The S49 Kin- cell line transcribes and translates a functional mRNA coding for the catalytic subunit of cAMP-dependent protein kinase

The S49 mouse lymphoma mutant cell line Kin- is resistant to the cytotoxic effects of elevated cAMP levels, has no detectable cAMP-dependent protein kinase activity, and has depressed levels of cAMP-binding regulatory subunits. We demonstrate that although the Kin- cell line lacks detectable catalytic subunit protein, these cells express wild-type levels of mRNA for both C alpha and C beta catalytic subunit isoforms. Translation of C alpha mRNA appears to be normal in the Kin- cell, based on the observation that C alpha mRNA associates with large polyribosomes in both wild-type and Kin- cells. We cloned the C alpha cDNA from Kin- cells and show that its transient expression in another cell type leads to activation of a cAMP-sensitive luciferase reporter gene, suggesting that functional C alpha protein is made. In addition to having catalytic activity, the C alpha subunit from Kin- cells is inhibited in the presence of mouse RI alpha regulatory subunit, indicating that formation of the holoenzyme complex is normal. We suggest that the mutation responsible for the Kin- phenotype is in a cellular component that directly or indirectly causes Kin- catalytic subunit protein to be degraded rapidly.     

Multiple mRNA species code for the catalytic subunit of the cAMP-dependent protein kinase from LLC-PK1 cells. Evidence for two forms of the catalytic subunit

We present evidence for the existence of two forms of the catalytic (C) subunit of the cAMP-dependent protein kinase. A lambda gt-11 cDNA library constructed from poly(A)-rich RNA from the porcine kidney cell line, LLC-PK1, was screened using a 1.5-kb EcoRI fragment from a bovine cDNA for the C subunit. Two independent classes of cDNAs were identified on the basis of partial restriction map and sequence data. These two cDNAs, lambda CAT4 and lambda CAT3, apparently encode two forms of C subunit designated C alpha and C beta, respectively. The nucleotide sequence of the C alpha and C beta cDNAs revealed differences in the coding region and particularly in the 3' untranslated region. However, the deducted amino acid sequences of C alpha and C beta subunits were 96% homologous to the sequences so far determined. Specific probes from the 3' coding region of the two cDNA species were used to investigate C subunit mRNA expression in LLC-PK1 cells. Northern analysis showed a major mRNA species of 2.8 kb with the C alpha probe while the C beta probe detected two mRNA species of 5.0 kb and 3.8 kb. These data were supported by genomic blot analysis which showed distinct hybridization patterns with either the C alpha or C beta probes. All the available evidence suggests that at least two distinct genes encode the C subunit which are expressed in LLC-PK1 cells.     

Mutation of glycine 49 to valine in the alpha subunit of GS results in the constitutive elevation of cyclic AMP synthesis

The G-protein GS couples hormone-activated receptors with adenylyl cyclase and stimulates increased cyclic AMP synthesis. Transient expression in COS-1 cells of cDNAs coding for the GS alpha-subunit (alpha S) or alpha S cDNAs having single amino acid mutations Gly49----Val or Gly225----Thr elevated cyclic AMP levels, resulting in the activation of cyclic AMP dependent protein kinase. Stable expression in Chinese hamster ovary cells of alpha S Val49 cDNA resulted in a small constitutive elevation of cyclic AMP that was sufficient to persistently activate cyclic AMP dependent protein kinase activity 1.5-2-fold over basal activity. Stable expression of wild-type alpha S or alpha S Thr225 in Chinese hamster ovary cells was less effective in sustaining elevated cyclic AMP synthesis and kinase activation compared to alpha SVal49.     

