Analysis of genetic diversity and conservation priorities for six north Ethiopian cattle breeds

Genetic diversity and conservation potential of six indigenous cattle breeds of north Ethiopia was analysed based on 20 microsatellite markers using core set methods. Expected future diversity (assuming assigned extinction probabilities are valid for the next 20-50 years) were 0.988+/-0.011 and 0.980+/-0.010 with expected loss of diversity estimated at 0.02% and 0.74% of current level for the Maximum Variance Total (MVT) and Maximum Variance Offspring (MVO) core sets, respectively. Even though all breeds have contributed to current diversity levels, the Afar and Abergelle breeds only contributed 51% and 62% to the MVT and MVO core sets, respectively, while the Raya breed contributed only 6% and 1.5% to the MVT and MVO core set diversities, respectively. Moreover, prioritizing the six north Ethiopian cattle breeds using the conservation potential obtained from the MVT core set method seems reasonable considering the origin and migration histories of the breeds. Our results suggest that the total current genetic diversity of these breeds can be sufficiently maintained by designing a conservation strategy based on conservation potential of each breed from the MVT core set so that priority is given to lowering the extinction probabilities of breeds with high conservation potential to zero.     

Marker-based estimates of between and within population kinships for the conservation of genetic diversity

In this article coefficients of kinship between and within populations are proposed as a tool to assess genetic diversity for conservation of genetic variation. However, pedigree-based kinships are often not available, especially between populations. A method of estimation of kinship from genetic marker data was applied to simulated data from random breeding populations in order to study the suitability of this method for livestock conservation plans. Average coefficients of kinship between populations can be estimated with low Mean Square Error of Prediction, although a bias will occur from alleles that are alike in state in the founder population. The bias is similar for all populations, so the ranking of populations will not be affected. Possible ways of diminishing this bias are discussed. The estimation of kinships between individuals is imprecise unless the number of marker loci is large (> 200). However, it allows distinction between highly related animals (full sibs, half sibs and equivalent relations) and animals that are not directly related if about 30–50 polymorphic marker genes are used. The marker-based estimates of kinship coefficients yielded higher correlations than genetic distance measures with pedigree-based kinships and thus to this measure of genetic diversity, although correlations were high overall. The relation between coefficients of kinship and genetic distances are discussed. Kinship-based diversity measures conserve the founder population allele frequencies, whereas genetic distances will conserve populations in which allele frequencies are the most different. Marker-based kinship estimates can be used for the selection of breeds and individuals as contributors to a genetic conservation programme.     

猪品种遗传多样性的研究进展

从猪品种的体型外貌、染色体带型、血型和蛋白质以及DNA分子水平等几个方面对猪的遗传多样性进行论述 ,并对遗传多样性的度量参数作了分析。认为猪种遗传多样性的研究是保种和利用的理论基础 ,从形态到DNA分子水平对猪品种遗传多样性的研究在遗传资源大量流失的今天具有重要意义。     

山羊品种遗传多样性的分析

利用6个微卫星标记对中西部7个山羊品种(陕南白山羊、陕北白绒山羊、西农萨能羊、关中奶山羊、太行山羊、黄淮山羊、伏牛山羊)共计322个个体进行了遗传多样性检测,并根据Nei氏遗传距离进行了聚类分析。结果表明:6个微卫星标记在这7个品种中存在高度多态性;陕北白绒山羊的遗传变异程度最大,平均杂合度和平均多态信息含量分别为:0.8401和0.8244;而关中奶山羊的遗传变异程度相对较小,平均杂合度和平均多态信息含量分别为:0.7990和0.7784。UPGMA聚类分析表明,黄淮山羊和伏牛山羊聚为一类,陕南白山羊,太行山羊,陕北白绒山羊依次加入,西农萨能羊和关中奶山羊作为一类最后加入。     

