Molecular characterisation of congenital myasthenic syndromes in Southern Brazil.

OBJECTIVE: To perform genetic testing of patients with congenital myasthenic syndromes (CMS) from the Southern Brazilian state of Parana. PATIENTS AND METHODS: Twenty-five CMS patients from 18 independent families were included in the study. Known CMS genes were sequenced and restriction digest for the mutation RAPSN p.N88K was performed in all patients. RESULTS: We identified recessive mutations of CHRNE in ten families, mutations in DOK7 in three families and mutations in COLQ, CHRNA1 and CHRNB1 in one family each. The mutation CHRNE c.70insG was found in six families. We have repeatedly identified this mutation in patients from Spain and Portugal and haplotype studies indicate that CHRNE c.70insG derives from a common ancestor. CONCLUSIONS: Recessive mutations in CHRNE are the major cause of CMS in Southern Brazil with a common mutation introduced by Hispanic settlers. The second most common cause is mutations in DOK7. The minimum prevalence of CMS in Parana is 0.18/100 000.

Molecular analysis of the yeast Ty4 element: homology with Ty1, copia, and plant retrotransposons.

The element; Ty4 is a retrotransposon present in low copy number in the genome of Saccharomyces cerevisiae [Stucka et al., Nucleic Acids Res. 17 (1989) 4993-5001]. We have determined the complete nucleotide sequence of one such element from a particular strain and compared it to the other two elements occurring in this strain. The genomic organization of Ty4 is homologous to that found in other retrotransposons of the Ty1-copia group. The internal part of the element contains two large open reading frames (TY4A and TY4B) overlapping by 226 bp in a + 1 mode. TY4A reveals characteristics of the gag portion of retrotransposons and retroviruses, while TY4B consists of a protease, an integrase, a reverse transcriptase, and an RNase H domain (in that order). Our analyses suggest that only one of these copies might be transpositionally active. Sequence comparisons at the amino acid level show that the domains in Ty4 diverge considerably from those of other retrotransposons. The greatest similarity is seen between the reverse transcriptases (50%), the proteases (40%), and the integrases (30%) of Ty4, Ty1/2 and copia, respectively, whereas the degree of similarity for all other entities of these elements is much lower. Considering evolutionary aspects of the retrotransposons, we have to conclude that Ty4 has diverged at an early stage from the progenitors of other known retroelements and represents a novel and independent subgroup of the Ty1-copia class of retrotransposons.

Characterization of the prephenate dehydrogenase-encoding gene, TYR1, from Saccharomyces cerevisiae.

TYR1, the gene from Saccharomyces cerevisiae, which encodes prephenate dehydrogenase, one of the tyrosine biosynthetic enzymes, has been cloned by complementing a yeast tyr1 mutant strain. The DNA fragment containing the gene is part of a 45-kb cosmid clone which represents a region of chromosome II covering the genetically mapped tyr1 locus. The nucleotide sequence of a 3.1-kb region carrying the TYR1 gene and adjacent regions has been determined. The open reading frame contains 441 codons, corresponding to about 52.2 kDa for the encoded protein. The canonical NAD-binding domain is located within the first 45 amino acids of the protein. By primer extension, we show that there is one transcription start point. Presumably, the expression of TYR1 is not under the general GCN4 control. Instead, we find a dependence on the presence or absence of phenylalanine. These data were obtained by analysing CAT activity in constructs containing promoter fragments of TYR1 and the cat reporter gene.

An element of symmetry in yeast TATA-box binding protein transcription factor IID. Consequence of an ancestral duplication?

TATA-box binding factor TFIID is one of the key factors in transcriptional activation. Surprisingly, the yeast TFDII protein [(1989) Nature 341, 299-303; (1989) Cell 56, 1173-1181; (1989) Proc. Natl. Acad. Sci USA 86, 7785-7789] reveals only limited homology with other DNA-binding proteins. From computer-assisted searches we infer that yeast TFIID possesses a domain structure in which homologous segments are repeated. The greatest similarity is found between two segments, each 33 amino acids in length, in which the positions of four basic residues are strictly conserved. The high homology is also reflected at the gene level. Implications of this novel type of domain structure for possible interactions in transcriptional activation are discussed.

A common mutation (epsilon1267delG) in congenital myasthenic patients of Gypsy ethnic origin.