Evidence for a second isoform of the catalytic subunit of cAMP-dependent protein kinase

We have used a previously characterized mouse cDNA clone for the catalytic (C) subunit of cAMP-dependent protein kinase (Uhler, M. D., Carmichael, D. F., Lee, D. C., Chrivia, J. C., Krebs, E. G., and McKnight, G. S. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 1300-1304), which we designate C alpha, to isolate cDNA clones coding for a second isoform of the C subunit, C beta. C alpha cDNA clones hybridize to a 2.4-kilobase mRNA on Northern blots whereas C beta cDNA clones detect a 4.3-kilobase mRNA. Nucleotide sequence comparison between C alpha and C beta cDNA clones shows that the C beta cDNA codes for a protein which shows 91% identity with C alpha. Determination of mRNA levels for C beta in various tissues shows that it is most highly expressed in brain although it is detectable in all tissues examined. The presence of two genes coding for the C subunit of cAMP-dependent protein kinase may explain past reports of heterogeneity in C subunit protein preparations.     

Role of threonine-286 as autophosphorylation site for appearance of Ca2(+)-independent activity of calmodulin-dependent protein kinase II alpha subunit.

To confirm directly the role of Thr-286 as the autophosphorylation site responsible for the appearance of Ca2(+)-independent activity of Ca2+/calmodulin-dependent protein kinase II alpha subunit, we constructed two mutated cDNAs of Thr-286 to Pro or Ala using site-directed mutagenesis and introduced into Chinese hamster ovary cells. The mutant enzymes expressed in stable cell lines were partially purified and their catalytic properties were confirmed to be similar to those of wild-type kinase, except that the mutant kinase which were deprived of Thr-286 as an autophosphorylation site could not be converted to Ca2(+)-independent forms upon autophosphorylation. Other autophosphorylation sites of the mutants were essentially unchanged from those of the wild-type kinase and phosphorylation of such sites did not convert them to Ca2(+)-independent forms. The results indicate that Thr-286 is the only indispensable autophosphorylation site for the appearance of Ca2(+)-independent activity of calmodulin-dependent protein kinase II alpha subunit.     

A cloned bovine cDNA encodes an alternate form of the catalytic subunit of cAMP-dependent protein kinase

While attempting to isolate a cDNA clone for the catalytic subunit of the bovine cAMP-dependent protein kinase, we have isolated cDNAs which code for a protein slightly different than the known amino acid sequence. The alternate cDNA was identified by screening a bovine pituitary cDNA library using synthetic oligonucleotides predicted from the known amino acid sequence of the catalytic subunit. The cDNA which we identified, encodes a protein which is 93% identical to the known amino acid sequence of the bovine catalytic subunit. It seems likely that this cDNA represents a previously undiscovered catalytic subunit of the cAMP-dependent protein kinase. The mRNA for the alternate catalytic subunit is different in size from the mRNA coding for the previously known catalytic subunit and also has a different tissue distribution. These findings suggest that there are at least two different genes for the catalytic subunit. The differences in amino acid sequence and tissue distribution suggest the possibility of important functional differences in the two enzymes.     

Characterization of cyclic AMP-requiring yeast mutants altered in the catalytic subunit of protein kinase

The cyr2 mutant of yeast, Saccharomyces cerevisiae, required cAMP for growth at 35 degrees C. The cyr2 mutation was suppressed by the bcy1 mutation which resulted in deficiency of the regulatory subunit of cAMP-dependent protein kinase. The DEAE-Sephacel elution profile of cyr2 cAMP-dependent protein kinase was markedly different from that observed for the wild-type enzyme. With histone as substrate, the cAMP-dependent protein kinase activity of cyr2 cells showed 100-fold greater Ka value for activation by cAMP at 35 degrees C than that of the wild-type cells, while the Kd value for cAMP of the mutant enzyme was not altered. The electrophoretic character, molecular weight, and pI value of the regulatory subunit of the mutant enzyme were the same as those of the wild-type enzyme. When histone, trehalase, and glutamate dehydrogenase were used as substrate, the free catalytic subunit of the mutant enzyme showed a markedly decreased affinity for ATP and was more thermolabile compared to that of the wild-type enzyme. The results indicated that the cyr2 phenotype was produced by a structural mutation in the cyr2 gene coding for the catalytic subunit of cAMP-dependent protein kinase in yeast.     

Cloning of the C alpha catalytic subunit of the bovine cAMP-dependent protein kinase.

