K-Cl cotransport modulation by intracellular Mg in erythrocytes from mice bred for low and high Mg levels.

Mg is an important determinant of erythrocyte cation transport system(s) activity. We investigated cation transport in erythrocytes from mice bred for high (MGH) and low (MGL) Mg levels in erythrocytes and plasma. We found that K-Cl cotransport activity was higher in MGL than in MGH erythrocytes, and this could explain their higher mean corpuscular hemoglobin concentration, median density, and reduced cell K content. Although mouse KCC1 protein abundance was comparable in MGL and MGH erythrocytes, activities of Src family tyrosine kinases were higher in MGH than in MGL erythrocytes. In contrast, protein phosphatase (PP) isoform 1 alpha (PP1 alpha) enzymatic activity, which has been suggested to play a positive regulatory role in K-Cl cotransport, was lower in MGH than in MGL erythrocytes. Additionally, we found that the Src family kinase c-Fgr tyrosine phosphorylates PP1 alpha in vitro. These findings suggest that in vivo downregulation of K-Cl cotransport activity by Mg is mediated by enhanced Src family kinase activity, leading to inhibition of the K-Cl cotransport stimulator PP1.

Cell-cycle-dependent association of protein phosphatase 1 and focal adhesion kinase.

Immunofluorescence studies with protein phosphatase-1 (PP1) isoforms-specific antibodies detected PP1delta, but not alpha or gamma1, at focal adhesions. PP1delta also co-immunoprecipitated with the focal adhesion kinase (FAK) and the alphav-integrin. In the present study glutathione S-transferase (GST)-PP1delta pulled-down FAK from fibroblasts extract and the interaction domain localized between residues 159 and 295 of delta. The association was confirmed by the ability to GST-FAK-related non-kinase (FRNK) to pull-down PP1delta from fibroblasts extract. GST-FRNK also pulled-down purified muscle PP1 catalytic subunit, thus indicating direct interaction between FAK and PP1. FAK displays consensus sequences for phosphorylation by cell division cycle kinase-2-cyclin B, and might be a PP1 substrate. In fact, FAK immunoprecipitated from metabolically-labelled mitotic HeLa cells without tyrosine phosphatase inhibitors was phosphorylated on Ser only and was dephosphorylated in vitro by purified muscle PP1, with loss of phospho-Ser. No PP1 was associated with FAK immunoprecipitated from mitotic HeLa cells. However, progressively more PP1 activity was assayed in FAK-immunoprecipitates obtained from cells released from mitosis. The associated activity was maximal at 2 h from the mitotic release (when 85-90% of the cells remained round) and decreased to basal level by 8 h (when cells were all polygonal). At the same time FAK underwent dephosphorylation, which was completed by 4 h. FAK obtained from cells at 1.5 h was Ser-phosphorylated, and underwent dephosphorylation during in vitro incubation, with loss of phospho-Ser, indicating the presence of active FAK-bound phosphatase. The only FAK-associated PP1 isoform between 1 and 8 h was PP1delta. The results suggest that FAK dephosphorylation by PP1delta occurs in cells released from mitosis, and confirmed the specific association of PP1delta, as detected previously in adherent cells.

Site-specific and temporally-regulated retinoblastoma protein dephosphorylation by protein phosphatase type 1.

pRb is dephosphorylated at mitotic exit by the type 1 serine/threonine protein phosphatases (PP1). Here we demonstrate for the first time that mitotic pRb dephosphorylation is a sequential, temporally-regulated event. We also provide evidence that the three mammalian isoforms of PP1, alpha, gamma-1, and delta, differ in their respective preferences for site-specific pRb dephosphorylation and that the mitotic and G(1) PP1-isoform counterparts exhibit differential activities towards mitotic pRb. Finally, the physiological relevance of the striking contrast between the patterns of Thr821 and Thr826 dephosphorylation, sites known to be important for disrupting binding of LXCXE-containing proteins to pRb, is addressed.

Binding of phosphatase-1 delta to the retinoblastoma protein pRb involves domains that include substrate recognition residues and a pRB binding motif.

