Preferential use of the VH4 Ig gene family by diffuse large-cell lymphoma

Ig heavy chain variable region (VH) genes expressed by human diffuse large-cell lymphoma (DLC) and follicular lymphoma (FL) were identified and analyzed with respect to germline gene families. In 67 cases of FL, VH region genes were expressed in a pattern similar to that of normal B cells, with a predominance of the large VH3 gene family being used. In contrast, of the 17 cases of DLC, there was an extremely biased use of VH genes. Of these DLC tumors, 88% expressed genes from the small VH4 gene family; and even among these tumors, there was a limited use of genes, with 11 cases producing Igs derived from the VH4.21 germline gene. Although most of the VH genes expressed by DLC tumor cells contained mutations with respect to their germline counterparts, almost all of these mutations occurred before the clonal expansion of the tumor. This contrasts with our previous findings of ongoing mutations in FL and represents a fundamental difference between these two malignancies. This preferential gene use implies an important role for the VH4 gene family, and specifically for VH4.21, in the genesis of DLC.     

Virtually identical enhancers containing a segment of homology to murine 3'IgH-E(hs1,2) lie downstream of human Ig C alpha 1 and C alpha 2 genes

We have isolated sequences downstream of human Ig C alpha 1 and C alpha 2 genes and have identified two enhancers in these regions. One enhancer is located approximately 9 kb downstream of C alpha 1, and the second enhancer is located approximately 11 kb downstream of C alpha 2. These approximately 1.6-kb enhancers are virtually identical to each other except for varying numbers of a approximately 53-bp motif. The C alpha 2-associated enhancer contains four copies of this motif in tandem, whereas the C alpha 1-associated enhancer has only a single copy. Within the human enhancers is a 177-bp segment that is homologous to a 191-bp segment of one of four enhancers from the 3' regulatory region of murine (and rat) DNA, namely 3'IgH-E(hs1,2). Like the murine and rat enhancers, both human enhancers are flanked by inverted repeats; furthermore, the human enhancers generally appear to be inverted with respect to each other. The evolutionarily conserved region of homology has substantial core enhancer activity. Contained within this region are the single octamer and one copy of the approximately 53-bp motif, both of which contribute to the activity of the full-length enhancer. A comparison of the DNA sequences and the results of transient transfection assays imply that the human C alpha-associated enhancers may be regulated (in part) differently than the murine enhancer 3'IgH-E(hs1,2).     

Identification of a homolog of the C alpha 3'/hs3 enhancer and of an allelic variant of the 3'IgH/hs1,2 enhancer downstream of the human immunoglobulin alpha 1 gene

Although four regulatory elements are known downstream of the mouse IgH alpha gene, a single enhancer homologous to hs1,2 has been thus far described downstream of each human alpha gene (Chen, C. and Birshtein, B. K., J. Immunol. 1997. 159: 1310). We characterized a 10-kb region downstream of the human alpha 1 gene. Two B cell-specific regulatory elements homologous to the murine C alpha 3'/hs3 and hs1,2,3' enhancers were found, which are duplicated downstream of alpha 2. The hs1,2 element is in inverted orientation by comparison with a recently reported alpha 1 hs1,2 element: it appears as a common allelic variant carrying an internal tandem repeat insertion and its prevalence in the human population is 60%. As in the mouse, the human hs1,2 enhancer is flanked with long inverted repeats which may have promoted inversion events through homologous recombination. Although the palindromic organization of the region is maintained in human, sequence identity with rodents focuses on core enhancer elements rather than on flanking repeats. Concerted divergence of both sides of the dyad symmetry suggests that inverted repeats are not just evolutionary remnants but rather play an architectural role in the LCR function.     

Evidence that multiple myeloma Ig heavy chain VDJ genes contain somatic mutations but show no intraclonal variation

To investigate whether somatic hypermutation occurs in multiple myeloma (MM) Ig VH region genes, we have cloned and sequenced the expressed VH genes from five cases of MM. The sequences were obtained after polymerase chain reaction (PCR) on total RNA isolated from the bone marrow, using 5' VH family-specific leader and 3' C gamma- or C alpha-specific primers. MM-specific CDR3 oligonucleotides were produced to isolate VH genes expressed by the malignant plasma cells. In all five cases, the productive Ig gene used the VH3 family. Extensive sequence analysis of multiple independent M13 clones showed no intraclonal variation with no evidence for ongoing somatic hypermutation in MM VH region genes. We were able to identify possible germline counterparts of the expressed VH genes in two cases. Comparison of these genes shows that the MM VH region genes have somatic mutations characteristic for an antigen-driven process. In the other three cases, no close homology could be found with published VH3 sequences. These findings implicate that, in MM, clonal proliferation takes place in a cell type that has already passed through the phase of somatic hypermutation.     

