Johnson, JD; Mehus, JG; Tews, K; Milavetz, BI; Lambeth, DO (1998). "Genetic evidence for the expression of ATP- and GTP-specific succinyl-CoA synthetases in multicellular eucaryotes". The Journal of Biological Chemistry 273 (42): 27580–6. doi:10.1074/jbc.273.42.27580. PMID 9765291. 
  9. Chinopoulos, C; Gerencser, AA; Mandi, M; Mathe, K; Töröcsik, B; Doczi, J; Turiak, L; Kiss, G et al. (2010). "Forward operation of adenine nucleotide translocase during F0F1-ATPase reversal: critical role of matrix substrate-level phosphorylation". FASEB J 24 (7): 2405–16. doi:10.1096/fj.09-149898. PMID 20207940. 
  10. Chinopoulos, C (2011). "Mitochondrial consumption of cytosolic ATP: not so fast". FEBS Lett 585 (9): 1255–9. doi:10.1016/j.febslet.2011.04.004. PMID 21486564. 
  11. Chinopoulos, C (2011). "The "B space" of mitochondrial phosphorylation". J Neurosci Res 89 (12): 1897–904. doi:10.1002/jnr.22659. PMID 21541983.