Myostatin and its implications on animal breeding: a review.

Myostatin, or growth and differentiation factor 8 (GDF8), has been identified as the factor causing a phenotype known as double muscling, in which a series of mutations render the gene inactive, and therefore, unable to regulate muscle fibre deposition. This phenotype occurs at a high frequency in some breeds of cattle such as Belgian Blue and Peidmontese. Phylogenetic analysis has shown that there has been positive selection pressure for non-synonymous mutations within the myostatin gene family, around the time of the divergence of cattle, sheep and goats, and these positive selective pressures on non-ancestral myostatin are relatively recent. To date, there have been reports of nine mutations in coding regions of myostatin that cause non-synonymous changes, of which three cause missense mutations, including two in exon 1 and one in exon 2. The remaining six mutations, located in exons 2 and 3, result in premature stop codons, which are the mutations responsible for the double-muscling phenotype. Unfortunately, breed management problems exist for double-muscled cattle, such as birthing difficulties, which can be overcome through genetically controlled breeding programmes, as shown in this review.

Identification of two new C4 alleles by DNA sequencing and evidence for a historical recombination of serologically defined C4A and C4B alleles.

Nucleotide polymorphisms of the C4 genes were investigated by direct sequencing of seven different homozygous typing cells from the 10IHW panels. Two novel sequences were identified within the C4d region of the C4 genes. Our sequencing analyses extend previous findings suggesting that a recombination hot spot is likely to have occurred between codon positions 1157 and 1186 within the C4d region. The classification of electrophoretically defined C4A and C4B alleles can be further subtyped by sequencing. Because the central major histocompatibility complex region that carries various copies of the C4 gene has been associated with a range of disorders; further analysis at the sequence level within the C4 locus may provide informative genetic markers for the investigation of disease-associated polymorphisms.

Corneodesmosin DNA polymorphisms in MHC haplotypes and Japanese patients with psoriasis.

In order to examine the relationship between corneodesmosin (CDSN) and psoriasis we have determined the presence of CDSN polymorphisms by DNA sequencing in (a) nine B-LCL cell lines of major histocompatibility complex ancestral haplotypes known to be associated with psoriasis vulgaris including 13.1AH, 46.1AH, 46.2 and 57.1AH, and in (b) a group of 267 unrelated individuals comprising Japanese psoriasis patients (n = 101) and Japanese subjects without the disease (n = 166). Three novel CDSN gene sequences were identified. In addition, we have classified the 18 alleles into seven main groups based on phylogeny of non-synonymous substitutions. However, we have found no statistically significant differences between the patients and the unaffected individuals in any of these groups. These findings indicate that CDSN is not a major psoriasis susceptibility gene.

Sequence analysis of the MHC class I region reveals the basis of the genomic matching technique.

The genomic matching technique (GMT) improves survival following bone marrow transplantation (BMT) between unrelated donor and recipient pairs correlating with a decrease in incidence and severity of graft-versus-host disease (GvHD). The principles of this technique are based on the duplication and polymorphic characteristics of the major histocompatibility complex (MHC). Specifically, the beta block GMT matches for a 300 kb region that contains the human leukocyte antigen (HLA-B and -C) genes as well as other non-HLA genes such as the natural killer cell receptor ligand PERB11 (MIC). The block contains two large segmental duplications. One results in two PERB11 genes (11.1 and 11.2), the other in two class I genes (HLA-B and -C). With the complete sequencing of the class I region of the MHC in different haplotypes, we can now show that the beta block GMT profiles reflect amplification of the duplicated PERB11 segments and not the duplicated segments containing HLA-B and -C, and yet provide a signature that characterizes the entire block rather than individual loci.

Further characterization of MHC haplotypes demonstrates conservation telomeric of HLA-A: update of the 4AOH and 10IHW cell panels.

Cell panels have been used extensively in studies of polymorphism and disease associations within the major histocompatibility complex (MHC), but the results from these panels require continuous updates with the increasing availability of novel data. We present here an updated table of the typings of the 10IHW and 4AOH panels. Local data included are HFE, HERV-K(C4) and six microsatellites telomeric of HLA-A. Typings for class I, MICA (PERB11.1), MICB (PERB11.2), XA, XB, LMP2 and 10 microsatellites reported by others have also been consolidated in this table. The tabulation shows that the length of conservation in the human MHC is even more extensive than previously thought. Human MHC ancestral haplotypes are inherited as a conserved region of genomic sequence spanning some 6-8 megabases from the HLA class II region and beyond the HLA class I region up to and including the HFE gene. Numerous examples of historical recombinations were also observed.

