Novel members and germline polymorphisms in the human T-cell receptor Vb6 family

The T-cell receptor in primates: identifying and sequencing new owl monkey TRBV gene sub-groups

The New World primate Aotus nancymaae (owl monkey) has been shown to be an excellent experimental model when studying malarial parasites. Characterising the T-cell receptor (TR) alphabeta repertoire by means of the different variable beta (TRBV) genes displayed contributes to a better understanding of these lymphocytes' role in the response against several malarial antigens. This study describes identifying and characterising eleven new TRBV gene sub-groups in cDNA from Aotus nancymaae's peripheral blood lymphocytes; these 11 gene sequences displayed homology to the previously reported human TRBV3, TRBV10, TRBV11, TRBV14, TRBV18, TRBV19, TRBV20, TRBV25, TRBV27, TRBV29 and TRBV30 sub-groups, resulting in 83% overall homology at the amino acid level. An additional Aotus sequence was found having similarity with the human TRBJ-2-7*01 gene. Evolutionary relationships amongst these sequences and the homologous genes from both New and Old World primates have shown that the TRBV repertoire has been maintained in the species being studied, displaying varying association patterns and substitution rates, depending on the sub-group being studied. The degree of identity observed when comparing human and Aotus genes suggests that these species might have a similar TRBV repertoire.

Diagnostic role of tests for T cell receptor (TCR) genes

Rapid advances in molecular biological techniques have made it possible to study disease pathogenesis at a genomic level. T cell receptor (TCR) gene rearrangement is an important event in T cell ontogeny that enables T cells to recognise antigens specifically, and any dysregulation in this complex yet highly regulated process may result in disease. Using techniques such as Southern blot hybridisation, polymerase chain reaction, and flow cytometry it has been possible to characterise T cell proliferations in malignancy and in diseases where T cells have been implicated in the pathogenesis. The main aim of this article is to discuss briefly the process of TCR gene rearrangement and highlight the disorders in which expansions or clonal proliferations of T cells have been recognised. It will also describe various methods that are currently used to study T cell populations in body fluids and tissue, their diagnostic role, and current limitations of the methodology.

The nonfunctional allele TCRBV6S1B is strongly associated with Helicobacter pylori infection

To determine genetic susceptibility factors for Helicobacter pylori infection, polymorphic T-cell receptor gene elements were investigated in 203 H. pylori-infected individuals and 180 uninfected individuals (controls). H. pylori infection is highly associated with individuals homozygous for the nonfunctional TCRBV6S1B element (odds ratio = 5.9; chi(2) = 13; P = 0.00032; P value corrected for multiple comparisons [Bonferroni correction] = 0. 00063).

Human T-cell receptor BV6 gene polymorphism in relation to expression level and CD4/CD8 skewness

Using 50 samples of umbilical cord blood lymphocytes from Japanese donors, we analysed two human T-cell receptor beta variable (TCRBV) genes, BV6S4 and BV6S5, for their polymorphism, usage frequencies and CD4/CD8 skewness. They showed contrasting CD4/CD8 skewness, BV6S4 to CD8+ T cells and BV6S5 to CD4+ T cells. Genotyping of the BV6S4 alleles (A1, A2 and A3) revealed two of the six possible BV6S4 genotypes, A1/A2 and A2/A2. Among the two BV6S4 genotypes, no significant difference was detected in usage frequency or CD4/CD8 skewness. On the other hand, genotyping of the BV6S5 alleles (A1 and A2) revealed all three possible BV6S5 genotypes, A1/A1, A1/A2 and A2/A2, and the gene usage frequency was high, in the order A1/A1 > A1/A2 > A2/A2. These results indicate that the amino acid substitutions in BV6S5 (S36R and G70E) are in some way associated with the expression level of this gene. In the analysis of CD4/CD8 skewness, the three BV6S5 genotypes had similar skewness, indicating that A1 alleles are expressed more frequently than A2 alleles in both CD4+ and CD8+ T-cell populations. Although BV6S5 exhibits marked skewness to CD4+ T cells, our results indicate that the higher expression of A1 alleles is not associated with the increased ratio of CD4+ T cells.

