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Nucleotide variation in the ovine KRT31 promoter region and its association with variation in wool traits in Merino-cross lambs

Published online by Cambridge University Press:  10 June 2019

W. Chai ,
H. Zhou Open the ORCID record for H. Zhou [Opens in a new window] ,
H. Gong ,
J. Wang Open the ORCID record for J. Wang [Opens in a new window] ,
Y. Luo  and
J. G. H. Hickford
W. Chai
Affiliation:
Gene-Marker Laboratory, Faculty of Agricultural and Life Science, Lincoln University, Lincoln 7647, New Zealand International Wool Research Institute/Faculty of Animal Science and Technology, Gansu Agricultural University, Lanzhou 730070, China
H. Zhou
Affiliation:
Gene-Marker Laboratory, Faculty of Agricultural and Life Science, Lincoln University, Lincoln 7647, New Zealand International Wool Research Institute/Faculty of Animal Science and Technology, Gansu Agricultural University, Lanzhou 730070, China
H. Gong
Affiliation:
Gene-Marker Laboratory, Faculty of Agricultural and Life Science, Lincoln University, Lincoln 7647, New Zealand International Wool Research Institute/Faculty of Animal Science and Technology, Gansu Agricultural University, Lanzhou 730070, China
J. Wang
Affiliation:
International Wool Research Institute/Faculty of Animal Science and Technology, Gansu Agricultural University, Lanzhou 730070, China
Y. Luo
Affiliation:
International Wool Research Institute/Faculty of Animal Science and Technology, Gansu Agricultural University, Lanzhou 730070, China
J. G. H. Hickford*
Affiliation:
Gene-Marker Laboratory, Faculty of Agricultural and Life Science, Lincoln University, Lincoln 7647, New Zealand International Wool Research Institute/Faculty of Animal Science and Technology, Gansu Agricultural University, Lanzhou 730070, China
*
Author for correspondence: J. G. H. Hickford, E-mail: jon.hickford@lincoln.ac.nz
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Abstract

Keratins are the main structural proteins of wool fibres, and it is thought that variation in the keratins may affect wool fibre characteristics. Polymerase chain reaction-single stranded conformational polymorphism (PCR-SSCP) analyses were used to investigate four regions of the ovine keratin gene KRT31 including a portion of the promoter, the exon 1, exon 3 and exon 7 regions. Initially, in a screening panel of 300 New Zealand Romney, Merino and White Dorper sheep obtained from 26 farms, three, two, two and two PCR-SSCP banding patterns were observed for these four regions, respectively. The promoter region, the exon 1 and exon 3 regions contained two single nucleotide polymorphisms (SNPs) and the exon 7 region contained one SNP. The effect of the variation found in the promoter region on wool traits was subsequently investigated in 485 Southdown × Merino-cross lambs from seven sire-lines. The three variants identified in the original 300 sheep (named A, B and C) were observed with frequencies of 56, 29 and 15%, respectively. The presence of A and B had no significant effect on wool traits, but the presence of C was found to be associated with an increase in greasy fleece weight (GFW), clean fleece weight (CFW) and mean staple length (MSL). There was an effect of genotype on CFW and MSL, with BC sheep producing wool of higher CFW and MSL than AA, AB, AC and BB sheep. These results suggest that ovine KRT31 might be a useful candidate gene for improving wool traits.

Keywords

KRT31sheepvariationwool traits
Type
Animal Research Paper
Information
The Journal of Agricultural Science , Volume 157 , Issue 2 , March 2019 , pp. 182 - 188
Copyright
Copyright © Cambridge University Press 2019 

