References

vavilov

Вавиловский журнал генетики и селекции

Vavilov Journal of Genetics and Breeding

2500-3259

Institute of Cytology and Genetics of Siberian Branch of the RAS

10.18699/VJ19.499

vavilov-2027

Research Article

Генетика животных

Animal genetics

Молекулярно-генетические основы формирования окраски оперения у кур

Molecular-genetic bases of plumage coloring in chicken

https://orcid.org/0000-0002-3281-4581

Макарова

А. В.

Makarova

A. V.

https://orcid.org/0000-0003-4702-2736

Митрофанова

О. В.

Mitrofanova

O. V.

https://orcid.org/0000-0001-5166-979X

Вахрамеев

А. Б.

Vakhrameev

A. B.

https://orcid.org/0000-0003-0210-9344

Дементьева

Н. В.

Dementeva

N. V.

dementevan@mail.ru

Всероссийский научно-исследовательский институт генетики и разведения сельскохозяйственных животных – филиал Федерального научного центра животноводства – ВИЖ им. академика Л.К. ЭрнстаРоссияRussian Research Institute of Farm Animal Genetics and Breeding – Branch of the L.K. Ernst Federal Science Center for Animal HusbandryRussian Federation

2019

14052019

233343354

2019

Макарова А.В., Митрофанова О.В., Вахрамеев А.Б., Дементьева Н.В.

Makarova A.V., Mitrofanova O.V., Vakhrameev A.B., Dementeva N.V.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://vavilov.elpub.ru/jour/article/view/2027

Окраска оперения – важный признак у птиц, нередко определяющий принадлежность к тому или иному виду или породе. Окраска является результатом действия веществ, которые поглощают определенную длину волны и формируют так называемые пигментные цвета, и оптическим эффектом, обусловленным интерференцией света, отраженного биологическими микроструктурами пера. Основой для формирования окраски служит синтез меланина. Эумеланин ответственен за черные и коричневые оттенки, а феомеланин отвечает за красновато-коричневые оттенки. Молекулярно-генетический механизм появления того или иного типа окраски еще до конца не изучен, поскольку на один и тот же признак могут влиять несколько генов. Первичная пигментация оперения определяется взаимодействием полиморфных вариантов гена MC1R и генов, участвующих в регуляции меланогенеза. Гены-модификаторы вызывают изменение окраски любого генотипа по локусу E и могут как уменьшать или увеличивать экспрес сию эумеланина, так и разрушать меланоциты. Вторичная пигментация оперения определяется белыми пятнами или специфическим распределением эумеланина на отдельных перьях. Современные методы анализа ДНК, такие как секвенирование, полногеномный анализ с использованием чипов различной плотности, анализ экспрессии генов, позволяют получать новые данные о генах, определяющих окраску оперения.

The color of plumage in birds is an important feature, often determining descent to a particular species or breed. It serves as a key factor in the interaction of birds with each other due to their well-developed visual perception of the surrounding world. In poultry including chickens, the color of the plumage can be treated as a genetic marker, useful for identifying breeds, populations and breeding groups with their specific traits. The origin of diverse color plumage is the result of two interrelated physical processes, chemical and optical, due to which pigment and structural colors in the color are formed. The pigment melanin, which is presented in two forms, eumelanin and pheomelanin, is widely spread in birds. The basis for the formation of melanin is the aromatic amino acid tyrosine. The process of melano-genesis involves many loci, part of the complex expression of plumage color genes. In birds, the solid black color locus encodes the melanocortin 1 receptor (MC1R), mutations in which lead to a change in receptor activation and form different variants of the E locus. Using the GWAS analysis, possible genes affecting the formation of color in chickens were detected. The biosynthesis and types of melanin are affected by the activity of the enzyme tyrosine, and mutations in the tyrosinase gene (TYR) cause albinism in different species. The formation mechanism of brown, silver, gold, lavender and a number of other shades is determined by the influence on the work of the MC1R genes and TYR specific modifier genes. Thus, locus I currently associated with the PMEL17 gene inhibits the expression of eumelanin, and the MLPH gene affects tyrosinase function. Research on the mechanisms of formation of the secondary coloring of plumage in chickens is being actively conducted nowadays. The formation of a marble feather pattern is associated with the mutation of the endothelin B2 receptor (EDNRB2), in the coding part of the gene of which a polymorphism is found associated with the mo locus. The molecular base that causes the feather banding (locus B and autosomal recessive banding) is identified. Today, only some genes that determine the color of the plumage of chickens are studied and described. Different genes can produce similar plumage patterns, and different phenotypes can be determined by the polymorphism of a single gene. Using molecular methods, you can more accurately identify these differences. This overview shows the nature of melanin coloration in birds using the example of chickens of various breeds and also attempts to systematize knowledge about the molecular-genetic mechanisms of the appearance of various types of coloration.

Gallus domesticusкурыокраска оперениягенылокусэкспрессиямаркеры

chickenscoloring plumagegeneslocusexpressionmarkers

The study is supported by the state assignment program AAAA-A18-118021590129-9.

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The authors declare that there are no conflicts of interest present.