Relationships among the subunits of the high molecular weight proteinase,macropain (proteasome)

An analysis of the subunits of the high molecular weight proteinase, macropain (multicatalytic proteinase or proteasome) from human erythrocytes has been conducted using N-terminal amino acid sequencing, gel electrophoresis and reverse-phase peptide mapping. This analysis provided evidence for the existence of 13 subunits of different primary structure. Five subunits were susceptible to the Edman degradation and yielded unique N-terminal sequences. Similarities among these sequences, however, indicated that the subunits are homologues. Two-dimensional gel electrophoresis discriminated 10 major components, which included two of the subunits for which N-terminal sequences had been determined and eight N-terminally blocked subunits. Tryptic peptide mapping indicated that all 10 of these components have a different amino acid sequence. Tryptic peptides from some of the subunits were subjected to amino acid sequence analysis, and the data indicated that all the subunits tested in this way are related by common ancestry. The data suggest that at least nine of the total of 13 subunits are encoded by members of the same gene family; the remaining four subunits have not yet been investigated in sufficient detail to establish their relationships. No evidence for a close relationship with any previously investigated proteinase family has been found. Finally, through a comparison of the ‘latent’ and ‘active’ forms of macropain, the study established a close similarity in the subunit composition of these catalytically very different species, although proteolytic degradation of selected subunits appears in the active form of the enzyme.     

Purification and characterization of a high molecular weight proteinase (macropain) from human erythrocytes

An alkaline proteinase, previously identified in rat liver and heart, has been purified from the soluble fraction of human erythrocytes. The proteinase has an apparent molecular weight of 600 000 and is composed of eight subunits with molecular weights ranging from 32 000 to 21 000. The proteinase degrades both protein and synthetic peptide substrates with a broad pH optimum of 7.5-11.0. Among the synthetic peptides tested, tripeptides with arginine at the P1 position (e.g. Z-Val-Leu-Arg-4-methoxy-2-napthylamine and Boc-Leu-Gly-Arg-4-methylcoumarin-7-amide) are particularly good substrates. The proteinase appears to be sulfhydryl-dependent and is inhibited completely by mersalyl acid and by hemin; inhibitors of serine and metallo-type proteinases have no effect on proteinase activity. Interestingly, a variety of other proteinase inhibitors such as leupeptin, chymostatin and N-ethylmaleimide failed to completely inhibit protein-hydrolyzing activities of the enzyme. These results indicate that these activities may be accounted for by at least two different catalytic sites. Proteinase activity is stable in the presence of 1 M urea, 0.5% Triton X-100 or 0.03% SDS and is not affected by ATP. Based on the high molecular weight and sulfhydryl-dependence, we have named this proteinase macropain.     

PA28 subunits of the mouse proteasome: primary structures and chromosomal localization of the genes

 The 20S proteasome is a multi-subunit protease responsible for the production of peptides presented by major histocompatibility complex (MHC) class I molecules. Recent evidence indicates that an interferon-γ (IFN-γ)-inducible PA28 activator complex enhances the generation of class I binding peptides by altering the cleavage pattern of the proteasome. In the present study, we determined the primary structures of the mouse PA28 α- and β-subunits. The deduced amino acid sequences of the α- and β-subunits were 49% identical. We also determined the primary structure of the mouse PA28 γ-subunit (Ki antigen), a protein of unknown function structurally related to the α- and β-subunits. The amino acid sequence identity of the γ-subunit to the α- and β-subunits was 40% and 32%, respectively. Interspecific backcross mapping showed that the mouse genes coding for the α- and β-subunits (designated Psme1 and Psme2, respectively) are tightly linked and map close to the Atp5g1 locus on chromosome 14. Thus, unlike the LMP2 and LMP7 subunits, the IFN-γ-inducible subunits of PA28 are encoded outside the MHC. The gene coding for the γ-subunit (designated Psme3) was mapped to the vicinity of the Brca1 locus on chromosome 11. A computer search of the DNA databases identified a γ-subunit-like protein in ticks and Caenorhabditis elegans, the organisms with no adaptive immune system. It appears that the IFN-γ-inducible α- and β-subunits emerged by gene duplication from a γ-subunit-like precursor. Received: 11 March 1997     

The NH2-terminal residues of rat liver proteasome (multicatalytic proteinase complex) subunits, C2, C3 and C8, are N alpha-acetylated

Rat liver proteasome (multicatalytic proteinase complex) is a 20S-ring shaped particle having a molecular mass of 750 kDa, and is composed of at least 13 non-identical components ranging from 21 to 31 kDa in size. We found here that the NH2-terminal residues of all the known 13 components, except for C5, are not reactive to phenylisothiocyanate. Among them, components C2, C3 and C8 are blocked in their NH2-termini with N alpha-acetyl-Met, N alpha-acetyl-Ala, and N alpha-acetyl-Ser, respectively. The NH2-terminal portions of C2, C3, and C8 exhibit sequence similarity to one another, but that of the non-blocked component C5 differs from those of C2, C3, and C8.     

