[1. AHN S.G., THIELE D.J., 2003 – Redox regulation of mammalian heat shock factor 1 is essential for Hsp gene activation and protection from stress. Genes & Development 17(4), 516-528.]Search in Google Scholar
[2. ANDERSSON D.C., FAUCONNIER J., YAMADA T., LACAMPAGNE A., ZHANG S.J., KATZ A., WESTERBLAD H., 2011 – Mitochondrial production of reactive oxygen species contributes to the β‐adrenergic stimulation of mouse cardiomycytes. The Journal of Physiology 589(7), 1791-1801.]Search in Google Scholar
[3. ASADOLLAHI H., VAEZ TORSHIZI R., EHSANI A., MASOUDI A.A., 2022 – An association of CEP78, MEF2C, VPS13A and ARRDC3 genes with survivability to heat stress in an F2 chicken population. Journal of Animal Breeding and Genetics 139(5), 574-582.]Search in Google Scholar
[4. ASADOLLAHPOUR NANAEI, H., KHARRATI-KOOPAEE, H., ESMAILIZADEH A., 2022 – Genetic diversity and signatures of selection for heat tolerance and immune response in Iranian native chickens. BMC Genomics 23(1), 224.]Search in Google Scholar
[5. BATISTA T.M., DAGDEVIREN S., CARROLL S.H., CAI W., MELNIK V.Y., NOH H.L., SAENGNIPANTHKUL S., KIM J.K., KAHN C.R., LEE R.T., 2020 – Arrestin domain-containing 3 (Arrdc3) modulates insulin action and glucose metabolism in liver. Proceedings of the National Academy of Sciences 117(12), 6733-6740.]Search in Google Scholar
[6. BELAY T., TEETER R.G., 1996 – Effects of ambient temperature on broiler mineral balance partitioned into urinary and faecal loss. British Poultry Science 37(2), 423-433.]Search in Google Scholar
[7. BJORKQUIST A., ASHWELL C., PERSIA M., ROTHSCHILD M.F., SCHMIDT C., LAMONT S.J., 2014 – QTL for body composition traits during heat stress revealed in an advanced intercross line of chickens. Change 55(36), 2-27.]Search in Google Scholar
[8. BJORKQUIST, A.G., ROTHSCHILD, M.F., PERSIA, M.E., ASHWELL, C., SCHMIDT, C. AND LAMONT, S.J., 2015 – Genetic markers found for response to heat stress in chickens. Iowa State University Animal Industry Report 12(1).]Search in Google Scholar
[9. BOTTJE W.G., HARRISON P.C., 1985 – Effect of carbonated water on growth performance of cockerels subjected to constant and cyclic heat stress temperatures. Poultry Science 64(7), 1285-1292.]Search in Google Scholar
[10. BRUNK K., ZHU M., BÄRENZ F., KRATZ A.S., HASELMANN-WEISS U., ANTONY C., HOFFMANN I., 2016 – Cep78 is a new centriolar protein involved in Plk4-induced centriole overduplication. Journal of Cell Science 129(14), 2713-2718.]Search in Google Scholar
[11. CASENGHI M., MERALDI P., WEINHART U., DUNCAN P.I., KÖRNER R., NIGG E.A., 2003 – Polo-like kinase 1 regulates Nlp, a centrosome protein involved in microtubule nucleation. Developmental Cell 5(1), 113-125.]Search in Google Scholar
[12. CEDRAZ H., GROMBONI J.G.G., GARCIA A.A.P., FARIAS FILHO R.V., SOUZA T.M., OLIVEIRA E.R.D., OLIVEIRA E.B.D., NASCIMENTO C.S.D., MENEGHETTI C., WENCESLAU A.A., 2017 – Heat stress induces expression of HSP genes in genetically divergent chickens. PLoS One 12(10), p.e0186083.]Search in Google Scholar
[13. CERVANTES M., COTA M., ARCE N., CASTILLO G., AVELAR E., ESPINOZA S., MORALES A., 2016 – Effect of heat stress on performance and expression of selected amino acid and glucose transporters, HSP90, leptin and ghrelin in growing pigs. Journal of Thermal Biology 59, 69-76.]Search in Google Scholar
