Hair cycle and wound healing in mice with a keratinocyte-restricted deletion of FAK.

Focal adhesion kinase (FAK) is a critical component in transducing signals downstream of both integrins and growth factor receptors. To determine how the loss of FAK affects the epidermis in vivo, we have generated a mouse model with a keratinocyte-restricted deletion of fak (FAKK5 KO mice). FAK(K5 KO) mice displayed three major phenotypes--irregularities of hair cycle, sebaceous glands hypoplasia, and a thinner epidermis--pointing to defects in the proliferative capacity of multipotent stem cells found in the bulge. FAK-null keratinocytes in conventional primary culture undergo massive apoptosis hindering further analyses, whereas the defects observed in vivo do not shorten the mouse lifespan. These results suggest that the structure and the signaling environment of the native tissue may overcome the lack of signaling through FAK. Our findings point to the importance of in vivo and three-dimensional in vitro models in analyses of cell migration, proliferation, and survival. Surprisingly, the difference between FAKloxP/+ and FAKK5 KO mice in wound closure was not statistically significant, suggesting that in vivo loss of FAK does not affect migration/proliferation of basal keratinocytes in the same way as it affects multipotent stem cells of the skin.

Divergent regulation of the human atrial natriuretic peptide gene by c-jun and c-fos.

Employing transient transfection analysis in neonatal rat cardiocytes, we have demonstrated that overexpression of c-jun results in a dose-dependent induction of the human atrial natriuretic peptide (hANP) gene promoter. Studies using a series of mutations in the hANP gene promoter identified a TRE-like, cis-acting regulatory sequence which conferred c-jun sensitivity. This same region was shown to interact with the c-jun/c-fos complex in an in vitro gel mobility shift assay. Selective mutation of this site suppressed basal activity of the hANP promoter and significantly reduced c-jun-dependent activation. Overexpression of c-fos had a biphasic effect on hANP gene promoter activity. At low levels, in concert with c-jun, it activated, while at higher levels it suppressed, transcription from the hANP gene promoter. This inhibition was both cell and promoter specific. hANP gene promoter sequences which mediate c-fos-dependent inhibition appear to be separable from those responsible for the induction. In addition, the protein domains on c-fos responsible for transcriptional activation and repression can be segregated topographically, with the inhibitory activity being localized to the carboxy-terminal domain. Thus, c-fos can activate or repress hANP gene expression through two separate functional domains that act on distinct regulatory elements in the hANP gene promoter. These data imply that the ANP gene may be a physiological target for c-fos- and c-jun-dependent activity in the heart and suggest a potential mechanism linking environmental stimuli to its expression.

Focal adhesion kinase and p130Cas mediate both sarcomeric organization and activation of genes associated with cardiac myocyte hypertrophy.

Hypertrophic terminally differentiated cardiac myocytes show increased sarcomeric organization and altered gene expression. Previously, we established a role for the nonreceptor tyrosine kinase Src in signaling cardiac myocyte hypertrophy. Here we report evidence that p130Cas (Cas) and focal adhesion kinase (FAK) regulate this process. In neonatal cardiac myocytes, tyrosine phosphorylation of Cas and FAK increased upon endothelin (ET) stimulation. FAK, Cas, and paxillin were localized in sarcomeric Z-lines, suggesting that the Z-line is an important signaling locus in these cells. Cas, alone or in cooperation with Src, modulated basal and ET-stimulated atrial natriuretic peptide (ANP) gene promoter activity, a marker of cardiac hypertrophy. Expression of the C-terminal focal adhesion-targeting domain of FAK interfered with localization of endogenous FAK to Z-lines. Expression of the Cas-binding proline-rich region 1 of FAK hindered association of Cas with FAK and impaired the structural stability of sarcomeres. Collectively, these results suggest that interaction of Cas with FAK, together with their localization to Z-lines, is critical to assembly of sarcomeric units in cardiac myocytes in culture. Moreover, expression of the focal adhesion-targeting and/or the Cas-binding proline-rich regions of FAK inhibited ANP promoter activity and suppressed ET-induced ANP and brain natriuretic peptide gene expression. In summary, assembly of signaling complexes that include the focal adhesion proteins Cas, FAK, and paxillin at Z-lines in the cardiac myocyte may regulate, either directly or indirectly, both cytoskeletal organization and gene expression associated with cardiac myocyte hypertrophy.

