Analysis of microsatellite instability and hypermutation of immunoglobulin variable genes in Werner syndrome.

Werner syndrome (WS) is a human premature aging syndrome, which is associated with high frequencies of neoplasia and genetic instability. We have examined the occurrence of microsatellite instability, which may result from defective mismatch repair, in lymphoblastoid cell lines derived from nine WS patients. Instability was measured at the D2S123 locus by gel analysis of PCR products. Three WS cell lines had 4-13% altered alleles, compared with 0% in the other six lines. The increased frequency of microsatellite instability could not readily be associated with overt cancer or any other known clinical condition in the three patients. To examine whether the WS defect affected the humoral immune system, we measured the hypermutation of immunoglobulin variable genes in peripheral blood cells from the WS patient who donated the cell line with the highest frequency of microsatellite instability. The frequency and pattern of mutation was similar to that from normal individuals, suggesting that the Werner protein is not involved in generating hypermutation.

Impact of age on hypermutation of immunoglobulin variable genes in humans.

Chronological aging is associated with an accumulation of DNA mutations that results in cancer formation. The effect of aging on spontaneous mutations in humans is difficult to study because mutations are infrequent in the overall genome and tumors are relatively rare. In contrast, somatic mutations in immunoglobulin variable genes are abundant and can be studied in peripheral blood lymphocytes. To determine if aging alters the frequency and pattern of hypermutation, we sequenced 331 cDNA clones with rearranged V(H)6 genes and compared 452 mutations from young humans to 570 mutations from old humans. There were more mutated clones in the young population compared to the old population. Among the mutated clones, the frequency, location, and types of substitutions were similar between the young and the old groups. However, the ratio of replacement-to-silent mutations was much higher in the complementarity-determining regions of heavy chains from old people, which indicates that their B cells had been selected by antigen. Among individuals, there was variability in the frequency of tandem mutations, which we have observed in mice defective for the PMS2 mismatch repair protein. Microsatellite variability in DNA, which is caused by impaired mismatch repair, was then measured, and there was a strong correlation between the frequency of tandem mutations and microsatellite alterations. The data suggest that individuals vary in their mismatch repair capacity, which can affect the mutational spectra in their antibodies.

DNA polymerase eta is an A-T mutator in somatic hypermutation of immunoglobulin variable genes.

To determine whether DNA polymerase eta plays a role in the hypermutation of immunoglobulin variable genes, we examined the frequency and pattern of substitutions in variable VH6 genes from the peripheral blood lymphocytes of three patients with xeroderma pigmentosum variant disease, whose polymerase eta had genetic defects. The frequency of mutation was normal but the types of base changes were different: there was a decrease in mutations at A and T and a concomitant rise in mutations at G and C. We propose that more than one polymerase contributes to hypermutation and that if one is absent, others compensate. The data indicate that polymerase eta is involved in generating errors that occur predominantly at A and T and that another polymerase(s) may preferentially generate errors opposite G and C.

Altered spectra of hypermutation in DNA repair-deficient mice.

Affinity maturation of the humoral immune response is based on the ability of immunoglobulin variable genes to undergo a process of rapid and extensive somatic mutation followed by antigenic selection for antibodies with higher affinity. While the behaviour of this somatic hypermutation phenomenon has been well characterized over the last 20 years, the molecular mechanism responsible for inserting mutations has remained shrouded. To better understand this mechanism, we studied the interplay between hypermutation and other DNA associated activities such as DNA repair. There was no effect on the frequency and pattern of hypermutation in mice deficient for nucleotide excision repair, base excision repair and ataxia-telangiectasia mutated gene repair of double strand breaks. However, variable genes from mice lacking some components of mismatch repair had an increased frequency of tandem mutations and had more mutations of G and C nucleotides. These results suggest that the DNA polymerase(s) involved in the hypermutation pathway produces a unique spectra of mutations, which is then altered by mismatch repair and antigenic selection. We, also describe the differential pattern of expression of some nuclear DNA polymerases in hypermutating versus non-hypermutating B lymphocytes. The rapidly dividing germinal centre B cells expressed DNA polymerases alpha, beta, delta, epsilon and zeta, whereas the resting non-germinal centre cells did not express polymerases alpha or epsilon at detectable levels, although they did express polymerases beta, delta and zeta. The lack of expression of polymerase epsilon in the non-germinal centre cells suggests that this enzyme has a critical role in chromosomal replication but does not participate in DNA repair in these cells.

Differential expression of DNA polymerase epsilon in resting and activated B lymphocytes is consistent with an in vivo role in replication and not repair.

