Tristetraprolin Is Required for Alveolar Bone Homeostasis.

Tristetraprolin (TTP) is an RNA-binding protein that targets numerous immunomodulatory mRNA transcripts for degradation. Many TTP targets are key players in the pathogenesis of periodontal bone loss, including tumor necrosis factor-α. To better understand the extent that host immune factors play during periodontal bone loss, we assessed alveolar bone levels, inflammation and osteoclast activity in periodontal tissues, and immune response in draining cervical lymph nodes in TTP-deficient and wild-type (WT) mice in an aging study. WT and TTP-deficient (knockout [KO]) mice were used for all studies under specific pathogen-free conditions. Data were collected on mice aged 3, 6, and 9 mo. Microcomputed tomography (µCT) was performed on maxillae where 3-dimensional images were generated and bone loss was assessed. Decalcified sections of specimens were scored for inflammation and stained with tartrate-resistant acid phosphate (TRAP) to visualize osteoclasts. Immunophenotyping was performed on single-cell suspensions isolated from primary and peripheral lymphoid tissues using flow cytometry. Results presented indicate that TTP KO mice had significantly more alveolar bone loss over time compared with WT controls. Bone loss was associated with significant increases in inflammatory cell infiltration and an increased percentage of alveolar bone surfaces apposed with TRAP+ cells. Furthermore, it was found that the draining cervical lymph nodes were significantly enlarged in TTP-deficient animals and contained a distinct pathological immune profile compared with WT controls. Finally, the oral microbiome in the TTP KO mice was significantly different with age from WT cohoused mice. The severe bone loss, inflammation, and increased osteoclast activity observed in these mice support the concept that TTP plays a critical role in the maintenance of alveolar bone homeostasis in the presence of oral commensal flora. This study suggests that TTP is required to inhibit excessive inflammatory host responses that contribute to periodontal bone loss, even in the absence of specific periodontal pathogens.

MARCKS Is Necessary for Netrin-DCC Signaling and Corpus Callosum Formation.

Axons of the corpus callosum (CC), the white matter tract that connects the left and right hemispheres of the brain, receive instruction from a number of chemoattractant and chemorepulsant cues during their initial navigation towards and across the midline. While it has long been known that the CC is malformed in the absence of Myristoylated alanine-rich C-kinase substrate (MARCKS), evidence for a direct role of MARCKS in axon navigation has been lacking. Here, we show that MARCKS is necessary for Netrin-1 (NTN1) signaling through the DCC receptor, which is critical for axon guidance decisions. Marcks null (Marcks-/-) neurons fail to respond to exogenous NTN1 and are deficient in markers of DCC activation. Without MARCKS, the subcellular distributions of two critical mediators of NTN1-DCC signaling, the tyrosine kinases PTK2 and SRC, are disrupted. Together, this work establishes a novel role for MARCKS in axon dynamics and highlights the necessity of MARCKS as an organizer of DCC signaling at the membrane.

Phagocytic and macropinocytic activity in MARCKS-deficient macrophages and fibroblasts.

Macrophages express high levels of the myristoylated, alanine-rich, C kinase substrate (MARCKS), an actin cross-linking protein. To investigate a possible role of MARCKS in macrophage function, fetal liver-derived macrophages were generated from wild-type and MARCKS knockout mouse embryos. No differences between the wild-type and MARCKS-deficient macrophages with respect to morphology (Wright's stain) or actin distribution (staining with rhodamine-phalloidin, under basal conditions or after treatment with phorbol esters, lipopolysaccharide, or both) were observed. We then evaluated phagocytosis mediated by different receptors: Fc receptors tested with IgG-coated sheep red blood cells, complement C3b receptors tested with C3b-coated yeast, mannose receptors tested with unopsonized zymosan, and nonspecific phagocytosis tested with latex beads. We also studied fluid phase endocytosis in macrophages and mouse embryo fibroblasts by using FITC-dextran to quantitate this process. In most cases, there were no differences between the cells derived from wild-type and MARCKS-deficient mice. However, a minor but significant and reproducible difference in rates of zymosan phagocytosis at 45-60 min was observed, with lower rates of phagocytosis in the MARCKS-deficient cells. Our data indicate that MARCKS deficiency may lead to slightly decreased rates of zymosan phagocytosis.