浙江省本地及引进鹅种遗传多样性研究

本研究利用PCR和DNA克隆测序技术扩增并分析了浙江省5个地方鹅种和1个引进家鹅品种96个个体的线粒体DNA D环区(D-loop)全序列。结果表明:浙江省境内的家鹅线粒体DNA D-loop全序长为1 166～1 179 bp,共发现89个变异位点,定义了36种单倍型,群体总核苷酸多样度达到了0.007 25,单倍型多样度为0.862,说明鹅群的遗传资源较为丰富,其中磐石灰鹅的遗传多样性最丰富,朗德鹅的遗传多样性最匮乏,而且没有发现朗德鹅与其他本地鹅种之间的显著差异。同时,个体聚类图中同品种内的个体没有聚在一起,说明浙江省鹅品种的母系来源比较混杂,品种选育偏重于父系,应同时结合基因组水平对其遗传结构进行分析。     

An assessment of genetic diversity and population structures of fifteen Vietnamese indigenous pig breeds for supporting the decision making on conservation strategies

Tropical Animal Health and Production - The study aimed to characterize genetic diversity, genetic clusters, and phylogenetic relationships of 15 Vietnamese indigenous pig breeds across the country...     

Genetic diversity of Swiss sheep breeds in the focus of conservation research

There is constant pressure to improve evaluation of animal genetic resources in order to prevent their erosion. Maintaining the integrity of livestock species as well as their genetic diversity is of paramount interest for long-term agricultural policies. One major use of DNA techniques in conservation is to reveal genetic diversity within and between populations. Forty-one microsatellites were analysed to assess genetic diversity in nine Swiss sheep breeds and to measure the loss of the overall diversity when one breed would become extinct. The expected heterozygosities varied from 0.65 to 0.74 and 10.8% of the total genetic diversity can be explained by the variation among breeds. Based on the proportion of shared alleles, each of the nine breeds were clearly defined in their own cluster in the neighbour-joining tree describing the relationships among the breeds. Bayesian clustering methods assign individuals to groups based on their genetic similarity and infer the number of populations. In STRUCTURE, this approach pooled the Valais Blacknose and the Valais Red. With BAPS method the two Valais sheep breeds could be separated. Caballero & Toro approach (2002) was used to calculate the loss or gain of genetic diversity when each of the breeds would be removed from the set. The changes in diversity based on between-breed variation ranged from −12.2% (Valais Blacknose) to 0% (Swiss Black Brown Mountain and Mirror Sheep); based on within-breed diversity the removal of a breed could also produce an increase in diversity (−0.6% to + 0.6%). Allelic richness ranged from 4.9 (Valais Red) to 6.7 (Brown Headed Meat sheep and Red Engadine Sheep). Breed conservation decisions cannot be limited to genetic diversity alone. In Switzerland, conservation goals are embedded in the desire to carry the cultural legacy over to future generations.     

Genetic selection and conservation of genetic diversity*

For 100s of years, livestock producers have employed various types of selection to alter livestock populations. Current selection strategies are little different, except our technologies for selection have become more powerful. Genetic resources at the breed level have been in and out of favour over time. These resources are the raw materials used to manipulate populations, and therefore, they are critical to the past and future success of the livestock sector. With increasing ability to rapidly change genetic composition of livestock populations, the conservation of these genetic resources becomes more critical. Globally, awareness of the need to steward genetic resources has increased. A growing number of countries have embarked on large scale conservation efforts by using in situ, ex situ (gene banking), or both approaches. Gene banking efforts have substantially increased and data suggest that gene banks are successfully capturing genetic diversity for research or industry use. It is also noteworthy that both industry and the research community are utilizing gene bank holdings. As pressures grow to meet consumer demands and potential changes in production systems, the linkage between selection goals and genetic conservation will increase as a mechanism to facilitate continued livestock sector development.     

