Parentage testing and linkage analysis in the horse using a set of highly polymorphic microsatellites

Ten (TG)_n positive clones, isolated from an equine genomic library and sequenced, contained 12–19 uninterrupted TG repeats. Primers for polymerase chain reaction (PCR) were synthesized and nine of these (TG)_n loci (HTG7-15) were successfully amplified and utilized in this study together with five previously reported equine microsatellite loci (HTG2-6). The PCR products were analysed by polyacrylamide gel electrophoresis followed by automated laser fluorescence detection or autoradiography. All microsatellites showed polymorphism and stable Mendelian inheritance. Differences in microsatellite variability between horse breeds were detected. A linkage analysis comprising HTG2-15, one coat colour gene and 16 genetic blood markers enabled addition of HTG2 to linkage group U2 and a new linkage group (U6) was established comprising the loci HTG7 and HTG12. Close linkage was excluded within a set of eight microsatellites. The estimated probability of exclusion in four breeds for a parentage test based on these eight loci varied between 0.96 and 0.99.     

Gametic phase disequilibrium between the syntenic multiallelic HTG4 and HMS3 markers widely used for parentage testing in Thoroughbred horses

Validation of parentage and horse breed registries through DNA typing relies on estimates of random match probabilities with DNA profiles generated from multiple polymorphic loci. Of the twenty-seven microsatellite loci recommended by the International Society for Animal Genetics for parentage testing in Thoroughbred horses, eleven are located on five chromosomes. An important aspect in determining combined exclusion probabilities is the ascertainment of the genetic linkage status of syntenic markers, which may affect reliable use of the product rule in estimating random match probabilities. In principle, linked markers can be in gametic phase disequilibrium (GD). We aimed at determining the extent, by frequency and strength, of GD between the HTG4 and HMS3 multiallelic loci, syntenic on chromosome 9. We typed the qualified offspring (n ₁ = 27; n ₂ = 14) of two Quarter Bred stallions (registered by the Brazilian Association of Quarter Horse Breeders) and 121 unrelated horses from the same breed. In the 41 informative meioses analyzed, the frequency of recombination between the HTG4 and HMS3 loci was 0.27. Consistent with genetic map distances, this recombination rate does not fit to the theoretical distribution for independently segregated markers. We estimated sign-based D′ coefficients as a measure of GD, and showed that the HTG4 and HMS3 loci are in significant, yet partial and weak, disequilibrium, with two allele pairs involved (HTG4*M/HMS3*P, D′(+) = 0.6274; and HTG4*K/HMS3*P, D′(−) = −0.6096). These results warn against the inadequate inclusion of genetically linked markers in the calculation of combined power of discrimination for Thoroughbred parentage validation.     

A medium density microsatellite map of BTA10: reassignment of INRA69

We have developed a genetic map of BTA10 based on 8952 informative meioses for 13 microsatellite markers and the erythrocyte antigen Z. With the exception of OarAE64 , the support for the order of all loci in the map exceeded a LOD > 3·0. The length of the BTA10 genetic map was 87·0 centimorgans (cM). The 14-marker, sex-average map in Kosambi cM was: CSSM38 –8·9- BM1237 –5·2- HH8A –2·6- INRA69 –10·6- TGLA378 –0·8- BM6305 –17·2- TGLA102 –17·9- INRA96 –0·3- CSRM60 –9·2- DIK20 –3·0- EAZ –6·7- CSSM46 –3·7- SRCRSP3 –1·0- OarAE64 with an average interval of 6·70 cM. The microsatellite INRA69 was recently assigned to the pseudoautosomal region of the bovine X chromosome by linkage analysis. However, we found that twopoint support for linkage between INRA69 and 15 X-linked bovine microsatellites was LOD < 0·50 in 529 reciprocal backcross and F₂ fullsib progeny. We performed twopoint analyses of INRA69 against 275 markers distributed throughout the bovine genome and found significant associations with a LOD > 3·0 only between INRA69 and eight BTA10 microsatellite loci. Consequently, we excluded INRA69 from the genetic map of the X chromosome and reassign this microsatellite to BTA10.     

