ENVIRONMENTAL STRESS AND MUTAGENESIS IN ENTERIC AND NON-ENTERIC BACTERIA

Mutations are fundamental for evolution. For many years it has been thought that mutagenesis occurs only in dividing cells. Now it is clear that mutations arise in non-dividing or slowly dividing microorganisms. Natural populations spend most of the time in stressful environments where their growth rate is highly reduced. Thus, the existence of a mutagenesis process, independent of multiplication (stress-induced mutagenesis, SIM), might have a profound evolutionary role. In the presented paper we review the stateof-the-art in enteric and non-enteric bacteria. We describe different experimental systems as well as the mechanisms and models presented to explain the huge amount of data obtained in more than twenty years of research

The exceptionally high rate of spontaneous mutations in the polymerase delta proofreading exonuclease-deficient Saccharomyces cerevisiae strain starved for adenine

BACKGROUND: Mutagenesis induced in the yeast Saccharomyces cerevisiae by starvation for nutrilites is a well-documented phenomenon of an unknown mechanism. We have previously shown that the polymerase delta proofreading activity controls spontaneous mutagenesis in cells starved for histidine. To obtain further information, we compared the effect of adenine starvation on mutagenesis in wild-type cells and, in cells lacking the proofreading activity of polymerase delta (phenotype Exo(-), mutation pol3-01). RESULTS: Ade(+ )revertants accumulated at a very high rate on adenine-free plates so that their frequency on day 16 after plating was 1.5 × 10(-4 )for wild-type and 1.0 × 10(-2 )for the Exo(- )strain. In the Exo(- )strain, all revertants arising under adenine starvation are suppressors of the original mutation, most possessed additional nutritional requirements, and 50% of them were temperature sensitive. CONCLUSIONS: Adenine starvation is highly mutagenic in yeast. The deficiency in the polymerase delta proofreading activity in strains with the pol3-01 mutation leads to a further 66-fold increase of the rate of mutations. Our data suggest that adenine starvation induces genome-wide hyper-mutagenesis in the Exo(- )strain

The initial peopling of the Americas: a growing number of founding mitochondrial genomes from Beringia

Pan-American mitochondrial DNA (mtDNA) haplogroup C1 has been recently subdivided into three branches, two of which (C1b and C1c) are characterized by ages and geographical distributions that are indicative of an early arrival from Beringia with Paleo-Indians. In contrast, the estimated ages of C1d—the third subset of C1—looked too young to fit the above scenario. To define the origin of this enigmatic C1 branch, we completely sequenced 63 C1d mitochondrial genomes from a wide range of geographically diverse, mixed, and indigenous American populations. The revised phylogeny not only brings the age of C1d within the range of that of its two sister clades, but reveals that there were two C1d founder genomes for Paleo-Indians. Thus, the recognized maternal founding lineages of Native Americans are at least 15, indicating that the overall number of Beringian or Asian founder mitochondrial genomes will probably increase extensively when all Native American haplogroups reach the same level of phylogenetic and genomic resolution as obtained here for C1d.Fil: Perego, Ugo A.. Soreson Molecular Genealogy Foundation; Estados Unidos. Università di Pavia. Dipartimento di Genetica e Microbiologia; ItaliaFil: Angerhofer, Norman. Soreson Molecular Genealogy Foundation; Estados UnidosFil: Pala, Maria. Università di Pavia. Dipartimento di Genetica e Microbiologia; ItaliaFil: Olivieri, Anna. Università di Pavia. Dipartimento di Genetica e Microbiologia; ItaliaFil: Lancioni, Hovirag. Universita Di Perugia; ItaliaFil: Kashani, Baharak Hooshiar. Università di Pavia. Dipartimento di Genetica e Microbiologia; ItaliaFil: Carossa, Valeria. Università di Pavia. Dipartimento di Genetica e Microbiologia; ItaliaFil: Ekins, Jayne E.. Soreson Molecular Genealogy Foundation; Estados UnidosFil: Gómez Carballa, Alberto. Universidad de Santiago de Compostela; EspañaFil: Huber, Gabriela. Universidad de Innsbruck; AustriaFil: Zimmermann, Bettina. Universidad de Innsbruck; AustriaFil: Corach, Daniel. Universidad de Buenos Aires. Facultad de Farmacia y Bioquímica. Servicio de Huellas Digitales Genéticas; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; ArgentinaFil: Babudri, Nora. Universita Di Perugia; ItaliaFil: Panara, Fausto. Universita Di Perugia; ItaliaFil: Myres, Natalie M.. Soreson Molecular Genealogy Foundation; Estados UnidosFil: Parson, Walther. Universidad de Innsbruck; AustriaFil: Semino, Ornella. Università di Pavia. Dipartimento di Genetica e Microbiologia; ItaliaFil: Salas, Antonio. Universidad de Santiago de Compostela; EspañaFil: Woodward, Scott R.. Soreson Molecular Genealogy Foundation; Estados UnidosFil: Achilli, Alessandro. Università di Pavia. Dipartimento di Genetica e Microbiologia; Italia. Universita Di Perugia; ItaliaFil: Torroni, Antonio. Università di Pavia. Dipartimento di Genetica e Microbiologia; Itali