Microsatellite-based diversity analysis and genetic relationships of three Indian sheep breeds

The genetic structure of three Indian sheep breeds from two different geographical locations (Nali, Chokla from north‐western arid and semi‐arid region; Garole from eastern saline marshy region) of India was investigated by means of 11 ovine‐specific microsatellite markers as proposed in FAOs MoDAD programme. Microsatellite analysis revealed high allelic and gene diversity in all the three breeds. Nali sheep showed higher mean number of alleles and gene diversity (6.27 and 0.65) than Chokla (5.63 and 0.64) and Garole (5.63 and 0.59). High within population inbreeding estimates observed in the three breeds (F_IS, Chokla = 0.286, Nali = 0.284, Garole = 0.227) reflected deficit of heterozygotes. The overall estimates for F‐statistics were significantly (p < 0.05) different from zero. High values of F_ST (0.183) across all the loci revealed substantial degree of breed differentiation. Based on pair wise F_ST and N_m between different breeds, Nali and Chokla (F_ST = 6.62% and N_m = 4.80) were observed to be the closest followed by Garole and Nali (F_ST = 20.9% and N_m = 1.80), and Garole and Chokla (F_ST = 21.4% and N_m = 1.71). In addition, genetic distance estimates, phylogeny analysis and individual assignment test used to evaluate interbreed genetic proximity and population structure also revealed substantial genetic differentiation between Garole and the other two Rajasthani (Nali and Chokla) sheep. This divergent status of Garole sheep indicated genetic uniqueness of this breed suggesting higher priority for its conservation.     

利用微卫星标记对四个绵羊品种遗传多样性的初步研究

采用3个微卫星标记，对4个中国地方绵羊品种进行遗传多样性检测。利用POPGENE软件分析了受试羊等位基因频率、等位基因数、有效等位基因数、遗传杂合度。     

Analyses of genetic diversity in five Canadian dairy breeds using pedigree data

The issue of loss of animal genetic diversity, worldwide in general and in Canada in particular, has become noteworthy. The objective of this study was to analyze the trend in within‐breed genetic diversity and identify the major causes of loss of genetic diversity in five Canadian dairy breeds. Pedigrees were analyzed using the software EVA (evolutionary algorithm) and CFC (contribution, inbreeding, coancestry), and a FORTRAN package for pedigree analysis suited for large populations (PEDIG). The average rate of inbreeding in the last generation analyzed (2003 to 2007) was 0.93, 1.07, 1.26, 1.09 and 0.80% for Ayrshire, Brown Swiss, Canadienne, Guernsey and Milking Shorthorn, respectively, and the corresponding estimated effective population sizes were 54, 47, 40, 46 and 66, respectively. Based on coancestry coefficients, the estimated effective population sizes in the last generation were 62, 76, 43, 61 and 76, respectively. The estimated percentage of genetic diversity lost within each breed over the last four decades was 6, 7, 11, 8 and 5%, respectively. The relative proportion of genetic diversity lost due to random genetic drift in the five breeds ranged between 59.3% and 89.7%. The results indicate that each breed has lost genetic diversity over time and that the loss is gaining momentum due to increasing rates of inbreeding and reduced effective population sizes. Therefore, strategies to decrease rate of inbreeding and increase the effective population size are advised.     

Investigation of the genetic diversity among native Turkish sheep breeds using mtDNA polymorphisms

A total of 135 unrelated sheep from nine Turkish native sheep breeds (Dagl?c, Kivircik, Imroz, Chios, Morkaraman, Ivesi, Hemsin, Karayaka and Akkaraman) were investigated to determinate the maternal genetic diversity using a sequence of a 531-bp segment of the mtDNA control region. Analysis of the mtDNA control region sequence revealed 63 haplotypes and 53 polymorphic sites. Haplotype diversity, nucleotide diversity and the average number of nucleotide differences were estimated to be 0.9496?±?0.011, 0.01407?±?0.00060 and 7.456, respectively. The sequence analysis also revealed high level of genetic diversity among the native Turkish breeds. These breeds were grouped into three major maternal haplogroups: A, B and C, with one animal belonging from the Akkaraman breed to the rare haplogroup E. Irregular shape of mismatch distribution of haplogroup C could be an indicator that haplogroup C may represent different haplogroups. Contrarily to previous studies carried out on Turkish native breeds, majority of animals grouped in haplogroup A in the present study. This result and the irregular shape of mismatch curve of haplogroup C indicate that genetic structure of Turkish native sheep breeds could be more complicated than it is thought.     