A genome-derived (gaa.ttc)24 trinucleotide block binds nuclear protein(s) specifically and forms triple helices

The properties of simple trinucleotide repeats generate increased interest as expansions of certain trinucleotide blocks cause human diseases. Here, we studied protein binding and structural features of a perfect (gaa.ttc)24 tract in its original genomic environment. Electrophoretic mobility shift assays revealed that HeLa nuclear proteins bind to the DNA fragment containing the (gaa.ttc)24 block. Competition experiments using simple (gt.ac)n repeats differing in length and flanking regions showed no cross-reactivity with the major retarded band. For the specific (gaa. ttc)n/protein complex, a binding constant of 9.3x10-9 mol/l was determined. DNase I footprinting revealed protein binding sites located exclusively within the repeat with a preference for the (gaa)24 strand. OsO4 and DEPC modifications followed by electrophoretic and electron microscopical analyses showed that the (gaa.ttc)24 block forms different types of intramolecular triple helices: Under superhelical stress, different H-DNA isomers are evident, whereas exclusively H-Y forms were detected in the relaxed state. Together, these data have functional implications for genomic (gaa.ttc)n tracts.

Expression of T-cell receptor Vbeta2, 6 and 8 gene families in chronic adult periodontal disease

Substantial evidence exists to suggest a role for T-cells in periodontal disease. As yet, however, the T-cell receptors remain to be characterised at the molecular level. The expression and the nucleotide sequence of genes from the T-cell receptor beta variable (TCRBV) gene families 2, 6 and 8 were analyzed in periodontal tissue from 24 patients with chronic adult periodontal disease (CAPD) and peripheral blood lymphocytes (PBL) of 16 of these patients. A restriction in the expression of these TCRBV gene families was detected in periodontal tissue from 14/24 patients with CAPD, and the pattern of gene expression was often different between individual patients; however there was no restriction in TCRBV gene expression in matched PBL samples from 8 of these 14 patients. Quantitative RT PCR analysis of samples from 5 CAPD patients who expressed all 3 TCRBV gene families in their periodontal tissues did not reveal any significant differences in the levels of gene expression in periodontal tissue and PBL. In contrast to the findings with some CAPD patients, genes from all 3 TCRBV families were always expressed in periodontal tissue and PBL from disease-free control subjects. PCR products from both the PBL and periodontal tissue of CAPD patients were cloned and sequenced; analysis of the nucleotide sequence revealed diversity with respect to the expression of TCRB joining (TCRBJ) and TCRB diversity (TCRBD) genes and the sequence of the junctional region in all samples analysed. In conclusion, in CAPD, the pattern of TCRBV gene expression in periodontal tissue is often but not always different from that in PBL and healthy periodontal tissue, which may indicate, in some cases, a local influence on particular T-cell subsets which is relevant to the pathogenesis of periodontal disease. However, the expressed TCRB genes are heterogeneous at the nucleotide level, emphasising the underlying complexity at the molecular level in the local T-cell response in CAPD.

Additional TCRV beta primers and minor method modifications improve detection of clonal T-cell populations by RT-PCR

The TCRV beta RT-PCR method for detection of clonal populations of T cells which we described previously could not detect clones that used certain variable (V) beta region families. V beta 2, 4, 8.3, and 18 had insufficient homology with the original consensus V region primer. Two new primers have been designed which work well and are able to amplify from V beta families previously undetectable by this RT-PCR. In addition, minor alterations to the cDNA synthesis and gel analysis of the PCR products make the results even easier to interpret. All the Diversity/Joining (D/J) region primer combinations except for D2/J2 have been omitted, and terminating the reverse transcription by heating prior to PCR greatly improves amplification with these primers. Use of 8% and/or 10% polyacrylamide gels increases clarity. Inclusion of the modifications described will reduce false reporting of patients as having a polyclonal T-cell population.

