Regulation of transcription in expressed and unexpressed mating type cassettes of yeast

rme1 Mutation of Saccharomyces cerevisiae: map position and bypass of mating type locus control of sporulation

Sporulation in Saccharomyces cerevisiae normally occurs only in MATa/MAT alpha diploids. We show that mutations in RME1 bypassed the requirements for both a and alpha mating type information in sporulation and therefore allowed MATa/MATa and MAT alpha/MAT alpha diploids to sporulate. RME1 was located on chromosome VII, between LEU1 and ADE6.

Sporulation and rna2 lower ribosomal protein mRNA levels by different mechanisms in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the levels of ribosomal protein mRNAs are regulated coordinately. Vegetative strains carrying the temperature-sensitive rna2 mutation exhibit a dramatic decrease in the levels of most ribosomal protein mRNAs at the restrictive temperature. Similarly, in wild-type cells induced to sporulate by nitrogen starvation, there is a fivefold reduction in the relative synthesis rate of ribosomal proteins. Using Northern gel analysis and cloned ribosomal protein genes, we compared the way in which ribosomal protein mRNA is affected under these two conditions. In vegetative rna2 cells, incubation at 34 degrees C led to the disappearance of ribosomal protein mRNAs and the accumulation of higher-molecular-weight precursor RNAs. A different phenotype was observed during sporulation. Although sporulating conditions led to a significant reduction in the relative abundance of ribosomal protein mRNA, there was no detectable accumulation of precursor RNAs even in rna2/rna2 diploids at 34 degrees C. A suppressor of rna2 and of other rna mutations, SRN1, at least partially relieved the block in the splicing of the ribosomal protein 51 intron in vegetative rna2 cells but did not detectably affect the level of ribosomal protein mRNA in sporulating cells. We concluded that the rna2 mutation and sporulation conditions affected ribosomal protein mRNA metabolism in two quite different ways. In vegetative cells the mutant rna2 effected a block which occurred primarily in post-transcriptional processing, whereas in sporulating cells the ribosomal protein mRNA levels were decreased by some other mechanism, presumably a change in the relative rate of transcription or mRNA turnover. Furthermore, the data suggest that the mutation rna2 has no additional effect on ribosomal protein mRNA metabolism in sporulating cells.

Yeast RNA polymerase II transcription of circular DNA at different degrees of supercoiling

Purified yeast RNA polymerase II was tested for transcriptional activity as a function of the degree of circular DNA supercoiling. Chimaeric plasmids P30 and P31 both containing inserts from the yeast transposable element TY1 cloned in pBR322 and the vector pBR322 were used as templates. For pBR322 the transcriptional activity increases about 4 fold from the fully relaxed covalently closed circles to the native supercoiled forms, further supercoiling having no effect on transcription. P30 shows a 5 fold increase of transcriptional activity reaching a plateau at the native supercoiled conformation. However, at an intermediate degree of supercoiling (sigma = 0.024), transcription decreases to a value close to zero. P31 too exhibits a conformation (sigma = 0.014) in which there is a drop of transcriptional activity. Furthermore, a 10 fold increase of transcription is obtained at the higher values of superhelix density. Both kinetic and autoradiographic experiments confirm the existence of DNA conformations that can inhibit "in vitro" transcription.

Transcriptional control signals of a eukaryotic protein-coding gene

Transcriptional control signals of a model eukaryotic protein-coding gene have been identified by a new procedure of in vitro mutagenesis. This method allows small clusters of nucleotide residues to be substituted in a site-directed manner without causing the addition or deletion of other sequences. Transcription assays of a systematic series of these clustered point mutants have led to the identification of three distinct control signals located within the 105-nucleotide residues immediately upstream from the point where transcription begins.

RNA splicing is required to make the messenger RNA for a variant surface antigen in trypanosomes

The expression of the gene for variant surface glycoprotein (VSG) 118 in Trypanosoma brucei is activated by transposing a DNA segment containing the gene and 1-2 kb in front of it to an expression site elsewhere in the genome. By S1 nuclease protection and RNA blotting experiments we show here the presence of several minor transcripts in trypanosomes synthesizing VSG 118, one of which covers the entire transposed segment. Comparison of the sequence of the 5' terminal segment of VSG 118 messenger RNA (mRNA), determined by primed reverse transcription, and the corresponding region of the 118 VSG gene, shows that the 5' terminal 34 nucleotides of the mRNA are not encoded in the 118 VSG gene contiguous with the remainder of the mRNA. We conclude that synthesis of a VSG mRNA involves splicing of a much longer primary transcript, which may start outside the transposed segment.

