Award details

Integrating genomics and transcriptomics to empower dairy breeding for feed efficient animals

ReferenceBB/X009505/1
Principal Investigator / Supervisor Dr Bingjie Li
Co-Investigators /
Co-Supervisors
Institution SRUC
DepartmentResearch
Funding typeResearch
Value (£) 346,974
StatusCurrent
TypeResearch Grant
Start date 20/03/2023
End date 19/03/2026
Duration36 months

Abstract

Feed efficiency (FE) is a complex trait in dairy animals and is highly linked to dairy production and Agricultural Net Zero. We recently developed and published pioneering methods to integrate population-level genomic and transcriptomic data for understanding genetics of animal complex traits. Based on a 50-year database on dairy FE, the overall aim of the project is to develop and apply the methods into dissecting the genetic basis of dairy FE through integrating population-level phenotypic, genomic, and transcriptomic data, which can be exploited to empower sustainable dairy breeding for feed efficient animals. The project builds on SRUC's award-winning Dairy Research Centre with 50-year recording on dairy FE. To achieve the overall aim, three work packages (WP) will be conducted: (i) WP1: We will generate whole-genome sequencing (WGS) data for representative animals in the study population to facilitate genotype imputation to sequence-level genotypes. We will conduct association analyses to characterize the genomic variants associated with FE using sequence-level genotypes; (ii) WP2: We will obtain transcriptomic profiles for 200 animals in the study population by RNA-seq of blood samples. Animals' transcriptomic profiles will be integrated with genomic data and FE phenotypes to identify the regulatory variants of the cattle genome that express functional significance to FE; (iii) WP3: We will apply the acquired genomic and regulatory variants from WP1 and WP2 into genomic prediction for FE. Research outcome has important scientific, economic, and social impact. The project provides novel knowledge of genomic and regulatory variants underlying FE. The project will facilitate at least 1% extra genetic progress for UK dairy breeding, worth millions of pounds per year for the industry. Research outcome delivers social impact in realizing Agricultural Net Zero and is highly relevant to BBSRC's strategic priorities in bioscience for sustainable agriculture.

Summary

Integrating genomics and transcriptomics to empower dairy breeding for feed efficient animals Improving feed efficiency (FE) of dairy cattle has been a major interest for animal scientists and dairy farmers over decades. Feed efficiency is a complex trait in dairy cattle and is highly linked to milk yield and methane emission in dairy production. Improving FE of dairy cattle will increase profits of dairy farmers and reduce methane emissions of UK dairy population. Including FE into genetic improvement scheme is one of the top priorities in the UK dairy breeding now. The overall aim of the proposal is to understand the genetic basis of dairy feed efficiency through integrating population-level phenotypic, genomic, and transcriptomic data, which will be exploited to empower dairy breeding for feed efficient and environmentally-friendly animals. The project builds on SRUC's award-wining Dairy Research Centre (Queen's Anniversary Prize) with 50-year data recording on dairy feed efficiency on a population level. We will apply new methods we recently published on Nature Genetics to this data, to fully utilize and integrate animals' genomic and transcriptomic profiles into understanding genetics of feed efficiency. To achieve the overall aim of the project, we will: (i) Identify cattle genes and genomic regions that are associated with FE using population-level phenotypic and genomic data; (ii) Characterize the genes and variants of the cattle genome whose expression is important to FE using genomic and RNA-sequencing information; (iii) Develop methods and apply the newly acquired genomic and regulatory variants to enhance genomic selection for FE in dairy breeding. The proposed project builds on SRUC's award-winning Dairy Research Centre with 50-year dairy recording on feed intake, milk production and composition, body weight (BW) and condition, health status, and reproductive events per animal. Three work packages (WP) will be conducted: (i) WP1: We will generatewhole genome-sequencing (WGS) data for 40 representative animals in the study population, plus WGS data we previously sequenced or obtained from publicly-available database. We will use these sequence data to facilitate genotype imputation to obtain sequence-level genotypes in the study population. We will conduct association analyses to identify genes and regions associated with FE using sequence-level genotypes. (ii) WP2: We will obtain RNA-sequencing for 200 animals in the study population from blood samples. Animals' transcriptomic profiles will be integrated with their genomic data and FE phenotypes to identify regulatory variants associated with FE. (iii) WP3: We will apply the newly acquired genomic and regulatory variants from WP1 and WP2 into genomic prediction for FE, to develop and assess methods of genomic prediction for FE using the functional variants. The present project will facilitate improved FE and reduced methane emission in the dairy population, highly relevant to BBSRC's strategic priorities in bioscience for sustainable agriculture and priority areas in data-driven biology. This project has extremely important scientific, economic, and social impact on understanding complex trait of feed efficiency, increasing profits of farmers and dairy industry, and mitigating methane emissions of UK dairy population. The project uses high-quality data and innovative methods to provide the scientific community a role model of integrating population-level omics data into genetic research for complex traits in animals and plants. The research outcome will have great potential to be applied to the UK national genetic improvement programs of dairy cattle. The research outcome will facilitate at least 1% extra genetic progress for UK dairy breeding, worth millions of pounds per year for the UK dairy industry.
Committee Research Committee C (Genes, development and STEM approaches to biology)
Research TopicsX – not assigned to a current Research Topic
Research PriorityX – Research Priority information not available
Research Initiative X - not in an Initiative
Funding SchemeX – not Funded via a specific Funding Scheme
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