TCR gene polymorphisms and autoimmune disease

Autoimmunity may result from abnormal regulation within the immune system. As the T cell is the principal regulator of the immune system and its normal function depends on immune recognition or self/non-self discrimination, abnormalities of the idiotypic T-cell receptor (TCR) may be one cause of autoimmune disease. The TCR is a clonally distributed, cell-surface heterodimer which binds peptide antigen when complexed with HLA molecules. In order to recognize the variety of antigens it may possibly encounter, the TCR, by necessity, is a diverse structure. As with immunoglobulin, it is the variable domain of the TCR which interacts with antigen and exhibits the greatest amount of amino acid variability. The underlying genetic basis for this structural diversity is similar to that described for immunoglobulin, with TCR diversity relying on the somatic recombination, in a randomly imprecise manner, of smaller gene segments to form a functional gene. There are a large number of gene segments to choose from (particularly the TCRAV, TCRAJ and TCRBV gene segments) and some of these also exhibit allelic variation. Finally, polymorphisms in non-coding regions of TCR genes, leading to biased recombination or expression, are also beginning to be recognized. All these factors contribute to the polymorphic nature of the TCR, in terms of both structure and repertoire formation. It follows that inherited abnormalities in either coding or regulatory regions of TCR genes may predispose to aberrant T-cell function and autoimmune disease. This review will outline the genomic organization of the TCR genes, the genetic mechanisms responsible for the generation of diversity, and the results of investigations into the association between germline polymorphisms and autoimmune disease.

Human T-cell receptor variable gene segment families

Multiple DNA and protein sequence alignments have been constructed for the human T-cell receptor alpha/delta, beta, and gamma (TCRA/D, B, and G) variable (V) gene segments. The traditional classification into subfamilies was confirmed using a much larger pool of sequences. For each sequence, a name was derived which complies with the standard nomenclature. The traditional numbering of V gene segments in the order of their discovery was continued and changed when in conflict with names of other segments. By discriminating between alleles at the same locus versus genes from different loci, we were able to reduce the number of more than 150 different TCRBV sequences in the database to a repertoire of only 47 functional TCRBV gene segments. An extension of this analysis to the over 100 TCRAV sequences results in a predicted repertoire of 42 functional TCRAV gene segments. Our alignment revealed two residues that distinguish between the highly homologous V delta and V alpha, one at a site that in VH contacts the constant region, the other at the interface between immunoglobulin VH and VL. This site may be responsible for restricted pairing between certain V delta and V gamma chains. On the other hand, V beta and V gamma appear to be related by the fact that their CDR2 length is increased by four residues as compared with that of V alpha/delta peptides.

Immunoprinting excludes many potential susceptibility genes as predisposing to early onset pauciarticular juvenile chronic arthritis except HLA class II and TNF

DNA profiles (immunoprints) were generated for 120 patients suffering from early onset pauciarticular chronic arthritis (EOPA-JCA) and > 500 healthy controls utilizing highly polymorphic microsatellites in the vicinity of immunorelevant genes. Six T cell receptor (TCR) markers for the CD3D, TCRDVAJ, TEA, TCRBV6S1, BV6S3, BV6S7 and BV13S2 genes were analysed. Furthermore markers for the cell surface molecule CD40L, for cytokine genes (IL-1A, IL-2, IFN-alpha, FGF-alpha, TNF-alpha), the chromosomal region of the IRF2 and the cytokine receptor gene IL5RA were studied as well as two polymorphisms within the promotor region of the TNF-alpha gene. Coding region polymorphisms were evidenced indirectly by repeat length variation or they were predicted from the microsatellite distribution profiles and then confirmed by direct sequence analysis. Statistical evaluations were performed with respect to known predispositions, predominance of females (> 80%) and HLA-DR and -DQ haplotypes. Cell surface molecules (TCR, CD40L, IL5RA) as well as almost all cytokines (IL-1A, IFN alpha, FGFA, IRF2 region) were excluded as predisposing in our JCA panel. The TNF-alpha microsatellite alleles (GT)10-12 contribute considerably to manifestation of the disease, in HLA-DRB1*11(12) individuals (RR = 12.8). The TNF-alpha allele is not found in linkage disequilibrium with HLA-DRB1*11(12) and may be present on either chromosome 6. Thus, a novel susceptibility factor probably within the TNFA/TNFB gene region has been identified via linkage with the TNF-alpha microsatellite allele. Apparently complex compositions of the genetic background rather than single genes provide the precondition for manifestation of the autoimmune disease EOPA-JCA. Immunoprinting unravels the variability of the immunological genome via the semi-directed microsatellite approach efficiently.

Indirect DNA/gene diagnoses via electrophoresis--an obsolete principle?