Degradation of oxidized insulin B chain by the multiproteinase complex macropain (proteasome)

The peptides generated from the degradation of the oxidized B chain of bovine insulin by the multiproteinase complex macropain (proteasome) have been analyzed by reverse-phase peptide mapping and identified by N-terminal amino acid sequencing and composition analysis. Six of the 29 peptide bonds in the insulin B chain were found to be rapidly cleaved by macropain. The catalytic center that cleaves the Gln4-His5 bond could be distinguished from the center or centers that cleave the other preferred bonds by its specific susceptibility to inhibition by leupeptin, antipain, chymostatin, and pentamidine, suggesting that macropain utilizes at least two distinct catalytic centers for the degradation of this model polypeptide. The same effectors simultaneously enhance the rate of cleavage at the other susceptible sites in insulin B. The quantitative characteristics of this effect indicate that different catalytic centers of the complex may be functionally coupled, possibly by an allosteric mechanism or possibly by a mechanism in which binding to the catalytic centers is preceded by a rate-limiting binding of the substrate to a site or sites on the enzyme distinct from the catalytic centers. The kinetics of insulin B chain degradation indicate that macropain can catalyze sequential hydrolysis of peptide bonds in a single substrate molecule via a reaction pathway that involves channeling of peptide intermediates between different catalytic centers within the multienzyme complex. This capacity for channeling may confer potential physiological advantages of increasing the efficiency of amino acid recycling and reducing the pool sizes of peptide intermediates that are generated during the degradation of polypeptides in the intracellular milieu.     

Purification and characterization of a protein inhibitor of the 20S proteasome (macropain).

An inhibitory protein for the 20S proteasome (also known as macropain, the multicatalytic proteinase complex and 20S proteinase) has been purified from bovine red blood cells. The inhibitor has an apparent molecular weight of 31,000 on SDS-PAGE and appears to form multimers under nondenaturing conditions. This protein inhibited all three of the putatively distinct catalytic activities of proteasome A (the active form of the proteinase) characterized by the hydrolysis of synthetic peptides such as Z-VLR-MNA, Z-GGL-AMC or Suc-LLVY-AMC and Z-LLE-beta NA. The inhibitor also prevented the hydrolysis of large protein substrates such as casein, lysozyme and bovine serum albumin. Proteasome L (the latent form of the proteinase) does not degrade these large protein substrates, but does hydrolyze the three synthetic peptides at rates similar to those by proteasome A. The inhibitor inhibited only two of these peptidase activities of proteasome L (hydrolysis of Z-GGL-AMC and of Z-LLE-beta NA or Suc-LLVY-AMC); it had no effect on the hydrolysis of Z-VLR-MNA. The inhibitor was specific for inhibition of the proteasome and had no effect on the activity of any other proteinase tested including trypsin, chymotrypsin, papain, subtilisin and both isoforms of calpain. Kinetic analysis indicates that the inhibitor interacted with the proteasome by a mechanism involving tight-binding. Because the proteasome appears to be a key component of the ATP/ubiquitin-dependent pathway of intracellular protein degradation, the inhibitor may represent an important regulatory protein of this pathway.     

Identification, purification, and characterization of a protein activator (PA28) of the 20 S proteasome (macropain).

A protein that greatly stimulates the multiple peptidase activities of the 20 S proteasome (also known as macropain, the multicatalytic protease complex, and 20 S protease) has been purified from bovine red blood cells and from bovine heart. The activator protein was a single polypeptide with an apparent molecular weight of 28,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and had a native molecular weight of approximately 180,000. This protein, which we have termed PA28, regulated all three of the putatively distinct peptidase activities displayed by each of two functionally different forms of the proteasome. This regulation usually included both an increase in the maximal reaction velocity and a decrease in the concentration of substrate required for half-maximal velocity and indicated that PA28 acted as a positive allosteric effector of the proteasome. PA28 failed, however, to stimulate the hydrolysis of large protein substrates such as casein and lysozyme. These results suggested that the hydrolysis of protein substrates occurred at a site or sites distinct from those that hydrolyzed small peptides and that the regulation of the two processes could be uncoupled. Evidence for direct binding of PA28 to the proteasome was obtained by glycerol density gradient centrifugation. PA28 may play an important regulatory role in intracellular proteolytic pathways mediated by the proteasome.     

