Isolation and characterization of cDNA for chicken muscle adenylate kinase

A cDNA clone for muscle adenylate kinase was isolated from a cDNA library of chick skeletal muscle poly(A)+ RNA, and the DNA sequence was determined. The cDNA insert had 854 nucleotides, which consisted of the 5'-untranslated sequence of 57 nucleotides, the sequence of 582 nucleotides coding for 194 amino acids, and the 3'-untranslated sequence of 163 nucleotides and the poly(A) tail of 52 nucleotides. The amino acid sequence predicted from the nucleotide sequence was highly homologous with the reported sequences of human, calf, porcine, and rabbit muscle adenylate kinases. RNA blot analysis of poly(A)+ RNA from various chicken tissues revealed a single species of mRNA of approximately 850 nucleotides and its tissue-specific distribution. The induction of muscle adenylate kinase mRNA synthesis during the chick embryogenesis was also demonstrated by the blot analysis. Southern blot analysis indicated a single gene for muscle adenylate kinase in the chicken genome.     

Distinctions between the multiple cationic forms of rat liver glutathione S-transferase

Three cationic glutathione S-transferase forms isolated from rat liver were characterized as dimers that originated from different combinations of two subunit types, Ya and Yc. The cationic forms were purified using lysyl glutathione affinity matrices and were chromatographically resolved from anionic glutathione S-transferases that contain Yb subunits. The three classes of cationic transferase exhibited similar specific activities with 1-chloro-2,4-dinitrobenzene as a substrate, all forms cross-reacted with antibodies to glutathione S-transferase B, and all had comparable secondary structures and tryptophan fluorescence properties. In spite of those similarities, the Yc-containing forms were clearly distinguishable from Ya forms on the basis of characteristic differences in circular dichroic patterns associated with their aromatic side chains. All cationic transferases bound bilirubin with stoichiometric ratios of 1 mol/dimeric protein molecule, but discrete differences in mode of binding were ascribed to forms containing Ya subunits as compared to Yc dimers. Binding to Yc forms was of lower affinity and may be associated with the catalytic region of the protein since glutathione effectively displaced bilirubin from the Yc component.     

Models of Evolution of Reproductive Isolation

Mathematical models are presented for the evolution of postmating and premating reproductive isolation. In the case of postmating isolation it is assumed that hybrid sterility or inviability is caused by incompatibility of alleles at one or two loci, and evolution of reproductive isolation occurs by random fixation of different incompatibility alleles in different populations. Mutations are assumed to occur following either the stepwise mutation model or the infinite-allele model. Computer simulations by using It?'s stochastic differential equations have shown that in the model used the reproductive isolation mechanism evolves faster in small populations than in large populations when the mutation rate remains the same. In populations of a given size it evolves faster when the number of loci involved is large than when this is small. In general, however, evolution of isolation mechanisms is a very slow process, and it would take thousands to millions of generations if the mutation rate is of the order of 10(-5) per generation. Since gene substitution occurs as a stochastic process, the time required for the establishment of reproductive isolation has a large variance. Although the average time of evolution of isolation mechanisms is very long, substitution of incompatibility genes in a population occurs rather quickly once it starts. The intrapopulational fertility or viability is always very high. In the model of premating isolation it is assumed that mating preference or compatibility is determined by male- and female-limited characters, each of which is controlled by a single locus with multiple alleles, and mating occurs only when the male and female characters are compatible with each other. Computer simulations have shown that the dynamics of evolution of premating isolation mechanism is very similar to that of postmating isolation mechanism, and the mean and variance of the time required for establishment of premating isolation are very large. Theoretical predictions obtained from the present study about the speed of evolution of reproductive isolation are consistent with empirical data available from vertebrate organisms.     

Functional consequences of alterations to amino acids located in the catalytic center (isoleucine 348 to threonine 357) and nucleotide-binding domain of the Ca2+-ATPase of sarcoplasmic reticulum

The sequence of 10 amino acids (ICSDKTGTLT357) at the site of phosphorylation of the rabbit fast twitch muscle Ca2+-ATPase is highly conserved in the family of cation-transporting ATPases. We changed each of the residues flanking Asp351, Lys352, and Thr353 to an amino acid differing in size or polarity and assayed the mutant for Ca2+ transport activity and autophosphorylation with ATP or P1. We found that conservative changes (Ile----Leu, Thr----Ser, Gly----Ala) or the alteration of Cys349 to alanine did not destroy Ca2+ transport activity or phosphoenzyme formation, whereas nonconservative changes (Ile----Thr, Leu----Ser) did disrupt function. These results indicate that very conservative changes in the amino acids flanking Asp351, Lys352, and Thr353 can be accommodated. A number of mutations were also introduced into amino acids predicted to be involved in nucleotide binding, in particular those in the conserved sequences KGAPE519, RDAGIRVIMITGDNK629, and KK713. Our results indicate that amino acids KGAPE519, Arg615, Gly618, Arg620, and Lys712-Lys713 are not essential for nucleotide binding, although changes to Lys515 diminished Ca2+ transport activity but not phosphoenzyme formation. Changes of Gly626 and Asp627 abolished phosphoenzyme formation with both ATP and Pi, indicating that these residues may contribute to the conformation of the catalytic center.     

Functional consequences of glutamate, aspartate, glutamine, and asparagine mutations in the stalk sector of the Ca2+-ATPase of sarcoplasmic reticulum

Nucleotides encoding glutamate, glutamine, aspartate, or asparagine residues within the stalk sector of the sarcoplasmic reticulum Ca2+-ATPase were altered by oligonucleotide-directed site-specific mutagenesis. The mutant cDNAs were expressed in COS-1 cells, and mutant Ca2+-ATPases were assayed for Ca2+ transport function and phosphoenzyme formation. Multiple mutations introduced into stalks, 1, 2, and 3 resulted in partial loss of Ca2+ transport function. In most cases, subsequent mutation of individual amino acids in the cluster had no effect on Ca2+ transport activity. In one cluster, however, it was possible to assign the reduction in Ca2+ transport activity to alterations of Asn111 and Asn114. The mutant Asn114 to alanine retained about 50% activity, whereas the change Asn111 to alanine retained only 10% activity. None of the mutations affected phosphorylation of the enzyme by ATP in the presence of Ca2+ or by inorganic phosphate in the absence of Ca2+. The combined experiments suggest that the reduced Ca2+ uptake observed in the Asn111 and Asn114 mutants was not due to a defect in enzyme activation by Ca2+ or in formation of the phosphorylated enzyme intermediate but rather to incompetent handling of the bound Ca2+ following ATP utilization. These results demonstrate that the acidic and amidated residues within the stalk region do not constitute the high affinity Ca2+-binding sites whose occupancy is required for enzyme activation. They may, however, act to sequester cytoplasmic Ca2+ and to channel it to domains that are involved in enzyme activation and cation translocation. Simultaneous mutation of 4 glutamate residues to alanine in the lumenal loop between transmembrane sequences M1 and M2 did not affect Ca2+ transport activity, indicating that acidic residues in this lumenal loop do not play an essential role in Ca2+ transport. Similarly, mutation of Glu192 and Asp196 in the beta-strand domain between stalk helices 2 and 3 did not affect Ca2+ transport activity, although mutation of Asp196 did diminish expression of the protein.