Nucleotide sequence and polymorphism analysis of canine DRA cDNA clones

Large-Scale Polymorphism Analysis of Dog Leukocyte Antigen Class I and Class II Genes (DLA-88, DLA-12/88L and DLA-DRB1) and Comparison of the Haplotype Diversity between Breeds in Japan

Polymorphisms of canine leukocyte antigen (DLA) class I (DLA-88 and DLA-12/88L) and class II (DLA-DRB1) genes are important for disease susceptibility studies, but information on the genetic diversity among dog breeds is still lacking. To better elucidate the polymorphism and genetic diversity between breeds, we genotyped DLA-88, DLA-12/88L, and DLA-DRB1 loci using 829 dogs of 59 breeds in Japan. Genotyping by Sanger sequencing identified 89, 43, and 61 alleles in DLA-88, DLA-12/88L, and DLA-DRB1 loci, respectively, and a total of 131 DLA-88-DLA-12/88L-DLA-DRB1 haplotypes (88-12/88L-DRB1) were detected more than once. Of the 829 dogs, 198 were homozygotes for one of the 52 different 88-12/88L-DRB1 haplotypes (homozygosity rate: 23.8%). Statistical modeling suggests that 90% of the DLA homozygotes or heterozygotes with one or other of the 52 different 88-12/88L-DRB1 haplotypes within somatic stem cell lines would benefit graft outcome after 88-12/88L-DRB1-matched transplantation. As previously reported for DLA class II haplotypes, the diversity of 88-12/88L-DRB1 haplotypes varied remarkably between breeds but was relatively conserved within most breeds. Therefore, the genetic characteristics of high DLA homozygosity rate and poor DLA diversity within a breed are useful for transplantation therapy, but they may affect biological fitness as homozygosity progresses.

Expanded dog leukocyte antigen (DLA) single nucleotide polymorphism (SNP) genotyping reveals spurious class II associations

The dog leukocyte antigen (DLA) system contains many of the functional genes of the immune system, thereby making it a candidate region for involvement in immune-mediated disorders. A number of studies have identified associations between specific DLA class II haplotypes and canine immune hemolytic anemia, thyroiditis, immune polyarthritis, type I diabetes mellitus, hypoadrenocorticism, systemic lupus erythematosus-related disease complex, necrotizing meningoencephalitis (NME) and anal furunculosis. These studies have relied on sequencing approximately 300 bases of exon 2 of each of the DLA class II genes: DLA-DRB1, DLA-DQA1 and DLA-DQB1. In the present study, an association (odds ratio=4.29) was identified by this method between Weimaraner dogs with hypertrophic osteodystrophy (HOD) and DLA-DRB1∗01501. To fine map the association with HOD, a genotyping assay of 126 coding single nucleotide polymorphisms (SNPs) from across the entire DLA, spanning a region of 2.5 Mb (3,320,000-5,830,000) on CFA12, was developed and tested on Weimaraners with HOD, as well as two additional breeds with diseases associated with DLA class II: Nova Scotia duck tolling retrievers with hypoadrenocorticism and Pug dogs with NME. No significant associations were found between Weimaraners with HOD or Nova Scotia duck tolling retrievers with hypoadrenocorticism and SNPs spanning the DLA region. In contrast, significant associations were found with NME in Pug dogs, although the associated region extended beyond the class II genes. By including a larger number of genes from a larger genomic region, a SNP genotyping assay was generated that provides coverage of the extended DLA region and may be useful in identifying and fine mapping DLA associations in dogs.

