Molecular mechanisms underlying a cellular analog of operant reward learning.

Operant conditioning is a ubiquitous but mechanistically poorly understood form of associative learning in which an animal learns the consequences of its behavior. Using a single-cell analog of operant conditioning in neuron B51 of Aplysia, we examined second-messenger pathways engaged by activity and reward and how they may provide a biochemical association underlying operant learning. Conditioning was blocked by Rp-cAMP, a peptide inhibitor of PKA, a PKC inhibitor, and by expressing a dominant-negative isoform of Ca2+-dependent PKC (apl-I). Thus, both PKA and PKC were necessary for operant conditioning. Injection of cAMP into B51 mimicked the effects of operant conditioning. Activation of PKC also mimicked conditioning but was dependent on both cAMP and PKA, suggesting that PKC acted at some point upstream of PKA activation. Our results demonstrate how these molecules can interact to mediate operant conditioning in an individual neuron important for the expression of the conditioned behavior.

Aldosterone-induced Sgk1 relieves Dot1a-Af9-mediated transcriptional repression of epithelial Na+ channel alpha.

Aldosterone plays a major role in the regulation of salt balance and the pathophysiology of cardiovascular and renal diseases. Many aldosterone-regulated genes--including that encoding the epithelial Na+ channel (ENaC), a key arbiter of Na+ transport in the kidney and other epithelia--have been identified, but the mechanisms by which the hormone modifies chromatin structure and thus transcription remain unknown. We previously described the basal repression of ENaCalpha by a complex containing the histone H3 Lys79 methyltransferase disruptor of telomeric silencing alternative splice variant a (Dot1a) and the putative transcription factor ALL1-fused gene from chromosome 9 (Af9) as well as the release of this repression by aldosterone treatment. Here we provide evidence from renal collecting duct cells and serum- and glucocorticoid-induced kinase-1 (Sgk1) WT and knockout mice that Sgk1 phosphorylated Af9, thereby impairing the Dot1a-Af9 interaction and leading to targeted histone H3 Lys79 hypomethylation at the ENaCalpha promoter and derepression of ENaCalpha transcription. Thus, Af9 is a physiologic target of Sgk1, and Sgk1 negatively regulates the Dot1a-Af9 repressor complex that controls transcription of ENaCalpha and likely other aldosterone-induced genes.

Severe aortic and arterial aneurysms associated with a TGFBR2 mutation.

BACKGROUND: A 24-year-old man presented with previously diagnosed Marfan's syndrome. Since the age of 9 years, he had undergone eight cardiovascular procedures to treat rapidly progressive aneurysms, dissection and tortuous vascular disease involving the aortic root and arch, the thoracoabdominal aorta, and brachiocephalic, vertebral, internal thoracic and superior mesenteric arteries. Throughout this extensive series of cardiovascular surgical repairs, he recovered without stroke, paraplegia or renal impairment. INVESTIGATIONS: CT scans, arteriogram, genetic mutation screening of transforming growth factor beta receptors 1 and 2. DIAGNOSIS: Diffuse and rapidly progressing vascular disease in a patient who met the diagnostic criteria for Marfan's syndrome, but was later rediagnosed with Loeys-Dietz syndrome. Genetic testing also revealed a de novo mutation in transforming growth factor beta receptor 2. MANAGEMENT: Regular cardiovascular surveillance for aneurysms and dissections, and aggressive surgical treatment of vascular disease.

THE ROLE OF E2F1 IN THE RESPONSE TO DNA DOUBLE STRAND BREAKS

The importance of E2F transcription factors in the processes of proliferation and apoptosis are well established. E2F1, but not other E2F family members, is also phosphorylated and stabilized in response to various forms of DNA damage to regulate the expression of cell cycle and pro-apoptotic genes. E2F1 also relocalizes and forms foci at sites of DNA double-strand breaks but the function of E2F1 at sites of damage is still unknown. Here I reveal that E2F1 deficiency leads to increased spontaneous DNA break and impaired recovery following exposure to ionizing radiation. In response to DNA double-strand breaks, NBS1 phosphorylation and foci formation are defective in cells lacking E2F1, but NBS1 expression levels are unaffected. Moreover, it was observed that an association between NBS1 and E2F1 is increased in response to DNA damage, suggesting that E2F1 may promote NBS1 foci formation through a direct or indirect interaction at sites of DNA breaks. E2F1 deficient cells also display impaired foci formation of RPA and Rad51, which suggests a defect in DNA end resection and formation of single-stranded DNA at DNA double-strand breaks. I also found E2F1 status affects foci formation of the histone acetyltransferase GCN5 in response to DNA double-strand breaks. E2F1 is phosphorylated at serine 31 (serine 29 in mouse) by the ATM kinase as part of the DNA damage response. To investigate the importance of this event, our lab developed an E2F1 serine 29 mutant mouse model. I find that E2F1 serine 29 mutant cells show loss of E2F1 foci formation in response to DNA double-strand breaks. Furthermore, DNA repair and NBS1 foci formation are impaired in E2f1S29A/S29A cells. Taken together, my results indicate novel roles for E2F1 in the DNA damage response, which may directly promote DNA repair and genome maintenance.

