Animal Molecular Breeding 2024, Vol.14, No.6 http://animalscipublisher.com/index.php/amb © 2024 AnimalSci Publisher, registered at the publishing platform that is operated by Sophia Publishing Group, founded in British Columbia of Canada. All Rights Reserved.
Animal Molecular Breeding 2024, Vol.14, No.6 http://animalscipublisher.com/index.php/amb © 2024 AnimalSci Publisher, registered at the publishing platform that is operated by Sophia Publishing Group, founded in British Columbia of Canada. All Rights Reserved. Publisher AnimalSci Publisher Editedby Editorial Team of Animal Molecular Breeding Email: edit@amb.animalscipublisher.com Website: http://animalscipublisher.com/index.php/amb Address: 11388 Stevenston Hwy, PO Box 96016, Richmond, V7A 5J5, British Columbia Canada Animal Molecular Breeding (ISSN 1927-5609) is an open access, peer reviewed journal published online by AnimalSci Publisher. The journal is publishing all the latest and outstanding research articles, letters and reviews in all areas of animal molecular breeding, containing transgenic breeding and marker assisted breeding, particularly publishing innovative research findings in the basic and applied fields of molecular genetics and novel techniques for improvement, applications of molecular enhanced products, as well as the significant evaluation of their related application field. AnimalSci Publisher is an international Open Access publisher specializing in animal molecular breeding, including genetics, breeding, as well as the related field registered at the publishing platform that is operated by Sophia Publishing Group (SPG), founded in British Columbia of Canada. All the articles published in Animal Molecular Breeding are Open Access, and are distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. AnimalSci Publisher uses CrossCheck service to identify academic plagiarism through the world’s leading plagiarism prevention tool, iParadigms, and to protect the original authors’ copyrights.
Animal Molecular Breeding (online), 2024, Vol. 14, No.4 ISSN 1927-5609 http://animalscipublisher.com/index.php/amb © 2024 AnimalSci Publisher, registered at the publishing platform that is operated by Sophia Publishing Group, founded in British Columbia of Canada. All Rights Reserved. Latest Content Quantitative Genetics in Livestock Breeding: Principles and Applications JueHuang Animal Molecular Breeding, 2024, Vol. 14, No. 4, 252-261 Gene Expression Profiles in Heat-Stressed Dairy Cattle Zhaolin Wang, Xiaofang Lin Animal Molecular Breeding, 2024, Vol. 14, No. 4, 262-270 Observation Analysis of Embryonic Development Genes in High Fertility Goat Breeds Jing He, Jun Li Animal Molecular Breeding, 2024, Vol. 14, No. 4, 271-279 Breeding for Hypoallergenic Traits in Cats: Genetic Insights TaoZhang Animal Molecular Breeding, 2024, Vol. 14, No. 4, 280-287 Behavioral Genetics in Companion Animals: Current Insights and Future Directions Wei Liu, Jia Xuan Animal Molecular Breeding, 2024, Vol. 14, No. 4, 288-296
Animal Molecular Breeding 2024, Vol.14, No.4, 252-261 http://animalscipublisher.com/index.php/amb 252 Review Article Open Access Quantitative Genetics in Livestock Breeding: Principles and Applications JueHuang Hangzhou Luohuashi Biotechnology Co., Ltd, Hangzhou, 310000, Zhejiang, China Corresponding email: 1298864817@qq.com Animal Molecular Breeding, 2024, Vol.14, No.4 doi: 10.5376/amb.2024.14.0026 Received: 02 May, 2024 Accepted: 20 Jun., 2024 Published: 05 Jul., 2024 Copyright © 2024 Huang, This is an open access article published under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Preferred citation for this article: Huang J., 2024, Quantitative genetics in livestock breeding: principles and applications, Animal Molecular Breeding, 14(4): 252-261 (doi: 10.5376/amb.2024.14.0026) Abstract This study explores the foundational principles of quantitative genetics, including Mendelian inheritance, polygenic traits, heritability, and genetic variance, and examines their practical applications in breeding programs. Key tools and methodologies, such as quantitative trait loci (QTL) mapping, genome-wide association studies (GWAS), and selection indices, are discussed in detail. Applications in enhancing productivity traits, improving health, and optimizing reproductive efficiency are highlighted, with a case study on dairy cattle breeding illustrating the economic and practical impacts of heritability and breeding value estimates. Emerging trends, including the integration of genomics, artificial intelligence, and CRISPR-based precision breeding, are addressed alongside challenges such as environmental interactions, ethical considerations, and the cost of advanced tools. The paper concludes by emphasizing the critical role of quantitative genetics in sustainable livestock breeding and advocating for continued research to address future challenges and opportunities. Keywords Quantitative genetics; Livestock breeding; QTL mapping; Genome-wide association studies; Heritability 1 Introduction Quantitative genetics is a branch of genetics that deals with the inheritance of traits that are determined by a