Analysis of mice containing a targeted deletion of beta-globin locus control region 5' hypersensitive site 3

To examine the function of murine beta-globin locus region (LCR) 5' hypersensitive site 3 (HS3) in its native chromosomal context, we deleted this site from the mouse germ line by using homologous recombination techniques. Previous experiments with human 5' HS3 in transgenic models suggested that this site independently contains at least 50% of total LCR activity and that it interacts preferentially with the human gamma-globin genes in embryonic erythroid cells. However, in this study, we demonstrate that deletion of murine 5' HS3 reduces expression of the linked embryonic epsilon y- and beta H 1-globin genes only minimally in yolk sac-derived erythroid cells and reduces output of the linked adult beta (beta major plus beta minor) globin genes by approximately 30% in adult erythrocytes. When the selectable marker PGK-neo cassette was left within the HS3 region of the LCR, a much more severe phenotype was observed at all developmental stages, suggesting that PGK-neo interferes with LCR activity when it is retained within the LCR. Collectively, these results suggest that murine 5' HS3 is not required for globin gene switching; importantly, however, it is required for approximately 30% of the total LCR activity associated with adult beta-globin gene expression in adult erythrocytes.     

Two cases of bilateral congenital cholesteatoma--usual and unusual presentations

We generated mice harboring germline mutations in which the enhancer element located 9 kb 3' of the immunoglobulin kappa light chain gene (3'E kappa) was replaced either by a single loxP site (3'E kappa delta) or by a neomycin resistance gene (3'E kappa N). Mice homozygous for the 3'E(kappa delta) mutation had substantially reduced numbers of kappa-expressing B cells and increased numbers of lambda-expressing B cells accompanied by decreased kappa versus lambda gene rearrangement. In these mutant mice, kappa expression was reduced in resting B cells, but was normal in activated B cells. The homozygous 3'E(kappa)N mutation resulted in a similar but more pronounced phenotype. Both mutations acted in cis. These studies show that the 3'E(kappa) is critical for establishing the normal kappa/lambda ratio, but is not absolutely essential for kappa gene rearrangement or, surprisingly, for normal kappa expression in activated B cells. These studies also imply the existence of additional regulatory elements that have overlapping function with the 3'E(kappa) element.     

Immunoglobulin VH gene mutational analysis suggests that primary effusion lymphomas derive from different stages of B cell maturation

Primary effusion lymphoma (PEL) is a recently described distinct subtype of non-Hodgkin's lymphoma associated with infection by the Kaposi's sarcoma-associated herpesvirus, also called human herpesvirus-8. Most cases of PEL are also associated with the Epstein-Barr virus (EBV). In order to better characterize the cellular origin of PEL, we investigated the immunoglobulin (Ig) heavy chain variable region (VH,) genes expressed by tumor cells of the BC-1 and BC-3 cell lines derived from PELs and five original PEL specimens. In the six EBV-positive PELs examined, including the BC-1 cell line, the expressed VH gene sequences showed numerous point mutations relative to the putative germline VH gene sequences. In addition, the VH, segment of one of these cases showed intraclonal sequence heterogeneity, indicating ongoing somatic mutation. In five cases, the distribution and type of mutations indicated that tumor cells had been selected by antigen. Because somatically mutated Ig genes are expressed by B cells that have reached a germinal center/post-germinal center stage of development, these findings suggest that the PEL cell of origin is a germinal center or post-germinal center B cell in most cases. In contrast, the VH gene segment expressed by tumor cells of the BC-3 cell line, which was originated from an EBV-negative PEL obtained from an HIV-negative patient, was unmutated, suggesting a pre-germinal center B cell origin for tumor cells of this particular PEL cell line. Taken together, these findings suggest that development of PELs may not be restricted to one stage of B cell differentiation and may represent transformation of B cells at different stages of ontogeny.     