Multiple site phosphorylation of tyrosine hydroxylase: A potential role for protein kinase C in the regulation of catecholamine synthesis

Tyrosine hydroxylase (TH), the initial and rate limiting enzyme in the catecholaminergic biosynthetic pathway, is phosphorylated on multiple serine residues by multiple protein kinases. Although it has been demonstrated that many protein kinases are capable of phosphorylating and activating TH in vitro, it is less clear which protein kinases participate in the physiological regulation of catecholamine synthesis in situ. These studies were designed to determine if protein kinase C (PK-C) plays such a regulatory role.^ Stimulation of intact bovine adrenal chromaffin cells with phorbol esters results in stimulation of catecholamine synthesis, tyrosine hydroxylase phosphorylation and activation. These responses are both time and concentration dependent, and are specific for those phorbol ester analogues which activate PK-C. RP-HPLC analysis of TH tryptic phosphopeptides indicate that PK-C phosphorylates TH on three putative sites. One of these (pepetide 6) is the same as that phosphorylated by both cAMP-dependent protein kinase (PK-A) and calcium/calmodulin-dependent protein kinase (CaM-K). However, two of these sites (peptides 4 and 7) are unique, and, to date, have not been shown to be phosphorylated by any other protein kinase. These peptides correspond to those which are phosphorylated with a slow time course in response to stimulation of chromaffin cells with the natural agonist acetylcholine. The activation of TH produced by PK-C is most closely correlated with the phosphorylation of peptide 6. But, as evident from pH profiles of tyrosine hydroxylase activity, phosphorylation of peptides 4 and 7 affect the expression of the activation produced by phosphorylation of peptide 6.^ These data support a role for PK-C in the control of TH activity, and suggest a two stage model for the physiological regulation of catecholamine synthesis by phosphorylation in response to cholinergic stimulation. An initial fast response, which appears to be mediated by CaM-K, and a slower, sustained response which appears to be mediated by PK-C. In addition, the multiple site phosphorylation of TH provides a mechanism whereby the regulation of catecholamine synthesis appears to be under the control of multiple protein kinases, and allows for the convergence of multiple, diverse physiological and biochemical signals. ^

Intracellular phosphorylation of ornithine decarboxylase: Regulation of enzyme activity

Ornithine decarboxylase (ODC), the rate-limiting enzyme in polyamine biosynthesis exists as two major and one minor ionic form in the macrophage cell line, RAW 264. The forms have the same molecular weight, 55,000, but differ in their isoelectric points, 5.2, 5.1, and 4.9-5.0. The hypothesis that phosphorylation accounts for the differences in the two major ionic forms and that phosphorylation is involved in the regulation of enzyme activity was investigated. Metabolic-radiolabeling of cells with $\sp{32}$P-orthophosphate indicated that only one of the major forms of the protein can be explained by phosphorylation: treatment of purified ODC with alkaline phosphatase resulted in the loss of the phosphorylated form of the protein, pl 5.1, with a concomitant increase in the unphosphorylated, pl 5.2, form of the protein. Characterization of the phosphorylation sites showed that serine was the present. Tryptic digests of $\sp{32}$P-labeled ODC, analyzed by either two dimensional tryptic peptide mapping or reverse-phase HPLC, contained only one major radiolabeled peptide.^ The role phosphorylation plays in the regulation of enzyme activity was also investigated. Treatment of purified ODC with alkaline phosphatase resulted in the loss of enzyme activity. A positive linear correlation exists between enzyme activity and the amount of phosphorylated form of the protein present.^ To ascertain if the two major forms of the protein were also found in animal cells, ODC was immunoprecipitated from various rat tissues, fractionated by isoelectric focusing, and detected by immunoblotting. ODC was present in rat tissues in a single major form, which comigrated with the pl 5.1, phosphorylated form of ODC present in RAW 264 cell.^ This study concludes that ODC exists as a phosphorylated form, pl 5.1, and an unphosphorylated form, pl 5.2 in RAW 264 cells. The amount of the phosphorylated form of ODC correlates well with the enzyme activity. ^

