Recombinant type I regulatory subunit of the cAMP-dependent protein kinase is biologically active

The cDNA for the porcine type I regulatory subunit (RI) of the cAMP-dependent protein kinase (cAMP-PK) was cloned into two different bacterial expression vectors: pKK223 and pUC18. Recombinant RI was produced by bacteria transformed with either construct, and purified by affinity chromatography. Both the native RI from the pKK223 construct and the RI with an amino terminal extension of eight amino acids from the pUC18 construct were found to be completely native with regard to inhibition of the catalytic subunit activity and cAMP binding.

Dependence of urokinase-type-plasminogen-activator induction on cyclic AMP-dependent protein kinase activation in LLC-PK1 cells

The activation of cyclic AMP-dependent protein kinase (cAMP-PK) in vivo was studied in LLC-PK1 pig kidney cells and the mutant cell lines M18 and FIB5, which have total levels of cAMP-PK catalytic-subunit and regulatory-subunit activities comparable with those of parental cells. The extent of cAMP-PK activation (release of active catalytic subunit from the holoenzyme) was directly correlated with the cellular cyclic AMP concentration in LLC-PK1 cells. In LLC-PK1 cells, as well as in the mutants M18 and FIB5, the extent of the induction of urokinase-type plasminogen activator (uPA) by the cyclic AMP-mediated effectors calcitonin, vasopressin and forskolin was directly correlated with the levels of activated catalytic subunit. The 'receptorless' mutant M18, which is impaired in calcitonin- and vasopressin-receptor function, did not show any activation of cAMP-PK or uPA production in response to either hormone, whereas cAMP-PK and uPA responses to forskolin were about 35% higher than in parental cells. Analysis of the FIB5-cell line revealed a lesion affecting the regulation of adenylate cyclase activity, whereby basal and stimulated (both receptor- and non-receptor-mediated) adenylate cyclase levels were less than 36% of those in parental cells. The activation of cAMP-PK in response to cyclic AMP effectors was similarly reduced, and uPA induction was concomitantly lower than that in parental cells. The results demonstrate the dependence of uPA induction by cyclic AMP effectors on dissociation of the cAMP-PK holoenzyme, implying the importance of activated free cAMP-PK catalytic subunit in this process. Thus it is concluded that the mutations in the cellular cyclic AMP-generating apparatus of the M18 and FIB5 cell lines impair uPA induction by preventing cAMP-PK activation.

Characterization of two mutants of the LLC-PK1 porcine kidney cell line affected in the catalytic subunit of the cAMP-dependent protein kinase

The catalytic (C) subunit activity of the cAMP-dependent protein kinase (cAMP-PK) from the mutant cell lines, FIB4 and FIB6, is only 10% compared with the parent cell line, LLC-PK1 [Jans and Hemmings (1986) FEBS Lett. 205, 127-131]. In order to understand the nature of the mutant phenotypes the cAMP-PK from parent and mutant cell lines was studied in more detail. Analysis of mutant cAMP-PK activity by ion-exchange chromatography revealed that kinase activity associated with type I holoenzyme of both FIB4 and FIB6 was only 5% parental, and the activity of the type II holoenzyme was about 20% parental. The type I regulatory (RI) subunits associated with the type I were also found to be reduced by 70-80% in both mutants, whereas the type II R subunit levels were similar to that of the parent. The residual kinase activity associated with the type I holoenzyme from FIB4 and FIB6 could not be activated by cAMP whereas the type II holoenzyme was activated by cAMP (Ka of 5.5 X 10(-8) M), and showed normal affinities for Kemptamide and ATP. A polyclonal antibody to the catalytic subunit was used to quantify the level of this protein in wild-type and mutant cells. This analysis showed that FIB4 and FIB6 had nearly normal levels of C subunit, suggesting that the C subunit synthesized by the mutants was mostly inactive. As both type I and type II cAMP-PK holoenzymes were abnormal, the most likely explanation of the mutant phenotype is a defect either in the structural gene for the C subunit or in an enzyme involved in its posttranslational processing. However, a second lesion affecting the RI subunit cannot be ruled out at this moment.