[14. CHEN Y.J., LAI K.C., KUO H.H., CHOW L.P., YIH L.H., LEE T.C., 2014 – HSP70 colocalizes with PLK1 at the centrosome and disturbs spindle dynamics in cells arrested in mitosis by arsenic trioxide. Archives of Toxicology 88, 1711-1723.]Search in Google Scholar
[15. CHU B., SONCIN F., PRICE B.D., STEVENSON M.A., CALDERWOOD S.K., 1996 – Sequential phosphorylation by mitogen-activated protein kinase and glycogen synthase kinase 3 represses transcriptional activation by heat shock factor-1. Journal of Biological Chemistry 271(48), 30847-30857.]Search in Google Scholar
[16. CLAIRE D’ANDRE H., PAUL W., SHEN X., JIA X., ZHANG R., SUN L., ZHANG X., 2013 – Identification and characterization of genes that control fat deposition in chickens. Journal of Animal Science and Biotechnology 4(1), 1-16.]Search in Google Scholar
[17. CLEVELAND L.R., 1923 – Symbiosis between termites and their intestinal protozoa. Proceedings of the National Academy of Sciences 9(12), 424-428.]Search in Google Scholar
[18. COBLE D.J., FLEMING D., PERSIA M.E., ASHWELL C.M., ROTHSCHILD M.F., SCHMIDT C.J., LAMONT S.J., 2014 – RNA-seq analysis of broiler liver transcriptome reveals novel responses to high ambient temperature. BMC Genomics 15(1), 1-12.]Search in Google Scholar
[19. DAYYANI N., BAKHTIARI H., 2013 – Heat stress in poultry: background and affective factors. International Journal of Advanced Biological and Biomedical Research 1(11), 1409-1413.]Search in Google Scholar
[20. DE MAIO A., VAZQUEZ D., 2013 – Extracellular heat shock proteins: a new location, a new function. Shock (Augusta, Ga.), 40(4), p. 239.]Search in Google Scholar
[21. DEKKERS J.C., HOSPITAL F., 2002 – The use of molecular genetics in the improvement of agricultural populations. Nature Reviews Genetics 3(1), 22-32.]Search in Google Scholar
[22. DEKKERS J.C., HOSPITAL F., 2002 – The use of molecular genetics in the improvement of agricultural populations. Nature Reviews Genetics 3(1), 22-32.]Search in Google Scholar
[23. DEWE J.M., FULLER B.L., LENTINI J.M., KELLNER S.M., FU D., 2017 – TRMT1-catalyzed tRNA modifications are required for redox homeostasis to ensure proper cellular proliferation and oxidative stress survival. Molecular and Cellular Biology 37(21), e00214-17.]Search in Google Scholar
[24. DIAZ‐REAL J., KIM S.Y., VELANDO A., 2017 – Plumage colour and the expression of stress‐ related genes in gull chicks. Journal of Avian Biology 48(9), 1216-1225.]Search in Google Scholar
[25. DOBSON‐STONE C., VELAYOS‐BAEZA A., FILIPPONE L.A., WESTBURY S., STORCH A., ERDMANN T., WROE S.J., LEENDERS K.L., LANG A.E., DOTTI M.T., FEDERICO A., 2004 – Chorein detection for the diagnosis of chorea‐acanthocytosis. Annals of Neurology: Official Journal of the American Neurological Association and the Child Neurology Society 56(2), 299-302.]Search in Google Scholar
[26. DONKOH A., 1989 – Ambient temperature: a factor affecting performance and physiological response of broiler chickens. International Journal of Biometeorology 33, 259-265.]Search in Google Scholar
[27. DORES M.R., LIN H., GRIMSEY N.J., MENDEZ F., TREJO J., 2015 – The α-arrestin ARRDC3 mediates ALIX ubiquitination and G protein–coupled receptor lysosomal sorting. Molecular Biology of the Cell 26(25), 4660-4673.]Search in Google Scholar