OBJECTIVE: Mutation analysis of the acetylcholine receptor (AChR) epsilon subunit gene in patients with sporadic or autosomal recessive congenital myasthenic syndromes (CMS). BACKGROUND: The nicotinic AChR of skeletal muscle is a neurotransmitter-gated ion channel that mediates synaptic transmission at the vertebrate neuromuscular junction. Mutations in its gene may cause congenital myasthenic syndromes. A recently described mutation in exon 12 of the AChR epsilon subunit (epsilon1267delG) disrupts the cytoplasmic loop and the fourth transmembrane region (M4) of the AChR epsilon subunit. METHODS: Forty-three CMS patients from 35 nonrelated families were clinically classified as sporadic cases of CMS (group III according to European Neuromuscular Centre consensus) and were analyzed for epsilon1267delG by PCR amplification and sequence analysis. RESULTS: The authors report the complete genomic sequence and organization of the gene coding for the epsilon subunit of the human AChR (accession number AF105999). Homozygous epsilon1267delG was identified in 13 CMS patients from 11 independent families. All epsilon1267delG families were of Gypsy or southeastern European origin. Genotype analysis indicated that they derive from a common ancestor (founder) causing CMS in the southeastern European Gypsy population. Phenotype analysis revealed a uniform pattern of clinical features including bilateral ptosis and mild to moderate fatigable weakness of ocular, facial, bulbar, and limb muscles. CONCLUSIONS: The mutation epsilon1267delG might be frequent in European congenital myasthenic syndrome patients of Gypsy ethnic origin. In general, patients (epsilon1267delG) were characterized by the onset of symptoms in early infancy, the presence of ophthalmoparesis, positive response to anticholinesterase treatment, and the benign natural course of the disease.

The fdp1 and cif1 mutations are caused by different single nucleotide changes in the yeast CIF1 gene.

The allelism between the mutations cif1 and fdp1 from Saccharomyces cerevisiae has been demonstrated using PCR techniques and complementation of function. The cif1 mutation results in a shortened version of the protein while the fdp1 mutation introduces a charged residue in a highly hydrophobic stretch.

An intronic base alteration of the CHRNE gene leading to a congenital myasthenic syndrome.

Reported is a patient with a congenital myasthenic syndrome due to two compound heterozygous mutations of the CHRNE gene. The molecular consequences of a novel intronic base alteration (CHRNE IVS5-16GA) remote from the splice acceptor site were investigated in vivo and in vitro. In conclusion, RNA analysis may be necessary to reveal unexpected splicing aberrations due to intronic mutations that are not part of the consensus splice site.

Conserved and non-conserved features among the yeast Ty elements.

We have isolated and characterized a Ty element from a yeast cosmid library which exhibits several unusual features: it is flanked by non-homologous delta elements and directly associated with a singular delta element. A tRNA(Glu3) gene and tRNA(Cys) gene are found in conjunction with this element, located in opposite orientation on either end of it. The sequence information now available for several Ty elements has been used in a detailed comparative analysis to determine conserved features among the Ty elements, preferably between class I elements and a class II element. Highly conserved sequence motifs appear to be located at the borders of particular segments that correspond to the putative protein domains of the Tys. Furthermore, we include a comparison of the best-conserved amino acid homologies for these putative proteins of Ty elements, transposable elements from other organisms and several retroviral proviruses to confirm their close structural resemblance.

Different patterns of transposable elements in the vicinity of tRNA genes in yeast: a possible clue to transcriptional modulation.

We have extended the catalogue of yeast tRNA genes that are found associated with repetitive (transposable) elements. We determined the nucleotide sequences of loci containing the genes for a tRNAGln and a tRNASer2 (pY66), a tRNAGlu3 (pY80), and a tRNALys1 (pY109). Our analyses revealed that complex patterns exist in which different types of elements (Ty, delta, sigma, and tau) are involved. We could further demonstrate that in several there are alleles of which one contains a particular element and the other lacks it; such differences are also found when comparing hybridization patterns of DNA from a diploid and a haploid yeast strain. In order to investigate a possible functional role of the elements in conjunction with the tRNA genes, we compared the transcriptional activities of several tRNA genes by microinjection into Xenopus oocyte nuclei. The observed differences in expression may be attributed to the presence or absence of different elements in the vicinity of the tRNA genes.

One member of the tRNA(Glu) gene family in yeast codes for a minor GAGtRNA(Glu) species and is associated with several short transposable elements.

During characterization of the whole tRNA-(Glu) family from the yeast, Saccharomyces cerevisiae, we isolated one cosmid clone bearing a tRNA(Glu) gene copy that is deviant from the major tRNA(Glu3) gene members in only five positions. This divergent tRNA-(Glu) is a minor species and is represented by a single gene copy. One of the nucleotide exchanges concerns the anticodon which is modified from T-T-C in the tRNA(Glu3) gene to C-T-C which implies that this tRNA serves the codon triplet G-A-G. Two other minor yeast tRNA species have been reported which appear to be particularly designed for the translation of those codons that have a G in its third (Wobble) position. The low abundance of such minor tRNA species correlates positively to the low occurrence of most of the N-N-G codons in yeast. Furthermore, the GAGtRNA-(Glu) locus represents another case of the general phenomenon in which the majority of the tRNA genes in yeast are associated with one or several transposable elements forming complex patterns. In this particular case, divergent segments of delta and tau are present in the 5' flanking region of the tRNA gene and arranged in a novel configuration. The sequence data lend support to the view that tau is not an evolutionary young element as was earlier anticipated.