Variety in the level of gene control in eukaryotic cells

In light of present progress in the understanding of how messenger RNA is constructed in eukaryotic cells, the levels of gene control are discussed. Transcriptional control, assessed by the rate of synthesis of specific nuclear RNA, is strongly indicated to be the most frequent level of control. Definition of eukaryotic transcription units as simple (encoding one protein) and complex (encoding two or more proteins) affords a framework in which to discuss control at the level of RNA processing for which several examples also are known. Finally, differential stability of cytoplasmic mRNAs and differential translation, both well established, are briefly described.

The establishment of genomic DNA libraries for the human malaria parasite Plasmodium falciparum and identification of individual clones by hybridisation

The DNA of Plasmodium falciparum has been purified and fragmented with the restriction endonucleases EcoRI and HindIII. The fragments have been incorporated in vitro into derivatives of bacteriophage lambda to make libraries in which most of the parasite DNA is represented. By Southern hybridisation we have been able to recover from these libraries specific clones containing (a) repetitive DNA sequences, (b) rRNA gene(s) and (c) sequences homologous to an actin gene probe. Parasite DNA from two independent sources differs markedly in the pattern of its repetitive DNA visualised by hybridisation to our repetitive clone. By contrast, the rRNA genes of the two isolates prove to be carried on identically sized fragments.

Isolation and characterization of yeast ring chromosome III by a method applicable to other circular DNAs

A method is described for the isolation and purification of covalently closed circular (ccc) DNA from yeast (Saccharomyces cerevisiae). Spheroplasts are lysed at pH 12.45 which denatures linear but not ccc DNA. Next, the lysate is taken through a gentle high-salt-phenol extraction to remove single-stranded DNA. The ccc DNA, recovered by ethanol precipitation, can be further studied by agarose gel electrophoresis, can be cut with restriction endonucleases and can be used to transform Escherichia coli. This method efficiently purifies large (approx. 190 kb) and small (approx. 1.5 kb, TRP1-RI Circle) circular DNAs and thus has general applicability for isolation and purification of plasmids from yeast.

Structure and expression of a Trypanosoma brucei gambiense variant specific antigen gene

The expression-linked copy of the T. b. gambiense variant specific antigen gene LiTat 1.6 is transposed in a 20 kb DNA region devoid of restriction sites, located near a chromosome end. This expression site is very similar to that of T. b. brucei variants 117, 118 (1) and AnTat 1.8. In the basic copy, the transposable element (TE) is flanked by repetitive sequences; it includes the gene copy as well as a sequence of 0.9 to 2.1 kb (probably around 1.1 kb) long, upstream from the gene. Probes derived from the 5' part of the TE specifically reveal three polyadenylated transcripts of 4.2, 1.45 and 0.85 kb, respectively, distinct from the 2.1 kb mRNA. The amount of the 4.2 kb sequence is probably less than 0.01% of total trypanosome RNA. Whereas the mRNAs coding for the three isotypic antigens AnTat 1.8 (T. b. brucei), 12.2 (T. b. rhodesiense) and 3.3 (T. evansi) are recognized by LiTat 1.6 probes extending into the 3' half of the transposed sequence, the 5' genomic probes do not hybridize with any of these RNAs. These observations suggest that the LiTat 1.6 gene could be first transcribed in a large precursor molecule. This precursor would be rapidly processed, loosing a large portion of less conserved sequence from its 5' half. Our data are compatible with a model in which the promoter would be provided by the expression site.

Characterization of the DNA duplication-transposition that controls the expression of two genes for variant surface glycoproteins in Trypanosoma brucei

The genome of Trypanosoma brucei carries over a hundred genes coding for different variants of the major surface glycoprotein. Activation of some of these genes is accompanied by a duplication and transposition of the gene (the basic copy) to another region in the genome where it is transcribed. We present here physical maps of the basic and transposition-activated genes for two surface glycoproteins of Trypanosoma brucei, stock 427. In both cases the transposed segment starts 1-2 kb in front of the coding region and ends within the 3'-terminal region of the gene. The DNA segments flanking both transposed genes are indistinguishable and share a 6-kb stretch upstream and a 8-kb stretch downstream of the transposed segment not cut by several restriction endonucleases. The 5' borders of the two transposed segments are homologous and contain sequences present in many copies in the genome. A different repeated sequence has previously been found at the 3' edge of the transposed segment. The replicative transposition may, therefore, involve a unidirectional gene conversion initiated by base pairing between the edges of the transposed sequence and a single expression site elsewhere in the genome.