[28. DUANGJINDA M., TUNIM S., DUANGDAEN C., BOONKUM W., 2017 – Hsp70 genotypes and heat tolerance of commercial and native chickens reared in hot and humid conditions. Brazilian Journal of Poultry Science 19, 07-18.]Search in Google Scholar
[29. EBERHART D.E., WASHBURN K.W., 1993 – Assessing the effects of the naked neck gene on chronic heat stress resistance in two genetic populations. Poultry Science 72(8), 1391-1399.]Search in Google Scholar
[30. GALAL A., RADWAN L.M., REZIK H.H., AYOUB H., 2019 – Expression levels of HSP70 and CPT-1 in three local breeds of chickens reared under normal or heat stress conditions after the introduction of the naked neck gene. Journal of Thermal Biology 80, 113-118.]Search in Google Scholar
[31. GARCIA H., GRAGEOLA F., MORALES A., ARAIZA A., ARCE N., CERVANTES M., 2012 – Severe heat stress affects the expression of Hsp90, GLUT4 and b0,+, in liver and leptin in adipose tissue of pigs. The FASEB Journal pp, 651-3. The FASEB journal, pp, 651-3.]Search in Google Scholar
[32. GOCHEE P.A., POWELL L.W., CULLEN D.J., DU SART D., ROSSI E., OLYNYK J.K., 2002 – A population-based study of the biochemical and clinical expression of the H63D hemochromatosis mutation. Gastroenterology 122(3), 646-651.]Search in Google Scholar
[33. GOO D., KIM J.H., PARK G.H., DELOS REYES J.B., KIL, D.Y., 2019 – Effect of heat stress and stocking density on growth performance, breast meat quality, and intestinal barrier function in broiler chickens. Animals 9(3), 107.]Search in Google Scholar
[34. GUO Y., LIAO J.H., LIANG Z.L., BALASUBRAMANIAN B., LIU W.C., 2021 – Hepatic lipid metabolomics in response to heat stress in local broiler chickens breed (Huaixiang chickens). Veterinary Medicine and Science 7(4), 1369-1378.]Search in Google Scholar
[35. GUPTA S.C., MISHRA M., SHARMA A., BALAJI T.D., KUMAR R., MISHRA R.K., CHOWDHURI D.K., 2010 – Chlorpyrifos induces apoptosis and DNA damage in Drosophila through generation of reactive oxygen species. Ecotoxicology and Environmental Safety 73(6), 1415-1423.]Search in Google Scholar
[36. HOCKING P.M., MAXWELL M.H., MITCHELL M.A., 1994 – Haematology and blood composition at two ambient temperatures in genetically fat and lean adult broiler breeder females fed ad libitum or restricted throughout life. British Poultry Science 35(5), 799-807.]Search in Google Scholar
[37. JOHNSON M., KUMAR A., OLADZAD-ABBASABADI A., SALSMAN E., AOUN M., MANTHEY F.A., ELIAS E.M., 2019 – Association mapping for 24 traits related to protein content, gluten strength, color, cooking, and milling quality using balanced and unbalanced data in durum wheat [Triticum turgidum L. var. durum (Desf).]. Frontiers in Genetics 10, 717.]Search in Google Scholar
[38. KEATINGE W.R., COLESHAW S.R., EASTON J.C., COTTER F., MATTOCK M.B., CHELLIAH R., 1986 – Increased platelet and red cell counts, blood viscosity, and plasma cholesterol levels during heat stress, and mortality from coronary and cerebral thrombosis. The American Journal of Medicine 81(5), 795-800.]Search in Google Scholar
[39. KIM S.A., YOON J.H., LEE S.H., AHN S.G., 2005 – Polo-like kinase 1 phosphorylates heat shock transcription factor 1 and mediates its nuclear translocation during heat stress. Journal of Biological Chemistry 280(13), pp.12653-12657.]Search in Google Scholar
[40. KOUL H.K., PAL M., KOUL S., 2013 – Role of p38 MAP kinase signal transduction in solid tumors. Genes & Cancer 4(9-10), 342-359.]Search in Google Scholar
