略阳乌鸡褐壳蛋壳颜色量化体系的建立和遗传基础分析

doi:10.3864/j.issn.0578-1752.2023.17.017

摘要/Abstract

摘要： 【背景】 褐壳蛋壳颜色与蛋壳强度、蛋内抗菌肽含量、血斑肉斑和孵化率有密切联系，是影响蛋品质和销售的一个重要的指标。然而，一些地方鸡因选育程度低，存在蛋色偏浅、均匀度差等不足，给鸡蛋的销售和品牌的打造造成不利影响。 【目的】 探讨以略阳乌鸡为对象，建立能灵敏度量蛋壳颜色变异的量化体系，估计品种特异性蛋壳颜色的遗传力，筛选参与蛋壳颜色调控的候选基因，为略阳乌鸡褐壳蛋壳颜色选育奠定理论基础。 【方法】 在略阳乌鸡蛋用系62个半同胞家系中选取841只母鸡，每只鸡收集3枚蛋，用L*a*b色度体系量化蛋壳颜色。在贝叶斯框架下，用马尔可夫链蒙特卡罗（Markov Chain Monte Carlo, MCMC）算法计算各色度指标的后验遗传力。用逆γ分布指定育种值和残差方差的先验分布。执行130 000迭代，弃去前30 000次迭代结果，按间隔100存储迭代结果，获得各方差组分的后验分布和各指标的后验遗传力。选取产浅褐壳、褐壳、浅绿壳的母鸡各8只，每只鸡收集3枚蛋用于蛋壳色素含量的测定。用原卟啉和胆绿素标准品建立浓度与吸光度值的回归关系，分别在670 nm和412 nm处测定胆绿素和原卟啉的吸光度，用回归法求得待测样本两种蛋壳色素的浓度。采集褐壳（n=8）和浅褐壳（n=8）母鸡的蛋壳腺，用qPCR法检测ALAS1和CPOX在蛋壳腺中的表达量。 【结果】 在3个色度指标中，a值递减的变化规律与褐色向绿色调过渡的视觉观感吻合度最高。L值和b值能够反映褐壳颜色深浅的变化，但在区分褐色和绿色调上存在较大误差。L值和b值分布呈现出较高的集中度，50%的样本的L值和b值集中分布于73.3—79.1和13.1—18.2之间，而a值分布更为分散，50%的样本分布于1.4—7.1之间。与上述分布特征保持一致，a值的变异系数88.2%要高于L值5.7%和b值24.0%。遗传力估计结果显示，a值主要受遗传效应调控（h²=0.77），而L值（h²=0.46）和b值（h²=0.37）受环境效应影响更大。在蛋壳色素和蛋壳颜色之间，原卟啉浓度与3个色度指标均存在强相关关系（L: r=-0.86，a: r=0.73, b: r=0.88），但胆绿素浓度仅与a值存在强负相关（r=-0.73）。ALAS1和CPOX是两个催化原卟啉前体物合成的酶。表达结果显示，CPOX在褐壳鸡中的表达水平是浅褐壳的1.5倍（P<0.05），但ALAS1的表达量无显著差异（P>0.05）。【结论】 原卟啉是影响略阳乌鸡蛋壳颜色的关键色素，而CPOX是与蛋壳原卟啉含量和褐壳颜色显著关联的候选基因。a值是量化略阳乌鸡蛋壳颜色准确度和灵敏度最高的指标，且具有较高的遗传力。对a值向上选择，有望在提高褐壳颜色深度和均匀度方面取得较大选择反应。

关键词: 略阳乌鸡, 蛋壳颜色, L*a*b色度空间, 遗传力, CPOX, ALAS1

Abstract:

