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Full-Text Articles in Life Sciences
Escherichia Coli Itat Is A Type Ii Toxin That Inhibits Translation By Acetylating Isoleucyl-Trnaile, Brendan Wilcox, Ilya Osterman, Marina Serebryakova, Dmitry Lukyanov, Ekaterina Komarova, Bridget Gollan, Natalia Morozova, Yuri I Wolf, Kira S Makarova, Sophie Helaine, Petr Sergiev, Svetlana Dubiley, Sergei Borukhov, Konstantin Severinov
Escherichia Coli Itat Is A Type Ii Toxin That Inhibits Translation By Acetylating Isoleucyl-Trnaile, Brendan Wilcox, Ilya Osterman, Marina Serebryakova, Dmitry Lukyanov, Ekaterina Komarova, Bridget Gollan, Natalia Morozova, Yuri I Wolf, Kira S Makarova, Sophie Helaine, Petr Sergiev, Svetlana Dubiley, Sergei Borukhov, Konstantin Severinov
Rowan-Virtua School of Osteopathic Medicine Faculty Scholarship
Prokaryotic toxin-antitoxin (TA) modules are highly abundant and are involved in stress response and drug tolerance. The most common type II TA modules consist of two interacting proteins. The type II toxins are diverse enzymes targeting various essential intracellular targets. The antitoxin binds to cognate toxin and inhibits its function. Recently, TA modules whose toxins are GNAT-family acetyltransferases were described. For two such systems, the target of acetylation was shown to be aminoacyl-tRNA: the TacT toxin targets aminoacylated elongator tRNAs, while AtaT targets the amino acid moiety of initiating tRNAMet. We show that the itaRT gene pair from Escherichia coli …
Monitoring Expression Of Metabolic Genes During The Hypoxic Response Of S. Cerevisae, Nikkoli Lueder
Monitoring Expression Of Metabolic Genes During The Hypoxic Response Of S. Cerevisae, Nikkoli Lueder
Theses and Dissertations
All organisms appear to have the ability to sense and respond to changes in their environment. Hypoxia, or low oxygen, is experienced by many organisms at some point in their life cycle. Some organisms such as S. cerevisiae, a species of yeast, respond by dramatically altering gene expression. The result is that genes needed in the new environment are turned on and unneeded genes are turned off. S. cerevisiae has been used in our study because it shares many genes with other eukaryotes, including humans, so many of our findings are applicable to these organisms. Here, we tried to understand …