Coevolution of HLA-B and PERB11.1 (MICA): significance of independent triplet expansion within the transmembrane region of PERB11.1 (MICA).

Several highly polymorphic sequences are present in the beta block of the MHC, especially HLA-B, HLA-C, PERB11.1 (MICA), and PERB11.2 (MICB). It is now apparent that the polymorphism of PERB11.1 is of the same order as that of HLA-A, -B, and -C and it has been suggested that PERB11 could explain some of the disease associations previously attributed to HLA-B. Phylogenetic analysis of PERB11 alpha-domain sequences demonstrates relationships with HLA-B cross-reactive serogroups. In contrast, the transmembrane polymorphisms do not appear to be associated with either PERB11 or HLA-B. These data indicate that PERB11 and HLA-B have evolved in concert from their common ancestors and that the transmembrane polymorphisms have arisen independently and more recently. MHC disease associations will need to be reviewed in the light of mechanisms such as receptor binding and signaling.

PERB11 (MIC): a polymorphic MHC gene is expressed in skin and single nucleotide polymorphisms are associated with psoriasis.

The susceptibility genes for psoriasis remain to be identified. At least one of these must be in the major histocompatibility complex (MHC) to explain associations with alleles at human leucocyte antigen (HLA)-A, -B, -C, -DR, -DQ and C4. In fact, most of these alleles are components of just two ancestral haplotypes (AHs) designated 13.1 and 57.1. Although relevant MHC gene(s) could be within a region of at least 4 Mb, most studies have favoured the area near HLA-B and -C. This region contains a large number of non-HLA genes, many of which are duplicated and polymorphic. Members of one such gene family, PERB11.1 and PERB11.2, are expressed in the skin and are encoded in the region between tumour necrosis factor and HLA-B. To investigate the relationship of PERB11.1 alleles to psoriasis, sequence based typing was performed on 97 patients classified according to age of onset and family history. The frequency of the PERB11.1*06 allele is 44% in type I psoriasis but only 7% in controls (Pc = 0.003 by Fisher's exact test, two-tailed). The major determinant of this association is a single nucleotide polymorphism (SNP) within intron 4. In normal and affected skin, expression of PERB11 is mainly in the basal layer of the epidermis including ducts and follicles. PERB11 is also present in the upper keratin layers but there is relative deficiency in the intermediate layers. These findings suggest a possible role for PERB11 and other MHC genes in the pathogenesis of psoriasis.

The significance of HLA matching in cardiac transplantation.

It is argued that HLA matching is not worthwhile in heart transplantation. However, transplanting HLA compatible hearts enhances graft survival and should significantly reduce infection and malignancies related to aggressive immunosuppression. It is our view that the problem is technical and we offer a potential solution.

Reconstruction of the block matching profiles.

Block matching is a valuable tool for selecting donors for bone marrow transplantation. Identical, electrophoretic profiles of unrelated bone marrow donor-recipient pairs have been shown to be associated with long-term survival and a reduction of graft versus host disease (GVHD). This study was undertaken to determine the sequences of the PCR products which are generated. PCR products obtained with beta-block primers following the amplification of DNA extracted from cell lines homozygous for 7.1 and 8.1 ancestral haplotypes were cloned and sequenced. The PCR products were characterised and the beta block profiles reconstructed. The data indicate that the profiles consist of homoduplexes and heteroduplexes which are formed by the products of probably 3 different sequence locations.

Linkage of chromosome 5q and 11q gene markers to asthma-associated quantitative traits in Australian children.

Asthma is a genetically complex disease, and the investigation of putative linkages to candidate loci in independent populations is an important part of the gene discovery process. This study investigated the linkage of microsatellite markers in the 5q and 11q regions to asthma-associated quantitative traits in 121 Australian Caucasian nuclear families. The families were recruited on the basis of a child proband: a cohort of 95 randomly recruited families of unselected probands (n = 442 subjects) and a cohort of 26 families of probands selected on the basis of severe symptomatic asthma (n = 134 subjects). The quantitative traits assessed included serum levels of total IgE and specific IgE to house dust mite and mixed grass, blood eosinophil counts, and the dose-response slope (DRS) of FEV1 to histamine provocation. Multipoint linkage analysis using Haseman-Elston sib-pair methods provided evidence of significant linkage between the chromosome 5q markers and loge total serum IgE levels, specific serum IgE levels, and loge blood eosinophil counts. The chromosome 11q markers showed evidence of significant linkage to specific serum IgE levels. Neither region demonstrated significant linkage to the loge DRS to histamine. Phenotypes were residualized for age and sex. These data are consistent with the existence of loci regulating asthma-associated quantitative traits in both the 5q31-33 and 11q13 chromosomal regions.

