A long terminal repeat-containing retrotransposon is mobilized during hybrid dysgenesis in Drosophila virilis.

A hybrid dysgenesis syndrome similar to those described in Drosophila melanogaster occurs in Drosophila virilis when a laboratory stock is crossed to a wild strain collected in the Batumi region of Georgia (U.S.S.R). Mutations in various loci obtained during these crosses are presumably induced by the insertion of DNA sequences. We have cloned an induced white mutation and characterized the insertion sequence responsible for the mutant phenotype. This sequence is a 10.6-kilobase (kb) transposable element we have named Ulysses. This element is flanked by unusually large 2.1-kb long terminal repeats. Ulysses also contains other landmarks characteristic of the retrotransposon family, such as a tRNA-binding site adjacent to the 5' long terminal repeat and open reading frames encoding putative products with homology to the reverse transcriptase, protease, and integrase domains typical of proteins encoded by vertebrate retroviruses. Some of the mutations obtained do not contain a copy of the Ulysses element at the mutant locus, suggesting that a different transposable element may be responsible for the mutation. Therefore, Ulysses may not be the primary cause of the entire dysgenic syndrome, and its mobilization may be the result of activation by an independent mobile element.

A hybrid dysgenesis syndrome in Drosophila virilis.

A new example of "hybrid dysgenesis" has been demonstrated in the F1 progeny of crosses between two different strains of Drosophila virilis. The dysgenic traits were observed only in hybrids obtained when wild-type females (of the Batumi strain 9 from Georgia, USSR) were crossed to males from a marker strain (the long-established laboratory strain, strain 160, carrying recessive markers on all its autosomes). The phenomena observed include high frequencies of male and female sterility, male recombination, chromosomal nondisjunction, transmission ratio distortion and the appearance of numerous visible mutations at different loci in the progeny of dysgenic crosses. The sterility demonstrated in the present study is similar to that of P-M dysgenesis in Drosophila melanogaster and apparently results from underdevelopment of the gonads in both sexes, this phenomenon being sensitive to developmental temperature. However, in contrast to the P-M and I-R dysgenic systems in D. melanogaster, in D. virilis the highest level of sterility (95-98%) occurs at 23-25 degrees. Several of the mutations isolated from the progeny of dysgenic crosses (e.g., singed) proved to be unstable and reverted to wild type. We hypothesize that a mobile element ("Ulysses") which we have recently isolated from a dysgenically induced white eye mutation may be responsible for the phenomena observed.

A rapid method for mapping exposed cytosines in polyribonucleotides. Application to tRNATrp (yeast, beef liver).

A rapid method for mapping exposed cytosine residues in 5'-[32P]-labeled RNA molecules is suggested. The exposed cytosines (C's) are converted into uracyls (U's) by bisulphite treatment at pH 5.8 in the presence of Mg2+, followed by complete modification of the residual (non-exposed) C's by a methoxyamine and bisulphite mixture at pH 5.0. The control RNA is modified only by methoxyamine and bisulphite without the preliminary C leads to U conversion. The location of the exposed C's is determined by comparing the products of partial T1, T2, A and U2 ribonuclease digestions of the C leads to U converted and control RNAs after slab gel polyacrylamide electrophoresis and autoradiography. The method has been applied for mapping exposed cytosine bases in tRNATrp (yeast) which have been found in the anti-codon loop and at the 3'-end of the molecule. In tRNATrp (beef liver), in addition to the same exposed bases, C in the diHU-loop is exposed. The data obtained are in full agreement with what is known about exposed C's for other tRNAs.

The effect of tRNA and tryptophanyl adenylate on limited proteolysis of beef pancreas tryptophanyl-tRNA synthetase.