large number of genes, each contributing a small effect, and are often influenced by environmental factors. These traits, known as quantitative traits, exhibit continuous variation and are typically measured on a numerical scale, such as body weight, milk yield, or egg production in livestock (Schmid and Bennewitz, 2017; Silva et al., 2017; Núñez-Torres and Almeida-Secaira, 2022). The scope of quantitative genetics extends to understanding the genetic architecture of these traits, predicting breeding values, and improving selection methods to enhance desirable traits in livestock populations (fHill, 2010; Rukundo et al., 2018). Quantitative genetics plays a crucial role in livestock breeding by providing the theoretical foundation and practical tools necessary for the genetic improvement of economically important traits. The application of quantitative genetics in livestock breeding involves the use of statistical models to predict breeding values, which are essential for selecting animals with superior genetic potential (Haley, 2002; Núñez-Torres and Almeida-Secaira, 2022). This field has significantly contributed to the efficiency of livestock production by enabling breeders to make informed decisions based on genetic data, thereby optimizing the genetic quality of livestock (Gautier, 2001; Jenko et al., 2015). Moreover, advancements in genome-wide association studies (GWAS) and genomic selection have further enhanced the ability to map and exploit quantitative trait loci (QTL) for improved breeding outcomes (Schmid and Bennewitz, 2017). This study attempts to elucidate the principles of quantitative genetics and their application in livestock breeding, discuss the importance of quantitative genetics in enhancing livestock production, and provide an overview of the latest advancements and methodologies in the field. By examining the integration of quantitative genetics with modern genomic tools, this study aims to provide insights into the future directions of livestock breeding programs and the potential for continued genetic improvement. 2 Theoretical Foundations of Quantitative Genetics 2.1 Mendelian principles underlying quantitative traits Quantitative traits in livestock are influenced by multiple genes, each contributing a small effect, which aligns with Mendelian principles of inheritance. These traits, such as body weight gain and milk production, exhibit
Animal Molecular Breeding 2024, Vol.14, No.4, 252-261 http://animalscipublisher.com/index.php/amb 253 continuous variability and are typically distributed normally due to the additive effects of numerous genes. The action of additive genes results in a phenotypic distribution that is intermediate between the parental populations, while multiplicative gene actions can create geometric series in trait expression (Núñez-Torres and Almeida-Secaira, 2022). Understanding these principles is crucial for developing effective breeding strategies that enhance economically important traits in livestock. 2.2 Polygenic inheritance and complex trait analysis Polygenic inheritance refers to the genetic architecture where multiple genes contribute to the expression of a single trait. In livestock, most economically significant traits are complex and influenced by numerous genetic and environmental factors. Genome-wide association studies (GWAS) have become a pivotal tool in identifying quantitative trait loci (QTL) that contribute to genetic variance in these traits. The use of dense SNP panels allows for the mapping of genes and mutations that affect these complex traits, providing insights into their genetic underpinnings and facilitating more precise selection in breeding programs (Schmid and Bennewitz, 2017; Singh et al., 2019; Bijma, 2021). 2.3 Concepts of heritability and genetic variance Heritability is a key concept in quantitative genetics, representing the proportion of phenotypic variance that can be attributed to genetic variance within a population. It is a critical factor in determining the potential for genetic improvement through selection. Genetic variance encompasses both additive and non-additive genetic effects, with additive variance being particularly important for selection as it directly contributes to the response to selection. Understanding the genetic variance and heritability of traits allows breeders to predict the outcomes of selection and optimize breeding strategies to enhance desirable traits in livestock populations (Figure 1) (Viana et al., 2016; Núñez-Torres and Almeida-Secaira, 2022; Kandel et al., 2023). In summary, the theoretical foundations of quantitative genetics in livestock breeding involve understanding Mendelian principles, polygenic inheritance, and the concepts of heritability and genetic variance. These principles guide the development of breeding strategies aimed at improving economically important traits through informed selection and genetic analysis. Figure 1 Schematic presentation of multiple ovulation embryo transfer in buffalo (Adopted from Kandel et al., 2023) 3 Tools and Methods in Quantitative Genetics 3.1 Quantitative trait loci (QTL) mapping Quantitative Trait Loci (QTL) mapping is a fundamental tool in quantitative genetics, used to identify genomic regions associated with the expression of quantitative traits. These loci may contain one or more genes that contribute to the trait's variance. QTL mapping typically involves analyzing biparental populations to detect associations between marker genotypes and trait phenotypes. Various methods, such as regression analysis,
