Evolution of Digestive Enzymes and RNASE1 Provides Insights into Dietary Switch of Cetaceans

Wang, Zhengfei; Xu, Shixia; Du, Kexing; Huang, Feizhou; Chen, Zhuo; Zhou, Kaiya; Yang, Guang

doi:10.1093/molbev/msw191

Cited by 43 publications

(39 citation statements)

References 60 publications

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“…A similar phenomenon is known to have occurred in leaf-eating monkeys, where a secondary form of RNase 1 evolved to participate in ruminant-like digestion [31]. Analogously, modern whales and dolphins, which share a common ancestor with cattle, seemingly lost their extra copies of RNase 1 concurrent to switching from a herbivorous to a carnivorous diet [32]. Taken together, extant evidence suggests that cow RNase A—the original so-called “pancreatic ribonuclease”—might be a functional outlier among RNase 1 homologs, with the true physiological role of RNase 1 in other vertebrates still to be unveiled.…”

Section: Introductionmentioning

confidence: 83%

Comparative functional analysis of ribonuclease 1 homologs: molecular insights into evolving vertebrate physiology

Lomax

Eller

Raines

2017

Biochemical Journal

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Pancreatic-type ribonucleases (ptRNases) comprise a class of highly conserved secretory endoribonucleases in vertebrates. The prototype of this enzyme family is ribonuclease 1 (RNase 1). Understanding the physiological roles of RNase 1 is becoming increasingly important, as engineered forms of the enzyme progress through clinical trials as chemotherapeutic agents for cancer. Here we present an in-depth biochemical characterization of RNase 1 homologs from a broad range of mammals (human, bat, squirrel, horse, cat, mouse, and cow) and non-mammalian species (chicken, lizard, and frog). We discover that the human homolog of RNase 1 has a pH optimum for catalysis, ability to degrade double-stranded RNA, and affinity for cell-surface glycans that are distinctly higher than those of its homologs. These attributes have relevance for human health. Moreover, the functional diversification of the ten RNase 1 homologs illuminates the regulation of extracellular RNA and other aspects of vertebrate evolution.

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Section: Introductionmentioning

confidence: 83%

Comparative functional analysis of ribonuclease 1 homologs: molecular insights into evolving vertebrate physiology

Lomax

Eller

Raines

2017

Biochemical Journal

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“…Unlike RNase1, which has been extensively studied with gene duplication events observed in many mammals (Zhang et al 2002;Liu et al 2014;Wang et al 2016;Lang et al 2017), RNase6 has been examined in only a few species (Rosenberg & Dyer 1996;Deming et al 1998;Dyer et al 2004;Goo & Cho 2013). We studied 27 species representing the 3 main lineages of rodents and 10 families to investigate the evolutionary mechanism of RNase6.…”

Section: Discussionmentioning

confidence: 99%

“…Novel physiological functions may have evolved in group B and group C, which is reflected by selection pressures, key sites, isoelectric points and positive net charge. Positive selection has been used as one of the key evolutionary forces for the functional divergence of the duplicate genes and the association between positive selection and function divergence has been reported in some members of the RNase A superfamily (Zhang et al 2002;Liu et al 2014;Wang et al 2016;Lang et al 2017). One of the classical examples is the eosinophil-derived neurotoxin (EDN) and eosinophil cationic protein (ECP) of humans (Zhang et al 2000).…”

Section: Discussionmentioning

confidence: 99%

“…Using Mus musculus RNase6 sequences, TBLASTN and BLATN searches were carried out on Rodentia genomes to identify variation in this enzyme family. We used 10 −10 as the E-value cutoff for our searches (Cho et al 2005;Cho & Zhang 2006;Goo & Cho 2013;Wang et al 2016). In total, 27 species representing 10 families of Rodentia were examined in this study.…”

Section: Datasetsmentioning

confidence: 99%

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Adaptive evolutionary expansion of the ribonuclease 6 in Rodentia

Lang

Lim

Gao

et al. 2019

Integrative Zoology

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Ribonuclease 6 (RNase6 or RNase K6) is a protein that belongs to a superfamily thought to be the sole vertebrate-specific enzyme known for a wide range of physiological functions, including digestion, cytotoxicity, angiogenesis, male reproduction and host defense. In our study, 51 functional genes and 11 pseudogenes were identified from 27 Rodentia species. Intriguingly, in the 3 main lineages of rodents there were multiple RNas-e6s identified in all species of Ctenohystrica, whereas only a single RNase6 was observed in other Rodentia species examined except for 2 species in the mouse-related clade. The evolutionary scenario of "birth (gene duplication) and death (gene deactivation)" and gene sorting have been demonstrated in Ctenohystrica. In addition, bursts of positive selection, diversification of isoelectric point and positive net charge have been identified in Ctenohystrica, especially at two key sites that are involved in antimicrobial function. Site Trp30 has undergone positive selection and Ile45 has changed into other residues in Group B and Group C of the Ctenohystrica. Our results demonstrated a complex and intriguing evolutionary pattern of rodent RNase6, and indicated that functional modification may have occurred, which establishes an important theoretical foundation for future functional assays in rodent RNase6.

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“…Comparative analysis of cetacean genomes has provided important insights into the genomic determinants of cetacean traits and aquatic specializations (8). Several studies revealed patterns of positive selection in genes with roles in the nervous system, osmoregulation, oxygen transport, blood circulation, protein and lipid digestion, or bone microstructure (9)(10)(11)(12)(13)(14)(15)). An adaptive increase in myoglobin surface charge likely permitted a high concentration of this oxygen transport and storage protein in cetacean muscles (16).…”

Section: Introductionmentioning

confidence: 99%

Genes lost during the transition from land to water in cetaceans highlight genomic changes involved in aquatic adaptations

Huelsmann

Hecker

Springer

et al. 2019

Preprint

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The transition from land to water in whales and dolphins (cetaceans) was accompanied by remarkable anatomical, physiological and behavioral adaptations. To better understand the genomic changes that occurred during this transition, we systematically screened for protein-coding genes that were inactivated in the ancestral cetacean lineage. We discovered genes whose loss is likely beneficial for cetaceans by reducing the risk of thrombus formation during diving (F12, KLKB1), improving the fidelity of oxidative DNA damage repair (POLM), and protecting from oxidative stress-induced lung inflammation (MAP3K19). Additional gene losses may reflect other diving-related adaptations, such as enhanced vasoconstriction during the diving response (mediated by SLC6A18) and altered pulmonary surfactant composition (SEC14L3), while loss of SLC4A9 relates to a reduced need for saliva in aquatic environments. Finally, the complete loss of melatonin synthesis and receptor genes (AANAT, ASMT, MTNR1A/B) may have been a precondition for the evolution of unihemispheric sleep. Our findings suggest that some genes lost in the ancestral cetacean lineage may have been involved in adapting to a fully-aquatic lifestyle.

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Evolution of Digestive Enzymes and RNASE1 Provides Insights into Dietary Switch of Cetaceans

Cited by 43 publications

References 60 publications

Comparative functional analysis of ribonuclease 1 homologs: molecular insights into evolving vertebrate physiology

Comparative functional analysis of ribonuclease 1 homologs: molecular insights into evolving vertebrate physiology

Adaptive evolutionary expansion of the ribonuclease 6 in Rodentia

Genes lost during the transition from land to water in cetaceans highlight genomic changes involved in aquatic adaptations

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