Molecular Insights into Lymphoid Malignancy : Role of Transcription Factor BCL11B in T-cell Leukemia Genesis and Biochemical Characterization of DNA Binding Domain of RAG1

Deepthi, R

January 2017

The lymphoid tissues consist of distinct cell subpopulations of B and T cell lineages and possess complex signaling pathways that are controlled by a myriad of molecular interactions. During the fine-tuned developmental process of the lymphoid system, inappropriate activation of oncogenes and loss of tumor suppressor gene activity can push lymphocytes into uncontrolled clonal expansion, causing several lymphoid malignancies. V(D)J recombination is one such essential process, important for the proper development of the mammalian immune system. However, mistakes in normal V(D)J recombination can lead to deletion of tumor suppressor genes or activation of proto-oncogenes. In the first part of the study, the physiological and pathological roles of DNA binding domain of RAG1 have been characterized. RAG (Recombination Activating Gene) complex consisting of RAG1 and RAG2, is a site specific endonuclease responsible for the generation of antigen receptor diversity. It cleaves a specific DNA sequence termed as recombination signal sequence (RSS), comprising of a conserved heptamer and nonamer. Recent studies have shown that RAGs can also act as a structure-specific nuclease by cleaving flaps, heterologous loops, bubbles, hairpins etc. Nonamer binding domain (NBD) of RAG1 plays a central role in the recognition of RSS during its sequence specific activity. To investigate its DNA binding properties, NBD of murine RAG1 was cloned, overexpressed and purified from E. coli. Electrophoretic mobility shift assays showed that NBD binds with high affinity to nonamer in the context of 12/23 RSS. However, it did not bind to heteroduplex DNA, irrespective of the sequence of the single-stranded region. Interestingly, when a nonamer was present next to a heteroduplex DNA, NBD exhibited robust binding. NBD binding was specific to thymines when single stranded DNA containing poly A, C, G and T were used. Biolayer interferometry studies showed that the observed poly T binding to NBD was robust with a binding constant of 0.45±0.16 µM. >23 nt was essential for NBD binding at homothymidine stretches. On a double-stranded DNA, NBD could bind to A:T stretches, but not G:C stretches or random sequences. Although NBD is indispensable for sequence-specific activity of RAGs, external supplementation of purified nonamer binding domain to NBD deleted cRAG1/cRAG2 did not restore the sequence specific activity, suggesting that the overall domain architecture of RAG1 is important for maintaining its properties. Therefore, we define the sequence requirements of NBD binding to double- and single-stranded DNA, which will have implications in generation of chromosomal rearrangement and genomic instability in lymphoid cells. Genetic alterations are one of the hallmarks of lymphoid malignancies. Many genes involved in chromosomal abnormalities are known to play central roles in the development of normal lymphocytes. In the second part of the study, molecular mechanism associated with fragility of the transcription factor, B cell leukemia 11B (BCL11B) that drives malignant transformation of T-cells has been studied. BCL11B is a zinc finger protein transcription factor with multiple functions. It plays a key role in both development and subsequent maintenance of T-cells. BCL11B gene alterations are implicated in a number of diseases including T-cell malignancies. It acts as a haplo-insufficient tumor suppressor and loss of BCL11B allele leads to susceptibility to mouse thymic lymphoma and human T-ALL. Recent studies reveal heterozygous BCL11B mutations and deletions across each of the major molecular subtypes of T-ALL (15% of patients). Most of the BCL11B missense mutations identified so far affected the residues within BCL11B zinc finger domains of the exon 4. However, mechanism of generation of such specific mutations leading to altered functions of BCL11B remains to be explored. In the present study, we address the potential mechanism of fragility of BCL11B gene during leukemia genesis. Firstly, we have evaluated different regions of BCL11B gene for presence of non-B DNA sequence motifs. Studies using non-B DB database reveal clustering of several non-B DNA forming motifs at the region spanning exon 4 of BCL11B gene. In order to biochemically evaluate the potential of non-B DNA structure formation, two different regions of exon 4 were PCR amplified and cloned. Using bisulfite modification assay we demonstrate that, single strandedness exists at both region I and II of BCL11B exon 4, when the region is present on a plasmid DNA. Bisulfite reactivity on chromosomal DNA confirmed existence of such altered DNA structures in the context of human genome. In vitro gel shift assays showed formation of both intra and intermolecular G-quadruplexes. Primer extension studies revealed that non-B DNA structures could block polymerization during replication on a plasmid, leading to DNA replication arrest. Extrachromosomal assays showed that non-B DNA structure motifs, in contrast to its mutants, blocked transcription leading to reduced expression of green fluorescent protein (GFP) within cells. Many non-B DNA-forming sequences have been mapped to regions of common chromosomal breakpoints in human tumors, known as “hotspots”, which are associated with leukemia, lymphomas and genomic disorders. Thus, alternative DNA conformations are believed to contribute to mutations, deletions and other genetic instability, leading to the deregulation of cancer-related genes in malignant diseases such as leukemia and lymphoma. Activation induced cytidine deaminase (AID), is an essential enzyme involved in antibody diversification of immunoglobulin genes. However, aberrant AID expression in B- cell and non-B cell background is reported in various cancers including leukemia and lymphoma. AID activity requires single stranded DNA (ssDNA) as a substrate. Since activation induced cytidine deaminase (AID) deaminates cytosines when present on a single stranded DNA and its expression is deregulated in many cancers, we investigated the role of AID in BCL11B gene mutagenesis. We observed substantial AID expression in many T-cell leukemic cell lines. Thus, we hypothesize that AID might be targeted to single stranded DNA present at BCL11B exon 4 due to formation of non-B DNA structures such as G-quadruplexes causing AID mediated deamination, further leading to nucleotide alterations and the mutational signature observed at BCL11B exon 4 resulting in T-ALL. Based on our findings, we propose that single strandedness resulted due to formation of non-B DNA structures such as G-quadruplex DNA, triplex DNA or cruciform DNA during physiological processes like DNA replication and transcription at exon 4 of BCL11B, can act as the target for AID. Thus, our findings uncover a new possible link between non-B DNA structure motifs and AID expression in causing mutations at BCL11B exon 4 which could lead to T cell leukemia genesis. BCL11B is a bifunctional transcriptional regulator that can act as a repressor and transactivator, and is known to differentially control the expression of specific genes in a context-dependent manner. In order to understand the transcriptional network involving BCL11B, it was cloned, overexpressed and purified from E. coli. To investigate the DNA binding properties of BCL11B protein, electrophoretic mobility shift assays were performed. Our results lead to identification of a specific sequence motif that is responsible for DNA binding. Competition experiments in presence of specific and nonspecific oligomers further confirmed the binding specificity. Thus, in the present study, we have characterized the binding properties of nonamer binding domain of RAG1, emphasizing its pathological relevance in causing genomic instability in lymphoid cells. The study may help in better understanding of RAG induced genomic instability in lymphoid tissues and role of aberrant AID expression in inducing mutations at BCL11B Zinc finger domain, leading to its deregulation and culminating into T-cell leukemia

