Mechanism of antigen-driven somatic hypermutation of rearranged immunoglobulin V(D)J genes in the mouse

ADAR deaminase A-to-I editing of DNA and RNA moieties of RNA:DNA hybrids has implications for the mechanism of Ig somatic hypermutation

The implications are discussed of recently published biochemical studies on ADAR-mediated A-to-I DNA and RNA deamination at RNA:DNA hybrids. The significance of these data are related to previous work on strand-biased and codon-context mutation signatures in B lymphocytes and cancer genomes. Those studies have established that there are two significant strand biases at A:T and G:C base pairs, A-site mutations exceed T-site mutations (A>>T) by 2.9 fold and G-site mutations exceed C-site mutations (G>>C) by 1.7 fold. Both these strand biases are inconsistent with alternative "DNA Deamination" mechanisms, yet are expected consequences of the RNA/RT-based "Reverse Transcriptase" mechanism of immunoglobulin (Ig) somatic hypermutation (SHM). The A-to-I DNA editing component at RNA:DNA hybrids that is likely to occur in Transcription Bubbles, while important, is of far lower A-to-I editing efficiency than in dsRNA substrates. The RNA moiety of RNA:DNA hybrids is also edited at similar lower frequencies relative to the editing rate at dsRNA substrates. Further, if the A-to-I DNA editing at RNA:DNA hybrids were the sole cause of A-to-I (read as A-to-G) mutation events for Ig SHM in vivo then the exact opposite strand biases at A:T base pairs (T>>A) of what is actually observed (A>>T) would be predicted. It is concluded that the strand-biased somatic mutation patterns at both A:T and G:C base pairs in vivo are best interpreted by the sequential steps of the RNA/RT-based mechanism. Further, the direct DNA A-to-I deamination at Transcription Bubbles is expected to contribute to the T-to-C component of the strand-biased Ig SHM spectrum.

Hypothesis: biological role for J-C intronic matrix attachment regions in the molecular mechanism of antigen-driven somatic hypermutation

A major function of J-C intronic matrix attachment regions (MAR) during immune diversification via somatic hypermutation (SHM) at immunoglobulin loci may be to manipulate the topology of DNA within the upstream target domain. The suggestion that SHM induction requires MAR-induced torsional strain, in conjunction with DNA remodelling at the J-C intron, completes the definition of a cogent paradigm within which all extant molecular data on the issue may be interpreted. Moreover, the suggestion that a mutagenic mechanism relieves MAR-generated superhelicity could provide an indication as to the evolutionary basis of SHM.

On the molecular mechanism of somatic hypermutation of rearranged immunoglobulin genes

Somatic hypermutation (SHM) diversifies the genes that encode immunoglobulin variable regions in antigen-activated germinal centre B lymphocytes. Available evidence strongly suggests that DNA deamination potentiates phase I SHM and subsequently triggers phase II SHM. A concise review of this evidence is followed by a detailed critique of two possible models which suggest that polymerase-eta potentiates phase II SHM via either its DNA-dependent or its RNA-dependent DNA synthetic activity. Quantitative analysis, in the context of extant data that define the features of SHM, favours the RNA-dependent mechanism.

Human DNA polymerase‐η, an A‐T mutator in somatic hypermutation of rearranged immunoglobulin genes, is a reverse transcriptase

We have proposed previously that error-prone reverse transcription using pre-mRNA of rearranged immunoglobulin variable (IgV) regions as templates is involved in the antibody diversifying mechanism of somatic hypermutation (SHM). As patients deficient in DNA polymerase-eta exhibit an abnormal spectrum of SHM, we postulated that this recently discovered Y-family polymerase is a reverse transcriptase (RT). This possibility was tested using a product-enhanced RT (PERT) assay that uses a real time PCR step with a fluorescent probe to detect cDNA products of at least 27-37 nucleotides. Human pol-eta and two other Y-family enzymes that are dispensable for SHM, human pols-iota and -kappa, copied a heteropolymeric DNA-primed RNA template in vitro under conditions with substantial excesses of template. Repeated experiments gave highly reproducible results. The RT activity detected using one aliquot of human pol-eta was confirmed using a second sample from an independent source. Human DNA pols-beta and -mu, and T4 DNA polymerase repeatedly demonstrated no RT activity. Pol-eta was the most efficient RT of the Y-family enzymes assayed but was much less efficient than an HIV-RT standard in vitro. It is thus feasible that pol-eta acts as both a RNA- and a DNA-dependent DNA polymerase in SHM in vivo, and that Y-family RT activity participates in other mechanisms of physiological importance.

