Characterisation of a Dictyostelium discoideum DNA fragment coding for a putative tRNAValGUU gene. Evidence for a single transcription unit consisting of two overlapping class III genes

Ordered yeast artificial chromosome clones representing the Dictyostelium discoideum genome

High resolution gene maps of the six chromosomes of Dictyostelium discoideum have been generated by a combination of physical mapping techniques. A set of yeast artificial chromosome clones has been ordered into overlapping arrays that cover >98% of the 34-magabase pair genome. Clones were grouped and ordered according to the genes they carried, as determined by hybridization analyses with DNA fragments from several hundred genes. Congruence of the gene order within each arrangement of clones with the gene order determined from whole genome restriction site mapping indicates that a high degree of confidence can be placed on the clone map. This clone-based description of the Dictyostelium chromosomes should be useful for the physical mapping and subcloning of new genes and should facilitate more detailed analyses of this genome. cost of silicon-based construction and in the efficient sample handling afforded by component integration.

Genetic structure of a natural population of Dictyostelium discoideum, a cellular slime mould

Dictyostelium discoideum is a eukaryotic microbe feeding on soil bacteria. A first step towards describing the genetic structure of populations of this species was made by examining multiple isolates from a single locale. The isolates were grown clonally and their RFLP patterns compared, using a probe specific for a family of tRNA genes. Thirty-nine types were distinguished in 54 isolates. To determine if genetic exchange occurs among members of the population, an analysis of linkage disequilibrium was performed on the RFLP data. Little disequilibrium was found, implying gene flow in the population. In conflict with this result is the finding that no recombinant progeny were recovered from many attempted crosses between pairs of isolates. The tentative conclusion is that genetic exchange does not in fact occur, and that the observed shuffling of RFLP bands is caused by insertion and excision of transposons known to be associated with the tRNA genes of Dictyostelium.

Transfer RNA genes from Dictyostelium discoideum are frequently associated with repetitive elements and contain consensus boxes in their 5' and 3'-flanking regions

A total of 68 different tRNA genes from the cellular slime mold Dictyostelium discoideum have been isolated and characterized. Although these tRNA genes show features common to typical nuclear tRNA genes from other organisms, several unique characteristics are apparent: (1) the 5'-proximal flanking region is very similar for most of the tRNA genes; (2) more than 80% of the tRNA genes contain an "ex-B motif" within their 3'-flanking region, which strongly resembles characteristics of the consensus sequence of a T-stem/T-loop region (B-box) of a tRNA gene; (3) probably more than 50% of the tRNA genes in certain D. discoideum strains are associated with a retrotransposon, termed DRE (Dictyostelium repetitive element), or with a transposon, termed Tdd-3 (Transposon Dictyostelium discoideum). DRE always occurs 50 (+/- 3) nucleotides upstream and Tdd-3 always occurs 100 (+/- 20) nucleotides downstream from the tRNA gene. D. discoideum tRNA genes are organized in multicopy gene families consisting of 5 to 20 individual genes. Members of a particular gene family are identical within the mature tRNA coding region while flanking sequences are idiosyncratic.

Electrophoretic karyotype for Dictyostelium discoideum

This paper reports on the separation of the Dictyostelium discoideum chromosomes by pulse-field electrophoresis and the correlation of the electrophoretic pattern with linkage groups established by classical genetic methods. In two commonly used laboratory strains, five chromosome-sized DNA molecules have been identified. Although the majority of the molecular probes used in this study can be unambiguously assigned to established linkage groups, the electrophoretic karyotype differs between the closely related strains AX3k and NC4, suggesting that chromosomal fragmentation may have occurred during their maintenance and growth. The largest chromosome identified in this study is approximately 9 million base pairs. To achieve resolution with molecules of this size, programmed voltage gradients were used in addition to programmed pulse times.

