Increased frequency of CD45 negative T cells (T zone cells) in older Golden retriever dogs.

T zone lymphoma (TZL) is characterized by the clonal expansion of T cells lacking expression of the pan-leukocyte antigen CD45 (TZ cells). A strong breed predisposition is observed in Golden retrievers. This study aimed to confirm aberrant CD45 mRNA expression and determine if Golden retrievers without clinical lymphoma have an increased frequency of circulating TZ cells. Gene expression analysis on confirmed TZL cases showed a significant decrease in CD45 expression compared to normal dogs. Peripheral blood samples from senior dogs, 242 Golden retrievers and 42 non-Golden retrievers, without evidence of lymphoproliferative disease were assessed for the presence of TZ cells by flow cytometry. Thirty-one percent of Golden retrievers had TZ cells compared to 14% of non-Golden retrievers. Thirty-four percent of Golden retrievers with TZ cells had a clonal T cell receptor gamma (TRG) gene rearrangement. Interestingly, 20% of Golden retrievers without TZ cells also had a clonal TRG rearrangement. Golden retrievers may have an increased risk of TZL due to an increased frequency of TZ cells.

A tumor-related lymphoid progenitor population supports hierarchical tumor organization in canine B-cell lymphoma.

BACKGROUND: Tumors have heterogeneous properties, which could be explained by the existence of hierarchically and biologically distinct tumor cells such as tumor-initiating cells (TICs). This model is clinically important, as TICs are promising targets for cancer therapies. However, TICs in spontaneous B-cell lymphoma have not been conclusively identified. HYPOTHESIS/OBJECTIVES: Tumor cells with a progenitor phenotype exist in B-cell lymphoma, reflecting a hierarchical organization. ANIMALS: Twenty-eight client-owned dogs with previously untreated B-cell lymphoma and 6 healthy dogs. METHODS: This was a prospective study. Flow cytometry was used to identify lymphoid progenitor cells (LPCs) that coexpressed hematopoietic progenitor antigens CD34, CD117, and CD133, with lymphoid differentiation markers CD21 and/or CD22 in B-cell lymphoma. The polymerase chain reaction for antigen receptor rearrangements was used to analyze clonality and relatedness of tumor populations. A xenograft model with NOD/SCID/IL-2Rγ(-/-) mice was adapted to expand and serially transplant primary canine B-cell lymphoma. RESULTS: LPCs were expanded in lymph nodes from 28 dogs with B-cell lymphoma compared with 6 healthy dogs (P= .0022). LPCs contained a clonal antigen receptor gene rearrangement identical to that of the bulk of tumor cells. Canine B-cell lymphoma xenografts in recipient mice that maintained LPCs in the tumors were recurrently observed. CONCLUSIONS AND CLINICAL IMPORTANCE: These results suggest the presence of a hierarchy of tumor cells in B-cell lymphoma as has been demonstrated in other cancers. These findings have the potential to impact not only the understanding of lymphoma pathogenesis but also the development of lymphoma therapies by providing novel targets for therapy.

Use of FoxP3 expression to identify regulatory T cells in healthy dogs and dogs with cancer.

Regulatory T cells (Treg) are a distinct group of T lymphocytes with immunosuppressive properties that serve normally to prevent harmful autoimmune responses. However, Tregs can also interfere with beneficial immune responses such as anti-tumor and anti-viral immunity in humans and rodents. Given the overall importance of Tregs, it is likely that they play an important role in diseases of dogs as well. However, at present reagents required for identification of Tregs in dogs are not available. Therefore, we investigated whether expression of FoxP3, a transcription factor that is highly expressed in Tregs in humans and rodents could also be used to identify Tregs in dogs. We found that a cross-reactive FoxP3 antibody identified a subset of CD4(+) T cells in blood and lymph nodes of dogs. By flow cytometry the mean percentage of FoxP3(+)CD4(+) T cells in normal dogs was 4.3% in blood and 9.8% in the lymph nodes. In dogs with cancer, there was a significant increase in numbers of Treg in blood (7.5%) and tumor-draining lymph nodes (17.1%) compared to age-matched healthy control dogs. We also found that FoxP3(+)CD4(+) T cells in dogs could be significantly expanded in vitro by TCR activation together with addition of TGF-beta and IL-2. Treated cells also significantly increased expression of TGF-beta and IL-10mRNA. We conclude from these studies that a cross-reactive FoxP3 antibody can be used to identify Tregs in dogs and that this reagent may serve as a useful tool for investigating the role of Treg in a variety of diseases of dogs.