[41. KRAFT C., HERZOG F., GIEFFERS C., MECHTLER K., HAGTING A., PINES J., PETERS J.M., 2003 – Mitotic regulation of the human anaphase-promoting complex by phosphorylation. The EMBO Journal 22(24), 6598-6609.]Search in Google Scholar
[42. KUMAR M., RATWAN P., DAHIYA S.P., NEHRA, A.K., 2021 – Climate change and heat stress: Impact on production, reproduction and growth performance of poultry and its mitigation using genetic strategies. Journal of thermal Biology 97, 102867.]Search in Google Scholar
[43. KUMARI K.N.R., NATH D.N., 2018 – Ameliorative measures to counter heat stress in poultry. World’s Poultry Science Journal 74(1), 117-130.]Search in Google Scholar
[44. LAMONT S., COBLE D.J., BJORKQUIST A., ROTHSCHILD M., PERSIA M., ASHWELL C., SCHMIDT C., 2014 – Genomics of heat stress in chickens. Proceedings, 10th World Congress of Genetics Applied to Livestock Production.]Search in Google Scholar
[45. LANDE R., THOMPSON R., 1990 – Efficiency of marker-assisted selection in the improvement of quantitative traits. Genetics 124(3), pp.743-756.]Search in Google Scholar
[46. LEI L., HEPENG L., XIANLEI L., HONGCHAO J., HAI L., SHEIKHAHMADI A., YUFENG W., ZHIGANG S., 2013 – Effects of acute heat stress on gene expression of brain–gut neuropeptides in broiler chickens (Gallus gallus domesticus). Journal of Animal Science 91(11), 5194-5201.]Search in Google Scholar
[47. LIN H., JIAO H.C., BUYSE J., DECUYPERE E., 2006 – Strategies for preventing heat stress in poultry. World’s Poultry Science Journal 62(1), 71-86.]Search in Google Scholar
[48. LU Q., WEN J., ZHANG H., 2007 – Effect of chronic heat exposure on fat deposition and meat quality in two genetic types of chicken. Poultry Science 86(6), 1059-1064.]Search in Google Scholar
[49. LUO Q.B., SONG X.Y., JI C.L., ZHANG X.Q., ZHANG D.X., 2014 – Exploring the molecular mechanism of acute heat stress exposure in broiler chickens using gene expression profiling. Gene 546(2), 200-205.]Search in Google Scholar
[50. MACK L.A., FELVER-GANT J.N., DENNIS,R.L., CHENG H.W., 2013 – Genetic variations alter production and behavioral responses following heat stress in 2 strains of laying hens. Poultry Science 92(2), 285-294.]Search in Google Scholar
[51. MACK L.A., FELVER-GANT J.N., DENNIS R.L., CHENG H.W., 2013 – Genetic variations alter production and behavioral responses following heat stress in 2 strains of laying hens. Poultry Science 92(2), 285-294.]Search in Google Scholar
[52. MEIMARIDOU E., GOOLJAR S.B., CHAPPLE J.P., 2009 – From hatching to dispatching: the multiple cellular roles of the Hsp70 molecular chaperone machinery. Journal of Molecular Endocrinology 42(1), 1-9.]Search in Google Scholar
[53. MELCHIORRE M.G., CHIATTI C., LAMURA G., TORRES-GONZALES F., STANKUNAS M., LINDERT J., IOANNIDI-KAPOLOU E., BARROS H., MACASSA G., SOARES J.F., 2013 – Social support, socio-economic status, health and abuse among older people in seven European countries. PloS One 8(1), p.e54856.]Search in Google Scholar
[54. MISZTAL I., LEGARRA A., AGUILAR I., 2009 – Computing procedures for genetic evaluation including phenotypic, full pedigree, and genomic information. Journal of Dairy Science 92(9), 4648-4655.]Search in Google Scholar
[55. NARDONE A., RONCHI B., LACETERA N., RANIERI M.S., BERNABUCCI U., 2010 – Effects of climate changes on animal production and sustainability of livestock systems. Livestock Science 130(1-3), 57-69.]Search in Google Scholar
