Avian myelocytomatosis virus (MC29V) is a retrovirus that transforms both fibroblasts and macrophages in culture and induces myelocytomatosis,
carcinomas, and
sarcomas in birds. Previous work identified a sequence of about 1,500
nucleotides (here denoted onc(MCV)) that apparently derived from a normal cellular sequence and that may encode the oncogenic capacity of MC29V. In an effort to further implicate onc(MCV) in
tumorigenesis, we used molecular hybridization to examine the distribution of nucleotide sequences related to onc(MCV) among the genomes of various avian retroviruses. In addition, we characterized further the genetic composition of the remainder of the MC29V genome. Our work exploited the availability of radioactive DNAs (
cDNA's) complementary to onc(MCV) (
cDNA(MCV)) or to specific portions of the genome of avian sarcoma virus (ASV). We showed that genomic RNAs of avian erythroblastosis virus (AEV) and avian myeloblastosis virus (AMV) could not hybridize appreciably with
cDNA(MCV). By contrast,
cDNA(MCV) hybridized extensively (about 75%) and with essentially complete fidelity to the genome of Mill Hill 2 virus (MH2V), whose pathogenicity is very similar to that of MC29V, but different from that of AEV or AMV. Hybridization with the ASV
cDNA's demonstrated that the MC29V genome includes about half of the ASV envelope
protein gene and that the remainder of the MC29V genome is closely related to nucleotide sequences that are shared among the genomes of many
avian leukosis and
sarcoma viruses. We conclude that onc(MCV) probably specifies the unique set of pathogenicities displayed by MC29V and MH2V, whereas the oncogenic potentials of AEV and AMV are presumably encoded by a distinct nucleotide sequence unrelated to onc(MCV). The genomes of ASV, MC29V, and other avian oncoviruses thus share a set of common sequences, but apparently owe their various oncogenic potentials to unrelated transforming genes.