Drosophila contains three genes that encode distinct isoforms of protein phosphatase 1

The sequences of two Drosophila and one rabbit protein phosphatase (PP) 1 catalytic subunits were determined from their cDNA. The sequence of Drosophila PP1 alpha 1 was deduced from a 2.2-kb cDNA purified from an embryonic cDNA library, while that for Drosophila PP1 beta was obtained from overlapping clones isolated from both a head cDNA library and an eye imaginal disc cDNA library. The gene for Drosophila PP1 alpha 1 is at 96A2-5 on chromosome 3 and encodes a protein of 327 amino acids with a calculated molecular mass of 37.3 kDa. The gene for Drosophila PP1 beta is localized at 9C1-2 on the X chromosome and encodes a protein of 330 amino acids with a predicted molecular mass of 37.8 kDa. PP1 alpha 1 shows 96% amino acid sequence identity to PP1 alpha 2 (302 amino acids), an isoform whose gene is located in the 87B6-12 region of chromosome 3 [Dombrádi, V., Axton, J. M., Glover, D.M. Cohen, P.T.W. (1989) Eur. J. Biochem. 183, 603-610]. PP1 beta shows 85% identity to PP1 alpha 1 and PP1 alpha 2 over the 302 homologous amino acids. These results demonstrate that at least three genes are present in Drosophila that encode different isoforms of PP1. Drosophila PP1 alpha 1 and PP1 beta show 89% amino acid sequence identity to rabbit PP1 alpha (330 amino acids) [Cohen, P.T.W. (1988) FEBS Lett. 232, 17-23] and PP1 beta (327 amino acids), respectively, demonstrating that the structures of both isoforms are among the most conserved proteins known throughout the evolution of the animal kingdom. The presence of characteristic structural differences between PP1 alpha and PP1 beta, which have been preserved from insects to mammals, implies that the alpha and beta isoforms may have distinct biological functions.     

Protein phosphatase 1beta is required for the maintenance of muscle attachments

Type 1 serine/threonine protein phosphatases (PP1) are important regulators of many cellular and developmental processes, including glycogen metabolism, muscle contraction, and the cell cycle [1] [2] [3] [4] [5]. Drosophila and humans both have multiple genes encoding PP1 isoforms [3] [6] [7]; each has one beta and several alpha isoform genes (alpha(1), alpha(2), alpha(3) in flies, alpha and gamma in humans; mammalian PP1beta is also known as PP1delta). The alpha/beta subtype differences are highly conserved between flies and mammals [6]. Though all these proteins are >85% identical to each other and have indistinguishable activities in vitro, we show here that the Drosophila beta isoform has a distinct biological role. We show that PP1beta9C corresponds to flapwing (flw), previously identified mutants of which are viable but flightless because of defects in indirect flight muscles (IFMs) [8]. We have isolated a new, semi-lethal flw allele that shows a range of defects, especially in muscles, which break away from their attachment sites and degenerate.     

Protein serine/threonine phosphatases; an expanding family

Five protein serine/threonine phosphatases (PP) have been identified by cloning cDNA from mammalian and Drosophila libraries. These novel enzymes, which have not yet been detected by the techniques of protein chemistry and enzymology, are termed PPV, PP2Bw, PPX, PPY and PPZ. The complete amino acid sequences of PPX, PPY and PPZ and an almost complete sequence of PPV are presented. In the catalytic domain PPV and PPX are more similar to PP2A (57-69% identity) than PP1 (45-49% identity), while PPY and PPZ are more similar to PP1 (66-68% identity) than PP2A (44% identity). The cDNA for PP2Bw encodes a novel Ca2+/calmodulin-dependent protein phosphatase only 62% identical to PP2B in the catalytic domain. Approaches for determining the cellular functions of these protein phosphatases are discussed.     

Differential distribution of the mRNA encoding two isoforms of the catalytic subunit of calcineurin in the rat brain.

The distribution of mRNAs encoding two distinct isoforms of the catalytic subunit of calmodulin-dependent protein phosphatase (calcineurin A), designated calcineurin A alpha and A beta, in the rat brain was examined by using Northern blots and in situ hybridization histochemistry. The mRNAs for calcineurin A alpha and A beta were both unevenly present in the brain and showed different distribution. The differential distribution between calcineurin A alpha and A beta messages suggests that the individual isoforms are involved in specialized neural functions.     