[56. PATWARI P., EMILSSON V., SCHADT E.E., CHUTKOW W.A., LEE S., MARSILI A., ZHANG Y., DOBRIN R., COHEN D.E., LARSEN P.R., ZAVACKI A.M., 2011 – The arrestin domain-containing 3 protein regulates body mass and energy expenditure. Cell Metabolism 14(5), 671-683.]Search in Google Scholar
[57. PAWAR S.S., SAJJANAR B., LONKAR V.D., KURADE N.P., KADAM A.S., NIRMAL A.V., BRAHMANE M.P. BAL S.K., 2016 – Assessing and mitigating the impact of heat stress in poultry. Advances in Animal and Veterinary Sciences 4(6), 332-341.]Search in Google Scholar
[58. PEARSON G., ROBINSON F., BEERS GIBSON T., XU B.E., KARANDIKAR M., BERMAN K., COBB M.H., 2001 – Mitogen-activated protein (MAP) kinase pathways: regulation and physiological functions. Endocrine Reviews 22(2), 153-183.]Search in Google Scholar
[59. QUINTEIRO-FILHO W.M., RIBEIRO A., FERRAZ-DE-PAULA V., PINHEIRO M.L., SAKAI M., SÁ L.R.M.D., FERREIRA A.J.P., PALERMO-NETO J., 2010 – Heat stress impairs performance parameters, induces intestinal injury, and decreases macrophage activity in broiler chickens. Poultry Science 89(9), 1905-1914.]Search in Google Scholar
[60. ROWLAND K., ASHWELL C.M., PERSIA M.E., ROTHSCHILD M.F., SCHMIDT C., LAMONT S.J., 2019 – Genetic analysis of production, physiological, and egg quality traits in heat-challenged commercial white egg-laying hens using 600k SNP array data. Genetics Selection Evolution 51(1), 1-9.]Search in Google Scholar
[61. SAELAO P., WANG Y., CHANTHAVIXAY G., GALLARDO R.A., WOLC A., DEKKERS J.C., LAMONT S.J., KELLY T., ZHOU H., 2019 – Genetics and genomic regions affecting response to newcastle disease virus infection under heat stress in layer chickens. Genes 10(1), p.61.]Search in Google Scholar
[62. SANDERCOCK D.A., HUNTER R.R., NUTE G.R., MITCHELL M.A., HOCKING P.M., 2001 – Acute heat stress-induced alterations in blood acid-base status and skeletal muscle membrane integrity in broiler chickens at two ages: Implications for meat quality. Poultry Science 80(4), 418-425.]Search in Google Scholar
[63. SCHMIDT E.M., SCHMID E., MÜNZER P., HERMANN A., EYRICH A.K., RUSSO A., WALKER B., GU S., VOM HAGEN J.M., FAGGIO C., SCHALLER M., 2013 – Chorein sensitivity of cytoskeletal organization and degranulation of platelets. The FASEB Journal 27(7), 2799-2806.]Search in Google Scholar
[64. SENJU M., SUEOKA N., SATO A., IWANAGA K., SAKAO Y., TOMIMITSU S., TOMINAGA M., IRIE K., HAYASHI S., SUEOKA E., 2006 – Hsp90 inhibitors cause G2/M arrest associated with the reduction of Cdc25C and Cdc2 in lung cancer cell lines. Journal of Cancer Research and Clinical Oncology 132, 150-158.]Search in Google Scholar
[65. SHEHATA A.M., SAADELDIN I.M., TUKUR H.A., HABASHY W.S., 2020 – Modulation of heat-shock proteins mediates chicken cell survival against thermal stress. Animals 10(12), p.2407.]Search in Google Scholar
[66. SHIELDS H.J., TRAA A., VAN RAAMSDONK J.M., 2021 – Beneficial and detrimental effects of reactive oxygen species on lifespan: a comprehensive review of comparative and experimental studies. Frontiers in Cell and Developmental Biology 9, 181.]Search in Google Scholar
[67. SILVER J.T., NOBLE E.G., 2012 – Regulation of survival gene hsp70. Cell Stress and Chaperones 17, 1-9.]Search in Google Scholar