Ty4, a novel low-copy number element in Saccharomyces cerevisiae: one copy is located in a cluster of Ty elements and tRNA genes.

We have identified a composite element, Ty4, in S. cerevisiae that is ca 6.3 kb in length and contains two tau sequences as long terminal repeats. According to hybridization analyses, Ty4 occurs in low but varying copy number (one to four copies) in different yeast strains. By several criteria, Ty4 is a novel type of retroelement which is similar but not related to the other Ty elements in yeast. Two cosmid clones from strain C836 (c90 and c476) carrying individual copies of Ty4 were isolated. By restriction analysis and nucleotide sequence we show that c476 derives from the 'transposition right arm hot spot' of chromosome III [1]. The analysis of c476 revealed that an initiator tRNA(Met) gene is present at this locus and that an unusual concentration of different Ty elements has occurred: in addition to the Ty4, a Ty1 and a Ty2 element were detected in this region, confirming its highly polymorphic character.

A hot-spot for transposition of various Ty elements on chromosome V in Saccharomyces cerevisiae.

Ty4 is a novel transposable element in the yeast, Saccharomyces cerevisiae, which is present in only a few copies in the genome (Stucka et al. 1989). In strain C836 one of the three copies (Ty4-90) is contained in cosmid clone c90, where it resides on chromosome V. Analysis of this region reveals a "hot-spot" of transposition: in addition to Ty4-90, the locus contains a complete Ty3 element and seven singular delta, sigma and tau elements. Three tRNA genes (for His, Lys, and Ile) are located in this region, and these are closely associated with one or the other of the elements, a phenomenon commonly observed in yeast. A comparison of c90 with corresponding regions from other strains shows that the locus is highly polymorphic and that this polymorphism is explicitly associated with Ty transposition and recombination events.

The use of a synthetic tRNA gene as a novel approach to study in vivo transcription and chromatin structure in yeast.

To monitor in vivo transcription and chromatin structure of yeast tRNA genes, we constructed a synthetic tRNA gene that can be used as a reporter. Constructs in which this synthetic tRNA gene is combined with different flanking regions can be integrated into the genome as single copies. The artificial tRNA gene is tagged by the insertion of an intron-like sequence that cannot be spliced out from the precursor and transcripts can thus be identified and quantitated. By several criteria, the artificial tRNA gene behaves like a resident tRNA gene. By measuring the accessibility towards DNaseI in chromatin, we found that the artificial tRNA gene exhibits the same characteristic pattern as resident tRNA genes. Three DNaseI-sensitive sites across the transcribed part of the gene and the immediate flanking regions reflect the formation of the stable transcription complex; positioned nucleosomes are observed in the upstream flanking region. We are confident that the system we have established will prove useful for studying regulatory aspects of tRNA gene expression as well as aspects of pre-tRNA processing and splicing.

DNA sequences in chromosomes II and VII code for pyruvate carboxylase isoenzymes in Saccharomyces cerevisiae: analysis of pyruvate carboxylase-deficient strains.

A gene encoding pyruvate carboxylase has previously been isolated from Saccharomyces cerevisiae. We have isolated a second gene, PYC2, from the same organism also encoding a pyruvate carboxylase. The gene PYC2 is situated on the right arm of chromosome II between the DUR 1, 2 markers and the telomere. We localized the previously isolated gene, which we designate PYC1, to chromosome VII. Disruption of either of the genes did not produce marked changes in the phenotype. However, simultaneous disruption of both genes resulted in inability to grow on glucose as sole carbon source, unless aspartate was added to the medium. This indicates that in wild-type yeast there is no bypass for the reaction catalysed by pyruvate carboxylase. The coding regions of both genes exhibit a homology of 90% at the amino acid level and 85% at the nucleotide level. No appreciable homology was found in the corresponding flanking regions. No differences in the Km values for ATP or pyruvate were observed between the enzymes obtained from strains carrying inactive, disrupted versions of one or other of the genes.

Trehalose-6-P synthase is dispensable for growth on glucose but not for spore germination in Schizosaccharomyces pombe.