Association of Doberman hepatitis to canine major histocompatibility complex II

Doberman hepatitis (DH) is a chronic and progressive inflammatory liver disease that mainly affects female dogs. The high incidence of chronic hepatitis in Dobermans is suggestive of a genetic predisposition. DH is characterized by mononuclear cell infiltration and copper accumulation in the liver and major histocompatibility complex (MHC) class II antigen expression in the hepatocytes. In dogs, the MHC is referred to as the dog leukocyte antigen (DLA) system. In this study, the potential role of DLA genes in DH was investigated by sequence-based typing in the exon 2 of DLA-DRB1, -DQA1 and -DQB1. The case group comprised 37 Dobermans with subclinical or clinical DH. The control group consisted of 37 healthy Dobermans, with normal liver enzyme values and without immunosuppressive medication. The control dogs were over 10 years old to include dogs with the lowest genetic risk of DH. Our results indicate that Dobermans with homozygous DLA-DRB1*00601/DQA1*00401/DQB1*01303 [odds ratio (OR) = 14.9, confidence limit (CL) = 3.1-71.7, P < 0.00005], especially with homozygosity for DLA-DRB1*00601 (P < 0.0005), are susceptible to DH. The DQ heterodimer DLA-DQA1*00901/DQB1*00101 and the allele DLA-DRB1*01501 appear to confer protection against DH (P < 0.001). Allele and haplotype frequencies were compared using chi-squared statistics. The disease shows a complex pattern of inheritance, but the observed DLA class II association with DH suggests a role for the immune system in the development of the disease.

Transmission and expansion of HOXB4-induced leukemia in two immunosuppressed dogs: implications for a new canine leukemia model

OBJECTIVE

There are currently no large animal models to study the biology of leukemia and development of novel antileukemia therapies. We have previously shown that dogs transplanted with homeobox B4 (HOXB4)-transduced autologous CD34(+) cells developed myeloid leukemia associated with HOXB4 overexpression. Here we describe the transmission, engraftment, and expansion of these canine leukemia cells into two genetically unrelated, immunosuppressed dogs.

MATERIALS AND METHODS

Two dogs immunosuppressed after major histocompatibility complex-haploidentical hematopoietic cell transplantation and exhibiting mixed donor-host chimerism were accidentally infused trace amounts of HOXB4-overexpressing leukemia cells from a third-party dog.

RESULTS

Six weeks after infusion of HOXB4-overexpressing leukemia cells, these two dogs rapidly developed myeloid leukemia consisting of marrow and organ infiltration, circulating blasts, and, in one dog, chloromatous masses. Despite neither of these dogs sharing any dog leukocyte antigen haplotypes with the sentinel case, the HOXB4-transduced clones engrafted and proliferated without difficulty in the presence of immunosuppression. Chimerism studies in both dogs confirmed that donor and, in one case, host hematopoietic cell engraftment was lost and replaced by third-party HOXB4 cells.

CONCLUSIONS

The engraftment and expansion of these leukemia cells in dogs will allow studies into the biology of leukemia and development and evaluation of novel antileukemia therapies in a clinically relevant large animal model.

Sequence of the canine major histocompatibility complex region containing non-classical class I genes

We have sequenced a segment of 150,102 nucleotides of canine major histocompatibility complex (MHC) DNA, corresponding to the junction of the class I and class III regions. The distal portion contained five class III genes including two tumor necrosis factor genes and the proximal portion contained five genes or pseudogenes belonging to the class I region. The order of the class III region genes was conserved as in the porcine and human MHC regions. The order of the class Ib loci from the proximal side outwards was DLA-53, DLA-12a, DLA-64, stress-induced phosphoprotein-1, followed by DLA-12. Only DLA-64 and DLA-12 display an overall predicted protein sequence compatible with the expression of membrane-anchored glycoproteins. The other class 1b loci do not appear to be functional by sequence analysis. In all, these 10 genes spanned 24% of the total sequence. The remaining 76% comprised of a number of non-coding and repetitive DNA elements including long interspersed nuclear element (LINE) fragments, short interspersed nuclear elements (SINE), and microsatellites.

