GDF9 as a candidate gene for prolificacy of Small Tail Han sheep

Growth differentiation factor 9 (GDF9) which controls the fecundity of Belclare, Cambridge, Santa Ines, Moghani, Ghezel and Thoka ewes was studied as a candidate gene for the prolificacy of Small Tail Han sheep. According to the sequence of ovine GDF9 gene, six pairs of primers were designed to detect single nucleotide polymorphisms of two exons of GDF9 gene in both high fecundity breed (Small Tail Han sheep) and low fecundity breed (Dorset sheep) by polymerase chain reaction-single strand conformation polymorphism (PCR-SSCP). Only the products amplified by primers 2-1 and 2-2 displayed polymorphisms. For primer 2-1, three genotypes (AA, AB and BB) were detected in both sheep breeds. Sequencing revealed one silent mutation (G477A) in exon 2 of GDF9 gene in the BB genotype in comparison with the AA, which was known as G3 mutation of GDF9 gene in Belclare and Cambridge ewes. The relationship of least squares means for litter size was AA?>?AB?>?BB in Small Tail Han sheep (P?>?0.05). For primer 2-2, two genotypes (CC and CD) were detected in both sheep breeds. Sequencing revealed one novel single nucleotide mutation (G729T) in exon 2 of GDF9 gene in the CD genotype in comparison with the CC, which resulted in an amino acid change (Gln243His). The ewes with mutation heterozygous genotype CD had 0.77 (P?相似文献   

Investigation of the Booroola (FecB) and Inverdale (FecX(I)) mutations in 21 prolific breeds and strains of sheep sampled in 13 countries

Twenty-one of the world's prolific sheep breeds and strains were tested for the presence of the FecB mutation of BMPR1B and the FecX(I) mutation of BMP15. The breeds studied were Romanov (2 strains), Finn (2 strains), East Friesian, Teeswater, Blueface Leicester, Hu, Han, D'Man, Chios, Mountain Sheep (three breeds), German Whiteheaded Mutton, Lleyn, Loa, Galician, Barbados Blackbelly (pure and crossbred) and St. Croix. The FecB mutation was found in two breeds, Hu and Han from China, but not in any of the other breeds. The 12 Hu sheep sampled were all homozygous carriers of FecB (FecB(B)/FecB(B)) whereas the sample of 12 Han sheep included all three genotypes (FecB(B)/FecB(B), FecB(B)/FecB+, FecB+/FecB+) at frequencies of 0.33, 0.58 and 0.08, respectively. There was no evidence of FecX(I) in any of the breeds sampled.     

Highly prolific Booroola sheep have a mutation in the intracellular kinase domain of bone morphogenetic protein IB receptor (ALK-6) that is expressed in both oocytes and granulosa cells

The Booroola fecundity gene (FecB) increases ovulation rate and litter size in sheep and is inherited as a single autosomal locus. The effect of FecB is additive for ovulation rate (increasing by about 1.6 corpora lutea per cycle for each copy) and has been mapped to sheep chromosome 6q23-31, which is syntenic to human chromosome 4q21-25. Bone morphogenetic protein IB (BMP-IB) receptor (also known as ALK-6), which binds members of the transforming growth factor-beta (TGF-beta) superfamily, is located in the region containing the FecB locus. Booroola sheep have a mutation (Q249R) in the highly conserved intracellular kinase signaling domain of the BMP-IB receptor. The mutation segregated with the FecB phenotype in the Booroola backcross and half-sib flocks of sheep with no recombinants. The mutation was not found in individuals from a number of sheep breeds not derived from the Booroola strain. BMPR-IB was expressed in the ovary and in situ hybridization revealed its specific location to the oocyte and the granulosa cell. Expression of mRNA encoding the BMP type II receptor was widespread throughout the ovary. The mutation in BMPR-IB found in Booroola sheep is the second reported defect in a gene from the TGF-beta pathway affecting fertility in sheep following the recent discovery of mutations in the growth factor, GDF9b/BMP15.     