Effect of reduced myristoylated alanine-rich C kinase substrate expression on hippocampal mossy fiber development and spatial learning in mutant mice: transgenic rescue and interactions with gene background.

The myristoylated alanine-rich C kinase substrate (MARCKS) is a prominent protein kinase C (PKC) substrate in brain that is expressed highly in hippocampal granule cells and their axons, the mossy fibers. Here, we examined hippocampal infrapyramidal mossy fiber (IP-MF) limb length and spatial learning in heterozygous Macs mutant mice that exhibit an approximately 50% reduction in MARCKS expression relative to wild-type controls. On a 129B6(N3) background, the Macs mutation produced IP-MF hyperplasia, a significant increase in hippocampal PKCepsilon expression, and proficient spatial learning relative to wild-type controls. However, wild-type 129B6(N3) mice exhibited phenotypic characteristics resembling inbred 129Sv mice, including IP-MF hypoplasia relative to inbred C57BL/6J mice and impaired spatial-reversal learning, suggesting a significant contribution of 129Sv background genes to wild-type and possibly mutant phenotypes. Indeed, when these mice were backcrossed with inbred C57BL/6J mice for nine generations to reduce 129Sv background genes, the Macs mutation did not effect IP-MF length or hippocampal PKCepsilon expression and impaired spatial learning relative to wild-type controls, which now showed proficient spatial learning. Moreover, in a different strain (B6SJL(N1), the Macs mutation also produced a significant impairment in spatial learning that was reversed by transgenic expression of MARCKS. Collectively, these data indicate that the heterozygous Macs mutation modifies the expression of linked 129Sv gene(s), affecting hippocampal mossy fiber development and spatial learning performance, and that MARCKS plays a significant role in spatial learning processes.

Promoter sequence, expression, and fine chromosomal mapping of the human gene (MLP) encoding the MARCKS-like protein: identification of neighboring and linked polymorphic loci for MLP and MACS and use in the evaluation of human neural tube defects.

The MARCKS-like protein (MLP), also known as F52, MacMARCKS, or MARCKS-related protein, is a widely distributed substrate for protein kinase C (PKC). Recent studies using gene disruption in vivo have demonstrated the importance of both MARCKS and MLP to the development of the central nervous system; specifically, mice lacking either protein exhibit a high frequency of neural tube defects. We isolated a genomic clone for human MLP and discovered a directly linked polymorphism (MLP1) useful for genetic linkage analysis. The MLP promoter was 71% identical over 433 bp to that of the corresponding mouse gene, Mlp, with conservation of many putative transcription factor-binding sites; it was only 36% identical over 433 bp to the promoter of the human gene, MACS, which encodes the MLP homologue MARCKS. This 433-bp fragment drove expression of an MLP-beta-galactosidase transgene in a tissue-specific and developmental expression pattern that was similar to that observed for the endogenous gene, as shown by in situ hybridization histochemistry. In contrast to MACS, the MLP and Mlp promoters contain a TATA box approximately 40 bp 5' of the presumed transcription initiation site. MLP was localized to chromosome 1p34-->1pter by analysis of human-mouse somatic cell hybrid DNA and to 1p34 by fluorescence in situ hybridization. Radiation hybrid mapping of MLP placed it between genetic markers D1S511 (LOD > 3.0) and WI9232. MACS was localized to 6q21 between D6S266 (LOD > 3.0) and AFM268uh5 by the same technique. We tested the novel MLP1 polymorphism and the MACS flanking markers in a series of 43 Caucasian simplex families in which the affected child had a lumbosacral myelomeningocele. We found no evidence of linkage disequilibrium, suggesting that these loci were not major genes for spina bifida in these families. Nonetheless, the identification of linked and neighboring polymorphisms for MACS and MLP should permit similar genetic studies in other groups of patients with neural tube defects and other neurodevelopmental abnormalities.

Widespread neuronal ectopia associated with secondary defects in cerebrocortical chondroitin sulfate proteoglycans and basal lamina in MARCKS-deficient mice.

