Genomic insights into body size evolution in Carnivora support Peto’s paradox

Huang, Xin; Sun, Di; Wu, Tianzhen; Xing, Lianxi; Xu, Shixia; Yang, Guang

doi:10.1186/s12864-021-07732-w

Cited by 11 publications

(12 citation statements)

References 78 publications

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“…The fixed amino acid replacements in certain group of mammals might contribute to the explanation underlying a specific phenotype [ 29 ]. Among 5333 proteins and 3,585,819 amino acid positions, only one ascrotal mammal-specific amino acid substitution was identified in Glucagon Like Peptide 2 Receptor (GLP2R).…”

Section: Resultsmentioning

confidence: 99%

Comparative genomics reveals molecular mechanisms underlying health and reproduction in cryptorchid mammals

Chai

Huang

et al. 2021

BMC Genomics

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Background Mammals have wide variations in testicular position, with scrotal testes in some species and ascrotal testes in others. Although cryptorchidism is hazardous to human health, some mammalian taxa are natural cryptorchids. However, the evolution of testicular position and the molecular mechanisms underlying the maintenance of health, including reproductive health, in ascrotal mammals are not clear. Results In the present study, comparative genomics and evolutionary analyses revealed that genes associated with the extracellular matrix and muscle, contributing to the development of the gubernaculum, were involved in the evolution of testicular position in mammals. Moreover, genes related to testicular position were significantly associated with spermatogenesis and sperm fertility. These genes showed rapid evolution and the signature of positive selection, with specific substitutions in ascrotal mammals. Genes associated with testicular position were significantly enriched in functions and pathways related to cancer, DNA repair, DNA replication, and autophagy. Conclusions Our results revealed that alterations in gubernaculum development contributed to the evolution of testicular position in mammals and provided the first support for two hypotheses for variation in testicular position in mammals, the “cooling hypothesis”, which proposes that the scrotum provides a cool environment for acutely heat-sensitive sperm and the “training hypothesis”, which proposes that the scrotum develops the sperm by exposing them to an exterior environment. Further, we identified cancer resistance and DNA repair as potential protective mechanisms in natural cryptorchids. These findings provide general insights into cryptorchidism and have implications for health and infertility both in humans and domestic mammals.

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Section: Resultsmentioning

confidence: 99%

Comparative genomics reveals molecular mechanisms underlying health and reproduction in cryptorchid mammals

Chai

Huang

et al. 2021

BMC Genomics

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“…Results of both the two-ratio and free-ratio models were compared with the null model—a one-ratio model that allowed an equal ω ratio for all branches in the phylogeny. When the value of d N or d S in each ω value is less than 0.0002, we considered it as an outlier “n/a” [ 56 ]. The relative goodness-of-fit of the nested models was determined using a likelihood ratio test (LRT) that was performed by comparing twice the difference in ln likelihood scores (2ΔlnL) against a χ 2 distribution, with the number of degrees of freedom corresponding to the difference in number of parameters between the nested models.…”

Section: Methodsmentioning

confidence: 99%

Evolutionary genetics of flipper forelimb and hindlimb loss from limb development-related genes in cetaceans

et al. 2022

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Background Cetacean hindlimbs were lost and their forelimb changed into flippers characterized by webbed digits and hyperphalangy, thus allowing them to adapt to a completely aquatic environment. However, the underlying molecular mechanism behind cetacean limb development remains poorly understood. Results In the present study, we explored the evolution of 16 limb-related genes and their cis-regulatory elements in cetaceans and compared them with that of other mammals. TBX5, a forelimb specific expression gene, was identified to have been under accelerated evolution in the ancestral branches of cetaceans. In addition, 32 cetacean-specific changes were examined in the SHH signaling network (SHH, PTCH1, TBX5, BMPs and SMO), within which mutations could yield webbed digits or an additional phalange. These findings thus suggest that the SHH signaling network regulates cetacean flipper formation. By contrast, the regulatory activity of the SHH gene enhancer—ZRS in cetaceans—was significantly lower than in mice, which is consistent with the cessation of SHH gene expression in the hindlimb bud during cetacean embryonic development. It was suggested that the decreased SHH activity regulated by enhancer ZRS might be one of the reasons for hindlimb degeneration in cetaceans. Interestingly, a parallel / convergent site (D42G) and a rapidly evolving CNE were identified in marine mammals in FGF10 and GREM1, respectively, and shown to be essential to restrict limb bud size; this is molecular evidence explaining the convergence of flipper-forelimb and shortening or degeneration of hindlimbs in marine mammals. Conclusions We did evolutionary analyses of 16 limb-related genes and their cis-regulatory elements in cetaceans and compared them with those of other mammals to provide novel insights into the molecular basis of flipper forelimb and hindlimb loss in cetaceans.

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“…However, the molecular mechanisms for maintaining large sizes and longevity in large carnivores have not been extensively investigated thus far. Huang et al (2021 ) reported 100 body size-associated genes in carnivores related to cancer control, including tumor suppressors, DNA repair, and immunity. From these genes, 15 cancer-related genes were identified as rapidly evolving in the extremely large lineages, which might protect the animal from cancer invasion: ADGRF2, CABCOCO1, CATSPERG, CCDC146, CPLX4, CTLA4, MAS1, PACSIN1, PHF13, SDR39U1, SLC25A28, TCTE1, TERB1, YTHDC2 and ZBED1 ( Huang et al , 2021 ).…”

Section: Mechanisms To Evade Cancermentioning

confidence: 99%

A phylogenetic review of cancer resistance highlights evolutionary solutions to Peto’s Paradox

et al. 2022

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Cancer is a genetic disease present in all complex multicellular lineages. Finding ways to eliminate it is a goal of a large part of the scientific community and nature itself. Early, scientists realized that the cancer incidence at the species level was not related to the number of cells or lifespan, a phenomenon called Peto's Paradox. The interest in resolving this paradox triggered a growing interest in investigating the natural strategies for cancer suppression hidden in the animal's genomes. Here, we gathered information on the main mechanisms that confer resistance to cancer, currently described for lineages that have representatives with extended longevity and large body sizes. Some mechanisms to reduce or evade cancer are common and shared between lineages, while others are species-specific. The diversity of paths that evolution followed to face the cancer challenge involving coding, regulatory, and structural aspects of genomes is astonishing and much yet lacks discovery. Multidisciplinary studies involving oncology, ecology, and evolutionary biology and focusing on nonmodel species can greatly expand the frontiers of knowledge about cancer resistance in animals and may guide new promising treatments and prevention that might apply to humans.

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Genomic insights into body size evolution in Carnivora support Peto’s paradox

Cited by 11 publications

References 78 publications

Comparative genomics reveals molecular mechanisms underlying health and reproduction in cryptorchid mammals

Comparative genomics reveals molecular mechanisms underlying health and reproduction in cryptorchid mammals

Evolutionary genetics of flipper forelimb and hindlimb loss from limb development-related genes in cetaceans

A phylogenetic review of cancer resistance highlights evolutionary solutions to Peto’s Paradox

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