Immunoglobulin variable region hypermutation in hybrids derived from a pre-B- and a myeloma cell line

Biotechnology and the chicken B cell line DT40

Protein optimization is a major focus of the biotech and pharmaceutical industry. Various in vitro technologies have been developed to accelerate protein evolution and to achieve protein optimization of functional characteristics such as substrate specificity, enzymatic activity and thermostability. The chicken B cell line DT40 diversifies its immunoglobulin (Ig) gene by gene conversion and somatic hypermutation. This machinery can be directed to almost any gene inserted into the Ig locus. Enormously diverse protein libraries of any gene of interest can be quickly generated in DT40 by utilizing random shuffling of complex genetic domains (gene conversion) and by the introduction of novel non-templated genetic information (random mutagenesis). The unique characteristics of the chicken cell line DT40 make it a powerful in-cell diversification system to improve proteins of interest within living cells. One essential advantage of the DT40 protein optimization approach is the fact that variants are generated within an in-cell system thus allowing the direct screening for desired features in the context of intracellular networks. Utilizing specially designed selection strategies, such as the powerful fluorescent protein technology, enables the reliable identification of protein variants exhibiting the most desirable traits. Thus, DT40 is well positioned as a biotechnological tool to generate optimized proteins by applying a powerful combination of gene specific hypermutation, gene conversion and mutant selection.

Retroviral vectors to monitor somatic hypermutation

The recent expansion of studies on hypermutation may benefit from a fast and uncomplicated way to measure mutation rates. In this paper we compare different retroviral vector designs for monitoring hypermutation in vivo. Retroviral vectors combine a high transduction rate with integration at random sites within the host cell genome, thus equalizing positional effects on the reporter gene. The vectors contain a reporter gene with a premature TAG termination codon; upon reversion, a full-length fluorescent protein is expressed. Any single point mutation at the amber codon activates the reporter--except the transition from G to A, which only creates the stop codon TAA. In the construct, the reporter gene is followed by an internal ribosome entry site and a second marker that allows selection of stably transduced cells. As a reporter gene, we tested the green and yellow fluorescence proteins (GFP and YFP); and various proteins with red fluorescence (dsRed). The second marker was either a drug resistance gene, or a second fluorescent protein. We also introduced various cis-acting enhancer elements into the reporter construct, to study the simultaneous activity of enhancers on transcription and hypermutation. We found that GFP as a reporter, combined with a drug selection marker, gave the most consistent and convenient mutation rate measurements. DsRed is a good alternative to GFP, but variants with greater fluorescence intensity are needed when combined with green fluorescence measurements. We also confirm that no immunoglobulin specific sequence is needed to target hypermutation. Depending on their position in these ectopically expressed constructs, enhancers can have positive or negative effects on hypermutation.

Mutation detection of immunoglobulin V-regions by DHPLC

One of the key features in the affinity maturation of antibodies is somatic hypermutation of the variable regions of immunoglobulin genes. The mutations that occur in immunoglobulin genes are detected by direct sequencing of cloned polymerase chain reaction (PCR) products. The frequencies of mutations in vivo are generally high enough to provide sufficient numbers of point mutations in order to generate large databases that can be analyzed in various ways. Recently, the mechanisms of variable (V)-region hypermutation have been studied in tissue culture systems and transgenic mice where mutation occurs at frequencies that are approximately 10-fold lower than the estimated in vivo rate. Identifying mutations by brute force sequencing of PCR products in comparative studies is limiting when trying to determine if there are statistically significant differences. Here we describe a high throughput technique that can facilitate the identification of immunoglobulin V-regions that contain one or more mutations before sequencing. This technique, known as denaturing high-performance liquid chromatography (DHPLC), utilizes a standard HPLC apparatus with a column that binds double-stranded DNA (dsDNA). In this study, we have successfully detected approximately 90% of previously sequenced mutated V-regions by DHPLC. Our results show that we were able to detect mutations throughout a 321-base pair (bp) region of the Ricin 45 immunoglobulin (Ig) V-region. Also, with the use of this assay, we have been able to detect mutations in multiple clones of different immunoglobulin genes.