Diagnosis of canine lymphoid neoplasia using clonal rearrangements of antigen receptor genes.

Although the diagnosis of canine leukemia and lymphoma in advanced stages is usually uncomplicated, some presentations of the disease can be a diagnostic challenge. In certain situations, lymphoma and leukemia can be difficult to distinguish from a benign reactive proliferation of lymphocytes. Because clonality is the hallmark of malignancy, we have developed an assay that uses the polymerase chain reaction to amplify the variable regions of immunoglobulin genes and T-cell receptor genes to detect the presence of a clonal lymphocyte population. The assay detected clonally rearranged antigen receptor genes in 91% of the 77 dogs with lymphoid malignancy. Of the 24 dogs tested, that were either healthy or had clearly defined conditions not related to lymphoid malignancy, a clonally rearranged antigen receptor gene was found in one (a dog with Ehrlichia canis infection). Gene rearrangement was appropriate for the immunophenotype (immunoglobulin gene rearrangement in B-cell leukemias and T-cell receptor gene rearrangement in T-cell leukemias). Dilution analysis showed that the clonal rearrangement could be detected when 0.1-10% of the DNA was derived from neoplastic cells, depending on the source tissue. Potential applications of this assay include the diagnosis of lymphoma or leukemia in biopsy samples, cavity fluids, fine needle aspirates, bone marrow and peripheral blood; the determination of lineage (B or T cell); staging of lymphoma; and detection of residual disease after chemotherapy.

Organization of the canine major histocompatibility complex: current perspectives.

The dog is a valuable model for studying several human diseases as well as one of the most important models for organ transplantation. Important to understanding the pathophysiology or development of some of these diseases is an understanding of the canine major histocompatibility complex (MHC) or dog leukocyte antigen (DLA). Initial characterization of the DLA involved primarily cellular, serological, and biochemical analyses. Later a molecular analysis of the DLA region was begun. There are at least four complete class I genes: DLA-88, DLA-12, DLA-64, and DLA-79. DLA-88 is highly polymorphic, with more than 40 alleles obtained from an examination of 50 mixed breed dogs. The other class I loci are less polymorphic, with fewer than 12 alleles each. In the class II region there is one complete DRB gene called DLA-DRB1 with at least 24 alleles and one full-length DQB gene, DLA-DQB1, with 20 alleles characterized to date. DLA-DQA is less polymorphic with nine alleles and DLA-DRA appears monomorphic. Two highly polymorphic canine microsatellite markers, one located in the class I region and one located in the class II region, can be used to identify DLA-matched and -mismatched dogs within families for organ transplantation experiments. Future projects include mapping the DLA region by pulsed-field gel electrophoresis and using a recently constructed canine bacterial artificial chromosome (BAC) library to search for new genes within the DLA. The dog has been a useful model for understanding several human diseases such as gluten-sensitive enteropathy (Hall and Batt 1990), rheumatoid arthritis (Halliwell et al. 1972), narcolepsy (Tafti et al. 1996), and systemic lupus erythematosus (Lewis and Schwartz 1971, Teichner et al. 1990), as well as an important model for solid organ and hematopoietic stem cell transplantation (Storb and Deeg 1985). Much of the impetus behind efforts to characterize the canine MHC comes from its importance in transplantation. In spite of the dog's importance in studying human disease and in immunology, molecular analysis of the DLA has lagged behind that of the mouse and human as well as several agricultural animals.

Molecular analysis of six dog leukocyte antigen class I sequences including three complete genes, two truncated genes and one full-length processed gene.

We have isolated six distinct dog leukocyte antigen (DLA) class I sequences. An additional functional nonclassical class I gene, DLA-79, was characterized previously. This brings the number of isolated canine class I sequences to seven. These seven loci account for nearly all class I sequences detected in genomic DNA by Southern blotting. With approximately seven members, the class I gene family in dog is considerably less complex than in either human or mouse. Three of the six sequences described in this article contain complete class I genes. These genes have the typical arrangement of exons and introns, and their predicted protein sequences have the features expected of expressed class I molecules. Two sequences contain truncated genes. These genes, having only partial class I homology and disruptive mutations, are clearly nonfunctional. The remaining locus contains a full-length processed gene which is unique among characterized class I loci. Sequence comparisons were performed to examine evolutionary relationships among the family members. Two sequences, DLA-64 (complete) and -53 (truncated), appear to be chimeras presumably formed by interlocus recombination. Using the reverse transcription-polymerase chain reaction, mRNA originating from each of the three complete genes was identified in canine peripheral blood leukocytes. DLA-79 specific transcripts were identified previously. Thus, each of the four complete canine class I genes is transcribed in vivo.