Reproductive biology of the Booroola Merino sheep

This paper reviews the genetic and physiological characteristics of the Booroola Merino, one of the four most prolific sheep breeds in the world, and which was acquired by CSIRO in 1958 from a commercial sheep property, 'Booroola', Cooma, N.S.W. The exceptional prolificacy of this genotype--e.g. mean flock ovulation rate in 1982 of 4.2 (range 1-10) and mean litter size of 2.5 (range 1-7)--is largely attributable to a single gene (F) of uncertain origin which increases ovulation rate. Crosses of the Booroola with other Merinos produce progeny which have a 47-87% increase in ovulation rate, a 45-56% increase in litter size at birth, and a 1-33% reduction in lamb survival relative to control Merinos. This represents a 16-37% increase in the number of lambs weaned per ewe joined in favour of the Booroola crosses. The exact site of action of the F gene is not well established, although it is expressed primarily at the ovary, where more than the normal number of follicles mature and ovulate each oestrous cycle. This may result from some abnormality of the Booroola follicle itself or it may reflect differences in Booroola gonadotrophin secretion. There is some evidence that Booroola ewes have elevated plasma concentrations of follicle stimulating hormone (FSH) early in life and during the oestrous cycle, and that FSH concentrations in the pituitary gland and urine of the adult ewe are also high. These elevated FSH levels in the adult are attributed to an ovarian feedback deficiency, probably because the inhibin content of the Booroola ovary is only one-third that of normal Merino ovaries. The low inhibin content appears to be due to Booroola follicles having significantly fewer granulosa cells than control Merinos. Analogous studies of the prolific D'man sheep of Morocco point to FSH as the main correlate of prolificacy. The testis growth rate, testis size and total daily production of spermatozoa of the Booroola ram are similar to those of normal Merinos, as also are the endocrine characteristics of adult rams. The Booroola gene's expression is evidently sex-limited. Several theories concerning the mode of action of the F gene are being tested.     

A review of the effects of the Booroola gene (FecB) on sheep production

Booroola Merino (B^oM) ewes have a high ovulation rate and litter size which in 1980 was postulated to be due to the effects of a major gene (FecB). This was confirmed in breeding experiments and FecB was subsequently shown to be due to a mutation (BMPR-1B) on chromosome 6. The B^oM originated from an Australian commercial fine wool Merino flock (Booroola) and has been used in crossing experiments and for introgression of FecB into many breeds around the world to improve fecundity. The mutation has recently been found in native sheep breeds in India, China and Indonesia and it is likely that FecB in the Australian B^oM was derived from importations of Garole sheep from India in 1792 and 1793.The effects on production traits of the FecB mutation in a range of genetic comparisons, environments and production systems are reviewed. Comparisons involving B^oM crosses with various other breeds and contrasts of FecB homozygous (BB), heterozygous (B+) and non-carrier (++) genotypes in comparable background genotypes, including non-B^oM, have been summarised from 45 reports. The weighted mean effect for ewes carrying one copy of FecB (B+) was +1.3 (range +0.8 to +2.0) for ovulation rate and +0.7 (range +0.4 to +1.3) for litter size. The effect of a second copy (BB) was generally additive for ovulation rate, with little or no increase in litter size for BB ewes among B^oM crosses. However there was generally a further increase in litter size for BB ewes of about half the effect of one copy (B+) in the Indian and Chinese breeds. Poor lamb survival and lamb growth reduced the number of lambs weaned and total weight of lamb weaned by B+ ewes. Most studies still showed a small advantage for B+ ewes, although several reported negative effects. While embryo survival declines at higher ovulation rates, the effects of FecB per se are equivocal. There is some evidence of a higher non-pregnancy rate among homozygous BB ewes. Most studies reported lower birth weight and growth rate from B^oM cross lambs and lambs from crossbred ewes introgressed with FecB. However it is difficult to separate the effects of low background genetic merit for growth of the B^oM and the lower birth weight and growth rate of lambs from larger litters from the genetic effect of carrying FecB. There was little or no difference in growth rate between BB, B+ and ++ genotype lambs. For other traits including, seasonal oestrous activity, carcass and meat quality and wool production, there was no evidence of major effects of FecB. The opportunities for management and nutritional modification of FecB expression and implications for industry adoption are briefly discussed.     

