DNA Architectural Protein Research Articles

Single-molecule FRET investigation of binding and the comparative effect of DNA architectural proteins on Holliday junction conformational dynamics

Single-molecule FRET investigation of binding and the comparative effect of DNA architectural proteins on Holliday junction conformational dynamics

DNA architectural protein CTCF facilitates subset-specific chromatin interactions to limit the formation of memory CD8+ T cells

Although the importance of genome organization for transcriptional regulation of cell-fate decisions and function is clear, the changes in chromatin architecture and how these impact effector and memory CD8+ Tcell differentiation remain unknown. Using Hi-C, we studied how genome configuration is integrated with CD8+ Tcell differentiation during infection and investigated the role of CTCF, a key chromatin remodeler, in modulating CD8+ Tcell fates through CTCF knockdown approaches and perturbation of specific CTCF-binding sites. We observed subset-specific changes in chromatin organization and CTCF binding and revealed that weak-affinity CTCF binding promotes terminal differentiation of CD8+ Tcells through the regulation of transcriptional programs. Further, patients with de novo CTCF mutations had reduced expression of the terminal-effector genes in peripheral blood lymphocytes. Therefore, in addition to establishing genome architecture, CTCF regulates effector CD8+ Tcell heterogeneity through altering interactions that regulate the transcription factor landscape and transcriptome.

Nucleus size and its effect on nucleosome stability in living cells

DNA architectural proteins play a major role in organization of chromosomal DNA in living cells by packaging it into chromatin, whose spatial conformation is determined by an intricate interplay between the DNA-binding properties of architectural proteins and physical constraints applied to the DNA by a tight nuclear space. Yet, the exact effects of the nucleus size on DNA-protein interactions and chromatin structure currently remain obscure. Furthermore, there is even no clear understanding of molecular mechanisms responsible for the nucleus size regulation in living cells. To find answers to these questions, we developed a general theoretical framework based on a combination of polymer field theory and transfer-matrix calculations, which showed that the nucleus size is mainly determined by the difference between the surface tensions of the nuclear envelope and the endoplasmic reticulum membrane as well as the osmotic pressure exerted by cytosolic macromolecules on the nucleus. In addition, the model demonstrated that the cell nucleus functions as a piezoelectric element, changing its electrostatic potential in a size-dependent manner. This effect has been found to have a profound impact on stability of nucleosomes, revealing a previously unknown link between the nucleus size and chromatin structure. Overall, our study provides new insights into the molecular mechanisms responsible for regulation of the nucleus size, as well as the potential role of nuclear organization in shaping the cell response to environmental cues.

DNA-binding proteins studied by mechanical manipulation and AFM imaging of single DNA molecules.

The functions of DNA-binding proteins are dependent on protein-induced DNA distortion, the binding preference to special sequences, DNA secondary structures, the binding kinetics and the binding affinity. Recent rapid progress in single-molecule imaging and mechanical manipulation technologies have made it possible to directly probe the DNA binding by proteins, footprint the positions of the bound proteins on DNA, quantify the kinetics and the affinity of protein-DNA interactions, and study the interplay of protein binding with DNA conformation and DNA topology. Here, we review the applications of an integrated approach where the single-DNA imaging using atomic force microscopy and the mechanical manipulation of single DNA molecules are combined to study the DNA-protein interactions. We also provide our views on how these findings yield new insights into understanding the roles of several essential DNA architectural proteins.

The extracellular innate-immune effector HMGB1 limits pathogenic bacterial biofilm proliferation.

Herein, we describe an extracellular function of the vertebrate high-mobility group box 1 protein (HMGB1) in the proliferation of bacterial biofilms. Within host cells, HMGB1 functions as a DNA architectural protein, similar to the ubiquitous DNABII family of bacterial proteins; despite that, these proteins share no amino acid sequence identity. Extracellularly, HMGB1 induces a proinflammatory immune response, whereas the DNABII proteins stabilize the extracellular DNA-dependent matrix that maintains bacterial biofilms. We showed that when both proteins converged on extracellular DNA within bacterial biofilms, HMGB1, unlike the DNABII proteins, disrupted biofilms both in vitro (including the high-priority ESKAPEE pathogens) and in vivo in 2 distinct animal models, albeit with induction of a strong inflammatory response that we attenuated by a single engineered amino acid change. We propose a model where extracellular HMGB1 balances the degree of induced inflammation and biofilm containment without excessive release of biofilm-resident bacteria.