In principle, gene defects can be investigated directly or indirectly via informative polymorphisms in their vicinity. But because many defects are not yet defined molecularly, these inherited diseases can only be diagnosed indirectly via analysis of informative family situations. Since (multiple) mutation analyses, e.g. via DNA sequencing, are time-consuming and expensive, indirect analysis may still be performed initially--particularly in diseases caused by heterogenous mutations. We focus on diagnoses of neurological and (auto)immune diseases by polymerase chain reaction and separation of the DNA fragments via gel electrophoreses. Even after gene defects have been identified, indirect analysis might be necessary, for example in Huntington's chorea. Although this genetic defect has been characterized as a trinucleotide disease, indirect DNA diagnosis is still performed in particular cases for psychological reasons. The causes of autoimmune diseases are multifactorial and the inheritance is complex, involving several genes. Genome-wide screening programs may involve indirect approaches via analyses of polymorphic microsatellites. Large parts of the immunological genome can be covered when 20 or more genes are investigated simultaneously. Thus the genetic bases of autoimmune diseases are disclosed. Microsatellites themselves could have a biological meaning. We therefore discuss also DNA/protein interactions for simple tandem repeats, the major targets for indirect gene diagnoses. Only indirect evidence exists that certain simple repeats influence genomic (in)stability. Taken together, indirect gene diagnoses supplement direct approaches in a variety of different purposes and in combination with standard electrophoresis techniques.

The T-cell receptor V beta 6 gene usage in alloreactive T-cell responses

To analyze the role of TCR V beta gene elements in allorecognition, we have determined frequencies of the TCR V beta 6 elements expressed by allospecific T cells as compared to randomly activated T cells. Limiting dilution analysis was applied to estimate the usage of TCR V beta elements in CD4+ T cells polyclonally stimulated by immobilized anti-CD3 or specifically activated with HLA-DR disparate allotargets. In a focused alloresponse of HLA-DRB1*0401+ responders to HLA-DRB1*0404+ stimulator cells, V beta 6+ T cells were preferentially recruited. To map the functional domain of allogeneic HLA-DR molecules involved in the recruitment of V beta 6+ T-cell specificities, CD4+ T cells from HLA-DRB1*0401+ donors were activated with allogeneic stimulators sharing either the first and second or the third HVR of the HLA-DRB1 gene. Stimulation with allotargets sharing the sequence of the HVR3 caused a twofold to fourfold enrichment of V beta 6+ CD4+ T cells, while sequence variations in the HVR3 was sufficient to abrogate the preferential usage of V beta 6+ T cells. These data suggest that sequence variations mapped to the alpha-helical loop of the HLA-DR beta chain impose structural constraints that shape the alloreactive TCR V beta repertoire.

Immunoprinting: various genes are associated with increased risk to develop rheumatoid arthritis in different groups of adult patients

To identify genes that contribute to the manifestation of rheumatoid arthritis we performed association studies via microsatellite analyses of immunorelevant loci (HLA-DRB, 5 T cell receptor loci, TNFa IL1, IL2, IL5R and CD40L). A total of 183 patients and 275 healthy controls were typed in terms of HLA and grouped according to the known predisposing HLA-DRB1 genes (DRB1*04; relative risk approx. 5; DRB1*01, relative risk approx. 2; a third group carried neither allele). Microsatellite polymorphisms characterizing the TCRBV6S3, CD3D, IL1A, IL2, and IL5R genes did not show significant associations with rheumatoid arthritis, whereas TCRBV6S1, TCRBV6S7, TNFa, and CD40L genes may influence relative protection or risk in certain groups of patients. Analysis of a microsatellite marker adjacent to the transcription element alpha (TEA) in the T cell receptor alpha delta complex indicates that in the cohort carrying neither the DRB1*04 nor the DRB1*01 allele the relative risk to acquire rheumatoid arthritis is increased (> 13) or decreased (< 0.07), depending on the inherited microsatellite allele adjacent to the TEA locus. Sequence analysis of the closely linked TEA region from patients and controls revealed a novel dimorphism. Only the newly identified TEA allele leads to binding of a nuclear protein that may be involved in the regulated expression of the TCRDA genes. Subsequent typing of rheumatoid arthritis patients and controls revealed, however, that the association of the microsatellite marker is largely independent of the TEA allele, confirming incomplete linkage in the 2 kb region of the TCRDA locus. These results are discussed in the context of hot spots of recombination in this genomic region and other linked candidate sequences that predispose to develop rheumatoid arthritis.

