Turdoides affinis mitogenome reveals the translational efficiency and importance of NADH dehydrogenase complex-I in the Leiothrichidae family

Abstract Mitochondrial genome provides useful information about species concerning its evolution and phylogenetics. We have taken the advantage of high throughput next-generation sequencing technique to sequence the complete mitogenome of Yellow-billed babbler (Turdoides affinis), a species endemic to Peninsular India and Sri Lanka. Both, reference-based and de-novo assemblies of mitogenome were performed and observed that de-novo assembled mitogenome was most appropriate. The complete mitogenome of yellow-billed babbler (assembled de-novo) was 17,672 bp in length with 53.2% AT composition. Thirteen protein-coding genes along with two rRNAs and 22 tRNAs were detected. The arrangement pattern of these genes was found conserved among Leiothrichidae family mitogenomes. Duplicated control regions were found in the newly sequenced mitogenome. Downstream bioinformatics analysis revealed the effect of translational efficiency and purifying selection pressure over thirteen protein-coding genes in yellow-billed babbler mitogenome. Ka/Ks analysis indicated the highest synonymous substitution rate in the nad6 gene. Evolutionary analysis revealed the conserved nature of all the protein-coding genes across Leiothrichidae family mitogenomes. Our limited phylogeny results placed T. affinis in a separate group, a sister group of Garrulax. Overall, our results provide a useful information for future studies on the evolutionary and adaptive mechanisms of birds belong to the Leiothrichidae family.

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Comprehensive bioinformatic analysis of newly sequenced Turdoides affinis mitogenome reveals the persistence of translational efficiency and dominance of NADH dehydrogenase complex-I in electron transport system over Leiothrichidae family

10.1101/2020.01.23.917716 ◽

2020 ◽

Author(s):

Indrani Sarkar ◽

Prateek Dey ◽

Sanjeev Kumar Sharma ◽

Swapna Devi Ray ◽

Ram Pratap Singh

Keyword(s):

Electron Transport ◽

Transport System ◽

Complex I ◽

Nadh Dehydrogenase ◽

De Novo ◽

Translational Efficiency ◽

Protein Coding ◽

Protein Coding Genes ◽

Complete Mitogenome ◽

Dehydrogenase Complex

AbstractMitochondrial genome provides useful information about species with respect to its evolution and phylogenetics. We have taken the advantage of high throughput next-generation sequencing technique to sequence the complete mitogenome of Yellow-billed babbler (Turdoides affinis), a species endemic to Peninsular India and Sri Lanka. Both, reference-based and de-novo assemblies of mitogenome were performed and observed that de-novo assembled mitogenome was most appropriate. The complete mitogenome of yellow-billed babbler (assembled de-novo) was 17,671 bp in length with 53.2% AT composition. Thirteen protein-coding genes along with 2 rRNAs and 22 tRNAs were detected along with duplicated control regions. The arrangement pattern of these genes was found conserved among Leiothrichidae family mitogenomes. Downstream bioinformatics analysis revealed the effect of translational efficiency and purifying selection pressure over all the thirteen protein-coding genes in yellow-billed babbler mitogenome. Moreover, genetic distance and variation analysis indicated the dominance of NADH dehydrogenase complex-I in the electron transport system of T. affinis. Evolutionary analysis revealed the conserved nature of all the protein-coding genes across Leiothrichidae family mitogenomes. Our limited phylogenetics results suggest that T. affinis is closer to Garrulax.

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Ab Initio Construction and Evolutionary Analysis of Protein-Coding Gene Families with Partially Homologous Relationships: Closely Related Drosophila Genomes as a Case Study

Genome Biology and Evolution ◽

10.1093/gbe/evaa041 ◽

2020 ◽

Vol 12 (3) ◽

pp. 185-202

Author(s):

Xia Han ◽

Jindan Guo ◽

Erli Pang ◽

Hongtao Song ◽

Kui Lin

Keyword(s):

Gene Family ◽

De Novo ◽

Gene Families ◽

Gene Family Evolution ◽

Evolutionary Analysis ◽

Protein Coding ◽

Protein Coding Genes ◽

Genome Phylogeny ◽

Partial Homology

Abstract How have genes evolved within a well-known genome phylogeny? Many protein-coding genes should have evolved as a whole at the gene level, and some should have evolved partly through fragments at the subgene level. To comprehensively explore such complex homologous relationships and better understand gene family evolution, here, with de novo-identified modules, the subgene units which could consecutively cover proteins within a set of closely related species, we applied a new phylogeny-based approach that considers evolutionary models with partial homology to classify all protein-coding genes in nine Drosophila genomes. Compared with two other popular methods for gene family construction, our approach improved practical gene family classifications with a more reasonable view of homology and provided a much more complete landscape of gene family evolution at the gene and subgene levels. In the case study, we found that most expanded gene families might have evolved mainly through module rearrangements rather than gene duplications and mainly generated single-module genes through partial gene duplication, suggesting that there might be pervasive subgene rearrangement in the evolution of protein-coding gene families. The use of a phylogeny-based approach with partial homology to classify and analyze protein-coding gene families may provide us with a more comprehensive landscape depicting how genes evolve within a well-known genome phylogeny.