Animal Molecular Breeding 2024, Vol.14, No.4, 252-261 http://animalscipublisher.com/index.php/amb 254 maximum likelihood estimation, and Bayesian models, are employed to identify QTLs. Single QTL mapping methods focus on detecting one QTL at a time, while multiple QTL mapping combines multiple regression analysis with interval mapping to include all significant QTLs in the genetic model. This approach can be extended to handle data from multiple cross populations and for joint analysis of multiple traits (Singh and Singh, 2015). Fine mapping of QTL regions is often achieved using homozygous lines derived from near-isogenic lines (NILs) and intercross recombinant inbred lines. Additionally, QTL meta-analysis integrates results from different studies to refine the number of QTLs affecting a trait and reduce confidence intervals (Halladakeri et al., 2023). 3.2 Genome-wide association studies (GWAS) Genome-Wide Association Studies (GWAS) have become a preferred method for mapping quantitative traits in livestock due to the availability of dense SNP panels. GWAS involves scanning the genome to identify SNPs associated with traits of interest. Different statistical models, including single-marker and Bayesian multi-marker models, are used in GWAS to account for nonadditive genetic effects and genotype-by-environment interactions (Schmid and Bennewitz, 2017). Multibreed GWAS can enhance mapping precision and power by leveraging conserved linkage disequilibrium across breeds, as demonstrated in dairy cattle studies. This approach can detect more QTLs compared to within-breed GWAS, especially when multiple populations are combined (Berg et al., 2016). GWAS results can be further refined through conditional analyses and fine mapping to identify significant SNPs and candidate genes (Li et al., 2020). 3.3 Selection indices and breeding values Selection indices and breeding values are critical tools in livestock breeding, enabling the selection of individuals with desirable genetic traits. These indices combine information from multiple traits to provide a comprehensive measure of an individual's genetic potential. Breeding values are estimated using statistical models that incorporate phenotypic and genotypic data, allowing breeders to predict the genetic merit of animals for specific traits. The integration of genomic data into selection indices has improved the accuracy of breeding value predictions, particularly for complex traits like fertility in dairy cattle (Ma et al., 2019). Genomic selection has stabilized and even reversed unfavorable trends in traits such as dairy fertility, demonstrating its effectiveness in modern breeding programs. In summary, QTL mapping, GWAS, and selection indices are essential tools in quantitative genetics, each contributing uniquely to the understanding and improvement of complex traits in livestock. These methods enable the identification of genetic loci, the prediction of breeding values, and the enhancement of breeding strategies through genomic selection. 4 Applications of Quantitative Genetics in Livestock Breeding 4.1 Enhancing productivity traits: milk, meat, and egg yield Quantitative genetics plays a crucial role in enhancing productivity traits such as milk, meat, and egg yield in livestock. These traits are typically quantitative, meaning they are influenced by multiple genes and environmental factors, leading to continuous variability in the population (Núñez-Torres and Almeida-Secaira, 2022). Techniques such as genome-wide association studies (GWAS) and marker-assisted selection (MAS) have been employed to identify and select for genes associated with these economically important traits (Khalil and Gonda, 2020). By understanding the genetic basis of these traits, breeders can make informed decisions to improve yield and efficiency in livestock production (Khatib and Gonda, 2015). 4.2 Improving health and disease resistance Quantitative genetics also contributes significantly to improving health and disease resistance in livestock. Although individual disease traits often have low heritability, the genetic variance for disease prevalence can be substantial due to indirect genetic effects. This implies that selection against infectious diseases can be more effective than previously thought. By integrating quantitative genetics with epidemiology, breeders can develop strategies to enhance disease resistance, thereby reducing the impact of pathogens on livestock (Bijma, 2021). Additionally, genome editing techniques, such as the promotion of alleles by genome editing (PAGE), offer potential for improving health traits by targeting specific quantitative trait nucleotides (QTN) (Jenko et al., 2015).