Studies on effect of Booroola (FecB) genotype on lifetime ewes' productivity efficiency, litter size and number of weaned lambs in Garole x Malpura sheep

The FecB gene of Garole was introgressed into non-prolific Malpura sheep. The present study was conducted to evaluate the effects of FecB genotypes on cumulative lifetime (three lamb crops) litter size (CLS), cumulative number of weaned lambs (CWL) and cumulative ewe's productivity efficiency (CEPE) in 51 Garole x Malpura (GM) crossbred sheep. The GM ewes of F(1) were selected and screened for FecB mutation using forced RFLP-PCR technique. The majority (78.4%) of F(1) GM individuals were carriers (FecB(B+)) for the FecB mutation. In first parity 55% FecB(B+) ewes gave births to multiple lambs. The FecB genotypes were significantly (P<0.01) associated with the CLS and CWL. The FecB(B+) ewes resulted in 65.6 and 62.1% higher CLS and CWL, respectively compared to non-carriers. The CEPE was also affected significantly by the FecB genotypes at birth, weaning, 6 and 12 months of age. The FecB(B+) ewes weaned 20.9% higher total litter weight as compared to FecB++ ewes and at 12 months age the difference was 43.5% in favor of B+ ewes. The study indicated that the CLS, CWL and CEPE of carrier ewes (FecB(B+)) were comparatively higher than that of non-carriers (FecB++).     

Genetic linkage analysis between protein polymorphisms and the FecB major gene in sheep

A genetically linked marker locus is sought for the Booroola gene (FecB), a major gene which confers increased prolificacy in sheep. We examined 18 polymorphic proteins in sheep and found 10 to be informative in half-sib families where the Booroola gene was segregating. Recombination was observed between each of the protein loci and the Booroola gene. The loci and exclusion distance for each (calculated as the recombination fraction where the lod score was equal to -2.0) are as follows: NADH diaphorase, DIA1 (9.2 cM); arylesterase, EsA (11.9 cM); haemoglobin beta chain, HBB (17.5 cM); leucine amino peptidase, LAP (19.7 cM); malic enzyme, ME1 (14.8 cM); ovine plasminogen antigen, OPA (12.6 cM); alpha-1-protease inhibitor, PI2 (5.7 cM), erythrocyte 'X' protein, Prot-X (25.3 cM); post transferrin, PTF (2.2 cM); transferrin, TF (33.8 cM).     

Concentrations of progesterone,follistatin, and follicle-stimulating hormone in peripheral plasma across the estrous cycle and pregnancy in merino ewes that are homozygous or noncarriers of the Booroola gene

The circulating concentrations of progesterone, FSH, and follistatin across the estrous cycle and gestation were compared in Australian merino sheep that were homozygous for the Booroola gene, FecB, or were noncarriers. The Booroola phenotype is due to a point mutation in the bone morphogenetic protein receptor 1B. Progesterone concentrations began to rise earlier and were higher in the Booroola ewes than in the noncarriers on most days of the luteal phase but not during the follicular phase of the cycle. Follistatin concentrations remained unchanged across the estrous cycle in both groups of ewes, with no differences between genotypes. FSH concentrations were higher in Booroola ewes than in noncarrier ewes on most days of the estrous cycle, with a significantly higher and broader peak of FSH around the time of estrus. Progesterone concentrations were significantly higher in early and midgestation in Booroola ewes but were lower toward the end of gestation than those in noncarriers. FSH declined in both groups across gestation, with lower concentrations of FSH in Booroola ewes during midgestation. Follistatin remained unchanged across gestation in Booroola ewes and noncarrier ewes with a twin pregnancy but declined across gestation in noncarrier ewes with a singleton pregnancy. These results suggest that follistatin concentration is not regulated by the FecB gene during the estrous cycle and pregnancy but is influenced by the number of fetuses. However, the FecB gene appears to positively affect both progesterone and FSH during the estrous cycle and across pregnancy, which suggests that bone morphogenetic proteins play an important role in the regulation of both hormones.     