Lymphoid Malignancy

Transcription Factor - BCL11B

BCL11B in T-cell Leukemia Genesis

Lymphoid Malignancies

Recombination Activating Gene (RAG)

RAG1

BCL11B Gene

Biochemistry

Extrathymic T cell receptor gene rearrangement in human alimentary tract

Bas, Anna

January 2003

<p>T lymphocytes regulate the initiation, duration, and magnitude of adaptive immune responses and function as effector cells in cell mediated immunity. To become immunologically competent they must generate functional antigen receptors. This process takes place in the thymus and requires somatic recombination of T cell receptor (TCR) genes. It is mediated by the endonucleases recombination activating gene-1 (RAG1) and RAG2. Although the thymus regresses at puberty, T cells are present throughout life implying that other tissues must provide the proper milieu for T cell development. This thesis describes extrathymic T cell maturation in man. RAG1, RAG2, and the preTα-chain (pTα), which is exclusively utilized in developing T cells, were used as markers for TCR gene rearrangement. Two new exons (1A and 1B) encoding sequences in the 5’ untranslated region (5’UTR) of mRNA were discovered in the human RAG1 gene. The previously described 5’UTR exon (renamed 1C) was located between the new exons and exon 2, the latter containing the entire coding sequence. We found that small intestinal lymphocytes of the T cell lineage expressed the new exons in three different splice forms. RAG1 mRNA containing the 1C exon was not expressed in small intestinal lymphocytes. In contrast, splice forms containing the 1A exon were not expressed in thymocytes. RAG1 and pTα mRNA expressing lymphocytes were seen both within the epithelium and in lamina propria. Thymocyte-like CD2⁺CD7⁺CD3^-, CD4⁺CD8⁺, CD1a⁺, and IL7-R+ lymphocytes were identified in the small intestinal mucosa. CD2⁺CD7⁺CD3^- cells had the highest expression levels of mRNA for RAG1 and pTα, suggesting that the small intestinal mucosa is indeed a site for T cell maturation. Small intestinal T lymphocytes were also shown to kill via the Fas/FasL pathway in a TCR/CD3 independent manner and via the perforin/granzyme pathway in a TCR/CD3 dependent manner. The Fas/FasL-mediated cytotoxicity may reflect an ongoing selection process of extrathymically maturated T cells. </p><p>The nasopharyngeal tonsil is the major inductive site for immune reactions against inhaled antigens. Previous demonstration of RAG1 expression in tonsillar B cells was interpreted as antigen driven receptor revision. The present study confirms the expression of RAG1 in B cells. We also found that RAG1, RAG2, and pTa mRNAs were expressed in lymphocytes of the T cell lineage. A small population of cells with the immature phenotype CD2+CD7+CD3- was demonstrated. This population had the highest expression levels of mRNA for RAG1, RAG2, pTα and terminal deoxynucleotidyl transferase. All four splice-forms of RAG1 mRNA were expressed. RAG1 and pTα mRNA expressing cells were mainly located in the proximity of the surface epithelium and in the outer rim of the follicles. These results suggest that the nasopharyngeal tonsil is a site where extrathymic T cell development and antigen driven TCR revision are occurring in parallel. </p><p>Celiac disease (CD) is a small intestinal enteropathy characterized by permanent intolerance to gluten. Gluten reactive intestinal T cells are central in the pathogenesis and CD can be regarded as a failure to maintain tolerance to this food antigen. Expression of the RAG1 1A/2 splice form was significantly decreased in small intestinal T cell subsets of CD patients suggesting that impaired TCR gene rearrangement could contribute to failure of maintain tolerance in CD. </p><p>Together, these findings show that both small intestinal and nasopharyngeal tonsillar lymphocytes of T cell lineage have the molecular machinery for antigen receptor rearrangement and that thymocyte-like lymphocytes are present in both tissues. Thus these organs are likely sites of T lymphocyte ontogeny as well as for secondary T cell receptor rearrangement in man. </p>

