Reconsideration of blood donation testing strategy for human T-cell lymphotropic virus in Australia

BACKGROUND AND OBJECTIVES

Universal testing of blood donations for human T-cell lymphotropic virus (HTLV) in Australia may no longer be appropriate given the low prevalence of HTLV infection and the mitigating effect of universal leucodepletion for cellular components. This study aimed to determine the most appropriate HTLV testing strategy using the Risk-Based Decision-Making Framework for Blood Safety.

MATERIALS AND METHODS

The risk of HTLV transfusion-transmission using three testing strategies (universal, new-donor and no testing) and cost-effectiveness of the first two strategies were assessed using adaptations of published mathematical models.

RESULTS

The overall prevalence for 2004-2014 was three HTLV-positives per million donations. It was estimated that annually, universal testing incurred a cost of approximately AUD $3 million and prevented 83 HTLV-positive cellular components from being issued, and new-donor testing cost approximately $225 000 and prevented 81 components. The number of cases of transfusion-transmitted HTLV and HTLV-associated disease prevented per year by universal and new-donor testing was essentially equivalent. According to preset risk thresholds, the risk of transfusion-transmission was negligible for universal and new-donor testing, and minimal without testing.

CONCLUSION

Transfusion-transmission of HTLV is a minimal risk in Australia even without testing. However, any revision of testing strategy must consider not only risk and cost-effectiveness, but also stakeholder, ethical and regulatory perspectives. Considering all relevant criteria, new-donor testing is judged the optimal strategy because it is able to achieve almost the same outcomes as universal testing, at a fraction of the cost.

Missingness in the T1DGC MHC fine-mapping SNP data: association with HLA genotype and potential influence on genetic association studies

AIM

The absence or 'missingness' of single nucleotide polymorphism (SNP) assay values because of genotype or related factors of interest may bias association and other studies. Missingness was determined for the Type 1 Diabetes Genetics Consortium (T1DGC) Major Histocompatibility Complex (MHC) data and was found to vary across the region, ranging up to 11.1% of the non-null proband SNPs, with a median of 0.3%. We consider factors related to missingness in the T1DGC data and briefly assess its possible influence on association studies.

METHODS

We assessed associations of missingness in the SNP assay data with human leucocyte antigen (HLA) genotype of the individual and with SNP genotypes of the parents. Within-cohort analyses were combined (over all cohorts) using (i) Mantel-Haenszel tests for two-by-two tables or (ii) by combining test statistics for larger tables and regression models. Mixed effect regression models were used to assess association of the SNP genotypes with affected status of the offspring after adjustment for parental SNP genotypes, cohort membership and HLA genotypes. Log-linear models were used to assess association of missingness in the unaffected sib assays with SNP genotypes of the probands.

RESULTS

Missingness of SNP values near the HLA class I (A, B and C) and class II (DR, DQ and DP) loci is strongly associated with carriage of corresponding HLA genotypes within these groups. Similar associations pertain to missing values among the microsatellite data. In at least some of these cases, regions of missingness coincided with known deletion regions corresponding to the associated HLA haplotype. We conjecture that other regions of associated missingness may point to similar haplotypic deletions. Analysis of association patterns of SNP genotypes with affected status of offspring does not indicate strong informative missingness. However, association of missingness in proband data with parental SNP genotypes may impact transmission disequilibrium test (TDT)-type analyses. Comparisons of affected and unaffected siblings point to possible susceptibility regions additional to the classical HLA-DR3/4 alleles near BAT4-LY6G5B-BAT5 and NOTCH4.

CONCLUSIONS

Potentially informative missingness in SNP assay values in the MHC region may impact on association and related analyses based on the T1DGC data. These results suggest that it would be prudent to assess the degree to which missingness may abrogate assessed SNP disease markers in such studies. Initial analyses based on comparison of affected and unaffected status in offspring suggest that at least these may be little affected.

Influence of inhibitory killer immunoglobulin-like receptors and their HLA-C ligands on resolving hepatitis C virus infection

An estimated 2%-3% of the world's population is chronically infected with hepatitis C virus (HCV) and this is a major cause of liver disease worldwide. Following acute infection, outcome is variable with acute HCV successfully resolved in some individuals (20%-30%), but in the majority of cases the virus is able to persist. Co-infection with human immunodeficiency virus has been associated with a negative impact on the course of HCV infection. The host's immune response is an important correlate of HCV infection outcome and disease progression. Natural killer (NK) cells provide a major component of the antiviral immune response by recognising and killing virally infected cells. NK cells modulate their activity through a combination of inhibitory and activatory receptors such as the killer immunoglobulin-like receptors (KIRs) that bind to human leukocyte antigen (HLA) Class I molecules. In this workshop component, we addressed the influence of KIR genotypes and their HLA ligands on resolving HCV infection and we discuss the implications of the results of the study of Lopez-Vazquez et al. on KIR and HCV disease progression.