The neuronal actin-binding proteins,neurabin I and neurabin II,recruit specific isoforms of protein phosphatase-1 catalytic subunits

Neurabins are protein phosphatase-1 (PP1) targeting subunits that are highly concentrated in dendritic spines and post-synaptic densities. Immunoprecipitation of neurabin I and neurabin II/spinophilin from rat brain extracts sedimented PP1gamma1 and PP1alpha but not PP1beta. In vitro studies showed that recombinant peptides representing central regions of neurabins also preferentially bound PP1gamma1 and PP1alpha from brain extracts and associated poorly with PP1beta. Analysis of PP1 binding to chimeric neurabins suggested that sequences flanking a conserved PP1-binding motif altered their selectivity for PP1beta and their activity as regulators of PP1 in vitro. Assays using recombinant PP1 catalytic subunits and a chimera of PP1 and protein phosphatase-2A indicated that the C-terminal sequences unique to the PP1 isoforms contributed to their recognition by neurabins. Collectively, the results from several different in vitro assays established the rank order of PP1 isoform selection by neurabins to be PP1gamma1 > PP1alpha > PP1beta. This PP1 isoform selectivity was confirmed by immunoprecipitation of neurabin I and II from brain extracts from wild type and mutant PP1gamma null mice. In the absence of PP1gamma1, both neurabins showed enhanced association with PP1alpha but not PP1beta. These studies identified some of the structural determinants in PP1 and neurabins that together contribute to preferential targeting of PP1gamma1 and PP1alpha to the mammalian synapse.     

Critical role for protein phosphatase 2A heterotrimers in mammalian cell survival

The predominant forms of protein phosphatase 2A (PP2A), one of the major Ser/Thr phosphatases, are dimers of catalytic (C) and scaffolding (A) subunits and trimers with an additional variable regulatory subunit. In mammals, catalytic and scaffolding subunits are encoded by two genes each (alpha/beta), whereas three gene families (B, B', and B') with a total of 12 genes contribute PP2A regulatory subunits. We generated stable PC12 cell lines in which the major scaffolding Aalpha subunit can be knocked down by inducible RNA interference (RNAi) to study its role in cell viability. Aalpha RNAi decreased total PP2A activity as well as protein levels of C, B, and B' but not B' subunits. Inhibitor experiments indicate that monomeric C and B subunits are degraded by the proteosome. Knock-down of Aalpha triggered cell death by redundant apoptotic and non-apoptotic mechanisms because the inhibition of RNAi-associated caspase activation failed to stall cell death. PP2A holoenzymes positively regulate survival kinase signaling, because RNAi reduced basal and epidermal growth factor-stimulated Akt phosphorylation. RNAi-resistant Aalpha cDNAs rescued RNAi-induced loss of the C subunit, and Aalpha point mutants prevented regulatory subunit degradation as predicted from each mutant's binding specificity. In transient, stable, and stable-inducible rescue experiments, both wild-type Abeta and Aalpha mutants capable of binding to at least one family of regulatory subunits were able to delay Aalpha RNAi-induced death of PC12 cells. However, only the expression of wild-type Aalpha restored viability completely. Thus, heterotrimeric PP2A holoenzymes containing the Aalpha subunit and members of all three regulatory subunit families are necessary for mammalian cell viability.     

The amphioxus rab GDP-dissociation inhibitor (GDI) gene is neural-specific: implications for the evolution of chordate rab GDI genes.

The rab GDP-dissociation inhibitor (rab GDI) proteins are involved in the regulation of vesicle-mediated cellular transport. We isolated the amphioxus rab GDI gene, analyzed its expression during amphioxus development, and performed a phylogenetic analysis of the rab GDI family. In contrast to the two major rab GDI forms in mammals, the alpha and beta forms, there is only one rab GDI isoform in amphioxus. Our analysis indicates that the occurrence of the alpha and beta forms of rab GDI preceded the divergence of lineages leading to birds and mammals, and that the amphioxus rab GDI may have evolved directly from the common ancestor of both forms. While the mammalian rab GDI beta-genes are ubiquitously expressed, the rab GDI alpha genes are predominantly expressed in neural tissues. The expression analysis of the amphioxus rab GDI gene shows predominantly neural expression similar to that of the mammalian rab GDI alpha form, suggesting that the ancestral expression pattern of chordate rab GDI was neural. In addition, the chicken rab GDI beta-like gene also shows neural-specific expression, which indicates that the neural expression was retained in both early postduplication alpha and beta isoforms and that a novel function associated with ubiquitous expression may have evolved uniquely in mammals. These results reveal a likely scenario of functional divergence of the rab GDI genes after duplication of the ancestral gene. A similar pattern of evolution, in which one of the duplicated genes retained a role similar to that of the ancestral one while other genes were recruited into novel roles, was also observed in the analysis of chordate Otx and hedgehog genes. In the rab GDI, hedgehog, and Otx gene families, the gene retaining the ancestral role shows a lower rate of sequence evolution than its counterpart, which was recruited for a novel function.     

