Primate DRB6 pseudogenes: clue to the evolutionary origin of the HLA-DR2 haplotype

The HLA-DR2 haplotype contains three \-chain encoding DRB genes and one -chain encoding DRA gene. Of the three DRB genes, two are presumably functional (HLA-DRB1 and HLA-DRB5), whereas the third (HLA-DRBV1) is a pseudogene. A pseudogene closely related to HLA-DRBVI is present in the chimpanzee (Patr-DRB6) and in the gorilla (Gogo-DRB6). We sequenced the HLA-DRBVI and Patr-DRB6 pseudogenes (all exons and most of the introns), and compared the sequence to that of the Gogo-DRB6 gene (of which only the exon sequence is available). All three pseudogenes seem to lack exon 1 and contain other deletions responsible for shifts in the translational reading frame. At least the HLA-DRBVI pseudogene, however, seems to be transcribed nevertheless. The chimpanzee pseudogene contains two inserts in intron 2, one of which is an Alu repeat belonging to the Sb subfamily, while the other remains unidentified. These inserts are lacking in the human gene. A comparison with sequences published by other investigators revealed the presence of the HLA-DRBVI pseudogene also in the DRI and DRw10 haplotypes. Measurements of genetic distances indicate DRB6 to be closely related to the DRB2 pseudogene and to the HLA-DRB4 functional gene. In humans, gorillas, and chimpanzees, the DRB6 pseudogene is associated with the same functional gene (DRB5) indicating that this linkage disequilibrium is at least six million years old and that DR2 is one of the oldest DR haplotypes in higher primates.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M77284-M77295. Address correspondence and offprint requests to: J. Klein.     

Comparative anatomy of the primate major histocompatibility complex DR subregion: evidence for combinations of DRB genes conserved across species.

The class II region of the human major histocompatibility complex (HLA) is made up of three major subregions designated DR, DQ, and DP. With the aim of gaining an insight into the evolution and stability of DR haplotypes, a total of 63 cosmid clones were isolated from the DR subregion (Gogo-DR) of a western lowland gorilla. All but one of these cosmid clones were found to fall into two clusters. The larger cluster, A, was defined by 41 overlapping cosmid clones and contained a DRB gene segment made up of exons 4 through 6 and four DRB genes, designated Gogo-DRB6, Gogo-DRB5*01, Gogo-DRB8, and Gogo-DRB3*01. The total length of this cluster was approximately 180 kb. The second cluster, B, encompassed a contiguous DNA stretch of approximately 145 kb and was composed of 21 overlapping cosmid clones. Cluster B contained three DRB genes, designated Gogo-DRB1*08, Gogo-DRB2, and Gogo-DRB3*02. One cosmid clone (WP1-9) containing a DRB pseudogene could not be linked to either cluster A or B. Neither the organization of cluster A nor that of cluster B was identical to that of known HLA-DR haplotypes. However, two gorilla DRB genes, Gogo-DRB6 and Gogo-DRB5*01, the human counterparts of which are linked in the HLA-DR2 haplotype, were found to be located next to each other in cluster A. The arrangement of the Gogo-DRB genes in cluster B, which is presumed to be the gorilla DR8 haplotype, was similar to that of HLA-DR3/DR5/DR6 haplotypes and to that of the presumed ancestral HLA-DR8 haplotype.(ABSTRACT TRUNCATED AT 250 WORDS)     

HLA-DP/DR interaction in early onset pauciarticular juvenile chronic arthritis

We investigated the polymorphic second exon of the HLA-DPB1 and HLA-DRB1 genes, using in vitro DNA amplification by polymerase chain reaction (PCR) and oligonucleotide hybridization in 136 patients with early onset pauciarticular juvenile chronic arthritis (EOPA-JCA) and 199 healthy controls. The analysis of the HLA-DRB1 system revealed that most of the DRB1 alleles are not indifferent with respect to susceptibility to EOPA-JCA. There is a hierarchy of susceptible (DRB1*08, DR5), permissive (DRB1*01), moderately protective (DR2, DRB1*04), and protective (DRB1*07) alleles. In contrast, no hierarchy could be shown for the HLA-DPB1 system. DPB1*0201 was found to be susceptible. The relatively frequent alleles DPB1*0402 and DPB1*0401 seem to be indifferent. The associations with DPB1*0201, DR5, and DRB1*08 are independent of each other: that is to say they, are not brought about by linkage disequilibrium. The susceptible alleles DPB1*0201 and DR5 show evidence for interaction in the pathogenesis of EOPA-JCA. Interaction seems likely between DPB1*0201 and DRB1*08, DR5 and DRB1*08, or between DR6 and DRB1*08. The strongest interaction exists between DPB1*0201 and a common DQ factor associated with both DR5 and DRB1*08. Finally, we observed a hierarchy among the various marker combinations, where the risk of developing EOPA-JCA increases with the number of associated markers present in an individual.This work was supported by SFB217.The data presented here are part of the doctoral thesis of C. Paul.     