【Background】 Brown eggshell color is closely relevant to eggshell strength, concentrations of egg white antimicrobial protein and yolk carotenoid, blood and meat spots, and hatchability, and is an important index affecting quality and sale of eggs. However, due to absence of selection for eggshell color, color of brown eggs that some indigenous breeds lay is light and highly variable, which has an adverse effect on sale of eggs and creation of egg brands. 【Objective】 The aims of this study are to establish a quantization method that could accurately and sensitively capture the variation of eggshell color, to estimate breed-specific heritability of eggshell color and to identify candidate genes associated with eggshell color in the Lüeyang black-boned chicken (LBC), so as to provide a theoretic basis for genetic improvement of LBC eggshell color. 【Method】 841 hens from 62 half-sibling families of LBC breeding population were selected. Three eggs were collected from each hen, and then the eggshell color was quantified using the L*a*b color space, and posterior heritabilities of L, a, and b values were estimated in a Bayesian framework using the Markov Chain Monte Carlo (MCMC) algorithm. The prior distributions of breeding value and residual variances were set using an inverse-Gamma distribution. MCMC performed 130 000 iterations, dropped 30 000 iterations at the beginning and stored one every 100 iterations to obtain posterior distributions of variance components and posterior heritability estimates of color indexes. Hens that laid light brown (n=8), brown (n=8) and light blue (n=8) eggs were selected from LBC population. Three eggs were collected from each hen for the measurement of eggshell pigment, and the absorbance values were measured at 670 nm for biliverdin and at 412 nm for protoporphyrin. The concentrations of protoporphyrin and biliverdin were calculated by regression equations, which were fitted using absorbances and concentrations of standard samples. Shell glands of brown- (n=8) and light brown-shelled (n=8) hens were collected. Expression levels of ALAS1 and CPOX in shell glands were detected using qPCR. 【Result】 Among three color indexes, a* value kept a high consistency with the change of eggshell color based on subjective perception as a* value generally decreased with transition of egg color from brown to green hues. L and b values could accurately reflect the change of egg color from light to dark brown, but L and b values were unable to discriminate between brown and green hues reliably. L and b values showed low variation as L and b values of 50% of samples were distributed between 73.3-79.1 and 13.1-18.2. In contrast, a* values were evenly distributed among the samples as a* values of 50% of samples ranged from 1.4 to 7.1. In line with the distribution characteristics, the coefficient of variation (88.2%) of a value was higher than ones of L (5.7%) and b (24.0%) values. Estimation results of heritability showed that a* value (h²=0.77) was predominately affected by genetic factors. In contrast, L (h²=0.46) and b (h²=0.37) values were controlled by environmental effect to larger extents. For the relationship of eggshell pigment and color, protoporphyrin concentration had a strong correlation with all of three color indexes (L: r=-0.86, a: r=0.73, b: r=0.88). But biliverdin concentration showed a strong (r=-0.73) negative correlation with a* value alone. ALAS1 and CPOX were two key enzymes that catalyze the biosynthensis of protoporphyrin precursors. Expression results showed that expression levels of CPOX in shell glands of brown-shelled chickens were 1.5-fold higher (P<0.05) than that in shell glands of light brown-shelled chickens. ALAS1 had no significant (P>0.05) difference between brown- and light brown-shelled chickens. 【Conclusion】 These results indicated that protoporphyrin was the key pigment affecting LBC eggshell color, and CPOX was a candidate associated with protoporphyrin concentration and color of brown eggs. The a* value was an optimal index quantifying eggshell color of LBC with high accuracy and sensitivity. In view of high heritability estimate of a* value, it was possible to increase brown hue and uniformity of LBC eggshell color via positive selection of a* value.

Key words: Lüeyang black-boned chicken, eggshell color, L*a*b color space, heritability, CPOX, ALAS1

陈球, 黄晶晶, 王哲鹏. 略阳乌鸡褐壳蛋壳颜色量化体系的建立和遗传基础分析[J]. 中国农业科学, 2023, 56(17): 3452-3460.

CHEN Qiu, HUANG JingJing, WANG ZhePeng. Establishment of Quantization Method and Genetic Basis Analysis of Brown Eggshell Color in the Lüeyang Black-Boned Chicken[J]. Scientia Agricultura Sinica, 2023, 56(17): 3452-3460.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2023.17.017