T-bet regulates IgG class switching and pathogenic autoantibody production

A molecular understanding of the regulation of IgG class switching to IL-4-independent isotypes, particularly to IgG2a, remains largely unknown. The T-box transcription factor T-bet directly regulates Th1 lineage commitment by CD4 T cells, but its role in B lymphocytes has been largely unexplored. We show here a role for T-bet in the regulation of IgG class switching, especially to IgG2a. T-bet-deficient B lymphocytes demonstrate impaired production of IgG2a, IgG2b, and IgG3 and, most strikingly, are unable to generate germ-line or postswitch IgG2a transcripts in response to IFN-gamma. Conversely, enforced expression of T-bet initiates IgG2a switching in cell lines and primary cells. This function contributes critically to the pathogenesis of murine lupus, where the absence of T-bet strikingly reduces B cell-dependent manifestations, including autoantibody production, hypergammaglobulinemia, and immune-complex renal disease and, in particular, abrogates IFN-gamma-mediated IgG2a production. Classical T cell manifestations persisted, including lymphadenopathy and cellular infiltrates of skin and liver. These results identify T-bet as a selective transducer of IFN-gamma-mediated IgG2a class switching in B cells and emphasize the importance of this regulation in the pathogenesis of humorally mediated autoimmunity.

Clonal instability of V region hypermutation in the Ramos Burkitt's lymphoma cell line

Affinity maturation of the humoral immune response is caused by single base changes that are introduced into the V regions of the Ig genes during a brief period of B cell differentiation. It has recently become possible to study V region mutation in some human Burkitt's lymphoma cell lines that mutate their V regions and express surface markers that suggest they arose from the malignant transformation of germinal center B cells. Ramos Burkitt's cells constitutively mutate their V regions at a rate of approximately 2 x 10(-5) mutations/bp/generation. However, the sequencing of unselected V regions suggested that our Ramos cell line was progressively losing its ability to undergo V region hypermutation. To accurately quantify this process, subclones with different nonsense mutations in the mu heavy chain V region were identified. Reversion analysis and sequencing of unselected V regions were used to examine the clonal stability of V region hypermutation. Even after only 1 month in culture, stable and unstable subclones could be identified. The identification of mutating and non-mutating subclones of Ramos provided a unique opportunity to identify factors involved in the mutational process. Differential gene expression between mutating and non-mutating Ramos clones was examined by RT-PCR and cDNA microarray analyses. We found that the expression of activation-induced cytidine deaminase (AID), a putative cytidine deaminase, correlated with mutation rates in Ramos subclones. These results suggest that the hypermutation phenotype is inherently unstable in Ramos and that long culture periods favor outgrowth of non-mutating cells that express lower levels of AID.

Increased transcription levels induce higher mutation rates in a hypermutating cell line

Somatic hypermutation, in addition to V(D)J recombination, is the other major mechanism that generates the vast diversity of the Ab repertoire. Point mutations are introduced in the variable region of the Ig genes at a million-fold higher rate than in the rest of the genome. We have used a green fluorescent protein (GFP)-based reversion assay to determine the role of transcription in the mutation mechanism of the hypermutating cell line 18-81. A GFP transgene containing a premature stop codon is transcribed from the inducible tet-on operon. Using the inducible promoter enables us to study the mutability of the GFP transgene at different transcription levels. By analyzing stable transfectants of a hypermutating cell line with flow cytometry, the mutation rate at the premature stop codon can be measured by the appearance of GFP-positive revertant cells. Here we show that the mutation rate of the GFP transgene correlates with its transcription level. Increased transcription levels of the GFP transgene caused an increased point mutation rate at the premature stop codon. Treating a hypermutating transfection clone with trichostatin A, a specific inhibitor of histone deacetylase, caused an additional 2-fold increase in the mutation rate. Finally, using Northern blot analysis we show that the activation-induced cytidine deaminase, an essential trans-factor for the in vivo hypermutation mechanism, is transcribed in the hypermutating cell line 18-81.