Allelic diversity at the primate major histocompatibility complex DRB6 locus

The HLA-DRB6 gene (also called DRB/V1) has been found only in about 26% of human HLA haplotypes, i.e.; DR1, DRw10, and DR2-bearing ones (Corell et al. 1991). In contrast, exon-2 DRB6 sequences have been obtained from all tested primates: nine chimpanzees (Pan troglodytes), three gorillas (Gorilla gorilla) and three orangutans (Pongo pygmaeus); other apes which had already been sequenced (one gorilla and one chimpanzee) also had the DRB6 gene. Thus, all apes tested from three different species, some of them evolutionary separated by at least 14–16 million years, bear the DRB6 gene. In addition, more than one gene copy per haplotype has been found in one chimpanzee; this, together with the apparent loss of this gene in some of the human DR haplotypes, may indicate that the DR genome has undergone evolutionary changes more recently and more actively than class I or III genes. In addition, ten different and presumably allelic DRB6 exon-2 sequences have been obtained, and some of them coming from different species are more similar to each other than the one from the same species; this finding goes in favor of the trans-species theory of major histocompatibility complex polymorphism generation. Also, data are presented supporting that DRB6 may be one of the eldest genes of the DRB family, thus one of the first to diverge from the ancestral DRB gene.The contribution to this paper by A. Corell and P. Morales is equal, and the order of the authorship is arbitrary.     

The chimpanzee major histocompatibility complex class II DR subregion contains an unexpectedly high number of beta-chain genes

The major histocompatibility complex (MHC) class II DR subregion of the chimpanzee was studied by restriction fragment length polymorphism (RFLP) analysis. Genomic DNA obtained from a panel of 94 chimpanzees was digested with the restriction enzyme Taq I and hybridized with an HLA-DR probe specific for the 3' untranslated (UT) region. Such a screening revealed the existence of 14 distinct DRB/Taq I gene-associated fragments allowing the definition of 11 haplotypes. Segregation studies proved that the number of chimpanzee class II DRB/Taq I fragments is not constant and varies from three to six depending on the haplotype. Comparison of these data with a human reference panel manifested that some MHC DRB/Taq I fragments are shared by man and chimpanzee. Moreover, the number of HLA-DRB/Taq I gene-associated fragments detected in a panel of homozygous typing cells varies from one to three and corresponds with the number of HLA-DRB genes present for most haplotypes. However, a discrepancy is observed for the HLA-DR4,-DR7, and -DR9 haplotypes since a fourth HLA-DRB pseudogene present within these haplotypes lacks its 3' UT region and thus is not detected with the probe used. These results suggest that chimpanzees have a higher maximum number of DRB genes per haplotype than man. As a consequence, some chimpanzee haplotypes must show a dissimilar organization of the MHC DR subregion compared to their human equivalents. The implications of these findings are discussed in the context of the trans-species theory of MHC polymorphism. Address correspondence and offprint requests to: R. E. Bontrop.     