The catalytic and the RNA subunits of human telomerase are required to immortalize equid primary fibroblasts

Many human primary somatic cells can be immortalized by inducing telomerase activity through the exogenous expression of the human telomerase catalytic subunit (hTERT). This approach has been extended to the immortalization of cell lines from several mammals. Here, we show that hTERT expression is not sufficient to immortalize primary fibroblasts from three equid species, namely donkey, Burchelli’s zebra and Grevy’s zebra. In vitro analysis of a reconstituted telomerase composed by hTERT and an equid RNA component of telomerase (TERC) revealed a low activity of this enzyme compared to human telomerase, suggesting a low compatibility of equid and human telomerase subunits. This conclusion was also strengthened by comparison of human and equid TERC sequences, which revealed nucleotide differences in key regions for TERC and TERT interaction. We then succeeded in immortalizing equid fibroblasts by expressing hTERT and hTERC concomitantly. Expression of both human telomerase subunits led to telomerase activity and telomere elongation, indicating that human telomerase is compatible with the other equid telomerase subunits and proteins involved in telomere metabolism. The immortalization procedure described herein could be extended to primary cells from other mammals. The availability of immortal cells from endangered species could be particularly useful for obtaining new information on the organization and function of their genomes, which is relevant for their preservation.     

Molecular cloning of cDNAs for rat proteasomes: deduced primary structures of four other subunits.

Proteasomes (multi-protease complexes) are composed of approximately 15 non-identical subunits of similar sizes (molecular weight = 21-32 kDa), but different charges (isoelectric point = 4-9). Previously, we deduced the primary structures of 6 subunits of rat proteasomes by recombinant DNA techniques. In this paper we report the nucleotide sequences of 4 other subunits, rIOTA, rZETA, rDELTA, and rRING12, determined from cDNA clones isolated by screening a rat H4TG hepatoma cell cDNA library with the cDNAs of their human counterparts as probes. The polypeptides deduced from their nucleotide sequences consisted of 246, 241, 202, and 219 amino acid residues with calculated molecular weights of 27,399, 26,391, 21,649, and 23,324, and calculated isoelectric points of 6.37, 4.65, 4.84, and 4.70, respectively. These results and previous findings indicate that the primary structures of the subunits of rat proteasomes show considerably high inter-subunit homology, but can be classified into apparently distinct sub-groups, suggesting that rat proteasome genes form a multi-gene family with the same evolutionary origin, but have diverged during evolution to acquire possibly subunit-specific functions.     

小麦高分子量谷蛋白亚基及其基因的研究进展

主要介绍了小麦高分子量谷蛋白亚基（HMW－GS）及其基因的研究进展情况,目前,转基因小麦的技术已经逐渐成熟,由于分子生物学领域分子标记技术的迅速发展,尤其是PCR技术的广泛应用,为实现外源优良储藏蛋白基因导入改良品种提供了可能,利用已知小麦品种的基因序列设计引物,从众多的未知小麦品种中扩增出新基因加以研究并做外源优质HMW－GS基因的转入已成为一种趋势。     

The human connexin gene family of gap junction proteins: distinct chromosomal locations but similar structures.

Connexins are protein subunits that constitute gap junction channels. Two members of this gene family, connexin43 (Cx43) and connexin32 (Cx32), are abundantly expressed in the heart and liver, respectively. Human genomic DNA analysis revealed the presence of two loci for Cx43: an expressed gene and a processed pseudogene. The expressed gene (GJA1) was mapped to human chromosome 6 and the pseudogene (GJA1P) to chromosome 5. To determine whether Cx32 was linked to Cx43, somatic cell hybrids were analyzed by polymerase chain reaction and hybridization, resulting in the assignment of the gene for Cx32 (GJB1) to the X chromosome at Xp11----q22. Comparison of the structures of connexin genes suggests that members of this multigene family arose from a single precursor, but evolved to distinct chromosomal locations.     