Analysis of the Soehner-Dmochowski strain of Moloney murine sarcoma virus

The Soehner-Dmochowski strain of murine sarcoma virus (MuSV-SD) was derived from a bone tumor of a New Zealand Black (NZB) rat infected with the Moloney strain of MuSV, which carries the gene encoding the v-mos protein. Serial passage of cell-free tumor extracts both decreased the latent period and resulted in osteosarcomas. Cells from a late passage tumor were established in culture, cell-free extracts frozen, and later inoculated into newborn NZB rats. One of the resulting bone tumors was established in culture and clonal cell lines derived, of which S4 was selected for the present study. The objectives of the study were two-fold: an examination of the genetic organization of MuSV-SD, and an examination of the biochemical characteristics of the viral proteins, since this is an acutely transforming virus which may yield insights into the mechanism of transformation caused by the v-mos protein. Blot hybridization of digested S4 genomic DNA reveals three candidate MuSV-SD integrated viral DNAs. The largest of these, MuSV-SD-6.5, was cloned from an S4 cosmid library, and the complete MuSV-SD-mos sequence was determined. The predicted amino acid sequence of the v-mos protein was compared to that of MuSV-124 and Ht-1, which show a 96.5% and 97.1% similarity, respectively. To characterize the MuSV-SD-mos protein further, immunochemical assays were performed using anti-mos antisera. The immunoblot analysis and immunoprecipitation assays demonstrated that similar levels of the v-mos protein were present in cells chronically infected with either MuSV-SD or MuSV-124; however, the immune complex kinase assay revealed greatly reduced in vitro serine kinase activity of the MuSV-SD-mos protein compared to that of MuSV-124. Sequence analysis demonstrated that the serine at amino acid residue 358 of the MuSV-SD-mos protein, like that of MuSV-Ht-1, had been mutated to a glycine. Mutations of this serine residue have been shown to affect the detectable in vitro kinase activity, however, v-mos proteins containing this mutation still retain transforming properties. Therefore, although the characteristic in vitro kinase activity of the MuSV-SD-mos protein has not been demonstrated, it is clear that this virus is a potent transforming agent. ^

Positional cloning and characterization of the human aniridia and murine small eye genes

Aniridia (AN) is a congenital, panocular disorder of the eye characterized by the complete or partial absence of the iris. The disease can occur in both the sporadic and familial forms which, in the latter case, is inherited as an autosomal dominant trait with high penetrance. The objective of this study was to isolate and characterize the genes involved in AN and Sey, and thereby to gain a better understanding of the molecular basis of the two disorders.^ Using a positional cloning strategy, I have approached and cloned from the AN locus in human chromosomal band 11p13 a cDNA that is deleted in two patients with AN. The deletions in these patients overlap by about 70 kb and encompass the 3$\sp\prime$ end of the cDNA. This cDNA detects a 2.7 kb mRNA encoded by a transcription unit estimated to span approximately 50 kb of genomic DNA. The message is specifically expressed in all tissues affected in all forms of AN, namely within the presumptive iris, lens, neuroretina, the superficial layers of the cornea, the olfactory bulbs, and the cerebellum. Sequence analysis of the AN cDNA revealed a number of motifs characteristic of certain transcription factors. Chief among these are the presence of the paired domain, the homeodomain, and a carboxy-terminal domain rich in serine, threonine and proline residues. The overall structure shows high homology to the Drosophila segmentation gene paired and members of the murine Pax family of developmental control genes.^ Utilizing a conserved human genomic DNA sequence as probe, I was able to isolate an embryonic murine cDNA which is over 92% homologous in nucleotide sequence and virtually identical at the amino acid level to the human AN cDNA. The expression pattern of the murine gene is the same as that in man, supporting the conclusion that it probably corresponds to the Sey gene. Its specific expression in the neuroectodermal component of the eye, in glioblastomas, but not in the neural crest-derived PC12 pheochromocytoma cell line, suggests that a defect in neuroectodermal rather mesodermal development might be the common etiological factor underlying AN and Sey. ^