Domestic dog skull diversity across breeds,breed groupings,and genetic clusters

Domestic dogs have become a model organism for studying the extent and consequences of morphological diversity, especially in the skull. It has been demonstrated that Cephalic Index (CI, skull width/skull length) correlates with central concentration of ganglion cells in the retina and with ventral rotation of the cerebral hemispheres. These changes may be reflected in the behavior of breeds with different skulls shapes. This study explored skull variation in the breed groups (n = 7) described by the Australian National Kennel Club to determine if CI differed significantly among the breed groups; groups were expected to differ not least in behavior. The CI of 12 representative dogs (females, n = 6; males, n = 6) of the most popular breeds (n = 80; total n = 960 dogs) were measured. Multivariate analysis of variance was performed to determine CI variance among the breed groups and between previously reported clusters of breeds with similar DNA, which identifies common ancestry. Although CI differed significantly among some breed groups, neither the breed groupings nor the DNA clusters satisfactorily explained all the variance in CI. The results show that breed groupings and genetic clusters only partially explain CI differences. They also suggest that CI is on a continuum and that the definition of three categories of canine skull as dolichocephalic, mesocephalic, and brachycephalic may be overly arbitrary.     

The genetic diversity and structure of 18 sheep breeds exposed to isolation and selection

The phylogenetic layout of the genotyped (30 microsatellite) 18 sheep breeds in this study demands and provides the opportunity to evaluate both neutral and adaptive components of genetic diversity in a naturally and artificially selected and subdivided sheep population. Seven Pramenka strains from Bosnia and Herzegovina and Croatia characterized by a very low intensity of artificial selection, preserved the highest neutral genetic variability. Eight central and north‐western European breeds under considerable artificial isolation and selection preserved the lowest genetic variability. Only combinations of various phylogenetic parameters offer a reasonable explanation for underlying evolutionary forces working in the investigated island and mainland sheep breeds under variable natural and artificial selection. More than 60% of total genetic, diversity was allocated to virtually unselected Pramenka strains, and an additional 25% to native moderately selected Graue Gehoernte Heidschnucke and intensively selected Ostfriesische Milchschafe. Some economically very important breeds and strains did not contribute to a pool with maximal genetic diversity, while they play an important role in the cultural heritage of respective countries.     

甘肃地方绵羊品种微卫星遗传多样性与系统发育分析

通过对甘肃省6个地方绵羊品种(240只个体)15个微卫星座位的等位基因的研究,结果共发现了179个等位基因。其中在藏羊中发现的等位基因数最多(136个),兰州大尾羊最少(94个)。多态信息含量、期望杂合度和观察杂合度的数据表明:在研究的6个绵羊品种中藏羊和甘肃高山细毛羊的遗传多样性较丰富,而兰州大尾羊和岷县黑裘皮羊的遗传多样性较低。DA遗传距离和D s遗传距离构建的NJ系统发育树均表明:兰州大尾羊、蒙古羊和滩羊具有较近的亲缘关系,预示这3个品种可能具有相同的原始祖先。而甘肃高山细毛羊与其他5个甘肃地方品种的遗传距离较远,另为一类。     

Assessing the genetic diversity conserved in the Norwegian live poultry genebank

ABSTRACT

The aim of this study was to evaluate genetic diversity within and between lines at the Norwegian live poultry gene bank as well as assessing the conservation value in an international context. Eight lines including the national breed, Jærhøns, were genotyped with the 600K Affymetrix^® Axiom^® Chicken Genotyping Array. The white egg layers were generally more inbred than the brown layers. Comparative analyses were carried out with 72 international populations of different origins. The lines that were last bred for commercial production in Norway, Norbrid, are clearly separated from the rest of the international set and more closely related to the current commercial lines. The brown egg layer Norbrid 7 has the highest relative contribution to genetic diversity. The Norwegian genebank lines are of conservation value in a national and international perspective, as they all add genetic diversity to the global set.     