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Extreme purifying selection against point mutations in the human genome

10.1101/2021.08.23.457339 ◽

2021 ◽

Author(s):

Noah Dukler ◽

Mehreen R Mughal ◽

Ritika Ramani ◽

Yi-Fei Huang ◽

Adam Siepel

Keyword(s):

Human Genome ◽

De Novo ◽

Point Mutations ◽

Purifying Selection ◽

Selection Coefficient ◽

Sequencing Data ◽

Protein Coding ◽

Coding Regions ◽

Protein Coding Genes ◽

Selective Effects

Genome sequencing of tens of thousands of human individuals has recently enabled the measurement of large selective effects for mutations to protein-coding genes. Here we describe a new method, called ExtRaINSIGHT, for measuring similar selective effects at individual sites in noncoding as well as in coding regions of the human genome. ExtRaINSIGHT estimates the prevalance of strong purifying selection, or "ultraselection" (λs), as the fractional depletion of rare single-nucleotide variants (minor allele frequency <0.1%) in a target set of genomic sites relative to matched sites that are putatively neutrally evolving, in a manner that controls for local variation and neighbor-dependence in mutation rate. We show using simulations that, above an appropriate threshold, λs is closely related to the average site-specific selection coefficient against heterozygous point mutations, as predicted at mutation-selection balance. Applying ExtRaINSIGHT to 71,702 whole genome sequences from gnomAD v3, we find particularly strong evidence of ultraselection in evolutionarily ancient miRNAs and neuronal protein-coding genes, as well as at splice sites. Moreover, our estimated selection coefficient against heterozygous amino-acid replacements across the genome (at 1.4%) is substantially larger than previous estimates based on smaller sample sizes. By contrast, we find weak evidence of ultraselection in other noncoding RNAs and transcription factor binding sites, and only modest evidence in ultraconserved elements and human accelerated regions. We estimate that ~0.3-0.5% of the human genome is ultraselected, with one third to one half of ultraselected sites falling in coding regions. These estimates suggest ~0.3-0.4 lethal or nearly lethal de novo mutations per potential human zygote, together with ~2 de novo mutations that are more weakly deleterious. Overall, our study sheds new light on the genome-wide distribution of fitness effects for new point mutations by combining deep new sequencing data sets and classical theory from population genetics.

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Theory of prokaryotic genome evolution

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1614083113 ◽

2016 ◽

Vol 113 (41) ◽

pp. 11399-11407 ◽

Cited By ~ 62

Author(s):

Itamar Sela ◽

Yuri I. Wolf ◽

Eugene V. Koonin

Keyword(s):

Genome Size ◽

Prokaryotic Genome ◽

Genetic Material ◽

Purifying Selection ◽

Synonymous Substitution ◽

Protein Coding ◽

Protein Coding Genes ◽

New Genes ◽

Extra Energy ◽

Prokaryotic Genomes

Bacteria and archaea typically possess small genomes that are tightly packed with protein-coding genes. The compactness of prokaryotic genomes is commonly perceived as evidence of adaptive genome streamlining caused by strong purifying selection in large microbial populations. In such populations, even the small cost incurred by nonfunctional DNA because of extra energy and time expenditure is thought to be sufficient for this extra genetic material to be eliminated by selection. However, contrary to the predictions of this model, there exists a consistent, positive correlation between the strength of selection at the protein sequence level, measured as the ratio of nonsynonymous to synonymous substitution rates, and microbial genome size. Here, by fitting the genome size distributions in multiple groups of prokaryotes to predictions of mathematical models of population evolution, we show that only models in which acquisition of additional genes is, on average, slightly beneficial yield a good fit to genomic data. These results suggest that the number of genes in prokaryotic genomes reflects the equilibrium between the benefit of additional genes that diminishes as the genome grows and deletion bias (i.e., the rate of deletion of genetic material being slightly greater than the rate of acquisition). Thus, new genes acquired by microbial genomes, on average, appear to be adaptive. The tight spacing of protein-coding genes likely results from a combination of the deletion bias and purifying selection that efficiently eliminates nonfunctional, noncoding sequences.

