Your search keyword '"Sabath, Niv"' showing total 6 results

1. Evolution of viral proteins originated de novo by overprinting.

Author

Sabath N, Wagner A, and Karlin D

Subjects

Computational Biology, Genetic Variation, Codon genetics, Evolution, Molecular, Genes, Overlapping genetics, Selection, Genetic, Viral Proteins genetics

Abstract

New protein-coding genes can originate either through modification of existing genes or de novo. Recently, the importance of de novo origination has been recognized in eukaryotes, although eukaryotic genes originated de novo are relatively rare and difficult to identify. In contrast, viruses contain many de novo genes, namely those in which an existing gene has been "overprinted" by a new open reading frame, a process that generates a new protein-coding gene overlapping the ancestral gene. We analyzed the evolution of 12 experimentally validated viral genes that originated de novo and estimated their relative ages. We found that young de novo genes have a different codon usage from the rest of the genome. They evolve rapidly and are under positive or weak purifying selection. Thus, young de novo genes might have strain-specific functions, or no function, and would be difficult to detect using current genome annotation methods that rely on the sequence signature of purifying selection. In contrast to young de novo genes, older de novo genes have a codon usage that is similar to the rest of the genome. They evolve slowly and are under stronger purifying selection. Some of the oldest de novo genes evolve under stronger selection pressure than the ancestral gene they overlap, suggesting an evolutionary tug of war between the ancestral and the de novo gene.

Published

2012

2. Neutral evolution of robustness in Drosophila microRNA precursors.

Author

Price N, Cartwright RA, Sabath N, Graur D, and Azevedo RB

Subjects

Algorithms, Animals, Computer Simulation, Mutation, Nucleic Acid Conformation, Phylogeny, Selection, Genetic, Statistics, Nonparametric, Drosophila genetics, Evolution, Molecular, MicroRNAs genetics, Penetrance

Abstract

Mutational robustness describes the extent to which a phenotype remains unchanged in the face of mutations. Theory predicts that the strength of direct selection for mutational robustness is at most the magnitude of the rate of deleterious mutation. As far as nucleic acid sequences are concerned, only long sequences in organisms with high deleterious mutation rates and large population sizes are expected to evolve mutational robustness. Surprisingly, recent studies have concluded that molecules that meet none of these conditions--the microRNA precursors (pre-miRNAs) of multicellular eukaryotes--show signs of selection for mutational and/or environmental robustness. To resolve the apparent disagreement between theory and these studies, we have reconstructed the evolutionary history of Drosophila pre-miRNAs and compared the robustness of each sequence to that of its reconstructed ancestor. In addition, we "replayed the tape" of pre-miRNA evolution via simulation under different evolutionary assumptions and compared these alternative histories with the actual one. We found that Drosophila pre-miRNAs have evolved under strong purifying selection against changes in secondary structure. Contrary to earlier claims, there is no evidence that these RNAs have been shaped by either direct or congruent selection for any kind of robustness. Instead, the high robustness of Drosophila pre-miRNAs appears to be mostly intrinsic and likely a consequence of selection for functional structures.

Published

2011

3. A method for the simultaneous estimation of selection intensities in overlapping genes.

Author

Sabath N, Landan G, and Graur D

Subjects

Animals, Influenza A virus genetics, Models, Genetic, Evolution, Molecular, Genes, Overlapping, Genetic Techniques, Selection, Genetic

Abstract

Inferring the intensity of positive selection in protein-coding genes is important since it is used to shed light on the process of adaptation. Recently, it has been reported that overlapping genes, which are ubiquitous in all domains of life, seem to exhibit inordinate degrees of positive selection. Here, we present a new method for the simultaneous estimation of selection intensities in overlapping genes. We show that the appearance of positive selection is caused by assuming that selection operates independently on each gene in an overlapping pair, thereby ignoring the unique evolutionary constraints on overlapping coding regions. Our method uses an exact evolutionary model, thereby voiding the need for approximation or intensive computation. We test the method by simulating the evolution of overlapping genes of different types as well as under diverse evolutionary scenarios. Our results indicate that the independent estimation approach leads to the false appearance of positive selection even though the gene is in reality subject to negative selection. Finally, we use our method to estimate selection in two influenza A genes for which positive selection was previously inferred. We find no evidence for positive selection in both cases.

Published

2008

4. The "inverse relationship between evolutionary rate and age of mammalian genes" is an artifact of increased genetic distance with rate of evolution and time of divergence.