Fec基因及BMPR-IB基因的突变特性与生物学意义

FecB基因位于Booroola绵羊的常染色体上,具有提高排卵率和产羔数等生物学作用。FecB基因已被定位在绵羊6号染色体6q23~q31的狭窄区域内,并且已从分子水平上找到了控制Booroola绵羊排卵数的主效基因。本文详细阐述了近年来对FecB基因的定位及分子生物学作用机制方面的研究进展。     

优良的BMPR-IB基因型可提高绵羊冷冻胚胎的受胎效果

以控制BooroolaMerino羊高繁殖力的BMPR-IB基因为候选基因,以小尾寒羊及其杂交羊、东北半细毛羊、澳洲美利奴羊、德国肉用美利奴羊、萨福克羊、特克塞尔羊、夏洛莱羊为试验对象,采用PCR-限制性片段长度多态性(PCR-RFLP)方法进行基因单核苷酸多态性(SNP)检测和基因型分析,同时研究基因对高繁殖力的影响.研究结果表明:小尾寒羊及其杂交羊、东北半细毛羊和夏洛莱羊群体中发现了与BooroolaMerino羊相同的A746G碱基突变,而小尾寒羊及其杂交羊群体的B等位基因频率明显高于其他2个品种.另外4个品种中未发现此突变.携带B等位基因的群体较非携带B等位基因群体排出更多的卵子,排卵后黄体直径较小.移植入冷冻胚胎后, 、B 和BB3种基因型群体的妊娠率分别为38.78%、45.71%和66.67%.由此推断,BMPR-IB基因突变很有可能从增加卵巢排卵数和提高胚胎着床及妊娠建立效率两个方面同时影响绵羊高繁殖力性状.所得BB型群体冻胚移植妊娠率明显高于 和B 型群体,已接近鲜胚移植水平,通过PCR-RFLP方法进行基因型分析,选用合适基因型群体作为胚胎移植受体,有可能为提高绵羊胚胎移植受胎率提供新的方向.     

Identification of fecundity gene (FecB) carriers using microsatellite markers and its effect on sheep weight

Abstract. Altogether 115 animals representing 5 genetic groups: 3 purebred Booroola Merino, Corriedale and Olkuska, and 2 Booroola crossbreds were included in the studies. In total 6 alleles from 97 bp to 119 bp in microsatellite OarAE101, and 5 alleles from 162 bp to 174 bp in BM1329 were identified. The marker of FecB gene presence seems to be an allele of 97 bp in the case of microsatellite OarAE 101 and 162 bp in the case of BM1329. Significant differences FecB carriers (Booroola-Corriedale) and non-carriers (Corriedale) in birth weight and at weaning at 100 days (males and females from twins) as well as weight gain during the first 28 days and 100 days were found. Purebred lambs showed higher values of the investigated traits.     

绵羊多胎主效基因研究进展

绵羊存在影响多胎性状的主效基因。BMPR-IB的突变体FecB对排卵数的增加具有增强效应,GDF-9的突变体FecGH和FecI及BMP-15的突变体FecXI、FecXH、FecXG、FecXB、FecXL和FecXR均为纯合子不育,杂合子增加排卵数,而GDF-9的突变体FecGE只有纯合子增加排卵数。Woodlands和Lacaune是遗传方式已知的多胎主效基因。Woodlands是与X染色体连锁的母系印迹基因,Lacaune与FecB类似对排卵数的增加具有增强效应。主效基因突变体单拷贝增加排卵数的效应具有差异性,FecB和FecXL的效应最高可增加1.5个,Woodlands最低可增加0.4个。研究绵羊多胎性状主效基因不仅有助于家畜的选种选育,提高绵羊繁殖力,而且为研究哺乳动物的繁殖机制开拓了新的方向。文章综述了绵羊多胎主效基因的来源、定位、表型、作用机制以及我国绵羊品种多胎主效基因的研究现状,旨在为深入研究绵羊多胎主效基因的作用机制及为绵羊多胎品种的选育提供参考。     