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.

Molecular analysis of DLA-DRBB1 polymorphism.

The polymorphism of the canine major histocompatibility complex class II DRB gene, DRBB1, was analyzed. Exon 2 that encodes the polymorphic beta 1 domain was amplified by the polymerase chain reaction (PCR). The PCR product from 250 dogs was cloned and sequenced. Eighteen alleles were identified. Most of the variation in amino acid composition occurred at 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 DRBB1 alleles into three major allelic groups. The number of nonsynonymous changes was higher than the number of synonymous changes in the putative antigen recognition sites indicative of positive selection. The data generated can serve as a basis for developing a typing assay for the canine DRBB1 gene.

Histocompatibility testing of dog families with highly polymorphic microsatellite markers.

The dog has served traditionally as a model for marrow and organ transplantation. A key component of any study of transplantation is histocompatibility typing of donors and recipients. Towards the development of a less expensive, more simplified typing system within canine families, a new highly polymorphic microsatellite marker for the canine Major Histocompatibility Complex class II region was isolated and characterized. In addition, we report on the application of class I and class II microsatellite-based markers for following the inheritance of the alleles within the canine analog of the human HLA loci, DLA, through multi-generation pedigree.

Molecular analysis and polymorphism of the DLA-DQA gene.

A full-length cDNA clone and two overlapping genomic clones corresponding to the canine DQA class II gene were isolated and sequenced. Restriction mapping and sequence data allow identification and orientation of the five exons corresponding to the alpha (alpha) chain. Sequence analysis of exon 2 amplified from 17 unrelated dogs of various breeds identified seven alleles. The structure of the canine DQA gene is similar to HLA-DQA1 and other mammalian DQA genes. This study will serve as a reference for developing a typing system for the DLA-DQA gene for donor and recipient matching in the canine model for organ and bone marrow transplantation.

Structure and expression of a divergent canine class I gene.

We have isolated and characterized a canine class I MHC (dog leukocyte Ag, DLA) gene, DLA-79. The deduced protein sequence shares only 65% identity with a previously published canine class I cDNA, designated DLA-A, and exhibits 64% amino acid identity with the HLA-A, -B, -C consensus. The peptide-binding region of DLA-79 is unusual. Three of four highly conserved tyrosine residues (Tyr7, 59, 159, and 171), proposed to interact with the N terminus of peptide-Ag, are substituted. Additionally, the long alpha-helix lining the peptide-binding region in the alpha 1 domain contains one more amino acid residue than that observed in typical class I. Together, these features suggest that DLA-79 binds a distinct subset of peptides or other ligands. This gene has been expressed in a class I null human lymphoblastoid cell line, and the encoded heavy chain associated with beta 2-microglobulin and was transported to the cell surface. Ribonuclease protection analysis detected low levels of gene-specific mRNA in a broad variety of dog tissues. The highest levels were found in skeletal muscle, a tissue expressing relatively low levels of classical class I Ag. These data suggest that DLA-79 is functional and plays a specialized role in the immune response. Nucleotide sequence analysis of second exon sequences (encoding the alpha 1 domain) identified only two alleles in five dogs of different breeds; a third variant was found in a coyote. The divergent structure, relatively low mRNA expression, and limited polymorphism of this gene suggest that DLA-79 is not a classical or class Ia gene, but rather, an analogue of the MHC class Ib genes of humans and rodents.

Molecular analysis of the T-cell acute lymphoblastic leukemia-associated t(1;7)(p34;q34) that fuses LCK and TCRB.

