uvsZ1 mutation shows epistatic relations with uvsD153 and uvsJ1 mutations without any involvement with checkpoint control in Aspergillus nidulans

The participation of the recently described uvsZ1 mutation in checkpoint control and the identification of epistatic relations between uvsZ1 mutation and uvsD153 and uvsJ1 mutations are provided. The effect of mutation uvsZ1 in mitotic exchanges into paba-bi (chromosome I) and cho-nic (chromosome VII) genetic intervals has also been evaluated. The mutation uvsZ1 was epistatic with regard to uvsD153 and uvsJ1 mutations, with no involvement with checkpoint control. In contrast to mutations in UvsB and UvsF groups, the uvsZ1 mutation failed to cause any changes in the frequencies of mitotic crossing-over. The distinct phenotypic traits given by mutation uvsZ1 suggest the presence of complex interactions among the different DNA repair pathways. Interaction may be an additional cell strategy of DNA damage respons

Genotoxic evaluation of sodium nitroprusside in Aspergillus nidulans

The exogenous nitric oxide donor, sodium nitroprusside, evaluated the recombinogenic potential of nitric oxide. Drug inhibited mycelial growth and conidiation in A757 Aspergillus nidulans master strain. Two heterozygous diploid strains, one wild (uvsH+//uvsH+) and the other defective to DNA repair (uvsH//uvsH) were used for recombinagenesis tests. Sodium nitroprusside recombinogenic effect was evaluated by the induction of homozygosis of recessive genes, originally present in heterozygous condition. Results show that sodium nitroprusside (40 muM, 80 muM and 160 muM) is effective in inducing mitotic crossing-over in diploid cells of A. nidulans

Characterization and mapping of an informational suppressor in Aspergillus nidulans

The present work was undertaken to characterize a suppressor gene present in a mutant strain of A. nidulans obtained with NTG (N-Methyl-N'-Nitro-N-Nitrosoguanidine). Analyses of this mutant have shown that this suppressor, designated suO1, induces phenotypic co-reversion of several auxotrophic mutations and makes the strain sensitive to aminoglycoside antibiotics and lower temperatures. suO1 has shown to be on linkage group VIII. The vegetative growth of the mutant strain is very unstable because the suppressor gene induces the production of prototrophic mitotic sectors. The strains bearing the suO1 gene produce cleistothecia containing a reduced number of viable ascospores during the sexual cycle. The segregation of the genetic markers has also been observed in the mutant strain self crossed. From the above results it may be concluded that suO1 is an informational suppresso

Genetic and cytological characterization of a developmental mutant of Aspergillus nidulans induced by 5-azacytidine

An analysis of a new medusa mutant of Aspergillus nidulans obtained by 5-azacytidine-treatment and named B116 is provided. The B116 mutant was phenotypically characterized by the production of conidiophores with reduced pigmentation and vesicles bearing multiple tiers of sterigmata. A single nuclear gene located on chromosome I is responsible for phenotypical changes in the mutant. The 5-azacytidine-altered locus, designated medA102, is recessive in heterozygous diploid and the medusa mutant is a Dp(II,I) duplication bearer that renders the strain mitotically unstable

<b>Segregação mitótica induzida pelo edulcorante L-Aspartil-L-Fenilalanina-Metil-Ester (aspartame) em células diplóides de <em>Aspergillus nidulans</em></b> - DOI: 10.4025/actascibiolsci.v25i1.2121 <b>Mitotic segregation induced by edulcorant l-aspartyl-l-phenylalanine-metyl-ester (aspartame) in diploid cells of <em>Aspergillus nidulans</em></b> - DOI: 10.4025/actascibiolsci.v25i1.2121

O presente trabalho demonstra o efeito recombinagênico do edulcorante artificial L-Aspartil-L-Fenilalanina-Metil-Ester (aspartame), amplamente utilizado em dietas hipocalóricas e de baixo consumo de glicose. Este efeito pode refletir respostas celulares a danos genéticos induzidos pelo edulcorante artificial, no período G2 do ciclo celular e demonstra sua capacidade de induzir homozigose de genes recessivos previamente presentes em heterozigose<br>This study aims to verify the recombinogenic effect of artificial edulcorant l-aspartil-l-phenylalanine-metyl-ester (aspartame), widely used in hypocaloric and low-glucose diets. Such effect may reflect cell response to genetic damage, induced by artificial edulcorant in the cell cycle G2 period and shows its capacity to induce homozygosis of recessive genes, previously present in heterozygosi