HMGA2 as a Critical Regulator in Cancer Development.

The high mobility group protein 2 (HMGA2) regulates gene expression by binding to AT-rich regions of DNA. Akin to other DNA architectural proteins, HMGA2 is highly expressed in embryonic stem cells during embryogenesis, while its expression is more limited at later stages of development and in adulthood. Importantly, HMGA2 is re-expressed in nearly all human malignancies, where it promotes tumorigenesis by multiple mechanisms. HMGA2 increases cancer cell proliferation by promoting cell cycle entry and inhibition of apoptosis. In addition, HMGA2 influences different DNA repair mechanisms and promotes epithelial-to-mesenchymal transition by activating signaling via the MAPK/ERK, TGFβ/Smad, PI3K/AKT/mTOR, NFkB, and STAT3 pathways. Moreover, HMGA2 supports a cancer stem cell phenotype and renders cancer cells resistant to chemotherapeutic agents. In this review, we discuss these oncogenic roles of HMGA2 in different types of cancers and propose that HMGA2 may be used for cancer diagnostic, prognostic, and therapeutic purposes.

Epigenetic regulation of white adipose tissue in the onset of obesity and metabolic diseases.

Obesity and metabolic syndrome are among the most prevalent health problems in developed countries. The impairment of adipose tissue (AT) function is partially responsible for the aetiology of these conditions. Epigenetics refers to several processes that add modifications to either the DNA or chromatin architectural proteins (histones). These processes can regulate gene expression, chromatin compaction and DNA repair. Epigenetics includes mechanisms by which the cell can adapt the cellular response to the environmental conditions. Here, we review the role of epigenetics in the onset of obesity and related metabolic disorders, with special focus on AT. We highlight the importance of nutrients and lifestyle in the regulation of the epigenetic mechanisms and how they can impact on AT plasticity and function in obesity and metabolic diseases. Thus, the epigenetic landscape emerges as a fine-tune regulator of the cellular responses according to the energetic, metabolic and physiological conditions of the cell. Alterations in metabolic pathways deregulated during obesity and metabolic syndrome could in part explain the disturbances in the epigenetic marks of the AT in these disorders. The understanding of how this epigenetic deregulation may affect AT biology and function could lead to new therapeutic approaches based on epigenetic strategies.

Proteome of HU-Lacking E. coli Studied by Means of 2D Gel Electrophoresis

Histone-like protein HU is a dimeric nucleoid-associated protein (NAP). HU is the most conserved NAP. It binds nonspecifically to duplex DNA with a preference for targeting nicked and bent DNA. HU limits the architecture of the bacterial nucleoid and its deletion is lethal for Bacillus subtilis and Mycoplasma genitalium which do not contain other NAPs. E. coli lacking HU is viable but has numerous growth defects. The effects of the HU protein on gene expression is known from microarray analysis and HU regulons were identified. In HU-deficient E. coli, absence of this DNA architectural protein causes a disorder in gene regulation; on the other hand, E. coli growth under standard conditions is almost unaltered in the absence of HU. To understand how the bacterium confronts the chromosomal disorder, we performed proteome analysis to compare protein abundances in cells containing the HU protein or not. Comparison of the proteomic profile of wild-type and HU-deficient E. coli shows how the altered gene expression influences the protein content. We show that proteome profile changes are very similar to the gene expression profile changes in HU-deficient E. coli. Several exceptions show that proteome studies are very important.

Cooperative DNA binding by proteins through DNA shape complementarity.