ADAPTIVE MUTAGENESIS IN THE YEAST SACCHAROMYCES CEREVISIAE

The nature of mutation in microorganisms has been debated for a long time. Two theories have been at odds: random spontaneous mutagenesis vs. adaptive mutagenesis. "random mutagenesis" means that mutations occur in proliferating cells before they encountered the selective agent. "adaptive mutagenesis" means that advantageous mutations form in the environment where they have been selected, in non-replicating or poorly replicating cells even though other, non-selected, mutations occur at the same time. In the last 20 years it has been definitely shown that random as well as adaptive mutagenesis occur in bacteria and yeast. microorganisms in nature do not divide or divide poorly because of adverse environmental conditions; therefore adaptive mutations could provide cells with a selective advantage and allow evolution of populations. Here we will focus on some fundamental aspects of adaptive mutagenesis in the yeast Saccharomyces cerevisiae. We begin with a historical overview on the nature of mutation. We then focus on experimental systems aimed at proving or disproving adaptive mutagenesis. We have briefly summarized the results obtained in this field, with particular attention to genetic and molecular mechanisms

ADAPTIVE MUTAGENESIS IN THE YEAST SACCHAROMYCES CEREVISIAE

The nature of mutation in microorganisms has been debated for a long time. Two theories have been at odds: random spontaneous mutagenesis vs. adaptive mutagenesis. "random mutagenesis" means that mutations occur in proliferating cells before they encountered the selective agent. "adaptive mutagenesis" means that advantageous mutations form in the environment where they have been selected, in non-replicating or poorly replicating cells even though other, non-selected, mutations occur at the same time. In the last 20 years it has been definitely shown that random as well as adaptive mutagenesis occur in bacteria and yeast. microorganisms in nature do not divide or divide poorly because of adverse environmental conditions; therefore adaptive mutations could provide cells with a selective advantage and allow evolution of populations. Here we will focus on some fundamental aspects of adaptive mutagenesis in the yeast Saccharomyces cerevisiae. We begin with a historical overview on the nature of mutation. We then focus on experimental systems aimed at proving or disproving adaptive mutagenesis. We have briefly summarized the results obtained in this field, with particular attention to genetic and molecular mechanisms

High rate of starvation-associated mutagenesis in Ung-yeast caused by the overproduction of human activation-induced deaminase

We examined the role of Saccharomyces cerevisiae uracil DNA glycosylase in the suppression of mutagenesis in non-dividing, adenine-starved cells expressing human activation-induced deaminase (AID) gene. Our aim was to further understand the mechanisms preventing starvation-associated mutagenesis in yeast and to explore the consequences of AID gene expression in non-proliferating eukaryotic cells. Genetic control of starvation-induced mutagenesis in many aspects is similar to the control of spontaneous logarithmic phase mutagenesis. Low DNA polymerase fidelity, defects of mismatch repair or post-replication repair lead to the elevation of mutagenesis. Less is known about the role of uracil in DNA. In yeast, the UNG1 gene codes for a uracil DNA glycosylase, which removes uracil from DNA, thus preventing an accumulation of mutations. The UNG1 gene is constitutively expressed at low levels throughout the cell cycle and peaks in late G1/early S phase. We have shown that the wild-type UNG1 allele protects from AID-induced mutations in starved cells to the same extent as it does in logarithmic growth phase cells. This finding implies that the first step in uracil removal by base excision repair (BER) is similar in these two conditions and provides the first data for understanding the role of BER in starvation-associated mutagenesis