Immunology

T cell maturation

recombination activating gene

preTα

human intestinal mucosa

intraepithelial lymphocytes

lamina propria lymphocytes

nasopharyngeal tonsil

Immunologi

Immunology

Immunologi

Extrathymic T cell receptor gene rearrangement in human alimentary tract

Bas, Anna

January 2003

T lymphocytes regulate the initiation, duration, and magnitude of adaptive immune responses and function as effector cells in cell mediated immunity. To become immunologically competent they must generate functional antigen receptors. This process takes place in the thymus and requires somatic recombination of T cell receptor (TCR) genes. It is mediated by the endonucleases recombination activating gene-1 (RAG1) and RAG2. Although the thymus regresses at puberty, T cells are present throughout life implying that other tissues must provide the proper milieu for T cell development. This thesis describes extrathymic T cell maturation in man. RAG1, RAG2, and the preTα-chain (pTα), which is exclusively utilized in developing T cells, were used as markers for TCR gene rearrangement. Two new exons (1A and 1B) encoding sequences in the 5’ untranslated region (5’UTR) of mRNA were discovered in the human RAG1 gene. The previously described 5’UTR exon (renamed 1C) was located between the new exons and exon 2, the latter containing the entire coding sequence. We found that small intestinal lymphocytes of the T cell lineage expressed the new exons in three different splice forms. RAG1 mRNA containing the 1C exon was not expressed in small intestinal lymphocytes. In contrast, splice forms containing the 1A exon were not expressed in thymocytes. RAG1 and pTα mRNA expressing lymphocytes were seen both within the epithelium and in lamina propria. Thymocyte-like CD2+CD7+CD3-, CD4+CD8+, CD1a+, and IL7-R+ lymphocytes were identified in the small intestinal mucosa. CD2+CD7+CD3- cells had the highest expression levels of mRNA for RAG1 and pTα, suggesting that the small intestinal mucosa is indeed a site for T cell maturation. Small intestinal T lymphocytes were also shown to kill via the Fas/FasL pathway in a TCR/CD3 independent manner and via the perforin/granzyme pathway in a TCR/CD3 dependent manner. The Fas/FasL-mediated cytotoxicity may reflect an ongoing selection process of extrathymically maturated T cells. The nasopharyngeal tonsil is the major inductive site for immune reactions against inhaled antigens. Previous demonstration of RAG1 expression in tonsillar B cells was interpreted as antigen driven receptor revision. The present study confirms the expression of RAG1 in B cells. We also found that RAG1, RAG2, and pTa mRNAs were expressed in lymphocytes of the T cell lineage. A small population of cells with the immature phenotype CD2+CD7+CD3- was demonstrated. This population had the highest expression levels of mRNA for RAG1, RAG2, pTα and terminal deoxynucleotidyl transferase. All four splice-forms of RAG1 mRNA were expressed. RAG1 and pTα mRNA expressing cells were mainly located in the proximity of the surface epithelium and in the outer rim of the follicles. These results suggest that the nasopharyngeal tonsil is a site where extrathymic T cell development and antigen driven TCR revision are occurring in parallel. Celiac disease (CD) is a small intestinal enteropathy characterized by permanent intolerance to gluten. Gluten reactive intestinal T cells are central in the pathogenesis and CD can be regarded as a failure to maintain tolerance to this food antigen. Expression of the RAG1 1A/2 splice form was significantly decreased in small intestinal T cell subsets of CD patients suggesting that impaired TCR gene rearrangement could contribute to failure of maintain tolerance in CD. Together, these findings show that both small intestinal and nasopharyngeal tonsillar lymphocytes of T cell lineage have the molecular machinery for antigen receptor rearrangement and that thymocyte-like lymphocytes are present in both tissues. Thus these organs are likely sites of T lymphocyte ontogeny as well as for secondary T cell receptor rearrangement in man.

Immunology

T cell maturation

recombination activating gene

preTα

human intestinal mucosa

intraepithelial lymphocytes

lamina propria lymphocytes

nasopharyngeal tonsil

Immunologi

Immunology

Immunologi