The bovine C alpha type catalytic subunit of the cAMP-dependent protein kinase was cloned. A partial cDNA was isolated from a bovine heart cDNA library. This clone contained 120 bp of the coding sequence and the entire 3' untranslated region of 1431 bp. The complete coding region was cloned by PCR amplification from total bovine heart and skeletal muscle RNA. The sequence of the 3' oligonucleotide was taken from the partial cDNA clone whereas the 5' oligonucleotide was chosen by comparison of sequences of published C alpha subunits from other species. In the deduced amino acid sequence there is one deviation from the published bovine C alpha protein sequence, aspartic acid 286 is exchanged by an asparagine. The C alpha mRNA was found to be expressed differentially in various bovine tissues.     

Decreased expression of the type I isozyme of cAMP-dependent protein kinase in tumor cell lines of lung epithelial origin

A spontaneous transformant derived from a mouse lung epithelial cell line exhibited decreased cAMP-dependent protein kinase (PKA) activity. DEAE column chromatography demonstrated that this was caused by specific loss of the type I PKA isozyme (PKA I). Western immunoblot analysis indicated that indeed several mouse lung tumor-derived cell lines and spontaneous transformants of immortalized, nontumorigenic lung cell lines contained less PKA I regulatory subunit (RI) protein than normal cell lines. PKA II regulatory subunit protein differed only slightly among cell lines and showed no conspicuous trend between normal and neoplastic cells. The decrease in RI was apparently concomitant with decreased catalytic (C) subunit levels in neoplastic cells since no free catalytic subunit activity was detected by DEAE chromatography. Northern blot analysis using RI alpha and C alpha cDNA probes showed that the levels of RI alpha and C alpha mRNAs paralleled their intracellular protein concentrations; neoplastic cell lines contained significantly less RI alpha and C alpha mRNAs than the normal cell line. The decreased expression of both RI and C subunits therefore results in a net decrease of PKA I in neoplastic lung cells, an isozymic difference which may account for the differential effects of cAMP analogs on cell growth and differentiation in normal and neoplastic cells.     

Molecular genetic analysis of the regulatory and catalytic domains of protein kinase C

We have constructed the expression plasmids harboring protein kinase C (PKC) mutant cDNAs with a series of deletions in the PKC coding region. These plasmids were transfected into COS7 cells to characterize the PKC mutants. Immunoblot analysis using the anti-PKC antibody identified proteins with the Mr values expected from the PKC mutant cDNAs in the extracts from COS7 cells. The wild-type PKC, when expressed in COS7 cells, conferred increased phorbol ester binding activity on intact cells; but the PKC mutants with the deletion around the C1 region did not show this activity. The wild-type PKC showed protein kinase activity dependent on phospholipid, Ca2+, and phorbol ester, whereas these PKC mutants exhibited protein kinase activity independent of the activators in a cell-free system. A PKC mutant cDNA with the deletion in the C2 region gave increased phorbol ester binding activity. Protein kinase activity of this mutant was much less dependent on Ca2+ compared with the wild-type PKC. A PKC mutant cDNA with the deletion in the C3 region conferred increased phorbol ester binding activity, but neither activator-dependent nor -independent protein kinase activity. These results indicate that elimination of the C1 region of PKC gives rise to constitutively active PKC independent of phospholipid, Ca2+, and phorbol ester and that the C1-C3 regions play distinct roles in the regulatory and catalytic function of PKC. In another series of experiments, transfection of some PKC mutant cDNAs with the deletions around the C1 region into Chinese hamster ovary and Jurkat cells activated the activator protein-1-binding element or the c-fos gene enhancer linked to the chloramphenicol acetyltransferase reporter gene in the absence of phorbol ester. Microinjection of these constructs into Xenopus oocytes induced initiation of germinal vesicle breakdown, indicating that they stimulated the PKC pathway in vivo. Thus, the phorbol ester-independent PKC mutant cDNAs could be a powerful tool to investigate the transmembrane signaling pathway mediated by PKC.     