Cis-active determinants of cardiac-specific expression in the human atrial natriuretic peptide gene.

Expression of the human atrial natriuretic peptide (hANP)gene is controlled by a series of positive and negative cis-acting regulatory elements present in the 5' flanking sequences (5'FS) of the gene. Positive elements located between -1150 and -222, relative to the transcription start site, appear to be responsible for the major portion of ANP gene expression in neonatal rat cardiac atrial cells. While neonatal ventricular cardiocytes, at a qualitative level, seem to employ regulatory signals similar to their atrial counterparts, they do so with reduced efficiency. Expression of the hANP gene in nonmyocardial cells is limited by the presence of silencer elements in the distal (-2593 to -1150) and proximal (-222 to the CAP site) 5'FS. Further characterization of a 64-base pair cardiac-specific element (-410 to -332), described previously, revealed that a core sequence of 40 base pairs is required for functional activity. This core sequence includes a previously defined DNAse-I footprint region flanked by two GC-rich segments arranged in an inverted repeat-like array. These findings suggest that the disparity in atrial vs. ventricular cardiocyte expression of the ANP gene reflects differences that are largely quantitative in nature, while differences in myocardial vs. nonmyocardial cells result from fundamental qualitative differences in the way these cells recognize and use the regulatory elements present within the 5'FS.

Selective regulation of the atrial natriuretic peptide gene by individual components of the activator protein-1 complex.

We used the human atrial natriuretic peptide (hANP) gene as a model to investigate the causal relationship between immediate early gene expression and the subsequent activation of the embryonic gene repertoire in cardiac hypertrophy. Using transient transfection analysis, we found that overexpression of individual Jun family members, alone or in combination, displayed unique activity that varied as a function of the promoter and the nature of the transfected myocyte populations under examination. In neonatal cardiac ventriculocytes, both c-jun and to a lesser extent, JunB stimulated hANP promoter activity (approximately 7- and 3- fold, respectively). When cotransfected together, a synergistic activation was observed (approximately 16-fold activation), a finding that stands in contrast to the behavior of JunB (i.e. neutral or inhibitory) with other 12-O- tetradeconoylphorbol 13-acetate response element-dependent promoters. In atriocytes, on the other hand, JunB did not itself activate the hANP promoter, and it antagonized c-jun- mediated transcription. JunD, a third member of this gene family, was devoid of activity in these transfected cultures. These findings suggest that the hANP gene promoter exhibits a broad range of responses to the individual products of the jun gene family. The response in any single situation is a function of the relative concentrations and subunit composition of the prevailing activator protein-1 complexes.

Fra-1, a Fos gene family member that activates atrial natriuretic peptide gene transcription.

Previous studies suggested that individual components of the activator protein 1 (AP-1) complex behave in a highly idiosyncratic fashion at the level of the human atrial natriuretic peptide (ANP) gene promoter. ANP gene transcription is activated by c-jun and is generally suppressed by c-fos. In the present study, fra-1, a close relative of the c-fos gene product in terms of its structure and functional activity, behaved like fos in cardiac atriocytes, effecting an approximately 50% reduction in c-jun-activatable expression of a human ANP chloramphenicol acetyltransferase (CAT) reporter. In cardiac ventriculocytes, however, fra-1 effected a synergistic amplification of the c-jun response (a 2.5-fold increase over c-jun alone). In atrial cells, fos-like proteins were not uniformly inhibitory in that a carboxy terminal deletion mutant of c-fos activated a human ANP-CAT reporter in the atriocyte cultures. Finally, using a series of domain-swap mutations in the fos/fra structural sequences, we showed that sequences at both the amino and the carboxy termini are required to realize the full fra-1-dependent stimulatory effect as well as the c-fos-dependent inhibition of ANP gene transcription. These findings suggest considerable heterogeneity in the response of the ANP promoter to different components of the AP-1 complex. Such heterogeneity may serve to broaden the range of biological responses available to this promoter as the cardiac cell attempts to adapt to perturbations in the extracellular environment.

Regulation of the human atrial natriuretic peptide gene in atrial cardiocytes by the transcription factor AP-1.