Advances in animal cell recombinant protein production: GS-NS0 expression system

The production of recombinant proteins using mammalian cell expression systems is of growing importance within biotechnology, largely due to the ability of specific mammalian cells to carry out post-translational modifications of the correct fidelity. The Glutamine Synthetase-NS0 system is now one such industrially important expression system.Glutamine synthetase catalyses the formation ofglutamine from glutamate and ammonia. NS0 cellscontain extremely low levels of endogenous glutaminesynthetase activity, therefore exogenous glutaminesynthetase can be used efficiently as a selectablemarker to identify successful transfectants in theabsence of glutamine in the media. In addition, theinclusion of methionine sulphoximine, an inhibitor ofglutamine synthetase activity, enables furtherselection of those clones producing relatively highlevels of transfected glutamine synthetase and henceany heterologous gene which is coupled to it. Theglutamine synthetase system technology has been usedfor research and development purposes during thisdecade and its importance is clearly demonstrated nowthat two therapeutic products produced using thissystem have reached the market place.

Human B cells accumulate immunoglobulin V gene somatic mutations in a cell contact-dependent manner in cultures supported by activated T cells but not in cultures supported by CD40 ligand

The acquisition of somatic mutations in the rearranged immunoglobulin V regions in B cells occurs within the tightly regulated microenvironment of a germinal centre. The precise mechanism responsible for turning on the mutational process is unknown. To dissect the role of different components of the germinal centre in this mechanism, we have used in vitro cultures of normal human IgD+ peripheral blood B lymphocytes co-cultured with activated CD4+ T cells, or with resting CD4+ T cells, or with CD40 ligand and IL-4. We observed that if the cultures included activated CD4+ T cells, then up to 100% of VH transcripts on day 14 were somatically mutated. Transcripts were found to carry from one to 36 substitutions (median five). In contrast, in the absence of activated T cells, transcripts contained only background levels of somatic mutation irrespective of the presence of resting T cells or CD40 ligand and IL-4. Cell-cell contact was required for mutation because mutations were not detected when B cells were separated from activated T cells by a membrane.

Hypermutation targets a green fluorescent protein-encoding transgene in the presence of immunoglobulin enhancers

Hypermutation introduces point mutations into the gene segments encoding immunoglobulin variable regions at a rate that is a million-fold higher than the spontaneous mutation rate in most of the genome. Because Ig enhancers are required to target hypermutation, transcription appears to play a critical role for the hypermutation mechanism. We have developed a novel system for detecting mutations that enables us to determine the influence of expression levels on the mutability of a transgene. This system utilizes a green fluorescent protein receptor gene and the powerful enumeration and quantification properties of flow cytometry. We have tested this system with several constructs bearing Ig enhancers in cell lines with active and inactive hypermutation systems.

Induction of Ig Somatic Hypermutation and Class Switching in a Human Monoclonal IgM+ IgD+ B Cell Line In Vitro: Definition of the Requirements and Modalities of Hypermutation

Partly because of the lack of a suitable in vitro model, the trigger(s) and the mechanism(s) of somatic hypermutation in Ig genes are largely unknown. We have analyzed the hypermutation potential of human CL-01 lymphocytes, our monoclonal model of germinal center B cell differentiation. These cells are surface IgM+ IgD+ and, in the absence of T cells, switch to IgG, IgA, and IgE in response to CD40:CD40 ligand engagement and exposure to appropriate cytokines. We show here that CL-01 cells can be induced to effectively mutate the expressed VHDJH-Cμ, VHDJH-Cδ, VHDJH-Cγ, VHDJH-Cα, VHDJH-Cε, and VλJλ-Cλ transcripts before and after Ig class switching in a stepwise fashion. In these cells, induction of somatic mutations required cross-linking of the surface receptor for Ag and T cell contact through CD40:CD40 ligand and CD80:CD28 coengagement. The induced mutations showed intrinsic features of Ig V(D)J hypermutation in that they comprised 110 base substitutions (97 in the heavy chain and 13 in the λ-chain) and only 2 deletions and targeted V(D)J, virtually sparing CH and Cλ. These mutations were more abundant in secondary VHDJH-Cγ than primary VHDJH-Cμ transcripts and in V(D)J-C than VλJλ-Cλ transcripts. These mutations were also associated with coding DNA strand polarity and showed an overall rate of 2.42 × 10−4 base changes/cell division in VHDJH-CH transcripts. Transitions were favored over transversions, and G nucleotides were preferentially targeted, mainly in the context of AG dinucleotides. Thus, in CL-01 cells, Ig somatic hypermutation is readily inducible by stimuli different from those required for class switching and displays discrete base substitution modalities.

