Correlated evolution of maternally derived yolk testosterone and early developmental traits in passerine birds.

Recent studies on hormone-mediated maternal effects in birds have highlighted the influence of variable maternal yolk androgen concentration on offspring phenotype, particularly in terms of early development. If genetic differences between laying females regulate variation in yolk hormone concentration, then this physiological maternal effect is an indirect genetic effect which can provide a basis for the co-evolution of maternal and offspring phenotypes. Thus, we investigated the evolutionary associations between maternally derived yolk testosterone (T) and early developmental traits in passerine birds via a comparative, phylogenetic analysis. Our results from species-correlation and independent contrasts analyses provide convergent evidence for the correlated evolution of maternal yolk T concentration and length of the prenatal developmental period in passerines. Here, we show these traits are significantly negatively associated (species-correlation: p<0.001, r2=0.85; independent contrasts: p=0.005). Our results highlight the need for more studies investigating the role of yolk hormones in evolutionary processes concerning maternal effects.

Methods for studying synthesis, turnover, and phosphorylation of catalytic subunit of cAMP-dependent protein kinase in mammalian cells.

Because of the low abundance of the two major isoforms (C alpha and C beta) of catalytic (C) subunit of cAMP-dependent protein kinase, it has been difficult to monitor their expression and virtually impossible to quantify their synthesis, phosphorylation, and turnover in intact mammalian cells. We now describe sensitive and quantitative immunochemical methods using a goat antibody raised against the recombinant C alpha isoform of murine C subunit that enable studies of the expression and metabolism of C subunit in cultured cells. The antibody reacts well with C alpha and C beta isoforms of murine C subunit and with C subunits from rat, hamster, and human cell lines, so it should have widespread utility. Immunoreactivity with bovine heart C subunit was substantially weaker. For quantitation of C subunit radioactivity in extracts of cells labeled metabolically with [35S]methionine, we developed a two-cycle immunoadsorption protocol that reduces nonspecific adsorption to negligible levels. A tritium-labeled, truncated C subunit marker protein is added to extracts as an internal marker to monitor C subunit recoveries in different samples. For analysis of expression of C subunit isoforms in different cells or tissues, we describe a nonradioactive Western immunoblot procedure that can quantitate C subunit in amounts as low as 12 pg. Using extraction conditions that either stabilize or destabilize the phosphate on Thr-197, we show how the relative expression and phosphorylation of C alpha and C beta isoforms can be estimated from SDS-gel patterns resulting from either immunoblot or immunoadsorption procedures.

Second-site mutations in cyclic AMP-sensitive revertants of a Ka mutant of S49 mouse lymphoma cells reduce the affinity of regulatory subunit of cyclic AMP-dependent protein kinase for catalytic subunit.

Ka mutants of S49 mouse lymphoma cells are generally heterozygous for expression of wild-type and mutant regulatory (R) subunits of type I alpha cyclic AMP-(cAMP)-dependent protein kinase, where the mutant R subunit has a defect in cAMP-binding to one of two intrachain cAMP-binding sites. Several cAMP-sensitive revertants of such a Ka mutant were found previously to harbor second-site mutations in the mutant allele, and we have now identified three such mutations by sequence analysis of PCR-amplified cDNAs. The resulting amino acid changes were Ala98 to Thr, Gly179 to Arg, or Gly224 to Asp. The Ka mutation in these strains (Glu201 to Lys) eliminated cAMP-binding to the more aminoterminal cAMP-binding site (site A). None of the second-site mutations restored this activity in bacterially expressed recombinant R subunit. On the other hand, all three second-site mutations reduced the apparent affinity of the mutant R subunit for catalytic (C) subunit with the effects of the substitutions at Ala98 and Gly179 substantially greater than the effect of the substitution at Gly224. Patterns of phosphorylation and turnover of wild-type and mutant R subunits in intact revertant cells were consistent with reduced association of the doubly mutant subunits with C subunit, but the free mutant subunits apparently were more stable than free wild-type subunits. Differences in metabolic turnover of mutant and wild-type subunits did not correlate with the sensitivities of the isolated proteins to proteolytic cleavage.