Animal Molecular Breeding 2024, Vol.14, No.4, 252-261 http://animalscipublisher.com/index.php/amb 255 4.3 Addressing reproductive efficiency Reproductive efficiency is another area where quantitative genetics is applied in livestock breeding. Traits related to reproduction, such as fertility and litter size, are complex and influenced by many genetic and environmental factors. By utilizing quantitative genetic principles, breeders can identify genetic markers associated with reproductive traits and select animals with superior breeding values (Viana et al., 2016; Schmid and Bennewitz, 2017). This approach helps in optimizing reproductive performance and increasing the overall productivity of livestock populations. Techniques like genomic selection, which uses SNP markers to predict breeding values, have shown promise in improving reproductive traits. In summary, quantitative genetics provides a framework for enhancing productivity, health, and reproductive efficiency in livestock breeding. By leveraging genetic information and advanced breeding techniques, breeders can achieve significant improvements in these key areas, ultimately leading to more efficient and sustainable livestock production systems. 5 Case Study: Application of Quantitative Genetics in Dairy Cattle Breeding 5.1 Background and significance of dairy cattle breeding Dairy cattle breeding has evolved significantly over the past century, driven by the need to improve milk production and adapt to changing environmental and market demands. Initially, the focus was on increasing milk yield, but over time, the breeding goals have expanded to include traits such as fertility, health, and longevity, reflecting a more balanced approach to breeding (Figure 2) (Miglior et al., 2017; Weigel et al., 2017). The advent of genomic technologies has revolutionized the field, allowing for more precise selection and faster genetic progress (Gutierrez-Reinoso et al., 2021; Ma and Lin, 2024). This shift is crucial for meeting the growing global demand for dairy products while ensuring the sustainability and welfare of dairy cattle. Figure 2 Recording of performance data for dairy cows then (1936, left panels) and now (2017, right panel) (Adopted from Weigel et al., 2017) 5.2 Use of heritability and breeding values in selecting high-yielding cows Heritability and breeding values are fundamental concepts in quantitative genetics, used extensively in dairy cattle breeding to select high-yielding cows. Heritability estimates the proportion of phenotypic variation in a trait that is attributable to genetic differences among individuals. Traits such as milk yield have moderate to high heritability, making them suitable targets for selection (Kadri et al., 2015; Brajković et al., 2024). Breeding values, which
Animal Molecular Breeding 2024, Vol.14, No.4, 252-261 http://animalscipublisher.com/index.php/amb 256 predict an animal's genetic potential, are calculated using pedigree and performance data, and more recently, genomic information (Weigel et al., 2017; Gutierrez-Reinoso et al., 2021; Gutierrez-Reinoso et al., 2021). The integration of genomic selection has enhanced the accuracy of breeding values, enabling the identification of superior animals for milk production and other economically important traits. 5.3 Economic and practical impacts of quantitative genetics in the dairy industry The application of quantitative genetics in dairy cattle breeding has had profound economic and practical impacts. By improving traits such as milk yield, health, and fertility, breeders have increased the productivity and profitability of dairy operations (Miglior et al., 2017; Weigel et al., 2017). Genomic selection has accelerated genetic gains, reduced generation intervals, and allowed for more efficient use of resources (Gutierrez-Reinoso et al., 2021). Additionally, the ability to select for disease resistance and adaptability to environmental stressors has improved animal welfare and reduced veterinary costs (König and May, 2019; Narayana et al., 2022). These advancements contribute to the sustainability of the dairy industry, ensuring it can meet future challenges and consumer demands. In summary, the application of quantitative genetics in dairy cattle breeding has transformed the industry, enhancing productivity, sustainability, and animal welfare through the use of advanced genetic selection techniques. 6 Advances and Emerging Trends in Quantitative Genetics 6.1 Integration of genomics and big data in breeding programs The integration of genomics and big data has revolutionized livestock breeding programs by enhancing the accuracy and efficiency of genetic selection. Genomic selection, which utilizes DNA sequencing and statistical algorithms, allows for the prediction of genomic breeding values, thereby accelerating genetic progress in complex traits such as growth and reproduction (Adebayo et al., 2024). The use of high-density SNP chips enables the selection of genetically superior animals at an early age with high accuracy, facilitating more precise breeding decisions (Singh et al., 2019). Additionally, the combination of genomic data with on-farm sensor data supports precision management, optimizing productivity and sustainability in modern dairy farms (Weigel et al., 2017). 