By
From the * Basel Institute for Immunology, CH-4005 Basel, Switzerland; the Institute for Genetics,
University of Cologne, 50931 Cologne, Germany; the § Department of Cellular Biology and Genetics,
Erasmus University, 3000 DR Rotterdam, The Netherlands; the
Department of Molecular
Carcinogenesis, The Netherlands Cancer Institute, 1066 CX Amsterdam, The Netherlands; the ¶ Department of Immunology, University Hospital Utrecht, 3508 GA Utrecht, The Netherlands; the ** Ecole Superieure de Biotechnologie de Strasbourg, Université Louis Pasteur, F-67400
Illkirch-Graffenstaden, France; and the
Department of Molecular and Cellular Toxicology,
Harvard School of Public Health, Boston, Massachusetts 02115
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Abstract |
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To investigate the possible involvement of DNA repair in the process of somatic hypermutation of rearranged immunoglobulin variable (V) region genes, we have analyzed the occurrence, frequency, distribution, and pattern of mutations in rearranged V1 light chain genes
from naive and memory B cells in DNA repair-deficient mutant mouse strains. Hypermutation
was found unaffected in mice carrying mutations in either of the following DNA repair genes: xeroderma pigmentosum complementation group (XP)A and XPD, Cockayne syndrome complementation group B (CSB), mutS homologue 2 (MSH2), radiation sensitivity 54 (RAD54),
poly (ADP-ribose) polymerase (PARP), and 3-alkyladenine DNA-glycosylase (AAG). These
results indicate that both subpathways of nucleotide excision repair, global genome repair, and
transcription-coupled repair are not required for somatic hypermutation. This appears also to
be true for mismatch repair, RAD54-dependent double-strand-break repair, and AAG-mediated base excision repair.
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Introduction |
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In humans and mice, the primary Ig repertoire is generated by V(D)J recombination in B cell progenitors of the
embryonic liver and adult bone marrow. Rearranged Ig
genes of antigen-specific B cells can be further diversified
by hypermutation in germinal center B cells, which develop in secondary lymphatic tissues during immune responses (for review see reference 1). The mutations are
mainly point mutations, with rare deletions and insertions (2). The mutation rate has been estimated to be as high as 103 base pairs/generation, which is approximately six orders of magnitude higher than the spontaneous mutation
rate (3).
Notwithstanding the extensive knowledge of the immunobiology (1), the molecular mechanism underlying somatic hypermutation remains speculative (6). Several models have been proposed: (a) "gratuitous" transcription-coupled repair (TCR1; 10, 11), (b) site-specific nicking and repair of DNA via an error prone DNA polymerase (12, 13), (c) gene conversion (14), (d) local DNA hyperreplication (15), (e) cDNA retrotransposition of reverse transcribed Ig mRNA (16), (f) altered DNA replication (17), and (g) inhibition of mismatch repair (8).
Recent advances in cloning, characterizing, and targeting eukaryotic DNA repair genes (18) has provided mouse models that allow us to test present concepts on the mechanism of hypermutation. The molecular mechanism underlying hypermutation is unlikely to be controlled by a single gene product and most likely has evolved from preexisting components involved in DNA modification. We speculate that mutations are introduced by a "site-specific mutator" that depends on other molecules involved in DNA repair and/or DNA synthesis, a scenario that is reminiscent of V(D)J-recombination, which uses the site-specific recombination activating gene (RAG) recombinase as well as components of DNA repair such as DNA-dependent protein kinase and x ray cross-complementing (XRCC)4 (19).
Therefore, seven mouse strains with predefined mutations in either one of the DNA repair genes xeroderma pigmentosum complementation group (XP)A (20), XPD (20a), Cockayne syndrome (CS)B (21), mutS homologue 2 (MSH2; 22), radiation sensitivity 54 (RAD54; 23), poly (ADP-ribose) polymerase (PARP; reference 24), and 3-alkyladenine DNA-glycosylase or 3-methyladenine DNA-glycosylase (AAG; 24a) were tested for the occurrence of somatic mutations in naive and memory B cells. The different repair pathways where XPA, XPD, CSB, MSH2, RAD54, PARP, and AAG are involved are briefly outlined below. For further details the reader is referred to Friedberg et al. (25).
The XPA protein is an essential component of the nucleotide-excision repair (NER) pathway. XPA protein functions in a preincision step of NER, i.e., the recognition of DNA damage and controls both NER pathways, global genome repair (GGR) and TCR. It recruits the basal transcription factor (TF)IIH, which among other downstream components is common to GGR and TCR (26). XP-deficient mice are highly susceptible to UV-B- or chemical-carcinogen-induced skin and eye tumors (20, 27).