The effects of overexpression of individual components of the AP-1 transcription complex (ie, c-fos and c-jun) were examined in neonatal rat atriocyte cultures. Cotransfection of a c-jun expression plasmid together with a test plasmid linking portions of the human atrial natriuretic peptide (hANP) gene promoter to a bacterial chloramphenicol acetyl transferase (CAT) reporter resulted in a dramatic increase in ANP gene promoter activity. This effect appeared to operate through a consensus TPA (phorbol 12-myristate 13-acetate) response element (ie, AP-1 binding site) located approximately 235 base pairs upstream from the start site of transcription. This same TPA response element appears to be responsible for induction of hANP gene promoter activity by the phorbol ester TPA. Cotransfection of the same hANP promoter-CAT reporter constructs with a c-fos expression vector resulted in an unpredicted inhibition of reporter gene expression. This inhibitory activity was localized to the carboxy terminus of the c-fos protein and dominated the more conventional AP-1-dependent activity located elsewhere in the c-fos molecule. These findings suggest potential mechanisms for linking regulatory signals operative at or near the cell surface to the control of transcriptional activity in the cell nucleus.

Absence of detectable ribonucleic acid in the purified, untransformed mouse glucocorticoid receptor.

The glucocorticoid receptor (GC-R) isolated from the mouse AtT-20 pituitary tumor cell line exists in three forms. The untransformed (non-DNA-binding), 9.1S species (319K) can be converted into two transformed (DNA-binding) species. One of these (5.2 S, Mr 132K) appears to be composed of one molecule of the hormone-binding, monomeric protein (96K) plus a small RNA, while the second transformed species is the monomeric, hormone-binding subunit (3.8 S, 96K) itself. We wished to determine whether the untransformed GC-R contains RNA or if the monomer binds to RNA subsequent to subunit dissociation (which occurs during receptor transformation). Kinetic studies using both the crude and purified untransformed GC-R show that the untransformed, 9.1S GC-R dissociates into 3.8S monomeric subunits, without forming a transient 5.2S complex. The untransformed receptor was then purified with affinity chromatography, gel filtration, and DEAE-cellulose chromatography. One major protein band, corresponding in size to the GC-R monomer (94K-96K), was observed on sodium dodecyl sulfate-polyacrylamide gels upon silver staining or fluorography of [3H]dexamethasone mesylate covalently labeled receptor. In vivo 32P-labeling of AtT-20 cells, followed by purification of the untransformed GC-R, yielded two major 32P-labeled components (94K-96K and 24K). Both of these bands were protease-sensitive, contained phosphoserine, and were unaffected by ribonuclease treatment. We conclude that the untransformed mouse GC-R is wholly proteinaceous and contains no RNA. Thus, RNA binding occurs subsequent to dissociation of the oligomeric, untransformed GC-R complex into monomers.

Arachidonic acid metabolites regulate the secretion of atrial natriuretic peptide in cultured rat atrial cardiocytes.

Prostaglandins F2 alpha and E2 increase release of immunoreactive (irANP) in primary cultures of rat atrial cardiocytes. This effect is independent of cell density in the cultures and does not appear to operate through a cAMP-dependent mechanism. Studies that probed the PGF2 alpha effect with a number of different pharmacological antagonists suggest that it is tied to a calmodulin-dependent step. This latter effect does not appear to be related to increased calcium entry through voltage-gated channels in the plasma membrane nor to mobilization of ryanodine-sensitive intracellular calcium pools. Inhibitors of the lipoxygenase pathway, a second avenue of arachidonate metabolism, resulted in a decrease in irANP release from cultured atrial or ventricular cardiocytes. Leukotriene C4, a lipoxygenase product, had a modest effect to promote irANP release over a 24-h period. However, pretreatment of anesthetized rats with nordihydroguarietic acid, a lipoxygenase inhibitor, had no effect on stretch-dependent release of irANP from the heart in vivo. These findings suggest that the prostaglandins represent the more important group of arachidonate metabolites in regulating irANP release physiologically.