Killer immunoglobulin-like receptors and HLA act both independently and synergistically to modify HIV disease progression

Variation in the host response to infection by pathogens including HIV-1 may be conferred by polymorphic genetic factors such as HLA and killer immunoglobulin-like receptors (KIR) genes. Here, we examined KIR and HLA genotype effects on pretreatment viral load, rate of CD4(+) T-cell decline and progression to AIDS among adult HIV-1-infected patients within the Western Australian HIV Study Cohort. In this study, carriage of KIR genes within the 'B' haplotype (eg KIR2DS2) was specifically associated with a more rapid CD4(+) T-cell decline over time and progression to AIDS. In contrast, KIR gene repertoire had no effect on pretreatment viral load while selected HLA alleles (eg HLA-B*5701, HLA-B*2705) demonstrated significant protective effects on viremia. Furthermore, interactions between specific HLA and KIR genes did appear to influence HIV disease progression. The results suggest that host genetic variation within the HLA and KIR gene complexes have clinically relevant effects on the course of HIV-1/AIDS, acting independently as well as synergistically to modify disease progression at multiple levels.

Use of the genomic matching technique to complement multiplex STR profiling reduces DNA profiling costs in high volume crimes and intelligence led screens

The genomic matching technique (GMT) targets duplicated polymorphic sequences within genomic blocks in the human major histocompatibility complex (MHC), differentiating between individuals at the DNA level using a single primer pair per block. The GMT is currently used to supplement human leukocyte antigen (HLA) typing to match donor and recipient pairs for bone marrow transplantation and has the potential to be employed as a powerful exclusion tool in forensic biology. The GMT is highly reproducible, produces DNA profiles from less than 1 ng of DNA and was successfully employed to profile a range of forensic samples including buccal swabs, handled objects and fingerprints. Furthermore, GMT profiles from a single genomic block in the MHC are likely to be more discriminatory than known highly polymorphic short tandem repeat (STR) loci such as ACTBP2. As such, the GMT can reduce the cost of investigations that require profiling of multiple suspects or samples from one or more crime scenes and could be extended to profile genomic blocks in other polymorphic genetic systems in the human genome.

Cluster of TRIM genes in the human MHC class I region sharing the B30.2 domain

The major histocompatibility complex (MHC), a region of high gene density, contains a large number of genes relevant to the immune response, belonging to different multigenic families. We studied the genomic organization and polymorphism of a set of genes in the MHC class I region containing the tripartite motif (TRIM), consisting of a RING domain, B-box and coiled coil region, and a B30.2-like domain. A cluster of seven genes at 6p21.33 and two related family members telomeric of the cluster were characterized. All MHC-encoded TRIM-B30.2 genes showed moderate levels of polymorphism, affecting predominantly the RING and B-box domains. In terms of structure, the genes varied by the loss of partial and, in some cases, complete domains. They were strongly conserved in exons 2, 3 and 4, which form the coiled-coil region. The last exon, encoding the B30.2-like domain, is shared with the otherwise unrelated butyrophilin-like (BTN) genes, located 4.3 Mb telomeric of the TRIM-B30.2 cluster. The data are consistent with multiple, ancient duplications giving rise to a set of related genes.

Genomic and phylogenetic analysis of the human CD1 and HLA class I multicopy genes