Mice deficient in MARCKS, a prominent neural substrate for protein kinase C (PKC), die before or shortly after birth. They exhibit high frequencies of exencephaly, universal agenesis of forebrain commissures, and abnormalities of cerebral cortical and retinal lamination. We show here that these mice have wide-spread and severe neuronal ectopia in the outer layers of the developing forebrain, manifested by the migration of clusters of developing neuroblasts through the basal lamina and often through the pial membrane and into the subarachnoid space. This abnormality became apparent by Embryonic Day (E) 13 or 14, shortly after the formation of the early marginal zone. MARCKS deficiency was associated with decreased staining for marginal zone chondroitin sulfate proteoglycans; this decrease was detectable earlier in development than the neuronal ectopia. Later in development, there was also marked disruption of the basal lamina at the pial-glial interface, as evidenced by gross abnormalities in laminin and reticulin staining; however, the basal lamina appeared normal at E9.5. These data indicate that MARCKS is required for the prevention of neuronal ectopia during development. Potential mechanisms responsible for the neuronal ectopia in the MARCKS-deficient mice include decreased expression or increased proteolytic destruction of basal lamina proteins and marginal zone chondroitin sulfate proteoglycans in the developing brain.

Disruption of the gene encoding the mitogen-regulated translational modulator PHAS-I in mice.

PHAS-I is the prototype of a group of eIF4E-binding proteins that can regulate mRNA translation in response to hormones and growth factors. To investigate the importance of PHAS-I in the physiology of the intact animal, we disrupted the PHAS-I gene in mice. Tissues and cells derived from the knockout mice contained no detectable PHAS-I protein. A related protein, PHAS-II, and eIF4E were readily detectable in tissues from these animals, but neither appeared to be changed in a compensatory manner. Mice lacking PHAS-I appeared normal at birth. However, male knockout mice weighed approximately 10% less than controls at all ages, whereas female weights were similar to those of controls. Both males and females were fertile. Tissues from adult animals appeared to be normal by routine histological staining techniques, as were routine blood cell counts and chemistries. Fibroblasts derived from PHAS-I-deficient mouse embryos exhibited normal rates of growth and overall protein synthesis, responded normally to serum stimulation of ornithine decarboxylase activity and cell growth, and rapamycin inhibition of cell growth. Under these experimental conditions, PHAS-I is apparently not required for the normal development and reproductive behavior of female mice, but is required for normal body weight in male mice; the mechanisms responsible for this phenotype remain to be determined.

Developmental expression of MARCKS and protein kinase C in mice in relation to the exencephaly resulting from MARCKS deficiency.

The roles of protein kinase C and its substrates in development are poorly understood. Recently, we disrupted the mouse gene for a major cellular substrate for protein kinase C, the MARCKS protein (Proc. Natl. Acad. Sci. USA, 92, 944-948, 1995). The resulting phenotype consisted of universal perinatal lethality, agenesis of the corpus callosum and other forebrain commissures, and neuronal ectopia and other cortical and retinal lamination disturbances. These mice also had high frequencies of exencephaly (25% overall, 35% in females). In the present study, we have examined the normal expression of MARCKS and the various isozymes of protein kinase C at the time of cranial neural tube closure, in an attempt to correlate MARCKS expression in time and anatomical location with the exencephaly characteristic of MARCKS deficiency. Failure of neural tube closure occurred at various sites in the cranial neural tube, suggesting a cellular functional defect that was not limited to a specific location. Non-exencephalic MARCKS-deficient embryos appeared to be anatomically normal on embryonic day (E) 8.5-9.5. MARCKS and PKC alpha were expressed at the plasma membrane of the neuroepithelial cells comprising the future neural tube, as well as in the surface ectoderm and underlying mesenchyme. Endogenous protein kinase C species, comprising either or both alpha and delta, were capable of phosphorylating MARCKS in intact E8.5 embryos. Thus, MARCKS is expressed at the plasma membranes of the specific cell types involved in cranial neurulation; its deficiency presumably results in a still-to-be-elucidated functional defect in these cells that leads to exencephaly in a high proportion of cases.

MARCKS deficiency in mice leads to abnormal brain development and perinatal death.