6.2 Role of artificial intelligence and machine learning Artificial intelligence (AI) and machine learning (ML) are playing increasingly significant roles in livestock breeding by improving the analysis and interpretation of complex genetic data. These technologies have been integrated into genomic selection processes, enhancing the prediction accuracy of breeding values and enabling more informed selection decisions (Weigel et al., 2017). Machine learning algorithms, alongside traditional mixed linear models, are now part of the modern breeder's toolkit, offering new insights into genetic inheritance and epigenetic modifications. The application of AI and ML in breeding programs is expected to continue growing, providing innovative solutions to challenges in genetic selection and management (Adebayo et al., 2024). 6.3 CRISPR and gene editing for precision breeding CRISPR and other gene-editing technologies are emerging as powerful tools for precision breeding in livestock. These technologies allow for targeted modifications of specific genes, offering the potential to enhance desirable traits and eliminate undesirable ones with unprecedented precision. Gene editing can be used to knock out or over-express genes, providing deeper insights into gene functions and their impact on animal physiology (Khare and Khare, 2017). The application of CRISPR in livestock breeding holds promise for improving disease resistance, productivity, and overall animal welfare, marking a significant advancement in the field of quantitative genetics (Gutierrez-Reinoso et al., 2021). In summary, the integration of genomics and big data, the application of AI and ML, and the use of CRISPR for gene editing are key emerging trends in quantitative genetics. These advancements are transforming livestock breeding by enhancing genetic selection accuracy, enabling precision management, and offering new possibilities for genetic improvement.
Animal Molecular Breeding 2024, Vol.14, No.4, 252-261 http://animalscipublisher.com/index.php/amb 257 7 Challenges and Limitations 7.1 Complexity of traits and environmental interactions Quantitative traits in livestock are influenced by numerous genes and environmental factors, making their genetic mapping and improvement complex. The interaction between these genes and the environment can significantly affect the expression of traits, leading to challenges in predicting breeding outcomes accurately. Genome-wide association studies (GWAS) have been employed to map these traits, but the nonadditive genetic and genotype-by-environment effects add layers of complexity that are difficult to unravel (Núñez-Torres and Almeida-Secaira, 2022). Additionally, the heritability of traits, which is crucial for effective breeding, can be obscured by these interactions, complicating the development of breeding strategies (Núñez-Torres and Almeida-Secaira, 2022). 7.2 Ethical and regulatory issues in advanced breeding technologies The use of advanced molecular techniques, such as genome editing, raises ethical and regulatory concerns. While these technologies hold promise for improving quantitative traits, their application is often met with scrutiny regarding animal welfare and the potential long-term impacts on genetic diversity. The promotion of alleles through genome editing, for instance, can lead to increased inbreeding if not managed carefully, posing ethical dilemmas about the balance between genetic improvement and maintaining genetic diversity (Jenko et al., 2015). Regulatory frameworks are still evolving to address these issues, which can hinder the widespread adoption of such technologies (Kandel et al., 2023). 7.3 Accessibility and cost of genetic tools The accessibility and cost of genetic tools remain significant barriers, particularly in developing regions. While molecular breeding techniques offer substantial potential for genetic improvement, their implementation is often limited by the high costs associated with genotyping and the need for sophisticated infrastructure (Kandel et al., 2023). This disparity in access can lead to unequal advancements in livestock breeding across different regions, with underdeveloped areas lagging behind due to financial and technological constraints (Khare and Khare, 2017). Moreover, the cost of routinely recording phenotypes and the sacrifice of animals for certain traits further limit the progress achievable through conventional breeding methods (Su et al., 2018). In summary, the challenges in quantitative genetics for livestock breeding include the complexity of trait interactions, ethical and regulatory concerns surrounding advanced technologies, and the accessibility and cost of genetic tools. These factors collectively impact the efficiency and equity of breeding programs globally. 8 Future Directions 8.1 Expanding research on climate-resilient livestock breeds The increasing impact of climate change on livestock production necessitates the development of climate-resilient breeds. Genomic tools and statistical models, such as genome-wide association studies (GWAS), have been instrumental in identifying traits that contribute to climate resilience in dairy cattle, including heat tolerance and disease resistance (Silpa et al., 2021; Arya et al., 2024). Additionally, integrating enviromics and machine learning can enhance precision breeding by considering the complex interactions between genetics and environmental factors, thus improving the adaptability of beef cattle to diverse climates (Passamonti et al., 2021; Rosa et al., 2023). These approaches are crucial for sustaining livestock productivity in the face of changing environmental conditions. 