Localized arrays of proteins cooperatively assemble onto chromosomes to control DNA activity in many contexts. Binding cooperativity is often mediated by specific protein–protein interactions, but cooperativity through DNA structure is becoming increasingly recognized as an additional mechanism. During the site-specific DNA recombination reaction that excises phage λ from the chromosome, the bacterial DNA architectural protein Fis recruits multiple λ-encoded Xis proteins to the attR recombination site. Here, we report X-ray crystal structures of DNA complexes containing Fis + Xis, which show little, if any, contacts between the two proteins. Comparisons with structures of DNA complexes containing only Fis or Xis, together with mutant protein and DNA binding studies, support a mechanism for cooperative protein binding solely by DNA allostery. Fis binding both molds the minor groove to potentiate insertion of the Xis β-hairpin wing motif and bends the DNA to facilitate Xis-DNA contacts within the major groove. The Fis-structured minor groove shape that is optimized for Xis binding requires a precisely positioned pyrimidine-purine base-pair step, whose location has been shown to modulate minor groove widths in Fis-bound complexes to different DNA targets.

Reconstitution of CRISPR adaptation in vitro and its detection by PCR.

CRISPR adaptation is the initial step in CRISPR-Cas immunity and involves the acquisition of foreign invading DNA. Acquisition is facilitated by the almost universally conserved proteins Cas1 and Cas2, which form an adaptation complex. The Cas1-Cas2 complex binds fragments of invading DNA, completes final processing, and catalyzes integration into specific host loci called CRISPR arrays. Structural and biochemical studies from reconstituted complexes have provided mechanistic insight into how CRISPR adaptation occurs; however, these studies have been limited to a narrow subset of CRISPR-Cas types and may not be representative of the other types. Here we describe methods for the purification of the type I-F CRISPR adaptation complex (Cas1:Cas2-3) from Pectobacterium atrosepticum, purification of the DNA architectural protein integration host factor (IHF), and a sensitive PCR-based in vitro integration assay. This assay could easily be used to investigate mechanisms of CRISPR adaptation in other CRISPR-Cas systems, including the roles of accessory proteins.

High mobility group proteins: the multifaceted regulators of chromatin dynamics

DNA super-coiling and architectural proteins are the key players that maintain the chromatin in its compact state. Genomic DNA needs to be packaged such that it takes minimum space and can simultaneously be accessed for various DNA dependent processes. Architectural proteins are instrumental in organizing the dynamic higher order chromatin structure by effectuating a concerted effort among themselves and other nuclear proteins across spatio-temporal scales. The regulation of these proteins and their interaction with DNA modify the cellular phenotype by the modulation of gene expression. This review focuses on the structure–function relationship of three broad families of High mobility groups (HMGs) of protein, namely HMGA, HMGN and HMG-Box which are major chromatin architectural components of the eukaryotes. These nuclear elements not only act as architectural proteins but also play a multifaceted role in chromatin dynamics by facilitating interaction with nucleosomes, nucleosome-remodeling machines, transcription factors and histones.

Molecularly-Targeted Therapy of Spinocerebellar Ataxia Type 1 by HMGB1

Spinocerebellar ataxia type 1 (SCA1) is an untreatable neurodegenerative disease. We reported a decrease in HMGB1 levels in the nucleus of cerebellar neurons in mouse SCA 1. The decrease in this DNA architectural protein leads to the impairment of DNA repair and transcription, the two essential nuclear functions, and eventually causes neurodegeneration. We have designed a gene therapy using AAV-HMGB1 and tested it using the mouse model. Based on the results of these proof of concept (POC) studies, we are now preparing GMP-level AAV vector and designing human clinical trials.

Theoretical Methods for Studying DNA Structural Transitions under Applied Mechanical Constraints.

Recent progress in single-molecule manipulation technologies has made it possible to exert force and torque on individual DNA biopolymers to probe their mechanical stability and interaction with various DNA-binding proteins. It was revealed in these experiments that the DNA structure and formation of nucleoprotein complexes by DNA-architectural proteins can be strongly modulated by an intricate interplay between the entropic elasticity of DNA and its global topology, which is closely related to the mechanical constraints applied to the DNA. Detailed understanding of the physical processes underlying the DNA behavior observed in single-molecule experiments requires the development of a general theoretical framework, which turned out to be a rather challenging task. Here, we review recent advances in theoretical methods that can be used to interpret single-molecule manipulation experiments on DNA.