XPD and XPB are components of the basal transcription factor TFIIH and both display helicase activity. Specific mutations in the XPD gene and in the XPB gene can cause the multisystemic disorder trichothiodystrophy (TTD) (28). Clinically, the defining feature of TTD is sulfur-deficient brittle hair, which is due to a reduced cysteine content. TTD is also associated with reduced size, mental retardation, unusual facial appearance, and ichthyosis. These and other findings led to the hypothesis that the clinical features underlying TTD relate to defective transcription, i.e., a repair/transcription syndrome concept (29).
Unlike XPD and XPB, the CSB gene is not essential for transcription but appears to play a key role in coupling transcription and NER. CSB is thought to control the functional transition of a RNA-polymerase II complex into a "repairosome" as soon as the polymerase becomes stalled at a DNA lesion. Alternatively, repairosomes might continuously be active in scanning-transcribed DNA for the occurrence of DNA damage. CS is a multisystemic disorder. CS patients are deficient in TCR. TCR is a subpathway of NER that accomplishes the fast and efficient repair of certain types of lesions from the transcribed strand of active genes (30). Mutations in either the CSA or CSB gene give rise to the classical form of CS. Specific mutations in the XPD, XPB, or XPG genes can also cause CS symptoms in combination with XP (28, 29). Consistent with a lack in TCR, CSB mutant mice are UV sensitive, show a selective inactivation of TCR but unaffected GGR, and are unable to resume RNA synthesis after UV exposure (21).
MSH2 is the eukaryotic homologue of the bacterial mutS gene. Like mutS, the MSH2 protein plays a central role in mismatch repair (MMR) and blocks recombination between nonhomologous DNA strands, i.e., antirecombination activity of MMR (22). MSH2 binds together with MSH6 to base mispairs and to extrahelical loops that occur during homologous recombination and replication. In contrast, the MSH3/MSH6 heterodimer (MSH3 is another mutS homologue) recognizes preferentially extrahelical loops (31). Upon recognition of the mismatch, the MSH2-containing heterodimer recruits other components of the mismatch repair system, i.e., the MLH1-PMS2 heterodimer (MLH, mutL homologue; PMS, postmeiotic segregation). This complex triggers the excision of the mismatched nucleotide by removal of a tract of single-stranded DNA that contains the mismatched nucleotide. Resynthesis of the excised DNA strand and ligation of the remaining nick completes the repair process.
RAD54 is a key factor in the RAD52 DNA repair pathway. RAD54, RAD51, and RAD52 belong to the Saccharomyces cerevisiae RAD52 epistasis group (RAD50-RAD57, RAD24, RAD59, meiotic recombination [MRE]11, and x-ray sensitivity [XRS]2). Mutants show a wide range of recombination deficiencies including a defect in double-strand-break repair (DSBR) through homologous recombination. Consistent with a defect in DSBR, RAD54 double-knockout embryonic stem cells display a reduced frequency in homologous recombination and are sensitive to ionizing radiation, mitomycin C, and the alkylating agent methyl methane-sulfonate, but not to UV light (23). RAD51 and its mouse counterpart are functional homologues of the Escherichia coli recombination protein RecA, which forms nucleoprotein filaments with single-stranded DNA and mediates homologous DNA pairing and strand exchange. RAD54 is likely to be involved in this process since it was found to physically interact with RAD51 in S. cerevisiae (34).
PARP, a zinc-finger DNA binding protein, is involved
in single-stranded break detection. In response to these
breaks, the catalytic domain of PARP catalyses the covalent
attachment of poly-ADP ribose to itself and to nuclear proteins. Its catalytic activity requires free DNA ends. Upon
binding, PARP is thought to recruit DNA-repair components. A subsequent automodification of the enzyme negatively interferes with DNA binding. Because of these features,
PARP appears to act as a "nick sensor". This function is
consistent with the increased sensitivity of PARP-deficient mice to -irradiation and MNU treatment (24).
The AAG is like other DNA-glycosylases involved in
the initial step of base-excision repair (BER), the detection
and processing of a modified base (25). Removal of the
damaged base generates an AP (apurinic or apyrimidinic)
site. The AP site is processed by the sequential action of
AP-endonuclease/deoxyribophosphodiesterase or AP-lyase/3'
repair diesterase, leaving a single-stranded gap, which in
mammalian cells is filled by the DNA polymerase (35). Alternatively, proliferating cell nuclear antigen-dependent
longer patch repair synthesis may contribute to the BER
pathway (36). Ligation of the remaining nick is thought to
be performed by DNA ligase II. AAG mutant mice are viable and do not show an overt phenotype.