Altered electrophoretic behavior of DNA due to short-time UV-B irradiation

UV-B irradiation is often inevitable for visualization of DNA fragments after ethidium bromide staining. Three different simple-repeat-containing, double-stranded genomic DNA fragments were analyzed for UV-B (312 nm) damage using different gel electrophoretic systems. The effects of UV-B light were obvious after 5 min (31.5 kJ/m2) of irradiation in native polyacrylamide gel electrophoresis (PAGE). Standard single-strand conformation analyses revealed no alterations while a modification did. Sodium dodecyl sulfate (SDS)-PAGE was found to be highly sensitive with regard to the detection of damages and their time/dosage dependency. In addition, SDS-PAGE analysis pointed to different events occurring during UV-B irradiation. Alterations in DNA conformation were detected in every single strand analyzed after 1 min (6.3 kJ/m2) of UV-B exposure. Gel retardation analyses revealed significant changes of protein binding to target DNAs after 2 min of irradiation--possibly stemming from structural modifications and/or originating from binding sites for proteins involved in DNA repair.

Genetic control of the human V beta 13.2 T cell repertoire: importance of allelic variation outside the coding regions of the TCRBV13S2 gene

In humans, the T cell repertoire is influenced by HLA, T cell receptor null alleles and antigen. Here, we describe a novel mechanism, independent of superantigen or T cell receptor structure which influences the T cell repertoire in a V beta-dependent manner. We have identified a biallelic locus, the TCRBV13S2 T cell receptor gene, where allelic differences predominate in the non-coding regions including transitions, transversions and frameshift deletions. The expressed protein is non-polymorphic at this locus. The TCRBV13S2 genotype profoundly influences the circulating levels of V beta 13.2 CD4 T cells but does not affect T cell receptor expression or function.

A complex composed of at least two HeLa nuclear proteins protects preferentially one DNA strand of the simple (gt)n(ga)m containing region of intron 2 in HLA-DRB genes

Electrophoretic mobility shift assays reveal that HeLa nuclear proteins bind fast and with measurable affinity to target DNAs containing mixed simple repetitive (gt)n(ga)m stretches. Preincubation of the proteins at elevated temperature prevents the formation of the major DNA/protein complex in favour of several distinct assemblies. A similar pattern of retarded bands was observed employing higher salt concentrations in the binding reaction. Thus conformational changes of different proteins appear to influence the complex rather than alternating DNA structures. Separation of the total nuclear extract into a water soluble and an insoluble protein fraction leads to a complete loss of target DNA binding capability of the fractions. The binding capacity is restored by combining the two fractions suggesting that at least two protein components are necessary to form a complex with the target sequence. The proteins can be differentiated into heat sensitive, water soluble and temperature stable, water insoluble, respectively. Furthermore, specifically binding polypeptides are not detectable by Southwestern analyses, probably because the essential components are separated during electrophoresis. DNase I footprint analyses yield four different protein binding regions only on the (gt)n(ga)m harbouring strand. The footprints cover larger portions of the mixed simple repeat in addition to a portion 5' of the (gt)n part. Hence at least two nuclear protein components of unknown biological function have to be present simultaneously to protect preferentially the (gt)n(ga)m-containing strand of intron 2 in HLA-DRB genes.

Selected di- and tetranucleotide microsatellites from chromosomes 7, 12, 14, and Y in various Eurasian populations

Microsatellite polymorphisms of nine Eurasian populations (> 1200 chromosomes) were analyzed for the following loci: i) intronic (gt)n stretches of three T cell receptor (TCR) B loci on chromosome 7 (TCRBV6S1, TCRBV6S3, TCRBV6S7); ii) an intergenic (gt)n repeat in the region between the TCRDV3 and TCRAJ61 elements on chromosome 14; iii) two tetranucleotide simple repeats (D12S66, D12S67), not linked to known genes on chromosome 12; iv) a Y-chromosomal (gata)n polymorphism (DYS19). In general, allele frequencies and heterozygosity rates were similar, but specific alleles were missing in one or more populations. Distinct DYS19 alleles predominated in particular cohorts. Different allele frequencies were observed for the TCR loci in European and Asian populations. Tetranucleotide polymorphisms were distributed normally, whereas TCR alleles displayed bimodal frequency profiles. For TCRBV6S1 and TCRBV6S7, this profile reflects a diallelic protein polymorphism that correlates exactly with the length of the intronic repeats.