[68. SOLEIMANI A.F., ZULKIFLI I., OMAR A.R., RAHA A.R., 2011 – Physiological responses of 3 chicken breeds to acute heat stress. Poultry Science 90(7), 1435-1440.]Search in Google Scholar
[69. SORGER P.K., 1991 – Heat shock factor and the heat shock response. Cell 65(3), 363-366.]Search in Google Scholar
[70. SRIKANTH K., KUMAR H., PARK W., BYUN M., LIM D., KEMP S., TE PAS M.F., KIM J.M., PARK J.E., 2019 – Cardiac and skeletal muscle transcriptome response to heat stress in Kenyan chicken ecotypes adapted to low and high altitudes reveal differences in thermal tolerance and stress response. Frontiers in Genetics 10, 993.]Search in Google Scholar
[71. SUN X., ZHANG H., SHEIKHAHMADI A., WANG Y., JIAO H., LIN H., SONG Z., 2015 – Effects of heat stress on the gene expression of nutrient transporters in the jejunum of broiler chickens (Gallus gallus domesticus). International Journal of Biometeorology 59, 127-135.]Search in Google Scholar
[72. TAMZIL M.H., NOOR R.R., HARDJOSWORO P.S., MANALU W., SUMANTRI C., 2013 – Acute heat stress responses of three lines of chickens with different heat shock protein (HSP)-70 genotypes. International Journal of Poultry Science 12(5), 264-272.]Search in Google Scholar
[73. TELLECHEA M., BUXADÉ M., TEJEDOR S., ARAMBURU J., LOPEZ-RODRIGUEZ C., 2018 – NFAT5-regulated macrophage polarization supports the proinflammatory function of macrophages and T lymphocytes. The Journal of Immunology 200(1), 305-315.]Search in Google Scholar
[74. TIAN W., ZHENG H., YANG L., LI H., TIAN Y., WANG Y., LYU S., BROCKMANN G.A., KANG X., LIU X., 2018 – Dynamic expression profile, regulatory mechanism and correlation with egg-laying performance of ACSF gene family in chicken (Gallus gallus). Scientific Reports 8(1), 8457.]Search in Google Scholar
[75. VAN GOOR A., BOLEK K.J., ASHWELL C.M., PERSIA M.E., ROTHSCHILD M.F., SCHMIDT C.J., LAMONT S.J., 2015 – Identification of quantitative trait loci for body temperature, body weight, breast yield, and digestibility in an advanced intercross line of chickens under heat stress. Genetics Selection Evolution 47(1), 1-13.]Search in Google Scholar
[76. VASSALLI G., MILANO G., MOCCETTI T., 2012 – Role of mitogen-activated protein kinases in myocardial ischemia-reperfusion injury during heart transplantation. Journal of Transplantation 2012.]Search in Google Scholar
[77. WALUGEMBE M., BERTOLINI F., DEMATAWEWA C.M.B., REIS M.P., ELBELTAGY A.R., SCHMIDT C.J., LAMONT S.J., ROTHSCHILD M.F., 2019 – Detection of selection signatures among Brazilian, Sri Lankan, and Egyptian chicken populations under different environmental conditions. Frontiers in Genetics 9, 737.]Search in Google Scholar
[78. WANG H., SMITH K.P., COMBS E., BLAKE T., HORSLEY R.D., MUEHLBAUER G.J., 2012 – Effect of population size and unbalanced data sets on QTL detection using genome-wide association mapping in barley breeding germplasm. Theoretical and Applied Genetics 124, 111-124.]Search in Google Scholar
[79. WANG S.H., CHENG C.Y., TANG P.C., CHEN C.F., CHEN H.H., LEE Y.P., HUANG S.Y., 2015 – Acute heat stress induces differential gene expressions in the testes of a broiler-type strain of Taiwan country chickens. PLoS One 10(5), p.e0125816.]Search in Google Scholar
[80. WANG Y., LIU Z., LI Z., SHI H., KANG Y., WANG J., HUANG J., JIANG L., 2016 – Effects of heat stress on respiratory burst, oxidative damage and SERPINH1 (HSP47) mRNA expression in rainbow trout Oncorhynchus mykiss. Fish physiology and Biochemistry 42, 701-710.]Search in Google Scholar