Development of pathogenic anti-DNA antibodies in patients with systemic lupus erythematosus

The anti-DNA response is a hallmark of systemic lupus erythematosus (SLE). The precise mechanisms leading to anti-DNA antibody (Ab) production remain to be studied. Nonetheless, it is becoming clear that anti-DNA Abs cause inflammatory lesions not only via deposition of circulating immune complexes (IC) consisting of anti-DNA Ab and antigens (Ags), but also via in situ IC formation by cationic anti-DNA Abs. It is intriguing that cationic anti-DNA Abs are encoded by a unique germline Vkappa gene, A30, which encodes an extraordinary cationic light chain, whereas somatic mutations did not induce a cationic shift of electrical charge in human lupus nephritis, suggesting that the usage of a specific germline gene may confer the cationic charge (or pathogenicity) on anti-DNA Abs and that somatic mutations induce the affinity maturation of Abs. Whether cationic anti-DNA Abs will develop depends at least partly on the presence or absence of the germline A30 gene, since patients who lack this gene in the germline Vkappa repertoire did not develop severe lupus nephritis. Receptor editing, a mechanism for changing the affinity of the B cell Ag receptor [surface immunoglobulin (Ig) receptor] to avoid self-reactivity actually seems defective in patients with SLE because normal B cells edited the A30 gene, whereas SLE B cells express A30 mRNA. Thus, along with the importance of somatic mutations, polymorphisms of Ig Vkappa locus, and genetic predisposition, the failure of receptor editing may contribute to the development of pathogenic anti-DNA responses in humans.     

Mutation in the mismatch repair gene Msh6 causes cancer susceptibility

Mice carrying a null mutation in the mismatch repair gene Msh6 were generated by gene targeting. Cells that were homozygous for the mutation did not produce any detectable MSH6 protein, and extracts prepared from these cells were defective for repair of single nucleotide mismatches. Repair of 1, 2, and 4 nucleotide insertion/deletion mismatches was unaffected. Mice that were homozygous for the mutation had a reduced life span. The mice developed a spectrum of tumors, the most predominant of which were gastrointestinal tumors and B- as well as T-cell lymphomas. The tumors did not show any microsatellite instability. We conclude that MSH6 mutations, like those in some other members of the family of mismatch repair genes, lead to cancer susceptibility, and germline mutations in this gene may be associated with a cancer predisposition syndrome that does not show microsatellite instability.     

Evidence for immunoglobulin heavy chain variable region gene replacement in a patient with B cell chronic lymphocytic leukemia

Immunoglobulin heavy chain variable (V) gene replacement is an unusual recombinatorial event characterized by rearrangement of a germline V gene to a preformed VDJ gene complex. This phenomenon has occasionally been implicated in the emergence of clonal subpopulations during the course of acute lymphoblastic leukemia; it has also been found in murine precursor B cell lines. V gene replacement has never been described in lymphoproliferative disorders corresponding to more differentiated stages of B cell ontogeny. The present communication provides evidence for the operation of the same mechanism in B cell chronic lymphocytic leukemia (B-CLL). Genomic DNA and total cellular RNA extracted from peripheral blood mononuclear cells of a 48-year-old female patient diagnosed as having typical B-CLL were subjected to polymerase chain reaction (PCR) amplification aiming to detect rearranged clonal heavy and light chain variable genes (VH and VL, respectively). PCR consistently gave two VH amplification products, both at the DNA and the RNA level; similar analysis for the VL region revealed the presence of a single rearranged VK gene. Direct sequence analysis of the PCR products revealed that, except for a number of silent mutations, the single rearranged VK gene was identical to the germline A1-A17 VK gene. The two rearranged VH gene segments belong to the VHl and VHIII gene families and are closely homologous, respectively, to the germline gene segments V1-18 and V3-30, which have been shown to be used by autoantibodies. Both rearranged VH genes showed identical in-frame D-N-JH junctions and JH gene usage (JH5b), whereas the VH-N-D junctions were different. The above findings indicate that, during the course of the disease of our patient, VH gene replacement took place giving rise to two different clonally related subpopulations. This raises the intriguing possibility that the recombinase machinery, which governs Ig recombinatorial processes, might be operative even at more advanced stages in B cell ontogeny.     

A 20.7 kb deletion within the factor VIII gene associated with LINE-1 element insertion

Large deletions within the factor VIII gene account for approximately 5% of the mutations causing haemophilia A. The characterization of such mutations can provide insights into the molecular mechanisms of these and other deletions in man. We have analyzed a 20.7 kb deletion spanning exons 15 to 20 within the factor VIII gene in a patient with severe haemophilia A. Long range PCR was used to investigate the extent of the deletion and to provide a template for sequencing across the deletion breakpoint. A 38-base insertion homologous to the 3' region of a LINE-1 (L1) element was detected at the breakpoint of the deletion. Normal sequence at the 5' breakpoint in intron 14 was homologous to an L1 flanking region and normal sequence at the 3' breakpoint in intron 20 was homologous to an adjacent sequence within the same L1 flanking region. A molecular mechanism for the deletion involving retrotransposition of a readthrough product of an L1 element plus its 3' flanking region is suggested.