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Materials and Methods |
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Mice.
The background, genotyping, and characterization of XPA, CSB, MSH2, RAD54, PARP, and AAG (our manuscript submitted) mutant mice have been published elsewhere (20-24a). Since all mice had to be imported from outside laboratories, there was an infection risk for our animal facility at the University of Cologne (Cologne, Germany). Given this problem and the limited space in our quarantine facility, the availability of the mice was limited and they had to be analyzed soon after arrival. Nonimmunized wild-type and CSB, MSH2, XPA, and PARP mutant mice were analyzed at an age of 10-30 wk. RAD54 and AAG mutant mice were immunized with 50 µg NP-CG alumn in 100 µl PBS 10 d before analysis and killed at an age of 10 and 11 wk, respectively. For the analysis of hypermutation in XPDTTDIBEL mutant mice, which carry the same mutation in XPD as the TTDIBEL patient (20a), an immunized mouse (10 wk) and a nonimmunized mouse (11 wk) were used. Data from immunized or nonimmunized mice are presented together, since immunization did not affect the frequency and pattern of VIsolation of Single B220+, Igµ+, Ig +, V
1+ Naive B Cells and
B220+, Igµ
, Ig
, V
1+ Memory B Cells from Spleen.
Amplification of Rearranged 1 Genes from Single Cells.
Sequencing of 1 PCR Products.
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Results and Discussion |
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To analyze somatic hypermutation efficiently in any mouse
strain, we established a seminested PCR approach to amplify and sequence functionally rearranged V1 genes from
single cells. The method is based on the availability of the
V
1-specific monoclonal Ab LS136 (38) that allows the
identification and isolation of single B cells expressing a
functionally rearranged V
1 gene (Fig. 1). An equivalent
monoclonal Ab specific for the translational product of a
unique V gene in both IgH allotypes is not available. In addition, gene conversion, which might to some extent contribute to the diversification of rearranged VH genes (39),
does not occur in V
1 genes (40). Therefore, the analysis
of hypermutation in rearranged V
1 genes will focus on
the primary molecular mechanism of somatic hypermutation, the introduction of untemplated point mutations into
rearranged Ig heavy and light chain gene segments.
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The single cell PCR approach omits cloning of the PCR products and thus excludes the potential formation of recombination products between PCR intermediates generated during amplification of genomic DNA or cDNA from sorted populations. It is also essentially not obscured by errors of the Taq polymerase since the amplificates are directly sequenced. Using this ex vivo approach it is possible to efficiently analyze hypermutation parameters like mutation frequency, base exchange pattern, ratio of transitions versus transversions, and distribution in any mouse strain.
Frequency, Distribution, and Base Exchange Pattern of Somatic Hypermutation in DNA Repair-deficient Mouse Strains.A possible role of NER in somatic hypermutation was analyzed in XPA, XPD, and CSB mutant mice. Consistent with the role of CSB in TCR, CSB-deficient mice lack TCR activity (21) and accordingly form an ideal system to test the gratuitous TCR-based hypermutation model (6, 10, 11). This model proposes a mutator that is loaded during transcription initiation and carried into the gene by the elongating transcription complex. Next, mutator-mediated stalling of RNA polymerase II, in the absence of DNA lesions (41), is thought to recruit factors involved in NER. A small single-stranded DNA fragment of the transcribed strand is excised by the NER machinery, and the fill in of the single stranded gap by an unknown error-prone DNA polymerase is thought to introduce the mutation. The mutation rate is determined by the error rate of the DNA polymerase.
In line with these considerations, triplex-forming oligonucleotides were found to inhibit transcription and lead to mutations 5' of a transcriptional block in mammalian cells. Mutagenesis was dependent on NER since it was not detectable in XPA- or CSB-deficient cells, respectively (42). The mechanism by which the triplex-mediated transcription inhibition not only triggers repair but also induces mutagenesis was extrapolated from the model of Hanawalt (41), which proposes that the TCR pathway of a cell may trigger "gratuitous repair" when transcription stalls at natural pause sites, even in the absence of a classical DNA lesion. These data raise the possibility that a transcriptional block might initiate the hypermutation process. A transcriptional block, for example in the V gene intron, mediated by an as yet unknown cis motif(s), could explain the reduced mRNA and protein levels of Ig in germinal center B cells (43, 44). In the frame of these speculations, hypermutation should not occur in XPA-, XPD-, or CSB-deficient mice.