Induction of Ig somatic hypermutation and class switching in a human monoclonal IgM+ IgD+ B cell line in vitro: definition of the requirements and modalities of hypermutation

Partly because of the lack of a suitable in vitro model, the trigger(s) and the mechanism(s) of somatic hypermutation in Ig genes are largely unknown. We have analyzed the hypermutation potential of human CL-01 lymphocytes, our monoclonal model of germinal center B cell differentiation. These cells are surface IgM+ IgD+ and, in the absence of T cells, switch to IgG, IgA, and IgE in response to CD40:CD40 ligand engagement and exposure to appropriate cytokines. We show here that CL-01 cells can be induced to effectively mutate the expressed VHDJH-C mu, VHDJH-C delta, VHDJH-C gamma, VHDJH-C alpha, VHDJH-C epsilon, and V lambda J lambda-C lambda transcripts before and after Ig class switching in a stepwise fashion. In these cells, induction of somatic mutations required cross-linking of the surface receptor for Ag and T cell contact through CD40:CD40 ligand and CD80: CD28 coengagement. The induced mutations showed intrinsic features of Ig V(D)J hypermutation in that they comprised 110 base substitutions (97 in the heavy chain and 13 in the lambda-chain) and only 2 deletions and targeted V(D)J, virtually sparing CH and C lambda. These mutations were more abundant in secondary VHDJH-C gamma than primary VHDJH-C mu transcripts and in V(D)J-C than V lambda J lambda-C lambda transcripts. These mutations were also associated with coding DNA strand polarity and showed an overall rate of 2.42 x 10(-4) base changes/cell division in VHDJH-CH transcripts. Transitions were favored over transversions, and G nucleotides were preferentially targeted, mainly in the context of AG dinucleotides. Thus, in CL-01 cells, Ig somatic hypermutation is readily inducible by stimuli different from those required for class switching and displays discrete base substitution modalities.

Alternative Splicing and Hypermutation of a Nonproductively Rearranged TCR α-Chain in a T Cell Hybridoma

Like Ig genes, TCR genes are formed by somatic rearrangements of noncontiguous genomic V, J, and C regions. Unlike Ig genes, somatic hypermutation of TCR V regions is an infrequent event. We describe the occurrence of spontaneous hypermutation in a nonproductively rearranged TCR α-chain gene in a clonal T cell hybridoma that had lost its productively rearranged α-chain. The mutating hybridoma was eventually supplanted in culture by a nonmutating variant that had restored an open reading frame in the nonproductively rearranged TCR α-chain through the use of cryptic splice sites in the Vα region. Evidence is presented for the presence of cDNA reverse transcripts of the TCR α-chain within the hybridoma, suggesting a role for reverse transcriptase in the generation of mutations.

A Role for RAD51 in the Generation of Immunoglobulin Gene Diversity in Rabbits

Ig VDJ genes in rabbit somatically diversify by both hyperpointmutation and gene conversion. To elucidate the mechanism of gene conversion of IgH genes, we cloned a rabbit homologue of RAD51, a gene involved in gene conversion in Saccharomyces cerevisiae (yeast), and tested whether it could complement a yeast rad51 mutant deficient in recombination repair. We found that rabbit RAD51 partially complemented the defect in switching mating types by gene conversion as well as in DNA double-strand break repair after γ-irradiation. Further, by Western blot analysis, we found that levels of Rad51 were higher in appendix-derived B lymphocytes of 6-wk-old rabbits, a time at which IgH genes diversify by somatic gene conversion. We suggest that Rad51 is involved in somatic gene conversion of rabbit Ig genes.