Protein Ser/Thr phosphatase-1 (PP1) controls the retinoblastoma protein (pRb) function, including its dephosphorylation at mitotic exit. Since PP1delta was found to coimmunoprecipitate with pRb from mitotic and early G1 cells, we further investigated the PP1delta-pRb association using GST-full length and GST-deletion mutants of delta. GST-delta pulled-down pRb from G2, mitotic and G1 HeLa cells, thus confirming the coimmunoprecipitation results. Among the delta deletion mutants tested, pRb was pulled down by mutant 159-295, which reproduces the C-terminal domain of delta without the C-terminus, whereas the C-terminus alone did not pull-down pRb. Further fragmentation of the 159-295 mutant indicated that pRb was pulled down by fragment 195-260, which includes several residues involved in substrate binding, and by fragment 159-212, which contains the putative pRb-binding motif LxSxE. Altogether the results supported the hypothesis that PP1delta may contribute to the dephosphorylation of pRb at mitotic exit and that the PP1delta-pRb interaction may be at multiple sites.

Protein phosphatase-1 activation and association with the retinoblastoma protein in colcemid-induced apoptosis.

Protein phosphatase-1 (PP1) is cell cycle regulated and potentially related to apoptosis. We studied PP1 in HeLa cells exposed to colcemid, which leads first to mitotic block, then to cell death within 72 h. The soluble PP1 activity, which was low at 14 h (mitosis), was then reversibly activated (maximally around 48 h), with parallel changes in the protein levels of the alpha, gamma1 and delta PP1 isoforms. PP1 activation suggested its involvement in dephosphorylating proteins relevant to apoptosis. Among these, we examined the retinoblastoma protein (pRb). This was found hyperphosphorylated at 14 h. Hypophosphorylated pRb appeared at 24 h, increased at 48 h, and was the only form left at 72 h. PP1 was found to associate with immunoprecipitated pRb, as indicated by PP1 activity assays on the pRb-immunocomplexes. The pRb-associated PP1 activity was low at 14 h, maximal at 24 h, low again by 72 h and was due to PP1delta. The presence of active PP1 suggests its involvement in pRb dephosphorylation.

Inhibitory phosphorylation of PP1alpha catalytic subunit during the G(1)/S transition.

We have shown earlier that, in cells expressing the retinoblastoma protein (pRB), a protein phosphatase (PP) 1alpha mutant (T320A) resistant to inhibitory phosphorylation by cyclin-dependent kinases (Cdks) causes G(1) arrest. In this study, we examined the cell cycle-dependent phosphorylation of PP1alpha in vivo using three different antibodies. PP1alpha was phosphorylated at Thr-320 during M-phase and again in late G(1)- through early S-phase. Inhibition of Cdk2 led to a small increase in PP1 activity and also prevented PP1alpha phosphorylation. In vitro, PP1alpha was a substrate for Cdk2 but not Cdk4. In pRB-deficient cells, phosphorylation of PP1alpha occurred in M-phase but not at G(1)/S. G(1)/S phosphorylation was at least partially restored after reintroduction of pRB into these cells. Consistent with this result, PP1alpha phosphorylated at Thr-320 co-precipitated with pRB during G(1)/S but was found in extracts immunodepleted of pRB in M-phase. In conjunction with earlier studies, these results indicate that PP1alpha may control pRB function throughout the cell cycle. In addition, our new results suggest that different subpopulations of PP1alpha regulate the G(1)/S and G(2)/M transitions and that PP1alpha complexed to pRB requires inhibitory phosphorylation by G(1)-specific Cdks in order to prevent untimely reactivation of pRB and permit transition from G(1)- to S-phase and/or complete S-phase.

Protein tyrosine phosphatase PTP-S binds to the juxtamembrane region of the hepatocyte growth factor receptor Met.