The human CD1 proteins belong to a lipid-glycolipid antigen-presenting gene family and are related in structure and function to the MHC class I molecules. Previous mapping and DNA hybridization studies have shown that five linked genes located within a cluster on human chromosome 1q22-23 encode the CD1 protein family. We have analyzed the complete genomic sequence of the human CD1 gene cluster and found that the five active genes are distributed over 175,600 nucleotides and separated by four expanded intervening genomic regions (IGRs) ranging in length between 20 and 68 kb. The IGRs are composed mostly of retroelements including five full-length L1 PA sequences and various pseudogenes. Some L1 sequences have acted as receptors for other subtypes or families of retroelements. Alu molecular clocks that have evolved during primate history are found distributed within the HLA class I duplicated segments (duplicons) but not within the duplicons of CD1. Phylogeny of the alpha3 domain of the class I-like superfamily of proteins shows that the CD1 cluster is well separated from HLA class I by a number of superfamily members including MIC (PERB11), HFE, Zn-alpha2-GP, FcRn, and MR1. Phylogenetically, the human CD1 sequences are interspersed by CD1 sequences from other mammalian species, whereas the human HLA class I sequences cluster together and are separated from the other mammalian sequences. Genomic and phylogenetic analyses support the view that the human CD1 gene copies were duplicated prior to the evolution of primates and the bulk of the HLA class I genes found in humans. In contrast to the HLA class I genomic structure, the human CD1 duplicons are smaller in size, they lack Alu clocks, and they are interrupted by IGRs at least 4 to 14 times longer than the CD1 genes themselves. The IGRs seem to have been created as "buffer zones" to protect the CD1 genes from disruption by transposable elements.

Genetics of human complement component C4 and evolution the central MHC

The two classes of human complement component C4 proteins C4A and C4B manifest differential chemical reactivities and binding affinities towards target surfaces and complement receptor CR1. There are multiple, polymorphic allotypes of C4A and C4B proteins. A complex multiplication pattern of C4A and C4B genes with variations in gene size, gene dosage and flanking genes exists in the population. This is probably driven by the selection pressure to respond to a great variety of parasites efficiently and effectively, which the bony fish achieved through the multiplication and diversification of the related complement C3 proteins. Complement C4, C3 and C5 belong to the alpha2 macroglobulin protein family but acquired specific features that include an anaphylatoxin domain, a netrin (NTR) domain, and stretches of basic residues for proteolytic processings to form multiple chain structures. Complement C3 and C4 are important in the innate immune response as they opsonize parasites for phagocytosis. The emergence of complement C3 predates proteins involved in the adaptive immune response as C3 is present in deuterostome invertebrates such as echinoderms. The human C4 genes are located in the central MHC at chromosome 6p21.3. C3 and C5 are located at chromosome 19 and 9, respectively, with representatives of the other groups of genes paralogous to the MHC at 19p13.1-p13.3, 1q21-25, and 9q33-34. The central MHC also contains genes for complement components C2 and Bf. These genes appear to have similar evolutionary histories to C3/C4/C5 and are used here to illustrate stepwise processes resulting in co-location of diverse domains, chromosomal duplication, local segmental duplication and divergence of sequence and function. This model of evolution is useful in the investigation of innate and acquired immunity and in seeking explanations for diseases associated with MHC ancestral haplotypes.

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.

Mitochondrial DNA variants in inclusion body myositis

Mitochondrial DNA variants have been shown to be associated with many diseases. Mutations at mitochondrial DNA nucleotide positions 3192, 3196, 3397 and 4336 have been described in association with late-onset Alzheimer's disease. The pathological similarities between inclusion body myositis and Alzheimer's disease prompted an analysis of the relationship between the reported mutations and sporadic inclusion body myositis. The 4336G variant was not significantly increased in patients with inclusion body myositis or Alzheimer's disease when compared to controls. None of the patients with inclusion body myositis carried mutations at nucleotide positions 3192, 3196 and 3397. A transition at nucleotide position 4580 was detected in some patients with inclusion body myositis and Alzheimer's disease but was not significantly higher in frequency when compared to controls. Phylogenetic analysis showed that the 4336G and 4580A variants clustered together in their respective group. A group of patients with inclusion body myositis also clustered together on a separate branch of the phylogenetic tree. Closer investigation of this group revealed a common polymorphism at nucleotide position 16311. The frequency of the 16311C variant was higher in inclusion body myositis than in Alzheimer's disease and controls, although when only caucasian patients were considered the increased frequency was not statistically significant. Further studies will be required to determine whether this variant plays a role in the pathogenesis of inclusion body myositis.

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.

SNP profile within the human major histocompatibility complex reveals an extreme and interrupted level of nucleotide diversity

