Plasma membrane H+-ATPase explained

hydrogen-exporting ATPase, phosphorylative mechanism
Ec Number:3.6.3.6
Go Code:0008553

The P-type plasma membrane -ATPase is found in plants and fungi. For the gastric / ATPase (involved in the acidification of the stomach in mammals), see Hydrogen potassium ATPase.

Plasma membrane -ATPase (P-type)

This enzyme belongs to the family of hydrolases, specifically those acting on acid anhydrides to catalyse transmembrane movement of substances. To be specific, the protein is a part of the P-type ATPase family. The systematic name of this enzyme class is ATP phosphohydrolase (-exporting).

-exporting ATPase is also known as proton ATPase or more simply proton pump. Other names in common use include proton-translocating ATPase, yeast plasma membrane -ATPase, plant plasma membrane -ATPase, yeast plasma membrane ATPase, plant plasma membrane ATPase, and ATP phosphohydrolase.

The yeast (Saccharomyces cerevisiae) enzyme is encoded by the gene Pma1 and hence referred to as Pma1p.[1]

Function and location

The plasma membrane -ATPase or proton pump creates the electrochemical gradients in the plasma membrane of plants, fungi, protists, and many prokaryotes. Here, proton gradients are used to drive secondary transport processes. As such, it is essential for the uptake of most metabolites, and also for plant responses to the environment (e.g., movement of leaves).

Plasma membrane -ATPases are specific for plants, fungi, and protists; and -ATPases are specific for animal cells. These two groups of P-type ATPases, although not from the same subfamily, seem to perform a complementary function in plants/fungi/protists and animal cells, namely the creation of an electrochemical gradient used as an energy source for secondary transport.[2]

Structural studies

Structural information on P-type plasma membrane (PM) proton ATPases are scarce compared to that obtained for SERCA1a. A low resolution structure from 2D crystals of the PM -ATPase from Neurospora crassa is, as of medio 2011, the only structural information on the fungal -ATPase.[3] For the plant counterpart, a crystal structure of the AHA2 PM -ATPase from Arabidopsis thaliana has been obtained from 3D crystals with a resolution of 3.6 Å.[4] The structure of AHA2 clearly identifies three cytosolic domains corresponding to the N (nucleotide binding), P (phosphorylation), and A (actuator) domains, similar to those observed in the SR -ATPase and also verifies the presence of ten transmembrane helices. The 3D crystal structure shows the AHA2 PM -ATPase in a so-called quasi-occluded E1 state with the non-hydrolysable ATP analogue AMPPCP bound, and the overall fold of the catalytic unit reveals a high degree of structural similarity to the SR -ATPase and the ,-ATPase. The overall arrangement of the domains is similar to that observed for the occluded E1 conformation of the SR -ATPase, and based on comparison with structural data for the other conformations of the SR -ATPase, it was suggested that the structure of the AHA2 PM -ATPase represents a novel E1 intermediate. A distinct feature of the PM -ATPase not observed in other P-type ATPases is the presence of a large cavity in the transmembrane domain formed by M4, M5 and M6.

Regulation

Precise regulation of PM -ATPase activity is crucial to the plant. Over-expression of the PM -ATPase is compensated by a down-regulation of activity,[5] whereas deletion of an isoform is compensated by redundancy as well as augmented activity of other isoforms by increased level of post-translational modifications.[6] The PM -ATPase is subject to autoinhibition, which negatively regulates the activity of the pump and keeps the enzyme in a low activity state where ATP hydrolytic activity is partly uncoupled from ATP hydrolysis,.[7] [8] Release from the autoinhibitory restraints requires posttranslational modifications such as phosphorylation and interacting proteins. Autoinhibition is achieved by the N- and C-termini of the protein - communication between the two termini facilitates the necessary precise control of pump activity.[9] The autoinhibitory C-terminal domain can be displaced by phosphorylation of the penultimate Thr residue and the subsequent binding of 14-3-3 proteins.[10] [11] The PM -ATPase is the first P-type ATPase for which both termini have been demonstrated to take part in the regulation of protein activity.

Physiological roles in plants

Plasma membrane -ATPases are found throughout the plant in all cell types investigated, but some cell types have much higher concentrations of -ATPase than others. In general, these cell types are specialised for intensive active transport and accumulate solutes from their surroundings. Most studies of these roles come from genetic studies on Arabidopsis thaliana.[12] -ATPases in plants are expressed from a multigene subfamily, and Arabidopsis thaliana for instance, have 12 different -ATPase genes.