Immunoglobulin hypermutation in cultured cells

Studies of endogenous and engineered Ig genes in mice have begun to reveal some of the cis-acting regions that are involved in the somatic hypermutation of variable regions in vivo. These studies suggest that the initiation of transcription plays a role in this process. However, it will be difficult to identify and manipulate the individual genetic elements and the trans-acting proteins that regulate and target the mutational events using solely in vivo assays. These studies would be greatly facilitated if constructs containing the genetic elements that are essential for V-region mutation could be transfected into cultured cells and undergo high rates of V-region mutation in vitro, and if permissive and non-permissive cell lines could be identified. Such in vitro systems would also allow a detailed molecular and biochemical analysis of this process. Here, we discuss some of the in vitro systems that have been developed and use data from our own studies in cultured cells to illustrate the potential benefits of studying V-region hypermutation in model in vitro systems.

The Ig mutator is dependent on the presence, position, and orientation of the large intron enhancer

Hypermutation at the Ig loci is confined to the area between the promoter and the intronic enhancer, which includes the rearranged variable region gene segment. We identified factors that contribute to the site-specificity at the heavy chain locus. We found that distance from both the promoter and the intronic enhancer is crucial in hypermutation. The presence of the enhancer is required, and, in contrast to its definition for transcriptional activity, its effect is orientation-sensitive.

Somatic hypermutation of antibody genes: a hot spot warms up

In the course of an immune response, antibodies undergo affinity maturation in order to increase their efficiency in neutralizing foreign invaders. Affinity maturation occurs by the introduction of multiple point mutations in the variable region gene that encodes the antigen binding site. This somatic hypermutation is restricted to immunoglobulin genes and occurs at very high rates. The precise molecular basis of this process remains obscure. However, recent studies using a variety of in vivo and in vitro systems have revealed important regulatory regions, base motifs that are preferred targets of mutation and evidence that transcription may play an active role in hypermutation.

Critical test of hot spot motifs for immunoglobulin hypermutation

In hypermutation at the immunoglobulin loci, some bases are much more mutable than others. The increased mutability of the hot spots has been attributed to their being embedded in short sequence motifs. Among the suggested motifs are palindromes, TAA and RGYW (i.e. A/G G C/T A/T). We have tested these proposed motifs in a transfection system in vitro, which ordinarily uses the hypermutable stop codon TAG. The stop codon TAA is not hypermutable in our system, even when embedded in the pentamer and hexamer palindromes TAATA and ATTAAT; in fact, the revertants isolated were due to deletions. Single or double base changes in an RGYW motif containing a hypermutable stop codon result in a reduction of one order of magnitude or more in point mutation frequency. When the nonamer GACTAGTAT, which includes the same RGYW motif, was moved over hundred base pairs upstream, hypermutability was reduced by an order of magnitude. Thus, while RGYW apparently is a hypermutability motif, it cannot be the sole determinant of mutability.

Sequence dependent hypermutation of the immunoglobulin heavy chain in cultured B cells

The variable (V) regions of immunoglobulin heavy and light chains undergo high rates of somatic mutation during the immune response. Although point mutations accumulate throughout the V regions and their immediate flanking sequences, analysis of large numbers of mutations that have arisen in vivo reveal that the triplet AGC appears to be most susceptible to mutation. We have stably transfected B cell lines with gamma2a heavy chain constructs containing TAG nonsense codons in their V regions that are part of either a putative (T)AGC hot spot or a (T)AGA non-hot spot motif. Using an ELISA spot assay to detect revertants and fluctuation analysis to determine rates of mutation, the rate of reversion of the TAG nonsense codon has been determined for different motifs in different parts of the V region. In the NSO plasma cell line, the (T)AGC hot spot motif mutates at rates of approximately 6 x 10(-4)/bp per generation and approximately 3 x 10(-5)/bp per generation at residues 38 and 94 in the V region. At each of these locations, the (T)AGC hot spot motif is 20-30 times more likely to undergo mutation than the (T)AGA non-hot spot motif. Moreover, the AGA non-hot spot motif mutates at as high a rate as the hot spot motif when it is located adjacent to hot spot motifs, suggesting that more extended sequences influence susceptibility to mutation.