The human major histocompatibility complex (MHC) is characterized by polymorphic multicopy gene families, such as HLA and MIC (PERB11); duplications; insertions and deletions (indels); and uneven rates of recombination. Polymorphisms at the antigen recognition sites of the HLA class I and II genes and at associated neutral sites have been attributed to balancing selection and a hitchhiking effect, respectively. We, and others, have previously shown that nucleotide diversity between MHC haplotypes at non-HLA sites is unusually high (>10%) and up to several times greater than elsewhere in the genome (0.08%-0.2%). We report here the most extensive analysis of nucleotide diversity within a continuous sequence in the genome. We constructed a single nucleotide polymorphism (SNP) profile that reveals a pattern of extreme but interrupted levels of nucleotide diversity by comparing a continuous sequence within haplotypes in three genomic subregions of the MHC. A comparison of several haplotypes within one of the genomic subregions containing the HLA-B and -C loci suggests that positive selection is operating over the whole subgenomic region, including HLA and non-HLA genes. [The sequence data for the multiple haplotype comparisons within the class I region have been submitted to DDBJ/EMBL/GenBank under accession nos. AF029061, AF029062, and AB031005-AB031010. Additional sequence data have been submitted to the DDBJ data library under accession nos. AB031005-AB03101 and AF029061-AF029062.]

Using alu J elements as molecular clocks to trace the evolutionary relationships between duplicated HLA class I genomic segments

The class I region of the major histocompatibility complex contains two subgenomic blocks (250-350 kb each), known as the alpha and beta blocks. These blocks contain members of multicopy gene families including HLA class I, HERV-16 (previously called P5 sequences), and PERB11 (MIC). We have previously shown that each block consists of imperfect duplicated segments (duplicons) containing linked members of different gene families, retroelements and transposons that have coevolved as part of two separate evolutionary events. Another region provisionally designated here as the kappa block is located between the alpha and the beta blocks and contains HLA-E, -30, and -92, HERV-16 (P5.3), and PERB11.3 (MICC) within about 250 kb of sequence. Using Alu elements to trace the evolutionary relationships between different class I duplicons, we have found that (a) the kappa block contains paralogous (duplicated) Alu J sequences and other retroelement patterns more in common with the beta than the alpha block; (b) the retroelement pattern associated with the HLA-E duplicon is different from all other HLA class I duplicons, indicating a more complex evolution; (c) the HLA-92 duplicon, although substantially shorter, is closely related in sequence to the HLA-B and -C duplicons; (d) two of the six paralogous Alu J elements within the HLA-B and -C duplicons are associated with the HLA-X duplicon, confirming their evolutionary relationships within the beta block; and (e) the paralogous Alu J elements within the alpha block are distinctly different from those identified within the beta and kappa blocks. The sequence conservation and location of duplicated (paralogous) Alu J elements in the MHC class I region show that the beta and kappa blocks have evolved separately from the alpha block beginning at a time before or during the evolution of Alu J elements in primates.

Duplication and diversification of the apolipoprotein CI (APOCI) genomic segment in association with retroelements

We have previously shown that several multicopy gene families within the major histocompatibility complex (MHC) arose from a process of segmental duplication. It has also been observed that retroelements play a role in generating diversity within these duplicated segments. The objective of this study was to compare the genomic organization of a gene duplication within another multicopy gene family outside the MHC. Using new continuous genomic sequence encompassing the APOE-CII gene cluster, we show that APOCI and its pseudogene, APOCI', are contained within large duplicated segments which include sequences from the hepatic control region (HCR). Flanking Alu sequences are observed at both ends of the duplicated unit, suggesting a possible role in the integration of these segments. As observed previously within the MHC, the major differences between the segments are the insertion of sequences (approximately 200-1000 bp in length), consisting predominantly of Alu sequences. Ancestral retroelements also contribute to the generation of sequence diversity between the segments, especially within the 3' poly(A) tract of Alu sequences. The exonic and regulatory sequences of the APOCI and HCR loci show limited sequence diversity, with exon 3 being an exception. Finally, the typing of pre- and postduplication Alus from both segments indicates an estimated time of duplication of approximately 37 million years ago (mya), some time prior to the separation of Old and New World monkeys.

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.

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.

Extensive nucleotide variability within a 370 kb sequence from the central region of the major histocompatibility complex

The recent availability of the genomic sequence spanning the central and telomeric end of the major histocompatibility complex (MHC) has allowed a detailed study of its organisation, gene content and level of nucleotide variability. Previous analyses of nucleotide variability in the MHC have focused on the coding regions of the human leukocyte antigen (HLA) Class I and II genes. Non-coding nucleotide variability has been considered a by-product of exonic diversity. However, with the advent of genomic sequencing, the extent of non-coding nucleotide variability within the MHC has just begun to be appreciated. In this study, we compared different human haplotypes in 370 kb of sequence in the central region of the MHC to show the following: 1. unusually high levels of non-coding nucleotide variability, up to 80 times greater than elsewhere in the genome; 2. non-coding nucleotide variability greater than 1% at nucleotide sites distant to the Class I genes; 3. nucleotide variability greater than 1% maintained over regions containing highly linked loci; and 4. distinct troughs and peaks in the level of nucleotide variability. We will discuss these observations in relation to a possible role of nucleotide variability in the organisation of the MHC.

