Evolution of Gene Families Based on Gene Duplication, Loss, Accumulated Change, and Innovation

Summary: Phylogenetic trees are widely used to represent the evolution of gene families. As the history of gene families can be complex (including lots of gene duplications), its visualisation can become a difficult task. A good/accurate visualisation of phylogenetic trees - especially on the web - allows easier understanding and interpretation of trees to help to reveal the mechanisms that shape the evolution of a specific set of gene/species. Here, I present treeWidget, a modular BioJS component to visualise phylogenetic trees on the web. Through its modularity, treeWidget can be easily customized to allow the display of sequence information, e.g. protein domains and alignment conservation patterns.Availability: http://github.com/biojs/biojs; http://dx.doi.org/10.5281/zenodo.7707

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Evolution of Gene Families: A Clue to Some Problems of Neo-Darwinism

Lecture Notes in Biomathematics - Frontiers in Mathematical Biology ◽

10.1007/978-3-642-50124-1_10 ◽

1994 ◽

pp. 174-185

Author(s):

Tomoko Ohta

Keyword(s):

Gene Families ◽

Evolution Of Gene Families

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Promoter-mediated diversification of transcriptional bursting dynamics following gene duplication

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1800943115 ◽

2018 ◽

Vol 115 (33) ◽

pp. 8364-8369 ◽

Cited By ~ 17

Author(s):

Edward Tunnacliffe ◽

Adam M. Corrigan ◽

Jonathan R. Chubb

Keyword(s):

Gene Duplication ◽

Expression Profiles ◽

Single Cells ◽

Family Members ◽

Gene Families ◽

Developmental Expression ◽

Upstream Sequence ◽

Genomic Context ◽

Entire Family ◽

Transcriptional Bursting

During the evolution of gene families, functional diversification of proteins often follows gene duplication. However, many gene families expand while preserving protein sequence. Why do cells maintain multiple copies of the same gene? Here we have addressed this question for an actin family with 17 genes encoding an identical protein. The genes have divergent flanking regions and are scattered throughout the genome. Surprisingly, almost the entire family showed similar developmental expression profiles, with their expression also strongly coupled in single cells. Using live cell imaging, we show that differences in gene expression were apparent over shorter timescales, with family members displaying different transcriptional bursting dynamics. Strong “bursty” behaviors contrasted steady, more continuous activity, indicating different regulatory inputs to individual actin genes. To determine the sources of these different dynamic behaviors, we reciprocally exchanged the upstream regulatory regions of gene family members. This revealed that dynamic transcriptional behavior is directly instructed by upstream sequence, rather than features specific to genomic context. A residual minor contribution of genomic context modulates the gene OFF rate. Our data suggest promoter diversification following gene duplication could expand the range of stimuli that regulate the expression of essential genes. These observations contextualize the significance of transcriptional bursting.

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Ancient Genome Duplications Did Not Structure the Human Hox-Bearing Chromosomes

Genome Research ◽

10.1101/gr.160001 ◽

2001 ◽

Vol 11 (5) ◽

pp. 771-780 ◽

Cited By ~ 2

Author(s):

Austin L. Hughes ◽

Jack da Silva ◽

Robert Friedman

Keyword(s):

Phylogenetic Analysis ◽

Gene Duplication ◽

Genome Duplication ◽

Gene Families ◽

Gene Duplications ◽

Human Chromosomes ◽

Time Period ◽

Genome Duplications

The fact that there are four homeobox (Hox) clusters in most vertebrates but only one in invertebrates is often cited as evidence for the hypothesis that two rounds of genome duplication by polyploidization occurred early in vertebrate history. In addition, it has been observed in humans and other mammals that numerous gene families include paralogs on two or more of the fourHox-bearing chromosomes (the chromosomes bearing theHox clusters; i.e., human chromosomes 2, 7, 12, and 17), and the existence of these paralogs has been taken as evidence that these genes were duplicated along with the Hox clusters by polyploidization. We tested this hypothesis by phylogenetic analysis of 42 gene families including members on two or more of the humanHox-bearing chromosomes. In 32 of these families there was evidence against the hypothesis that gene duplication occurred simultaneously with duplication of the Hox clusters. Phylogenies of 14 families supported the occurrence of one or more gene duplications before the origin of vertebrates, and of 15 gene duplication times estimated for gene families evolving in a clock-like manner, only six were dated to the same time period early in vertebrate history during which the Hox clusters duplicated. Furthermore, of gene families duplicated around the same time as the Hoxclusters, the majority showed topologies inconsistent with their having duplicated simultaneously with the Hox clusters. The results thus indicate that ancient events of genome duplication, if they occurred at all, did not play an important role in structuring the mammalian Hox-bearing chromosomes.

