Molecular dissection of the C-terminal regulatory domain of the plant plasma membrane H+-ATPase AHA2: mapping of residues that when altered give rise to an activated enzyme.

The plasma membrane H+-ATPase is a proton pump belonging to the P-type ATPase superfamily and is important for nutrient acquisition in plants. The H+-ATPase is controlled by an autoinhibitory C-terminal regulatory domain and is activated by 14-3-3 proteins which bind to this part of the enzyme. Alanine-scanning mutagenesis through 87 consecutive amino acid residues was used to evaluate the role of the C-terminus in autoinhibition of the plasma membrane H+-ATPase AHA2 from Arabidopsis thaliana. Mutant enzymes were expressed in a strain of Saccharomyces cerevisiae with a defective endogenous H+-ATPase. The enzymes were characterized by their ability to promote growth in acidic conditions and to promote H+ extrusion from intact cells, both of which are measures of plasma membrane H+-ATPase activity, and were also characterized with respect to kinetic properties such as affinity for H+ and ATP. Residues that when altered lead to increased pump activity group together in two regions of the C-terminus. One region stretches from K863 to L885 and includes two residues (Q879 and R880) that are conserved between plant and fungal H+-ATPases. The other region, incorporating S904 to L919, is situated in an extension of the C-terminus unique to plant H+-ATPases. Alteration of residues in both regions led to increased binding of yeast 14-3-3 protein to the plasma membrane of transformed cells. Taken together, our data suggest that modification of residues in two regions of the C-terminal regulatory domain exposes a latent binding site for activatory 14-3-3 proteins.

The 14-3-3 proteins associate with the plant plasma membrane H(+)-ATPase to generate a fusicoccin binding complex and a fusicoccin responsive system.

The plasma membrane H(+)-ATPase in higher plants has been implicated in nutrient uptake, phloem loading, elongation growth and establishment of turgor. Although a C-terminal regulatory domain has been identified, little is known about the physiological factors involved in controlling the activity of the enzyme. To identify components which play a role in the regulation of the plant H(+)-ATPase, a fusicoccin responsive yeast expressing Arabidopsis plasma membrane H(+)-ATPase AHA2 was employed. By testing the fusicoccin binding activity of yeast membranes, the C-terminal regulatory domain of AHA2 was found to be part of a functional fusicoccin receptor, a component of which was the 14-3-3 protein. ATP hydrolytic activity of AHA2 expressed in yeast internal membranes was activated by all tested isoforms of the 14-3-3 protein of yeast and Arabidopsis, but only in the presence of fusicoccin, and activation was prevented by a phosphoserine peptide representing a known 14-3-3 protein binding motif in Raf-1. The results demonstrate that the 14-3-3 protein is an activator molecule of the H(+)-ATPase and provides the first evidence of a protein involved in activation of plant plasma membrane H(+)-ATPase.

Modified plant plasma membrane H(+)-ATPase with improved transport coupling efficiency identified by mutant selection in yeast.

Transport across the plasma membrane is driven by an electrochemical gradient of H+ ions generated by the plasma membrane proton pump (H(+)-ATPase). Random mutants of Arabidopsis H(+)-ATPase AHA1 were isolated by phenotypic selection of growth of transformed yeast cells in the absence of endogenous yeast H(+)-ATPase (PMA1). A Trp-874-Leu substitution as well as a Trp-874 to Lys-935 deletion in the hydrophilic C-terminal domain of AHA1 conferred growth of yeast cells devoid of PMA1. A Trp-874-Phe substitution in AHA1 was produced gy site-directed mutagenesis. The modified enzymes hydrolyzed ATP at 200-500% of wild-type level, had a sixfold increase in affinity for ATP (from 1.2 to 0.2 mM; pH 7.0), and had the acidic pH optimum shifted towards neutral pH. AHA1 did not contribute significantly to H+ extrusion by transformed yeast cells. The different specifies of aha1, however, displayed marked differences in initial rates of net H+ extrusion and in their ability to sustain an electrochemical H+ gradient. These results provide evidence that Trp-874 plays an important role in auto-inhibition of the plant H(+)-ATPase and may be involved in controlling the degree of coupling between ATP hydrolysis and H+ pumping. Finally, these results demonstrate the usefulness of yeast as a generalized screening tool for isolating regulatory mutants of plant transporters.

Amino acid sequence of Coprinus macrorhizus peroxidase and cDNA sequence encoding Coprinus cinereus peroxidase. A new family of fungal peroxidases.

Sequence analysis and cDNA cloning of Coprinus peroxidase (CIP) were undertaken to expand the understanding of the relationships of structure, function and molecular genetics of the secretory heme peroxidases from fungi and plants. Amino acid sequencing of Coprinus macrorhizus peroxidase, and cDNA sequencing of Coprinus cinereus peroxidase showed that the mature proteins are identical in amino acid sequence, 343 residues in size and preceded by a 20-residue signal peptide. Their likely identity to peroxidase from Arthromyces ramosus is discussed. CIP has an 8-residue, glycine-rich N-terminal extension blocked with a pyroglutamate residue which is absent in other fungal peroxidases. The presence of pyroglutamate, formed by cyclization of glutamine, and the finding of a minor fraction of a variant form lacking the N-terminal residue, indicate that signal peptidase cleavage is followed by further enzymic processing. CIP is 40-45% identical in amino-acid sequence to 11 lignin peroxidases from four fungal species, and 42-43% identical to the two known Mn-peroxidases. Like these white-rot fungal peroxidases, CIP has an additional segment of approximately 40 residues at the C-terminus which is absent in plant peroxidases. Although CIP is much more similar to horseradish peroxidase (HRP C) in substrate specificity, specific activity and pH optimum than to white-rot fungal peroxidases, the sequences of CIP and HRP C showed only 18% identity. Hence, CIP qualifies as the first member of a new family of fungal peroxidases. The nine invariant residues present in all plant, fungal and bacterial heme peroxidases are also found in CIP. The present data support the hypothesis that only one chromosomal CIP gene exists. In contrast, a large number of secretory plant and fungal peroxidases are expressed from several peroxidase gene clusters. Analyses of three batches of CIP protein and of 49 CIP clones revealed the existence of only two highly similar alleles indicating less peroxidase polymorphism in C. cinereus strains than observed in plants and white-rot fungi.