The MARCKS protein is a widely distributed cellular substrate for protein kinase C. It is a myristoylprotein that binds calmodulin and actin in a manner reversible by protein kinase C-dependent phosphorylation. It is also highly expressed in nervous tissue, particularly during development. To evaluate a possible developmental role for MARCKS, we disrupted its gene in mice by using the techniques of homologous recombination. Pups homozygous for the disrupted allele lacked detectable MARCKS mRNA and protein. All MARCKS-deficient pups died before or within a few hours of birth. Twenty-five percent had exencephaly and 19% had omphalocele (normal frequencies, < 1%), indicating high frequencies of midline defects, particularly in cranial neurulation. Nonexencephalic MARCKS-deficient pups had agenesis of the corpus callosum and other forebrain commissures, as well as failure of fusion of the cerebral hemispheres. All MARCKS-deficient pups also displayed characteristic lamination abnormalities of the cortex and retina. These studies suggest that MARCKS plays a vital role in the normal developmental processes of neurulation, hemisphere fusion, forebrain commissure formation, and formation of cortical and retinal laminations. We conclude that MARCKS is necessary for normal mouse brain development and postnatal survival.

Protein kinase C isozyme distribution and down-regulation in relation to insulin-stimulated c-fos induction.

Insulin can stimulate the expression of c-fos and other immediate early genes in many insulin-sensitive cell types. We found previously that this effect of insulin was essentially normal in cells in which protein kinase C (PKC) was down-regulated by 16 h of exposure to 16 microM phorbol 12-myristate 13-acetate (PMA). However, recent studies by other groups have suggested that much of the insulin response was lost in down-regulated cells and that at least part of the remaining response could be due to a species of PKC beta that is resistant to down-regulation. To resolve these discrepancies, we performed PKC enzyme assays and immunoblots on HIRc-B, H4IIEC3, and BC3H-1 cells before and after down-regulation with PMA. PKC enzyme activity was undetectable in the first two cell types after down-regulation; in addition, in all three cells the expressed PKC isozymes other than PKC zeta were completely down-regulated by the PMA exposure. Neither PKC beta 1 nor beta 2 was expressed in any of the cells, as determined by immunoblotting with isotype-specific antibodies. As in our previous studies, c-Fos mRNA accumulation in response to insulin was essentially normal in the down-regulated HIRc-B and H4IIEC3 cells, whereas the response to re-added PMA was completely abolished. PKC zeta was expressed in all three cell types and was not down-regulated by PMA; these and other considerations leave open the possibility that this and other "atypical" PKC isotypes could play a role in insulin action.

Protein kinase C-mediated phosphorylation and calmodulin binding of recombinant myristoylated alanine-rich C kinase substrate (MARCKS) and MARCKS-related protein.

The myristoylated alanine-rich C kinase substrate (MARCKS) and the MARCKS-related protein (MRP) are members of a distinct family of protein kinase C (PKC) substrates that also bind calmodulin in a manner regulated by phosphorylation by PKC. The kinetics of PKC-mediated phosphorylation and the calmodulin binding properties of intact, recombinant MARCKS and MRP were investigated and compared with previous studies of synthetic peptides spanning the PKC phosphorylation site/calmodulin binding domains (PSCBD) of these proteins. Both MARCKS and MRP were high affinity substrates for the catalytic fragment of PKC, and their phosphorylation occurred with positive cooperativity (MARCKS: S0.5 = 100 nM, KH = 1.43; MRP: S0.5 = 238 nM, KH = 1.72). These affinities are similar to the values determined from studies of their respective PSCBD peptides. Two-dimensional mapping of MRP and its synthetic PSCBD peptide yielded identical patterns of tryptic phosphopeptides, indicating that, as in the case of MARCKS, all of the PKC phosphorylation sites in MRP lie within the 24-amino acid PSCBD. Sequence analysis of tryptic phosphopeptides revealed that the first and third, but not the second, serines in the MRP PSCBD were phosphorylated by PKC. Both MARCKS and MRP bound dansyl-calmodulin with high affinity, with a Kapp of 4.6 and 9.5 nM, respectively. Phosphorylation of MARCKS and MRP by PKC disrupted the protein-calmodulin complexes, with half-lives of 4.0 and 3.5 min, respectively. These studies suggest that intact, recombinant MARCKS and MRP are accurately modeled by their synthetic PSCBD peptides with respect to PKC phosphorylation kinetics and their phosphorylation-dependent calmodulin binding properties.

Severely decreased MARCKS expression correlates with ras reversion but not with mitogenic responsiveness.