绵羊微卫星BMS2508和FecB基因的多态及连锁分析

文章分析与绵羊高繁殖力主效基因FecB紧密连锁的微卫星座位BMS2508在高繁殖力绵羊品种(小尾寒羊)和低繁殖力绵羊品种(特克塞尔、多赛特和中国美利奴)中的遗传多态性, 同时探讨该微卫星座位与小尾寒羊FecB基因的连锁不平衡关系。高繁殖力品种小尾寒羊在骨形态发生蛋白受体IB(Bone morphogenetic protein receptor IB, BMPR-IB)基因编码序列第746位碱基处发生了与Booroola Merino绵羊相同的FecB突变(A746G), 而在低繁殖力的特克塞尔、多赛特和中国美利奴绵羊中没有检测到该突变; 小尾寒羊BB、B+、++的基因型频率分别为0.485、0.398和0.117。微卫星座位BMS2508在4个绵羊品种的438个个体中共检测到8个等位基因和15种基因型, 最小等位基因为94 bp, 最大等位基因为116 bp; 小尾寒羊(n = 307)、特克塞尔(n = 45)、多赛特(n = 46)、中国美利奴(n = 40)和BB型(n = 149)、B+型(n = 122)、++型(n = 36)小尾寒羊群体中优势等位基因分别是100 bp、94 bp、94 bp、112 bp、100 bp、100 bp、112 bp, 其频率分别为0.453、0.544、0.802、0.475、0.483、0.439、0.389。连锁不平衡分析显示小尾寒羊FecB基因B等位基因与BMS2508微卫星座位100 bp等位基因之间存在一定的连锁不平衡(D′=0.408), 而+等位基因与BMS2508微卫星座位110 bp和114b p等位基因均存在一定的连锁不平衡(D′=0.513)。     

Screening for Booroola (FecB) and Galway (FecX) mutations in Indian sheep

This study reports the status of the Booroola (FecB) and Galway (FecX^G) mutations in Indian sheep breeds. The Kendrapada sheep (n = 46) was genotyped for the presence of FecB and FecX^G mutations, while the Garole (n = 34), Malpura (n = 30), and Decanni sheep (n = 15) for the FecX^G mutation. The FecB and FecX^G genotyping was carried out by forced restriction fragment length polymorphism PCR technique. In the present study, FecB mutation was discovered in the Kendrapada sheep of Orissa, which is now the second prolific sheep of India after the Garole. Out of 46 individuals of Kendrapada sheep, 26 were homozygous (BB), 15 heterozygous (B+) and 5 non-carriers (++) for the FecB mutation. The frequency of the FecB allele in this sample was about 0.73. Results indicated that the frequency of the FecB mutation is high, but the gene is not fixed in the population as reported in Garole sheep. None of sheep breeds carried the FecX^G mutation. The discovery of the FecB mutation in Kendrapada sheep will facilitate the use of FecB allele in improving the prolificacy of non-prolific sheep breeds of India.     

Patterns of expression of messenger RNAs encoding GDF9, BMP15, TGFBR1, BMPR1B, and BMPR2 during follicular development and characterization of ovarian follicular populations in ewes carrying the Woodlands FecX2W mutation

Woodlands sheep have a putative genetic mutation (FecX2(W)) that increases ovulation rate. At present, the identity of FecX2(W) is unknown. The trait does not appear to be due to the previously described mutations in bone morphogenetic protein 15 (BMP15), growth differentiation factor 9 (GDF9), or bone morphogenetic protein receptor type 1B (BMPR1B) that affect ovulation rate in sheep. Potentially, FecX2(W) could be an unidentified genetic mutation in BMP15 or in the closely related GDF9, which interacts with BMP15 to control ovarian function. Alternatively, FecX2(W) may affect ovulation rate by changing the expression patterns in the molecular pathways activated by genes known to regulate ovulation rate. The objectives of these experiments were to sequence the complete coding region of the BMP15 and GDF9 genes, determine the patterns of expression of mRNAs encoding GDF9, BMP15, TGFBR1, BMPR1B, and BMPR2 during follicular development, and characterize the follicular populations in ewes heterozygous for the Woodlands mutation and their wild-type contemporaries. No differences in the coding sequences of BMP15 or GDF9 genes were identified that were associated with enhanced ovulation rate. The expression patterns of GDF9 and BMPR2 mRNAs were not different between genotypes. However, expression of BMP15 mRNA was less in oocytes of FecX2(W) ewes in large preantral and antral follicles. Expression of ALK5 mRNA was significantly higher in the oocytes of FecX2(W) ewes, whereas expression of BMPR1B was decreased in both oocytes and granulosa cells of FecX2(W) ewes. FecX2(W) ewes also had increased numbers of antral follicles <1 mm in diameter. These follicles were smaller in average diameter, with the oocytes also being of a smaller mean diameter. Given that a mutation in BMP15 or BMPR1B results in increased ovulation rates in sheep, the differences in expression levels of BMP15 and BMPR1B may play a role in the increase in ovulation rate observed in Woodlands ewes with the FecX2(W) mutation.     