Neural network in planarian revealed by an antibody against planarian synaptotagmin homologue

In order to investigate the neural connection of planarian, it is imperative to produce an antibody that specifically stains axons. To identify axon-specific genes, we constructed a cDNA library from a single eye by using a single cell PCR method, in which visual neurons are major components, and sequenced one thousand independent clones. We succeeded in the identification of a planarian homologue of synaptotagmin, Djsyt, whose specific expression in neurons was confirmed by in situ hybridization. The antibody against DjSYT specifically stained axons although its mRNA is distributed in the cell bodies. By using anti-DjSYT, we succeeded in the visualization of neural connections in planarians by whole mount staining. The anti-DjSYT antibody will become a powerful tool to analyze the molecular mechanisms underlying neural network formation in planarian.

Coevolution of PERB11 (MIC) and HLA class I genes with HERV-16 and retroelements by extended genomic duplication

The recent availability of genomic sequence information for the class I region of the MHC has provided an opportunity to examine the genomic organization of HLA class I (HLAcI) and PERB11/MIC genes with a view to explaining their evolution from the perspective of extended genomic duplications rather than by simple gene duplications and/or gene conversion events. Analysis of genomic sequence from two regions of the MHC (the alpha- and beta-blocks) revealed that at least 6 PERB11 and 14 HLAcI genes, pseudogenes, and gene fragments are contained within extended duplicated segments. Each segment was searched for the presence of shared (paralogous) retroelements by RepeatMasker in order to use them as markers of evolution, genetic rearrangements, and evidence of segmental duplications. Shared Alu elements and other retroelements allowed the duplicated segments to be classified into five distinct groups (A to E) that could be further distilled down to an ancient preduplication segment containing a HLA and PERB11 gene, an endogenous retrovirus (HERV-16), and distinctive retroelements. The breakpoints within and between the different HLAcI segments were found mainly within the PERB11 and HLA genes, HERV-16, and other retroelements, suggesting that the latter have played a major role in duplication and indel events leading to the present organization of PERB11 and HLAcI genes. On the basis of the features contained within the segments, a coevolutionary model premised on tandem duplication of single and multipartite genomic segments is proposed. The model is used to explain the origins and genomic organization of retroelements, HERV-16, DNA transposons, PERB11, and HLAcI genes as distinct segmental combinations within the alpha- and beta-blocks of the human MHC.

Different evolutionary histories in two subgenomic regions of the major histocompatibility complex

Two subgenomic regions within the major histocompatibility complex, the alpha and beta blocks, contain members of the multicopy gene families HLA class I, human endogenous retroviral sequence (HERV-16; previously known as P5 and PERB3), hemochromatosis candidate genes (HCG) (II, IV, VIII, IX), 3.8-1, and MIC (PERB11). In this study we show that the two blocks consist of imperfect duplicated segments, which contain linked members of the different gene families. The duplication and truncation sites of the segments are associated with retroelements. The retroelement sites appear to generate the imperfect duplications, insertions/deletions, and rearrangements, most likely via homologous recombination. Although the two blocks share several characteristics, they differ in the number and orientation of the duplicated segments. On the 62.1 haplotype, the alpha block consists of at least 10 duplicated segments that predominantly contain pseudogenes and gene fragments of the HLA class I and MIC (PERB11) gene families. In contrast, the beta block has two major duplications containing the genes HLA-B and HLA-C, and MICA (PERB11.1) and MICB (PERB11.2). Given the common origin between the blocks, we reconstructed the duplication history of the segments to understand the processes involved in producing the different organization in the two blocks. We then found that the beta block contains four distinct duplications from two separate events, whereas the alpha block is characterized by multisegment duplications. We will discuss these results in relation to the genetic content of the two blocks.