Synteny-mapping horse microsatellite markers using a heterohybridoma panel

A panel of horse-mouse heterohybridoma cells was tested for genetic markers using biochemical and polymerase chain reaction-(PCR-) based tests. Biochemical markers included phospho-glucomutase ( PGM ), glucose phosphate isomerase ( GPI ) and 6-phosphogluconate dehydrogenase ( PGD ). Markers detected using PCR-based tests included microsatellite markers HTG2–15, HMS 1–3, 5–8, VHL20, ECA2 and genes for equine major histocompatibility gene ELA-DRA , tumour necrosis factor alpha (TNFA) and transferrin. The results were analysed for correlation and concordance. Based on the results, five synteny groups were identified, specifically between ELA-DRA, TNFA, HMS5 and HTG5 ; between HTG3 and HTG13 ; between HTG4, HTG8 and HMS3 ; between HTG6 and HMS1 ; and between HTG7, HTG9 and HMS6. Evidence was also found for synteny between HTG12, HMS7 and ECA2 , however, confirmation requires further testing. Cytogenetic evaluation of the cell lines making up the panel indicated that large metacentric chromosomes were preferentially lost or tended to break at the centromere. Consequently, the results from this analysis can be used to identify synteny, but not to exclude synteny.     

Development of new VNTR markers for pike and assessment of variability at di- and tetranucleotide repeat microsatellite loci

Levels of variation at six VNTR (variable number of tandem repeats) loci, one minisatellite and five microsatellite loci, isolated from tri- and tetranucleotide enriched DNA libraries for northern pike were generally low in two Danish populations (1–4 alleles; expected heterozygosity 0–0·57), though one highly variable microsatellite (13 alleles; expected heterozygosity 0·79) was identified. In combination with previously published microsatellites a set consisting of nine polymorphic loci appeared to be useful for discriminating populations, as determined by assignment tests.     

The epitheliogenesis imperfecta locus maps to equine chromosome 8 in American Saddlebred horses

Epitheliogenesis imperfecta (EI) is a hereditary junctional mechanobullous disease that occurs in newborn American Saddlebred foals. The pathological signs of epitheliogenesis imperfecta closely match a similar disease in humans known as Herlitz junctional epidermolysis bullosa, which is caused by a mutation in one of the genes (LAMA3, LAMB3 and LAMC2) coding for the subunits of the laminin 5 protein (laminin alpha3, laminin beta3 and laminin gamma2). The LAMA3 gene has been assigned to equine chromosome 8 and LAMB3 and LAMC2 have been mapped to equine chromosome 5. Linkage disequilibrium between microsatellite markers that mapped to equine chromosome 5 and equine chromosome 8 and the EI disease locus was tested in American Saddlebred horses. The allele frequencies of microsatellite alleles at 11 loci were determined for both epitheliogenesis imperfecta affected and unaffected populations of American Saddlebred horses by genotyping and direct counting of alleles. These were used to determine fit to Hardy-Weinberg equilibrium for control and EI populations using Chi square analysis. Two microsatellite loci located on equine chromosome 8q, ASB14 and AHT3, were not in Hardy-Weinberg equilibrium in affected American Saddlebred horses. In comparison, all of the microsatellite markers located on equine chromosome 5 were in Hardy-Weinberg equilibrium in affected American Saddlebred horses. This suggested that the EI disease locus was located on equine chromosome 8q, where LAMA3 is also located.     