Alternative splicing generates two isoforms of the alpha 2 subunit of the inhibitory glycine receptor.

The inhibitory glycine receptor (GlyR) is a ligand-gated chloride channel protein which displays developmental heterogeneity in the mammalian central nervous system. Here we describe 2 novel cDNA variants of the rat GlyR alpha 2 subunit and demonstrate that alternative splicing generates these 2 isoforms. The deduced protein sequences (alpha 2A and alpha 2B) exhibit 99% identity with the previously characterized human alpha 2 subunit. In situ hybridization revealed expression of both alpha 2A and alpha 2B mRNAs in the prenatal rat brain, suggesting that these variant proteins may have a role in synaptogenesis. Heterologous expression in Xenopus oocytes showed that the more abundantly expressed alpha 2A subunit forms strychnine-sensitive ion channels which resemble human alpha 2 subunit GlyRs in their electrophysiological properties.     

Expression of human protein phosphatase-1 in Saccharomyces cerevisiae highlights the role of phosphatase isoforms in regulating eukaryotic functions

Human (PP1) isoforms, PP1alpha, PP1beta, PP1gamma1, and PP1gamma2, differ in primary sequences at N and C termini that potentially bind cellular regulators and define their physiological functions. The GLC7 gene encodes the PP1 catalytic subunit with >80% sequence identity to human PP1 and is essential for viability of Saccharomyces cerevisiae. In yeast, Glc7p regulates glycogen and protein synthesis, actin cytoskeleton, gene expression, and cell division. We substituted human PP1 for Glc7p in yeast to investigate the ability of individual isoforms to catalyze Glc7p functions. S. cerevisiae expressing human PP1 isoforms were viable. PP1alpha-expressing yeast grew more rapidly than strains expressing other isoforms. On the other hand, PP1alpha-expressing yeast accumulated less glycogen than PP1beta-or PP1gamma1-expressing yeast. Yeast expressing human PP1 were indistinguishable from WT yeast in glucose derepression. However, unlike WT yeast, strains expressing human PP1 failed to sporulate. Analysis of chimeric PP1alpha/beta subunits highlighted a critical role for their unique N termini in defining PP1alpha and PP1beta functions in yeast. Biochemical studies established that the differing association of PP1 isoforms with the yeast glycogen-targeting subunit, Gac1p, accounted for their differences in glycogen synthesis. In contrast to human PP1 expressed in Escherichia coli, enzymes expressed in yeast displayed in vitro biochemical properties closely resembling PP1 from mammalian tissues. Thus, PP1 expression in yeast should facilitate future structure-function studies of this protein serine/threonine phosphatase.     

Identification by molecular cloning of two cDNA sequences from the plant Brassica napus which are very similar to mammalian protein phosphatases-1 and -2A

Two clones encoding protein phosphatase (PP) catalytic subunits have been isolated from a Brassica napus cDNA library screened with rabbit muscle PP1 alpha and PP2A alpha cDNAs. The deduced protein sequences are very similar to those of mammalian PP1 alpha and PP2A alpha (72% and 79% overall identity, respectively) indicating that they are the plant homologues of PP1 alpha and PP2A alpha. This high degree of similarity provides a molecular explanation for the remarkable conservation of the catalytic and regulatory properties between animal and plant protein phosphatases and supports the concept that PP1 and PP2A may be the most highly conserved of known enzymes.     