Modulation of DNA-Biding Properties of Euryarchaeal Architectural Proteins by MG2+ Ions Triggers Drastic Changes in the Global DNA Organization

DNA-architectural proteins play a major role in the cell genome organization, packaging DNA into a highly ordered chromatin structure inside living cells. It has been previously shown that the conformation of this structure can be very sensitive to surrounding conditions. This way, DNA-architectural proteins not only help to preserve integrity of the chromosomal DNA but also actively participate in the regulation of the cells’ behaviour via modulation of the global gene expression profile in response to environmental cues. Recent experimental studies have provided a lot of useful insights into possible biological functions of individual architectural proteins. However, there is still a large gap in understanding of molecular mechanisms underlying the emergent collective behaviour of these proteins in DNA organization and gene transcription regulation, which is especially the case for archaea cells, whose genome organization remains much less understood comparing to eukaryotic and bacterial cells. Here we report a single-molecule study of the DNA-binding properties of the three major architectural proteins (Alba, histones and TrmBL2), which have been recently identified in model euryarchaeon T. kodakarensis. Using single-DNA manipulation assays, we show how the interplay between physicochemical characteristics of each of these architectural proteins and the global DNA topology lead to very intricate regulation of the DNA organization, explaining high plasticity of the nucleoid structure in archaeal cells. It was found that DNA-binding competition among Alba, TrmBL2 and histone proteins results in a delicate balance between the DNA open (extended) and closed (collapsed) conformations, which can be shifted to one or the other side via slight changes in the proteins stochiometry, Mg2+ concentration in solution or the DNA supercoiling level. These findings provide important insights into the potential molecular mechanisms accountable for the modulation of the nucleoid structure and the global gene expression profile in archaeal cells in response to environmental changes.

Transcriptional Repressor TrmBL2 from Thermococcus kodakarensis Forms Filamentous Nucleoprotein Structures and Competes with Histones for DNA Binding in a Salt- and DNA Supercoiling-dependent Manner

Architectural DNA proteins play important roles in the chromosomal DNA organization and global gene regulation in living cells. However, physiological functions of some DNA-binding proteins from archaea remain unclear. Recently, several abundant DNA-architectural proteins including histones, Alba, and TrmBL2 have been identified in model euryarchaeon Thermococcus kodakarensis. Although histones and Alba proteins have been previously characterized, the DNA binding properties of TrmBL2 and its interplay with the other major architectural proteins in the chromosomal DNA organization and gene transcription regulation remain largely unexplored. Here, we report single-DNA studies showing that at low ionic strength (<300 mM KCl), TrmBL2 binds to DNA largely in non-sequence-specific manner with positive cooperativity, resulting in formation of stiff nucleoprotein filamentous patches, whereas at high ionic strength (>300 mM KCl) TrmBL2 switches to more sequence-specific interaction, suggesting the presence of high affinity TrmBL2-filament nucleation sites. Furthermore, in vitro assays indicate the existence of DNA binding competition between TrmBL2 and archaeal histones B from T. kodakarensis, which can be strongly modulated by DNA supercoiling and ionic strength of surrounding solution. Overall, these results advance our understanding of TrmBL2 DNA binding properties and provide important insights into potential functions of architectural proteins in nucleoid organization and gene regulation in T. kodakarensis.

Chromosomal "stress-response" domains govern the spatiotemporal expression of the bacterial virulence program.

ABSTRACTRecent studies strongly suggest that the gene expression sustaining both normal and pathogenic bacterial growth is governed by the structural dynamics of the chromosome. However, the mechanistic device coordinating the chromosomal configuration with selective expression of the adaptive traits remains largely unknown. We used a holistic approach exploring the inherent relationships between the physicochemical properties of the DNA and the expression of adaptive traits, including virulence factors, in the pathogen Dickeya dadantii (formerly Erwinia chrysanthemi). In the transcriptomes obtained under adverse conditions encountered during bacterial infection, we explored the patterns of chromosomal DNA sequence organization, supercoil dynamics, and gene expression densities, together with the long-range regulatory impacts of the abundant DNA architectural proteins implicated in pathogenicity control. By integrating these data, we identified transient chromosomal domains of coherent gene expression featuring distinct couplings between DNA thermodynamic stability, supercoil dynamics, and virulence traits.