MHC haplotype analysis by artificial neural networks.

Conventional matching is based on numbers of alleles shared between donor and recipient. This approach, however, ignores the degree of relationship between alleles and haplotypes, and therefore the actual degree of difference. To address this problem, we have compared family members using a block matching technique which reflects differences in genomic sequences. All parents and siblings had been genotyped using conventional MHC typing so that haplotypes could be assigned and relatives could be classified as sharing 0, 1 or 2 haplotypes. We trained an Artificial Neural Network (ANN) with subjects from 6 families (85 comparisons) to distinguish between relatives. Using the outputs of the ANN, we developed a score, the Histocompatibility Index (HI), as a measure of the degree of difference. Subjects from a further 3 families (106 profile comparisons) were tested. The HI score for each comparison was plotted. We show that the HI score is trimodal allowing the definition of three populations corresponding to approximately 0, 1 or 2 haplotype sharing. The means and standard deviations of the three populations were found. As expected, comparisons between family members sharing 2 haplotypes resulted in high HI scores with one exception. More interestingly, this approach distinguishes between the 1 and 0 haplotype groups, with some informative exceptions. This distinction was considered too difficult to attempt visually. The approach provides promise in the quantification of degrees of histocompatibility.

Homology models for the PERB11 multigene family.

BACKGROUND: PERB11 is a multicopy polymorphic gene family found in association with HLA Class I genes within the major histocompatibility complex (MHC). Although its function is unknown, PERB11 has sequence similarities to HLA Class I and other related proteins. To explore the possible functional roles for PERB11, homology models have been constructed using both HLA Class I and Class I-like protein structures as templates. RESULTS: The models show that PERB11.1 appears to have an unusual distribution of charged residues that potentially give the molecule a distinct polarity. Furthermore, a cluster of negatively charged residues in the traditional P2 site may form a novel binding site for a positively charged ligand such as a metal ion or complex. Other charged residues line the floor and walls of the cleft and are able to form salt bridges, reminiscent of the closed cleft of the Class I-like mouse neonatal Fc receptor structure. The closely related PERB11.2 family has a different arrangement of charged residues in the cleft, but these residues are still able to form salt bridges. Unlike HLA Class I, the majority of polymorphic positions in the PERB11 family occur outside the cleft and on the surface of the molecule. CONCLUSIONS: Homology models for PERB11 suggest that the structure is capable of associating with beta2 microglobulin or a similar molecule. Furthermore, not all of the potential glycosylation sites suggested by the PERB11 sequences appear viable. Importantly, the models suggest that the molecule has a less accessible cleft than HLA Class I and is not, therefore, able to bind peptides. Other small ligands, including metal ions, might be bound, however.

Sequencing of 42kb of the APO E-C2 gene cluster reveals a new gene: PEREC1.

Through the sequencing of a 42kb cosmid clone we describe a new gene, designated PEREC1, located approximately 1.5kb centromeric of the human apolipoprotein (APO) E-C2 cluster. The combination of dotplot analysis, predicted coding potential and interrogation of the Expressed Sequence Tag (EST) database determined the genomic organisation of PEREC1. Sequence alignment with multiple overlapping ESTs confirmed the predicted splice sites. The predicted cDNA and amino acid sequences of PEREC1 have extensive similarity to the Caenorhabditis elegans protein, C18E9.6. Conserved structural and functional motifs have been defined by combining nucleotide and amino acid analyses to identify third base degeneracy and therefore selection at the protein level. The Poliovirus Receptor Related Protein2 gene (PRR2), previously mapped to chromosome 19q13.2 by Fluorescent In-Situ Hybridisation, has also been located approximately 17kb centromeric of APO E.

Conservation of ancestral haplotypes telomeric of HLA-A.

Genes that predispose to haemochromatosis are though to be located within the several megabases telomeric of HLA-A. Further recombinant mapping has been used previously to map susceptibility genes for diseases such as insulin-dependent diabetes mellitus, myasthenia gravis and cystic fibrosis, and should be useful in relation to haemochromatosis. However, this method requires the recognition of ancestral haplotypes within the susceptibility region. Using a panel of six microsatellite markers from this region (MOG A, MOG B, MOG C, D6S464, D6S306 and D6S105), we show that ancestral haplotypes extend telomeric of HLA-A, at least as far as D6S105. Nine of 14 haplotypes carrying HLA-B7 and HLA-A3 shared the same microsatellite alleles between HLA-A and at least D6S105. Similarly, nine of 10 haplotypes sharing HLA-B8 and HLA-A1 shared the same microsatellite alleles, although a different set to those with HLA-B7 and HLA-A3. Haplotypes representing historical recombination events were also identified. These two findings demonstrate that recombinant mapping may be applicable to the mapping of disease genes in this region.