Glucose and type 2A protein phosphatase regulate the interaction between catalytic and regulatory subunits of AMP-activated protein kinase

We have expressed in yeast the different subunits of AMP-activated protein kinase (AMPK) and, by using the two-hybrid system, we have found a glucose-regulated interaction between alpha 2 catalytic and gamma 1 regulatory subunits. This regulation was not affected by known regulators of the corresponding yeast orthologue, the SNF1 complex, such as Reg1 or Hxk2, but it was affected by deletion of regulatory subunits of yeast type 2A protein phosphatase (PP2A) complex. We have also found that Tpd3 and PR65 alpha, the corresponding yeast and mammalian A subunits of PP2A, interacted with AMPK alpha 2 both in yeast and mammals, respectively. This interaction occurred only through the regulatory domain of this subunit. These results suggested a direct involvement of PP2A complex in regulating the interaction between AMPK alpha 2 and gamma 1 in a glucose-dependent manner.     

Uniquely conserved non-translated regions are involved in generation of the two major transcripts of protein phosphatase 2Cbeta

Partial cDNAs of different isoforms of protein phosphatase 2Cbeta (PP2Cbeta or PPM1B) have been characterized in mammals. We disclose here the full cDNAs of two major PP2Cbeta isoforms from human, rat and mouse. These cDNAs (2.6 and 3.3 kb) are able to encode 53 kDa (PP2Cbetal) and 43 kDa (PP2Cbetas) polypeptides, respectively. The isoforms are co-expressed ubiquitously with the highest level in skeletal muscle, as assessed by Northern-blot analysis. Western and in situ analyses using monoclonal antibodies against PP2Cbeta confirmed the existence of two isoforms in the cytoplasm. Comparative sequence analysis revealed that both cDNAs consist of six exons with an alternate usage of the 3' exons that underlies the differences between them. The genomic structure of PP2Cbeta is similar to that of other PP2C paralogs and includes a non-coding first exon followed by a large intron and a large second exon that encoded most of the catalytic domain. Both variants of the ending exon include large non-coding regions. All non-translated regions (NTRs) are highly conserved between the orthologous genes, indicating their regulatory function. The 5'-NTR is long (379 bp), includes upstream start codons and is predicted to contain stable secondary structures. Such features inhibit translation initiation by the scanning mechanism. Introduction of this NTR element into a bi-luciferase expression-cassette enabled expression of the second cistron, suggesting that it might serve as an internal ribosome entry site, or it contains a cryptic promoter. Overexpression of PP2Cbeta under CMV-promoter in 293 cells led to cell-growth arrest or cell death.     

Proteomic characterization of protein phosphatase complexes of the mammalian nucleus

Our knowledge of the serine/threonine protein phosphatases of the mammalian nucleus is limited compared with their cytosolic counterparts. Microcystin-Sepharose chromatography and mass spectrometry were utilized to affinity purify and identify protein phosphatase-associated proteins from isolated rat liver nuclei. Far Western analysis with labeled protein phosphatase 1 (PP1) showed that many more PP1 binding proteins exist in the nucleus than were previously demonstrated. Mass spectrometry confirmed the presence in the nucleus of the mammalian PP1 isoforms alpha1, alpha2, beta, and gamma1, plus the Aalpha and several of the B and B' subunits that are complexed to PP2A. Other proteins enriched on the microcystin matrix include the spliceosomal proteins known as the U2 snRNPs SAP145 and SAP155 and the U5 snRNPs p116 and p200, myosin heavy chain, and a nuclear PP1 myosin-targeting subunit related to M110. The putative RNA binding protein ZAP was also established as a nuclear PP1 binding protein using the criteria of co-purification with PP1 on microcystin-Sepharose, co-immunoprecipation, binding PP1 in an overlay assay, and presence of a putative PP1 binding site (KKRVRWAD). These results further support a key role for protein phosphatases in several nuclear functions, including the regulation of pre-mRNA splicing.     