Comparison between two human endogenous retrovirus (HERV)-rich regions within the major histocompatibility complex

Sixteen human endogenous retrovirus (HERV) sequences were detected within 656 kb of genomic sequence obtained from the alpha- and beta-block of the class I region of the major histocompatibility complex (MHC). The HERVs were identified and characterized as family members of HERV-16 (11 copies), HERV-L (1 copy), HERV-I (2 copies), HERV-K91 (1 copy), and HARLEQUIN (1 copy) by sequence comparison using CENSOR or Repeat Masker, BLAST searches, and dot plots. The 11 copies of HERV-16 arose as products of duplication of genomic segments containing HLA class I (HLAcI) and PERB11 (MIC) genes inter alia, whereas the other five HERVs arose after duplication probably as a consequence of single insertion events or translocations. HERV-L and HERV-I are located between the duplicated genes PERB11.2 (MICB) and PERB11.1 (MICA), and HLA-B and HLA-C, respectively, whereas HERV-K91 and HARLEQUIN are located telomeric of HLA-C. A highly fragmented copy of HERV-I was also found telomeric of PERB11. 4. Structural analysis of open reading frames (ORFs) revealed the absence of intact coding sequence within the putative gag, pol, and env gene regions of all the HERVs with the exception of HERV-K91, which had two large ORFs within the region of the putative protease and pol genes. In addition, the 5'-LTR of HERV-L contained a 2.5-kb element that was AT-rich and large ORFs with putative amino acid sequences rich in tyrosines and isoleucines. HERV-I, HARLEQUIN, and at least four copies of HERV-16 appear to have been receptors for the insertion of other retrotransposons including Alu elements and fragments of L1 and THE1. Examination of flanking sequences suggests that HERV-I and HERV-L had occurred by insertion into ancient L1 fragments. This study has revealed that the alpha- and beta-block region within the MHC is rich in HERV sequences occurring at a much higher ratio (10 to 1) than normally observed in the human genome. These HERV sequences will therefore enhance further studies on disease associations and differences between human haplotypes and primates and their role in the evolution of class I genes in the MHC.

Characterisation of the human central MHC gene, BAT1: genomic structure and expression

The BAT1 gene (D6S81E) encodes a member of the DEAD-box family of RNA-binding proteins, and lies in the central MHC. This region contains genes which affect susceptibility to immunopathological diseases. A 14-kb section of the human MHC containing the BAT1 gene and a further 5-kb telomeric of BAT1 was sequenced using DNA from individuals homozygous for HLA-A1, B8, DR3 and HLA- A1, B57, DR7. Analysis of our sequences and the previously reported human cDNA sequence showed that the expressed sequence of the 8.1 and 57.1 haplotypes is identical with only minor substitutions in the introns. Phylogenetic analysis suggests BAT1 may be a translation initiation factor. Screening of cells and tissues for BAT1 mRNA suggests an abundant member of a family of proteins expressed in multiple cell types, notably macrophages and hepatocytes. Expression was independent of MHC haplotype, consistent with the lack of sequence polymorphism.

Phylogenetic analysis of primate MIC (PERB11) sequences suggests that the representation of the gene family differs in different primates: comparison of MIC (PERB11) and C4

Duplication of segments within the MHC has led to numerous multicopy families such as class I, class II, C4 and MIC (PERB11). Different copy numbers between haplotypes and species may be explained by the extent of duplication and subsequent deletion. There are at least five copies of MIC (PERB11) in humans, but MICA (PERB11.1) appears to have been deleted from the chimpanzee. By comparing the sequences of primates (chimpanzee, gorilla, gibbon, orang-utan, pygmy chimpanzee, Patas monkey, Aethiops and baboon) we conclude that the gorilla has a copy of PERB11.1, whereas the baboon and Patas possess MICD (PERB11.4) and/or MICE (PERB11.5) rather than MICA (PERB11.1). These findings indicate that the primate MHC is more plastic than has been appreciated.

Genomics of the major histocompatibility complex: haplotypes, duplication, retroviruses and disease

The genomic region encompassing the Major Histocompatibility Complex (MHC) contains polymorphic frozen blocks which have developed by local imperfect sequential duplication associated with insertion and deletion (indels). In the alpha block surrounding HLA-A, there are ten duplication units or beads on the 62.1 ancestral haplotype. Each bead contains or contained sequences representing Class I, PERB11 (MHC Class I chain related (MIC) and human endogenous retrovirus (HERV) 16. Here we consider explanations for co-occurrence of genomic polymorphism, duplication and HERVs and we ask how these features encode susceptibility to numerous and very diverse diseases. Ancestral haplotypes differ in their copy number and indels in addition to their coding regions. Disease susceptibility could be a function of all of these differences. We propose a model of the evolution of the human MHC. Population-specific integration of retroviral sequences could explain rapid diversification through duplication and differential disease susceptibility. If HERV sequences can be protective, there are exciting prospects for manipulation. In the meanwhile, it will be necessary to understand the function of MHC genes such as PERB11 (MIC) and many others discovered by genomic sequencing.