Previously we had characterized the t(1;7)(p34;q34) translocation from HSB-2. This translocation fused the beta T-cell receptor gene (TCRB) constant region and transcriptional enhancer with the type I transcription unit of the LCK gene on the derivative 1 [der(1)] chromosome. The type II promoter was translocated to the der(7) chromosome. Regarding the mechanism of the t(1;7) in HSB-2, we identified an alternating purine-pyrimidine tract (G-T)17 at the 1p34/LCK breakpoint. Additionally, sequence analysis of both breakpoint junctions provided data that implicate the V(D)J recombinase in formation of the t(1;7). A heptamer-nonamer recognition sequence with a 12-bp spacer was found in the immediate vicinity of the 1p34/LCK breakpoint and, thus, chromosomal breakage at 1p34 may be explained as resulting from recombinase activity. Because phosphorylation of Tyr-505 in vivo regulates the tyrosine kinase activity of p56lck we amplified a region from LCK exon 12 that contains the codon for Tyr-505 and showed no mutation of this codon in HSB-2 DNA and, therefore, p56lck in HSB-2 is not activated by mutation of Tyr-505. We have analyzed LCK gene expression in HSB-2 and SUP-T12 cell lines. RNase protection analysis identified almost exclusively type I transcripts in HSB-2. An independent t(1;7) in SUP-T12 also resulted in the juxtaposition of LCK to TCRB. The breakpoint in SUP-T12 occurred 2 kb 5' of the type II promoter, leaving an intact LCK gene on the der(1) chromosome. RNase protection analysis identified both type I and type II LCK transcripts in a 3:1 ratio in SUP-T12. Factors other than proximity to the TCRB enhancer must affect promoter utilization in this cell line.

Rearrangement of the MLL gene in acute lymphoblastic and acute myeloid leukemias with 11q23 chromosomal translocations.

BACKGROUND: Translocations involving chromosome band 11q23 are very frequent in both acute lymphoblastic and acute myeloid leukemias and are the most common genetic alteration in infants with leukemia. In all age groups and all phenotypes of leukemia, an 11q23 translocation carries a poor prognosis. A major question has been whether one or several genes on band 11q23 are implicated in these leukemias. Previously, we identified the chromosomal breakpoint region in leukemias with the common 11q23 translocations and subsequently cloned a gene named MLL that spans the 11q23 breakpoint. METHODS: We isolated a 0.74-kb BamHI fragment from a complementary DAN (cDNA) clone of the MLL gene. To determine the incidence of MLL rearrangements in patients with 11q23 abnormalities, we analyzed DNA from 61 patients with acute leukemia, 3 cell lines derived from such patients, and 20 patients with non-Hodgkin's lymphoma and 11q23 aberrations. RESULTS: The 0.74-kb cDNA probe detected DNA rearrangements in the MLL gene in 58 of the patients with leukemia, in the 3 cell lines, and in 3 of the patients with lymphoma. All the breaks occurred in an 8.3-kb breakpoint cluster region within the MLL gene. The probe identified DNA rearrangements in all 48 patients with the five common 11q23 translocations involving chromosomes 4, 6, 9, and 19, as well as in 16 patients with uncommon 11q23 aberrations. Twenty-one different chromosomal breakpoints involving the MLL gene were detected. CONCLUSIONS: MLL gene rearrangements were detected with a single probe and a single restriction-enzyme digest in all DNA samples from patients with the common 11q23 translocations as well as in 16 patients or cell lines with other 11q23 anomalies. The ability to detect an MLL gene rearrangement rapidly and reliably, especially in patients with limited material for cytogenetic analysis, should make it possible to identify patients who have a poor prognosis and therefore require aggressive chemotherapy or marrow transplantation.

Molecular analysis of a t(11;14)(q23;q11) from a patient with null-cell acute lymphoblastic leukemia.

/lp;&-3qChromosome 11, band q23, is the frequent site of recurring cytogenetic rearrangements in human leukemia. We have cloned and sequenced the breakpoint junctions from a patient who had null-cell acute lymphoblastic leukemia (ALL) with a t(11;14)(q23;q11). The chromosome 14 breakpoints occurred within the TCRD locus, close to two diversity segments. The chromosome 11 breakpoint occurred between two head-to-head heptamer sequences, and junctional diversity was evident at both derivative junctions, suggesting involvement of the V(D)J recombinase. The TCRA/D locus on the normal chromosome 14 had undergone a V delta 2-D delta 3-psi J alpha joining. Two phage clones with this VDJ rearrangement were isolated; one of these contained an intra-J alpha region deletion. Two clones with the derivative 11 junction were isolated; one of these had a similar, but not identical, deletion. A heptamer-nonamer recognition sequence (located approximately 70 kb 5' to C alpha), not associated with a TCR gene coding segment, was found in the immediate vicinity of both 5' breakpoints. We have designated this sequence 5'del for 5' deleting element. An intra-J alpha region deletion involving this heptamer-nonamer was previously identified in the leukemia cells recovered from a patient who had T-cell ALL. Fifty kilobases of DNA on 11q23 surrounding the breakpoint were cloned and analyzed. No CpG islands or conserved sequences were identified within this region.(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning of cDNAs of the MLL gene that detect DNA rearrangements and altered RNA transcripts in human leukemic cells with 11q23 translocations.