A consensus linkage map for swine chromosome 7

The First International Workshop on Swine Chromosome 7 (SSC7) was held in Minnesuing, Wisconsin, USA on 21–24 September 1995. The objective was to develop a comprehensive linkage map for porcine chromosome 7 by combining genotypic data from four swine reference populations. Contributions of genotypic data were made from the US Meat Animal Research Center, the University of Minnesota, the PiGMaP consortium and the Scandinavian consortium. Primers for selected sequence tagged site markers, to be genotyped across the reference populations, were exchanged to integrate individual maps of SSC7. Eighty-six loci were genotyped; these loci represented microsatellite, minisatellite, single-strand conformation polymorphism, restriction fragment length polymorphism, erythrocyte antigen and protein polymorphisms. Eighteen genes were mapped, including 12 markers within class I, class II and class III regions (four markers in each class) of the swine major histocompatibility complex. Forty-two markers were either genotyped on more than one population or were included in a haplotype system and used to develop skeletal linkage maps that spanned 147·6, 212·7 and 179·5 cM for the male, female and sex-average maps, respectively. A comprehensive linkage map was developed incorporating those markers with more than 30 informative meioses. The comprehensive map was slightly longer than the skeletal map, at 153·3, 215·3 and 183·8 cM, respectively, with only three intervals greater than 10 cM. These results significantly improve the genetic resolution of the porcine chromosome 7 map and represent an accurate approach for the merging of genetic maps produced in different reference populations.     

Linkage and physical mapping of prolactin to porcine chromosome 7

Comparative mapping studies between human and pig have shown that there is conserved synteny between human chromosome 6 and pig chromosomes 1 and 7, but some gene locations are not well established. Prolactin ( PRL ), an anterior pituitary hormone, has been mapped to human chromosome 6, and has tentatively mapped to pig chromosome 7 using Southern-RFLP analysis with a limited number of meioses. To confirm the assignment of prolactin to porcine chromosome 7 by physical and linkage analysis, pig cDNA and human genomic DNA sequences were used to design pig-specific PCR primers. The primers amplified a fragment of ≈2·8 kb. Two polymorphic restriction sites were identified within this fragment with the restriction endonuclease Bst UI. Prolactin was significantly linked to six markers on the published PiGMaP map of pig chromosome 7. Prolactin was physically mapped using a pig × rodent somatic cell hybrid panel. An analysis of these data placed PRL on pig 7p1·1–p1·2 with 100% concordance and was in complete agreement with the linkage data. Both mapping techniques placed PRL in a conserved order with the loci in the syntenic region of human chromosome 6.     

Linkage mapping of AFLP and microsatellite DNA markers with the body color- and sex-determining loci in the guppy (Poecilia reticulata)

The guppy is an ornamental fish species that exhibits various phenotypic characteristics, such as body color and fin-shape. Although linkage relationships of a limited number of phenotypic traits have already been investigated, the association between phenotypic and molecular markers is still unknown. We constructed a total of 35 linkage groups for the guppy using 186 polymorphic loci of AFLP and microsatellite DNA. The locus related to the yellow body color was linked with ten markers and the sex-determination locus was linked with five markers.     

猪F2设计资源家系中4条染色体微卫星标记分析

利用中国地方猪种蓝塘猪(16头母猪)与外来品种长白猪(8头公猪)按F2设计建立资源家系, 根据美国肉畜中心(USDA-MARC 2.0)公布的猪连锁图谱, 在1、4、7和8号染色体上间隔10~20 cM选择一个微卫星标记, 共31个标记, 采用WAVEÒ核苷酸片段分析系统和ABI 377 DNA序列分析仪检测资源群体的P、F1和F2代个体微卫星的基因型, 对其基因频率、杂合度和多态信息含量等进行统计分析。结果发现: 利用ABI 377检测的猪1、4和8号染色体上的有效微卫星标记21个, 其中13个标记的18个等位基因片段大小超过了网上已报道的结果, 发现新等位基因的标记占62%; 在31个微卫星标记中, 杂合度(h)在0.043~0.7855之间, 总平均杂合度为0.6460, 其中70%座位的h>0.60; 总平均多态信息含量(PIC)为0.5949, 有77.4%位点的PIC>0.5。统计分析结果表明, 选用的微卫星标记能够较好地提供标记信息, 为进一步在该家系中进行猪重要性状的QTL定位打下了良好的基础。     

Mapping 28 erythrocyte antigen, plasma protein and enzyme polymorphisms using an efficient genomic scan of the porcine genome