DNA polymerases may be differentially expressed by cells during periods of quiescence and proliferation. Murine B cells are an ideal population to study because their division time varies widely in vivo, and different subsets can be easily isolated. Consequently, we analyzed RNA from resting cells (B220(+)peanut agglutinin(-)) and activated germinal center cells (B220(+)peanut agglutinin(+)) from spleens by reverse transcriptase-PCR using primers for five nuclear polymerases and their associated subunits. Gel analyses of the amplified products showed that the rapidly-dividing germinal center B cells expressed DNA polymerases alpha, beta, delta, epsilon, and zeta. The resting B cells did not express polymerases alpha or epsilon at detectable levels, although they did express polymerases beta, delta, and zeta. Thus, polymerase epsilon, as well as alpha, appears to have a primary role in chromosomal replication of murine B lymphocytes. Further, the lack of expression of polymerase epsilon in resting cells indicates that this enzyme is not used in any DNA repair pathways by these cells. The expression of polymerase zeta by resting cells suggests that it has another role in DNA repair, perhaps recombination, in addition to its function of bypassing damage during chromosomal replication.

Esophagogastric adenocarcinoma in an E1A/E1B transgenic model involves p53 disruption.

We studied tumorigenesis and p53 immunostaining in a murine transgenic model introducing E1A/E1B under the control of the mouse mammary tumor virus-long terminal repeat (MMTV-LTR) promoter in which adenocarcinoma occurs at the squamocolumnar junction in the foregut, predominantly in males, and at no other site. Mutations of p53 are frequent in human esophageal adenocarcinoma and the E1B gene product interferes with p53-mediated apoptosis, inhibiting tumor suppression at the G(1)/S checkpoint. Transgenic animals were generated utilizing a purified linear 6.7 kb fragment of plasmid DNA containing MMTV-LTR/E1A/E1B and were confirmed by dot blot hybridization of tail DNA to (32)P-labeled E1A/E1B probe and polymerase chain reaction (PCR) amplification of E1A. Transgenic and control animals were observed for morbidity and weight changes. Eleven of 45 animals were transgenic (24% efficiency) with an estimated 5 to 57 copies of the gene per genome. Profound weight loss (>20%) led to sacrifice or death of one of five females (at 12 weeks) and four of six males (at 16 to 17 weeks). Grossly visible tumors (2 to 10 mm) were noted in the forestomach at the visible margin between the proximal (squamous-lined) stomach and the distal glandular stomach. Histologic sections confirmed adenocarcinoma arising in each case at the squamocolumnar junction with glandular formation, pleomorphism, and frequent mitotic figures. Immunostaining was positive for p53 indicating accumulation of mutated or altered p53 protein. E1A/E1B transgenic animals developed macroscopic and microscopic adenocarcinoma at the squamocolumnar junction, which corresponds to adenocarcinoma at the human esophagogastric junction. Disruption of p53 was present in the transgenic model as in the human cancer.

Hypermutation in Ig V genes from mice deficient in the MLH1 mismatch repair protein.

During somatic hypermutation of Ig V genes, mismatched nucleotide substitutions become candidates for removal by the DNA mismatch repair pathway. Previous studies have shown that V genes from mice deficient for the MSH2 and PMS2 mismatch repair proteins have frequencies of mutation that are comparable with those from wild-type (wt) mice; however, the pattern of mutation is altered. Because the absence of MSH2 and PMS2 produced different mutational spectra, we examined the role of another protein involved in mismatch repair, MLH1, on the frequency and pattern of hypermutation. MLH1-deficient mice were immunized with oxazolone Ag, and splenic B cells were analyzed for mutations in their V kappa Ox1 light chain genes. Although the frequency of mutation in MLH1-deficient mice was twofold lower than in wt mice, the pattern of mutation in Mlh1-/- clones was similar to wt clones. These findings suggest that the MLH1 protein has no direct effect on the mutational spectrum.

Characterization of an aFGF gene expression vector with therapeutic potential.

BACKGROUND: Topical application of growth factors to wounds has proven to be suboptimal in achieving epithelial growth and accelerating healing. We propose transfection of fibroblasts with a gene for acidic fibroblast growth factor (aFGF) which will allow continuous, local delivery of the growth factor to wounds, ulcerative lesions, or healing tissues. METHODS: We utilized a pMEXneo vector containing the human aFGF gene with a secretory signal sequence from the hst/KS3 gene to obtain continuous secretion of therapeutic doses of aFGF. NIH 3T3 fibroblasts were transfected using a liposomal transfection reagent and grown in selective media. RESULTS: Dot blot hybridization with labeled complementary DNA probes revealed the presence of plasmid DNA in transfected but not wild type fibroblasts. Intracellular concentrations of aFGF remained low in transfected cells; however, the media contained high levels (32 +/- 7 nM) of aFGF as measured by ELISA. Concentrations of aFGF capable of stimulating cell proliferation were maintained for several weeks. CONCLUSIONS: The aFGF cDNA was transcribed and translated into a functional polypeptide that is secreted from NIH 3T3 cells at physiologically significant concentrations. Stable transfection with a eukaryotic vector which induces secretion of aFGF at levels promoting cell growth holds promise for clinical application in wounds or healing tissue. Transfection could be achieved by topical or endoscopic injection of this type of vector.

