Transcriptional adaptations following exercise in Thoroughbred horse skeletal muscle highlights molecular mechanisms that lead to muscle hypertrophy

McGivney, Beatrice A.; Eivers, Suzanne S.; MacHugh, David E.; MacLeod, James N.; O'Gorman, Grace M.; Park, Stephen D. E.; Katz, Lisa; Hill, E. W.

doi:10.1186/1471-2164-10-638

Cited by 49 publications

(56 citation statements)

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“…GHB is of interest because it is a natural compound with neuromodulatory properties at central GABAergic synapses [108], is an energy regulator that promotes the release of growth hormone [109], and has been illegally used by athletes as a performance-enhancing drug [110]. Indeed, endogenous GHB metabolism appears to be associated with natural athletic ability [111]. This idea is supported by data that identify ADHFE1 as an athletic-performance candidate gene, which has been a target for positive selection during 400 years in Thoroughbred horses [112].…”

Section: Resultsmentioning

confidence: 99%

Diversity and Evolutionary Analysis of Iron-Containing (Type-III) Alcohol Dehydrogenases in Eukaryotes

2016

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BackgroundAlcohol dehydrogenase (ADH) activity is widely distributed in the three domains of life. Currently, there are three non-homologous NAD(P)+-dependent ADH families reported: Type I ADH comprises Zn-dependent ADHs; type II ADH comprises short-chain ADHs described first in Drosophila; and, type III ADH comprises iron-containing ADHs (FeADHs). These three families arose independently throughout evolution and possess different structures and mechanisms of reaction. While types I and II ADHs have been extensively studied, analyses about the evolution and diversity of (type III) FeADHs have not been published yet. Therefore in this work, a phylogenetic analysis of FeADHs was performed to get insights into the evolution of this protein family, as well as explore the diversity of FeADHs in eukaryotes.Principal FindingsResults showed that FeADHs from eukaryotes are distributed in thirteen protein subfamilies, eight of them possessing protein sequences distributed in the three domains of life. Interestingly, none of these protein subfamilies possess protein sequences found simultaneously in animals, plants and fungi. Many FeADHs are activated by or contain Fe2+, but many others bind to a variety of metals, or even lack of metal cofactor. Animal FeADHs are found in just one protein subfamily, the hydroxyacid-oxoacid transhydrogenase (HOT) subfamily, which includes protein sequences widely distributed in fungi, but not in plants), and in several taxa from lower eukaryotes, bacteria and archaea. Fungi FeADHs are found mainly in two subfamilies: HOT and maleylacetate reductase (MAR), but some can be found also in other three different protein subfamilies. Plant FeADHs are found only in chlorophyta but not in higher plants, and are distributed in three different protein subfamilies.Conclusions/SignificanceFeADHs are a diverse and ancient protein family that shares a common 3D scaffold with a patchy distribution in eukaryotes. The majority of sequenced FeADHs from eukaryotes are distributed in just two subfamilies, HOT and MAR (found mainly in animals and fungi). These two subfamilies comprise almost 85% of all sequenced FeADHs in eukaryotes.

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Section: Resultsmentioning

confidence: 99%

Diversity and Evolutionary Analysis of Iron-Containing (Type-III) Alcohol Dehydrogenases in Eukaryotes

2016

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“…Since this modified pyrimidine is exclusively found in transfer and ribosomal RNAs, its increase in body fluids is generally considered as an index of increased rate of RNAs turnover, due to increased rate of protein synthesis (Sander et al 1986). Increase in the rate of protein synthesis following physical exercise has been demonstrated both in human beings (Dreyer et al 2010) and in horses (McGivney et al 2009). On the other hand, in patients affected by Canavan disease, the genetic neuroedegenerative leukodystrophy, characterized by cerebral spongi degeneration due to a defective form of the enzyme N-acetylaspartoacylase responsible for abnormal cerebral accumulation in N-acetylaspartate (NAA), a dramatic increase in circulating and excreted b-pseudouridine was recorded (Tavazzi et al 2005).…”

Section: Discussionmentioning

confidence: 96%

Modulation of circulating purines and pyrimidines by physical exercise in the horse

et al. 2010

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This study was designed to examine the influence of sub-maximal exercise on purine and pyrimidine catabolism in horses. Ten horses were initially trained for 12 weeks at the end of which they underwent a standardized exercise test (SET); venous blood samples were taken at rest, 5 and 30 min after the SET. Six untrained healthy horses, from which a blood withdrawal was taken at rest, were used as the control group. Samples were analyzed by HPLC for the simultaneous determination of uric acid, uridine, β-pseudouridine and creatinine in plasma. Glucose and lactate were measured in blood. Trained horses had basal uridine levels significantly lower than sedentary horses. The SET caused significant increase in plasma uric acid, uridine, β-pseudouridine and creatinine. Following the SET, a significant negative correlation was found between plasma uridine and glucose, whilst a significant positive correlation was observed between plasma uric acid and creatinine. These results indicate that increase in energy demand during exercise in the horse causes not only the degradation of purine but also of pyrimidine compounds, the latter possibly exerting a control on glucose uptake as also demonstrated in human beings.

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“…e l s e v i e r . c o m / l o c a t e / g e n e transcripts (McGivney et al, 2009;Hill et al, 2010a;Hill et al, 2010b;Park et al, 2012). Jeju horses are the descendants of 160 Mongolian horses that have inhabited and been bred since 1276 on Jeju Island, South Korea (Nam, 1969).…”

Section: Contents Lists Available At Sciencedirectmentioning

confidence: 99%

HEpD: A database describing epigenetic differences between Thoroughbred and Jeju horses

Gim

Lee

Kim

et al. 2015

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Transcriptional adaptations following exercise in Thoroughbred horse skeletal muscle highlights molecular mechanisms that lead to muscle hypertrophy

Cited by 49 publications

References 111 publications

Diversity and Evolutionary Analysis of Iron-Containing (Type-III) Alcohol Dehydrogenases in Eukaryotes

Diversity and Evolutionary Analysis of Iron-Containing (Type-III) Alcohol Dehydrogenases in Eukaryotes

Modulation of circulating purines and pyrimidines by physical exercise in the horse

HEpD: A database describing epigenetic differences between Thoroughbred and Jeju horses

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