https://www.chinaagrisci.com/CN/Y2023/V56/I17/3452

图/表 5

图1

图2

图3

表1

图4

参考文献 36

[1]	SAMIULLAH S, ROBERTS J R, CHOUSALKAR K. Eggshell color in brown-egg laying hens - A review. Poultry Science, 2015, 94(10): 2566-2575. doi: 10.3382/ps/pev202 pmid: 26240390
[2]	ŞEKEROĞLU A, DUMAN M. Effect of egg shell colour of broiler parent stocks on hatching results, chickens performance, carcass characteristics, internal organ weights and some stress indicators. Kafkas Universitesi Veteriner Fakultesi Dergisi, 2011, 17(5):837-842.
[3]	JAV\U016FRKOVÁ V G, POKORNÁ M, MIKŠÍ K I, T\U016FMOVÁ E. Concentration of egg white antimicrobial and immunomodulatory proteins is related to eggshell pigmentation across traditional chicken breeds. Poultry Science, 2019, 98(12): 6931-6941. doi: 10.3382/ps/pez472 pmid: 31420680
[4]	DRABIK K, KARWOWSKA M, WENGERSKA K, PRÓCHNIAK T, ADAMCZUK A, BATKOWSKA J. The variability of quality traits of table eggs and eggshell mineral composition depending on hens' breed and eggshell color. Animals, 2021, 11(5): 1204. doi: 10.3390/ani11051204
[5]	CASSEY P, PORTUGAL S J, MAURER G, EWEN J G, BOULTON R L, HAUBER M E, BLACKBURN T M. Variability in avian eggshell colour: A comparative study of museum eggshells. PLoS ONE, 2010, 5(8): e12054. doi: 10.1371/journal.pone.0012054
[6]	SKRADE P D B, DINSMORE S J. Egg crypsis in a ground-nesting shorebird influences nest survival. Ecosphere, 2013, 4(12): 1-9.
[7]	LAHTI D C. Population differentiation and rapid evolution of egg color in accordance with solar radiation. The Auk, 2008, 125(4): 796-802. doi: 10.1525/auk.2008.125.issue-4
[8]	BAKKEN G S, VANDERBILT V C, BUTTEMER W A, DAWSON W R. Avian eggs: Thermoregulatory value of very high near-infrared reflectance. Science, 1978, 200(4339): 321-323. pmid: 17745564
[9]	GOSLER A G, HIGHAM J P, JAMES REYNOLDS S. Why are birds’ eggs speckled? Ecology Letters, 2005, 8(10): 1105-1113. doi: 10.1111/j.1461-0248.2005.00816.x
[10]	MORENO J, OSORNO J L. Avian egg colour and sexual selection: Does eggshell pigmentation reflect female condition and genetic quality? Ecology Letters, 2003, 6(9): 803-806. doi: 10.1046/j.1461-0248.2003.00505.x
[11]	LANG M R, WELLS J W. A review of eggshell pigmentation. World’s Poultry Science Journal, 1987, 43(3): 238-246. doi: 10.1079/WPS19870016
[12]	KENNEDY G Y, VEVERS H G. A survey of avian eggshell pigments. Comparative Biochemistry and Physiology Part B: Comparative Biochemistry, 1976, 55(1): 117-123. pmid: 947658
[13]	LU M Y, XU L, QI G H, ZHANG H J, QIU K, WANG J, WU S G. Mechanisms associated with the depigmentation of brown eggshells: A review. Poultry Science, 2021, 100(8): 101273. doi: 10.1016/j.psj.2021.101273
[14]	WANG Z P, QU L J, YAO J F, YANG X L, LI G Q, ZHANG Y Y, LI J Y, WANG X T, BAI J R, XU G Y, DENG X M, YANG N, WU C X. An EAV-HP insertion in 5' Flanking region of SLCO1B3 causes blue eggshell in the chicken. PLoS Genetics, 2013, 9(1): e1003183. doi: 10.1371/journal.pgen.1003183
[15]	CHEN L, GU X R, HUANG X T, LIU R, LI J X, HU Y Q, LI G Q, ZENG T, TIAN Y, HU X X, LU L Z, LI N. Two cis- regulatory snps upstream of ABCG2 synergistically cause the blue eggshell phenotype in the duck. Plos Genetics, 2020, 16(11): E1009119. doi: 10.1371/journal.pgen.1009119
[16]	SASAKI O, ODAWARA S, TAKAHASHI H, NIRASAWA K, OYAMADA Y, YAMAMOTO R, ISHII K, NAGAMINE Y, TAKEDA H, KOBAYASHI E, FURUKAWA T. Genetic mapping of quantitative trait loci affecting body weight, egg character and egg production in F₂ intercross chickens. Animal Genetics, 2004, 35(3): 188-194. doi: 10.1111/age.2004.35.issue-3
[17]	SCHREIWEIS M A, HESTER P Y, SETTAR P, MOODY D E. Identification of quantitative trait loci associated with egg quality, egg production, and body weight in an F₂ resource population of chickens1. Animal Genetics, 2006, 37(2): 106-112. doi: 10.1111/age.2006.37.issue-2
[18]	GOTO T, ISHIKAWA A, YOSHIDA M, GOTO N, UMINO T, NISHIBORI M, TSUDZUKI M. Quantitative trait loci mapping for external egg traits in F₂ chickens. The Journal of Poultry Science, 2014, 51(2): 118-129. doi: 10.2141/jpsa.0130100