However, with regard to distribution of point mutations
along the rearranged gene (Fig. 2), strand bias of hypermutation, as reflected by a preferential mutation of A, G, and
C rather than T bases (Fig. 3), frequency and ratio of transitions versus transversions (Table 1), the pattern of hypermutation appears to be normal in memory B cells of XPA-,
XPD-, and CSB-mutant mice and hypermutation is absent
in naive B cells (0/7 naive B cells carrying mutations in
XPA-mutant mice, 0/5 in XPD-mutant mice, 1/28 in
CSB-mutant mice, and 2/61 in wild-type mice; data not shown). Naive B cells were included in this analysis because of the possibility that the mutator is constitutively expressed throughout B cell development is efficiently counteracted by a specific DNA repair pathway in naive B cells
and becomes only apparent in germinal center B cells. The
slightly decreased mutation frequency in XPDTTDIBEL mice
(0.7% in XPD versus 1.0-1.6% in other mice) might relate to the fact that relatively young mice were analyzed in this
case (Table 1), since both the proportion of B cells that express mutated V-genes and the average number of nucleotide substitutions carried by the mutant V genes can increase considerably with age (2). Hypermutation thus occurs
in the absence of NER, in accord with the finding of normal hypermutation in XPB, XPD, XPV, and CSA patients
(45, 46). This strongly argues against the gratuitous TCR-based model, but does not exclude a physical link between hypermutation and transcription. The latter is based on the
findings that hypermutation is most efficient in the presence of both Ig transcriptional enhancers (47), displays a
strand bias that is based on the preference to mutate A, G,
or C rather than T (2), is restricted to a 1.5-kb window
downstream of the leader intron (48), and can be reinitiated by placing an additional Ig promoter immediately
5' to the constant portion of the Ig
chain gene, which
leads to hypermutation in the rearranged VJ region and the
C
region but not in the spacer region between these elements (11). However, the apparent dependency of the mutator on an active locus might merely reflect the accessibility of the rearranged Ig locus for the mutator. This
possibility calls for the analysis of other transcription-independent DNA repair pathways in hypermutation.
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The MSH2-deficient mouse strain allowed us to test the MMR-based model of somatic hypermutation (8). A temporal and/or local inhibition of MMR would increase the mutation rate. First, because of an increased frequency of recombination between identical and related sequences, and second, because of a defective repair of mismatches that occur during DNA replication or DNA repair. This model has an interesting evolutionary aspect. Both gene conversion and hypermutation, two processes known to diversify the Ig repertoire in chickens (conversion), sheep (hypermutation), and rabbits (conversion and hypermutation) (52) would be increased in the absence of MMR. In addition, a temporal and/or local lack of MMR could explain how a mismatch that has been introduced by the mutator can be maintained until segregation of the daughter cells. Alternatively, the mutator might "abuse" mismatch recognition proteins to fix the introduced mismatches by a temporal and/or local inhibition of subsequent MMR steps. However, in the absence of MSH2-mediated MMR throughout B cell development, the mutation frequency in memory B cells of MSH2-deficient mice was neither increased (as expected from the MMR inhibition model) nor decreased (as expected from the MMR abuse model), and the distribution of mutations along the rearranged locus were normal (Fig. 2 and Table 1). An excess of mutations at germline G·C rather than A·T pairs was found (Fig. 3). This is in accord with Phung et al., who suggested that MMR, although not required for the occurrence of somatic mutations, may influence its pattern (55). In another study, high levels of mutations were also found in variable genes from mice deficient for the mismatch repair protein PMS2. However, genes from PMS2-deficient mice showed a higher frequency of tandem mutations (Gearhart, P., personal communication). In MSH2-deficient memory B cells, the frequency of doublet mutations appears normal, i.e., one doublet mutation out of 54 mutations as compared with one triplet and two doublet mutations out of 85 mutations in wild-type memory B cells. The difference between the two mutants might relate to the fact that PMS2 lies downstream of not only MSH2 but also MSH3, which is known to bind preferentially to extrahelical loops. Considering a constitutively active mutator that is efficiently counteracted by MMR in naive B cells, a lack of MMR throughout B cell development might have caused hypermutation in naive B cells. However, seven out of seven naive B cells analyzed were unmutated (data not shown).
