Unstable and stable CAD gene amplification: importance of flanking sequences and nuclear environment in gene amplification.

We analyzed the amplification of the CAD gene in independently isolated N-(phosphonacetyl)-L-aspartate-resistant clones derived from single parental clones in two mouse cell lines. We report for the first time that the CAD gene is amplified unstably in mouse cells, that the degree of instability varies greatly between clones, and that minute chromosomes and highly unstable chromosomelike structures contain the amplified sequences. These data are most consistent with the idea that the amplified unit in each clone consists of different flanking DNA and that such differences engender amplified sequences with unequal stability. We also introduced the mouse chromosome containing the CAD gene into hamster cells by microcell-mediated chromosome transfer to determine whether the propensity for unstable extrachromosomal amplification of the mouse CAD gene would prevail in the hamster cell nuclear environment. We report that the mouse CAD gene was amplified stably in expanded chromosomal regions in each of seven hybrids that were analyzed. This observation is consistent with the idea that the nuclear environment influences whether mutants containing intra- or extrachromosomally amplified sequences will be isolated.     

Drosophila melanogaster H1 histone is phosphorylated stably.

Phosphorylation of histone H1 is developmentally regulated in Drosophila spp. It cannot be detected in preblastoderm embryos or polytene salivary gland cells, but in cellular blastoderm, postblastoderm embryo, and amitotic adult head nuclei, it occurs with a frequency of roughly 4 x 10(5) molecules per nucleus. We used pulse-labeling to study the relationship between H1 synthesis and modification in cultured cells. These results reveal that the H1-associated phosphate is stable and suggest that Drosophila H1 is synthesized, translocated to the nucleus, associated with chromatin, and then phosphorylated. Partial tryptic digestion of Drosophila H1 revealed that the phosphorylation site is located within the globular, central domain of the protein. Thus, the developmentally regulated phosphorylation of Drosophila H1 presents two contrasts with previously studied H1 phosphorylation. It is not correlated with DNA replication, and it is located in the central domain of the protein.     

Characterization of a centromere-linked recombination hot spot in Saccharomyces cerevisiae.

A 1.5-kilobase-pair SalI-HindIII (SH) restriction fragment from the region of Saccharomyces cerevisiae chromosome XIV immediately adjacent to the centromere appears to contain sequences that act as a hot spot for mitotic recombination. The presence of SH DNA on an autonomously replicating plasmid stimulates homologous genetic exchange between yeast genomic sequences and those present on the plasmid. In all recombinants characterized, exchange occurs in plasmid yeast sequences adjacent to rather than within the SH DNA. Hybridization analyses reveal that SH-containing plasmids are present in linear as well as circular form in S. cerevisiae and that linear forms are generated by cleavage at specific sites. Presumably, it is the linear form of the plasmid that is responsible for the stimulation of genetic exchange. Based on these observations, it is proposed that this DNA fragment contains a centromere-linked recombination hot spot and that SH-stimulated recombination occurs via a mechanism similar to double-strand-gap repair (J. W. Szostak, T. Orr-Weaver, J. Rothstein, and F. Stahl, Cell 33:25-35 1983).     

Localization of an alpha-amanitin resistance mutation in the gene encoding the largest subunit of mouse RNA polymerase II.

RNA polymerase II is inhibited by the mushroom toxin alpha-amanitin. A mouse BALB/c 3T3 cell line was selected for resistance to alpha-amanitin and characterized in detail. This cell line, designated A21, was heterozygous, possessing both amanitin-sensitive and -resistant forms of RNA polymerase II; the mutant form was 500 times more resistant to alpha-amanitin than the sensitive form. By using the wild-type mouse RNA polymerase II largest subunit (RPII215) gene (J.A. Ahearn, M.S. Bartolomei, M. L. West, and J. L. Corden, submitted for publication) as the probe, RPII215 genes were isolated from an A21 genomic DNA library. The mutant allele was identified by its ability to transfer amanitin resistance in a transfection assay. Genomic reconstructions between mutant and wild-type alleles localized the mutation to a 450-base-pair fragment that included parts of exons 14 and 15. This fragment was sequenced and compared with the wild-type sequence; a single AT-to-GC transition was detected at nucleotide 6819, corresponding to an asparagine-to-aspartate substitution at amino acid 793 of the predicted protein sequence. Knowledge of the position of the A21 mutation should facilitate the study of the mechanism of alpha-amanitin resistance. Furthermore, the A21 gene will be useful for studying the phenotype of site-directed mutations in the RPII215 gene.     

Alterations in pp60c-src accompany differentiation of neurons from rat embryo striatum.

Cultured neurons from rat embryo striatum were found to contain two structurally distinct forms of pp60c-src. The 60-kilodalton (kDa) form appeared similar to pp60c-src from cultured rat fibroblasts or astrocytes. The 61-kDa form was specific to neurons and differed in the NH2-terminal 18 kDa of the molecule. In undifferentiated neurons the predominant phosphorylated species of pp60c-src was the fibroblast form. Upon differentiation, a second phosphorylated form of pp60c-src was detected. This form had two or more additional sites of serine phosphorylation within the NH2-terminal 18-kDa region of the molecule, one of which was Ser-12. The specific protein-tyrosine kinase activity of the total pp60c-src population increased 14-fold, as measured by autophosphorylation, or 7-fold, as measured by phosphorylation of an exogenous substrate, as striatal neurons differentiated. This elevation in protein kinase activity occurred without a detectable decrease in Tyr-527 phosphorylation or increase in Tyr-416 phosphorylation. Our results support the idea that the expression of the neuron-specific form of pp60c-src and the increase in specific protein kinase activity may be important for neuronal differentiation.     

DNA sequence analysis of spontaneous mutations at the aprt locus of hamster cells.

To determine the nature of spontaneous mutational events in cellular genes in hamster cells, mutant adenine phosphoribosyltransferase (aprt) genes were cloned and the regions to which we mapped alterations were sequenced. A variety of nucleotide changes were found to occur in the 12 mutant genes analyzed. Most mutations were simple base-pair substitutions-transitions (both G X C----A X T and A X T----G X C) and transversions. The only multiple mutation was a simple transition next to a single-base-pair insertion. Of the 12 mutations, 4 were more complex, involving small deletions or duplications. Two of these were similar to previously described deletions in that they occurred between short direct sequence repeats. No hot spots were detected. Three independent mutations were characterized at one restriction endonuclease site, although no other mutations were detected in the nucleotides surrounding this site in other mutant strains. At a functional level, sequence changes were either in exons (resulting in missense and, in one instance, nonsense mutations) or at splicing sites.