Some important physiological processes the plant -ATPase is involved in are:

References

Notes and References

  1. Thierry Ferreira, A. Brett Mason and Carolyn W. Slayman . The Yeast Pma1 Proton Pump: a Model for Understanding the Biogenesis of Plasma Membrane Proteins. J Biol Chem . 276 . 29613–29616 . 2001 . 32. 10.1074/jbc.R100022200 . 11404364. free .
  2. Pedersen JT, Palmgren M . Why do plants lack sodium pumps and would they benefit from having one? . Functional Plant Biology . 44 . 5 . 473–479 . March 2017 . 10.1071/FP16422 . 32480580 .
  3. Auer M, Scarborough GA, Kühlbrandt W . Three-dimensional map of the plasma membrane -ATPase in the open conformation . Nature . 392 . 6678 . 840–3 . April 1998 . 9572146 . 10.1038/33967 . 1998Natur.392..840A . 4318649 .
  4. Pedersen BP, Buch-Pedersen MJ, Morth JP, Palmgren MG, Nissen P . Crystal structure of the plasma membrane proton pump . Nature . 450 . 7172 . 1111–4 . December 2007 . 18075595 . 10.1038/nature06417 . 2007Natur.450.1111P . 4413142 .
  5. Gévaudant F, Duby G, von Stedingk E, Zhao R, Morsomme P, Boutry M . Expression of a constitutively activated plasma membrane -ATPase alters plant development and increases salt tolerance . Plant Physiol. . 144 . 4 . 1763–76 . August 2007 . 17600134 . 1949876 . 10.1104/pp.107.103762 .
  6. Haruta M, Burch HL, Nelson RB, etal . Molecular characterization of mutant Arabidopsis plants with reduced plasma membrane proton pump activity . J. Biol. Chem. . 285 . 23 . 17918–29 . June 2010 . 20348108 . 2878554 . 10.1074/jbc.M110.101733 . free .
  7. Palmgren MG, Sommarin M, Serrano R, Larsson C . Identification of an autoinhibitory domain in the C-terminal region of the plant plasma membrane -ATPase . J. Biol. Chem. . 266 . 30 . 20470–5 . October 1991 . 10.1016/S0021-9258(18)54948-6 . 1834646 . free .
  8. Morsomme P, de Kerchove d'Exaerde A, De Meester S, Thinès D, Goffeau A, Boutry M . Single point mutations in various domains of a plant plasma membrane -ATPase expressed in Saccharomyces cerevisiae increase -pumping and permit yeast growth at low pH . EMBO J. . 15 . 20 . 5513–26 . October 1996 . 10.1002/j.1460-2075.1996.tb00936.x . 8896445 . 452296 .
  9. Ekberg K, Palmgren MG, Veierskov B, Buch-Pedersen MJ . A novel mechanism of P-type ATPase autoinhibition involving both termini of the protein . J. Biol. Chem. . 285 . 10 . 7344–50 . March 2010 . 20068040 . 2844182 . 10.1074/jbc.M109.096123 . free .
  10. Svennelid F, Olsson A, Piotrowski M, et al. . Phosphorylation of Thr-948 at the C terminus of the plasma membrane -ATPase creates a binding site for the regulatory 14-3-3 protein . Plant Cell . 11 . 12 . 2379–91 . December 1999 . 10590165 . 144135 . 10.2307/3870962. 3870962 .
  11. Fuglsang AT, Visconti S, Drumm K, Jahn T, Stensballe A, Mattei B, Jensen ON, Aducci P, Palmgren MG . Binding of 14-3-3 protein to the plasma membrane -ATPase AHA2 involves the three C-terminal residues Tyr946-Thr-Val and requires phosphorylation of Thr947. . J Biol Chem . 274 . 51 . 36774–80 . December 1999 . 10593986 . 10.1074/jbc.274.51.36774. free .
  12. Palmgren MG . PLANT PLASMA MEMBRANE -ATPases: Powerhouses for Nutrient Uptake . Annu. Rev. Plant Physiol. Plant Mol. Biol. . 52 . 817–845 . June 2001 . 11337417 . 10.1146/annurev.arplant.52.1.817 .
  13. Sondergaard. Teis. Schulz. Alexander. Palmgren. Michael. September 2004. Energization of Transport Processes in Plants. Roles of the Plasma Membrane H+-ATPase. Plant Physiology. 136. 1. 2475–2482. 10.1104/pp.104.048231. 15375204. 523315. free.