Complementation between LLC-PK1 mutants affected in polypeptide hormone-receptor function

The mutant LLC-PK1 cell lines FIB6 and FIB5/N4 were examined for responsiveness to the polypeptide hormones calcitonin and vasopressin. Both mutants exhibited little or no activation of adenylate cyclase or cAMP-dependent protein kinase (cAMP-PK) in response to calcitonin, but responded to vasopressin. Analysis of calcitonin receptor function demonstrated that both mutants bound less than 9 fmol 125I-labeled salmon calcitonin/mg cellular protein, which was about 1% of parental activity (642 fmol calcitonin bound/mg). Concomitant with reduced calcitonin binding, both mutants exhibited increased vasopressin binding (greater than 272 fmol [[3H]Arg]vasopressin bound/mg) compared to parental (166 fmol bound/mg). The concentration of vasopressin for half-maximal stimulation of adenylate cyclase in both mutants was comparable to that for LLC-PK1 cells (40 pM) and hence the increased binding activity was concluded to be due to increased numbers of functional vasopressin receptors in the mutants. Somatic cell hybrids formed between each mutant and LLC-PK1 cells exhibited normal hormone binding and activation of cAMP-PK in response to both vasopressin and calcitonin. The mutations affecting receptor function in FIB6 and FIB5/N4 were accordingly concluded to be recessive. Somatic cell hybrids between FIB6 and FIB5/N4 showed no complementation of the mutant phenotype, indicating that both cell lines were affected in the same gene. In contrast, somatic cell hybrids between FIB5/N4 and the 'receptorless' mutant M18 (which lacks functional calcitonin and vasopressin receptors) exhibited approximately the same responsiveness to vasopressin and to calcitonin as LLC-PK1. Complementation between two different mutations affecting polypeptide receptor function was thus observed. The results are discussed in terms of a proposed common pathway for processing of calcitonin and vasopressin receptors.

Expression cloning of a cDNA encoding the type II regulatory subunit of the cAMP-dependent protein kinase

We report here the isolation and sequence of a cDNA for the type II regulatory subunit of the cAMP-dependent protein kinase (cAMP-PK) from a lambda gt-11 cDNA library derived from a porcine epithelial cell line (LLC-PK1). The cDNA was detected by immunological screening using an affinity purified polyclonal antibody for bovine RII. DNA sequence analysis of the 467 bp EcoRI insert confirmed the identity of the clone, because the deduced amino acid sequence corresponded to the published sequence for the bovine RII protein. Northern analysis of total RNA from the LLC-PK1 cells indicated a single mRNA species of about 6.0 kb, probably derived from a single copy gene.

Isolation of a mutant LLC-PK1 cell line defective in hormonal responsiveness. A pleiotropic lesion in receptor function

A mutant LLC-PK1 cell line, M18, was isolated after a single treatment of the parent culture with N-methyl-N'-nitro-N-nitroso-guanidine. In contrast to LLC-PK1 cells, the mutant did not exhibit production of urokinase-type plasminogen activator (uPA) in response to the hormones calcitonin and vasopressin, but produced the expected levels of uPA upon stimulation by the receptor-independent adenylate cyclase activators forskolin and cholera toxin, as well as by the phosphodiesterase inhibitor isobutylmethylxanthine and the 8-bromo analogue of adenosine cyclic monophosphate, Br8cAMP. The patterns of activation of cAMP-dependent protein kinase were identical to those of uPA induction: calcitonin and vasopressin were without effect, but the response to all other agents was normal. In similar fashion, mutant cell homogenates displayed normal activation of adenylate cyclase upon treatment with sodium fluoride, forskolin, or the non-hydrolyzable GTP analogue guanosine 5'-[beta, gamma-imino]triphosphate, but were unresponsive to calcitonin or vasopressin. The ability of M18 cells to bind radioactively labelled calcitonin and vasopressin was measured. The mutant possessed less than 4% of the normal levels of the receptor binding activity for both hormones. Somatic cell hybrids formed between M18 and LLC-PK1 cells were found to retain normal hormone binding activity and responsiveness to hormones, indicating that the defect in M18 cells was recessive. M18 was concluded most probably to contain a single mutation impairing the function of two distinct polypeptide hormone receptors.