Ras inhibits Jun-activated human atrial natriuretic peptide gene transcription in cultured ventricular myocytes.

p21ras is a potent regulator of myogenic cell growth and differentiation. It has been implicated as playing a major role in the genesis of cardiac hypertrophy. We examined the effect of Ras overexpression on human atrial natriuretic peptide (hANP) gene expression, a marker of hypertrophy, in neonatal rat ventricular myocytes. Transient transfection of Haras, which expresses an activated form of p21ras, effected a modest stimulation of basal hANP-chloramphenicol acetyl transferase (hANPCAT) expression. Noteworthy, the same construct inhibited both c-Jun- and Jun B-stimulated hANPCAT activity (60% and 80%, respectively). Cotransfection of a dominant-negative Ras mutant reversed this inhibition completely. The inhibitory effect was promoter selective in this system. Of those tested, only the hANP and cardiac troponin T promoters were suppressed by Ras. The inhibitory effect appears to operate through a Ras-mediated increase in c-Fos activity as evidenced by (1) the absence of additivity of the Ha-Ras- and c-Fos-mediated inhibition at higher levels of proto-oncogene expression, (2) Ras-dependent activation of c-fos gene transcription, inferred from the induction of a c-fos chloramphenicol acetyl transferase reporter (3.4-fold), and (3) reversal of Ras inhibition by a c-fos antisense oligonucleotide but not by a scrambled DNA sequence of identical base composition or the complementary sense oligonucleotide. Our findings suggest that p21tas can exert a wide range of effects on the phenotype of the cardiac ventricular myocyte. The direction that these effects take appears largely to be a function of the preexisting activation state of the cell.

Ribonucleic acid is a component of the oligomeric, transformed mouse AtT-20 cell glucocorticoid receptor.

The glucocorticoid receptor from mouse AtT-20 pituitary tumor cells exists in three forms. The largest form is an untransformed (non-DNA-binding), oligomeric species (9.1 S, 8.3 nm, Mr 319 000). Two transformed (DNA-binding) forms can be generated. One is an oligomeric protein (5.2 S, 6-8.3 nm, Mr 132 000-182 000), while the other is the monomeric, hormone-binding subunit (3.8 S, 6 nm, Mr 96 000). The composition of the oligomeric, transformed receptor and its relationship to the monomeric protein were examined. The 3.8S monomer can be isolated from DEAE-cellulose (0.12 M step elution) in a form that continues to sediment at about 3.8 S on molybdate-containing sucrose gradients and at about 4.2 S on molybdate-free gradients. Addition of a non-hormone-binding component isolated from the same DEAE-cellulose column (0.5 M KCl step) can apparently interact with the 3.8-4.2 S monomer, increasing its sedimentation coefficient to 5.2 S (on molybdate-containing gradients) or 6.6 S (on low-salt, molybdate-free gradients). This factor is a macromolecule (nondialyzable) and is heat-stable (100 degrees C, 20 min). A dose-dependent shift to the higher sedimentation coefficient is observed when increasing quantities of the 0.5 M step material are added to the receptor monomer. This activity is abolished when the 0.5 M step material is treated with ribonuclease A. Further, when RNA is purified from the 0.5 M step by phenol/chloroform extraction, its ability to increase the S value of the monomer is retained. Ribonuclease treatment of the untransformed, 9.1S, oligomeric complex does not cause a significant decrease in sedimentation rate, while the same treatment of the 5.2S, oligomeric, transformed receptor (obtained after Sephadex G-25 transformation) causes a decrease in sedimentation rate to about 3.8 S. The addition of bovine liver mRNA and rRNA does not cause a shift in sedimentation rate of the receptor monomer to a discrete, higher sedimenting receptor form. However, the addition of total rabbit liver tRNA or three distinct tRNA species causes a shift in sedimentation to a similar, but not identical, form as that with the 0.5 M step material. We propose that the 5.2S, oligomeric transformed glucocorticoid receptor is composed of one monomeric hormone-binding, protein subunit (Mr 96 000) and a low molecular weight RNA (Mr 36 000). This interaction may be important for the role of the receptor in regulating gene expression.

Transformed mouse glucocorticoid receptor: generation and interconversion of the 3.8S, monomeric and 5.2S, oligomeric species.

