The B″ regulatory subunit of protein phosphatase 2A mediates the dephosphorylation of rice retinoblastoma-related protein-1.

The phosphorylation of plant retinoblastoma-related (RBR) proteins by cyclin-dependent kinases (CDKs) is well documented, but the counteracting phosphatases have not been identified yet. We report here that rice retinoblastoma-related protein-1 (OsRBR1) interacted with the B″ subunit of rice protein phosphatase 2A (OsPP2A B″) and underwent reversible phosphorylation during the cell division cycle. The OsRBR1-OsPP2A B" association required B domain in OsRBR1 and the C-terminal region of OsPP2A B″. We found by immunoprecipitation that OsPP2A B″, OsPP2A catalytic subunit subtype II, PSTAIRE-type CDK and OsRBR1 were in the same protein complex, indicating a physical association between the phosphatase, the kinase and their common substrate. OsPP2A B″ contains three predicted CDK phosphorylation sites: Ser95, Ser102 and Ser119. The in vitro phosphorylation of Ser95 and Ser119 with PSTAIRE-kinases was verified by mass spectrometry. We generated a series of phosphorylation site mutants to mimic the dephosphorylated or phosphorylated states of OsPP2A B″, and confirmed that all of the three predicted sites can be phosphorylated. Yeast two-hybrid experiments suggested that the phosphorylation of OsPP2A B″ promoted the formation of the OsPP2A holoenzyme. A triple phosphorylation mimicking OsPP2A B″ mutant containing holoenzyme showed higher activity in phosphatase assays. Our data collectively show that the phosphatase activity of OsPP2A against OsRBR1 is regulated by the phosphorylation of its B″ regulatory subunit. However, the analysis of the effect of okadaic acid, a phosphatase inhibitor, in rice cell suspension cultures revealed that the dephosphorylation of OsRBR1 was completely inhibited only by high dose (300 nM) of the okadaic acid during the cell cycle progression. Therefore the role of the protein phosphatase 1 should be considered as an additional post translational regulatory component of RBR protein function in higher plants.

Protein phosphatase CaPpz1 is involved in cation homeostasis, cell wall integrity and virulence of Candida albicans.

The opportunistic pathogen Candida albicans has a single protein phosphatase Z (PPZ) candidate gene termed CaPPZ1, which shows significant allele variability. We demonstrate here that bacterially expressed CaPpz1 protein exhibits phosphatase activity which can be inhibited by recombinant Hal3, a known inhibitor of Saccharomyces cerevisiae Ppz1. Site-directed mutagenesis experiments based on natural polymorphisms allowed the identification of three amino acid residues that affect enzyme activity or stability. The expression of CaPPZ1 in ppz1 S. cerevisiae and pzh1 Schizosaccharomyces pombe cells partially rescued the salt and caffeine phenotypes of the deletion mutants. CaPpz1 also complemented the slt2 S. cerevisiae mutant, which is crippled in the mitogen-activated protein (MAP) kinase that mediates the cell wall integrity signalling pathway. Collectively, our results suggest that the orthologous PPZ enzymes have similar but not identical functions in different fungi. The deletion of the CaPPZ1 gene in C. albicans resulted in a mutant that was sensitive to salts such as LiCl and KCl, to caffeine, and to agents that affect cell wall biogenesis such as Calcofluor White and Congo red, but was tolerant to spermine and hygromycin B. Reintegration of the CaPPZ1 gene into the deletion mutant alleviated all of the mutant phenotypes tested. Thus CaPpz1 is involved in cation homeostasis, cell wall integrity and the regulation of the membrane potential of C. albicans. In addition, the germ tube growth rate, and virulence in the BALB/c mouse model, were reduced in the null mutant, suggesting a novel function for CaPpz1 in the yeast to hypha transition that may have medical relevance.

Protein phosphatase Z modulates oxidative stress response in fungi.

The genome of the filamentous fungus Aspergillus nidulans harbors the gene ppzA that codes for the catalytic subunit of protein phosphatase Z (PPZ), and the closely related opportunistic pathogen Aspergillus fumigatus encompasses a highly similar PPZ gene (phzA). When PpzA and PhzA were expressed in Saccharomyces cerevisiae or Schizosaccharomyces pombe they partially complemented the deleted phosphatases in the ppz1 or the pzh1 mutants, and they also mimicked the effect of Ppz1 overexpression in slt2 MAP kinase deficient S. cerevisiae cells. Although ppzA acted as the functional equivalent of the known PPZ enzymes its disruption in A. nidulans did not result in the expected phenotypes since it failed to affect salt tolerance or cell wall integrity. However, the inactivation of ppzA resulted in increased sensitivity to oxidizing agents like tert-butylhydroperoxide, menadione, and diamide. To demonstrate the general validity of our observations we showed that the deletion of the orthologous PPZ genes in other model organisms, such as S. cerevisiae (PPZ1) or Candida albicans (CaPPZ1) also caused oxidative stress sensitivity. Thus, our work reveals a novel function of the PPZ enzyme in A. nidulans that is conserved in very distantly related fungi.