LLC-PK1 cell mutants in cAMP metabolism respond normally to phorbol esters

Mutants of the pig kidney cell line, LLC-PK1, affected in cAMP metabolism, were examined for cAMP-dependent protein kinase (cAMP-PK) activity and for cAMP-mediated induction of urokinase-type plasminogen activator (uPA). The FIB4 and FIB6 mutant cell lines possessed about 10% parental levels of cAMP-PK activity and concomitantly reduced uPA production (10-20% parental) in response to calcitonin, forskolin and 8-bromo cAMP. The FIB1, FIB2 and FIB5 mutant cell lines had about 70% parental levels of cAMP-PK and the synthesis of uPA was 40-60% parental. Thus, cAMP-mediated induction of uPA showed a dependence on the absolute levels of cAMP-PK. However, uPA synthesis in response to phorbol-12-myristate-13-acetate by all of the mutants was similar to parental, which indicates that enzyme induction mediated by phorbol esters does not involve cAMP or cAMP-PK.

The F1F0-ATPase of Escherichia coli. The substitution of alanine by threonine at position 25 in the c-subunit affects function but not assembly

A mutant strain of Escherichia coli carrying a mutation in the uncE gene which codes for the c-subunit of the F1F0-ATPase has been isolated and examined. The mutant allele, designated uncE513, results in alanine at position 25 of the c-subunit being replaced by threonine. The mutant F1F0-ATPase appears to be fully assembled and is partially functional with respect to oxidative phosphorylation. The ATPase activity of membranes from the mutant strain is resistant to the inhibitor dicyclohexylcarbodiimide, but this is due to the F1-ATPase being lost from the membranes in the presence of the inhibitor. Mutant membranes from which the F1-ATPase has been removed have a greatly reduced proton permeability compared with similarly treated normal membranes. The results are discussed in relation to a previously proposed mechanism of oxidative phosphorylation.

Complementation between uncF alleles affecting assembly of the F1F0-ATPase complex of Escherichia coli

A mutant affected in the b subunit (coded by the uncF gene) of the F1F0-ATPase in Escherichia coli was isolated by a localized mutagenesis procedure in which a plasmid carrying the unc genes was mutagenized in vivo. The biochemical properties of cells carrying the uncF515 allele were examined in a strain carrying the allele on a multicopy plasmid and a mutator-induced polar unc mutation on the chromosome. The strain carrying the mutant unc allele was uncoupled with respect to oxidative phosphorylation. Membrane-bound ATPase activity was very low or absent, and membranes were somewhat proton permeable. It was concluded that the F0 sector was assembled. Determination of the DNA sequence of the uncF515 allele showed it differed from wild type in that a G----A substitution occurred at position 392, resulting in glycine being replaced by aspartate at position 131. Genetic complementation tests indicated that the uncF515 allele complemented the uncF476 allele (Gly 9----Asp). Two-dimensional gel electrophoresis of membrane preparations indicated that the uncF515 and uncF476 alleles interrupted assembly of the F1F0-ATPase at different stages.

An acidic or basic amino acid at position 26 of the b subunit of Escherichia coli F1F0-ATPase impairs membrane proton permeability: suppression of the uncF469 nonsense mutation

The uncF469 allele differed from normal in that a G----A base change occurred at nucleotide 77 of the uncF gene, resulting in a TAG stop codon rather than the tryptophan codon TGG. Two partial revertant strains were isolated which retained the uncF469 allele but formed a partially functional b-subunit, due to suppression of the uncF469 nonsense mutation. From the altered isoelectric points of the b-subunits from these strains, it was concluded that the suppressor gene of partial revertant strain AN1956 inserts an acidic amino acid for the TAG codon, and that the suppressor gene of partial revertant strain AN1958 inserts a basic amino acid. The membranes of both partial revertant strains showed impaired permeability to protons on removal of F1-ATPase. The membranes of both strains, however, were able to carry out oxidative phosphorylation, and the ATPase activities of both were resistant to the inhibitor dicyclohexylcarbodiimide.

An additional acidic residue in the membrane portion of the b-subunit of the energy-transducing adenosine triphosphatase of Escherichia coli affects both assembly and function

Glycine at position 9 is replaced by aspartic acid in the mutant b-subunit of Escherichia coli F1F0-ATPase coded for by the uncF476 allele. The mutant b-subunit is not assembled into the membrane in haploid strains carrying the uncF476 allele, but, if the mutant allele is incorporated into a multicopy plasmid, then some assembly of the mutant b-subunit occurs. Two revertant strains were characterized, one of which (AN2030) was a full revertant, the other (AN1953) a partial revertant. DNA sequencing indicated that in strain AN2030 the uncF476 mutation had reverted to give the sequence found in the normal uncF gene. The partial-revertant strain AN1953, however, retained the DNA sequence of the uncF476 allele, and complementation analysis indicated that the second mutation may be in the uncA gene. Membranes prepared from the partial-revertant strain carried out oxidative phosphorylation, although the membranes appeared to be impermeable to protons, and the ATPase activity was sensitive to the inhibitor dicyclohexylcarbodi-imide.