Analysis of GC-rich repetitive nucleotide sequences in great apes

The genomes of four primate species, belonging to the families Pongidae (chimpanzee, gorilla, and orangutan) and Hylobatidae (gibbons), have been analyzed for the presence and organization of two human GC-rich heterochromatic repetitive sequences: Satellite (Sat) and LongSau (LSau) repeats. By Southern blot hybridization and PCR, both families of repeats were detected in all the analyzed species, thus indicating their origin in an ape ancestor. In the chimpanzee and gorilla, as in man, Sat sequences showed a 68-bp Sau3A periodicity and were preferentially organized in large clusters, whereas in the orangutan, they were organized in DNA fragments of 550 bp, which did not seem to be characterized by a tandem organization. On the contrary, in each of the analyzed species, the bulk of LSau sequences showed a longer Sau3A periodicity than that observed in man (450–550 bp). Furthermore, only in the chimpanzee genome some of LSau repeats seemed to be interspersed within blocks of Sat sequences. This sequence organization, which also characterizes the human genome, is probably absent in the gorilla. In fact, the analysis of a gorilla genomic library suggested that LSau repeats are not preferentially in linkage with Sat sequences. Moreover, LSau sequences were found in a genomic sector characterized by the simultaneous presence of L1 and (CA) repeats, as well as of anonymous sequences and known genes. In spite of the different sequence organization, the nucleotide differences between complete human and gorilla LSau repeats were very few, whereas one gorilla LSau repeat, interrupted by a probably-truncated L1 transposon, showed a higher degree of divergence. Besides the gorilla, this unusual sequence organization was detected in man, and, to a lesser extent, in the chimpanzee. Correspondence to: R. Meneveri     

DNA typing of HLA-DR β chain genes can discriminate between undetected alleles and real homozygotes

The polymorphism of HLA-DR antigens has been studied by Southern blot hybridization under conditions specific for the detection of the DR chain genes. Haplotype-specific patterns were defined with DNA from DR1, 2, 3, 4, 7, w8, w11, w12, and W13 homozygous typing cells, with restriction enzymes Eco RI, Bgl I, and Pvu II. Certain serological specificities, such as DR2, DR3, and DR7, can be encoded by distinct allelic forms of DR chain genes. The procedure of DNA typing was applied to family analysis of individuals expressing only a single DR specificity upon serological typing. Three cases are described here: (1) in family GR, phenotypic DR 7 homozygotes correspond to genomic heterozygotes, and a novel DR7 allele is described: (2) in family RU, the genes corresponding to a serologically undetected (blank) DR allele were identified by restriction fragment length polymorphism (RFLP); this novel DR haplotype has an RFLP pattern similar to those of the DRw52 family, even though this specificity was not expressed on the DR-blank lymphocytes; (3) in family RG, there is no blank allele, but a homozygote RFLP situation at the DR subregion.     

HLA class II alleles and measles virus-specific cytokine immune response following two doses of measles vaccine

Measles virus-specific T cells and the production of cytokines play a critical role in the immune response following measles immunization. To understand the genetic factors that influence variation in IFN- and IL-4 responses following measles immunization and to provide insight into the factors influencing both cellular and humoral immunity to measles, we assessed associations between human leukocyte antigen (HLA) class II genes and measles-specific Th1 and Th2-type cytokine responses in peripheral blood lymphocytes from 339 children previously vaccinated with two doses of measles-mumps-rubella vaccine (MMR-II). Median values for measles-specific IFN- and IL-4 secretion levels were 40.73 and 9.71 pg/ml, respectively. The global tests suggested associations between measles-specific IFN- response and alleles of the DRB1 and DQB1 loci (P=0.07 and P=0.02, respectively). Specifically, DRB1*0301, *0901, and *1501 alleles were significantly associated with IFN- secretion. The alleles that suggested evidence of an HLA association with IL-4 secretion were DRB1*0103, *0701, and *1101. Th1 cytokine responses and DQB1 allele associations revealed that the alleles with the strongest association with IFN- secretion were DQB1*0201, *0303, *0402, and *0602. Specific alleles with a suggestive association with low measles-specific Th2 cytokine responses were DQB1*0202 and *0503. In addition, DPB1*0101, *0201, and *0601 alleles provided suggestive evidence of an HLA association with measles-induced IFN- response, while DPB1*0501 was associated with an IL-4 response. These data suggest that IFN- and IL-4 cytokine responses to measles may be genetically restricted in part by HLA class II genes, which in turn can restrict the cellular immune response to measles vaccine.     

The single DR β gene of the DRw8 haplotype is closely related to the DR β 3III gene encoding DRw52

In most individuals two HLA-DR genes are expressed from each chromosome. One of these genes encodes one of the classical DR specificities, while the other encodes either of the supertypic DRw52/DRw53 specificities. In addition to these genes usually one or two DR pseudogenes are present. In contrast, the DRw8 chromosomal region only contains a single DR gene. To determine the relationship of this single gene to the multiple DR genes of other DR specificities, comparisons of Southern genomic blots were carried out. In this analysis genomic clones for each individual DR chain locus were included. The DR w8 gene was indistinguishable from the DR III gene of DR3 cells (encoding DRw52), suggesting that it is closely related to the latter gene. The functional implications of this finding are discussed.     