Increased hypermutation at G and C nucleotides in immunoglobulin variable genes from mice deficient in the MSH2 mismatch repair protein.

Rearranged immunoglobulin variable genes are extensively mutated after stimulation of B lymphocytes by antigen. Mutations are likely generated by an error-prone DNA polymerase, and the mismatch repair pathway may process the mispairs. To examine the role of the MSH2 mismatch repair protein in hypermutation, Msh2-/- mice were immunized with oxazolone, and B cells were analyzed for mutation in their VkappaOx1 light chain genes. The frequency of mutation in the repair-deficient mice was similar to that in Msh2+/+ mice, showing that MSH2-dependent mismatch repair does not cause hypermutation. However, there was a striking bias for mutations to occur at germline G and C nucleotides. The results suggest that the hypermutation pathway frequently mutates G.C pairs, and a MSH2-dependent pathway preferentially corrects mismatches at G and C.

Altered spectra of hypermutation in antibodies from mice deficient for the DNA mismatch repair protein PMS2.

Mutations are introduced into rearranged Ig variable genes at a frequency of 10(-2) mutations per base pair by an unknown mechanism. Assuming that DNA repair pathways generate or remove mutations, the frequency and pattern of mutation will be different in variable genes from mice defective in repair. Therefore, hypermutation was studied in mice deficient for either the DNA nucleotide excision repair gene Xpa or the mismatch repair gene Pms2. High levels of mutation were found in variable genes from XPA-deficient and PMS2-deficient mice, indicating that neither nucleotide excision repair nor mismatch repair pathways generate hypermutation. However, variable genes from PMS2-deficient mice had significantly more adjacent base substitutions than genes from wild-type or XPA-deficient mice. By using a biochemical assay, we confirmed that tandem mispairs were repaired by wild-type cells but not by Pms2(-/-) human or murine cells. The data indicate that tandem substitutions are produced by the hypermutation mechanism and then processed by a PMS2-dependent pathway.

Early rearrangements of genes encoding murine immunoglobulin kappa chains, unlike genes encoding heavy chains, use variable gene segments dispersed throughout the locus.

Immunoglobulin heavy-chain variable region (TH) gene segments located closest to the joining (JH) gene segments are preferentially rearranged during ontogeny, indicating that chromosomal position influences the frequency of rearrangement. In addition, certain VH gene segments are repeatedly rearranged, suggesting that the DNA sequence or structure surrounding these segments may increase the probability of rearrangement. To determine whether there is similar based rearrangement of kappa variable (V kappa) gene segments, 25 rearrangements were sequenced from murine fetal and neonatal B-cell hybridomas and from subclones of a pre-B cell line that rearranged V kappa genes during in vitro culture. Four gene segments were isolated twice and one gene segment was isolated three times, suggesting that the process that targets individual variable gene segments for repeated rearrangement operates on both the VH and V kappa loci. Based on a current map of the V kappa locus, the rearranged gene segments belong to nine families that are dispersed throughout the locus. Thus, in these cell types, V kappa rearrangements use germ-line gene segments located across the entire locus, whereas the corresponding VH rearrangements use gene segments proximal to the JH gene segments. Heterogeneity of V kappa rearrangements would add diversity to the biased pool of VH rearrangements, producing a broad repertoire of antibodies early in development.

Clusters of point mutations are found exclusively around rearranged antibody variable genes.

We have examined the nucleotide sequences of a series of murine antibody genes derived from one kappa light chain gene in order to gain insight into the mechanism that specifically mutates variable genes. Six rearranged VK167 genes from hybridoma and myeloma cells were cloned from bacteriophage lambda libraries. The sequences were compared to the germ-line sequence of the VK167 gene, the JK genes, and the CK gene to identify sites of mutation. Four of six rearranged genes had extensive mutation which occurred exclusively in a 1-kilobase region of DNA centered around the V-J gene. No mutations were found at more distant sites in the intervening sequence or in the constant gene. The frequency of mutation was approximately 0.5% (32 mutations per 6,749 base pairs). Mutations were mostly due to nucleotide substitutions with no preference for transitions or transversions. The location of mutations around each gene indicates that they occur in clusters at random sites. The observation of mutations in the intervening sequence downstream from the JK5 gene rules out models for the mechanism of mutagenesis that rely solely on gene conversion or recombination. The distribution and high frequency of mutations are most easily explained by a mechanism of error-prone repair that occurs during several cycles of cell division.