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

Available data relevant to the mechanism of somatic hypermutation have been critically evaluated in the context of alternative models: (i) error-generating reverse transcription (RT) followed by homologous recombination; and (ii) error-prone DNA replication/repair. A set of basic principles concerning somatic hypermutation has also been formulated and a revised and expanded "RT-Mutatorsome" concept (analogous to telomerase) is presented which is consistent with these principles and all data on the distribution of somatic mutations in normal and Ig transgenic mice carrying particular V(D)J and flanking region constructs. It is predicted that in the mouse VH and Vk loci. the J-C intronic Enhancer-Nuclear Matrix Attachment Region (Ei/MAR) contains a unique sequence motif or secondary structure which ensures that only V(D)J sequences mutate whilst other regions of the genome are not mutated.

Induction of somatic mutation in a human B cell line in vitro

Both the B cell-surface trigger(s) and the intracellular molecular mechanism(s) of somatic hypermutation in immunoglobulin (Ig) variable region genes remain unknown, partly because of the lack of a simple and reproducible in vitro model. Here, we show that upon surface immunoglobulin cross-linking followed by co-culture with activated cloned T cells, the Burkitt's lymphoma cell line BL2 is induced to mutate its IgV(H) gene. Repeated activation of BL2 cells increased the frequency of mutation. The in vitro-induced mutations, which do not affect the IgM constant region, are point mutations distributed over the entire V(H)DJ(H) gene segment and do not show evidence of antigen-driven selection.

Differential V region mutation of two transfected Ig genes and their interaction in cultured B cell lines

We have established B cell culture systems in which transfected and stably integrated Ig constructs spontaneously undergo high rates of variable (V) region mutation. Mutation rates were determined using reversion analysis of an Ig V region nonsense codon (Vn). A construct (Vn/gamma2a) in which a Vn was associated with the gamma2a constant region and its intervening and immediate flanking sequences mutated at a high rate of 2.2 x 10(-4)/bp/generation in the NSO myeloma cell line. This same Vn, when associated with the mu constant region (Vn/mu), mutated at a 1000-fold lower rate in NSO. The Vn/gamma2a construct also mutated at high rates in the 18.81 pre-B and the S107 myeloma cell lines and at a low rate in the J558 myeloma cell line. In NSO, the presence of the gamma2a construct raised the mutation rate of the mu construct and the mu decreased the mutation rate of gamma2a. These results suggest that there is both positive and negative regulation of V region mutation and that different cell lines express different combinations and/or amounts of trans-acting factors that are involved in the mutational process.

Somatic hypermutation of immunoglobulin genes

The relationship between somatic hypermutation and affinity maturation in the mouse is delineated. Recent work on the anatomical and cellular site of this process is surveyed. The molecular characteristics of somatic hypermutation are described in terms of the region mutated and the distinctive patterns of nucleotide changes that are observed. The results of experiments utilizing transgenic mice to find out the minimum cis-acting sequences required to recruit hypermutation are summarized. The hypothesis that V gene sequences have evolved in order to target mutation to certain sites but not others is discussed. The use that different species make of somatic hypermutation to generate either the primary or secondary B cell repertoire is considered. Possible molecular mechanisms for the hypermutation process and future goals of research are outlined.

The molecular basis of somatic hypermutation of immunoglobulin genes

Somatic hypermutation amplifies the variable region repertoire of immunoglobulin genes. Recent experimental evidence has thrown light on various molecular models of somatic hypermutation. A link between somatic hypermutation and transcription coupled DNA repair is shaping up.

Affinity maturation and class switching

Affinity maturation and class switching of antibodies are temporally, but not mechanistically, related processes. The basis of affinity maturation is the selection, in the germinal centers, of antibodies that bind the antigen better. Early in an immune response, the selection is from the primary repertoire; later, it is from mutants generated by hypermutation at the immunoglobulin loci. Recently, the door has been opened for the study of the molecular mechanism of hypermutation, which is expected to make a major contribution to general biology. Class switching has been studied in the past for its obvious clinical importance, but also at the basic level of DNA recombination. Progress in understanding class switching has been trailing the progress made in V(D)J recombination, but new in vitro systems and gene-targeted mice are closing the gap.