One hundred and fifty-four microsatellite markers were selected for genomic scanning of the porcine genome and were grouped into amplification sets to reduce the cost and labour required. Thirty amplification sets had two markers (duplex), 20 sets had three markers (triplex) and five sets had four markers (quadruplex) while 14 markers were analysed separately. The selection criteria for microsatellites were: ease of scoring, level of polymorphism, genetic location and ability to be genotyped in a multiplexed polymerase chain reaction (PCR). The selected microsatellites were chosen to span the entire genome flanked by the porcine linkage map with intervals between adjacent markers of 15–20 cM where possible. The utility of this set of markers was demonstrated by linkage analyses with loci controlling blood plasma protein and red cell enzyme polymorphisms ( n = 13), erythrocyte antigens ( n = 15), the S blood group, coat colour and ryanodine receptor from 174 backcross Meishan-White Composite pigs. These loci displayed various forms of inheritance and most (24 loci) have been placed in linkage groups. Significant two-point linkages (lod > 3·0) were detected for each polymorphic marker. These results provide the first linkage assignments for phosphoglucomutase (PGM2) and erythrocyte antigen F (EAF) to SSC8; and serum amylase (AMY) and erythrocyte antigen I (EAI) to SSC18. All of the remaining polymorphic loci ( n = 24) mapped to previously identified regions confirming earlier results. Most of the markers used in this study should be useful in resource populations of various breed crosses as the number of alleles detected in a multibreed reference population was one of the selection criteria.     

Bovine microsatellite loci are highly conserved in red deer (Cervus elaphus), sika deer (Cervus nippon) and Soay sheep (Ovis aries)

We tested 174 bovine microsatellite primer pairs for use in a primitive breed of sheep and two species of deer. Of 173 markers, 127 (73·4%) gave a product in Soay sheep ( Ovis aries ) of which 54 (42·5%) were polymorphic. One hundred and twenty-nine of 174 (74·1%) markers gave a product in red deer ( Cervus elaphus ) of which 72 (55·8%) were polymorphic. In sika deer ( Cervus nippon ) 126 of 171 (73·7%) microsatellite primers gave a product with 47 (37·3%) polymorphic. The proportion of bovine microsatellite loci conserved across artiodactyl species was significantly greater in this study than previously reported. Reasons for this high degree of microsatellite conservation are discussed. We suggest that a high resolution comparative map of the artiodactyls can be constructed using microsatellites.     

Validation of microsatellite markers for routine horse parentage testing

A parallel testing of 4803 routine Quarter Horse parentage cases, using 15 loci of blood group and protein polymorphisms (blood typing) and 11 loci of dinucleotide repeat microsatellites (DNA typing), validated DNA markers for horse pedigree verification. For the 26 loci, taken together, the theoretical effectiveness of detecting incorrect parentage was 99·999%, making it extremely unlikely that false parentage would fail to be recognized. The tests identified incorrect parentage assignment for 95 offspring (2% of cases). Despite fewer loci, DNA typing was as effective as blood typing and, in parentage exclusion cases, provided more systems to substantiate the genetic incompatibility. Five offspring presented potential genetic incompatibilities with their parents in only a single microsatellite system, but the parentage exclusions could not be confirmed with discordant results at additional loci. Two of these five incompatibilities could be explained as consequences of a null allele and three as fragment size increases or decreases (putative mutations). Provided that an exclusion assignment was based on at least two systems of genetic incompatibility, such rare genetic events did not lead to false exclusions. Notwithstanding the near 100% effectiveness estimations for either typing panel alone to identify incorrect parentage, this validation test showed an actual effectiveness of 97·3% for blood typing and 98·2% for DNA typing. The DNA-based test, however, may feasibly achieve higher efficacy than reported here by adding selected systems to the parentage test panel.     