DNA polymorphism of HLA class II genes in primary biliary cirrhosis

We investigated the DNA restriction fragment length polymorphism of the major histocompatibility complex class II genes: HLA-DRB,-DQA,-DQB, DPA,-DPB, the serologically defined HLA-A, B, C, DR antigens, and the primed lymphocyte typing defined HLA-DP antigens in 23 Danish patients with primary biliary cirrhosis (PBC) and in healthy Danes. The following genetic markers were found with increased frequencies in PBC: HLA-B8 (relative risk, RR=2.4, P<0.05, corrected P>0.05), HLA-DR3 (RR=3.4, P<0.01, corrected P<0.05), the DRB3 ^* 01/02/03 (DRw52) associated DRB Bgl II 9.1 kilobase (kb) fragment (RR= 2.9; P<0.05, corrected P>0.05), the DQA1 ^* 0501 associated DQA Taq I4.8 kb fragment (RR=3.1; P<0.05, corrected P>0.05), the DQB1 ^* 0201 (DQw2) associated DQB Hin dIII 11.5 kb fragment (RR=3.1; P<0.05, corrected P>0.05). No DNA fragments specific for DRB1 ^* 0301 (DR3) could be identified. The frequencies in PBC of other genetic markers including DRw8, DRB1 ^* 08, HLA-DP antigens, DPA, and DPB genes did not differ significantly from those in controls. The associations between PBC and B8, DR3, DQA1 ^* 0501, and DQB ^* 0201, which are frequently found together on the same haplotype, are at variance with recent reports on associations between PBC and Drw8. The discrepancy suggests that PBC is genetically heterogenous.     

Serological recognition of HLA-DR allodeterminant corresponding to DNA sequence involved in gene conversion

HLA class 11 molecules were isolated from mouse L cells transfected with a DR gene and an allele, 52a, of locus DR III from an HLA-homozygous cell line, AVL, of the DR3 haplotype. The isolated molecules were found to possess a new allospecificity, named TR81. This specificity behaved allelic to the previously described DR III locus. The TR81 specificity was also present on the DR I gene product of the DR3 haplotype. The nucleotide sequence of the gene encoding TR81 differs from TR81-negative DR genes of the DRw52 family in only two codons, both located in the regions known to be involved in a gene conversion event. Consequently, the following conclusions can be formulated. (a) TR81 is a bi-locus specificity and allelic to TR22 only in its DR III locus localization. (b) The TR81 specificity is the phenotypic counterpart of the gene conversion event which led to the generation of the DR I gene of the DR3 haplotype. (c) One or both individual amino acid substitutions in the first domain of the DR chain are responsible for the TR81 allospecificity. (d) Since TR81 is expressed on the DR I chain of the DR3 haplotype, it is possible that TR81 and DR3 represent the same serological specificity.     

Transcription and diversity of immunoglobulin lambda chain variable genes in the rat

The DRB region of the human major histocompatibility complex displays length polymorphism: Five major haplotypes differing in the number and type of genes they contain have been identified, each at appreciable frequency. In an attempt to determine whether this haplotype polymorphism, like the allelic polymorphism, predates the divergence of humansfrom great apes, we have worked out the organization of the DRB region of the chimpanzee Hugo using a combination of chromosome walking, pulsed-field gel electrophoresis, and sequencing. Hugo is a DRB homozygote whose single DRB haplotype is some 440 kilobases (kb) long and contains five genes. At least one and possibly two of these are pseudogenes, while three are presumably active genes. The genes are designated DRB ^* A0201, DRB2 ^* 0101, DRB3 ^* 0201, DRB6 ^* 0105, and DRB5 ^* 0301, and are arranged in this order on the chromosome. The DRB2 and DRB3 genes are separated by approximately 250 kb of sequence that does not seem to contain any additional DRB genes. The DRB ^* A0201 gene is related to the DRB1 gene of the human DR2 haplotype; the DRB2 ^* 0101 and DRB3 ^* 0201 genes are related to the DRB2 and DRB3 genes of the human DR3 haplotype, respectively; the DRB6 ^* 0105 and DRB5 ^* 0301 genes are related to the DRBVI and DRB5 genes of the human DR2 haplotype, respectively. Thus the Hugo haplotype appears to correspond to the entire human DR2 haplotype, into which a region representing a portion of the human DR3 haplotype has been inserted. Since other chimpanzees have their DRB regions organized in different ways, we conclude that, first, the chimpanzee DRB region, like the human DRB region, displays length polymorphism; second, some chimpanzee DRB haplotypes are longer than the longest known human DRB haplotypes; third, in some chimpanzee haplotypes at least, the DRB genes occur in combinations different from those of the human haplotypes; fourth, and most importantly, certain DRB gene combinations have been conserved in the evolution of chimpanzees and humans from their common ancestors. These data thus provide evidence that not only allelic but also haplotype polymorphism can be passed on from one species to another in a given evolutionary lineage.     