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Recurrent Sequence Evolution After Independent Gene Duplication

10.21203/rs.2.22450/v4 ◽

2020 ◽

Author(s):

Samuel Hermann Alexander Von Der Dunk ◽

Berend Snel

Keyword(s):

Gene Duplication ◽

Experimental Testing ◽

Parallel Evolution ◽

Gene Families ◽

Functional Differentiation ◽

Functional Change ◽

Neutral Evolution ◽

Sequence Evolution ◽

Recurrent Sequence ◽

Independent Gene

Abstract Background Convergent and parallel evolution provide unique insights into the mechanisms of natural selection. Some of the most striking convergent and parallel (collectively recurrent ) amino acid substitutions in proteins are adaptive, but there are also many that are selectively neutral. Accordingly, genome-wide assessment has shown that recurrent sequence evolution in orthologs is chiefly explained by nearly neutral evolution. For paralogs, more frequent functional change is expected because additional copies are generally not retained if they do not acquire their own niche. Yet, it is unknown to what extent recurrent sequence differentiation is discernible after independent gene duplications in different eukaryotic taxa. Results We develop a framework that detects patterns of recurrent sequence evolution in duplicated genes. This is used to analyze the genomes of 90 diverse eukaryotes. We find a remarkable number of families with a potentially predictable functional differentiation following gene duplication. In some protein families, more than ten independent duplications show a similar sequence-level differentiation between paralogs. Based on further analysis, the sequence divergence is found to be generally asymmetric. Moreover, about 6\% of the recurrent sequence evolution between paralog pairs can be attributed to recurrent differentiation of subcellular localization. Finally, we reveal the specific recurrent patterns for the gene families Hint1/Hint2, Sco1/Sco2 and vma11/vma3. Conclusions The presented methodology provides a means to study the biochemical underpinning of functional differentiation between paralogs. For instance, two abundantly repeated substitutions are identified between independently derived Sco1 and Sco2 paralogs. Such identified substitutions allow direct experimental testing of the biological role of these residues for the repeated functional differentiation. We also uncover a diverse set of families with recurrent sequence evolution and reveal trends in the functional and evolutionary trajectories of this hitherto understudied phenomenon.

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GeneSeqToFamily: the Ensembl Compara GeneTrees pipeline as a Galaxy workflow

10.1101/096529 ◽

2016 ◽

Author(s):

Anil S. Thanki ◽

Nicola Soranzo ◽

Wilfried Haerty ◽

Robert P. Davey

Keyword(s):

Gene Duplication ◽

Structural Changes ◽

Gene Families ◽

Vital Role ◽

Software Project ◽

Command Line ◽

Gene Trees ◽

Ancestral Gene ◽

The Galaxy ◽

Duplication Events

AbstractBackgroundGene duplication is a major factor contributing to evolutionary novelty, and the contraction or expansion of gene families has often been associated with morphological, physiological and environmental adaptations. The study of homologous genes helps us to understand the evolution of gene families. It plays a vital role in finding ancestral gene duplication events as well as identifying genes that have diverged from a common ancestor under positive selection. There are various tools available, such as MSOAR, OrthoMCL and HomoloGene, to identify gene families and visualise syntenic information between species, providing an overview of syntenic regions evolution at the family level. Unfortunately, none of them provide information about structural changes within genes, such as the conservation of ancestral exon boundaries amongst multiple genomes. The Ensembl GeneTrees computational pipeline generates gene trees based on coding sequences and provides details about exon conservation, and is used in the Ensembl Compara project to discover gene families.FindingsA certain amount of expertise is required to configure and run the Ensembl Compara GeneTrees pipeline via command line. Therefore, we have converted the command line Ensembl Compara GeneTrees pipeline into a Galaxy workflow, called GeneSeqToFamily, and provided additional functionality. This workflow uses existing tools from the Galaxy ToolShed, as well as providing additional wrappers and tools that are required to run the workflow.ConclusionsGeneSeqToFamily represents the Ensembl Compara pipeline as a set of interconnected Galaxy tools, so they can be run interactively within the Galaxy’s user-friendly workflow environment while still providing the flexibility to tailor the analysis by changing configurations and tools if necessary. Additional tools allow users to subsequently visualise the gene families produced by the workflow, using the Aequatus.js interactive tool, which has been developed as part of the Aequatus software project.

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Characterizing Gene Copy Number of Heat Shock Protein Gene Families in the Emerald Rockcod, Trematomus bernacchii

Genes ◽

10.3390/genes11080867 ◽

2020 ◽

Vol 11 (8) ◽

pp. 867

Author(s):

Anthony D. Tercero ◽

Sean P. Place

Keyword(s):

Heat Shock ◽

Gene Duplication ◽

Heat Shock Proteins ◽

Heat Shock Response ◽

Copy Number ◽

Gene Families ◽

Gene Copy ◽

Shock Response ◽

Trematomus Bernacchii ◽

Shock Proteins

The suborder Notothenioidae is comprised of Antarctic fishes, several of which have lost their ability to rapidly upregulate heat shock proteins in response to thermal stress, instead adopting a pattern of expression resembling constitutive genes. Given the cold-denaturing effect that sub-zero waters have on proteins, evolution in the Southern Ocean has likely selected for increased expression of molecular chaperones. These selective pressures may have also enabled retention of gene duplicates, bolstering quantitative output of cytosolic heat shock proteins (HSPs). Given that newly duplicated genes are under more relaxed selection, it is plausible that gene duplication enabled altered regulation of such highly conserved genes. To test for evidence of gene duplication, copy number of various isoforms within major heat shock gene families were characterized via qPCR and compared between the Antarctic notothen, Trematomus bernacchii, which lost the inducible heat shock response, and the non-Antarctic notothen, Notothenia angustata, which maintains an inducible heat shock response. The results indicate duplication of isoforms within the hsp70 and hsp40 super families have occurred in the genome of T. bernacchii. The findings suggest gene duplications may have been critical in maintaining protein folding efficiency in the sub-zero waters and provided an evolutionary mechanism of alternative regulation of these conserved gene families.

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