Author

Elhaik E, Sabath N, and Graur D

Subjects

Animals, Computer Simulation, Time Factors, Evolution, Molecular, Genes genetics, Mammals genetics, Models, Genetic, Phylogeny

Abstract

It has recently been claimed that older genes tend to evolve more slowly than newer ones (Alba and Castresana 2005). By simulation of genes of equal age, we show that the inverse correlation between age and rate is an artifact caused by our inability to detect homology when evolutionary distances are large. Since evolutionary distance increases with time of divergence and rate of evolution, homologs of fast-evolving genes are frequently undetected in distantly related taxa and are, hence, misclassified as "new." This misclassification causes the mean genetic distance of 'new' genes to be overestimated and the mean genetic distance of "old" genes to be underestimated.

Published

2006

5. Evolution of Viral Proteins Originated De Novo by Overprinting

Author

Andreas Wagner, David Karlin, Niv Sabath, University of Zurich, and Sabath, Niv

Subjects

Biology, Genome, Evolution, Molecular, 03 medical and health sciences, Negative selection, 10127 Institute of Evolutionary Biology and Environmental Studies, Viral Proteins, 1311 Genetics, Genetic variation, Genetics, 1312 Molecular Biology, Genes, Overlapping, Selection, Genetic, Codon, Molecular Biology, Gene, Ecology, Evolution, Behavior and Systematics, Research Articles, 030304 developmental biology, 0303 health sciences, 030302 biochemistry & molecular biology, Computational Biology, Genetic Variation, Genome project, Open reading frame, 1105 Ecology, Evolution, Behavior and Systematics, Codon usage bias, overlapping genes, 570 Life sciences, biology, 590 Animals (Zoology), de novo origin, new genes, Function (biology)

Abstract

New protein-coding genes can originate either through modification of existing genes or de novo. Recently, the importance of de novo origination has been recognized in eukaryotes, although eukaryotic genes originated de novo are relatively rare and difficult to identify. In contrast, viruses contain many de novo genes, namely those in which an existing gene has been “overprinted” by a new open reading frame, a process that generates a new protein-coding gene overlapping the ancestral gene. We analyzed the evolution of 12 experimentally validated viral genes that originated de novo and estimated their relative ages. We found that young de novo genes have a different codon usage from the rest of the genome. They evolve rapidly and are under positive or weak purifying selection. Thus, young de novo genes might have strain-specific functions, or no function, and would be difficult to detect using current genome annotation methods that rely on the sequence signature of purifying selection. In contrast to young de novo genes, older de novo genes have a codon usage that is similar to the rest of the genome. They evolve slowly and are under stronger purifying selection. Some of the oldest de novo genes evolve under stronger selection pressure than the ancestral gene they overlap, suggesting an evolutionary tug of war between the ancestral and the de novo gene.

Published

2012

6. Growth temperature and genome size in bacteria are negatively correlated, suggesting genomic streamlining during thermal adaptation

Author

Aditya Barve, Niv Sabath, Andreas Wagner, Evandro Ferrada, University of Zurich, and Sabath, Niv

Subjects

Genome evolution, Hot Temperature, thermophilic bacteria, Bacterial genome size, Biology, genome evolution, Genome, Evolution, Molecular, 03 medical and health sciences, 10127 Institute of Evolutionary Biology and Environmental Studies, 1311 Genetics, Genome Size, Genome, Archaeal, Genetics, Selection, Genetic, Genome size, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Natural selection, Bacteria, 030306 microbiology, Adaptation, Physiological, Archaea, streamlining, genomic DNA, Highlights, 1105 Ecology, Evolution, Behavior and Systematics, Prokaryotic Cells, 570 Life sciences, biology, 590 Animals (Zoology), Adaptation, Neutral theory of molecular evolution, Genome, Bacterial, Research Article

Abstract

Prokaryotic genomes are small and compact. Either this feature is caused by neutral evolution or by natural selection favoring small genomes-genome streamlining. Three separate prior lines of evidence argue against streamlining for most prokaryotes. We find that the same three lines of evidence argue for streamlining in the genomes of thermophile bacteria. Specifically, with increasing habitat temperature and decreasing genome size, the proportion of genomic DNA in intergenic regions decreases. Furthermore, with increasing habitat temperature, generation time decreases. Genome-wide selective constraints do not decrease as in the reduced genomes of host-associated species. Reduced habitat variability is not a likely explanation for the smaller genomes of thermophiles. Genome size may be an indirect target of selection due to its association with cell volume. We use metabolic modeling to demonstrate that known changes in cell structure and physiology at high temperature can provide a selective advantage to reduce cell volume at high temperatures.

Published

2013