Nonsense suppression in Dictyostelium discoideum

We describe the generation of Dictyostelium discoideum cell lines that carry different suppressor tRNA genes. These genes were constructed by primer-directed mutagenesis changing a tRNA(Trp)(CCA) gene from D. discoideum to a tRNA(Trp)(amber) gene and changing a tRNA(Glu)(UUC) gene from D. discoideum to a tRNA(Glu)(ochre) as well as a tRNA(Glu)(amber) gene. These genes were stably integrated into the D. discoideum genome together with a reporter gene. An actin 6::lacZ gene fusion carrying corresponding translational stop signals served as a reported. Active beta-galactosidase is expressed only in D. discoideum strains that contain, in addition to the reporter, a functional suppressor tRNA. Both amber suppressors are active in D. discoideum without interfering significantly with cell growth and development. We failed, however, to establish cell lines containing a functional tRNA(Glu)(ochre) suppressor. This may be due to the fact that nearly every message from D. discoideum known so far terminates with UAA. Therefore a tRNA capable of reading this termination codon may not be compatible with cell growth.

Transfer RNA genes: landmarks for integration of mobile genetic elements in Dictyostelium discoideum

In prokaryotes and eukaryotes mobile genetic elements frequently disrupt the highly conservative structures of chromosomes, which are responsible for storage of genetic information. The factors determining the site for integration of such elements are still unknown. Transfer RNA (tRNA) genes are associated in a highly significant manner with different putative mobile genetic elements in the cellular slime mold Dictyostelium discoideum. These results suggest that tRNA genes in D. discoideum, and probably tRNA genes generally in lower eukaryotes, may function as genomic landmarks for the integration of different transposable elements in a strictly position-specific manner.

tRNAGlu(GAA) genes from the cellular slime mold Dictyostelium discoideum

The haploid genome of the cellular slime mold Dictyostelium discoideum contains at least 18 gene copies coding for a tRNAGlu(GAA). Using a combination of parasexual genetic analysis and molecular biology techniques, 14 of the 18 individual members of this gene family could be assigned to particular linkage groups. According ot this analysis four tRNAGlu genes are located on group I (C, H, I, K), two genes on group II (D,J), seven genes on either group III or VI (A, B, E, F, L, M, N), and one gene on group VII (G). Eight of the tRNAGlu(GAA) genes have been cloned and characterized. All genes are identical in that part of the gene which corresponds to the mature tRNA, thus representing true nonallelic members of this gene family. Different members of this gene family can be distinguished from each other because they reside on restriction fragments of different lengths and because each gene contains unique 5'- and 3'-flanking regions. Nevertheless, a certain degree of sequence conservation within these flanking regions is apparent for members of this gene family. According to in vivo expression analyses of individual genes in Saccharomyces cerevisiae, all isolated tRNAGlu(GAA) copies represent functional transcription units.

CMER, an RNA encoded by human cytomegalovirus is most likely transcribed by RNA polymerase III

Through computer analysis of a human cytomegalovirus (HCMV) genomic region, previously identified to be homologous to human genomic DNA, an element showing significant similarity to the 3'-internal control region (3'-ICR or B-block) of a eukaryotic RNA polymerase III promoter could be detected. This region-located on the EcoRI b fragment within the UL segment of the viral genome of HCMV strain AD 169-cannot be transcribed in vitro in an RNA polymerase III specific transcription system. However, this part of the viral genome is able to compete for components of the RNA polymerase III transcription complex as shown in template exclusion experiments and by gel retardation assays. Two different synthetic oligonucleotides complementary to the 3'-ICR and to nucleotides located immediately downstream of this promoter element can anneal specifically to a HCMV-encoded ribonucleic acid (termed CMER) synthesized in human foreskin fibroblasts (HFF) late in virus replication. As a consequence of identifying the transcription initiation point by primer extension analyses the position of the 5'-internal control region (5'-ICR or A-block) of the CMER gene could be uncovered. Both identified control regions (the A-block as well as the B-block) of the transcription unit exhibit significant similarities to corresponding regulatory elements of other class III genes, including virus encoded class III genes. Initiation of in vivo transcription occurs 15 nucleotides upstream of the 5'-border of the 5'-ICR and the two non-contiguous gene internal promoter elements are separated by 79 nucleotides.

