Construction and characterization of a quadruplex DNA selective single-chain autoantibody from a viable motheaten mouse hybridoma with homology to telomeric DNA binding proteins

Balancing act: BRCA2's elaborate management of telomere replication through control of G-quadruplex dynamicity

In billion years of evolution, eukaryotes preserved the chromosome ends with arrays of guanine repeats surrounded by thymines and adenines, which can form stacks of four-stranded planar structure known as G-quadruplex (G4). The rationale behind the evolutionary conservation of the G4 structure at the telomere remained elusive. Our recent study has shed light on this matter by revealing that telomere G4 undergoes oscillation between at least two distinct folded conformations. Additionally, tumor suppressor BRCA2 exhibits a unique mode of interaction with telomere G4. To elaborate, BRCA2 directly interacts with G-triplex (G3)-derived intermediates that form during the interconversion of the two different G4 states. In doing so, BRCA2 remodels the G4, facilitating the restart of stalled replication forks. In this review, we succinctly summarize the findings regarding the dynamicity of telomeric G4, emphasize its importance in maintaining telomere replication homeostasis, and the physiological consequences of losing G4 dynamicity at the telomere.

Detection of alternative DNA structures and its implications for human disease

Around 3% of the genome consists of simple DNA repeats that are prone to forming alternative (non-B) DNA structures, such as hairpins, cruciforms, triplexes (H-DNA), four-stranded guanine quadruplexes (G4-DNA), and others, as well as composite RNA:DNA structures (e.g., R-loops, G-loops, and H-loops). These DNA structures are dynamic and favored by the unwinding of duplex DNA. For many years, the association of alternative DNA structures with genome function was limited by the lack of methods to detect them in vivo. Here, we review the recent advancements in the field and present state-of-the-art technologies and methods to study alternative DNA structures. We discuss the limitations of these methods as well as how they are beginning to provide insights into causal relationships between alternative DNA structures, genome function and stability, and human disease.

Detection of G-quadruplex DNA in mammalian cells

It has been proposed that guanine-rich DNA forms four-stranded structures in vivo called G-quadruplexes or G4 DNA. G4 DNA has been implicated in several biological processes, but tools to study G4 DNA structures in cells are limited. Here we report the development of novel murine monoclonal antibodies specific for different G4 DNA structures. We show that one of these antibodies designated 1H6 exhibits strong nuclear staining in most human and murine cells. Staining intensity increased on treatment of cells with agents that stabilize G4 DNA and, strikingly, cells deficient in FANCJ, a G4 DNA-specific helicase, showed stronger nuclear staining than controls. Our data strongly support the existence of G4 DNA structures in mammalian cells and indicate that the abundance of such structures is increased in the absence of FANCJ. We conclude that monoclonal antibody 1H6 is a valuable tool for further studies on the role of G4 DNA in cell and molecular biology.

Non-B DNA structure-induced genetic instability and evolution

Repetitive DNA motifs are abundant in the genomes of various species and have the capacity to adopt non-canonical (i.e., non-B) DNA structures. Several non-B DNA structures, including cruciforms, slipped structures, triplexes, G-quadruplexes, and Z-DNA, have been shown to cause mutations, such as deletions, expansions, and translocations in both prokaryotes and eukaryotes. Their distributions in genomes are not random and often co-localize with sites of chromosomal breakage associated with genetic diseases. Current genome-wide sequence analyses suggest that the genomic instabilities induced by non-B DNA structure-forming sequences not only result in predisposition to disease, but also contribute to rapid evolutionary changes, particularly in genes associated with development and regulatory functions. In this review, we describe the occurrence of non-B DNA-forming sequences in various species, the classes of genes enriched in non-B DNA-forming sequences, and recent mechanistic studies on DNA structure-induced genomic instability to highlight their importance in genomes.

Molecular expression systems for anti-DNA antibodies--2

Antibodies to double-stranded DNA are the best-known serological markers of systemic lupus erythematosus, and are closely associated with its renal pathogenesis. How these antibodies recognize DNA is not fully understood. An understanding of the relationship between the functional attributes of an antibody with the three-dimensional structure of its antigen-combining site would allow an insight into the rules that dictate auto-antibody-nucleic acid interaction and consequent pathogenicity of the autoantibody. Data from such studies could assist the development of novel drugs as an approach to specific therapies that can inhibit or disrupt protein-nucleic acid interactions. A full understanding of the binding specificities can be achieved only by experimental determination of detailed three-dimensional structure of these antibodies alone, and of their complexes with specific DNA antigens. A prerequisite of such a study is the ability to produce multimilligram quantities of the antibody protein. However, these antibodies are particularly difficult to express, probably due to their DNA-binding activity. This review attempts to focus on the recent developments on the over-expression of anti-DNA antibody fragments in heterologous cell expression systems and their purification to homogeneity that would in turn allow their structural studies via crystallization.

Minimal structural elements of an inhibitory anti-ATF1/CREB single-chain antibody fragment (scFv41.4)

Antibody variable domains represent potential structural models for the rational design of therapeutic molecules that bind cellular proteins with high affinity and specificity. The Activating Transcription Factor 1 (ATF1)/Cyclic AMP Response Element Binding Protein (CREB) family of transcription factors are particularly relevant targets due to their strong association with melanoma and clear cell sarcoma. Biochemical and structural investigations were performed to optimize a single-chain antibody fragment (scFv), scFv41.4, that disrupts the binding of ATF1/CREB to cyclic-AMP response elements (CRE) in vitro and inhibits transcriptional activation in cells. Molecular modeling and ligand docking simulations suggested that scFv41.4 could function as a disulfide-deficient single domain scFv. Functional studies verified that deletion of the light chain did not result in reduced inhibitory activity. The isolated heavy chain was predicted to assume a relaxed structural conformation that maintained a functional antigen binding pocket. The minimal structural elements necessary for intracellular function were further analyzed by selective deletion of CDR1 and CDR2. V(H)-CDR1 and V(H)-CDR3 were shown to play a key role in antigen binding activity, but V(H)-CDR2 was dispensable. Thus, scFv41.4 represents a unique molecule with potential for use in the design of peptidomimetic derivatives having therapeutic application to human cancer.