8.2 Leveraging multi-omics approaches for improved genetic predictions Multi-omics approaches, which include genomics, transcriptomics, proteomics, and metabolomics, offer comprehensive insights into the genetic architecture of economically important traits in livestock. By integrating these diverse data types, researchers can improve the accuracy of genomic predictions for complex traits such as feed efficiency and meat quality (An et al., 2017; Diniz and Ward, 2021). The functional annotation of animal genomes (FAANG) project exemplifies efforts to enhance the functional understanding of livestock genomes, thereby facilitating more precise breeding strategies (Verardo et al., 2023). Continued development of statistical models that incorporate multi-omics data will be essential for advancing genetic predictions and improving livestock production efficiency.
Animal Molecular Breeding 2024, Vol.14, No.4, 252-261 http://animalscipublisher.com/index.php/amb 258 8.3 Enhancing collaboration between academia and industry Strengthening collaboration between academic institutions and the livestock industry is vital for translating research findings into practical breeding programs. Open-source breeding approaches, where public and private entities share data and align their activities, can enhance the efficiency of breeding pipelines and accelerate genetic gains (Covarrubias-Pazaran et al., 2021). Such collaborations can also foster the implementation of innovative breeding strategies, such as genomic selection and precision agriculture, to address challenges like climate change and disease resilience (An et al., 2017; Knap and Doeschl-Wilson, 2020). By leveraging shared resources and expertise, academia and industry can jointly develop solutions that meet the evolving demands of livestock production. In summary, future research in livestock breeding should focus on developing climate-resilient breeds, utilizing multi-omics approaches for better genetic predictions, and fostering collaboration between academia and industry. These strategies will be crucial for enhancing the sustainability and productivity of livestock systems in the face of global challenges. 9 Concluding Remarks Quantitative genetics plays a crucial role in livestock breeding by focusing on economically important traits such as body weight gain, milk, and meat production, which are characterized by continuous variability and are influenced by multiple genes and environmental factors. The application of genome-wide association studies (GWAS) and genome editing (GE) has advanced the understanding and improvement of these traits by identifying specific genes and mutations that contribute to genetic variance. Heritability remains a key factor in optimizing genetic quality, and various breeding methods, including panmixia, inbreeding, and heterosis, are employed to enhance selection processes. Additionally, the integration of molecular techniques, such as marker-assisted selection (MAS) and genomic selection (GS), has improved the efficiency of breeding programs by enabling direct selection on genes or genomic regions. Quantitative genetics is fundamental to sustainable livestock breeding as it provides the framework for understanding and manipulating the genetic architecture of complex traits. By leveraging quantitative genetic principles, breeders can enhance traits that are vital for economic productivity and sustainability, such as disease resistance and production efficiency. The use of quantitative genetics in conjunction with modern genomic tools allows for more precise selection and breeding strategies, which can lead to significant improvements in livestock performance and resilience. This approach not only supports the economic viability of livestock production but also contributes to environmental sustainability by optimizing resource use and reducing the ecological footprint of agricultural systems. Continued research and innovation in quantitative genetics are essential to address the evolving challenges in livestock breeding. There is a need for further exploration of genome editing techniques and their potential to enhance quantitative traits while managing inbreeding. Additionally, the development of more sophisticated statistical models and experimental designs for GWAS will improve the detection of nonadditive genetic effects and genotype-by-environment interactions. Collaborative efforts and open-source data management can accelerate genetic gains by facilitating the sharing of knowledge and resources among breeding programs. As the demand for food increases and climate change impacts production conditions, it is imperative to strengthen breeding pipelines with a focus on quantitative genetics to ensure the sustainability and resilience of livestock systems. Acknowledgments Author would like to express our gratitude to the two anonymous peer reviewers for their critical assessment and constructive suggestions on our manuscript. Conflict of Interest Disclosure Author affirms that this research was conducted without any commercial or financial relationships that could be construed as a potential conflict of interest.