We reported previously that a protein tyrosine phosphatase (PTP) activity is associated with the immunoprecipitated hepatocyte growth factor (HGF) receptor, also known as Met. The activity increased reversibly when Met was stimulated by HGF and decreased when Met was inactivated by PMA. To identify the PTP-binding region, we used deletion mutants of the receptor beta-subunit. The PTP activity did not associate with Tpr-Met, a construct containing residues 1010-1390 of Met fused to Tpr. In contrast, PTP activity was present when the expressed protein contained the full juxtamembrane region (residues 956-1390 of Met) or part of this region (residues 957-1390 or 995-1390), indicating that the PTP-binding region is between residues 995 and 1009. This region includes Tyr1003, a site involved in Met downstream signalling. Incubation of Met immunoprecipitated from GTL-16 cells with an 8-mer phosphopeptide derived from residues 1003-1010 induced a marked decrease in the associated PTP activity, suggesting that the peptide reproduced the PTP-binding region. Mutation of Glu, Asp or Arg at positions -4, -1 or +1 respectively relative to Tyr1003 in a 9-mer peptide (residues 999-1007) abolished the ability of the peptide to decrease the PTP activity associated with Met. Phosphorylation of Tyr1003 was not required for PTP binding, since: (1) both phospho- and dephospho-peptides on a solid bead bound PTP activity from a GTL-16 cell extract, and (2) PTP activity was associated with a Met deletion mutant lacking residues 1-955 in which Tyr1003 had been changed into Phe. In order to partially purify the PTP from the GTL-16 cell extract, an affinity column was prepared using the Met-derived peptide comprising residues 998-1007. Less than 0.1% of the total cellular PTP was retained by the column, and was eluted with low salt concentrations. Using antibodies, this PTP was identified as PTP-S, a soluble PTP present in epithelial cells and fibroblasts.

Protein phosphatase 1 delta is associated with focal adhesions.

In all mammalian cells protein phosphatase-1 (PP1) exists in three isoforms, defined as alpha, gamma 1 and delta. Immunofluorescence studies with isoform-specific antibodies indicated that delta, but not alpha or gamma 1, is enriched at focal adhesions in HeLa cells, fibroblasts, endothelial cells and keratinocytes. This was confirmed also by interference reflection microscopy, which indicated that PP1 delta was in areas of tight adhesion of the membrane to the extracellular matrix at sites where the microfilament cytoskeleton is organized. In all the cell types so far considered the PP1 delta in focal adhesions represented only a small aliquot of the total PP1 delta, which was predominantly localized to the nucleus. The association of PP1 delta to focal adhesions was confirmed by the co-immunoprecipitation of PP1 delta with the focal adhesion kinase pp125FAK and with the alpha v integrin. Comparison between the amount of PP1 delta associated with focal adhesion proteins and that of PP1 delta recovered in an anti-PP1 delta immunoprecipitate confirmed that only a minor amount of the enzyme was associated with the focal adhesions. Since some focal adhesion proteins are phosphorylated on Ser/Thr, it is likely that PP1 delta may be involved in the regulation of focal adhesion functions and particularly in the signaling pathway generated by cell-substratum adhesion.

Protein phosphatase 1 isoforms in differentiating C2C12 myocytes.

In muscle protein phosphatase 1 (PP1) is involved in growth factor signal transduction and metabolic regulations. Three isoforms of the catalytic subunit are found in mammalian cells (PP1alpha, PP1gamma1 and PP1delta), with potentially different functions. We investigated the changes in the PP1 isoforms in differentiating C2C12 myoblasts. Few hours after differentiation induction the soluble PP1 activity was reversibly increased, displaying a peak at 6h. This was due to activation mainly of PP1alpha, with no change in the immunodetected protein. A further indication of PP1alpha involvement came from the observation that electroporation of inactive PP1alpha into myoblasts induced a differentiation delay of at least 24h. Subsequently, starting from 9-12 h, the activities and protein levels of all the three soluble PP1 isoforms decreased, reaching a minimum around 48 h. By this time the cells had undergone morphological changes and myosin became immunodetectable. We conclude that PP1 may be involved in myoblast differentiation, based on: 1) its higher activity in myoblasts than in myocytes, 2) the reversible activation of soluble PP1alpha during the first 6h from differentiation induction, 3) the delay in differentiation onset following electroporation of inactive PP1alpha into myoblasts.

Differential subcellular localization of protein phosphatase-1 alpha, gamma1, and delta isoforms during both interphase and mitosis in mammalian cells.

Protein phosphatase-1 (PP-1) is involved in the regulation of numerous metabolic processes in mammalian cells. The major isoforms of PP-1, alpha, gamma1, and delta, have nearly identical catalytic domains, but they vary in sequence at their extreme NH2 and COOH termini. With specific antibodies raised against the unique COOH-terminal sequence of each isoform, we find that the three PP-1 isoforms are each expressed in all mammalian cells tested, but that they localize within these cells in a strikingly distinct and characteristic manner. Each isoform is present both within the cytoplasm and in the nucleus during interphase. Within the nucleus, PP-1 alpha associates with the nuclear matrix, PP-1 gamma1 concentrates in nucleoli in association with RNA, and PP-1 delta localizes to nonnucleolar whole chromatin. During mitosis, PP-1 alpha is localized to the centrosome, PP-1 gamma1 is associated with microtubules of the mitotic spindle, and PP-1 delta strongly associates with chromosomes. We conclude that PP-1 isoforms are targeted to strikingly distinct and independent sites in the cell, permitting unique and independent roles for each of the isoforms in regulating discrete cellular processes.