Characterization of a cyclic AMP-resistant Chinese hamster ovary cell mutant containing both wild-type and mutant species of type I regulatory subunit of cyclic AMP-dependent protein kinase

We have characterized a cyclic AMP-resistant Chinese hamster ovary (CHO) cell mutant in which one of two major species of type I regulatory subunit (RI) of cyclic AMP-dependent protein kinase is altered. Wild-type CHO cell extracts contain two cyclic AMP-dependent protein kinase activities. As shown by DEAE-cellulose chromatography, there is a peak of type I protein kinase activity in mutant extracts, but the type II protein kinase activity is considerably reduced even though free type II regulatory subunit (RII) is present. The type I kinase from the mutant has an altered RI (RI*) whose KD for the binding of 8-N3[32P] cAMP (KD = 1.3 X 10(-5) M) is increased by more than 200-fold compared to RI from the wild-type enzyme (KD = 5.5 X 10(-8) M). No differences were found between the catalytic subunits from the wild-type and mutant type I kinases. A large portion of RI in mutant and wild-type extracts is present in the free form. The RI* derived from mutant type I protein kinase shows altered labeling by 8-N3[32P]cAMP (KD = 1.3 X 10(-5) M) whereas the free RI from the mutant is labeled normally by the photoaffinity label (KD = 7.2 X 10(-8) M), suggesting that the RI* which binds to the catalytic subunit is functionally different from the free form of RI. The decreased amount of type II kinase activity in the mutant appears to be due to competition of RI* with RII for binding to the catalytic subunit. Translation of mRNA from wild-type CHO cells results in the synthesis of two different charge forms of RI, providing biochemical confirmation of two different species of RI in CHO cells. Additional biochemical evidence based on isoelectric focusing behavior of 8-N3[32P]cAMP-labeled RI species and [35S]methionine-labeled RI from mutant and wild-type extracts confirms the charge heterogeneity of RI species in CHO cells. These genetic and biochemical data taken together are consistent with the conclusion that there are at least two different species of RI present in CHO cells and that one of these species is altered in the mutant analyzed in this work.     

Cellular localization and age-dependent changes in mRNA for cyclic adenosine 3',5'-monophosphate-dependent protein kinases in rat testis

Gonadotropin activation of cyclic adenosine 3',5'-monophosphate (cAMP)-dependent protein kinases plays an important role in the regulation of testicular function. This study was undertaken to establish the expression of various subunits of cAMP-dependent protein kinases in different testicular cell types as well as during sexual maturation. RNA was extracted from cultured Sertoli cells, cultured peritubular cells, germ cells (pachytene spermatocytes, round spermatids), tumor Leydig cells, as well as whole testis from rats of various ages. Messenger RNA levels were studied by Northern analysis using available cDNA probes. The regulatory subunit (R) designated RII51 was found to be predominantly expressed in cAMP-stimulated Sertoli cells and tumor Leydig cells. Much lower levels were found in cultured peritubular cells and germ cells. A 2.9- and 3.2-kb mRNA for the RI subunit were found at about similar levels in all cell types, whereas the smaller 1.7-kb mRNA was expressed in high levels in germ cells. Also, the catalytic subunit (C) of cAMP-dependent protein kinase, designated C alpha, was expressed in all cell types; the highest mRNA levels for this subunit were found in germ cells and in tumor Leydig cells. The 1.7-kb mRNA for androgen-binding protein (ABP) was abundant in cAMP-stimulated Sertoli cells and was not present in other cell types of the testis. Furthermore, the cellular localization of the cAMP-dependent protein kinase subunits was also supported by developmental studies. The mRNA level of the RII51 3.2-kb species was relatively constant until Day 30, after which there was a tendency to decrease. A 1.6-kb message first appeared at greater ages. The mRNA for the smaller 1.7-kb species of RI, as well as the C alpha, showed a significant increase during development, supporting an enrichment of these mRNAs in germ cells. Messenger RNA levels for ABP were not detected in testis from 5- to 10-day-old rats but increased up to Day 30. After this age, mRNA for ABP revealed an age-dependent decrease, which parallels the relative increase of germ cells in the testis. In summary, these results demonstrate a clear pattern of cellular localization of the various mRNA species for subunits of the cAMP-dependent protein kinase in the rat testis.     