Phorbol ester-inducible phosphorylation of MARCKS, the '80-kDa' substrate of protein kinase C, was undetectable in several phenotypically dominant, non-transformed revertants independently derived from the ras-transformed cell line NIH3T3 DT-ras. Extremely low expression of MARCKS protein accounted for this apparent lack of phosphorylation. MARCKS-encoding mRNA levels were correspondingly decreased relative to normal and ras-transformed cells in all four ras revertant cell lines studied: C-11 and F-2, derived by 5-azacytidine treatment and selection with ouabain; CHP 9CJ, derived by ethylmethane sulfonate mutagenesis and selection with cis-hydroxy-L-proline; and 12-V3, derived by transfection with the human Krev-1 gene. However, re-expression of MARCKS after transfection of a cloned MARCKS cDNA into the C-11 ras revertant cells was not sufficient to induce retransformation. In fact, no significant difference in sensitivity to mitogenic stimulation by phorbol esters was observed among several cell lines expressing widely varying levels of MARCKS. This evidence argues against a direct role for MARCKS in mitogenic signaling. However, the strong correlation between attenuation of MARCIS expression and phenotypically dominant ras reversion suggests that a common negative regulatory mechanism might be responsible for both effects, presenting a potentially useful strategy for identifying factors involved in transducing the ras signal.

Chromosomal mapping of the human (MACS) and mouse (Macs) genes encoding the MARCKS protein.

The myristoylated, alanine-rich C-kinase substrate, or MARCKS protein, is a major cellular substrate for protein kinase C that is also a high-affinity calmodulin-binding protein. In addition, it is the prototype of a small family of myristoylated, calmodulin-binding protein kinase C substrate proteins. We isolated a phage clone from a mouse genomic library that spanned the entire coding sequence of the mouse MARCKS protein. The first 612 bp of the putative promoter was 89% identical to a corresponding region of the human promoter, and contained at least 59 potential transcription factor binding sites in analogous locations; both human and mouse promoters lacked TATA boxes. The mouse genomic probe was used to localize the mouse gene to chromosome 10, in the middle of a linkage group that corresponds to a region on human chromosome 6q. These data strongly suggested that the human gene would localize to 6q21. This was confirmed by studies of DNA from a patient with del(6)(q21), in which expression of the human gene encoding MARCKS, MACS, was only about 50% of normal; MARCKS mRNA expression in lymphoblast RNA from this patient was only 22% of normal. These studies confirm that the mouse and human MARCKS proteins are products of the same genes in their respective species; differences in their primary sequence can therefore be attributed to species variation rather than to the existence of related genes.

Characteristics of the F52 protein, a MARCKS homologue.

A recently cloned mouse cDNA designated F52 encodes a putative protein with striking sequence similarity to the MARCKS protein, a major cellular substrate for protein kinase C (PKC). Major regions of sequence similarity include the amino-terminal myristoylation consensus sequence and the central calmodulin-binding/PKC phosphorylation site domain. The F52 protein was expressed in Escherichia coli with apparent M(r) 50,000; it was a substrate for PKC and comigrated on two-dimensional electrophoresis with a myristoylated protein whose phosphorylation was stimulated by phorbol 12-myristate 13-acetate in mouse neuroblastoma cells. The F52 protein also was myristoylated in E. coli by co-expression with N-myristoyltransferase. A 24-amino acid peptide derived from the protein's phosphorylation site domain was a good substrate for PKC; like the cognate MARCKS peptide, it was phosphorylated with high affinity (S0.5 = 173 nM) and positive cooperativity (KH = 5.4). The F52 peptide also bound calmodulin with high affinity (Kd = less than 3 nM); this binding could be disrupted by phosphorylation of the peptide with PKC, with a half-time of 8 min. The F52 protein is clearly a member of the MARCKS family as defined by primary sequence; in addition, the two proteins share several key attributes that may be functionally important.

The human myristoylated alanine-rich C kinase substrate (MARCKS) gene (MACS). Analysis of its gene product, promoter, and chromosomal localization.