Cellular, serological, and molecular polymorphism of the class I and class II loci of the canine Major Histocompatibility Complex

This study was undertaken to determine the relationships between canine cellular and serological determinants and more recently described genes. Such relationships might reveal information about immunological reactivity or function of various proteins. To do this we studied the haplotypic associations of dog leukocyte antigen (DLA) class I and class II alleles determined from a panel of 14 DLA-D homozygous dogs. This panel of dogs was typed for the serological determinants DLA-A, DLA-B and DLA-C. Polymorphisms for DLA-DQA1, DLA-DQB1, DLA-DRB1 and DLA-88 were also determined. The number of alleles (one or two) for two microsatellite markers in the DLA region were also determined. Analyses of the nucleotide sequences and of the serological and cellular typing data revealed that phenotypic homozygosity, as defined by the DLA-D type in mixed leukocyte culture (MLC), tended to correlate with homozygosity at the DLA-DRB1 locus but not necessarily at the DLA-DQB1 locus. Furthermore, MLC specificity was determined by other loci besides DLA-DRB1 and DLA-DQB1. The amino acid at position 63 of the DR beta chain could contribute to the DLA-B serological specificity. DLA-88, the most polymorphic class I gene characterized to date, did not have an easily identifiable association with either the DLA-A or DLA-C class I serological specificities. Homozygosity or heterozygosity of each of two microsatellite markers, FH 2200 and FH 2202, located in the class I or class II region, respectively, did not correlate with homozygosity or heterozygosity of the most polymorphic known class I (DLA-88) or class II (DLA-DRB1) genes.

Nomenclature for factors of the dog major histocompatibility system (DLA), 2000: second report of the ISAG DLA Nomenclature Committee

The International Society for Animal Genetics (ISAG) Dog Leukocyte Antigen (DLA) Nomenclature Committee met during the "Comparative Evolution of the Mammalian major Histocompatibility Complex (MHC)" meeting in Manchester, UK on 10 September 2000. The main points discussed were the naming of class I genes and alleles, and the inclusion of alleles from other canidae.

Nomenclature for factors of the dog major histocompatibility system (DLA), 2000: Second report of the ISAG DLA Nomenclature Committee

The ISAG DLA Nomenclature Committee met during the "Comparative Evolution of the Mammalian MHC" meeting in Manchester, England on 10th September 2000. The main points discussed were the naming of class I genes and alleles, and the inclusion of alleles from other canidae.

DLA-DQB1 alleles and bone marrow transplantation experiments in narcoleptic dogs

Human narcolepsy is a neurological disorder known to be tightly associated with HLA-DQB1*0602. A clinically similar disorder has been described in various dog breeds. The canine form of the disease is inherited as an autosomal recessive disorder in Labrador retrievers and Doberman pinschers (canarc-1) but occurs sporadically in other breeds, most typically dachshunds and poodles. In this study, we have examined if there is a relationship between the development of narcolepsy and specific dog leukocyte antigen (DLA)-DQB1 alleles. Ninety-nine dogs were typed for DLA-DQB1-31 with narcolepsy and 68 control animals. Recent studies have linked the development of autosomal recessive canine narcolepsy to a disruption of the hypocretin receptor 2 (Hcrtr2) gene on the same chromosome as the canine MHC region (CFA12), but not close to the DLA. Four Hcrtr2-positive families (two Doberman pinscher families, one Labrador retriever family, one dachshund family) were analyzed at the DLA-DQ level. No relationship was found between narcolepsy and DLA in Hcrtr2-mediated narcolepsy but loose genetic linkage was observed (Zmax=2.3 at theta=25%, m= 40). Bone marrow transplantation between two DLA identical affected (Hcrtr2-/-) and unaffected (Hcrtr2+/-) siblings was also performed and found not to be successful neither in transmitting narcolepsy nor in relieving the symptoms in Doberman pinschers. DLA-DQB1 was next studied in 11 dogs with sporadic (non-familial) narcolepsy and in unrelated control animals of the same and different breeds. The allelic and carrier frequencies of various DLA-DQB1 alleles were analyzed. There was no strong positive or negative correlation between the development of narcolepsy and specific DLA-DQB1 alleles. These results do not support the involvement of DLA-DQ in canine narcolepsy, whether of sporadic or familial origin.