Markers of follicle function in Belclare-cross ewes differing widely in ovulation rate.

High prolificacy due to a gene that has a large effect on ovulation rate has been noted in Booroola and Inverdale ewes. High prolificacy in the Belclare breed (a composite developed from stocks selected for very large litter size or high ovulation rate) may be related to the segregation of two genes. The aims of this study were (i) to compare the morphological and functional features of ovulatory follicles from carriers (which could only be heterozygous for the genes of interest) and non-carriers, and (ii) to identify markers of the Belclare genes among secreted or cellular ovarian proteins. Belclare carrier ewes had more ovulatory follicles (4.9 +/- 0.4) than did non-carrier ewes (2.0 +/- 0.2) (P < 0.001). Ovulatory follicles from carriers were also smaller (4.4 +/- 0.1 mm versus 5.7 +/- 0.2 mm, P < 0.001) and contained a significantly reduced number of granulosa cells (P < 0.001). However, the proportion of proliferating granulosa cells in ovulatory follicles was similar in both groups. The in vitro secretion of steroids per follicle was only marginally lower in follicles from Belclare carriers compared with non-carriers. Furthermore, similar concentrations of steroidogenic enzymes were present in both groups, indicating that steroidogenic potential per granulosa cell is similar between carriers and non-carriers. Possible markers of the Belclare genes were identified among cellular proteins of follicular walls by two-dimensional PAGE and image analysis. Two spots at 78 and 49 kDa were always absent in samples from non-carriers. When secreted proteins in follicles from carriers were compared with those from non-carriers, two spots at 53 and 41 kDa were restricted to samples from carriers and three spots at 97, 91 and 45 kDa were unique to samples from non-carriers. Interestingly, the spot at 91 kDa is also affected by the Booroola gene.     

Sperm motion characteristics of GarolexMalpura sheep evolved in a semi-arid tropical environment through introgression of FecB gene

The arid and semi-arid tropical climates of India are endowed with vast diversity of non-prolific sheep breeds. The GarolexMalpura sheep has been evolved in a semi-arid tropical environment by introgression of FecB gene via artificial insemination of Malpura ewes using diluted semen of prolific microsheep Garole and subsequently multiplied by inter se mating among GarolexMalpura halfbreds. The aim of the present study was to identify FecB mutation in sexually mature GarolexMalpura rams by forced RFLP-PCR of BMPR-1B gene and evaluate: (i) semen production and sperm motion characteristics of GM rams and (ii) influence of age and FecB genotype on their semen attributes. Semen was collected during autumn season from 12 donor rams by artificial vagina on 8 occasions at weekly interval. The overall means of traits which did not differed significantly with age or FecB genotyping were volume (0.72 ml), mass motility (4.44), sperm concentration (2721.56 x 10(6)ml(-1)), curvilinear velocity (134.51 microm/s), motility (81.3%), amplitude of lateral head displacement (6.24 microm), beat frequency (44.43 Hz), sperm head elongation (48.9%) and sperm head area (10.01 microm(2)). The FecB genotyping had a significant effect (P<0.05) on percent linearity and rapid motile sperms, which did not vary significantly with age. Although sperm concentration was higher in FecB(BB) and FecB(B+), compared to FecB(++) genotypes but the effect was non-significant. The age and FecB genotyping had significant effects (P<0.05) on straightness, average path velocity, straight-line velocity and percentage of medium or slow motile sperms. It is concluded that GarolexMalpura rams with introgressed FecB gene are capable of producing good quality semen in a semi-arid tropical climate.     