Parallel purification of three catalytic subunits of the protein serine/threonine phosphatase 2A family (PP2A(C), PP4(C), and PP6(C)) and analysis of the interaction of PP2A(C) with alpha4 protein

The protein serine/threonine phosphatase (PP) type 2A family consists of three members: PP2A, PP4, and PP6. Specific rabbit and sheep antibodies corresponding to each catalytic subunit, as well as a rabbit antibody recognizing all three subunits, were utilized to examine the expression of these enzymes in select rat tissue extracts. PP2A, PP4, and PP6 catalytic subunits (PP2A(C), PP4(C), and PP6(C), respectively) were detected in all rat tissue extracts examined and exhibited some differences in their levels of expression. The expression of alpha4, an interacting protein for PP2A family members that may function downstream of the target of rapamycin (Tor), was also examined using specific alpha4 sheep antibodies. Like the phosphatase catalytic subunits, alpha4 was ubiquitously expressed with particularly high levels in the brain and thymus. All three PP2A family members, but not alpha4, bound to the phosphatase affinity resin microcystin-Sepharose. The phosphatase catalytic subunits were purified to apparent homogeneity (PP2A(C) and PP4(C)) or near homogeneity (PP6(C)) from bovine testes soluble extracts following ethanol precipitation and protein extraction. In contrast to PP2A(C), PP4(C) and PP6(C) exhibited relatively low phosphatase activity towards several substrates. Purified PP2A(C) and native PP2A in cellular extracts bound to GST-alpha4, and co-immunoprecipitated with endogenous alpha4 and ectopically expressed myc-tagged alpha4. The interaction of PP2A(C) with alpha4 was unaffected by rapamycin treatment of mammalian cells; however, protein serine/threonine phosphatase inhibitors such as okadaic acid and microcystin-LR disrupted the alpha4/PP2A complex. Together, these findings increase our understanding of the biochemistry of alpha4/phosphatase complexes and suggest that the alpha4 binding site within PP2A may include the phosphatase catalytic domain.     

Multiple isoforms of a protein kinase C inhibitor (KCIP-1/14-3-3) from sheep brain. Amino acid sequence of phosphorylated forms.

A potent inhibitor of protein kinase C (PKC), inhibitor protein-1 (KCIP-1), isolated from sheep brain has been shown to consist of eight isoforms by reverse-phase HPLC. Direct protein sequence analysis has revealed these to be the same as those of 14-3-3 protein, described as an activator of tyrosine and tryptophan hydroxylases involved in neurotransmitter biosynthesis. The N-termini of KCIP-1 isoforms were shown to be acetylated, and secondary structure predictions revealed a high degree of alpha-helix with an amphipathic nature. KCIP-1 showed no inhibitory activity towards protein kinase M (the catalytic fragment of PKC) and had no effect on the activities of three other protein kinases, cAMP-dependent protein kinase, Ca2+/calmodulin-dependent protein kinase II and casein kinase 2. Four forms of KCIP-1 were shown to be substrates for PKC in vitro, but none were phosphorylated by the other protein kinases mentioned above.     

Cloning,characterization and expression of two alternatively splicing isoforms of Ca2+/calmodulin-dependent protein kinase I gamma in the rat brain

Ca2+/calmodulin-dependent protein kinase I (CaMKI), originally identified as a protein kinase phosphorylating synapsin I, has been shown to constitute a family of closely related isoforms (alpha, beta and gamma). Here, we have isolated and determined the complete primary structures of two alternatively splicing isoforms of CaMKI termed CaMKI gamma 1 and -gamma 2. CaMKI gamma 1 and -gamma 2 contain an identical N-terminal catalytic domain with different C-terminal regions due to the deletion of the 425-bp nucleotide sequence of CaMKI gamma 1 in CaMKI gamma 2. In vitro kinase assay has demonstrated the marked enhancement of the Ca2+/CaM-dependent activity of CaMKI gamma 1 by the preincubation with Ca2+/calmodulin-dependent protein kinase kinase (CaMKK), but no significant activation of CaMKI gamma 2. Northern blot analysis has demonstrated the predominant expression of CaMKI gamma in the brain. RT-PCR analysis has revealed similar expression patterns between CaMKI gamma 1 and CaMKI gamma 2 in various brain regions. In situ hybridization analysis has demonstrated that CaMKI gamma mRNA is expressed in a distinct pattern from other isoforms of CaMKI with predominant expression in some restricted brain regions such as the olfactory bulb, hippocampal pyramidal cell layer of CA3, central amygdaloid nuclei, ventromedial hypothalamic nucleus and pineal gland. In the primary hippocampal neurons and NG108-15 cells, transfected CaMKI gamma 1 and -gamma 2 are localized primarily in the cytoplasm and neurites but not in the nucleus. These findings suggest that both isoforms of CaMKI gamma may be involved in Ca2+ signal transduction in the cytoplasmic compartment of certain neuronal population.