Trehalose-6-P inhibits hexokinases in Saccharomyces cerevisiae (M. A. Blázquez, R. Lagunas, C. Gancedo, and J. M. Gancedo, FEBS Lett. 329:51-54, 1993), and disruption of the TPS1 gene (formerly named CIF1 or FDP1) encoding trehalose-6-P synthase prevents growth in glucose. We have found that the hexokinase from Schizosaccharomyces pombe is not inhibited by trehalose-6-P even at a concentration of 3 mM. The highest internal concentration of trehalose-6-P that we measured in S. pombe was 0.75 mM after heat shock. We have isolated from S. pombe the tps1+ gene, which is homologous to the Saccharomyces cerevisiae TPS1 gene. The DNA sequence from tps1+ predicts a protein of 479 amino acids with 65% identity with the protein of S. cerevisiae. The tps1+ gene expressed from its own promoter could complement the lack of trehalose-6-P synthase in S. cerevisiae tps1 mutants. The TPS1 gene from S. cerevisiae could also restore trehalose synthesis in S. pombe tps1 mutants. A chromosomal disruption of the tps1+ gene in S. pombe did not have a noticeable effect on growth in glucose, in contrast with the disruption of TPS1 in S. cerevisiae. However, the disruption prevented germination of spores carrying it. The level of an RNA hybridizing with an internal probe of the tps1+ gene reached a maximum after 20 min of heat shock treatment. The results presented support the idea that trehalose-6-P plays a role in the control of glycolysis in S. cerevisiae but not in S. pombe and show that the trehalose pathway has different roles in the two yeast species.

Analysis of yeast chromosomal regions carrying members of the glutamate tRNA gene family: various transposable elements are associated with them.

We carried out an analysis on the genomic organisation of the tRNA(Glu) family in S. cerevisiae; eight clones were characterized by restriction mapping, hybridization and sequencing. These data taken together with our earlier findings show that the individual tRNA(Glu3) copies are identical only in their structural part but embedded in entirely different genomic environments. All of the tRNA genes identified here are flanked by elements such as Ty, delta, sigma, and tau. In some cases, sequences from different elements form complex patterns indicating a sophisticated history of these chromosomal regions. A novel observation is that Ty and delta in the regions analyzed are exclusively associated with the tRNA genes. The observed patterns imply that the tRNA genes mark regions of multiple transposition and subsequent excision events, but that these have occurred after the individual tRNA gene copies had been fixed in their present locations. Transcription experiments by the use of micro-injection into Xenopus oocytes suggest that the elements flanking the tRNA genes exert a modulating effect on their expression.

DIT101 (CSD2, CAL1), a cell cycle-regulated yeast gene required for synthesis of chitin in cell walls and chitosan in spore walls.

A mutant screen has been designed to isolate mutants in Saccharomyces cerevisiae deficient in spore wall dityrosine. As shown by electron microscopy, most of the mutant spores lacked only the outermost, dityrosine-rich layer of the spore wall. Mutant dit101, however, was additionally lacking the chitosan layer of the spore wall. Chemical measurements showed that this mutant does not synthesize chitosan during sporulation. The mutant spores were viable but sensitive to lytic enzymes (glusulase or zymolyase). Unlike most of the dit-mutants, dit101 did show a distinctive phenotype in vegetative cells: they grew normally but contained very little chitin and were therefore resistant to the toxic chitin-binding dye, Calcofluor White. The cells showed barely detectable staining of the walls with Calcofluor White or primulin. The decrease in the amount of chitin in vegetative cells and the absence of chitosan in spores suggested that the mutant dit101 could be defective in a chitin synthase. Indeed, a genomic yeast clone harboring the gene, CSD2, sharing significant sequence similarity with yeast chitin synthases I and II (C. E. Bulawa (1992), Mol. Cell. Biol. 12, 1764-1776), complemented our mutant and was shown to correspond to the chromosomal locus of dit101. Thus, the mutations dit101 and csd2 (and probably also call; M. H. Valdivieso et al., (1991), J. Cell Biol. 114, 101-109) were shown to be allelic. The gene was mapped to chromosome II and was located about 3 kb distal of GAL1. Using this DNA clone, a transcript of about 3500-4000 nucleotides was detected. Comparing RNA isolated from vegetative cells and from sporulating cells at different times throughout the sporulation process, no significant differences in DIT101 transcript levels could be detected indicating absence of sporulation-specific transcriptional regulation. However, the amount of DIT101 transcript changed significantly at different stages of the mitotic cell cycle, peaking after septum formation, but before cytokinesis. As most of the chitin synthesis of vegetative cells occurs at this stage of the cell division cycle, chitin synthesis mediated by DIT101 could be primarily regulated at the level of transcription in vegetatively growing cells.