Different wild-type isolates of Dictyostelium discoideum exhibit extensive polymorphism in the length of restriction fragments carrying tRNA genes. These size differences were used to study the organisation of two tRNA gene families which encode a tRNA Val(GUU) and a tRNA Val(GUA) gene. The method used involved a combination of classical D. discoideum parasexual genetics and molecular genetics. The tRNA genes were mapped to specific linkage groups (chromosomes) by correlating the presence of polymorphic DNA bands that hybridized with the tRNA gene probes with the presence of genetic markers for those linkage groups. These analyses established that both of the tRNA gene families are dispersed among sites on several of the chromosomes. Information of nine tRNA Val(GUU) genes from the wild-type isolate NC4 was obtained: three map to linkage group I (C, E, F), two map to linkage group II (D, I), one maps to linkage group IV (G), one, which corresponds to the cloned gene, maps to either linkage group III or VI (B), and two map to one of linkage groups III, VI or VII (A, H). Six tRNA Val(GUA) genes from the NC4 isolate were mapped: one to linkage group I (D), two to linkage group III, VI or VII (B, C) and three to linkage group VII or III (A, E, F).
A genomic DNA fragment from Dictyostelium discoideum was characterized. This DNA, although 74% d(A + T)‐rich, codes for a putative tRNAValGUU. The tRNAVal gene overlaps at its 5′ half with another RNA polymerase III transcription unit. This RNA polymerase III transcription unit can be folded into a tRNA‐like shape and is comprised of significant amounts of invariant and semi‐invariant nucleotides present in all eukaryotic tRNAs. This unit contains the two promoter blocks defined for RNA polymerase III, which are homologous to recently defined promoter elements to the extent of 76–88% (A block) and 86–93% (B block) respectively [Sharp et al. (1981) Proc. Natl Acad. Sci. USA 78, 6657–6661]. Both of the overlapping class III genes are transcribed in germinal vesicle extracts prepared from Xenopus laevis oocytes as a single transcription unit, resulting in an unusually large product compared to primary transcripts of other tRNA genes. The unit is not transcribed in HeLa extracts but it competes very strongly for transcription factor(s) under the conditions of stable transcription complex formation. Although the whole unit is transcribed, it is believed that only one functional product is formed. Therefore we define the tRNA‐like structure, coded for on this class III transcription unit, as a putative tRNA ‘pseudogene’ meaning that, although it is transcribed by RNA polymerase III, it is not likely to mature to a functional tRNA.
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