The functional and structural interactions between v-{\it mos\/} proteins and cell cycle control elements

The v-mos gene of Moloney murine sarcoma virus (Mo-MuSv) encodes a serine/threonine protein kinase capable of inducing cellular transformation. The c-mos protein is an important cell cycle regulator that functions during meiotic cell division cycles in germ cells. The overall function of c-mos in controlling meiosis is becoming better understood but the role of v-mos in malignant transformation of cells is largely unknown.^ In this study, v-mos protein was shown to be phosphorylated by M phase kinase in vitro and in vivo. The kinase activity and neoplastic transforming ability of v-mos is positively regulated by the phosphorylation. Together with the earlier finding of activation of M phase kinase by c-mos, these results raise the possibility of mutual regulation between M phase kinase and mos kinases.^ In addition to its functional interaction with the M phase kinase, the v-mos protein was shown to be present in the same protein complex with a cyclin-dependent kinase (cdk). In addition, an antibody that recognizes the cdk proteins was shown to co-precipitate the v-mos proteins in the interphase and mitotic cells transformed by p85$\sp{\rm gag-mos}$. Cdk proteins have been shown to be associated with nonmitotic cyclins which are potential oncogenes. The perturbation of cdk kinase or the activation of non-mitotic cyclins as oncogenes by v-mos could contribute directly to v-mos induced cellular transformation. v-mos proteins were also shown to interact with tubulin and vimentin, the essential components of microtubules and type IV intermediate filaments, respectively. The organizations of both microtubules and intermediate filaments are cell cycle-regulated. These results suggest that the v-mos kinase could be directly involved in inducing morphological changes typically seen in transformed cells.^ The interactions between the v-mos protein and these cell cycle control elements in regards to v-mos induced neoplastic transformation are discussed in detail in the text. ^

Multisite phosphorylation of ornithine decarboxylase in transformed macrophages

Ornithine decarboxylase (ODC), the initial inducible enzyme in the polyamine biosynthetic pathway, exists in the transformed macrophage RAW264 cell line as a phosphoprotein following cell stimulation. The hypothesis that ODC is phosphorylated at multiple sites in stimulated RAW264 cells was investigated. ODC isolated from tetradecanoyl-phorbol-13-acetate (TPA)-stimulated cells metabolically radiolabeled in the presence of $\sp{32}$P$\sb{\rm i}$ was subjected to cyanogen bromide (CNBr) cleavage followed by phosphopeptide mapping and two dimensional phosphoamino acid analysis. These phosphorylation studies demonstrated six in situ phosphorylated CNBr-generated fragments having apparent molecular weights of 17, 14.3, 8, 6.5, 4, and 2.7 kDa and also revealed that ODC is phosphorylated in RAW264 cells on at least 5 serine and 2 threonine residues.^ In addition, the in vivo specific activity and phosphorylation pattern of ODC in response to various kinase cascade stimulants was studied. A differential response in ODC specific activity and a variation in the relative distribution of $\sp{32}$P-labeling of serine and threonine residues on the ODC molecule was noted in response to fetal bovine serum, cAMP and isobutylmethylxanthine, lipopolysaccharide, or TPA.^ Based on information derived from consensus sequence motifs, three protein kinases responsible for the phosphorylation of ODC in vitro were identified. Purified ODC was phosphorylated in vitro by casein kinase II (CK II), extracellular signal-regulated kinase 1 (ERK1), and its activator, extracellular signal-regulated kinase kinase (MEK). CK II phosphorylated ODC on serine residues contained on three CNBr-generated peptides with apparent molecular weights of 14.3, 6.5, and 2.7 kDa. Both ERK1 and MEK phosphorylated ODC on serine and threonine residues on a CNBr-generated peptide fragment with an apparent molecular weight of 6.5 kDa. The in vitro radiolabeled peptides corresponded in molecular mass with some of the CNBr fragments of ODC phosphorylated in situ in stimulated RAW264 cells.^ This study concludes that ODC is phosphorylated in the transformed macrophage RAW264 cell line at multiple sites in response to various kinase cascade stimulants. These stimulants also led to a differential response in specific activity and phosphorylation pattern of ODC in RAW264 cells. Three protein kinases have been identified which phosphorylate ODC in vitro on peptides and amino acid residues which correspond with those phosphorylated in situ. ^

The effect of v-{\it mos\/} expression on the regulation of the {\it fos\/} promoter in 490N3T cells