Screening for Booroola (FecB) and Galway (FecXG) mutations in Indian sheep

This study reports the status of the Booroola (FecB) and Galway (FecX^G) mutations in Indian sheep breeds. The Kendrapada sheep (n = 46) was genotyped for the presence of FecB and FecX^G mutations, while the Garole (n = 34), Malpura (n = 30), and Decanni sheep (n = 15) for the FecX^G mutation. The FecB and FecX^G genotyping was carried out by forced restriction fragment length polymorphism PCR technique. In the present study, FecB mutation was discovered in the Kendrapada sheep of Orissa, which is now the second prolific sheep of India after the Garole. Out of 46 individuals of Kendrapada sheep, 26 were homozygous (BB), 15 heterozygous (B+) and 5 non-carriers (++) for the FecB mutation. The frequency of the FecB allele in this sample was about 0.73. Results indicated that the frequency of the FecB mutation is high, but the gene is not fixed in the population as reported in Garole sheep. None of sheep breeds carried the FecX^G mutation. The discovery of the FecB mutation in Kendrapada sheep will facilitate the use of FecB allele in improving the prolificacy of non-prolific sheep breeds of India.     

Genes encoding the alpha and beta chains of follicle-stimulating hormone are not sites for the Booroola (FecB) mutation in sheep.

Bovine cDNA probes for the beta-subunit of follicle-stimulating hormone beta (FSH beta) and the alpha-subunit of the glycoprotein hormones identify genetic variation (polymorphic restriction fragments) near these genes in sheep. The inheritance of the polymorphic restriction fragments was studied in half-sibling pedigrees generated by mating heterozygous (B+) rams to non-carrier (++) ewes so that the co-inheritance or genetic linkage to the Booroola (FecB) locus and the alpha- and beta-subunits of FSH could be analysed. Genetic recombination was observed between the FSH beta locus and the FecB locus in all five families studied and between the alpha-subunit and the FecB locus in the two families studied. We conclude that the FecB mutation does not lie within the FSH beta- or alpha-subunit genes encoding the heterodimeric hormone FSH, and that the high concentrations of FSH observed in carrier ewes must result from indirect actions of the FecB mutation on the synthesis, processing, storage, release or metabolism of FSH.     

Investigation of Prolific Sheep from UK and Ireland for Evidence on Origin of the Mutations in BMP15 (FecXG,FecXB) and GDF9 (FecGH) in Belclare and Cambridge Sheep

This paper concerns the likely origin of three mutations with large effects on ovulation rate identified in the Belclare and Cambridge sheep breeds; two in the BMP15 gene (FecX^G and FecX^B) and the third (FecG^H) in GDF9. All three mutations segregate in Belclare sheep while one, FecX^B, has not been found in the Cambridge. Both Belclare and Cambridge breeds are relatively recently developed composites that have common ancestry through the use of genetic material from the Finnish Landrace and Lleyn breeds. The development of both composites also involved major contributions from exceptionally prolific ewes screened from flocks in Ireland (Belclare) and Britain (Cambridge) during the 1960s. The objective of the current study was to establish the likely origin of the mutations (FecX^G, FecX^B and FecG^H) through analysis of DNA from Finnish Landrace and Lleyn sheep, and Galway and Texel breeds which contributed to the development of the Belclare breed. Ewes with exceptionally high prolificacy (hyper-prolific ewes) in current flocks on Irish farms were identified to simulate the screening of ewes from Irish flocks in the 1960s. DNA was obtained from: prolific ewes in extant flocks of Lleyn sheep (n = 44) on the Lleyn peninsula in Wales; hyper-prolific ewes (n = 41); prolific Galway (n = 41) ewes; Finnish Landrace (n = 124) and Texel (n = 19) ewes. The FecX^G mutation was identified in Lleyn but not in Finnish Landrace, Galway or Texel sheep; FecX^B was only found among the hyper-prolific ewes. The FecG^H mutation was identified in the sample of Lleyn sheep. It was concluded from these findings that the Lleyn breed was the most likely source of the FecX^G and FecG^H mutations in Belclare and Cambridge sheep and that the FecX^B mutation came from the High Fertility line that was developed using prolific ewes selected from commercial flocks in Ireland in the 1960′s and subsequently used in the genesis of the Belclare.