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References

Byun, SO, Fang, Q, Zhou, H and Hickford, JG (2009) An effective method for silver-staining DNA in large numbers of polyacrylamide gels. Analytical Biochemistry 385, 174175.Google Scholar
Fong, YW and Zhou, Q (2001) Stimulatory effect of splicing factors on transcriptional elongation. Nature 414, 929933.Google Scholar
Furger, A, O'Sullivan, JM, Binnie, A, Lee, BA and Proudfoot, NJ (2002) Promoter proximal splice sites enhance transcription. Genes & Development 16, 27922799.Google Scholar
Gong, H, Zhou, H, Yu, Z, Dyer, J, Plowman, JE and Hickford, JGH (2011) Identification of the ovine keratin-associated protein KAP1-2 gene (KRTAP1-2). Experimental Dermatology 20, 815819.Google Scholar
Gong, H, Zhou, H, Hodge, S, Dyer, JM and Hickford, JGH (2015) Association of wool traits with variation in the ovine KAP1-2 gene in Merino cross lambs. Small Ruminant Research 124, 2429.Google Scholar
Gong, H, Zhou, H, Forrest, RHJ, Li, S, Wang, J, Dyer, JM, Luo, Y and Hickford, JGH (2016) Wool keratin-associated protein genes in sheep - a review. Genes 7, article number 24. doi: 10.3390/genes7060024.Google Scholar
Hediger, R, Ansari, HA and Stranzinger, GF (1991) Chromosome banding and gene localizations support extensive conservation of chromosome structure between cattle and sheep. Cytogenetics & Cell Genetics 57, 127134.Google Scholar
Heid, HW, Werner, E and Franke, WW (1986) The complement of native α-keratin polypeptides of hair-forming cells: a subset of eight polypeptides that differ from epithelial cytokeratins. Differentiation 32, 101119.Google Scholar
Heid, HW, Moll, I and Franke, WW (1988) Patterns of expression of trichocytic and epithelial cytokeratins in mammalian tissues. I. Human and bovine hair follicles. Differentiation 37, 137157.Google Scholar
Itenge-Mweza, TO, Forrest, RH, McKenzie, GW, Hogan, A, Abbott, J, Amoafo, O and Hickford, JGH (2007) Polymorphism of the KAP1.1, KAP1.3 and K33 genes in Merino sheep. Molecular and Cellular Probes 21, 338342.Google Scholar
Itenge, TO, Hickford, JGH, Forrest, RH, McKenzie, GW and Frampton, CM (2010) Association of variation in the ovine KAP1.1, KAP1.3 and K33 genes with wool traits. International Journal of Sheep and Wool Science 58, 119.Google Scholar
Kimchi-Sarfaty, C, Oh, JM, Kim, IW, Sauna, ZE, Calcagno, AM, Ambudkar, SV and Gottesman, MM (2007) A “silent” polymorphism in the MDR1 gene changes substrate specificity. Science 315, 525528.Google Scholar
Kwek, KY, Murphy, S, Furger, A, Thomas, B, O'Gorman, W, Kimura, H, Proudfoot, NJ and Akoulitchev, A (2002) U1 snRNA associates with TFIIH and regulates transcriptional initiation. Nature Structural Biology 9, 800805.Google Scholar
Liu, Y, Lyle, S, Yang, Z and Cotsarelis, G (2003) Keratin 15 promoter targets putative epithelial stem cells in the hair follicle bulge. Journal of Investigative Dermatology 121, 963968.Google Scholar
Lynch, MH, O'Guin, WM, Hardy, C, Mak, L and Sun, TT (1986) Acidic and basic hair/nail (“hard”) keratins: their colocalization in upper cortical and cuticle cells of the human hair follicle and their relationship to “soft” keratins. Journal of Cell Biology 103, 25932606.Google Scholar
Mortimer, S, Taylor, P and Atkins, K (2006) The Trangie QPLU$ selection lines: responses in clean fleece weight and fibre diameter on completion of ten rounds of selection. In Pope, CE (ed.) Trangie QPLU$ Merinos – Open Day 2006. Proceedings of the Trangie QPLU$ Open Day. Orange, Australia: NSW DPI, pp. 711.Google Scholar
Parsons, YM, Piper, LR and Cooper, DW (1994) Linkage relationships between keratin-associated protein (KRTAP) genes and growth hormone in sheep. Genomics 20, 500502.Google Scholar
Popescu, C and Höcker, H (2007) Hair - the most sophisticated biological composite material. Chemical Society Reviews 36, 12821291.Google Scholar
Rogers, GR, Hickford, JGH and Bickerstaffe, R (1993) Mspi RFLP in the gene for a type I intermediate filament wool keratin. Animal Genetics 24, 218.Google Scholar
Rogers, GR, Hickford, JGH and Bickerstaffe, R (1994) A potential QTL for wool strength located on ovine chromosome 11. Proceedings of the 5th World Congress on Genetics Applied to Livestock Production 21, 291294.Google Scholar
Roldan, DL, Dodero, AM, Bidinost, F, Taddeo, HR, Allain, D, Poli, MA and Elsen, JM (2010) Merino sheep: a further look at quantitative trait loci for wool production. Animal: An International Journal of Animal Bioscience 4, 13301340.Google Scholar
Sumner, RMW, Forrest, RHJ, Zhou, H, Henderson, HV and Hickford, JGH (2013) Association of the KRT33A (formerly KRT1.2) gene with live-weight and wool characteristics in yearing Perendale sheep. Proceedings of the New Zealand Society of Animal Production 73, 158164.Google Scholar
Tran, HTT, Takeshima, Y, Surono, A, Yagi, M, Wada, H and Matsuo, M (2005) A G-to-A transition at the fifth position of intron-32 of the dystrophin gene inactivates a splice-donor site both in vivo and in vitro. Molecular Genetics & Metabolism 85, 213219.Google Scholar
Yu, Z, Gordon, SW, Nixon, AJ, Bawden, CS, Rogers, MA, Wildermoth, JE, Maqbool, NJ and Pearson, AJ (2009) Expression patterns of keratin intermediate filament and keratin associated protein genes in wool follicles. Differentiation 77, 307316.Google Scholar
Zhou, H, Hickford, JGH and Fang, Q (2006) A two-step procedure for extracting genomic DNA from dried blood spots on filter paper for polymerase chain reaction amplification. Analytical Biochemistry 354, 159161.Google Scholar