The major histocompatability complex (MHC) contains conserved polymorphic genomic sequences that are shuffled by recombination to form ethnic-specific haplotypes.

The major histocompatibility complex (MHC) consists of polymorphic frozen blocks (PFBs) that are linked to form megabase haplotypes. These blocks consist of polymorphic sequences and define regions where recombination appears to be inhibited. We have been able to show, using a highly polymorphic sequence centromeric of HLA-B (within the beta block), that PFBs are conserved and contain specific insertions/deletions and substitutions that are the same for individuals with the same MHC haplotype but that differ between at least most different haplotypes. A sequence comparison between ethnic-specific haplotypes shows that these sequences have remained stable and predate the formation of these haplotypes. To determine whether the same conserved block has been involved in the generation of multiple haplotypes, we compared the block typing profiles of different ethnic specific haplotypes. Block typing profiles have previously been shown to be identical in individuals with the same MHC haplotype but, generally, to differ between different haplotypes. It was found that some PFBs are common to more than one haplotype, implying a common ancestry. Subsequently, haplotypes have been generated by the shuffling and exchange of these PFBs. The regions between these PFBs appear to permit the recombination sites and therefore could be expected to exhibit either low polymorphism or a localized "hotspot."

The identification of MHC identical siblings without HLA typing.

By comparing genomic sequences of different MHC haplotypes, we defined highly polymorphic markers. After amplification, electrophoresis, and scanning with a laser, we have identified profiles that serve as signatures of the haplotype and its component alleles. One set of markers can be used to define the block that includes HLA-B and HLA-C, among other loci. Another set provides signatures for the entire HLA-DR and -DQ multigene cluster. By profile overlay, it is possible to identify siblings who share both haplotypes from HLA-C to HLA-DQ. Here we demonstrate the value of genomic analysis ("block matching") in selecting genotypically identical siblings prior to transplantation. Forty-six siblings from 10 families were genotyped by family analysis after meticulous HLA, C4, and Bf typing including molecular methods for HLA-DRB1. In 43 siblings, the haplotype assignments were unequivocal. Twenty-two identical sibling pairs could then be compared with 77 nonidentical pairs. Independent genomic analysis yielded entirely concordant results. In three siblings, the possibility of parental recombination was considered but could not be defined by the conventional typing. By genomic analysis, however, it was clear that recombination had indeed occurred in one case. In the remaining two cases, additional, more telomeric markers will be necessary to resolve the issue. This simple, cost-effective method has immediate application to the identification of matched pairs (HLA-C to HLA-DQ) for bone marrow and renal transplantation.

Matching for MHC haplotypes results in improved survival following unrelated bone marrow transplantation.

Unrelated bone marrow donor-recipient pairs were assessed retrospectively for matching of the HLA-B, -C region (beta-block) and HLA-DR, DQ region (delta block) of the major histocompatibility complex (MHC) using a new DNA-based method referred to as MHC-block typing. The method utilises non-HLA DNA polymorphisms in the MHC as markers of blocks of ancestral haplotypes. Kaplan-Meier analysis of recipients who were matched at both the beta- and delta-blocks revealed a 6 months survival of 54%. Survival was better than for patients who were matched only by conventional criteria, including SSO-typing for class II.

Genomic MHC haplotyping of mutant cell lines using a novel marker.

The aim of this study was to characterize MHC mutant cell lines by studying haplospecific markers within the MHC and specifically in the 250 kilobase (kb) region between the HLA B and TNF loci. This region has been difficult to define because of the lack of appropriate markers. Spontaneous MHC mutants were isolated after immunoselection with an anti-HLA A2 monoclonal antibody and complement. Ten mutants were characterized using serological or allelic and genomic DNA markers within the HLA A to HLA DQ region of the MHC. Most mutants lost at least the 3 megabases of DNA from HLA A to HLA DQ viz the whole haplotype carrying HLA A2. Variants which have lost either HlA A alone or HLA A and HLA B were also found. The results show that it is possible to map the extent of the deletion between HLA B and TNF. Haplospecific scanning patterns for the CL region appear particularly useful.