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Modern animal breeding programs are largely based on biotechnological procedures, including AI and embryo transfer technology. Recent breakthroughs in reproductive technologies, such as somatic cell nuclear transfer and in vitro embryo production, and their combination with the emerging molecular genetic tools, will further advance progress and provide new opportunities for livestock breeding. This is urgently needed in light of the global challenges such as the ever-increasing human population, the limited resources of arable land, and the urgent environmental problems associated with farm animal production. Here, we focus on genomic breeding strategies and transgenic approaches for making farm animals more feed efficient. Based on studies in the mouse and rat model, we have identified a panel of genes that are critically involved in the regulation of feed uptake and that could contribute toward future breeding of farm animals with reduced environmental impact. We anticipate that genetically modified animals will play a significant role in shaping the future of feed-efficient and thus sustainable animal production, but will develop more slowly than the biomedical applications because of the complexity of the regulation of feed intake and metabolism. 相似文献
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精原干细胞介导法制备转基因动物是用试验导入的方法将外源基因移入动物细胞并整合到其基因组中,伴随着精原干细胞分化成精子,通过受精最终使外源基因得以表达。近年来,随着对精原干细胞研究的不断深入,人们发现其在建立转基因动物方面具有巨大的应用潜力和优势。作者从精原干细胞的生物学特性及携带外源基因的原理等方面阐述了其应用于转基因动物制备的理论机制,同时介绍了精原干细胞介导法在制备转基因动物方面,特别是转基因羊生产中的应用现状。 相似文献
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猪具有独特的生物学特征,在畜牧业生产和医学研究中占有重要地位。全基因组测序即de novo测序和全基因组重测序为解释猪的生物学特性和促进猪的分子育种发挥了重要作用。本文重点阐述全基因组测序在猪基因组学研究中的应用,分析全基因组测序技术及其在猪的全基因组测序工作中的优势和不足,并对未来猪的分子遗传育种研究工作进行展望。 相似文献
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VN Meyers-Wallen 《Reproduction in domestic animals》2003,38(1):73-76
There is an ongoing revolution in medicine that is changing the way that veterinarians will be counselling clients regarding inherited disorders. Clinical applications will emerge rapidly in veterinary medicine as we obtain new information from canine and comparative genome projects ( Meyers‐Wallen 2001 : Relevance of the canine genome project to veterinary medical practice. International Veterinary Information Service, New York). The canine genome project is described by three events: mapping markers on canine chromosomes, mapping gene locations on canine chromosomes ( Breen et al. 2001 : Genome Res. 11, 1784–1795), and obtaining the nucleotide sequence of the entire canine genome. Information from such research has provided a few DNA tests for single gene mutations [ Aguirre 2000 : DNA testing for inherited canine diseases. In: Bonagura, J (ed), Current Veterinary Therapy XIII. Philadelphia WB Saunders Co, 909–913]. Eventually it will lead to testing of thousands of genes at a time and production of DNA profiles on individual animals. The DNA profile of each dog could be screened for all known genetic disease and will be useful in counselling breeders. As part of the pre‐breeding examination, DNA profiles of prospective parents could be compared, and the probability of offspring being affected with genetic disorders or inheriting desirable traits could be calculated. Once we can examine thousands of genes of individuals easily, we have powerful tools to reduce the frequency of, or eliminate, deleterious genes from a population. When we understand polygenic inheritance, we can potentially eliminate whole groups of deleterious genes from populations. The effect of such selection on a widespread basis within a breed could rapidly improve health within a few generations. However, until we have enough information on gene interaction, we will not know whether some of these genes have other functions that we wish to retain. And, other population effects should not be ignored. At least initially it may be best to use this new genetic information to avoid mating combinations that we know will produce affected animals, rather than to eliminate whole groups of genes from a population. This is particularly important for breeds with small gene pools, where it is difficult to maintain genetic diversity. Finally, we will eventually have enough information about canine gene function to select for specific genes encoding desirable traits and increase their frequencies in a population. This is similar to breeding practices that have been applied to animals for hundreds of years. The difference is that we will have a large pool of objective data that we can use rapidly on many individuals at a time. This has great potential to improve the health of the dog population as a whole. However, if we or our breeder clients make an error, we can inadvertently cause harm through massive, rapid selection. Therefore, we should probably not be advising clients on polygenic traits or recommend large scale changes in gene frequencies in populations until much more knowledge of gene interaction is obtained. By then it is likely that computer modelling will be available to predict the effect of changing one or several gene frequencies in a dog population over time. And as new mutations are likely to arise in the future, these tools will be needed indefinitely to detect, treat and eliminate genetic disorders from dog populations. Information available from genetic research will only be useful in improving canine health if veterinarians have the knowledge and skills to use it ethically and responsibly. There is not only a great potential to improve overall canine health through genetic selection, but also the potential to do harm if we fail to maintain genetic diversity. Our profession must be in a position to correctly advise clients on the application of this information to individual dogs as well as to populations of dogs, and particularly purebred dogs. 相似文献