[81. WANG Y., METTE M.F., MIEDANER T., GOTTWALD M., WILDE P., REIF J.C., ZHAO Y., 2014 – The accuracy of prediction of genomic selection in elite hybrid rye populations surpasses the accuracy of marker-assisted selection and is equally augmented by multiple field evaluation locations and test years. BMC Genomics 15(1), 1-12.]Search in Google Scholar
[82. WELLS K.L., HADAD Y., BEN-AVRAHAM D., HILLEL J., CAHANER,A., HEADON D.J., 2012 – Genome-wide SNP scan of pooled DNA reveals nonsense mutation in FGF20 in the scaleless line of featherless chickens. BMC Genomics 13(1), 1-10.]Search in Google Scholar
[83. WOLC A., ARANGO J., SETTAR P., FULTON J.E., O’SULLIVAN N.P., DEKKERS J.C.M., 2019 – Genome wide association study for heat stress induced mortality in a white egg layer line. Poultry Science 98(1), 92-96.]Search in Google Scholar
[84. WOLF B.O., WALSBERG G.E., 2000 – The role of the plumage in heat transfer processes of birds. American Zoologist 40(4), 575-584.]Search in Google Scholar
[85. XIE J., TANG L., LU L., ZHANG L., XI L., LIU H.C., ODLE J., LUO X., 2014 – Differential expression of heat shock transcription factors and heat shock proteins after acute and chronic heat stress in laying chickens (Gallus gallus). PloS One 9(7), p.e102204.]Search in Google Scholar
[86. ZAHOOR I., MITCHELL M.A., HALL C.S., BEARD P.M., GOUS R.M., DE KONING D.J., HOCKING P.M., 2016. Predicted optimum ambient temperatures for broiler chickens to dissipate metabolic heat do not affect performance or improve breast muscle quality. British Poultry Science 57(1), 134-141.]Search in Google Scholar
[87. ZHANG J., MAROTEL M., FAUTEUX‐DANIEL S., MATHIEU A.L., VIEL S., MARÇAIS A., WALZER T., 2018 – T‐bet and Eomes govern differentiation and function of mouse and human NK cells and ILC1. European Journal of Immunology 48(5), 738-750.]Search in Google Scholar
[88. ZHANG X., BEURON F., FREEMONT P.S., 2002 – Machinery of protein folding and unfolding. Current Opinion in Structural Biology 12(2), 231-238.]Search in Google Scholar
[89. ZHOU T., LIU S., GENG X., JIN Y., JIANG C., BAO L., YAO J., ZHANG Y., ZHANG J., SUN L., WANG X., 2017 – GWAS analysis of QTL for enteric septicemia of catfish and their involved genes suggest evolutionary conservation of a molecular mechanism of disease resistance. Molecular Genetics and Genomics 292, 231-242.]Search in Google Scholar
[90. ZHOU W., NIELSEN J.B., FRITSCHE L.G., DEY R., GABRIELSEN M.E., WOLFORD B.N., LEFAIVE J., VANDEHAAR P., GAGLIANO S.A., GIFFORD A., BASTARACHE L.A., 2018 – Efficiently controlling for case-control imbalance and sample relatedness in large-scale genetic association studies. Nature Genetics 50(9), 1335-1341.]Search in Google Scholar
[91. ZHUANG Z.X., CHEN S.E., CHEN C.F., LIN E.C., HUANG S.Y., 2020 – Genomic regions and pathways associated with thermotolerance in layer-type strain Taiwan indigenous chickens. Journal of Thermal Biology 88, 102486.]Search in Google Scholar
[92. ZHUANG Z.X., CHEN S.E., CHEN C.F., LIN E.C., HUANG S.Y., 2019 – Genome-wide association study on the body temperature changes of a broiler-type strain Taiwan country chickens under acute heat stress. Journal of Thermal Biology 82, 33-42.]Search in Google Scholar