A possible role of RAD54 in somatic hypermutation was addressed in RAD54-mutant mice. The RAD54 mutants are deficient in DSBR through homologous recombination (23). One could imagine that pairing of homologous Ig alleles can take place in germinal center B cells. Based on the unique DNA sequence at the V(D)J recombination site, which lacks a homologous stretch of DNA on the other allele, pairing would be interrupted at this site. To resolve the Holiday junction(s), a resolvase would have to introduce nick(s) into the V(D)J region. A subsequent error-prone repair process, which might involve a nuclease activity or displacement synthesis, would introduce mutations in the recombinant strand. However, a lack of RAD54 did not influence hypermutation in memory B cells (Figs. 2 and 3, Table 1) and was absent in naive B cells (data not shown). Also V(D)J recombination and class switching were found to be normal in RAD54-mutant mice (23). Additional experiments are required to verify, whether other components of the S. cerevisiae RAD52 epistasis group (RAD50-57, RAD24, and x-ray sensitivity [XRS]2) or other recombinational repair genes are involved in the molecular mechanism underlying somatic hypermutation.
Hypermutation is characterized by nucleotide exchanges, which likely involve "nicks" of the DNA. Nicks exist as intermediates in DNA repair and DNA recombination, are intermediates in most hypermutation models, and were proposed to be actively introduced to initiate somatic hypermutation (12). To test whether the "nick-sensing activity" of PARP might be functionally involved in hypermutation, e.g., by recruiting the mutator, we analyzed hypermutation in PARP-deficient mice. Again, hypermutation occurred normally in memory B cells from PARP-deficient mice (Figs. 2 and 3, Table 1) and did not occur in the 13 naive B cells analyzed (data not shown).
In the course of this study, AAG-deficient mice became
available and were included in the analysis, as AAG is one
of the enzymes involved in BER, another mechanism of
DNA repair that could potentially be involved in somatic
hypermutation. Hypermutation appears to be unaffected in
AAG-deficient memory B (Figs. 2 and 3, Table 1) and naive B cells (5/5 unmutated). Although our data base comprises only 11 mutations (six clonally related mutations
were excluded), the base exchange patterns are within the
expected range. In addition, hypermutation has been found
to be normal in DNA polymerase -deficient memory B
cells (Texido, G., and K. Rajewsky, unpublished data).
These data argue against a connection between BER and
hypermutation.
In conclusion, single B220+, Igµ+, Ig+, V
1+ naive B
cells and B220+, Igµ
, Ig
, V
1+ memory B cells were
isolated ex vivo from XPA, XPD, CSB, MSH2, RAD54,
PARP, and AAG mutant mice and used to amplify and sequence rearranged Ig
1 genes. The results indicate that
NER does not control somatic hypermutation, strongly
arguing against the gratuitous TCR-based models of somatic hypermutation. Furthermore MMR, as well as
RAD54-dependent DSBR- and AAG-mediated BER are
not required for the hypermutation process. Although not
addressed in detail, the presence of V
1+, Igµ
, Ig
memory B cells in all the mutant mice analyzed in addition
indicates, that Ig class switching takes place in these animals.
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Footnotes |
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Address correspondence to Heinz Jacobs, Basel Institute for Immunology, Grenzacherstr. 487, CH-4005 Basel, Switzerland. Phone: 41-61-6051281; Fax: 41-61-6051364; E-mail: jacobs{at}bii.ch
Received for publication 1 December 1997 and in revised form 23 February 1998.
The authors are grateful to R. Zoebelein and C. Göttlinger for technical help and Drs. J.H.J. Hoeijmakers, J. Bachl, K.S. Campbell, R. Jessberger, and R. Torres for comments and critical reading.
This work was supported by a European Molecular Biology Organization (EMBO) long-term postdoctoral fellowship to H. Jacobs, the Deutsche Forschungsgemeinschaft through Sonderforschungsbereich 243, the Land Nordrhein-Westfalen, by the Netherlands Organization for Scientific Research (PGN 901-01-093), a fellowship of the Royal Netherlands Academy of Arts and Sciences to G. Weeda, and grants from the Dutch Cancer Society (projects EUR 94-763 and 94-858).
1Abbreviations used in this paper AAG, 3-alkyladenine DNA-glycosylase or 3-methyladenine DNA-glycosylase; AP, apurinic or apyrimidinic; BER, base-excision repair; CS, Cockayne syndrome; DSBR, double-strand- break repair; GGR, global genome repair; MMR, mismatch repair; MSH, mut S homologue; NER, nucleotide-excision repair; PARP, poly (ADP-ribose) polymerase; PI, propidium iodide; PMS, postmeiotic segregation; RAD, radiation sensitivity; TCR, transcription-coupled repair; Thy1, CD90; TTD, trichothiodystrophy; XP, xeroderma pigmentosum complementation group.
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