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Animal Molecular Breeding 2024, Vol.14, No.4, 262-270 http://animalscipublisher.com/index.php/amb 262 Research Insight Open Access Gene Expression Profiles in Heat-Stressed Dairy Cattle Zhaolin Wang , Xiaofang Lin 1 Tropical Animal Medicine Research Center, Hainan Institute of Tropical Agricultural Resources, Sanya, 572000, Hainan, China Corresponding author: 745457309@qq.com Animal Molecular Breeding, 2024, Vol.14, No.4 doi: 10.5376/amb.2024.14.0027 Received: 16 May, 2024 Accepted: 01 Jul., 2024 Published: 17 Jul., 2024 Copyright © 2024 Wang and Lin, This is an open access article published under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Preferred citation for this article: Wang Z.L., and Lin X.F., 2024, Gene expression profiles in heat-stressed dairy cattle, Animal Molecular Breeding, 14(4): 262-270 (doi: 10.5376/amb.2024.14.0027) Abstract This study investigates the significance of epigenetic markers, such as DNA methylation, histone modifications, and non-coding RNAs, in regulating disease resistance in dogs. A comparative analysis of disease-resistant and susceptible dog breeds highlights key epigenetic differences, shedding light on potential applications for enhancing disease resistance. Despite the technical and ethical challenges associated with using epigenetic data in breeding, the study underscores the long-term potential of epigenetic profiling for disease prevention and health monitoring in dogs. By identifying specific epigenetic markers, this study provides a foundation for improving canine breeding programs and personalized veterinary medicine. Keywords Canine health; Epigenetics; Disease resistance; DNA methylation; Veterinary medicine 1 Introduction Disease resistance in dogs is a critical area of veterinary research, as it directly impacts the health and well-being of companion animals. Various pathogens, including bacteria, viruses, and parasites, pose significant threats to canine health, leading to conditions such as antimicrobial resistance and susceptibility to diseases like leishmaniasis and hookworm infections (Tyson et al., 2021). Understanding the genetic and immunological factors that contribute to disease resistance can help in developing effective strategies for disease prevention and management in dogs (Vasconcelos et al., 2017). Epigenetics, the study of heritable changes in gene expression that do not involve changes to the underlying DNA sequence, plays a crucial role in disease resistance (Wegener et al., 2018). Epigenetic mechanisms, such as DNA methylation, histone modification, and non-coding RNA regulation, can influence how genes are expressed in response to environmental factors, including pathogen exposure (Wang et al., 2023). These modifications can affect the immune response and the ability of dogs to resist infections, making the identification of epigenetic markers a promising area for enhancing disease resistance (Gul et al., 2022). Identifying epigenetic markers associated with disease resistance in dogs has significant implications for veterinary medicine (Ceric et al., 2019). These markers can serve as biomarkers for early detection of susceptibility to diseases, allowing for timely interventions and personalized treatment plans. Moreover, understanding the epigenetic landscape can lead to the development of novel therapeutic strategies that target specific epigenetic modifications to enhance disease resistance (Islam et al., 2020). This approach can reduce the reliance on antibiotics and other treatments, thereby mitigating the risk of antimicrobial resistance (Mahfouz et al., 2020). This study identifies and evaluates current knowledge on epigenetic markers of disease resistance in dogs, highlighting the potential of epigenetic research to improve canine health and disease management, including examining genetic and epigenetic factors, the role of specific epigenetic mechanisms, and the implications of these findings for veterinary practice and future research, with the aim of aiding further exploration of epigenetic regulation of disease resistance in dogs and developing targeted health interventions.