The proteasome activator 11 S REG or PA28: chimeras implicate carboxyl-terminal sequences in oligomerization and proteasome binding but not in the activation of specific proteasome catalytic subunits

The REG homologs, alpha, beta and gamma, activate mammalian proteasomes in distinct ways. REGalpha and REGbeta activate the trypsin-like, chymotrypsin-like and peptidylglutamyl-preferring active sites, whereas REGgamma only activates the proteasome's trypsin-like subunit. The three REG homologs differ in carboxyl-terminal sequences that are located next to activation loops on their proteasome binding surface. To assess the importance of these carboxyl-terminal sequences in the activation of specific proteasome beta catalytic subunits, we characterized chimeras in which 8 or 12 residues were exchanged among the three proteins. Like the wild-type molecule, REGalpha chimeras activated all three proteasome catalytic subunits regardless of the carboxyl-terminal sequence. However, REGalpha-beta chimeras activated the proteasome at lower concentrations than wild-type REGalpha and higher levels of REGalpha-gamma chimeras were needed for maximal activation because exchanged carboxyl-terminal sequences can stabilize (REGalpha-beta) or destabilize (REGalpha-gamma) the REGalpha heptamer. REGgamma chimeras were equivalent to REGgamma in their activation properties, but they bound the proteasome less tightly than the wild-type molecule. REGbeta chimeras also bound the proteasome more weakly than wild-type REGbeta and were virtually unable to activate it. Our findings demonstrate that the carboxyl-terminal sequences of REG subunits can affect heptamer stability and proteasome affinity, but they do not determine which proteasome beta subunits become activated.     

The alpha 1-alpha 6 subunits of integrins are characteristically expressed in distinct segments of developing and adult human nephron

We studied the distribution of the alpha 1-alpha 6 subunits of beta 1 integrins in developing and adult human kidney using a panel of mAbs in indirect immunofluorescence microscopy. Uninduced mesenchyme displayed a diffuse immunoreactivity for only the alpha 1 integrin subunit. At the S-shaped body stage of nephron development, several of the alpha subunits were characteristically expressed in distinct fetal nephron segments, and the pattern was retained also in the adult nephron. Thus, the alpha 1 subunit was characteristically expressed in mesangial and endothelial cells, the alpha 2 in glomerular endothelium and distal tubules, the alpha 3 in podocytes, Bowman's capsule, and distal tubules, and the alpha 6 subunit basally in all tubules, and only transiently in podocytes during development. Unlike the alpha 3 and alpha 6 subunits, the alpha 2 subunit displayed an overall cell surface distribution in distal tubules. It was also distinctly expressed in glomerular endothelia during glomerulogenesis. The beta 4 subunit was expressed only in fetal collecting ducts, and hence the alpha 6 subunit seems to be complexed with the beta 1 rather than beta 4 subunit in human kidney. Of the two fibronectin receptor alpha subunits, alpha 4 and alpha 5, only the latter was expressed, confined to endothelia of developing and adult blood vessels, suggesting that these receptor complexes play a minor role during nephrogenesis. The present results suggest that distinct integrins play a role during differentiation of specific nephron segments. They also indicate that alpha 3 beta 1 and alpha 6 beta 1 integrin complexes may function as basement membrane receptors in podocytes and tubular epithelial cells.     

Phylogenic relationships of the amino acid sequences of prosome (proteasome, MCP) subunits

Prosomes [or proteasomes, Multi-Catalytic Proteinase (MCP)] are multisubunit protein complexes, found from archaebacteria to man, the structure of which (a 4-layer cylinder) is remarkably conserved. They were first observed as subcomplexes of untranslated mRNP, and then as a multicatalytic proteinase with several proteolytic activities. A number of sequences from subunits of these complexes are now available. Analysis of the sequences shows that these subunits are evolutionarily related, and reveals three highly conserved amino acid stretches. Based on a phylogenic approach, we propose to classify the sequenced subunits into 14 families, which fall into two superfamilies, of the - and -type. These data, together with several recently published observations, suggest that some subunits may be interchangeable within the complexes, which would thus constitute a population of heterogenous particles.     

Distinct primary structures, ligand-binding properties and tissue-specific expression of four human muscarinic acetylcholine receptors.