The polymorphism of protein phosphatase Z1 gene in Candida albicans.

The gene of protein phosphatase Z1 (CaPPZ1) that codes a fungus specific regulatory enzyme was investigated in Candida albicans. After cloning and sequencing CaPPZ1 we revealed the heterozygous nature of the ATCC 10231 reference strain, and identified two new alleles termed CaPPZ1-2 and CaPPZ1-3. The genetic polymorphism in CaPPZ1 was extended by finding a fourth allele CaPPZ1-4 in a clinical isolate. Single nucleotide replacements and short in/del mutations were identified in the gene, some of which resulted in amino acid changes in the protein. The analysis of the hypervariable 3'-noncoding gene region in 27 DNA sequences obtained from reference strains and clinical samples confirmed the presence of four distinct DNA sequence-groups that correspond to the four main alleles of CaPPZ1. In addition to the allelic combinations, we detected individual mutations elevating genetic variability of the opportunistic pathogen. We utilized the hypervariable gene region for genotyping C. albicans in clinical isolates by sequencing the cloned amplified region, by direct sequencing of the PCR products, or by RFLP analysis. The comparison of the genotypes of the strains originating from different body parts of the same patient proved to be useful in delineating the origin of the infection.

Arabidopsis PPP family of serine/threonine phosphatases.

Serine/threonine-specific phosphoprotein phosphatases (PPPs) are ubiquitous enzymes in all eukaryotes, but their regulatory functions are largely unknown in higher plants. The Arabidopsis genome encodes 26 PPP catalytic subunits related to type 1, type 2A and so-called novel phosphatases, including four plant-specific enzymes carrying large N-terminal kelch-domains, but no apparent homologue of the PP2B family. The catalytic subunits of PPPs associate with regulatory protein partners that target them to well defined cellular locations and modulate their activity. Recent studies of phosphatase partners and their interactions have directed attention again to functional dissection of plant PPP families, and highlight their intriguing roles in the regulation of metabolism, cell cycle and development, as well as their roles in light, stress and hormonal signalling.

Dissection of the regulatory role for the N-terminal domain in Candida albicans protein phosphatase Z1.

The novel type, fungus specific protein phosphatase Z1 of the opportunistic pathogen, Candida albicans (CaPpz1) has several important physiological roles. It consists of a conserved C-terminal catalytic domain and a variable, intrinsically disordered, N-terminal regulatory domain. To test the function of these domains we modified the structure of CaPpz1 by in vitro mutagenesis. The two main domains were separated, four potential protein binding regions were deleted, and the myristoylation site as well as the active site of the enzyme was crippled by point mutations G2A and R262L, respectively. The in vitro phosphatase activity assay of the bacterially expressed recombinant proteins indicated that the N-terminal domain was inactive, while the C-terminal domain became highly active against myosin light chain substrate. The deletion of the N-terminal 1-16 amino acids and the G2A mutation significantly decreased the specific activity of the enzyme. Complementation of the ppz1 Saccharomyces cerevisiae deletion mutant strain with the different CaPpz1 forms demonstrated that the scission of the main domains, the two point mutations and the N-terminal 1-16 deletion rendered the phosphatase incompetent in the in vivo assays of LiCl tolerance and caffeine sensitivity. Thus our results confirmed the functional role of the N-terminal domain and highlighted the significance of the very N-terminal part of the protein in the regulation of CaPpz1.

The histone phosphatase inhibitory property of plant nucleosome assembly protein-related proteins (NRPs).

SET/I(2)(PP2A), a member of the family of nucleosome assembly proteins (NAPs), has been previously described as a multifunctional protein inhibiting protein phosphatase 2A (PP2A)-mediated histone H3((pSer10)) dephosphorylation during the heat shock response in animal cells. In the present work we demonstrate that its plant orthologs, designated as NAP-related proteins (NRPs), have a similar in vitro biochemical activity and interact with PP2A and histone H3((pSer10))in vivo. Although heat shock gene promoters were found to be associated with histone H3((pSer10))-marked chromatin following a high temperature treatment, heat shock gene expression was not affected in NRP-deficient mutant Arabidopsis thaliana (L.) plantlets. These observations indicate that NRPs are potential regulators of histone dephosphorylation in plants, but they are dispensable for gene expression reorganization in response to heat shock.