Association of protein phosphatase-1delta with the retinoblastoma protein and reversible phosphatase activation in mitotic HeLa cells and in cells released from mitosis.

The retinoblastoma gene product (pRb) is dephosphorylated at the exit from mitosis and protein phosphatase-1 (PP1) seems to be responsible for such dephosphorylation. Three isoforms of PP1 exist in mammalian cells, alpha, gamma1 and delta, with differential subcellular localization and potentially different targeting subunits and functions. In order to identify which isoform dephosphorylates pRb, we used isoform-specific antibodies and analyzed the association of the PP1 isoforms with pRb in nocodazole-blocked (mitotic) HeLa cells and in cells released from the mitotic block (early G1). PP1delta was found associated with the pRb immunoprecipitated from a mitotic cell extract, whereas neither PP1gamma1 nor PP1alpha were detected. In G1 cells progressively less pRb and of lower Mr was detected in anti-PP1delta immunocomplexes, and pRb had almost disappeared by 8 h. The PP1 associated with pRb was inactive at mitosis, but underwent a quick activation as cells exited from mitosis, with a peak at 1 h. Then the activity decreased progressively and disappeared by 8 h. [32P]labeled pRb, obtained from G2 cells, was dephosphorylated "in vitro" by PP1delta obtained from early G1 cells. Altogether, the results indicated that PP1delta associated with pRb and may be responsible for the phosphatase activity detected in the pRb complexes, supporting the hypothesis that PP1delta may be the isoform that dephosphorylates pRb.

Phosphorylation of protein phosphatase-1 isoforms by cdc2-cyclin B in vitro.

Protein Phosphatase-1 is phosphorylated in vitro by cdc2-cyclin B (Villa-Moruzzi, FEBS Lett 304: 211-215, 1992). In the present study we show that all the three Phosphatase-1 isoforms, alpha, gamma 1, delta, are phosphorylated by cdc2-cyclin B. Phosphorylation is specific for this kinase and involves a C-terminal Thr. This site is most likely Thr 320 in alpha (shown by others to be phosphorylated also by cdc2-cyclin A). Such Thr is conserved in gamma 1, delta and in the testis-specific gamma 2, and is the only Thr that fits the cdc2-consensus sequence in the C-terminal region. Phosphorylation of Phosphatase-1 purified from skeletal muscle, which is a mixture of the alpha, gamma 1 and delta isoforms, is up to 0.4 mol/mol and induces 30-35% enzyme inactivation. Following tryptic proteolysis each isoform yields a distinct phosphopeptide map. This is in agreement with the different sequences of the isoforms in the C-terminal regions and may be useful to distinguish the isoforms in extracts from metabolically-labelled cells. Our results suggest that all the Phosphatase-1 isoforms may be potentially regulated at M-phase.

Protein phosphatase-1 alpha, gamma 1, and delta: changes in phosphorylation and activity in mitotic HeLa cells and in cells released from the mitotic block.

Protein phosphatase-1 is phosphorylated "in vitro" by cdc2-cyclin B (E. Villa-Moruzzi, FEBS Lett. 304, 211-215, 1992). In the present study the phosphatase-1 isoforms alpha, gamma 1, and delta were analyzed in mitotic (nocodazole-blocked) HeLa cells. Phosphorylation on threonine increased in gamma 1 and delta at mitosis. alpha was phosphorylated only in mitotic cells and mainly on serine. Exposure of permeabilized mitotic cells to a peptide that inhibits cdc2 decreased the phosphorylation of the isoforms. Cell fractionation indicated that phosphatase-1 was over 90% inactivated and phosphorylated in the soluble, but not in the chromosomal fraction of mitotic cells. Immunoprecipitation from the mitotic soluble fraction indicated that only gamma 1 and delta, but not alpha, were inactivated. Altogether the data pointed to a correlation between phosphatase-1 inactivation and phosphorylation in mitotic cells. cdc2-cyclin B might be the kinase (or one of the kinases) that phosphorylates phosphatase-1. In cells released from the mitotic block, the phosphatase-1 activity in the soluble, but not in the nuclear fraction, increased progressively, reaching control values by 16 h. Immunoprecipitation indicated that the increase in activity was due to alpha and delta only. On the other hand, the activity of gamma 1 remained low, and this was also the only isoform that remained phosphorylated, though less than in mitotic cells. Also in the case of the cells released from mitosis, a correlation may exist between phosphorylation and inactivation of phosphatase-1. However, the regulation of phosphatase-1 is complex and may involve also regulatory subunits that are still unknown. Altogether, the results indicated the differential regulation of the phosphatase-1 isoforms both at mitosis and in G1 cells.