Dog class I gene DLA-88 histocompatibility typing by PCR-SSCP and sequencing

The dog has been an important model for solid organ and hematopoietic stem cell transplantation, as well as for studying autoimmune diseases, the growth of malignant tumors and the immunology of vaccines. Fundamental to the continuing usage of the canine model for research is the development of molecular-based histocompatibility typing. Previous histocompatibility methods have focused on class II genes. This study was undertaken to develop a molecular-based histocompatibility typing method for the most polymorphic class I gene, DLA-88. In this study, polymerase chain reaction single-stranded conformational polymorphism was used to separate alleles, thereby allowing sequenced-based typing.

Nomenclature for factors of the dog major histocompatibility system (DLA), 1998: first report of the ISAG DLA Nomenclature Committee

A Nomenclature committee for Factors of the Dog Major Histocompatibility System or Dog Leukocyte Antigen (DLA) has been convened under the auspices of the International Society for Animal Genetics (ISAG) to define a sequence based nomenclature for the genes of the DLA system. The remit of this committee includes: assignment of gene names rules for naming alleles assignment of names to published alleles assignment of names to new alleles rules for acceptance of new alleles DLA Nomenclature Committee, rules for acceptance, DLA genes and alleles, sequence based nomenclature.

Nomenclature for factors of the dog major histocompatibility system (DLA), 1998. First report of the ISAG DLA Nomenclature Committee. International Society for Animals Genetics

A Nomenclature Committee for factors of the dog major histocompatibility system or dog leukocyte antigen (DLA) has been convened under the auspices of the International Society for Animal Genetics (ISAG) to define a sequence-based nomenclature for the genes of the DLA system. The remit of this committee includes: i) assignment of gene names; ii) rules for naming alleles; iii) assignment of names to published alleles; iv) assignment of names to new alleles; and v) rules for acceptance of new alleles.

DLA-DRB1 and DLA-DQB1 histocompatibility typing by PCR-SSCP and sequencing

The dog has been an important model for solid organ and hematopoietic stem cell transplantation for over 30 years. Fundamental to the continuing usage of the model is the development of molecular-based histocompatibility typing of donors and recipients. Previous histocompatibility typing methods used in the dog have not been precise enough to identify dog leukocyte antigen (DLA)-matched unrelated dogs. This study was undertaken to begin the process of identifying DLA-matched unrelated dogs. In this study polymerase chain reaction-single-stranded conformational polymorphism is used to separate alleles thereby allowing sequenced-based typing of the two most polymorphic class II genes described to date in the dog DLA-DRB1 and DLA-DQB1.

Molecular analysis and polymorphism of the DLA-DQB genes

Partial-length cDNA clones and full-length genomic clones corresponding to a complete canine DQB class II gene were isolated. Southern analyses suggested the presence of two DQB genes--one of which appeared to be a pseudogene lacking exon 2 called DQB2. The other DQB gene, called DQB1, was isolated from a genomic phage clone and contained six exons. The DQB1 clone was restriction mapped, and exon 2 was sequenced from 70 dogs. Twenty alleles were found. Most of the amino acid substitutions occurred at putative positions in the peptide binding site. Inheritance of these sequences showed Mendelian segregation with one or two alleles per dog. Cluster analysis of the nucleotide and predicted amino acid sequences subdivided the canine DQB1 alleles into four major allelic groups. The number of nonsynonymous changes was higher than the number of synonymous changes in the putative antigen recognition sites suggestive of positive selection.

Molecular analysis of the DLA DR region

The dog is an important model for studying organ transplantation. In order to develop a DNA-based typing system, a genomic analysis of the canine DR region of the MHC was undertaken. Southern analysis suggests the presence of two DRB genes in most dogs and all have one DRA gene. One dog out of 200 examined contains only one DRB gene. The DRA gene was mapped in one lambda phage clone. One DRB gene (DRBB1) was localized to two overlapping phage clones. Another DRB gene (DRBB2) was localized to two overlapping phage clones. Sequence analysis of the two DRB genes suggests that one gene is intact (DRBB1) and one gene is a pseudogene (DRBB2) because it lacks a splice acceptor signal for exon 3 and lacks exons 2 and exon 4. Intron 1 and 2 sequence data from DRBB1 allow amplification of the polymorphic exon 2 which, in turn, can serve as a basis for developing a typing system for DRB.