Craig A. McLure

Haplotyping of the canine MHC without the need for DLA typing

The genomic matching technique has proven useful in MHC haplotyping in humans. We have adopted a similar approach in Australian cattle dogs and report that genotyping can be achieved with a single assay.

Genomic evolution and polymorphism: segmental duplications and haplotypes at 108 regions on 21 chromosomes.

We describe here extensive, previously unknown, genomic polymorphism in 120 regions, covering 19 autosomes and both sex chromosomes. Each contains duplication within multigene clusters. Of these, 108 are extremely polymorphic with multiple haplotypes. We used the genomic matching technique (GMT), previously used to characterise the major histocompatibility complex (MHC) and regulators of complement activation (RCA). This genome-wide extension of this technique enables the examination of many underlying cis, trans and epistatic interactions responsible for phenotypic differences especially in relation to individuality, evolution and disease susceptibility. The extent of the diversity could not have been predicted and suggests a new model of primate evolution based on conservation of polymorphism rather than de novo mutation.

Extensive genomic and functional polymorphism of the complement control proteins

Using combinations of genomic markers, we describe more than 20 distinct ancestral haplotypes (AH) of complement control proteins (CCPs), located within the regulators of complement activation (RCA) alpha block at 1q32. This extensive polymorphism, including functional sites, is important because CCPs are involved in the regulation of complement activation whilst also serving as self and viral receptors. To identify haplotypes, we used the genomic matching technique (GMT) based on the pragmatic observation that extreme nucleotide polymorphism is packaged with duplicated sequences as polymorphic frozen blocks (PFB). At each PFB, there are many alternative sequences (haplotypes) which are inherited faithfully from very remote ancestors. We have compared frequencies of RCA haplotypes and report differences in recurrent spontaneous abortion (RSA) and psoriasis vulgaris (PV).

Genomic evolution in domestic cattle: Ancestral haplotypes and healthy beef

We have identified numerous Ancestral Haplotypes encoding a 14-Mb region of Bota C19. Three are frequent in Simmental, Angus and Wagyu and have been conserved since common progenitor populations. Others are more relevant to the differences between these 3 breeds including fat content and distribution in muscle. SREBF1 and Growth Hormone, which have been implicated in the production of healthy beef, are included within these haplotypes. However, we conclude that alleles at these 2 loci are less important than other sequences within the haplotypes. Identification of breeds and hybrids is improved by using haplotypes rather than individual alleles.

Novel sequence elements define ancestral haplotypes of the region encompassing complement factor H

The genomic region encompassing complement factor H (CFH) is thought to be important in determining susceptibility to inflammatory diseases such as age-related macular degeneration, but only limited polymorphism has been described. After applying the genomic matching technique to three-generation families and an ethnically diverse reference panel we have demonstrated that the polymorphism resembles that found in the major histocompatibility complex. The different ancestral haplotypes carry either T or C at T1277C but also other more polymorphic alleles over a region of 2 Mb. Thus the association between age-related macular degeneration and T1277 or Y402 actually reflects multiple linked polymorphisms including an indel that cannot be dissected from any direct effect of Y402 and may be more important. We show for the first time that simple algorithms can identify genomic sequence elements that appear to be more useful haplospecific markers than single nucleotide polymorphism or microsatellites.

Amino Acid Patterns Within Short Consensus Repeats Define Conserved Duplicons Shared by Genes of the RCA Complex

Complement control proteins (CCPs) contain repeated protein domains, short consensus repeats (SCRs), which must be relevant to diverse functions such as complement activation, coagulation, viral binding, fetal implantation, and self–nonself recognition. Although SCRs share some discontinuous and imperfect motifs, there are many variable positions and indels making classification in subfamilies extremely difficult. Using domain-by-domain phylogenetic analysis, we have found that most domains can be classified into only 11 subfamilies, designated a, b, c, d, e, f, g, h, i, j, or k and identified by critical residues. Each particular CCP is characterized by the order of representatives of the subfamilies. Human complement receptor 1 (CR1) has ajefbkd repeated four times and followed by ch. The classification crosses CCPs and indicates that a particular CCP is a function of the mix of SCRs. The aje set is a feature of several CCPs including human CR1 and DAF and murine Crry and appears to be associated with the success or failure of implantation inter alia. This approach facilitates genomic analysis of available sequences and suggests a framework for the evolution of CCPs. Units of duplication range from single SCRs, to septamers such as efbkdaj, to extensive segments such as MCP-CR1L. Imperfections of duplication with subsequent deletion have contributed to diversification.

Evaluation of the class II region of the major histocompatibility complex of the greyhound with the genomic matching technique and sequence-based typing.

The class II region of the major histocompatibility complex was evaluated in 25 greyhounds by sequence-based typing and the genomic matching technique (GMT). Two new DLA-DRB1 alleles were identified. Twenty-four dogs carried the DLA-DRB1*01201/DQA1*00401/DQB1*01303/DQB1*01701 haplotype, which carries two DQB1 alleles. One haplotype was identified from which DQB1 and DQA1 appeared to be deleted. The GMT enabled detection of DQB1 copy number, discrimination of the different class II haplotypes and the identification of new, possibly biologically relevant polymorphisms.

Almost total protection from age-related macular degeneration by haplotypes of the Regulators of Complement Activation

Age-related macular degeneration (AMD) is the leading cause of blindness in developed countries. It has been proposed that the polymorphism encoding Y402H (T1277C) in the complement factor H gene (CFH) is one of the main determinants of disease. We genotyped the polymorphism at a number of loci in the region encompassing the Regulators of Complement Activation (RCA) on chromosome 1, including T1277C SNP, in 187 patients and 146 controls. Haplotypes have been classified as protective (P) or susceptible (S) with respect to AMD. This included the identification of an S haplotype with a T at 1277. The results show that no single locus should be assumed to be directly responsible for AMD, but rather argue for the existence of RCA haplotypes, which can be assigned meaningful predictive values for AMD. We conclude that the critical sequences are within a region 450 kb centromeric to 128 kb telomeric of CFH.

Genomic analysis reveals a duplication of eight rather than seven short consensus repeats in primate CR1 and CR1L: evidence for an additional set shared between CR1 and CR2

We report the discovery of previously unrecognised short consensus repeats (SCRs) within human and chimpanzee CR1 and CR1L. Analysis of available genomic, protein and expression databases suggests that these are actually genomic remnants of SCRs previously reported in other complement control proteins (CCPs). Comparison with the nucleotide motifs of the 11 defined subfamilies of SCRs justifies the designation g-like because of the close similarity to the g subfamily found in CR2 and MCP.To date, we have identified five such SCRs in human and chimpanzee CR1, one in human and chimpanzee CR1L, but none in either rat or mouse Crry in keeping with the number of internal duplications of the long homologous repeat (LHR) found in CR1 and CR1L. In fact, at the genomic level, the ancestral LHR must have contained eight SCRs rather than seven as previously thought. Since g-like SCRs are found immediately downstream of d SCRs, we suggest that there must have been a functional dg set which has been retained by CR2 and MCP but which is degenerate in CR1 or CR1L. Interestingly, dg is also present in the CR2 component of mouse CR1. The degeneration of the g SCR must have occurred prior to the formation of primate CR1L and prior to the duplication events which resulted in primate CR1. In this context, the apparent conservation of g-like SCRs may be surprising and may suggest the existence of mechanisms unrelated to protein coding.These results provide examples of the many processes which have contributed to the evolution of the extensive repertoire of CCPs.