The expression of a major cellular substrate for protein kinase C, the MARCKS protein, is regulated in a cell-, tissue-, and developmental stage-specific fashion; in addition, this expression can be stimulated acutely by various cytokines in certain cell types. We have begun to characterize the human gene in order to elucidate the genetic elements responsible for this highly regulated expression. We first cloned a human MARCKS cDNA, which encoded a predicted protein of 332 amino acids (Mr 31,600) that was approximately 89, 74, and 59% identical to the bovine, mouse, and chicken proteins, respectively. Regions conserved at the amino acid level included the amino-terminal myristoylation consensus sequence, the site of intron splicing, and the phosphorylation site domain. The human cDNA was used to demonstrate that tumor necrosis factor-alpha could rapidly stimulate MARCKS gene transcription in the human promyelocytic leukemia cell line HL60. Genomic clones were then isolated; sequence analysis identified a putative promoter region that had no TATA box and contained multiple transcription initiation sites in a region spanning 57 base pairs (bp). This was followed by a 5'-untranslated region of approximately 400 bp, which displayed a complex predicted secondary structure with a delta G of -73.4 kcal/mol. Plasmid constructions containing between 52 and 1453 bp of the human MARCKS promoter linked to the human growth hormone gene were then used in transient expression experiments. Constructions containing 52 and 110 bp of the MARCKS promoter did not exhibit promoter function while the larger constructions all exhibited promotor function; the 248-bp fragment of the MARCKS promoter was 80% as effective as the human ferritin promoter in stimulating expression of human growth hormone in intact cells. Using an insert from the human genomic clone as a probe, we identified human chromosome 6, q21-qter, as the location of the MARCKS gene; this has been assigned the gene symbol MACS.

Insulin activation of protein kinase C: a reassessment.

Although insulin is known to activate several protein serine/threonine protein kinases, its ability to activate protein kinase C remains controversial. We reinvestigated this question, taking advantage of several technical advances such as the development of fibroblast cell lines that overexpress normal human insulin receptors, and the development of antibodies to and expression vectors for the myristoylated, alanine-rich C kinase substrate (MARCKS) protein, a major cellular substrate for protein kinase C. In HIR 3.5 cells, a mouse 3T3 cell derivative that expresses about 6 x 10(6) human insulin receptors/cell, insulin (70 nM for 10 min) stimulated phosphorylation of the MARCKS protein by approximately 2-fold (p less than 0.005). This phosphorylation was not further increased by different times of insulin exposure, different insulin concentrations, or longer periods of serum deprivation. The insulin stimulation represented about 14% of the response to phorbol 12-myristate 13-acetate and about 17% of the response to 10% fetal calf serum. No significant stimulation of MARCKS protein phosphorylation was seen in four other insulin-sensitive cell lines, in which insulin is known to activate other protein serine/threonine kinases: HIRC-B, BC3H-1, 3T3-L1 adipocytes, and H35 rat hepatoma cells made to stably express the MARCKS protein. In these four cell lines, serum and/or phorbol 12-myristate 13-acetate exerted a large stimulatory effect on MARCKS protein phosphorylation. We conclude that insulin may activate protein kinase C to a minor extent in certain cell types that vastly overexpress insulin receptors; however, we believe that this effect of insulin is unlikely to be of physiological importance.

Cellular expression of mutant insulin receptors interferes with the rapid transcriptional response to both insulin and insulin-like growth factor I.

We examined the expression of the proto-oncogene c-fos and the early growth response gene, Egr-1, in Rat 1 fibroblasts expressing high levels of normal or mutated human insulin receptors (McClain, D. A., Maegawa, H., Lee, J., Dull, T. J., Ullrich, A., and Olefsky, J. M. (1987) J. Biol. Chem. 262, 14663-14671). In cells expressing large numbers of normal human insulin receptors (HIRc-B cells), insulin (greater than or equal to 0.7 nM) stimulated the rapid accumulation of mRNAs for both genes. This response was blunted, but not lost, in cells expressing large numbers of human insulin receptors missing 43 amino acids at the carboxyl terminus of the beta-subunit. In contrast, the insulin response was completely absent in cells expressing large numbers of receptors that contained a mutation at the ATP-binding site that destroyed intrinsic protein tyrosine kinase activity (A/K 1018-B cells). This mutation also suppressed the modest transcriptional response to insulin that occurred in the parental Rat 1 cells. The transcriptional response to serum was normal in the A/K 1018-B cells, even after protein kinase C depletion; however, the response to insulin-like growth factor I was essentially lost. These studies suggest that overexpression of a kinase-deficient insulin receptor can suppress the transcriptional response to both insulin and insulin-like growth factor I that is ordinarily transduced through endogenous insulin and insulin-like growth factor I receptors, respectively. Competition for shared substrates of these related receptor kinases is a potential mechanism for this effect.