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A Idel 《DTW. Deutsche tier?rztliche Wochenschrift》1990,97(4):175-177
It's difficult to value the effects on animals caused by genetic engineering. Nowadays an enormous increase on animal tests is taken place. The detrimental alterations of small number of living born gene altered animals are in literature explained by deficiencies in method and the increased growth is described with deficient mechanisms on regulation. Not only the intention to increase productivity by genetic engineering but also the method to improve by fragments (genes) not facing the animals totality is against prevention of cruelty to animals. 相似文献
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The objective of transgenic livestock improvement projects is to develop and bring to market superior breeding stock, as well as germplasm for the artificial insemination and embryo transfer industries. Livestock animal biotechnology programs hold the promise of achieving, in a single generation, improvements in commercially important livestock species previously possible only through long-term traditional selective breeding practices or by chance mutation. Transgenic farm animals harboring growth hormone or metabolically related structural genes have been created. Studies of these animals demonstrate the effects of inadequate regulation of transgene expression. Research continues to explore the intricacies of developmental regulation of such genes and phenotypic consequences of mammalian gene transfer. Ultimately, genetically engineered livestock will provide producers with the benefit of increased production efficiencies while the consumer will have healthier animal food products. Conceivably, products will be produced with lower levels of fat, cholesterol, feed additives and pharmaceutical residues from animals with altered carcass composition that will result in greater nutritional benefit for the consumer. 相似文献
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This perspective considers genetic disorders of domestic animal populations, in particular their epidemiology and control. Inherited disorders of animals share the same basic molecular biology as those of human beings, but they differ in their epidemiology due largely to the breed structure of the various species, human control of breeding and a greater influence of the founder effect, particularly due to extensive use of a limited number of sires, and inbreeding. Control of genetic disorders in animals is also more practical through extensive screening for disease, or heterozygous animals within defined breed populations, followed by exclusion of affected or carrier animals from breeding. This is assisted by the fact that, within a breed, many inherited monogenic disorders are associated with a single mutation. However some of the more important disorders may be inherited in a non-Mendelian manner, being influenced by multiple genes as well as environmental factors. These aspects are discussed and contrasted with similar aspects in human medical genetics. 相似文献
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It has long been appreciated that animals fed the same diet may perform differently. This is due to the ability of nutrients to interact with and affect molecular pathways that result in differences in BW gain, production performance, or disease resistance. To understand these effects, studies are being undertaken to discover how the differential expression and function of genes occur with different diets. These studies are using new technologies, genomic resources, and analysis techniques that have recently become available for domestic animals. Nutrigenomics and nutrigenetics are new research approaches that strive to optimize health by looking beyond the diet to understand the effects of food at the genetic and epigenetic levels. Nutrigenomics is focused on the effects of diet on health through an understanding of how bioactive chemicals in foods and supplements alter gene expression or the structure of the genome of an animal. Nutrigenetics focuses on how the genetic composition (i.e., genetic variation) of an animal influences their response to a given diet. Results from these studies will aid in formulating nutritionally appropriate diets that may be optimized for animals based on their genomic underpinnings. Nutrigenomics and nutrigenetics unite many fields: nutrition, bioinformatics, molecular biology, genomics, functional genomics, epidemiology, and epigenomics. The use of multi-disciplinary tools promises new opportunities to investigate the complex interactions of the genome and the diet of an animal. Through these new approaches, the partnerships of the genome and nutrition will be revealed resulting in improved efficiency of diets, enhanced sustainability of animals as a protein source, and improved methods for preventing illnesses. 相似文献
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动物转基因技术是在基因工程、细胞工程及胚胎工程的基础上发展起来的一种综合性的生物技术.利用该技术,人类可以按照自己意愿去改变动物的遗传组成,提高动物生长率,改进动物脂肪质量、动物乳品质量以及羊毛产量和品质,还可获得用于治疗或预防人类疾病的转基因生物药品等.然而,动物转基因技术仍在探索之中,许多问题尚未解决,转基因动物的... 相似文献
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生殖激素是调控动物体内复杂生殖过程并影响繁殖性能的一系列的重要激素。近年来,利用生殖激素的批次化生产繁殖技术被广泛使用,提高了母猪的繁殖效率,促进了养猪业向集约化和规模化方向的发展。目前在批次化生产过程中主要采用孕马血清促性腺激素(PMSG)和人绒毛膜促性腺激素(HCG)以及化学类激素进行繁殖调控。但是这些产品的应用仍存在一些问题,因此需要开发出成本低、活性好的高品质蛋白类生殖激素产品,应用于猪场批次化生产中,提高生猪养殖效率和降低生产成本,为提升我国乃至全球畜牧业的动物繁殖效率做出贡献,为动物和人类的健康提供重要保证。 相似文献
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Finding cardiovascular disease genes in the dog 总被引:2,自引:0,他引:2