Balb/c T cells have the potential to recognize the TEPC 15 prototype antibody and its somatic variants.

Immunization of BALB/c mice with phosphorylcholine-Limulus polyphemus hemocyanin (PC-Hy) induces a population of T cells that recognize the predominant PC-binding antibody, TEPC15 (T15). The splenic fragment culture system was used to examine the specificity of these T cells for a series of PC-binding myeloma and hybridoma antibodies representing the prototype variable region of the heavy chain (VH)T 15 sequence as well as somatic variants of the T15 germ line-encoded sequence. Included in this group of PC-binding proteins were both T15-positive and T15-negative antibodies, as defined by anti-idiotypic antibody. T cell help was identified by the ability to promote TNP-specific B cell responses to trinitrophenylated PC-binding proteins. It was found that T cells generated by immunization with PC-Hy recognize both antibodies with the T15 prototype sequence and the putative somatic variants of this sequence. A population of these T cells appear to recognize common determinants shared by these proteins because immunization with T15 itself also induces the recognition of the somatic variants. This suggests that idiotopes encoded in the T15 germ line gene expressed by the T15 prototype idiotype and the somatic variants can function as targets for T cell recognition and are thus regulatory idiotopes.

IgG antibodies to phosphorylcholine exhibit more diversity than their IgM counterparts.

An amino acid sequence analysis of the N-terminal immunoglobulin heavy and light chain variable regions (VH and VL) from 16 hybridoma proteins which bind phosphorylcholine as well as the complete sequence analysis of 9 of these VH regions is presented. There seem to be more VH regions participating in the phosphorylcholine response than can be encoded directly by germ-line VH gene segments. Moreover, the V regions from IgG antibodies are considerably more variable than those from their IgM counterparts. These observations raise the possibility that a somatic mechanism for V region diversification produces greater diversity in IgG than in IgM antibodies.

Idiotype-specific neonatal suppression of phosphorylcholine-responsive B cells.

The effect on neonatal anti-idiotypic suppression on the expression of B cells of the T15 clonotype has been investigated at the level of individual clonal precursor cells. The results indicate that B cells of the T15 clonotype are almost completely eliminated from the repertoire for four months after neonatal injection of allogeneic anti-idiotypic serum. The degree of this suppression is dependent on the amount of anti-idiotypic antibody administered and is less profound if anti-idiotypic antibody is given after the first week of life. No suppression was observed when anti-idiotypic antisera were administered to mice 30 days of age or older, which may indicate that immature B cells are the population most susceptible to suppression. However, since suppression could be reversed by administration of T15 myeloma protein several days after injection of anti-idiotype, the inability to suppress adult BALB/c mice may have been due to the high level of T15 idiotype normally present in their serum. Finally, phosphorylcholine-responsive B cells of identifiable clonotypes other than T15, even a clonotype sharing antigen-combining site determinants with T15, appear unaffected by anti-T15 suppression.

Expression of phosphorylcholine-specific B cells during murine development.

The TEPC 15 (T15) clonotype, a putatively germline antibody specificity, does not appear in the neonatal B-cell repertoire until approximately 1 wk of age. This report extends this observation by the demonstration that (a) the T15 clonotype follows similar kinetics of appearance in germfree as well as conventionally-reared mice; (b) maternal influences and genetic background play a minor role in the development of the T15 clonotype since CBFI neonates raised by C57BL/6 or BALB/c mothers acquire the T15 clonotype at the same time in ontogeny as BALB/c neonates; (c) the lack of phosphorylcholine (PC)-specific B cells shortly after birth is reflected in a dearth of PC-binding cells in the neonate as well; and (d) no PC-specifc B cells are found in 19-day fetal liver or in bone marrow until 7 days of life, coincident with their appearance in the spleen. These findings, along with a previous report that PC-specific splenic B cells are tolerizable as late as day 10 after birth, confirm the invariant, late occurrence of the T15 clonotype and support a highly- ordered, rigorously predetermined mechanism for the acquisition of the B- cell repertoire. The results are discussed in light of other studies on the ontogeny of B-cell specificity, and in terms of the implications on the mechanism by which antibody diversity is generated.