Recurring chromosomal abnormalities involving translocations at chromosome 11 band q23 are associated with human myeloid and lymphoid leukemia as well as lymphoma. We have identified the gene located at this break-point and have named it MLL (for myeloid-lymphoid, or mixed-lineage, leukemia). The t(4;11), t(6;11), t(9;11), and t(11;19) are among the most common reciprocal translocations in leukemia cells involving this chromosomal band. We now have evidence that the breakpoints in all of these translocations are clustered within a 9-kilobase (kb) BamHI genomic region of the MLL gene. By Southern blot hybridization using a 0.7-kb BamHI cDNA fragment of the MLL gene called MLL 0.7B, we have detected rearrangements of DNA from cell lines and patient material with an 11q23 translocation in this region. Northern blot analyses indicate that this gene has multiple transcripts, some of which appear to be lineage-specific. In normal pre-B cells, four transcripts of 12.5, 12.0, 11.5, and 2.0 kb are detected. These transcripts are also present in monocytoid cell lines with additional hybridization to a 5.0-kb transcript, indicating that expression of different-sized MLL transcripts may be associated with normal hematopoietic lineage development. In a cell line with a t(4;11), the expression of the 12.5-, 12.0-, and 11.5-kb transcripts is reduced, and there is evidence of three other altered transcripts of 11.5, 11.25, and 11.0 kb. Thus, these 11q23 translocations result in rearrangements of the MLL gene and may lead to altered function(s) of MLL and of other gene(s) involved in the translocation.

The LCK gene is involved in the t(1;7)(p34;q34) in the T-cell acute lymphoblastic leukemia derived cell line, HSB-2.

HSB-2 is a cell line derived from a patient who had T-cell acute lymphoblastic leukemia (T-cell ALL) with a t(1;7)(p34;q34). We used a genomic probe from the T-cell receptor beta (TCR beta) locus (7q34) to identify DNA rearrangements in HSB-2. Two rearranged BglII DNA fragments were cloned, and one of these clones was shown to contain the translocation breakpoint on the derivative chromosome I [der(I)]. We used a probe derived from this clone to isolate an unrearranged phage clone encompassing the breakpoint at Ip34. The restriction map of this clone was compared to the published maps of known protooncogenes located at Ip32-34. By restriction mapping, Southern blot analysis, and DNA sequencing we showed that the translocation breakpoint on chromosome I is located within the first intron of the LCK gene. The LCK gene codes for p56lck, a member of the SRC family of cytoplasmic tyrosine protein kinases. There are two classes of LCK transcripts (type I and type II), each expressed from a distinct promoter, and each having a unique 5' untranslated region (UTR); the protein coding regions of the two classes are identical. The breakpoint in the t(1;7) separates the two LCK promoters and juxtaposes the constant region of the TCR beta locus with the proximal promoter and with the protein-coding region of the LCK gene on the der(I) chromosome.

The IgA heavy-chain gene family in rabbit: cloning and sequence analysis of 13 C alpha genes.

Southern analysis has previously shown that the rabbit genome contains multiple genes coding for the constant regions of IgA heavy chains. In the present study, clones containing these C alpha genes have been isolated from cosmid and phage libraries. Restriction mapping and Southern analysis of the clones identified 13 non-allelic C alpha genes; 11 of the genes were clustered in individual or overlapping clones. The clustered genes are separated by 8-18 kb, and in total, the C alpha genes span a minimum of 160 kb of DNA. Southern analysis has shown that all genes within a cluster have the same transcriptional orientation, and that switch sequences are present 5' of at least 12 of the 13 genes. The nucleotide sequence of each C alpha gene was determined, and it appears that all genes are functional; thus, rabbit may have as many as 13 IgA isotypes. Comparisons of the protein sequences encoded by the 13 C alpha genes showed that the CH2 and CH3 domains of the alpha-chains are highly conserved, whereas the CH1 and hinge regions are highly diverse. Southern analysis of genomic DNA samples from other species within the order Lagomorpha showed that all samples had multiple C alpha hybridizing fragments. Thus, it is likely that all lagomorphs have multiple IgA isotypes and hence complex secretory immune systems.