Structural gene for the phosphate-repressible phosphate-binding protein of Escherichia coli has its own promoter: complete nucleotide sequence of the phoS gene

The complete nucleotide sequence of the phoS gene, the structural gene for the phosphate-repressible, periplasmic phosphate-binding protein Escherichia coli K-12, was determined. The phosphate-binding protein is synthesized in a precursor form which includes an additional N-terminal segment containing 25 amino acid residues, with the general characteristics of a signal sequence. The amino acid sequence derived from the nucleotide sequence shows the mature protein to be composed of 321 amino acids with a calculated molecular weight of 34,427. The phoS gene is not part of an operon and is transcribed counterclockwise with respect to the E. coli genetic map. A promoter region has been identified on the basis of homology with the consensus sequence of other E. coli promoter regions. However, an alternative promoter region has been identified on the basis of homology with the promoter regions of the phoA and phoE genes, the structural genes for alkaline phosphatase and outer-membrane pore protein e, respectively.

Oxidative phosphorylation by mutant Escherichia coli membranes with impaired proton permeability

The effect on the function of the Escherichia coli F1F0-ATPase of the substitution of leucine-31 by phenylalanine in the c-subunit of the enzyme was examined. The assembly of the mutant c-subunit requires an increased gene dosage [Jans, Fimmel, Langman, James, Downie, Senior, Ash, Gibson & Cox (1983) Biochem. J. 211, 717-726], and this was achieved by incorporation of the uncE408 or uncE463 alleles on to F-plasmids or multicopy plasmids. Membranes from strains carrying either the uncE463 or uncE408 alleles on F-plasmids or multicopy plasmids were capable of carrying out oxidative phosphorylation. In particular, membranes from strain AN1928 (pAN162, uncE463) gave phosphorylation rates and P/O ratios equal to or greater than those obtained for the control strain AN1460 (pAN45, unc+). However, the mutant membranes, on removal of the F1-ATPase, appeared to be proton-impermeable. The ATPase activity of the mutant membranes was also resistant to the inhibitor dicyclohexylcarbodi-imide.

The F1F0-ATPase of Escherichia coli. Substitution of proline by leucine at position 64 in the c-subunit causes loss of oxidative phosphorylation

The uncE410 allele differs from the normal uncE gene in that C leads to T base changes occur at nucleotides 190 and 191, resulting in proline at position 64 in the c-subunit of the F1F0-ATPase being replaced by leucine. Two partial-revertant strains were isolated in which alanine-20 of the c-subunit was replaced by proline, owing to a G leads to C base change at nucleotide 58. These c-subunits, coded for by the uncE501 and uncE502 alleles, therefore contained two amino acid changes, namely proline-64 leads to leucine, and alanine-20 leads to proline. Membranes prepared from the partial-revertant strains lacked ATP-dependent atebrin-fluorescence-quenching activity but were able to carry out oxidative phosphorylation. The ATPase activity of the F1-ATPase was inhibited when bound to membranes from strains carrying the uncE410, uncE501 and uncE502 alleles. It is concluded that a bend in the helix axis in one of the arms of the c-subunit hairpin structure is required for integration of the c-subunit into a functional F1F0-ATPase.

Mutations in the uncE gene affecting assembly of the c-subunit of the adenosine triphosphatase of Escherichia coli

The amino acid substitutions in the mutant c-subunits of Escherichia coli F1F0-ATPase coded for by the uncE429, uncE408 and uncE463 alleles affect the incorporation of these proteins into the cell membrane. The DNA sequence of the uncE429 allele differed from normal in that a G leads to A base change occurred at nucleotide 68 of the uncE gene, resulting in glycine being replaced by aspartic acid at position 23 in the c-subunit. The uncE408 and uncE463 mutant DNA sequences were identical and differed from normal in that a C leads to T base change occurred at nucleotide 91 of the uncE gene, resulting in leucine being replaced by phenylalanine at position 31 in the c-subunit. An increased gene dosage of the uncE408 or uncE463 alleles resulted in the incorporation into the membranes of the mutant c-subunits. The results are discussed in terms of the 'Helical Hairpin Hypothesis' of Engelman & Steitz [(1981) Cell 23,411-422].