Specificity and diversity of antibodies to Mycobacterium tuberculosis arabinomannan

Arabinomannan (AM) is a polysaccharide antigen of the mycobacterial capsule. However, it is uncertain whether AM constitutes an immunologically distinct fraction of Mycobacterium tuberculosis. In this study, we analyzed the repertoire and specificity of antibodies to AM by using AM-binding murine monoclonal antibodies (MAbs) and human serum samples. Murine MAbs were found to be diverse in their specificity to AM and cross-reactivity with other arabinose-containing mycobacterial polysaccharides, with MAb 9d8 binding exclusively to AM. Human antibodies to AM were detected in serum samples from patients with pulmonary tuberculosis (TB), as well as in those from healthy, purified protein derivative-negative controls, with significantly higher titers among patients. The binding of human antibodies to AM was inhibited by MAb 9d8 in three patients with TB but not in controls. MAb 5c11, which recognizes other mycobacterial arabinose-containing carbohydrates in addition to AM, inhibited the binding of serum samples from 75% of patients and 76% of controls. Analysis of human antibodies with murine MAbs to human V(H) determinants demonstrated diversity among antibodies to AM with qualitative and quantitative differences compared with antibodies to lipoarabinomannan. In summary, our study suggests that antibodies to AM are diverse and heterogeneous with respect to antigen recognition and V(H) determinant expression, with human serum samples containing different subsets of antibodies to AM with the specificities of AM-binding murine MAbs. One MAb and a subset of human antibodies bind AM specifically, suggesting that this polysaccharide is antigenically distinct and is expressed in human infection.

Biological aspects of DNA/RNA quadruplexes

Among the many unusual conformations of DNA and RNA, quadruplex structures, based on the guanine quartet, possess several unique properties. These properties, along with the general features of guanine quadruplexes, are described in the context of possible roles for these structures in biological systems. A variety of experimental observations supporting the notion that quadruplexes are important in vivo is presented, including proteins known to specifically bind to quadruplex structures, guanine-rich DNA, and RNA sequences endowed with the potential for forming quartet-based structures in telomeres and regulatory regions, such as gene promoters, quadruplexes as DNA aptamer folding motifs arising from in vitro selection experiments, and potential chemotherapeutic, quadruplex-forming oligonucleotides. Taken together, all of these observations argue cogently not only for the presence of quadruplexes in biological systems but also for their significance in terms of their roles in various biological processes.

Two Tetrahymena G-DNA-binding proteins, TGP1 and TGP3, share novel motifs and may play a role in micronuclear division

G-DNA is a four-stranded DNA structure with diverse putative biological roles. We have previously purified and cloned a novel G-DNA-binding protein TGP1 from the ciliate Tetrahymena thermophila. Here we report the molecular cloning of TGP3, an additional G-DNA-binding protein from the same organism. The TGP3 cDNA encodes a 365 amino acid protein that is homologous to TGP1 (34% identity and 44% similarity). The proteins share a sequence pattern that contains two novel repetitive and homologous motifs flanking an extensively hydrophilic and basic region. A nuclear fractionation experiment showed that TGP1 and TGP3 activities are localized predominantly in the nuclear fraction. To further investigate the biological roles of the proteins in vivo, we have generated separate macronuclear gene knockout (KO) strains (TGP1KO and TGP3KO) for each of the two genes. Southern blot analysis demonstrated that the macronuclear copies of each gene were completely disrupted. Mobility shift assays showed that the corresponding G-DNA-binding activity for each protein was abolished in the KO strains. Growth analysis showed that both KO strains grew at near wild-type rates, indicating that neither of the genes is essential for cell growth. Nevertheless, nuclear staining analysis revealed that both TGP1KO and TGP3KO cells have an increased occurrence (more than 2-fold) of extra micronuclei, implying faulty control of micronuclear division in the KO cells.

Tandem affinity tags for the purification of bivalent anti-DNA single-chain Fv expressed in Escherichia coli

Antibodies to DNA define an important autospecificity that arises in systemic lupus erythematosus (SLE). To elucidate the molecular features that may explain the pathogenesis of SLE, a heterologous system for expression of cloned V genes is often desirable. Here, a single-chain Fv coding domain was constructed by using the heavy- and light-chain V genes of a high-affinity site-directed mutant of the murine anti-dsDNA autoantibody, 3H9. This scFv was joined in frame to the c-jun leucine zipper for dimerization, and to two affinity tags, domain B of the staphylococcal protein A and a pentahistidine peptide, for purification. Dimerization of the scFv was determined by size-exclusion chromatography. The yields of the scFv following affinity purification on IgG agarose or Ni-NTA agarose were compared, and the activities of the resulting protein fractions were determined. A two-step purification of periplasmic extracts on Ni-NTA agarose and IgG agarose, followed by elution with 3.5 M MgCl(2), yielded scFv with the highest specific activity. The final purified material bound DNA by ELISA, electrophoretic mobility shift assay, and immunofluorescence of fixed Hep-2 cells. Antibodies purified in this fashion should have applications in structure/function studies in which it is essential to generate highly purified antigen-combining sites.