DNA typing of HLA-DR antigens in systemic lupus erythematosus

HLA-DR typing is technically difficult in systemic lupus erythematosus (SLE), where patients have low numbers of peripheral B cells, often of poor viability and weak in antigenic expression. In this series, one third of SLE patients could not be HLA-DR typed by serological techniques, highlighting the potential for systematic bias in DR antigen assignment in studies of HLA and SLE. This potential bias was examined by comparing serological DR results with DNA-DR typing, achieved by examining Taq I fragments of DR, DQ, and DQ which permitted unequivocal DR phenotyping of all patients, including the 35% for whom conventional DR typing was technically impossible. This showed the success of serological DR antigen assignment was indeed nonrandom, with HLA-DR2 and -DR3 significantly more readily identifiable than DR5 and DRw13. Our study suggests that technical problems may well have contributed to conflicting reports regarding the association of DR2 or DR3 with SLE. Here, DNA-DR phenotyping showed HLA-DR3 is significantly (P<.05) associated with an increased risk for SLE (54% in 46 patients, 36% in 134 controls) and HLA-DR2 is not.     

MHC class II sequences of an HLA-DR2 narcoleptic

Narcolepsy has a 98% association with the DR2-Dw2/DQw1 haplotype. To establish if a disease-specific allele is present in narcolepsy, a cDNA library was made from a B-cell line from a DR2,4/DQw1,3 narcoleptic. Clones encoding the two expressed DR2 chains, along with DQw1 and chains, were isolated and completely sequenced. The coding regions of these four genes were similar to published nucleotide and protein sequences from corresponding healthy controls, with some minor exceptions. The 3 untranslated region of one of the DR2 genes in the narcoleptic was extended by 42 bp. Complete sequences were not available for DQw1.2 or from healthy individuals, but first domain nucleotide sequences showed only a single nonproductive difference in DQ. Partial protein sequences of both DQ and from published data were identical. Although the effects of minor differences cannot be ruled out completely, it is concluded that there are probably no narcolepsy-specific DR or DQ / sequences, and that the alleles found in narcolepsy are representative of those found in the healthy population.     

Immunochemistry of the HLA class II molecules isolated from a mouse cell transfected with DQ alpha and beta genes from a DR4 haplotype

Cells from a mouse B lymphoma were transfected by DQ alpha and DQ beta genes derived from a DR4 haplotype. Quantitatively, the resulting expression of human class II molecules was similar to that of human B lymphoblastoid cell lines. Qualitatively, the transformant class II molecules differed from normal class II molecules in their carbohydrate moiety. As for their antigenic specificity, they were shown to carry two determinants previously identified on DQ molecules controlled by DR4 haplotypes, i. e., DQw3 and DCHON. The transformant molecules did not carry a third DR4-associated specificity, DC5 (equivalent to TA10), and must possess a structure allelic to DC5. However, no corresponding alloantigenic specificity was detected by a screening of relevant alloantisera.     

