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相关概念视频

Background and Environment Affect Phenotype02:27

Background and Environment Affect Phenotype

6.4K
Although the genetic makeup of an organism plays a major role in determining the phenotype, there are also several environmental factors, such as temperature, oxygen availability, presence of mutagens, that can alter an organism’s phenotype.
An example of how genetic background affects phenotype can be seen in horses. The Extension gene in horses is responsible for their coat color. A wild-type gene (EE) produces black pigment in the coat, while a mutant gene (ee) produces red pigment. A...
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Epistasis01:39

Epistasis

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In addition to multiple alleles at the same locus influencing traits, numerous genes or alleles at different locations may interact and influence phenotypes in a phenomenon called epistasis. For example, rabbit fur can be black or brown depending on whether the animal is homozygous dominant or heterozygous at a TYRP1 locus. However, if the rabbit is also homozygous recessive at a locus on the tyrosinase gene (TYR), it will have an unshaded coat that appears white, regardless of its TYRP1...
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Complementation Tests00:49

Complementation Tests

4.8K
A complementation test is a simple cross to identify whether the two mutations are located on the same gene or different genes. It was first performed by Edward Lewis in the 1940s while working on fruit flies. He developed the test to identify the location and arrangement of different mutations on chromosomes.
Organisms heterozygous for different mutations are crossed pairwise in all combinations. If present on different genes, the mutations can complement each other by providing the missing...
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Epistasis Analysis01:09

Epistasis Analysis

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Although Mendel chose seven unrelated traits in peas to study gene segregation, most traits involve multiple gene interactions that create a spectrum of phenotypes. When the interaction of various genes or alleles at different locations influences a phenotype, this is called epistasis. Epistasis often involves one gene masking or interfering with the expression of another (antagonistic epistasis). Epistasis often occurs when different genes are part of the same biochemical pathway. The...
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相关实验视频

Updated: May 9, 2025

Probing the Limits of Egg Recognition Using Egg Rejection Experiments Along Phenotypic Gradients
07:34

Probing the Limits of Egg Recognition Using Egg Rejection Experiments Along Phenotypic Gradients

Published on: August 22, 2018

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基于转录组的分析揭示了子蛋颜色和蛋强度之间的关系.

Longxin Wang1,2, Hehe Liu3, Simeng Yu1

  • 1Chinese Academy of Agricultural Sciences, Institute of Animal Science, Beijin, China.

BMC genomics
|April 28, 2025
PubMed
概括
此摘要是机器生成的。

绿的蛋具有更强大的蛋,这是由于肝脏和蛋腺体中基因表达的增强. 发现的关键基因调节蛋的颜色和强度,影响比利韦丁沉积和抗氧化能力.

关键词:
比利维尔丁 (Biliverdin) 是一个名字.蛋的颜色是蛋的颜色.蛋的强度是什么肝脏 肝脏 肝脏 肝脏在WGCNA中,WGCNA是WGCNA.

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Mechanical Separation and Protein Solubilization of the Outer and Inner Perivitelline Sublayers from Hen's Eggs
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Mechanical Separation and Protein Solubilization of the Outer and Inner Perivitelline Sublayers from Hen's Eggs

Published on: January 27, 2021

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Processing Embryo, Eggshell, and Fungal Culture for Scanning Electron Microscopy
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Processing Embryo, Eggshell, and Fungal Culture for Scanning Electron Microscopy

Published on: August 16, 2019

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相关实验视频

Last Updated: May 9, 2025

Probing the Limits of Egg Recognition Using Egg Rejection Experiments Along Phenotypic Gradients
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Probing the Limits of Egg Recognition Using Egg Rejection Experiments Along Phenotypic Gradients

Published on: August 22, 2018

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Mechanical Separation and Protein Solubilization of the Outer and Inner Perivitelline Sublayers from Hen's Eggs
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Mechanical Separation and Protein Solubilization of the Outer and Inner Perivitelline Sublayers from Hen's Eggs

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Processing Embryo, Eggshell, and Fungal Culture for Scanning Electron Microscopy
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Processing Embryo, Eggshell, and Fungal Culture for Scanning Electron Microscopy

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科学领域:

  • 动物科学动物科学
  • 基因组学就是基因组学.
  • 生物化学 生化学

背景情况:

  • 蛋的强度对于工业应用至关重要.
  • 蛋的颜色通常与蛋的强度相关.

研究的目的:

  • 为了研究绿的子中优越的蛋强度的遗传基础.
  • 确定关键的基因和调节蛋颜色和强度的途径.

主要方法:

  • 用RNA测序 (RNA-Seq) 来分析蛋腺体和肝脏组织的mRNA转录组.
  • 权重基因共同表达网络分析 (WGCNA) 来构建基因表达网络.
  • 在两种组织中识别关键调节基因.

主要成果:

  • 绿贝的蛋的蛋强度明显高于白贝的蛋.
  • 与离子运输,跨膜运输和肝细胞增殖相关的基因在绿的子中被上调.
  • 特定的关键基因 (例如,FKBP10,PPARG,MAP3K5,PHLDA1,FLT3,CACNB4) 被确定为关键的调节者.

结论:

  • 确定了调节蛋颜色 (ESB) 和蛋强度 (ESS) 的关键基因.
  • 提出这些基因调节抗氧化能力和胆酸合成,增强 Biliverdin 沉积和外强度.
  • 特定基因组的升级支持绿色的子中卵强度的提高.