Perspectives in molecular mutagenesis

The models and paradigms that underlie a vigorously developing science may tend to stifle progress or may serve to sharpen the knife edge of paradox. Working out mutagenic mechanisms is a conceptually and technologically demanding task, and we are accumulating an increasingly uncomfortable number of experimental and theoretical inconsistencies. First, there continue to be widespread difficulties in specifying the chemical nature of mutagenic DNA alterations, both because of the multitude of DNA reaction products induced by many mutagens and because of the intrinsic rarity of most mutational responses. For instance, alkylation of the 0(6) position of guanine to generate adducts of modest dimensions is widely believed to form the basis for the mutagenic and carcinogenic actions of numerous chemicals. However, while this scheme is supported by in vitro evidence, it has failed to explain why bacteriophages can be thus alkylated in vitro by N-methyl-N'-nitro-N-nitrosoguanidine without the production of mutations, or why microbial eukaryotes alkylated by ethyl methanesulfonate or N-methyl-N'-nitro-N-nitrosoguanidine display no mutagenic response when their "error-prone repair systems" are mutationally inactivated. Second, a base pair is typically mutated at vastly different rates, and with different directional specificities, when it resides at different positions within a gene; whereas very little of this variability is explained by current theories that aim to describe the determinants of fidelity in DNA replication. (Some sizable portion of this variation now appears to depend not only upon neighboring base-pair influences but also upon much more subtle and distant effects). Third, experimental modifications of enzymatic fidelity by means of amino acid substitutions, and perhaps also cation replacements, lead to such a diversity of modified mutation rates as to seriously challenge the ability of any simple theory to organize the experimental observations into a coherent and predictive network.

rme1 Mutation of Saccharomyces cerevisiae: map position and bypass of mating type locus control of sporulation

Sporulation in Saccharomyces cerevisiae normally occurs only in MATa/MAT alpha diploids. We show that mutations in RME1 bypassed the requirements for both a and alpha mating type information in sporulation and therefore allowed MATa/MATa and MAT alpha/MAT alpha diploids to sporulate. RME1 was located on chromosome VII, between LEU1 and ADE6.

Analysis of the DNA and RNA changes associated with the expression of isotypic variant-specific antigens of trypanosomes

Using specific (32P) labelled cDNA probes, we compared the mRNAs and the genomic DNA sequences coding for the synthesis of two pairs of serologically related variant-specific antigens (VSAs) of trypanosomes: AnTat 1.1 and AnTat 1.1b, both from the strain 1125 of T.b.brucei and AnTat 1.8 and LiTat 1.6 from T.b.brucei and T.b. gambiense, respectively. Within each pair, large similarities were observed in the coding sequence, except in the 3' region which appears to be highly variable. However, a low level of cross-hybridization can be detected between all sequences, in the 3' region only. The expression of these VSAs is linked to a similar duplication-transposition mechanism. The insertion locus of the transposition unit is the same both in AnTat 1.1 and AnTat 1.1b DNAs. In both pairs, the transposition unit seems to comprise at least about 200 bp upstream of the 5' extremity of the coding sequence. The significance of these results, regarding the structure and synthesis of the VSAs, is discussed.

A position-effect control for gene transposition: state of expression of yeast mating-type genes affects their ability to switch

Mating-type switches of the yeast Saccharomyces cerevisiae occur by unidirectional transposition of copies of unexpressed mating-type genetic information, residing at HML and HMR loci, into the expressed MAT locus. The HML and HMR loci remain unchanged. In contrast, in appropriate strains where the silent loci are also allowed to express, for example in mar mutants, efficient switches of HML and HMR are shown to occur at rates equivalent to those observed for MAT. Thus the position-effect control on the direction of transposition is affected by the state of expression of the locus under study the expressed loci switch regardless of their location.

Structural comparison of two yeast tRNA Glu 3 genes

DNA sequences in a 1.7 kb Pst fragment from yeast have been determined. This fragment is part of a yeast 7.4 kb Hind III segment cloned ino pBR322 (pY 5). The fragment carries a single gene for a glutamate tRNA. The coding portion of this gene is identical in sequence to that of the tRNA Glu 3 gene from pY 20 [1]. The flanking regions differ in their sequences, but possible secondary structures within the 5'-flanking regions bear similar features. Sequence homologies between pY 5 and pY 20 were detected far outside the tRNA genes. More surprisingly, extended sequence homologies were seen between the flanking regions of the pY 20 tRNA Glu 3 gene and a tRNA Ser gene [2,3]. We have also checked the known tRNA genes for structural similarities. Hybridization studies indicate that portions of the Pst fragment are repeated within the yeast genome.

Homology and non-homology at the yeast mating type locus

Four mutations of the alpha mating type locus of Saccharomyces cerevisiae have been analysed to determine their relationship to the a mating type locus. Mat alpha+ recombinations are produced by mat alpha 2-/MAT but not by mat alpha 1-/MATa diploids. MAT alpha and MATa thus contain regions of homology (coding for at least part of MAT alpha 2) and regions of non-homology (coding for at least part of MAT alpha 1)-the genetic determinant for cell type is larger than the non-homologous sequence seen by DNA-DNA heteroduplexes and genetic analysis. The segment transposed in mating type interconversion includes both types of sequence.