Differential localization of myosin and myosin phosphatase subunits in smooth muscle cells and migrating fibroblasts.

Myosin II light chains (MLC20) are phosphorylated by a Ca2+/calmodulin-activated kinase and dephosphorylated by a phosphatase that has been purified as a trimer containing the delta isoform of type 1 catalytic subunit (PP1C delta), a myosin-binding 130-kDa subunit (M130) and a 20-kDa subunit. The distribution of M130 and PP1C as well as myosin II was examined in smooth muscle cells and fibroblasts by immunofluorescence microscopy and immunoblotting after differential extraction. Myosin and M130 colocalized with actin stress fibers in permeabilized cells. However, in nonpermeabilized cells the staining for myosin and M130 was different, with myosin mostly at the periphery of the cell and the M130 appearing diffusely throughout the cytoplasm. Accordingly, most M130 was recovered in a soluble fraction during permeabilization of cells, but the conditions used affected the solubility of both M130 and myosin. The PP1C alpha isoform colocalized with M130 and also was in the nucleus, whereas the PP1C delta isoform was localized prominently in the nucleus and in focal adhesions. In migrating cells, M130 concentrated in the tailing edge and was depleted from the leading half of the cell, where double staining showed myosin II was present. Because the tailing edge of migrating cells is known to contain phosphorylated myosin, inhibition of myosin LC20 phosphatase, probably by phosphorylation of the M130 subunit, may be required for cell migration.

Phosphorylation of phosphatase-1alpha in cells expressing v-src.

Phosphatase-1 (PP1) is phosphorylated "in vitro" by the tyrosine-kinases c-src, v-src and v-abl. In the case of src, this induces enzyme inactivation. We investigated whether in NIH-3T3 cells expressing v-src (A4 cells) PP1 was phosphorylated on Tyr and inactivated. In mammalian cells, three PP1 isoforms are present: PP1alpha, PP1gamma1 and PP1delta. In A4 cells the three PP1 isoforms were all phosphorylated on Ser, but only PP1alpha was also phosphorylated on Tyr. A lower level of PP1 phosphorylation, and on Ser only, was found also in wild-type NIH-3T3 cells. In A4 cells most of Tyr-phosphorylated PP1alpha was cytosolic. Also the PP1 activity was decreased in the cytosol of the A4 cells. Assay of the three immunoprecipitated PP1 isoforms indicated that only PP1alpha was inactivated. Altogether the data suggest that PP1alpha might be a target of v-src "in vivo".

Activation of protein phosphatase-1 isoforms and glycogen synthase kinase-3 beta in muscle from mdx mice.

Three Protein Phosphatase-1 (PP1) isoforms (PP1 alpha, PP1 gamma-1 and PP1 delta) are found in skeletal muscle. These are bound to regulatory subunits, such as inhibitor 2 (I2) in the cytosol and G in the glycogen and microsomal fractions. In vitro, the PP1-12 complex is activated by Glycogen Synthase Kinase-3 (GSK-3 or FA). We investigated the activities and protein levels of the three PP1 isoforms and of GSK-3 in muscle of mdx dystrophic mice. PP1 was assayed as phosphorylase phosphatase, in the presence of 5 nM okadaic acid (which inhibits PP2A). Peptide antibodies were produced and used to investigate PP1 alpha, PP1 gamma-1 and PP1 delta. GSK-3 was assayed using a previously described peptide. This was synthesized in a pre-phosphorylated from, which avoids the additional use of Casein Kinase II. Higher PP1 activity was assayed in the cytosol from mdx rather than from control muscles. Immunoprecipitation indicated that only PP1 alpha and PP1 gamma-1 were more active. This was most likely due to enzyme activation, since the immunodetected proteins were unchanged. On the other hand, the immunodetected PP1 delta was lower in the glycogen and microsomal fractions from mdx muscle. GSK-3 was more active in the mdx extract Selective immunoprecipitation of GSK-3 alpha and GSK-3 beta indicated that both isoforms were activated. In the case of GSK-3 beta, the immunodetected protein was also increased. The changes described herein may be related to the pathological events occurring in the mdx muscle. These include increased protein degradation and turnover, and fibre regeneration. In fact, the decreased PP1 delta may be due to protein degradation and the increased GSK-3 may be the consequence of increased protein turnover or regeneration. The apparent correlation between the increased PP1 alpha and PP1 gamma-1 activities and the increased GSK-3 may agree with the hypothesis that GSK-3 activates the newly synthesized PP1.