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.

Duplication and polymorphism in the MHC: Alu generated diversity and polymorphism within the PERB11 gene family

The PERB11 gene family has at least five members within the telomeric region of the MHC. The PERB11.1 and PERB11.2 genes are approximately 40 kb and 160 kb centromeric of HLA-B, respectively. Using continuous genomic sequence encompassing PERB11.1 and PERB11.2, we have found a large (approximately 25 kb) segmental duplication extending beyond the genes themselves and other potential coding sequences. The major difference between the segments are large indels which are predominantly Alu sequences. The Alu sequences within the duplicated segments have created diversity via the internal and 3' poly A-rich region. A sequence comparison of an Alu sequence between two different human ancestral haplotypes shows a high level of polymorphism, particularly in the poly A-rich regions. This study characterises the Alu sequences within the peri-PERB11.1 and peri-PERB11.2 duplicated segments in relation to diversity and polymorphism and as evolutionary markers.

The evolution of MHC diversity by segmental duplication and transposition of retroelements

Sequence analysis of a 237 kb genomic fragment from the central region of the MHC has revealed that the HLA-B and HLA-C genes are contained within duplicated segments peri-B (53 kb) and peri-C (48 kb), respectively, and separated by an intervening sequence (IF) of 30 kb. The peri-B and peri-C segments share at least 90% sequence homology except when interrupted by insertions/deletions including Alu, L1, an endogenous retrovirus, and pseudogenes. The sequences of peri-B, IF, and peri-C were searched for the presence of Alu elements to use as markers of evolution, chromosomal rearrangements, and polymorphism. Of 29 Alu elements, 14 were identified in peri-B, 11 in peri-C, and 4 in IF. The Alu elements in peri-B and peri-C clustered phylogenetically into two clades which were classified as "preduplication" and "postduplication" clades. Four Alu J elements that are shared by peri-B and peri-C and are flanked by homologous sequences in their paralogous locations, respectively, clustered into a "preduplication" clade. By contrast, the majority of Alu elements, which are unique to either peri-B or peri-C, clustered into a postduplication clade together with the Alu consensus subfamily members ranging from platyrrhine-specific (Spqxcg) to catarrhine-specific Alu sequences (Y). The insertion of platyrrhine-specific Alu elements in postduplication locations of peri-B and peri-C implies that these two segments are the products of a duplication which occurred in primates prior to the divergence of the New World primate from the human lineage (35-44 mya). Examination of the paralogous Alu integration sites revealed that 9 of 14 postduplication Alu sequences have produced microsatellites of different length and sequence within the Alu 3'-poly A tail. The present analysis supports the hypothesis that HLA-B and HLA-C genes are products of an extended segmental duplication between 44 and 81 million years ago (mya), and that subsequent diversification of both genomic segments occurred because of the mobility and mutation of retroelements such as Alu repeats.

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."

Allelic and interlocus comparison of the PERB11 multigene family in the MHC

The major histocompatibility complex (MHC) contains at least a hundred genes over 4 megabases of DNA. Within the MHC there are several new multigene families which have been recently described. PERB11 is a multigene family which occurs over the class I and central region of the MHC. Two members of the family have been shown to be functional and share domains with members of the supergene family including HLA class I, FcRn, and Zn-alpha2-glycoprotein molecules. The two functional members are contained within an area of the MHC which has been associated with increased susceptibility to autoimmune diseases such as insulin-dependent diabetes mellitus and also rapid progression to AIDS following HIV-1 infection. Intralocus and interlocus differences between PERB11.1 and PERB11.2 include: (1) several nucleotide substitutions leading to amino acid changes; (2) presence and absence of potential glycosylation sites; (3) insertions and deletions leading to a frame shift resulting in diversity at the amino acid level and an early termination signal. There are ten different alleles of PERB11.1 including one allele which contains a frame shift in the transmembrane region causing a putative truncated molecule lacking the cytoplasmic tail. The significance of this polymorphism in disease associations is under investigation. The most divergent domain is the transmembrane region when PERB11.1 and PERB11.2 are compared. The results suggest that these two molecules may have different functions.