Spectrum of spontaneous missense mutations causing cyclic AMP-resistance phenotypes in cultured S49 mouse lymphoma cells differs markedly from those of mutations induced by alkylating mutagens.

Mutants of S49 mouse lymphoma cells resistant to cytolysis by analogs of cyclic AMP (cAMP) generally have missense mutations in the gene encoding the regulatory subunit of cAMP-dependent protein kinase. We have compared the mutations in 95 spontaneous isolates with those in 60 mutagen-induced isolates by sequence analysis of amplified cDNAs. Twenty-nine single basepair substitutions in 19 codons produced selectable phenotypes. The spontaneous mutant spectrum was dominated by a CpG transition hotspot in the codon for Arg334. This and other nearby CpG sites were found to be methylated in genomic S49 cell DNA by restriction enzyme analyses. Most of the remaining spontaneous mutants had either G-C-->C-G or T-A-->G-C transversions, which have been associated with damage caused by oxygen radicals. In contrast, the majority of mutants induced with the alkylating mutagens ethyl methanesulfonate (EMS) and N-methyl-N'-nitro-N-nitrosoguanidine had G-C-->A-T mutations at non-CpG sites; in addition, EMS induced several A-T-->G-C, A-T-->T-A, and G-C-->T-A substitutions. A single ICR191-induced mutant analyzed had a unique A-T-->G-C lesion. A number of spontaneous and mutagen-induced isolates had closely linked double or triple substitutions, and two isolates had tandem triple substitutions.

Molecular basis for the 3',5'-cyclic adenosine monophosphate resistance of Kin mutant Y1 adrenocortical tumor cells.

A series of mutant cell lines (Kin) were previously isolated from Y1 adrenocortical tumor cells based on their ability to resist the growth-inhibitory effects of 8-bromo cAMP. In these Kin clones, cAMP-dependent protein kinase (cAMPdPK) was resistant to activation by cAMP as the consequence of mutations affecting the type I regulatory subunit (RI) of the enzyme. This study shows that the cAMP-resistant phenotypes of mutant clones Kin-2, Kin-7, and Kin-8 were associated with single base changes causing substitutions, respectively, of Glu for Gly200, Trp for Arg334, and Asp for Gly324 in the RI protein. By expressing the mutant Trp334 and Asp324 forms of RI under the control of an inducible promoter in Y1 cells, the causal relationship between these RI mutations and impairment of cAMP-stimulated adrenocortical responses was studied. Expression of the mutant RI forms rendered cAMPdPK resistant to activation by cAMP and decreased cAMP-stimulated cell rounding, steroid production, and growth inhibition. These observations indicate that the cAMP-resistant phenotype of Kin mutant clones resulted specifically from single mutational events in RI and thus establish the importance of cAMPdPK as an essential regulator of adrenocortical function. Unlike the original Kin mutant clones, transformants expressing the mutant forms of RI had adenylyl cyclases that were resistant to activation by ACTH, forskolin, or sodium fluoride. These results indicate that there may be a hitherto unappreciated mechanism of regulation of adenylyl cyclase activity by cAMPdPK.

Linked spontaneous CG----TA mutations at CpG sites in the gene for protein kinase regulatory subunit.

CG----TA transitions at CpG sequences account for many human point mutations and are thought to result from hydrolytic deamination of 5-methylcytosine residues in these sites. The gene for regulatory subunit of murine cyclic AMP-dependent protein kinase has two closely linked CpG sites, one of which is a strong hotspot for spontaneous CG----TA mutations leading to cyclic AMP resistance in S49 mouse lymphoma cells. About 5% of mutants with a spontaneous mutation at this CpG site had also acquired a second CG----TA mutation at the nearby CpG site. The two mutations were always at first positions of the Arg codons in which they occurred, and they were always together in a single regulatory subunit allele. Their linked appearance could be attributed to neither the selection conditions nor the preexistence of one mutation in the target cells. The high frequency of these double mutants suggests that their lesions result not from hydrolytic deamination but rather from an endogenous enzymatic mechanism.

Mutations that alter the charge of type I regulatory subunit and modify activation properties of cyclic AMP-dependent protein kinase from S49 mouse lymphoma cells.