The v-mos oncogene acquired by Moloney murine sarcoma viruses by recombination with the c-mos proto-oncogene encodes a 37kD cytoplasmic serine/threonine protein kinase which can phosphorylate tubulin and vimentin, as well as the cyclin B component of the maturation promotion factor complex (MPF). Our earliest experiments asked whether the v-mos protein could activate the transcription of transin. Since the transcription of transin was known to be mediated by both fos-dependent and fos-independent pathways, it seemed possible that the induction of transin transcription by v-mos might be mediated by p55$\sp{\rm c-}\sp{fos}$. Surprisingly, when we examined the effect of v-mos on the fos promoter, we observed a significant inhibition of transcription in 49ON3T cells, a subclone of N1H3T3 mouse fibroblasts.^ In this thesis we show that in mouse 49ON3T cells, transcription from the fos promoter is up to 10-fold repressed in the presence of v-mos. Moreover, in this cell line several other transforming constructs (v-ras, v-src, neu) also cause repression of the fos promoter. Interestingly, nontransforming oncogenes (e.g. myc) do not repress fos transcription. The repressive effect was lost in v-mos mutants lacking in ATP-binding or kinase domain, arguing that the effect on fos transcription was mediated by v-mos transforming kinase activity. As mos is a cytoplasmic protein, it was assumed that transcriptional repression was mediated by conversion of a transcriptional regulator to a repressor by mos-induced phosphorylation. As a first approximation of the identity of this factor, we mapped the position of the mos effect on the fos promoter using reporter (CAT) constructs. We found that repression was mediated by regions $-$221 to $-$106 and $-$122 to $-$65 relative to the fos transcriptional start site, both of which regions regulate baseline fos transcription. There are direct repeats containing E2F transcriptional activator/repressor recognition motifs in these regions which bind similar nuclear proteins independently of v-mos presence or absence. Our data show that the contribution of the direct repeat to baseline fos transcription is mediated by these E2F sites with perhaps some contribution from the overlapping retinoblastoma control element (RCE). We have shown that there is a separate DNA protein interaction in the direct repeat which is more pronounced in the presence of v-mos. The recognition site for this protein, which we speculate mediates the mos-induced downregulation of fos transcription, overlaps but is distinct from the E2F and RCE binding sites. (Abstract shortened by UMI.) ^

Molecular mechanisms of protein kinase-mediated desensitization and internalization of the $\beta$-adrenergic receptor

The $\beta$-adrenergic receptor ($\beta$AR), which couples to G$\sb{\rm s}$ and activates adenylylcyclase, has been a prototype for studying the activation and desensitization of G-protein-coupled receptors. The main objective of the present study is to elucidate the molecular mechanisms of protein kinase-mediated desensitization and internalization of the $\beta$AR.^ Activation of cAPK or PKC causes a rapid desensitization of $\beta$AR stimulation of adenylylcyclase in L cells, which previous studies suggest involves the cAPK/PKC consensus phosphorylation site in the third intracellular loop of the $\beta$AR, RRSSK$\sp{263}$. To determine the role of the individual serines in the cAPK- and PKC-meditated desensitizations, wild type (WT) and mutant $\beta$ARs containing the substitutions, Ser$\sp{261} \to$ A, Ser$\sp{262} \to$ A, Ser$\sp{262} \to$ D, and Ser$\sp{261/262} \to$ A, were constructed and stably transfected into L cells. The cAPK-mediated desensitization was decreased 70-80% by the Ser$\sp{262} \to$ A, Ser$\sp{262} \to$ D, and the Ser$\sp{261/262} \to$ A mutations, but was not altered by the Ser$\sp{261} \to$ A substitution, demonstrating that Ser$\sp{262}$ was the primary site of the cAPK-induced desensitization. The PMA/PKC-induced desensitization was unaffected by either of the single serine to alanine substitutions, but was reduced 80% by the double serine to alanine substitution, suggesting that either serine was sufficient to confer the PKC-mediated desensitization. Coincident stimulation of cAPK and PKC caused an additive desensitization which was significantly reduced (80%) only by the double substitution mutation. Quantitative evaluation of the coupling efficiencies and the GTP-shift of the WT and mutant receptors demonstrated that only one of the mutants, Ser$\sp{262} \to$ A, was partially uncoupled. The Ser$\sp{262} \to$ D mutation did not significantly uncouple, demonstrating that introducing a negative charge did not appear to mimic the desensitized state of the receptor.^ To accomplish the in vivo phosphorylation of the $\beta$AR, we used two epitope-modified $\beta$ARs, hemagglutinin-tagged $\beta$AR (HA-$\beta$AR) and 6 histidine-tagged $\beta$AR (6His-$\beta$AR), for a high efficiency purification of the $\beta$AR. Neither HA-$\beta$AR nor 6His-$\beta$AR altered activation and desensitization of the $\beta$AR significantly as compared to unmodified wild type $\beta$AR. 61% recovery of ICYP-labeled $\beta$AR was obtained with Ni-NTA column chromatography.^ The truncation 354 mutant $\beta$AR(T354), lacking putative $\beta$ARK site(s), displayed a normal epinephrine stimulation of adenylylcyclase. Although 1.0 $\mu$M epinephrine induced 60% less desensitization in T354 as compared to wild type $\beta$AR, 1.0 $\mu$M epinephrine-mediated desensitization in T354 was 35% greater than PGE$\sb1$-mediated desensitization, which is essentially identical in both WT and T354. These results suggested that sequences downstream of residue 354 may play a role in homologous desensitization and that internalization may be attributed to the additional desensitization besides the cAMP mechanism in T354 $\beta$AR. (Abstract shortened by UMI.) ^