A family of non-allelic tRNA(ValGUU) genes from the cellular slime mold Dictyostelium discoideum

A haploid genome of the cellular slime mold Dictyostelium discoideum contains at least 14 non-allelic gene copies coding for a tRNA(ValGUU). The structure, genomic organization, and expression of these genes have been analyzed in relation to stages of the developmental cycle. So far, 13 tRNA(ValGUU) genes have been isolated and characterized. All genes contain identical mature tRNA-coding regions, and consequently identical gene internal promoter elements. However, different genes differ with respect to their 5'- and 3'-flanking regions, although a certain degree of sequence conservation seems apparent. Different members of this tRNA gene family appear to be randomly dispersed along the seven D. discoideum chromosomes, and not clustered at any one genomic location. In vivo expression of individual genes was studied in yeast. All but one tRNA(ValGUU) gene are actively transcribed, though with different efficiencies. There is also evidence that not all of these tRNA genes are constitutively transcribed in Dictyostelium throughout the developmental cycle. One characteristic primary transcript can only be detected in cells of the late preaggregation phase, whereas growing cells, cells in the stationary phase or cells harvested 4 h after the onset of development do not seem to carry this transcript. This product seems to be transcribed from a gene of an unusual structure. Although this particular gene has not yet been isolated, it can be predicted from the sequence of the cDNA synthesized from primary transcription products of this putative gene, that it is composed of nt 1-54 of a 3'-truncated tRNA(ValGUU) gene linked to a bona fide tRNA(ValGUU) gene.

Influence of different 5'-flanking sequences of tRNA genes on their in vivo transcription efficiencies in Saccharomyces cerevisiae

We have investigated the influence of 5'-flanking sequences on the in vivo transcription activities in yeast. Since eukaryotic tRNA genes belong to multi-copy gene families monitoring of the activity of a particular tRNA gene is not possible. We therefore used two different tRNA genes from the cellular slime mould Dictyostelium discoideum which are efficiently transcribed and processed in vivo in yeast. The original 5'-flanking sequences of the two tRNA genes were replaced by random plasmid sequences. The modified tRNA genes were introduced into Saccharomyces cerevisiae and bulk tRNAs from the transformants were analyzed for the presence and the relative number of Dictyostelium tRNA gene transcripts. Substantial differences of steady-state levels of RNA transcribed were detected dependent on the 5'-flanking sequence of the tRNA gene. Minute structural changes, such as inserting two additional nucleotides in front of a tRNA gene, can lead to drastic activity changes. The efficiency of tRNA gene transcription can be conferred by sequences located more than 40 nucleotides upstream from the 5' end of the mature tRNA coding region.

Primer extension analysis of tRNA gene transcripts synthesized in vitro and in vivo

The primer elongation method has been adapted to analyze tRNA gene transcripts. The primer used to direct cDNA synthesis from a corresponding tRNA template, in the presence of AMV reverse transcriptase, was a restriction fragment, or a synthetic oligonucleotide, containing exclusively coding nucleotides of a tRNA gene. This method not only allows one to identify the exact 5'-end of mature tRNA, but also 5'-ends of primary transcripts are readily determined. Further, analysis of tRNAs synthesized in vitro, as well as tRNAs produced in vivo in homologous and heterologous organisms can be studied. Purification of the tRNAs questioned, from bulk tRNA, is not necessary.

Chromosomal mapping of tRNA genes from Dictyostelium discoideum

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).

Structure and transcription of eukaryotic tRNA genes

The availability of cloned tRNA genes and a variety of eukaryotic in vitro transcription systems allowed rapid progress during the past few years in the characterization of signals in the DNA-controlling gene transcription and in the processing of the precurser RNAs formed. This will be the subject matter discussed in this review.