Relationship between physical attributes and heat stress in dairy cattle from different genetic groups

Alfonzo, Evelyn Priscila München; Silva, Marcos Vinícius Gualberto Barbosa da; Daltro, Darlene dos Santos; Stumpf, Marcelo Tempel; Dalcin, Vanessa Calderaro; Kolling, G. J.; Fischer, Vívian; McManus, Concepta

doi:10.1007/s00484-015-1021-y

Cited by 34 publications

(23 citation statements)

References 26 publications

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“…HOXC13 gene has been found to determine skin thickness (Wu et al 2009(Wu et al , 2013. Skin thickness and number of hair follicles are reported to have an effect on thermoregulation; thermotolerant cattle have thicker skin than heat susceptible cattle breeds (Alfonzo et al 2016). In general, indicus cattle have thicker skin than taurus cattle (Pan 1963;Alfonzo et al 2016).…”

Section: Hair Coat Type and Colormentioning

confidence: 99%

Whole genome detection of signature of positive selection in African cattle reveals selection for thermotolerance

Taye

Lee

Caetano-Anollés

et al. 2017

Animal Science Journal

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As African indigenous cattle evolved in a hot tropical climate, they have developed an inherent thermotolerance; survival mechanisms include a light-colored and shiny coat, increased sweating, and cellular and molecular mechanisms to cope with high environmental temperature. Here, we report the positive selection signature of genes in African cattle breeds which contribute for their heat tolerance mechanisms. We compared the genomes of five indigenous African cattle breeds with the genomes of four commercial cattle breeds using cross-population composite likelihood ratio (XP-CLR) and cross-population extended haplotype homozygosity (XP-EHH) statistical methods. We identified 296 (XP-EHH) and 327 (XP-CLR) positively selected genes. Gene ontology analysis resulted in 41 biological process terms and six Kyoto Encyclopedia of Genes and Genomes pathways. Several genes and pathways were found to be involved in oxidative stress response, osmotic stress response, heat shock response, hair and skin properties, sweat gland development and sweating, feed intake and metabolism, and reproduction functions. The genes and pathways identified directly or indirectly contribute to the superior heat tolerance mechanisms in African cattle populations. The result will improve our understanding of the biological mechanisms of heat tolerance in African cattle breeds and opens an avenue for further study.

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Section: Hair Coat Type and Colormentioning

confidence: 99%

Whole genome detection of signature of positive selection in African cattle reveals selection for thermotolerance

Taye

Lee

Caetano-Anollés

et al. 2017

Animal Science Journal

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“…In domestic cattle, mitogenome analysis provides information regarding how functional traits like body size and tolerance are evolved in different lineages over temporal and spatial scales (Achilli et al, 2009(Achilli et al, , 2008 ). Thus, by simultaneously measuring both physiological and molecular responses, it is possible to assess differential tolerance among K E Y W O R D S adaptive tolerance, heat stress, livestock, phenotypic plasticity, phylogeny, size dependence dissimilar genetic groups of animals (Albon et al, 2017;Alfonzo et al, 2016;Mitchell et al, 2018). Additionally, mitogenome analysis can map out the observed differential adaptive trait variations at physiological and molecular levels to the phylogeny of different genetic groups (Lajbner, Pnini, Camus, Miller, & Dowling, 2018).…”

mentioning

confidence: 99%

Size does matter: Parallel evolution of adaptive thermal tolerance and body size facilitates adaptation to climate change in domestic cattle

Elayadeth-Meethal

Veettil

Maloney

et al. 2018

Ecology and Evolution

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The adaptive potential of livestock under a warming climate is increasingly relevant in relation to the growing pressure of global food security. Studies on heat tolerance demonstrate the interplay of adaptation and acclimatization in functional traits, for example, a reduction in body size and enhanced tolerance in response to a warming climate. However, current lack of understanding of functional traits and phylogenetic history among phenotypically distinct populations constrains predictions of climate change impact. Here, we demonstrate evidence of parallel evolution in adaptive tolerance to heat stress in dwarf cattle breeds (DCB, Bos taurus indicus) and compare their thermoregulatory responses with those in standard size cattle breeds (SCB, crossbred, Bos taurus indicus × Bos taurus taurus). We measured vital physiological, hematological, biochemical, and gene expression changes in DCB and SCB and compared the molecular phylogeny using mitochondrial genome (mitogenome) analysis. Our results show that SCB can acclimatize in the short term to higher temperatures but reach their tolerance limit under prevailing tropical conditions, while DCB is adapted to the warmer climate. Increased hemoglobin concentration, reduced cellular size, and smaller body size enhance thermal tolerance. Mitogenome analysis revealed that different lineages of DCB have evolved reduced size independently, as a parallel adaptation to heat stress. The results illustrate mechanistic ways of dwarfing, body size‐dependent tolerance, and differential fitness in a large mammal species under harsh field conditions, providing a background for comparing similar populations during global climate change. These demonstrate the value of studies combining functional, physiological, and evolutionary approaches to delineate adaptive potential and plasticity in domestic species. We thus highlight the value of locally adapted breeds as a reservoir of genetic variation contributing to the global domestic genetic resource pool that will become increasingly important for livestock production systems under a warming climate.

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“…Previous studies indicated that the density of hair follicles in Bos indicus is higher than that of Bos taurus (Turner & Schleger ), and the number of hair follicles is reported to have an effect on thermoregulation (Alfonzo et al ). The denser hair results in greater protection from radiant heat gain (Jian et al ), which is why the whole body of DHH cattle is covered with hairs that are extremely short, dense and closely applied to the skin (Yunnan Commission of Animal Genetic Resources ) (Fig.…”

Section: The Candidate Genes Are Associated With Heat Tolerance and Imentioning

confidence: 99%

Genome‐wide scan of selection signatures in Dehong humped cattle for heat tolerance and disease resistance

Chen

et al. 2019

Animal Genetics

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Summary Dehong humped cattle (DHH) is an indigenous zebu breed from southwestern China that possesses characteristics of heat tolerance and strong disease resistance and adapts well to the local tropical and subtropical climatic conditions. However, information on selection signatures of DHH is scarce. Herein, we compared the genomes of DHH and each of Diqing and Zhaotong cattle breeds using the population differentiation index (FST), cross‐population extended haplotype homozygosity (XP‐EHH) and cross‐population composite likelihood ratio (XP‐CLR) methods to explore the genomic signatures of heat tolerance and disease resistance in DHH. Several pathways and genes carried selection signatures, including thermal sweating (calcium signaling pathway), heat shock (HSF1) and oxidative stress response (PLCB1, PLCB4), coat color (RAB31), feed intake (ATP8A1, SHC3) and reproduction (TP63, MAP3K13, PTPN4, PPP3CC, ADAMTSL1, SS18L1, OSBPL2, TOX, RREB1, GRK2). These identified pathways and genes may contribute to heat tolerance in DHH. Simultaneously, we also identified LIPH, TP63 and CBFA2T3 genes under positive selection that were associated with immunity.

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Relationship between physical attributes and heat stress in dairy cattle from different genetic groups

Cited by 34 publications

References 26 publications

Whole genome detection of signature of positive selection in African cattle reveals selection for thermotolerance

Whole genome detection of signature of positive selection in African cattle reveals selection for thermotolerance

Size does matter: Parallel evolution of adaptive thermal tolerance and body size facilitates adaptation to climate change in domestic cattle

Genome‐wide scan of selection signatures in Dehong humped cattle for heat tolerance and disease resistance

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