Recent studies have implicated subunit dissociation as a possible mechanism of glucocorticoid receptor transformation [Vedeckis, W.V. (1983) Biochemistry 22, 1983-1989; Raaka, B.M., & Samuels, H.H. (1983) J. Biol. Chem. 258, 417-425]. While it is becoming increasingly evident that the untransformed (non-nuclear-binding and non-DNA-binding) glucocorticoid receptor from mouse AtT-20 cells is a 9.1S oligomeric species (Mr 290 000-360 000), two transformed species have been described for this receptor. One of these has a sedimentation coefficient of 5.2 S (on molybdate-containing gradients), while the smallest nonproteolyzed, monomeric subunit is 3.8 S. The present study was undertaken to determine which is the most common form generated both in vitro and in vivo and the structural relationship between these two forms. A wide variety of in vitro transformation protocols all yielded the 5.2S form when analyzed on molybdate-containing sucrose gradients by using a vertical tube rotor. Kinetic studies showed that the appearance of the 5.2S form coincided precisely with the appearance of transformed receptor, as defined by DEAE-cellulose elution. Furthermore, when the 3.8S and 5.2S peaks were collected from sucrose gradients directly, they were transformed receptors as defined by both DEAE-cellulose and DNA-cellulose chromatography, while the 9.1S sucrose gradient peak was untransformed when the same criteria were used. The 3.8S monomer, when isolated from high-salt sucrose gradients and then desalted, reverted to the 5.2S form (molybdate-containing gradients) or a 6.6S form (low-salt, molybdate-free gradients).(ABSTRACT TRUNCATED AT 250 WORDS)

A possible role for dephosphorylation in glucocorticoid receptor transformation.

Addition of bovine intestinal alkaline phosphatase to mouse AtT-20 cell cytosol increases the rate of glucocorticoid receptor transformation, as evidenced by a change in sedimentation rate from 9.1S to 5.2S. Acid phosphatases are completely ineffective in this regard. Alkaline phosphatase-promoted receptor transformation is both time- and dose-dependent. A variety of phosphatase inhibitors are effective in inhibiting this process, the most potent being transition metal oxyanions such as molybdate, tungstate, and arsenate. The ability of the various inhibitors to suppress alkaline phosphatase-promoted receptor transformation does not correspond well with their potencies for inhibiting para-nitrophenyl phosphate hydrolysis. However, a better correspondence between the inhibition of endogenous receptor transformation and total cytosolic phosphatase activity is observed, and both sodium fluoride and glucose-1-phosphate inhibit endogenous receptor transformation. The protease inhibitors phenyl-methylsulfonyl fluoride and antipain have no effect on receptor transformation. Surprisingly, leupeptin is effective in inhibiting alkaline phosphatase-promoted receptor transformation. Although this raises the possibility of a contaminating protease activity in the alkaline phosphatase enzyme preparation, treatment of covalently affinity-labeled receptor with the enzyme shows no proteolysis of the receptor or any other non-specifically labeled cytosolic protein. Thus, it is possible that a novel action of leupeptin, unrelated to its protease-inhibitory activity, may be involved in the suppression of receptor transformation. The studies presented here suggest that dephosphorylation of some component in cytosol is involved in the destabilization of receptor subunit interactions, resulting in glucocorticoid receptor transformation.

Signaling mechanisms underlying strain-dependent brain natriuretic peptide gene transcription.

Activation of brain natriuretic peptide (BNP) gene promoter activity represents one of the earliest and most reliable markers of ventricular cardiac myocyte hypertrophy. We recently demonstrated that mechanical strain increases immunoreactive BNP secretion, steady-state BNP mRNA levels and BNP gene transcriptional activity in neonatal rat myocyte cultures. We have also shown that strain-dependent BNP gene transcription is critically dependent on the functional integrity of a number of integrins (specfically beta1, beta3, and alpha(v)beta5 integrins) present on the surface of cardiac myocytes. When used alone, each of these antibodies resulted in a significant reduction in strain-dependent activation of a transfected hBNP-luciferase reporter and inhibition of a number of signaling pathways that have been linked to stimulation of this reporter (e.g., extracellular signal regulated kinase and c-Jun amino terminal kinase). The present study shows that combinations of these antibodies resulted in further reductions in hBNP gene promoter activity and inhibition of the relevant signaling cascades. These studies provide further support for the importance of integrin-matrix interactions in promoting strain-dependent changes in cardiac myocyte gene transcription.