Limited proteolysis of tryptophanyl-tRNA synthetase was used to detect changes in the enzyme molecule in the presence of substrates. Trypsinolysis of each of the two identical subunits occurs in succession from the N-terminus as follows: 60 leads to 51 leads to 40 leads to 24 kilodaltons. The transition 51 leads to 40 is hindered in tryptophanyl adenylate.enzyme complex. Yeast tRNATrp accelerates the first steps of hydrolysis and decelerates the transition 40 leads to 24. Once tRNATrp is added to the synthetase.adenylate complex, the protective effect of the adenylate disappears. The same effects are found also in the presence of tRNATrp oxidized with NaI04 and tRNATrp lacking the 3'-terminal adenosine. Oxidized tRNATrp (but not tRNATrp without the 3'-A) accelerates tryptophan-dependent hydrolysis of ATP catalyzed by the enzyme. A scheme is proposed for the interaction of yeast tRNATrp with beef pancreas tryptophanyl-tRNA synthetase involving the association of tRNA with a positively charged site(s) of the enzyme and the changes in the conformation of enzyme manifesting itself in unfolding of the acidic N-terminal fragment of the polypeptide chain and in the exposure of the adenylate.

Immunochemical studies of beef pancreas tryptophanyl-tRNA synthetase and its fragments. Determination of the number of antigenic determinants and a comparison with tryptophanyl- tRNA synthetases from other sources and with reverse transcriptase from avian myeloblastosis virus.

The immunoglobulin G (IgG) fraction of the antiserum from rabbits immunized with homogeneous beef pancreas tryptophanyl-tRNA synthetase inhibits the enzyme activity in the reactions of both tRNATrp aminoacylation and tryptophan activation. Fab fragments of IgG act in a similar way. Common antigenic determinants have been detected in tryptophanyl-tRNA synthetases from beef, pig, chicken and rat livers using pure antibodies against beef pancreas tryptophanyl-tRNA synthetase. This observation indicates the evolutional stability of certain structural features of tryptophanyl-tRNA synthetases. The interaction of antibodies with the fragments of beef tryptophanyl-tRNA synthetase produced by endogenous and tryptic proteolysis of the enzyme has been studied. On third of the antiserum antibodies interacting with the C-terminal fragment of the enzyme (Mr approximately equal to 40000) inhibits its activity whereas the antibodies to the N-terminal fragment (Mr approximately equal to 20000) have no effect on the enzyme activity. The immunochemical identity of the two synthetase fragments differing in their enzymatic activity supports the assumption that the loss of enzymatic activity of the tryptic fragment is caused by lack of a small peptide which is retained in case of endogenous proteolysis; probably the amino acid residues of this peptide participate in formation of active centre of tryptophanyl-tRNA synthetase. A radioimmunochemical method is described for determining the number of antigenic determinants. One molecule of tryptophanyl-tRNA synthetase was found to bind 9 (+/- 1) molecules of Fab fragments. Antibodies against tryptophanyl-tRNA snythetase from beef pancreas do not inhibit noticeably the activity of reverse transcriptase from avian myeloblastosis virus. No antigenic determinants in common have been detected in reverse transcriptase and tryptophanyl-tRNA synthetase by radioimmunochemical assays.

Tritium labelling of nucleic acids accompanied by conversion of cytosine to uracil.

A new method of incorporation of tritium into nucleic acids with an accompanying conversion of cytosine to uracil is proposed. The method is based on the reaction of nucleic acids with bisulfite in the presence of 3H2O. Under certain conditions poly(C) is quantitatively converted to a radioactive poly(U), whereas similar bisulfite treatment of poly(U) does not result in any tritium incorporation. Specificity of the reaction is confirmed by the results of analysis of modified tRNA and rRNA. Incubation of tRNA with bisulfite and 3H2O does not lead to cleavage of the polynucleotide chain. Similar treatment of the denatured DNA results in tritium incorporation into DNA which is accompanied by a conversion of cytosine to uracil. There is virtually no reaction between native DNA and bisulfite. Only certain cytosone residues in yeast tRNAVal/2a interact with bisulfate providing that reaction is carried out under sufficiently mild conditions.