Genetic diversity in Swiss cattle breeds

Introduction First attempts at establishing the genetic relationships among cattle populations relied on archeological evidence (Epstein 1971; Epstein and Mason 1984) and protein polymorphisms (Baker and Manwell 1980, 1991). Loftus et al. (1994) examined mitochondrial DNA to determine the divergence time between Bos taurus and Bos indicus. Today most studies on genetic diversity are based on microsatellite analysis (Litt and Luty 1989; Tautz 1989; Weber and May 1989). Microsatellites were used in, e.g. man (Bowcock et al. 1994), canids (Roy et al. 1994; Fredholm and Winter ø ; 1995) and sheep (Buchanan et al. 1994). Recent studies in cattle are also microsatellite based (e.g. Machugh et al. 1994; Ciampolini et al. 1995; Moazami -Goudarzi et al. 1997) and aim at facilitating the development of management programs for endangered breeds (FAO 1981). Our microsatellite-based investigation on the genetic diversity between and within Swiss cattle breeds included Original Swiss Brown, purebred Simmental, Holstein, Hérens and Evolènard. Previous studies in Swiss breeds made use of blood group systems (Reuse 1969), serum transferrin and hemoglobin (Krummen 1964), amylase (Buser 1970) and carboanhydrases (Kä ;stli et al. 1980). The Hérens breed is endemic to the canton of Wallis. The Evolènard, which are very few in numbers and restricted to a single valley in the canton of Wallis, are phenotypically very similar to the Hérens with the exception of the coat colour. In the Aosta valley (Italy) which borders the canton of Wallis these two breeds find their counterparts. The phenotype of the Aosta Chestnut fits the Hérens and the Aosta Black Pied fits the Evolènard. The Holstein breed replaced the Fribourg breed which was a colour variant of the purebred Simmental breed (Engeler et al. 1961) and is now extinct. The Original Swiss Brown and the purebred Simmental are endemic to Switzerland.     

Prioritization based on neutral genetic diversity may fail to conserve important characteristics in cattle breeds

Conservation of the intraspecific genetic diversity of livestock species requires protocols that assess between-breed genetic variability and also take into account differences among individuals within breeds. Here, we focus on variation between breeds. Conservation of neutral genetic variation has been seen as promoting, through linkage processes, the retention of useful and potentially useful variation. Using public information on beef cattle breeds, with a total of 165 data sets each relating to a breed comparison of a performance variable, we have tested this paradigm by calculating the correlations between pairwise breed differences in performance and pairwise genetic distances deduced from biochemical and immunological polymorphisms, microsatellites and single-nucleotide polymorphisms. As already observed in floral and faunal biodiversity, significant positive correlations (n=54) were found, but many correlations were non-significant (n=100) or significantly negative (n=11). This implies that maximizing conserved neutral genetic variation with current techniques may conserve breed-level genetic variation in some traits but not in others and supports the view that genetic distance measurements based on neutral genetic variation are not sufficient as a determinant of conservation priority among breeds.     

Porcine endogenous retrovirus copy number in different pig breeds is not related to genetic diversity

The risk of zoonoses is a major obstacle to xenotransplantation. Porcine endogenous retrovirus (PERV) poses a potential risk of zoonotic infection, and its control is a prerequisite for the development of clinical xenotransplantation. The copy number of PERV varies among different breeds, and it has been suggested that the PERV integrations number is increased by inbreeding. The purpose of this study was (i) to examine the copy number of PERV in different Spanish pig breeds, Spanish wild boar and commercial cross-bred pigs from five different farms and genetic background (CCP1-CCP5) and (ii) to investigate the correlation between PERV copy number and the genetic background of the pigs in order to improve the selection of pigs for xenotransplantation. PERV copy number was determined by quantitative, real-time polymerase chain reactions. Thirty-four microsatellite markers were genotyped to describe the genetic diversity within populations (observed and expected heterozygosities, Ho and He, respectively) and the inbreeding coefficient (F). Pearson's correlation coefficient was used to determine the relationship between PERV copy number and Ho, He and F. The copy number of PERV among different pig breeds was estimated to range between three (CCP1) and 43 copies (Iberian Pig). Statistical differences were found among the studied populations concerning PERV copy number. No correlation was found between the PERV copy number and the heterozygosity (calculated at an individual level or at a population level) or the inbreeding coefficient of each population. Our data suggest that pigs inbreeding does not increase PERV copy number and support the idea that careful selection of pigs for organ donation with reduced PERV copy number will minimize the risk of retrovirus transmission to the human receptor.