Mutation of the Gs protein alpha subunit NH2 terminus relieves an attenuator function, resulting in constitutive adenylyl cyclase stimulation.

G-proteins couple hormonal activation of receptors to the regulation of specific enzymes and ion channels. Gs and Gi are G-proteins which regulate the stimulation and inhibition, respectively, of adenylyl cyclase. We have constructed two chimeric cDNAs in which different lengths of the alpha subunit of Gs (alpha s) have been replaced with the corresponding sequence of the Gi alpha subunit (alpha i2). One chimera, referred to as alpha i(54)/s' replaces the NH2-terminal 61 amino acids of alpha s with the first 54 residues of alpha i. Within this sequence there are 7 residues unique to alpha s, and 16 of the remaining 54 amino acids are nonhomologous between alpha i and alpha s. The second chimera, referred to as alpha i/s(Bam), replaces the first 234 amino acids of alpha s with the corresponding 212 residues of alpha i. Transient expression of alpha i(54)/s in COS-1 cells resulted in an 18- to 20-fold increase in cyclic AMP (cAMP) levels, whereas expression of either alpha i/s(Bam) or the wild-type alpha s polypeptide resulted in only a 5- to 6-fold increase in cellular cAMP levels. COS-1 cells transfected with alpha i showed a small decrease in cAMP levels. Stable expression of the chimeric alpha i(54)/s polypeptide in Chinese hamster ovary (CHO) cells constitutively increased both cAMP synthesis and cAMP-dependent protein kinase activity. CHO clones expressing transfected alpha i/s(Bam) or the wild-type alpha s and alpha i cDNAs exhibited cAMP levels and cAMP-dependent protein kinase activities similar to those in control CHO cells. Therefore, the alpha i(54)/s chimera behaves as a constitutively active alpha s polypeptide, whereas the alpha i/s(Bam) polypeptide is regulated similarly to wild-type alpha s. Expression in cyc-S49 cells, which lack expression of wild-type alpha s, confirmed that the alpha i(54)/s polypeptide is a highly active alpha s molecule whose robust activity is independent of any change in intrinsic GTPase activity. The difference in phenotypes observed upon expression of alpha i(54)/s or alpha i/s(Bam) indicates that the NH2-terminal moieties of alpha s and alpha i function as attenuators of the effector enzyme activator domain which is within the COOH-terminal half of the alpha subunit. Mutation at the NH2 terminus of alpha s relieves the attenuator control of the Gs protein and results in a dominant active G-protein mutant.     

DNA-mediated gene transfer of a mutant regulatory subunit of cAMP-dependent protein kinase

We have used DNA-mediated gene transfer of genomic DNA to introduce into wild-type Chinese hamster ovary (CHO) cells a mutant gene that confers resistance to the growth inhibitory effect of cAMP. This dominant mutation in CHO cell line 10248 is responsible for an alteration in the RI subunit (RI*) of the type I cAMP-dependent protein kinase (Singh, T. J., Hochman, J., Verna, R., Chapman, M., Abraham, I., Pastan, I.H., and Gottesman, M.M. (1985) J. Biol. Chem. 260, 13927-13933). The transformant 11564 which was studied in detail, has the same characteristics as the original mutant 10248 including continued growth in medium containing 8-Br-cAMP, an increase in the Ka for cAMP activation of the kinase, a greatly reduced amount of type II protein kinase activity, an altered incorporation of the photoaffinity label 8-N3[32P]cAMP into the RI* subunit of PKI, and an absence of cAMP-dependent phosphorylation of a Mr = 52,000 protein in intact cells. In addition, analysis of the DNA of the transformant indicates the presence of an increased amount of DNA for the RI gene. These results are consistent with the transfer of a mutant gene for the RI* subunit of the cAMP-dependent protein kinase and its phenotypic expression in the transformant and also support the hypothesis that the mutation responsible for the defect in cell line 10248 is due to an alteration in the gene for RI.