Order of class III genes relative to HLA genes determined by the haplotype method

The B18 C4A3 C4BQ0 BfF1 DR3 haplotype was found to be ideal for determining the order of C4 and Bf relative to HLA-B and DR by the haplotype method. All the copies of this haplotype are assumed to be derived from a single ancestral haplotype. Sixteen of the twenty-six BfFl-containing haplotypes carried all of the alleles from this ancestral haplotype. Most of the other BfFl-containing haplotypes could be derived from the ancestral haplotype by a single crossover event for one of the two possible gene orders. This suggests that B18 C4A3 C4BQ0 BfFl DR3 is the sole source of the BfFl allele. The uncommon C4 type on B18 C4A3 C4BQ0 BfFl DR3 facilitates recognition of the BfFl-containing products of recombination between Bf and C4. One such recombinant haplotype was found which shows that the orientation of the class III genes is as follows: C4 is closest to HLA-B and Bf is closest to HLA-DR. This gene order is supported by all the earlier unequivocal results obtained using the haplotype method (Olaisen et al. 1983, Marshall et al. 1984a). Combining these results with the information on class III genes obtained from overlapping cosmid clones (Carroll et al. 1984) and earlier mapping studies (Robson and Lamm 1984) shows that HLA-B is telomeric to 21B. C4B, 21A, C4A, Bf and C2 then follow 21B in that order covering 120 kb. HLA-DR is located further toward the centromere.     

A distinct HLA-DRw8 haplotype characterizes patients with juvenile rheumatoid arthritis

We studied the first domain of the HLA-DRB1, HLA-DQA1, and HLA-DQB1 loci of 67 HLA-DRw8-positive Caucasians including 43 with early-onset pauciarticular juvenile rheumatoid arthritis (EOPA-JRA, alternatively known as early-onset pauciarticular juvenile chronic arthritis). Serology, restriction fragment length polymorphism (RFLP), and polymerase chain reaction (PCR) oligotyping revealed that 62, including all the EOPA-JRA patients, carried the HLA-DRB1*0801, DQA1*0401, DQB1*0402 genotype. Approximately onefifth of the controls carried atypical HLA-DRB1, HLA-DQA1, and/or HLA-DQB1 loci on their HLA-DRw8 haplotype confirmed by family studies. DNA sequences of HLA-DRB1, DQA1, and DQB1 alleles in patients and controls were identical to those previously reported. Disease association studies in 113 EOPA-JRA patients and 207 controls unselected for HLA-DRw8 revealed that the HLA-DRB1*0801, DQA1*0401, DQB1*0402 genotype was associated with a higher relative risk (RR) for disease (RR = 12.8, ² = 48.8, P < 10^–4) than was the serologically defined presence of HLA-DRw8 (RR = 8, ² = 39, P < 10^–4). Further analysis suggested that the DQ genes on HLA-DRw8 haplotypes are as likely as the DR genes to contribute to the pathogenesis of EOPA-JRA. This study increases to five the number of HLA-DR/DQ haplotypes identified in HLA-DRw8 Caucasians.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession number M34308.     

Analysis of rho mutability in Saccharomyces cerevisiae

Summary Two additional types of nuclear determinants involved in the control of spontaneous mutability of rho in S. cerevisiae have been identified: mmc and the pet-ts 1, 2, 10, 52 and 53 genes.These genes in their mutated recessive form increase at various extents the number of respiratory deficient cytoplasmic petite mutants accumulated.The gene mmc does not affect the respiratory activity and is not temperature-dependent whereas the pet-ts genes determine at the non permissive temperature a respiratory deficient phenotypes even if they affect the mutability of rho at the permissve and at the non permissive temperature.The data here reported suggest that a replicative complex exists for the mitochondrial DNA.It is in the purpose of this paper to deal with the relative contrition that mmc and pet-ts gene products have in ensuring the fidelity of this replicative complex.     

Chromosomal locations of the gene coding for the CD3 (T3) γ subunit of the human and mouse CD3/T-cell antigen receptor complexes

The gene coding for the M _r 26000 chain of the human CD3 (T3) antigen/T-cell antigen receptor complex was mapped to chromosome band 11q23 by using a cDNA clone (pJ6T3 -2), by in situ hybridization to metaphase chromosomes and by Southern blot analysis of a panel of human-rodent somatic cell hybrids. The mouse homolog, here termed Cdg-3, was mapped to chromosome 9 using the mouse cDNA clone pB10.AT3 -1 and a panel of mouse-hamster somatic cell hybrids. Similar locations for the CD3 genes have been described previously. Thus, the corporate results indicate that the CD3 and genes have remained together since they duplicated about 200 million years ago.