Identification of a core functional and structural domain of the v-Ski oncoprotein responsible for both transformation and myogenesis.

The v-ski oncogene promotes cellular transformation and myogenic differentiation. In quail embryo fibroblasts the two properties are displayed simultaneously and terminal muscle differentiation occurs only among cells already transformed by v-ski. To understand how the two phenotypes are derived from a single gene, we have undertaken to identify functionally important regions in v-ski and to test whether these regions can promote one phenotype without the other. We have generated both random and targeted mutations in v-ski and evaluated the effects of these mutations on expression, intracellular location, transformation, and myogenesis. Among a total of 26 mutants analysed, we have not found complete separation of the myogenic and transforming properties. Mutations in the region of v-Ski encoded by exon 1 of c-ski frequently abolish both its transformation and muscle differentiation activities, whereas mutations outside of this region are always tolerated. When expressed in cells from a minigene containing only the exon 1 sequence, the protein displays the transforming and myogenic activities similar to v-Ski. These results argue that the amino acid sequence encoded by exon 1 contains the core functional domain of the oncoprotein. To determine whether this functional domain has a structural counterpart, we have fragmented the v-Ski protein by limited proteolysis and found a single proteolytically stable domain spanning the entire exon 1-encoded region. Physical studies of the polypeptide encoded by exon 1 confirms that it folds into a compact, globular protein. The finding that both the transforming and myogenic properties of v-Ski are inseparable by mutation and are contained in a single domain suggests that they are derived from the same function.

The human basonuclin gene.

The human gene for basonuclin, a zinc-finger protein of keratinocytes, has been cloned, sequenced and assigned to chromosome 15. The transcription unit spans nearly 29 kb of sequence. The coding region is distributed over five exons, and the three pairs of zinc fingers are encoded by the last two. The 5' flanking sequence and first exon are unusually rich in G+C and in CpG dinucleotides. This region contains numerous target sites for the transcription factor Sp1.

Transformation-defective v-ski induces MyoD and myogenin expression but not myotube formation.

The ski oncogene induces muscle differentiation in otherwise nonmyogenic quail embryo cells (C. Colmenares and E. Stavnezer, Cell 59:293-303, 1989). Here we report that v-ski induces both MyoD and myogenin expression, suggesting that activation of these muscle regulatory genes may be a critical step in ski-induced myogenesis. We also describe a transformation-defective mutant of v-ski (tdM5i) that fails to induce myotube formation, although it induces the expression of many muscle-specific genes, including the MyoD and myogenin genes. Therefore, if activation of MyoD and myogenin expression is a necessary component of the myogenic program triggered by ski, it is clearly insufficient to account for complete muscle differentiation.

Human growth hormone in the blood of athymic mice grafted with cultures of hormone-secreting human keratinocytes.

An established line of human epidermal keratinocytes was permanently transformed by transfection with plasmid vectors bearing the human growth hormone gene under the control of two different promoters. Suitable selection permitted the isolation of clones secreting abundant growth hormone in culture. When such cultures were grafted to athymic mice, human growth hormone could be detected in the blood of the mice at concentrations in the physiological range for more than 4 weeks. Retrograde transfer from epithelial cells should be studied further as a possible means of introducing exogenous gene products into the circulation of humans.

Divergent evolution of part of the involucrin gene in the hominoids: unique intragenic duplications in the gorilla and human.

The gene for involucrin, an epidermal protein, has been remodeled in the higher primates. Most of the coding region of the human gene consists of a modern segment of repeats derived from a 10-codon sequence present in the ancestral segment of the gene. The modern segment can be divided into early, middle, and late regions. We report here the nucleotide sequence of three alleles of the gorilla involucrin gene. Each possesses a modern segment homologous to that of the human and consisting of 10-codon repeats. The early and middle regions are similar to the corresponding regions of the human allele and are nearly identical among the different gorilla alleles. The late region consists of recent duplications whose pattern is unique in each of the gorilla alleles and in the human allele. The early region is located in what is now the 3' third of the modern segment, and the late, polymorphic region is located in what is now the 5' third. Therefore, as the modern segment expanded during evolution, its 3' end became stabilized, and continuing duplications became confined to its 5' end. The expansion of the involucrin coding region, which began long before the separation of the gorilla and human, has continued in both species after their separation.

Unique sequence, ski, in Sloan-Kettering avian retroviruses with properties of a new cell-derived oncogene.

The Sloan-Kettering viruses (SKVs) are a group of transforming retroviruses that were isolated from chicken embryo cells which had been infected with the avian leukosis virus transformation-defective Bratislava 77 (tdB77). Each of the SKV isolates was shown to contain multiple genomes of different sizes indicating the presence of several viruses in addition to tdB77. To identify and characterize the putative transforming gene(s) of the SKVs, we used hybridization selection to isolate the fraction of a representative cDNA which was SKV specific. Both solution and blot hybridization studies with viral RNAs showed that the specific probe contained a sequence, ski, that was at least partially held in common by the multiple SKV genomes. This conclusion was confirmed by the observation that a molecularly cloned ski probe also hybridized to each of the multiple SKV genomes. Southern blots of chicken DNA revealed homologs of ski (c-ski) which were not associated with endogenous viral loci. Results showing that c-ski was expressed in polyadenylated cytoplasmic RNA of uninfected chicken cells indicated that it is a functional gene. Other data showed that c-ski was conserved in avian and mammalian evolution, suggesting a functional role for the gene in species other than chickens. Using ski cDNA in solution hybridizations with viral RNAs and in Southern blot hybridization with cloned retroviral oncogenes, we did not detect any relationship between ski and any of 15 previously identified oncogenes.