Genotyping microsatellite DNA markers at putative disease loci in inbred/multiplex families with respiratory chain complex I deficiency allows rapid identification of a novel nonsense mutation (IVS1nt -1) in the NDUFS4 gene in Leigh syndrome

Complex I deficiency, the most common cause of mitochondrial disorders, accounts for a variety of clinical symptoms and its genetic heterogeneity makes identification of the disease genes particularly tedious. Indeed, most of the 43 complex I subunits are encoded by nuclear genes, only seven of them being mitochondrially encoded. In order to offer urgent prenatal diagnosis, we have studied an inbred/multiplex family with complex I deficiency by using microsatellite DNA markers flanking the putative disease loci. Microsatellite DNA markers have allowed us to exclude the NDUFS7, NDUFS8, NDUFV1 and NDUFS1 genes and to find homozygosity at the NDUFS4 locus. Direct sequencing has led to identification of a homozygous splice acceptor site mutation in intron 1 of the NDUFS4 gene (IVS1nt -1, G-->A); this was not found in chorion villi of the ongoing pregnancy. We suggest that genotyping microsatellite DNA markers at putative disease loci in inbred/multiplex families helps to identify the disease-causing mutation. More generally, we suggest giving consideration to a more systematic microsatellite analysis of putative disease loci for identification of disease genes in inbred/multiplex families affected with genetically heterogeneous conditions.     

Dinucleotide Repeat Loci Contribute Highly Informative Genetic Markers to the Human Chromosome 2 Linkage Map

Microsatellite repeat loci can provide informative markers for genetic linkage. Currently, the human chromosome 2 genetic linkage map has very few highly polymorphic markers. Being such a large chromosome, it will require a large number of informative markers for the dense coverage desired to allow disease genes to be mapped quickly and accurately. Dinucleotide repeat loci from two anonymous chromosome 2 genomic DNA clones were sequenced so that oligonucleotide primers could be designed for amplifying each locus using the polymerase chain reaction (PCR). Five sets of PCR primers were also generated from nucleotide sequences in the GenBank Database of chromosome 2 genes containing dinucleotide repeats. In addition, one PCR primer pair was made that amplifies a restriction fragment length polymorphism on the TNP1 gene (Hoth and Engel, 1991). These markers were placed on the CEPH genetic linkage map by screening the CEPH reference DNA panel with each primer set, combining these data with those of other markers previously placed on the map, and analyzing the combined data set using CRI-MAP and LINKAGE. The microsatellite loci are highly informative markers and the TNP1 locus, as expected, is only moderately informative. A map was constructed with 38 ordered loci (odds 1000:1) spanning 296 cM (male) and 476 cM (female) of chromosome 2 compared with 306 cM (male) and 529 cM (female) for a previous map of 20 markers.     

A proposal for standardization in forensic equine DNA typing: allele nomenclature for 17 equine‐specific STR loci

In this study, a proposal is presented for the allele nomenclature of 17 polymorphic STR loci (AHT4, AHT5, ASB2, ASB17, ASB23, CA425, HMS1, HMS2, HMS3, HMS6, HMS7, HTG4, HTG6, HTG7, HTG10, LEX3 and VHL20) for equine genotyping (Equus caballus). The nomenclature is based on sequence data of the polymorphic region of the STR loci as recommended by the DNA commission of the International Society for Forensic Genetics for human DNA typing. For each STR locus, several alleles were selected and animals homozygous for those alleles were subjected to sequence analysis. The alleles of the 17 STR loci consisted either of simple (10), compound (6) or complex repeat patterns (1). Only a limited number of alleles with the same fragment size showed different repeat structures. The allele designation described here was based on the number of repeats, including all variable regions within the amplified fragment.     

Isolation and genetic characterization of the porcine apolipoprotein E gene

The present report describes the isolation and genetic characterization of the porcine apolipoprotein E (ape-E) gene. A single positive recombinant phage clone containing a 10·7-kb insert was isolated from a porcine genomic library, and a 4·2-kb fragment was subcloned and sequenced. The 4·2-kb fragment contained the entire apo-E gene in addition to upstream and downstream sequences (GenBank accession no. 470240). The porcine apo-E gene is made up of four exons and three introns, and encodes a preapo-E protein comprised of a signal peptide of 18 amino acids and a mature protein of 299 amino acids. The porcine apo-E gene contains a (CG)₁₃ microsatellite marker within intron three. This microsatellite is moderately polymorphic, and at least four alleles were evident at this locus among 10 animals from each of the Yorkshire, Hampshire, Landrace and Duroc breeds. Finally, localization of the porcine apo-E gene to chromosome 6 band q2·1 was determined by fluorescent in situ hybridization and confirmed by genetic linkage analysis.     