Genomic characterization of the region between HLA-B and TNF: implications for the evolution of multicopy gene families

The major histocompatibility complex (MHC) contains genes which confer susceptibility to numerous diseases and must be important in primate evolution. In some instances, genes have been mapped to the region between human histocompatibility leukocyte antigen (HLA)-B and tumor necrosis factor (TNF) but precise localization has proven difficult especially since this region is subject to insertions, deletions, and duplications. Utilizing computer similarity searches and coding prediction programs, we have identified several potential coding sequences between HLA-B and TNF. Three of these sequences, PERB11.2, PERB15, and PERB 18, are similar to members of multicopy gene families that are located in other regions of the MHC. The identification of numerous fragmented and intact retroelements (L1, Alu, LTR, and THE sequences) flanking the PERB11 and PERB15 genes suggests that these retroelements are involved in the duplication process. The evaluation of candidate genes for disease susceptibility within the MHC is complicated by their similarity to other members of multicopy gene families. The determination of sequence differences within and between species provides a strategy with which to investigate the candidate genes between HLA-B and TNF.

Psychological and immunological correlates of acute overtraining

Five men undertook two intensive interval training sessions per day for 10 days, followed by 5 days of active recovery. Subjects supplied a venous blood sample and completed a mood-state questionnaire on days 1, 6, 11 and 16 of the study. Performance capabilities were assessed on days 1, 11 and 16 using a timed treadmill test to exhaustion at 18 kmh-1 and 1% grade. These individuals became acutely overtrained as indicated by significant reductions in running performance from day 1 to day 11. The overtrained state was accompanied by severe fatigue, immune system deficits, mood disturbance, physical complaints, sleep difficulties, and reduced appetite. Mood states moved toward baseline during recovery, but feelings of fatigue and immune system deficits persisted throughout the study.

Effects of acute exercise on lymphocyte subsets and metabolic activity

Lymphocyte subsets, their responsiveness to mitogen and their capacity for glutamine oxidation and glycolysis were assessed in seven subjects before and after an acute bout of interval exercise, the purpose being to establish whether exercise is associated with alterations in lymphocyte metabolic capacities. The subjects exercised at 112% of their maximal work capacity (as determined by pre-test) on a treadmill and performed 25 repeat tests, each of 1 min duration interrupted by 2 min rest periods. Venous blood samples were taken at rest and 3 min following completion of exercise. Acute exercise was associated with significant decreases in the percentage of T- (p < 0.01) and B-cells (p < 0.01) and an increase in the percentage of NK-cells (p < 0.05). These changes were accompanied by a significant decrease in the responsiveness of peripheral blood lymphocytes to the mitogen concanavalin A (p < 0.05). Acute exercise was also associated with profound changes in the metabolic capacities of peripheral blood lymphocytes: rates of 14CO2 production from [U-14C]glutamine (19%: p < 0.05) and lactate (27%: p < 0.05) production were increased significantly in response to interval exercise. Linear regression analysis revealed significant correlation between the exercise-mediated changes (%) in T- and NK-cells and changes (%) in both lymphocyte responsiveness to concanavalin A and metabolic capacity, particularly glutamine oxidation to CO2. One interpretation of these data is that acute exercise promotes a redistribution in lymphocyte subsets, and that it is this redistribution that is the basis of both the impairment in lymphocyte responsiveness to mitogens and the increase in lymphocyte metabolic capacity, especially glutamine oxidation.(ABSTRACT TRUNCATED AT 250 WORDS)

Differences in the central major histocompatibility complex between humans and chimpanzees. Implications for development of autoimmunity and acquired immune deficiency syndrome

Chimpanzees (Pan Troglodytes) and humans are closely related and belong to the same subfamily, Homininae. The approximately 1.8% genetic difference that exists between humans and the chimpanzees must be responsible for observed differences between these two species. It has been shown that chimpanzees can be infected with HIV, but AIDS has not been reported. Furthermore, the prevalence of autoimmune diseases may be low in this species. For instance, type II diabetes occurs, but type I (autoimmune) diabetes (IDDM), to our knowledge, has not been reported. In humans, susceptibility genes for MG and IDDM have been localized to the region between TNF and HLA-B. This region may also influence the rate of progression to death after HIV infection. We have identified differences in this region between humans and the chimpanzees. As shown by PFGE, the TNF to Patr-B region in the chimpanzees is approximately 130-160 kb shorter than the equivalent in humans. Southern and sequence analyses indicate that the deletions in chimpanzees (insertions in humans) include one copy of CL (approximately 10 kb) and the X sequences (< 30 kb). Obviously, other deletions/insertions (approximately 120 kb) need to be identified. Since CL has been shown to be transcribed, the results imply the lack of the gene or, at least, a different gene copy number in the chimpanzees, and we propose that such differences may be relevant to the observed functional differences. We demonstrate here a strategy to identify critical genes responsible for disease development.