Evolutionary affinity and selectivity optimization of a pesticide-selective antibody utlizing a hapten-selective immunoglobulin repertoire

Selectivity and sensitivity are considered as pivotal criteria for the quality of immunochemical assay designs in environmental analysis. They are essentially determined by the variable domains of the implemented antibody. The variable domains of a triazine-selective single-chain Fv (scFv) were genetically engineered by stringent molecular evolution in order to optimize analytical characteristics of the corresponding atrazine immunoassay. Gene variation of the template antibody by sequential shuffling against the variable heavy and light chain repertoire of a triazine-selective immunoglobulin library was enhanced by introducing additional point mutatons. Improved scFv variants were selected by phage display employing an atrazine derivative. By this means the paramounting affinity of the initial scFv to sebuthylazine was shifted for the mutant antibodies toward a preferential recognition of the envisaged target analyte atrazine. In addition, the detection limit of the atrazine assaywas significantly improved by factor 25 from 5.1 microg/L for the initial template antibody to 0.2 microg/L for the mutant antibodies. The contribution of the engineered antibody variants to the assay improvement is also reflected by a shift of the equilibrium dissociation constant KD from 1.27 x 10(-8) M of the template antibody to 7.46 x 10(-10) M of the optimized variant. Sequence analysis revealed a bias of amino acid substitutions in the first two complementarity-determining regions (CDR) and the flanking framework regions of both variable chains for the shuffled clones as well as a deletion in the CDR3 of the light chain. Particularly the mutations of the VL domain turned out to have a decisive impact on the alterations in the analytical performance of the engineered scFv mutants. The application of the mutant antibodies for the atrazine determination of soil samples revealed consistency with HPLC data within the experimental error.

A model of the early evolution of soma-to-germline feedback

The V-genes of the immunoglobulin locus in vertebrates code for a part of the heavy and light chain variable regions of antibodies and are extremely variable. Steele (1979) has developed a theory that explains the evolution of adaptive immune response by a soma-to-germline flow of cDNAs derived from somatically mutated V-genes. Here we model the early evolution of soma-to-germline feedback in a population living in a changing viral environment in terms of the dynamics of an initially rare genetic modifier that controls transfer of V-genes to germ cells' DNA. It is shown that a modifier invades the population and creates a great variety of V-genes if the environment follows stepwise temporal changes, i.e. a soma-to-germline feedback machinery evolves in a population if newly derived V-alleles still play a role in protecting the population against foreign antigens in some following generations. The distribution of the age of V-genes evolves to a bell-shaped curve the width and the maximum of which depend mainly on selection strength. Two phases of modifier evolution are distinguished. In the first phase, the dynamics are slow while the number of different V-genes is small. In the second phase, when a sufficiently large number of different V-genes is created, the modifier increases faster in frequency. Linkage of V-genes and the modifier enhances the rate of evolution.

The intrinsic hypermutability of antibody heavy and light chain genes decays exponentially

Somatic hypermutation, essential for the affinity maturation of antibodies, is restricted to a small segment of DNA. The upstream boundary is sharp and is probably related to transcription initiation. However, for reasons unknown, the hypermutation domain does not encompass the whole transcription unit, notably the C-region exon. Since analysis of the downstream decay of hypermutation is obscured by sequence-dependent hot and cold spots, we describe a strategy to minimize these fluctuations by computing mutations of different sequences located at similar distances from the promoter. We pool large databases of mutated heavy and light chains and analyse the decay of mutation frequencies. We define an intrinsic decay of probability of mutation that is remarkably similar for heavy and light chains, faster than anticipated and consistent with an exponential fit. Indeed, quite apart from hot spots, the intrinsic probability of mutation at CDR1 can be almost twice that of CDR3. The analysis has mechanistic implications for current and future models of hypermutation.

The reverse transcriptase model of somatic hypermutation

The evidence supporting the reverse transcriptase model of somatic hypermutation is critically reviewed. The model provides a coherent explanation for many apparently unrelated findings. We also show that the somatic hypermutation pattern in the human BCL-6 gene can be interpreted in terms of the reverse transcriptase model and the notion of feedback of somatically mutated sequences to the germline over evolutionary time.