Isolation of twenty low stutter di- and tetranucleotide microsatellites for population analyses of walleye pollock and other gadoids

Fourteen tetra- and six dinucleotide microsatellites, which exhibit minimal stuttering following amplification via PCR were developed from walleye pollock Theragra chalcogramma . Most of these loci were isolated from a library enriched for tetranucleotide microsatellites by hybridization of genomic DNA to (gata)₇ oligonucleotides bound to streptavidin-coated paramagnetic beads. The average heterozygosity of these loci is ∼80%, and ranges from 53–95%. Mendelian inheritance was confirmed in five families, each consisting of a minimum of 10 or more offspring. Primer sets for all 20 loci were also evaluated in Arctic cod Boreogadus saida , Pacific cod Gadus macrocephalus , Pacific tomcod Microgadus proximus , sa.ron cod Eleginus gracilis , Pacific hake Merluccius productus , Atlantic cod Gadus morhua , haddock Melanogrammus aeglefinus , blue whiting Micromesistius poutassou , and European hake Merluccius merluccius . In each of these species, 3–19 primer sets amplified variable microsatellite loci. These loci, which exhibit little stutter and moderate to high variability, should be useful population markers in pollock and other gadoid fishes.     

A Preliminary Genetic Linkage Map of the Pacific Abalone Haliotis discus hannai Ino

Preliminary genetic linkage maps were constructed for the Pacific abalone (Haliotis discus hannai Ino) using amplified fragment length polymorphism (AFLP), randomly amplified polymorphic DNA (RAPD), and microsatellite markers segregating in a F₁ family. Nine microsatellite loci, 41 RAPD, and 2688 AFLP markers were genotyped in the parents and 86 progeny of the mapping family. Among the 2738 markers, 384 (including 365 AFLP markers, 10 RAPD markers, and 9 microsatellite loci) were polymorphic and segregated in one or both parents: 241 in the female and 146 in the male. The majority of these markers, 232 in the female and 134 in the male, segregated according to the expected 1:1 Mendelian ratio (α = 0.05). Two genetic linkage maps were constructed using markers segregating in the female or the male parent. The female framework map consisted of 119 markers in 22 linkage groups, covering 1773.6 cM with an average intermarker space of 18.3 cM. The male framework map contained 94 markers in 19 linkage groups, spanning 1365.9 cM with an average intermarker space of 18.2 cM. The sex determination locus was mapped to the male map but not to the female map, suggesting a XY-male determination mechanism. Distorted markers showing excess of homozygotes were mapped in clusters, probably because of their linkage to a gene that is incompatible between two parental populations.     

Localisation of merosin-positive congenital muscular dystrophy to chromosome 4p16.3

The congenital muscular dystrophies (CMD) are a heterogeneous group of autosomal recessive disorders, which present within the first 6 months of life with hypotonia, muscle weakness and contractures, associated with dystrophic changes on skeletal muscle biopsy. We have previously reported a large consanguineous family segregating merosin-positive congenital muscular dystrophy, in which involvement of known CMD loci was excluded. A genome-wide linkage search of the family conducted using microsatellite markers spaced at 10-Mb intervals failed to identify a disease locus. A second scan using a high-density SNP array, however, permitted a novel CMD locus on 4p16.3 to be identified (multipoint LOD score 3.4). Four additional consanguineous CMD families with a similar phenotype were evaluated for linkage to a 4.14-Mb interval on 4p16.3; however, none showed any evidence of linkage to the region. Our findings further illustrate the utility of highly informative SNP arrays compared with standard panels of microsatellite markers for the mapping of recessive disease loci.