To investigate the molecular basis for the diversity in muscarinic cholinergic function, we have isolated the genes encoding the human M1 and M2 muscarinic receptors (mAChR) as well as two previously undiscovered mAChR subtypes, designated HM3 and HM4. The amino acid sequence of each subtype reflects a structure consisting of seven, highly conserved transmembrane segments and a large intracellular region unique to each subtype, which may constitute the ligand-binding and effector-coupling domains respectively. Significant differences in affinity for muscarinic ligands were detected in individual mAChR subtypes produced by transfection of mammalian cells. Each subtype exhibited multiple affinity states for agonists; differences among subtypes in the affinities and proportions of such sites suggest the capacity of mAChR subtypes to interact differentially with the cellular effector-coupling apparatus. Subtype-specific mRNA expression was observed in the heart, pancreas and a neuronal cell line, indicating that the regulation of mAChR gene expression contributes to the differentiation of cholinergic activity.     

Catalytic activities of the 20 S proteasome, a multicatalytic proteinase complex

The proteasome, a multisubunit, multicatalytic proteinase complex, is attracting growing attention as the main intracellular, extralysosomal, proteolytic system involved in ubiquitin-(Ub) dependent and Ub-independent intracellular proteolysis. Its involvement in the mitotic cycle, and control of the half-life of most cellular proteins, functions absolutely necessary for cell growth and viability, make it an attractive target for researchers of intracellular metabolism and an important target for pharmacological intervention. The proteasome belongs to a new mechanistic class of proteases, the N-terminal nucleophile hydrolases, where the N-terminal threonine residue functions as the nucleophile. This minireview focuses on the three classical catalytic activities of the proteasome, designated chymotrypsin-like, trypsin-like, and peptidyl-glutamyl-peptide hydrolyzing in eukaryotes and also the activities of the more simple Archaebacteria and Eubacteria proteasomes. Other catalytic activities of the proteasome and their possible origin are also examined. The specificity of the catalytic components toward synthetic substrates, natural peptides, and proteins and their relationship to the catalytic centers are reviewed. Some unanswered questions and future research directions are suggested.     

Displacement of housekeeping proteasome subunits by MHC-encoded LMPs: a newly discovered mechanism for modulating the multicatalytic proteinase complex.

The degradation of cytoplasmic antigens to peptides presented by class I MHC molecules is thought to be mediated by the ubiquitin/proteasome pathway. Support for this view came from our observation that the subunit composition of proteasomes can be changed by interferon-gamma (IFN-gamma) treatment. Thereby two subunits, LMP2 and LMP7, which are encoded in the MHC class II region, are incorporated into the proteasomal complex, whereas other subunits disappear. In the experiments reported in this communication we studied the subunit changes occurring in cell lines where the expression of LMP2 or LMP7 can be regulated individually either by IFN-gamma induction or by applying a new system to control the expression of transfected LMPs. In both situations LMP2 induction leads exclusively to the disappearance of housekeeping subunit 2, whereas LMP7 affects only subunit 10. Subunit 2 was found to be 76% homologous to LMP2. Since incorporation of LMP2 into the proteasomal complex prevents processing of the subunit 2 precursor, we conclude that LMP2 displaces subunit 2 during assembly. Subunit displacement is most likely a general mechanism to modulate the catalytic activity of the proteasomal complex without changing its structure. Furthermore, the controlled incorporation of transfected subunits into the complex offers a new approach to study proteasome function in vivo.     

Hyperphosphorylation of rat liver proteasome subunits: the effects of ethanol and okadaic acid are compared

In experimental alcoholic liver disease, protein degradation by the ATP-ubiquitin-proteasome pathway is inhibited. Failure of the proteasome to eliminate cytoplasmic proteins leads to the accumulation of oxidized and otherwise modified proteins. One possible explanation for the inhibition of the proteasome is hyperphosphorylation of proteasome subunits. To examine this possibility, the 26S proteasomes from the liver of rats fed ethanol and a pair-fed control were studied by isolating the proteasomes in a purified fraction. The effect of ethanol on the phosphorylation of proteasomal subunits was compared with the hyperphosphorylation of the proteasomes caused by okadaic acid given to rats in vivo. Ethanol ingestion caused an inhibition of the chymotrypsin-like activity of the purified proteasome. The 2D electrophoresis and Western blot analysis of the purified 20S and 26S proteasomes from the ethanol-fed rats indicated that hyperphosphorylation of proteasomal subunits had occured. The proteasomal alpha type subunits C9/alpha3 and C8/alpha7 were hyperphosphorylated compared to the controls. Chymotrypsin-like activity was also inhibited by okadaic acid treatment similar to ethanol feeding. The 26S proteasome fraction examined by isoelectric focusing gel revealed many hyperphosphorylated bands in the proteasomes from the okadaic acid treated and the ethanol fed rat livers compared with the controls. In conclusion hyperphosphorylation of the proteasome subunits occurs in the ethanol treated proteasomal subunits which could be one mechanism of the inhibition of the 26S proteasome caused by ethanol feeding.     