Frequent recombination in the human T-cell receptor beta gene complex

Although individual TCRVBV gene segments exhibit limited polymorphism, human T-cell receptor beta (TCRB) haplotypes are characterized by multiple different combinations of allelic markers. This observation suggests that genetic recombination may have played a role in the generation of these haplotypes. Meiotic recombination in a region spanning approximately 250 kilobases (kb) at the 3' end of the TCRB gene complex was investigated by extended family studies and by analysis of single sperm. Segregation patterns of polymorphic TCRB markers in families allowed the assignment of TCRB alleles to parental haplotypes and detection of recombinants among the offspring. Among the 178 informative paternal meioses, four (approximately 2%) were recombinant, whereas no recombinants were found in the 199 maternal meioses. In addition, segregation of two allelic markers was examined in a total of 1101 individual sperm from two heterozygous donors to detect exchange events in this region. The results revealed a similar rate of recombination, approximately 1.3%, which, along with the family data, suggests that at, least in males, meiotic recombination in this 250 kb region may be six times higher than the "average" rate of 1% per 10(6) bases that has been estimated for the human genome.

The extent of the human germline T-cell receptor V beta gene segment repertoire

An assessment of the size of the human TCRBV gene segment repertoire based on the identification of TCRBV gene segments in genomic DNA was undertaken. PCR amplification from cloned and uncloned genomic DNA sources, nucleotide sequencing, Southern blot hybridization, and cosmid cloning were used to identify TCRBV gene segments in multiple unrelated individuals. The key advantages to this approach were: 1) TCRBV gene segments which are expressed only at very low levels in cDNA libraries were still detectable, and 2) it was possible to discriminate between alleles at the same locus vs products of different loci. A total of 63 unique TCRBV gene segments were identified and sequenced. Six of these TCRBV gene segments had not been previously described. Thirty-four cosmid clones containing 51 of the 63 identified TCRBV gene segments were isolated and screened for the presence of additional novel TCRBV subfamily members. These results, obtained by a variety of complementary approaches, indicate that the human TCRBV germline repertoire encodes at least 63 TCRBV gene segments of which 52 are functional. The availability of the majority of these TCRBV gene segments on cosmid clones should facilitate further investigation of germline TCRBV gene segment polymorphism and putative disease associations.

Typing of artiodactyl MHC-DRB genes with the help of intronic simple repeated DNA sequences

An efficient oligonucleotide typing method for the highly polymorphic MHC-DRB genes is described for artiodactyls like cattle, sheep and goat. By means of the polymerase chain reaction, the second exon of MHC-DRB is amplified as well as part of the adjacent intron containing a mixed simple repeat sequence. Using this primer combination we were able to amplify the MHC-DRB exons 2 and adjacent introns from all of the investigated 10 species of the family of Bovidae and giraffes. Therefore, the DRB genes of novel artiodactyl species can also be readily studied. Oligonucleotide probes specific for the polymorphisms of ungulate DRB genes are used with which sequences differing in at least one single base can be distinguished. Exonic polymorphism was found to be correlated with the allele lengths and the patterns of the repeat structures. Hence oligonucleotide probes specific for different simple repeats and polymorphic positions serve also for typing across species barriers. The strict correlation of sequence length and exonic polymorphism permits a preselection of specific oligonucleotides for hybridization. Thus more than 20 alleles can already be differentiated from each of the three species.

Towards covering immunological genes with highly informative markers: a trans-species approach

To establish a highly informative screening system for immunologically relevant genes ("immunoprinting") we co-amplified via polymerase chain reaction (PCR) polymorphic exons plus adjacent intronic simple repetitive dinucleotide stretches in the T-cell receptor (Tcr) Vb6 and Major Histocompatibility Complex (MHC)-DRB loci in man and several ungulate species. In both gene families the basic structure of the simple repeat was found to be preserved for more than 70 x 10(6) years in all investigated species. The simple repeats exhibit extensive length variability. Distinct exon sequences are correlated with a defined repeat length and substructure. In addition, PCR and the oligonucleotides for typing were applicable to a broad range of species from different mammalian orders. Multiplex PCR of different members of the Tcr Vb6 family and MHC-DRB resulted in a complex pattern similar to an oligolocus fingerprint. Hence immunoprinting can be employed for searching for associations of immunologically relevant genes with diseases even across species barriers.