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Contribution of Retrotransposition to Developmental Disorders

10.1101/471375 ◽

2018 ◽

Cited By ~ 2

Author(s):

Eugene J. Gardner ◽

Elena Prigmore ◽

Giuseppe Gallone ◽

Petr Danecek ◽

Kaitlin E. Samocha ◽

...

Keyword(s):

Developmental Disorders ◽

De Novo ◽

Purifying Selection ◽

Mobile Genetic Elements ◽

Protein Coding ◽

Protein Coding Genes ◽

Genome Wide ◽

The Impact ◽

Transcribed Sequences

AbstractMobile genetic Elements (MEs) are segments of DNA which, through an RNA intermediate, can generate new copies of themselves and other transcribed sequences through the process of retrotransposition (RT). In humans several disorders have been attributed to RT, but the role of RT in severe developmental disorders (DD) has not yet been explored. As such, we have identified RT-derived events in 9,738 exome sequenced trios with DD-affected probands as part of the Deciphering Developmental Disorders (DDD) study. We have ascertained 9 de novo MEs, 4 of which are likely causative of the patient’s symptoms (0.04% of probands), as well as 2 de novo gene retroduplications. Beyond identifying likely diagnostic RT events, we have estimated genome-wide germline ME mutagenesis and constraint and demonstrated that coding RT events have signatures of purifying selection equivalent to those of truncating mutations. Overall, our analysis represents a comprehensive interrogation of the impact of retrotransposition on protein coding genes and a framework for future evolutionary and disease studies.

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How do we transition from non-coding to coding?

10.7287/peerj.preprints.3031v1 ◽

2017 ◽

Author(s):

Jorge Ruiz-Orera ◽

José Luis Villanueva-Cañas ◽

William Blevins ◽

M.Mar Albà

Keyword(s):

De Novo ◽

Gene Evolution ◽

Purifying Selection ◽

Neutral Evolution ◽

Functional Protein ◽

Protein Coding ◽

Coding Sequences ◽

Sequence Composition ◽

Protein Coding Genes ◽

Small Proteins

Recent years have witnessed the discovery of protein–coding genes which appear to have evolved de novo from previously non-coding sequences. This has changed the long-standing view that coding sequences can only evolve from other coding sequences. However, there are still many open questions regarding how new protein-coding sequences can arise from non-genic DNA. Two prerequisites for the birth of a new functional protein-coding gene are that the corresponding DNA fragment is transcribed and that it is also translated. Transcription is known to be pervasive in the genome, producing a large number of transcripts that do not correspond to conserved protein-coding genes, and which are usually annotated as long non-coding RNAs (lncRNA). Recently, sequencing of ribosome protected fragments (Ribo-Seq) has provided evidence that many of these transcripts actually translate small proteins. We have used mouse non-synonymous and synonymous variation data to estimate the strength of purifying selection acting on the translated open reading frames (ORFs). Whereas a subset of the lncRNAs are likely to actually be true protein-coding genes (and thus previously misclassified), the bulk of lncRNAs code for proteins which show variation patterns consistent with neutral evolution. We also show that the ORFs that have a more favorable, coding-like, sequence composition are more likely to be translated than other ORFs in lncRNAs. This study provides strong evidence that there is a large and ever-changing reservoir of lowly abundant proteins; some of these peptides may become useful and act as seeds for de novo gene evolution.

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Analysis of Stop Codons within Prokaryotic Protein-Coding Genes Suggests Frequent Readthrough Events

International Journal of Molecular Sciences ◽

10.3390/ijms22041876 ◽

2021 ◽

Vol 22 (4) ◽

pp. 1876

Author(s):

Frida Belinky ◽

Ishan Ganguly ◽

Eugenia Poliakov ◽

Vyacheslav Yurchenko ◽

Igor B. Rogozin

Keyword(s):

Stop Codon ◽

Purifying Selection ◽

Protein Product ◽

Intermediate Step ◽

Protein Coding ◽

Stop Codons ◽

Protein Coding Genes ◽

Synonymous Sites ◽

Prokaryotic Protein ◽

Sense Codon

Nonsense mutations turn a coding (sense) codon into an in-frame stop codon that is assumed to result in a truncated protein product. Thus, nonsense substitutions are the hallmark of pseudogenes and are used to identify them. Here we show that in-frame stop codons within bacterial protein-coding genes are widespread. Their evolutionary conservation suggests that many of them are not pseudogenes, since they maintain dN/dS values (ratios of substitution rates at non-synonymous and synonymous sites) significantly lower than 1 (this is a signature of purifying selection in protein-coding regions). We also found that double substitutions in codons—where an intermediate step is a nonsense substitution—show a higher rate of evolution compared to null models, indicating that a stop codon was introduced and then changed back to sense via positive selection. This further supports the notion that nonsense substitutions in bacteria are relatively common and do not necessarily cause pseudogenization. In-frame stop codons may be an important mechanism of regulation: Such codons are likely to cause a substantial decrease of protein expression levels.