Phosphorylation in the regulation of muscle-specific transcription

The contents of this dissertation include studies on the mechanisms by which FGF and growth factor down-stream kinases inactivate myogenin; characterization of myogenin phosphorylation and its role in regulation of myogenin activity; analysis the C-terminal transcriptional activation domain of myogenin; studies on the nuclear localization of myogenin and characterization of proteins that interact with PKC.^ Activation of muscle transcription by the MyoD family requires their heterodimerization with ubiquitous bHLH proteins such as the E2A gene products E12 and E47. I have shown that dimerization with E2A products potentiates phosphorylation of myogenin at serine 43 in its amino-terminus and serine 170 in the carboxyl-terminal transcription activation domains. Mutations of these sites resulted in enhanced transcriptional activity of myogenin, suggesting that their phosphorylation diminishes myogenin's transcriptional activity. Consistent with the role of phosphorylation at serine 170, analysis of the carboxyl-terminal transcriptional activation domain by deletion has revealed a stretch of residues from 157 to 170 which functions as a negative element for myogenin activity.^ In addition to inducing phosphorylation of myogenin, E12 also localizes myogenin to the nucleus. The DNA binding and dimerization mutants of myogenin show various deficiencies in nuclear localization. Cotransfection of E12 with the DNA binding mutants, but not a dimerization mutant, greatly enhances their nuclear binding. These data suggest that the nuclear localization signal is located in the DNA binding region and myogenin can also be nuclear localized by virtue of dimerizing with a nuclear protein.^ FGF is one of the most potent inhibitors of myogenesis and activates many down-stream pathways to exert its functions. One of these pathway is the MAP kinase pathway. Studies have shown that Raf-1 and Erk-1 kinase inactivate transactivation by myogenin and E proteins independent of DNA binding. The other is the PKC pathway. In transfected cells, FGF induces phosphorylation of thr-87 that maps to the previously identified PKC sites in the DNA binding domain of myogenin. Myogenin mutant T-N87 could resist the inhibition directed to the bHLH domain by FGF, suggesting that FGF inactivates myogenin by inducing phosphorylation of this site. In C2 myotubes, where FGF receptors are lost, the phosphatase inhibitor, okadaic acid, and phorbal ester PdBu, can also induce the phosphorylation of thr-87. This result supports the previous observation and suggests that in myotubes, other mechanisms, such as innervation, may inactivate myogenin through PKC induced phosphorylation.^ Many functions of PKC have been well documented, yet, little is known about the activators or effectors of PKC or proteins that mediate PKC nuclear localizations. Identification of PKC binding proteins will help to understand the molecular mechanism of PKC function. Two proteins that interact with the C kinase (PICKS) have been characterized, PICK-1 and PICK-2. PICK1 interacts with two conserved regions in the catalytic domain of PKC. It is localized to the perinuclear region and is phosphorylated in response to PKC activation. PICK2 is a novel protein with homology to the heat shock protein family. It interacts extensively with the catalytic domain of PKC and is localized in the cytoplasm in a punctate pattern. PICK1 and PICK2 may play important roles in mediating the actions of PKC. ^