Phosphorylation of the inhibitor-2 of protein phosphatase-1 by cdc2-cyclin B and GSK3.

cdc2-cyclin B activates protein phosphatase-1 (PP1) "in vitro", phosphorylates both catalytic subunit and inhibitor-2 (I2) and both processes are inhibited by a cdc2-inhibitory peptide. We compared the phosphorylation of I2 by cdc2-cyclin B and by the PP1-activator Glycogen Synthase Kinase 3 (GSK3). Each kinase introduced less than 0.1 mol phosphate/mol into I2 bound to PP1 and the same two tryptic phosphopeptides were obtained from I2, which contained phospho-T only. The same results were obtained also with isolated I2 phosphorylated by GSK3. Since GSK3 phosphorylates only T-72, cdc2-cyclin B is also likely to phosphorylate this site. This was confirmed by using I2 that had been mutated at this site. On the other hand cdc2-cyclin B introduced up to 0.8 mol/mol phosphate into isolated I2 and four phosphopeptides were obtained. The two new peptides contained phospho-T and one of them also phospho-S. These data indicate the presence of at least one T and one S that are phosphorylated only by cdc2-cyclin B and are accessible on isolated I2 only.

Differential activities of protein phosphatase types 1 and 2A in cytosolic and particulate fractions from rat forebrain.

The activities and concentrations of protein phosphatase type 1 (PP1) and type 2A (PP2A) were compared in cytosol and particulate fractions of rat forebrain. Although the activity of PP2A was highest in the cytosol, immunoblot analysis with a PP2A-specific antibody showed that there were significant levels of the enzyme in the particulate fraction. There was no significant difference between the concentration of PP2A in the cytosol and particulate fractions such that the low activity of PP2A in the particulate fraction represents an inactivation of this form of the enzyme. Similar analysis in skeletal muscle, heart, and liver showed this finding was unique to the brain. Similarly, the majority of PP1 activity was recovered in the cytosol, but most PP1 enzyme was associated with the particulate fraction. Comparison with other tissues showed that the activities of PP1 in the particulate fractions were similar but that the forebrain contained significantly more enzyme than the other tissues. Thus, like PP2A it appears that the specific activity of PP1 in the particulate fraction of rat forebrain is much lower than that of the cytosol and of the particulate fractions of other tissues. Elution of PP1 and PP2A from membranes with 0.5 M NaCl plus 0.3% Triton X-100 resulted in severalfold activation of both enzymes. That the majority of PP1 and PP2A in rat forebrain are associated with membrane structures but in a low activity state suggests that novel regulatory mechanisms exist that have considerable and unique potential for activation of protein dephosphorylation.

Activation of the cdc25C phosphatase in mitotic HeLa cells.

The cdc2-activator cdc25C was immunoprecipitated from HeLa cell extracts and assayed as tyrosine phosphatase (PTP) using tyrosine-phosphorylated myelin basic protein. The PTP activity was 12-fold higher in immunocomplexes from mitotic (nocodazole-arrested) than from asynchronous cells. This difference is due to enzyme activation, since the same amount of cdc25C was immunodetected in both conditions. However, mitotic cdc25C had M(r) 59,000, while a 56,000-59,000 doublet was detected in immunocomplexes from asynchronous cells. The PTP activity of mitotic cdc25C was decreased by treatment with Phosphatase-2A catalytic subunit (but not with Phosphatase-1), with re-appearance of the 56,000 polypeptide. cdc25C was also found associated with cdc2-p13-Sepharose complex and its PTP activity was 7-fold higher in samples from mitotic than from asynchronous cells. cdc25C and cdc2 co-migrated during gel filtration and the higher activity of mitotic cdc25C was retained through gel filtration.