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From de novo to ‘de nono’: The majority of novel protein coding genes identified with phylostratigraphy are old genes or recent duplicates

Genome Biology and Evolution ◽

10.1093/gbe/evy231 ◽

2018 ◽

Cited By ~ 2

Author(s):

Claudio Casola

Keyword(s):

De Novo ◽

Protein Coding ◽

Protein Coding Genes ◽

Novel Protein

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Chromosome-level assembly of Drosophila bifasciata reveals important karyotypic transition of the X chromosome

10.1101/847558 ◽

2019 ◽

Author(s):

Ryan Bracewell ◽

Anita Tran ◽

Kamalakar Chatla ◽

Doris Bachtrog

Keyword(s):

X Chromosome ◽

Genome Assembly ◽

De Novo ◽

Pericentromeric Region ◽

Species Group ◽

Chromosome 15 ◽

Protein Coding ◽

Protein Coding Genes ◽

Long Read ◽

Chromosome Level

ABSTRACTThe Drosophila obscura species group is one of the most studied clades of Drosophila and harbors multiple distinct karyotypes. Here we present a de novo genome assembly and annotation of D. bifasciata, a species which represents an important subgroup for which no high-quality chromosome-level genome assembly currently exists. We combined long-read sequencing (Nanopore) and Hi-C scaffolding to achieve a highly contiguous genome assembly approximately 193Mb in size, with repetitive elements constituting 30.1% of the total length. Drosophila bifasciata harbors four large metacentric chromosomes and the small dot, and our assembly contains each chromosome in a single scaffold, including the highly repetitive pericentromere, which were largely composed of Jockey and Gypsy transposable elements. We annotated a total of 12,821 protein-coding genes and comparisons of synteny with D. athabasca orthologs show that the large metacentric pericentromeric regions of multiple chromosomes are conserved between these species. Importantly, Muller A (X chromosome) was found to be metacentric in D. bifasciata and the pericentromeric region appears homologous to the pericentromeric region of the fused Muller A-AD (XL and XR) of pseudoobscura/affinis subgroup species. Our finding suggests a metacentric ancestral X fused to a telocentric Muller D and created the large neo-X (Muller A-AD) chromosome ∼15 MYA. We also confirm the fusion of Muller C and D in D. bifasciata and show that it likely involved a centromere-centromere fusion.

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Draft genome assembly data of Anoxybacillus sp. strain MB8 isolated from Tattapani hot springs, India

10.1101/2021.06.09.447659 ◽

2021 ◽

Author(s):

VISHNU PRASOODANAN P K ◽

Shruti S. Menon ◽

Rituja Saxena ◽

Prashant Waiker ◽

Vineet K Sharma

Keyword(s):

Hot Springs ◽

De Novo ◽

Draft Genome ◽

Gc Content ◽

Central India ◽

Glycoside Hydrolases ◽

Rrna Gene ◽

Aerobic Bacterium ◽

Protein Coding ◽

Protein Coding Genes

Discovery of novel thermophiles has shown promising applications in the field of biotechnology. Due to their thermal stability, they can survive the harsh processes in the industries, which make them important to be characterized and studied. Members of Anoxybacillus are alkaline tolerant thermophiles and have been extensively isolated from manure, dairy-processed plants, and geothermal hot springs. This article reports the assembled data of an aerobic bacterium Anoxybacillus sp. strain MB8, isolated from the Tattapani hot springs in Central India, where the 16S rRNA gene shares an identity of 97% (99% coverage) with Anoxybacillus kamchatkensis strain G10. The de novo assembly and annotation performed on the genome of Anoxybacillus sp. strain MB8 comprises of 2,898,780 bp (in 190 contigs) with a GC content of 41.8% and includes 2,976 protein-coding genes,1 rRNA operon, 73 tRNAs, 1 tm-RNA and 10 CRISPR arrays. The predicted protein-coding genes have been classified into 21 eggNOG categories. The KEGG Automated Annotation Server (KAAS) analysis indicated the presence of assimilatory sulfate reduction pathway, nitrate reducing pathway, and genes for glycoside hydrolases (GHs) and glycoside transferase (GTs). GHs and GTs hold widespread applications, in the baking and food industry for bread manufacturing, and in the paper, detergent and cosmetic industry. Hence, Anoxybacillus sp. strain MB8 holds the potential to be screened and characterized for such commercially relevant enzymes.

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