Mutations in regulatory (R) subunit of cAMP-dependent protein kinase were analyzed from cAMP-resistant mutants of S49 mouse lymphoma cells by direct sequencing of amplified regions of mutant R subunit cDNAs. Eight distinct single base-change lesions were identified in 24 independent mutants that were hemizygous for expression of mutant R subunits with altered protein charge. CG----TA transitions predominated, but AT----GC transitions and GC----TA transversions were also observed. Four of five spontaneous mutants had identical C----T transitions at CG causing substitution of Trp for Arg-334. Sites mutated in isolates obtained after mutagenesis with ethyl methanesulfonate or N-methyl-N'-nitro-N-nitrosoguanidine were more varied. Six of the lesions (two in binding site A and four in site B) were at amino acid residues that are highly conserved among cAMP-binding sites of R subunits and the Escherichia coli catabolite activator protein. These mutations all either prevented or strongly hindered binding of cyclic nucleotides to the mutated site. One of the remaining lesions (at Arg-242) also prevented cyclic nucleotide binding to the mutated binding site; the other (at Gly-170) had only minimal effects on binding of cyclic nucleotides but, nevertheless, increased the apparent constant for cAMP-dependent kinase activation. These results are discussed with reference to a model for the cAMP-binding sites of R subunit based on the crystal structure of the E. coli catabolite activator protein.

Mutations that prevent cyclic nucleotide binding to binding sites A or B of type I cyclic AMP-dependent protein kinase.

Cyclic nucleotide binding and activation properties of cAMP-dependent protein kinases from five independent mutants of S49 mouse lymphoma cells were studied. These mutants were all hemizygous for expression of mutant regulatory (R) subunits of the type I kinase with lesions that altered the electrostatic charge of R subunit: lesions in three of the mutants mapped to cAMP-binding site A, and those in two of the mutants mapped to cAMP-binding site B. A nucleotide mismatch assay using 32P-labeled cRNA and ribonuclease A confirmed and refined localization of the mutations to single amino acid residues implicated in cAMP binding. R subunits from all mutants retained the ability to bind cAMP, but binding behaved as if it were entirely to nonmutated sites: 1) relative affinities of 11 adenine-modified derivatives of cAMP for mutant enzymes were identical to their relative affinities for the site of wild-type kinase that corresponded to the nonmutated site of the mutant; 2) the potencies of these analogs as activators of mutant kinases were strictly correlated with their binding affinities (for wild-type enzyme activation potencies were correlated with mean affinities of the analogs for cAMP-binding sites A and B); 3) combinations of analogs with strong preferences for opposite cAMP-binding sites in wild-type kinase showed no synergism in activating mutant kinases; 4) dissociation of cAMP from mutant kinases was monophasic; and 5) high salt accelerated dissociation of cAMP from kinases with site B lesions but retarded dissociation from those with site A lesions.

Cyclic AMP-resistant mutants of S49 mouse lymphoma cells hemizygous for expression of regulatory subunit of type I cyclic AMP-dependent protein kinase.

For use in studies of the functional organization of regulatory (R) subunit of type I cAMP-dependent protein kinase, 84 independent cyclic AMP-resistant mutants were isolated from sublines of S49 mouse lymphoma cells that are hemizygous for expression of the R subunit. Mutants were characterized by two-dimensional gel analysis of the R subunits, assays of kinase activation, and assays of cAMP-binding. All but eight of the mutants had kinases with increased apparent Kas for cAMP-dependent activation, and studies with site-selective cAMP analogs revealed considerable phenotypic diversity among these mutants. Forty-nine of the mutants had "charge-shift" lesions that mapped to regions of the R subunit polypeptide implicated in cAMP-binding. Twenty-five of the "charge-shift mutants" expressed only mutant R subunits, and the lesions in most of these isolates inhibited binding of cAMP to mutated cAMP-binding sites. The remainder of the charge-shift mutants expressed both mutant R subunit and R subunit with wild-type gel mobilities. The origin of these "heterozygous" mutants from parental "hemizygous" cells remains a puzzle.