Heidi G. Parker PhD Kathryn M. Meurs DVM PhD Elaine A. Ostrander PhD 《Journal of Veterinary Cardiology》2006,8(2):115-127
Recent advances in canine genomics are changing the landscape of veterinary biology, and by default, veterinary medicine. No longer are clinicians locked into traditional methods of diagnoses and therapy. Rather, major advances in canine genetics and genomics from the past five years are now changing the way the veterinarian of the 21st century practices medicine. First, the availability of a dense genome map gives canine genetics a much-needed foothold in comparative medicine, allowing advances made in human and mouse genetics to be applied to companion animals. Second, the recently released 7.5× whole genome sequence of the dog is facilitating the identification of hereditary disease genes. Finally, development of genetic tools for rapid screening of families and populations at risk for inherited disease means that the cost of identifying and testing for disease loci will significantly decrease in coming years. Out of these advances will come major changes in companion animal diagnostics and therapy. Clinicians will be able to offer their clients genetic testing and counseling for a myriad of disorders. In this review we summarize recent findings in canine genomics and discuss their application to the study of canine cardiac health. 相似文献
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Jiuxiu Ji Guorong Yan Dong Chen Shijun Xiao Jun Gao Zhiyan Zhang 《Zeitschrift für Tierzüchtung und Züchtungsbiologie》2019,136(3):217-228
The average daily gain (ADG) and body weight (BW) are very important traits for breeding programs and for the meat production industry, which have attracted many researchers to delineate the genetic architecture behind these traits. In the present study, single‐ and multi‐trait genome‐wide association studies (GWAS) were performed between imputed whole‐genome sequence data and the traits of the ADG and BW at different stages in a large‐scale White Duroc × Erhualian F2 population. A bioinformatics annotation analysis was used to assist in the identification of candidate genes that are associated with these traits. Five and seven genome‐wide significant quantitative trait loci (QTLs) were identified by single‐ and multi‐trait GWAS, respectively. Furthermore, more than 40 genome‐wide suggestive loci were detected. On the basis of the whole‐genome sequence association study and the bioinformatics analysis, NDUFAF6, TNS1 and HMGA1 stood out as the strongest candidate genes. The presented single‐ and multi‐trait GWAS analysis using imputed whole‐genome sequence data identified several novel QTLs for pig growth‐related traits. Integrating the GWAS with bioinformatics analysis can facilitate the more accurate identification of candidate genes. Higher imputation accuracy, time‐saving algorithms, improved models and comprehensive databases will accelerate the identification of causal genes or mutations, which will contribute to genomic selection and pig breeding in the future. 相似文献
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肉牛业是畜牧业的重要组成部分,而良种产业化是肉牛产业发展的关键。20世纪人工授精、胚胎移植、发情控制等繁育技术的出现及常规育种技术的应用,使肉牛遗传改良取得了巨大进展,但越来越不能满足现代肉牛业发展的需求。进入21世纪,随着现代生物技术的迅速发展,肉牛育种已从传统表型和表型值育种朝着分子水平方向发展;以配子与胚胎工程、基因工程为主体的高新繁育技术将逐渐成为肉牛繁育的主要手段;体外胚胎生产、胚胎移植商业化应用将会进一步提高,实现产业化;动物克隆、转基因动物生产经不断发展与完善,将成为肉牛育种方面最具潜力的方法。论文就肉牛育种与繁育技术的发展趋势作一简要论述,旨在为肉牛生产提供理论依据与参考。 相似文献
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Pierre Mormède 《Livestock Production Science》2005,93(1):15-21
Genetic factors are undoubtedly involved in inter-individual variability of the behaviours that may be important for livestock production, as shown by pedigree studies, comparison of genetic stocks raised in the same environment, and selection experiments. The knowledge of gene polymorphisms responsible for genetic variability would increase the efficiency of selection, as shown for instance by the identification of the ryanodine receptor gene that harbours the mutations responsible for the porcine stress syndrome, that allows the eradication of the susceptibility allele. One strategy is to screen systematically the genes that are known to be involved in regulation of behaviour (functional candidate genes). This strategy is however very difficult for most behavioural traits, since behaviour is an emerging function from the whole brain/body and the molecular pathways involved in genetic variability are very poorly understood. Another strategy is to investigate linkage between trait variation and genetic markers in a segregating population (usually an intercross or backcross between two strains or breeds contrasting for the trait under study). It allows the detection of genomic regions influencing that trait (quantitative trait loci or QTL), and further investigation aims at the identification of the gene(s) located in each of these regions and the molecular polymorphisms involved in phenotypic variation. Although many QTL have been published for behavioural traits in experimental animals, very few examples are available where strong candidate genes have been identified. Further progress will be very much dependent upon the careful definition of behavioural traits to be studied (including their importance for animal production), on the reliability of their measurement in a large number of animals and on the efficient mastering of environmental factors of variability. The fast increase in the knowledge of genome sequence in several species will undoubtedly facilitate the application to farm animal species of the knowledge obtained in model organisms, as well as the use of model organisms to explore candidate genes detected by QTL studies in farm animals. 相似文献