A new class of errant DNA polymerases provides candidates for somatic hypermutation

The mechanism of somatic hypermutation of the immunoglobulin genes remains a mystery after nearly 30 years of intensive research in the field. While many clues to the process have been discovered in terms of the genetic elements required in the immunoglobulin genes, the key enzymatic players that mediate the introduction of mutations into the variable region are unknown. The recent wave of newly discovered eukaryotic DNA polymerases have given a fresh supply of potential candidates and a renewed vigour in the search for the elusive mutator factor governing affinity maturation. In this paper, we discuss the relevant genetic and biochemical evidence known to date regarding both somatic hypermutation and the new DNA polymerases and address how the two fields can be brought together to identify the strongest candidates for further study. In particular we discuss evidence for the in vitro biochemical misincorporation properties of human Rad30B/Pol iota and how it compares to the in vivo somatic hypermutation spectra.

The expanding polymerase universe

Over the past year, the number of known prokaryotic and eukaryotic DNA polymerases has exploded. Many of these newly discovered enzymes copy aberrant bases in the DNA template over which 'respectable' polymerases fear to tread. The next step is to unravel their functions, which are thought to range from error-prone copying of DNA lesions, somatic hypermutation and avoidance of skin cancer, to restarting stalled replication forks and repairing double-stranded DNA breaks.

Mice reconstituted with DNA polymerase beta-deficient fetal liver cells are able to mount a T cell-dependent immune response and mutate their Ig genes normally

The ubiquitously expressed, error-prone DNA polymerase beta (polbeta) plays a role in base excision repair, and the involvement of this molecule in the nonhomologous end joining (NHEJ) process of DNA repair has recently been demonstrated in yeast. Polbeta-deficient mice are not viable, and studies on conditional mutants revealed a competitive disadvantage of polbeta(-/-) vs. wild-type cells. We show here that polbeta-deficient mice survive up to day 18.5 postcoitum, but die perinatally; a circumstance that allowed the investigation of a potential role of polbeta in lymphocyte development by transfer of fetal liver cells (FLC) derived from polbeta(-/-) embryos into lethally irradiated hosts. FLC transfers using mutant cells lead to an almost normal reconstitution of the lymphocyte compartment, indicating that polbeta-deficiency does not prevent V(D)J recombination, which is known to employ factors of the NHEJ pathway. Mice reconstituted with polbeta(-/-) FLC mount a normal T cell-dependent immune response against the hapten (4-hydroxy-3-nitrophenyl) acetyl (NP). Moreover, germinal center B cells from NP-immunized reconstituted mice show normal levels and patterns of somatic point mutations in their rearranged antibody genes, demonstrating that polbeta is not critically involved in somatic hypermutation.

A λ 3′ Enhancer Drives Active and Untemplated Somatic Hypermutation of a λ1 Transgene

Somatic hypermutation is a highly regulated process that targets mutations to the rearranged Ig genes. Little is known about the cis-elements required for somatic hypermutation of the λ light chain gene. We have studied somatic hypermutation of a rearranged λ1 transgene under the control of either a λ2-4 or κ 3′ enhancer. The mutations in the transgenes were analyzed by sequencing DNA amplified from hypermutating Peyer’s patch B cells. The results indicate that the λ 3′ enhancer can drive active hypermutation of a λ1 transgene in Peyer’s patch cells. The λ1 transgene under analysis carried two marked Vλ2 genes immediately upstream that could serve as sequence donors in possible gene conversion events. There was no evidence of sequence transfer to the hypermutated λ1 gene, suggesting that gene conversion is not a major mechanism for somatic hypermutation in mice.

A unifying hypothesis for the molecular mechanism of somatic mutation and gene conversion in rearranged immunoglobulin variable genes

We have reviewed available data concerning the mechanism of somatic hypermutation in rearranged variable genes of Ig in B lymphocytes of mice and the gene conversion process which generates diversity in these genes in the B lymphocytes of chickens. In our view, these data are consistent with a unifying hypothesis of diversity generating mechanisms involving reverse transcription to produce cDNA from RNA transcripts followed by homologous recombination into chromosomal DNA. Thus, seemingly different processes in the mouse and chicken may have a common molecular basis.