[19]	LI G Q, CHEN S R, DUAN Z Y, QU L J, XU G Y, YANG N. Comparison of protoporphyrin IX content and related gene expression in the tissues of chickens laying brown-shelled eggs. Poultry Science, 2013, 92(12): 3120-3124. doi: 10.3382/ps.2013-03484 pmid: 24235220
[20]	LU M Y, WANG W W, QI G H, XU L, WANG J. Mitochondrial transcription factor A induces the declined mitochondrial biogenesis correlative with depigmentation of brown eggshell in aged laying hens. Poultry Science, 2021, 100(3): 100811. doi: 10.1016/j.psj.2020.10.065
[21]	ZHENG C W, LI Z S, YANG N, NING Z H. Quantitative expression of candidate genes affecting eggshell color. Animal Science Journal, 2014, 85(5): 506-510. doi: 10.1111/asj.12182 pmid: 24612318
[22]	SAMIULLAH S, ROBERTS J, WU S B. Downregulation of ALAS1 by nicarbazin treatment underlies the reduced synthesis of protoporphyrin IX in shell gland of laying hens. Scientific Reports, 2017, 7: 6253. doi: 10.1038/s41598-017-06527-y pmid: 28740143
[23]	HAN G P, KIM J M, KANG H K, KIL D Y. Transcriptomic analysis of the liver in aged laying hens with different intensity of brown eggshell color. Animal Bioscience, 2021, 34(5): 811-823. doi: 10.5713/ajas.20.0237
[24]	GUO J, WANG K H, QU L, DOU T C, MA M, SHEN M M, HU Y P. Genetic evaluation of eggshell color based on additive and dominance models in laying hens. Asian-Australasian Journal of Animal Sciences, 2020, 33(8): 1217-1223. doi: 10.5713/ajas.19.0345 pmid: 31480129
[25]	GOGER H, DEMIRTAS S E, YURTOGULLARI S. A selection study for improving eggshell colour in two parent lines of laying hens and their hybrids. Italian Journal of Animal Science, 2016, 15(3): 390-395. doi: 10.1080/1828051X.2016.1215232
[26]	CAVERO D, SCHMUTZ M, ICKEN W, PREISINGER R. Attractive eggshell color as a breeding goal. Lohmann Information, 2012, 47(2): 16-21.
[27]	KAMANLI S. Estimation of genetic parameters for some performance traits in a selected Barred Rock line. Ankara Üniversitesi Veteriner Fakültesi Dergisi, 2019, 66:391-396. doi: 10.33988/auvfd.575742
[28]	党李苹, 周雯馨, 刘瑞芳, 白云, 王哲鹏. 略阳乌鸡体重和产蛋数性状遗传参数估计. 中国农业科学, 2020, 53(17): 3620-3628. doi: 10.3864/j.issn.0578-1752.2020.17.018
	DANG L P, ZHOU W X, LIU R F, BAI Y, WANG Z P. Estimation of genetic parameters of body weight and egg number traits of Lueyang black-boned chicken. Scientia Agricultura Sinica, 2020, 53(17): 3620-3628. (in Chinese) doi: 10.3864/j.issn.0578-1752.2020.17.018
[29]	WILSON A J, RÉALE D, CLEMENTS M N, MORRISSEY M M, POSTMA E, WALLING C A, KRUUK L E B, NUSSEY D H. An ecologist’s guide to the animal model. The Journal of Animal Ecology, 2010, 79(1): 13-26. doi: 10.1111/jae.2009.79.issue-1
[30]	HADFIELD J D. MCMC methods for multi-response generalized linear mixed models: The MCMCglmm R Package. Journal of Statistical Software, 2010, 33(2): 1-22.
[31]	HADFIELD J D. MCMCglmm course notes. MCMCglmm R package. 2010. http://cran.r-project.org/web/packages/MCMCglmm/index.html.
[32]	WANG X T, ZHAO C J, LI J Y, XU G Y, LIAN L S, WU C X, DENG X M. Comparison of the total amount of eggshell pigments in Dongxiang brown-shelled eggs and Dongxiang blue-shelled eggs. Poultry Science, 2009, 88(8): 1735-1739. doi: 10.3382/ps.2008-00434 pmid: 19590090
[33]	HARRELL F E. Hmisc: Harrell Miscellaneous. R package version 4.5-0. 2021. https://CRAN.R-project.org/package=Hmisc.
[34]	LI G, XU J, CHEN S, TAN S, LI H. Pigment concentrations in eggshell and their related gene expressions in uterus of Changshun blue eggshell chickens. British Poultry Science, 2022, 63(3): 421-425. doi: 10.1080/00071668.2021.1983919
[35]	PUNNETT C. Genetic studies in poultry. Journal of Genetics, 1933, 27(3): 465-470. doi: 10.1007/BF02981757
[36]	ZENG L S, XU G Y, JIANG C Y, LI J Y, ZHENG J X. Research Note: Lab* color space for prediction of eggshell pigment content in differently colored eggs. Poultry Science, 2022, 101(8): 101942. doi: 10.1016/j.psj.2022.101942

性状 Trait	褐壳(n=8) Brown shell	浅褐壳 (n=8) Light brown shell	P值 P value
L值 L value	70.1±1.9	80.8±1.4	0.0004
a值 a value	8.0±0.7	0.5±0.2	<0.0001
b值 b value	20.5±0.6	7.8±0.5	<0.0001
原卟啉含量Protoporphyrin concentration (μg·g^-1)	17.8±1.5	4.2±1.0	<0.0001