Animal Molecular Breeding 2024, Vol.14, No.4, 262-270 http://animalscipublisher.com/index.php/amb 263 2 Epigenetic Mechanisms in Disease Resistance 2.1 DNA methylation DNA methylation is a crucial epigenetic modification that involves the addition of a methyl group to the DNA molecule, typically at cytosine bases in CpG dinucleotides (Zhou et al., 2020). This process can regulate gene expression by altering the accessibility of the DNA to transcriptional machinery, thereby playing a significant role in genomic stability and disease resistance. For instance, DNA methylation-related long non-coding RNAs (lncRNAs) have been shown to modulate gene expression by interacting with chromosomal modifications or remodeling factors, which can impact the progression of diseases such as lower-grade gliomas (LGGs). Additionally, DNA methylation is a reversible modification, making it a potential target for therapeutic interventions in various diseases (Izquierdo and Crujeiras, 2019). 2.2 Histone modifications Histone modifications, including acetylation, methylation, phosphorylation, and ubiquitination, are another layer of epigenetic regulation that influences chromatin structure and gene expression. These modifications can either promote or repress transcription depending on the specific type and location of the modification. Histone deacetylation and methylation inhibitors have been approved for clinical use in treating hematological malignancies, highlighting their therapeutic potential (Begolli et al., 2019). Furthermore, lncRNAs have been found to interact with histone-modifying enzymes, thereby influencing histone modifications and contributing to disease resistance mechanisms (Gray et al., 2022). 2.3 Non-coding RNAs (miRNA, lncRNA) Non-coding RNAs, including microRNAs (miRNAs) and long non-coding RNAs (lncRNAs), play a pivotal role in the epigenetic regulation of gene expression. miRNAs are short non-coding RNAs that can silence gene expression post-transcriptionally, while lncRNAs can interact with chromatin and other epigenetic machinery to regulate gene expression. For example, miRNAs have been shown to be epigenetically regulated by DNA methylation and histone modifications, and their dysregulation is associated with various diseases, including cancers (Pathania et al., 2021). Similarly, lncRNAs are involved in a wide range of biological processes and can modulate gene expression through interactions with epigenetic regulators, contributing to disease resistance (Raei et al., 2021). 2.4 Interaction between epigenetics and genomic regulation The interaction between epigenetic mechanisms and genomic regulation is complex and involves multiple layers of control. Epigenetic modifications such as DNA methylation, histone modifications, and non-coding RNAs work in concert to regulate gene expression and maintain genomic stability. Disruption in these interactions can lead to disease progression and resistance to therapies. For instance, the crosstalk between lncRNAs and miRNAs has been shown to play a critical role in drug resistance in gastrointestinal cancers, highlighting the importance of understanding these interactions for developing effective therapeutic strategies5. Additionally, the integration of epigenetic and genomic data is essential for identifying novel biomarkers and therapeutic targets for disease resistance (Maimaiti et al., 2022). In summary, the study of epigenetic mechanisms, including DNA methylation, histone modifications, and non-coding RNAs, provides valuable insights into the regulation of gene expression and disease resistance. Understanding the intricate interactions between these mechanisms and genomic regulation is crucial for developing novel therapeutic approaches and improving clinical outcomes (Piletič and Kunej, 2016). 3 Current Research on Epigenetic Markers in Canine Health 3.1 Identified epigenetic markers for disease resistance Recent studies have identified several epigenetic markers that play a crucial role in disease resistance in dogs. For instance, the epigenetic regulation of the ABCB1 gene has been shown to be significant in determining the multidrug resistance (MDR) phenotype in canine lymphoid tumor cell lines (Tomiyasu et al., 2014). Specifically, differences in DNA methylation and histone H3 acetylation were observed between drug-sensitive and drug-resistant cell lines, indicating that these epigenetic modifications are associated with the MDR phenotype. Additionally, research on canine malignant lymphoma has highlighted the potential of histone deacetylases and
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