Two subunits of the canine signal peptidase complex are homologous to yeast SEC11 protein

Canine microsomal signal peptidase activity was previously isolated as a complex of five subunits (25, 22/23, 21, 18, and 12 kDa). Two of the signal peptidase complex (SPC) subunits (23/23 and 21 kDa) have been cloned and sequenced. One of these, the 21-kDa subunit, was observed to be a mammalian homolog of SEC11 protein (Sec11p) (Greenburg, G., Shelness, G. S., and Blobel, G. (1989) J. Biol. Chem. 264, 15762-15765) a gene product essential for signal peptide processing and cell growth in yeast (B?hni, P.C., Deshqies, R.J., and Schekman, R.W. (1988) J. Cell Biol. 106, 1035-1042). cDNA clones for the 18-kDa SPC subunit have now been characterized and found to encode a second SEC11p homolog. Both the 18- and 21-kDa canine SPC subunits are integral membrane proteins by virtue of their resistance to alkaline extraction. Upon detergent solubilization, both proteins are found in a complex with the 22/23 kDa SPC subunit, the only SPC subunit containing N-linked oligosaccharide. No steady-state pool of canine Sec11p-like monomers is detected in microsomal membranes. Alkaline extraction of microsomes prior to solubilization or solubilization at alkaline pH causes partial dissociation of the SPC. The Sec11p-like subunits displaced from the complex under these conditions demonstrate no signal peptide processing activity by themselves. The existence of homologous subunits is common to a number of known protein complexes and provides further evidence that the association between SPC proteins observed in vitro may be physiologically relevant to the mechanism of signal peptide processing and perhaps protein translocation.     

The catalytic subunits of protein phosphatase-1 and protein phosphatase 2A are distinct gene products

Three forms of protein phosphatase-1 were isolated from rabbit skeletal muscle that had Mr values of 37 000, 34 000 and 33 000 determined by sodium dodecyl sulphate (SDS) gel electrophoresis. Each species dephosphorylated the beta-subunit of phosphorylase kinase very much faster than the alpha-subunit, was inhibited by inhibitors 1 and 2 with equal potency, and was converted to a form dependent on glycogen synthase kinase-3 and Mg-ATP for activity by incubation with inhibitor-2. Digestion with cyanogen bromide or Staphylococcus aureus proteinase followed by SDS gel electrophoresis showed a very similar pattern of cleavage products for all three forms. The Mr-37 000 and Mr-34 000 species were converted to the Mr-33 000 form by incubation with chymotrypsin. It is concluded that the Mr-33 000 and Mr-34 000 forms are derived from the Mr-37 000 component by limited proteolysis. Conversion of the Mr-37 000 to the Mr-33 000 form was accompanied by a two-fold increase in activity, indicating that an Mr-4000 fragment at one end of the polypeptide is an inhibitory domain that decreases enzyme activity. The catalytic subunit of protein phosphatase 2A from rabbit skeletal muscle had an Mr of 36 000 determined by SDS gel electrophoresis and its specific activity (3 kU/mg) was much lower than that of the Mr-37 000 (15-20 kU/mg) or Mr-33/34 000 (40-50 kU/mg) forms of protein phosphatase-1. It dephosphorylated the alpha-subunit of phosphorylase kinase 4-5-fold faster than the beta-subunit, was unaffected by inhibitor-1 or inhibitor-2, and preincubation with the latter protein did not result in the production of a glycogen synthase kinase-3 and Mg-ATP-dependent form of the enzyme. Digestion with chymotrypsin did not alter the electrophoretic mobility of protein phosphatase 2A under conditions that caused quantitative conversion of the Mr-37 000 form of protein phosphatase-1 to the Mr-33 000 species. Digestion with cyanogen bromide or S. aureus proteinase, followed by SDS gel electrophoresis, showed a quite different pattern of cleavage products to those observed with protein phosphatase 1. Antibody to protein phosphatase-2A raised in sheep did not cross-react with any of the forms of protein phosphatase-1, as judged by immunoelectrophoretic and immunotitration experiments. It is concluded that protein phosphatase-1 and protein phosphatase-2A are distinct gene products.