Fiona Robertson scite author profile

BackgroundThe functional divergence of duplicate genes (ohnologues) retained from whole genome duplication (WGD) is thought to promote evolutionary diversification. However, species radiation and phenotypic diversification are often temporally separated from WGD. Salmonid fish, whose ancestor underwent WGD by autotetraploidization ~95 million years ago, fit such a ‘time-lag’ model of post-WGD radiation, which occurred alongside a major delay in the rediploidization process. Here we propose a model, ‘lineage-specific ohnologue resolution’ (LORe), to address the consequences of delayed rediploidization. Under LORe, speciation precedes rediploidization, allowing independent ohnologue divergence in sister lineages sharing an ancestral WGD event.ResultsUsing cross-species sequence capture, phylogenomics and genome-wide analyses of ohnologue expression divergence, we demonstrate the major impact of LORe on salmonid evolution. One-quarter of each salmonid genome, harbouring at least 4550 ohnologues, has evolved under LORe, with rediploidization and functional divergence occurring on multiple independent occasions >50 million years post-WGD. We demonstrate the existence and regulatory divergence of many LORe ohnologues with functions in lineage-specific physiological adaptations that potentially facilitated salmonid species radiation. We show that LORe ohnologues are enriched for different functions than ‘older’ ohnologues that began diverging in the salmonid ancestor.ConclusionsLORe has unappreciated significance as a nested component of post-WGD divergence that impacts the functional properties of genes, whilst providing ohnologues available solely for lineage-specific adaptation. Under LORe, which is predicted following many WGD events, the functional outcomes of WGD need not appear ‘explosively’, but can arise gradually over tens of millions of years, promoting lineage-specific diversification regimes under prevailing ecological pressures.Electronic supplementary materialThe online version of this article (doi:10.1186/s13059-017-1241-z) contains supplementary material, which is available to authorized users.

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Recent advances in understanding the molecular genetic basis of mitochondrial disease

Thompson

Collier

Glasgow

et al. 2019

J of Inher Metab Disea

126

104

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Mitochondrial disease is hugely diverse with respect to associated clinical presentations and underlying genetic causes, with pathogenic variants in over 300 disease genes currently described. Approximately half of these have been discovered in the last decade due to the increasingly widespread application of next generation sequencing technologies, in particular unbiased, whole exome—and latterly, whole genome sequencing. These technologies allow more genetic data to be collected from patients with mitochondrial disorders, continually improving the diagnostic success rate in a clinical setting. Despite these significant advances, some patients still remain without a definitive genetic diagnosis. Large datasets containing many variants of unknown significance have become a major challenge with next generation sequencing strategies and these require significant functional validation to confirm pathogenicity. This interface between diagnostics and research is critical in continuing to expand the list of known pathogenic variants and concomitantly enhance our knowledge of mitochondrial biology. The increasing use of whole exome sequencing, whole genome sequencing and other “omics” techniques such as transcriptomics and proteomics will generate even more data and allow further interrogation and validation of genetic causes, including those outside of coding regions. This will improve diagnostic yields still further and emphasizes the integral role that functional assessment of variant causality plays in this process—the overarching focus of this review.

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Age-associated mitochondrial DNA mutations cause metabolic remodeling that contributes to accelerated intestinal tumorigenesis

et al. 2020

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Oxidative phosphorylation (OXPHOS) defects caused by somatic mitochondrial DNA mutations increase with age in human colorectal epithelium and are prevalent in colorectal tumors, but whether they actively contribute to tumorigenesis remains unknown. Here we demonstrate that mitochondrial DNA mutations causing OXPHOS defects are enriched during the human adenoma/carcinoma sequence, suggesting that they may confer a metabolic advantage. To test this, we deleted the tumor suppressor Apc in OXPHOS-deficient intestinal stem cells in mice. The resulting tumors were larger than in control mice due to accelerated cell proliferation and reduced apoptosis. We show that both normal crypts and tumors undergo metabolic remodeling in response to OXPHOS deficiency by upregulating the de novo serine synthesis pathway. Moreover, normal human colonic crypts upregulate the serine synthesis pathway in response to OXPHOS deficiency before tumorigenesis. Our data show that age-associated OXPHOS deficiency causes metabolic remodeling that can functionally contribute to accelerated intestinal cancer development.

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Fiona Robertson

Lineage-specific rediploidization is a mechanism to explain time-lags between genome duplication and evolutionary diversification

Recent advances in understanding the molecular genetic basis of mitochondrial disease

Age-associated mitochondrial DNA mutations cause metabolic remodeling that contributes to accelerated intestinal tumorigenesis

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