Somatic hypermutation of immunoglobulin genes is independent of the Bloom's syndrome DNA helicase

Immunoglobulin gene somatic mutation leads to antibody affinity maturation through the introduction of multiple point mutations in the antigen binding site. No genes have as yet been identified that participate in this process. Bloom's syndrome (BS) is a chromosomal breakage disorder with a mutator phenotype. Most affected individuals exhibit an immunodeficiency of undetermined aetiology. The gene for this disorder, BLM, has recently been identified as a DNA helicase. If this gene were to play a role in immunoglobulin mutation, then people with BS may lack normally mutated antibodies. Since germ-line, non-mutated immunoglobulin genes generally produce low affinity antibodies, impaired helicase activity might be manifested as the immunodeficiency found in BS. Therefore, we asked whether BLM is specifically involved in immunoglobulin hypermutation. Sequences of immunoglobulin variable (V) regions were analysed from small unsorted blood samples obtained from BS individuals and compared with germ-line sequences. BS V regions displayed the normal distribution of mutations, indicating that the defect in BS is not related to the mechanism of somatic mutation. These data strongly argue against BLM being involved in this process. The genetic approach to identifying the genes involved in immunoglobulin mutation will require further studies of DNA repair- and immunodeficient individuals.

Recombination-based mechanisms for somatic hypermutation

We review some experiments designed to test recombination-based mechanisms for somatic hypermutation in mice, particularly mechanisms involving templated mutation or gene conversion. As recombination and repair functions are highly conserved among prokaryotes and eukaryotes, pathways of mutation in microorganisms may prove relevant to the mechanism of somatic hypermutation. Escherichia coli initiates a recombination-based pathway of mutation in response to environmental stimuli, and this "adaptive" pathway of mutation has striking similarities with somatic hypermutation, as does a process of mutagenic repair that occurs at double-strand breaks in Saccharomyces cerevisiae. We present a model for recombination-based hypermutation of the immunoglobulin loci which could result in either templated or non-templated mutation.

Evolution of somatic hypermutation and gene conversion in adaptive immunity

Examples of somatic hypermutation of antigen receptor genes can be seen in most lineages of vertebrates, including the cartilaginous fish. Analysis of the phylogenetic data reveals that two distinctive features of the mechanism are shared by most species studied: the mutation hot spot sequence AGY, and a preponderance of point mutations. These data suggest that some of the components of the machinery are shared between ectotherms and mammals. However, unique characters in particular species may have occurred by independent recruitment of novel factors onto the mechanism. A spotty phylogenetic distribution of gene conversion has also been revealed and can be explained if the two mechanisms share some characteristics. Both mutation and conversion require transcription-related sequences and/or factors. We theorized that targeting to V genes can be attained by a paused replication fork that has collided with a transcription complex stalled by a defective Ig transcription activator; the paused replication fork results in recruitment of an error-prone translesion synthesis DNA polymerase (somatic hypermutation) or of DNA repair mechanisms with homologous recombination (gene conversion). In addition, the pathway recruited in different species may be directed by the degree of homology among V genes.

The signature of somatic hypermutation appears to be written into the germline IgV segment repertoire

We present here a unifying hypothesis for the molecular mechanism of somatic hypermutation and somatic gene conversion in IgV genes involving reverse transcription using RNA templates from the V-gene loci to produce cDNA which undergoes homologous recombination with chromosomal V(D)J DNA. Experimental evidence produced over the last 20 years is essentially consistent with this hypothesis. We also review evidence suggesting that somatically generated IgV sequences from B lymphocytes have been fed back to germline DNA over evolutionary time.

Recombination signature of germline immunoglobulin variable genes

In human and mouse, the germline contains a tandem array of highly homologous variable (V) gene elements which encode part of the antigen-binding region of the antibody protein. During evolution this array apparently arose by gene duplication followed by diversification of duplicated genes via point mutation and recombination. Analysis of germline V gene sequences using a novel algorithm shows that major recombination sites coincide with the borders of the leader intron and the cap site, consistent with the hypothesis that over evolutionary time cDNA derived by reverse transcription of pre-mRNA in B lymphocytes has recombined with germline DNA.

Amino acid insertions and deletions contribute to diversify the human Ig repertoire

The sequence analysis of Ig variable region genes transcribed within different B-cell subpopulations from human tonsil led us to identify a rare DNA sequence modification event consisting of bp insertions and/or deletions (I/D). Although these events were previously reported, they had never been formally associated with the somatic hypermutation process. I/D events share with more conventional somatic hypermutation events their localization within hypervariable regions and, most particularly, within DNA motifs known to be mutational hot spots. Repetitive DNA tracts or DNA elements capable of forming DNA loop intermediates seem to be the preferred substrate for I/D to occur. These characteristics suggest a model for somatic hypermutation reminiscent of the "polymerase slippage" model involved in replication and repair mutations in prokaryotes, yeast, and mammals.