Rapid insulin-stimulated accumulation of an mRNA encoding a proline-rich protein.

By differential hybridization screening of a cDNA library derived from insulin-stimulated cells, we selected a clone which hybridized to an mRNA species that rapidly accumulated in response to insulin. The insert from this clone encoded a putative polypeptide of Mr 33,600, pI 11.2; because the protein was enriched in proline residues (14.4 mol %) and contained three Pro-Pro-Pro-Pro repeats, we have tentatively labeled it tris-tetraprolin (TTP). The function of this protein is not known, but it contains two regions very rich in proline (30-40 mol %); similar proline-rich regions have been shown to be involved in transcriptional activation by other proteins. The mRNA (2.0 kilobases) encoding the TTP protein was essentially undetectable in serum-deprived HIR 3.5 cells, but accumulated dramatically within 10 min of stimulation by insulin. This effect appeared to be due to insulin acting through the intrinsic protein-tyrosine kinase activity of its own receptor. Insulin induction of TTP mRNA accumulation was prevented by actinomycin D and superinduced by cycloheximide. Accumulation of TTP mRNA was also stimulated by a variety of growth factors and active phorbol esters; however, the insulin effect was virtually normal in cells depleted of protein kinase C. A single TTP gene appeared to be present in the mouse genome. This gene joins the group of genes whose members are rapidly transcribed in response to insulin and other mitogens.

Molecular cloning, sequence, and expression of a cDNA encoding the chicken myristoylated alanine-rich C kinase substrate (MARCKS).

Little is known about the important cellular substrates for protein kinase C (PKC) and their function in the cellular processes influenced by this kinase. This paper describes the molecular characteristics of a prominent cellular substrate for PKC in chicken cells, known as the myristoylated alanine-rich C kinase substrate, or MARCKS protein. The chicken protein was studied because it was apparently at least 20 kilodalton smaller than its mammalian counterpart; we hoped that regions of sequence similarity might point to conserved regions of biological importance. Using the bovine MARCKS cDNA as a probe, we selected a positive clone from a chicken brain cDNA library that contained an insert of about 1.5 kilobase, in which a single open reading frame encoded a protein of 281 amino acids, 27.7 kilodaltons, pI 5.26. This protein contained the sequences of ten tryptic peptides derived from the purified chicken brain protein. Expression of the cDNA insert in mammalian cells confirmed that the open reading frame encoded a protein that comigrated on two-dimensional electrophoresis with the authentic chicken protein, and could be phosphorylated by exposure of the cells to active phorbol esters. When the chicken and bovine protein sequences were compared, the two major regions of sequence identity were: 1) the amino terminal region containing a myristoylation consensus sequence and an mRNA splice site, and 2) a highly basic internal domain of 25 amino acids that contained all of the serines known to be phosphorylated by PKC in the intact protein. These conserved regions are likely to represent domains of some functional importance for this widely distributed cellular substrate for PKC.

Characterization of the phosphorylation sites in the chicken and bovine myristoylated alanine-rich C kinase substrate protein, a prominent cellular substrate for protein kinase C.

Little is known about the important cellular substrates for protein kinase C and their potential roles in mediating protein kinase C-dependent processes. We evaluated the protein kinase C phosphorylation sites in a major cellular substrate for the kinase, a protein of apparent Mr 80,000 in bovine and 60,000 in chicken tissues; we have recently determined the primary sequences of these proteins and tentatively named them the myristoylated alanine-rich C kinase substrates. The proteins were purified to apparent homogeneity from bovine and chicken brains, phosphorylated with protein kinase C, digested with trypsin, and the phosphopeptides purified and sequenced. Four distinct phosphopeptides were identified from both the bovine and chicken proteins. Two of the phosphorylated serines were contained in the repeated motif FSFKK, one in the sequence LSGF, and one in the sequence SFK. All four sites were contained within a basic domain of 25 amino acids which was identical in the chicken and bovine proteins. All of the sites phosphorylated in the cell-free system appeared to be phosphorylated in intact cells; an additional site may have been present in the proteins from intact cells. The identity of the phosphorylation site domains from two proteins of overall 65% amino acid sequence identity suggests a potential role for this domain in the physiological function of the myristoylated alanine-rich C kinase substrate proteins.