Site-specific DNA Inversion by Serine Recombinases.

Reversible site-specific DNA inversion reactions are widely distributed in bacteria and their viruses. They control a range of biological reactions that most often involve alterations of molecules on the surface of cells or phage. These programmed DNA rearrangements usually occur at a low frequency, thereby preadapting a small subset of the population to a change in environmental conditions, or in the case of phages, an expanded host range. A dedicated recombinase, sometimes with the aid of additional regulatory or DNA architectural proteins, catalyzes the inversion of DNA. RecA or other components of the general recombination-repair machinery are not involved. This chapter discusses site-specific DNA inversion reactions mediated by the serine recombinase family of enzymes and focuses on the extensively studied serine DNA invertases that are stringently controlled by the Fis-bound enhancer regulatory system. The first section summarizes biological features and general properties of inversion reactions by the Fis/enhancer-dependent serine invertases and the recently described serine DNA invertases in Bacteroides. Mechanistic studies of reactions catalyzed by the Hin and Gin invertases are then discussed in more depth, particularly with regards to recent advances in our understanding of the function of the Fis/enhancer regulatory system, the assembly of the active recombination complex (invertasome) containing the Fis/enhancer, and the process of DNA strand exchange by rotation of synapsed subunit pairs within the invertasome. The role of DNA topological forces that function in concert with the Fis/enhancer controlling element in specifying the overwhelming bias for DNA inversion over deletion and intermolecular recombination is emphasized.

TrmBL2 Protein from Thermococcus Kodakarensis Competes with Histones for DNA Binding and Forms Filamentous Nucleoprotein Complexes that Affect DNA Structural State

Architectural DNA proteins play important roles in the genome organization and maintenance of its functionality in living cells. During past years DNA binding properties of different architectural proteins from bacterial and eukaryotic cells were extensively investigated. However, physiological functions of some DNA-architectural proteins from archaeal cells still remain unclear. Recently, several abundant DNA-architectural proteins including histones, Alba, and TrmBL2 have been identified in model euryarchaeon T. kodakarensis. While histones and Alba proteins have been characterized in detail, the DNA-binding properties of TrmBL2 remain largely unexplored. Here, we report single-DNA studies showing that TrmBL2 binds to DNA with positive cooperativity, resulting in formation of rigid nucleoprotein filaments. Our results indicate that polymerization of such filaments on DNA reduces with increasing ionic strength of solution due to the electrostatic screening of TrmBL2 non-specific binding to DNA, which is nearly abolished at > 300 mM KCl. Yet, patches of DNA covered by TrmBL2 can be seen on AFM images even at large salt concentrations, suggesting presence of high affinity TrmBL2-filament nucleation DNA sequences. Further DNA footprint analysis revealed that TrmBL2 preferentially interacts with G/C-rich sequences, similar to archaeal histones, thus, suggesting existence of TrmBL2-histone binding competition to overlapping DNA segments. This observation is supported by competitive binding assay, showing that TrmBL2 and archaeal histones indeed mutually occlude each other for DNA binding. Finally, DNA twisting experiments showed that TrmBL2-filaments weaken formation of positively supercoiled plectonemes during DNA winding and promote DNA transition into negatively supercoiled Z/L-state during unwinding. Taken together, these results advance our understanding of TrmBL2 DNA-binding properties and provide important insights into its potential functions in nucleoid organization and gene regulation in hyperthermophilic euryarchaea cells.

A protein ballet around the viral genome orchestrated by HIV-1 reverse transcriptase leads to an architectural switch: From nucleocapsid-condensed RNA to Vpr-bridged DNA

HIV-1 reverse transcription is achieved in the newly infected cell before viral DNA (vDNA) nuclear import. Reverse transcriptase (RT) has previously been shown to function as a molecular motor, dismantling the nucleocapsid complex that binds the viral genome as soon as plus-strand DNA synthesis initiates. We first propose a detailed model of this dismantling in close relationship with the sequential conversion from RNA to double-stranded (ds) DNA, focusing on the nucleocapsid protein (NCp7). The HIV-1 DNA-containing pre-integration complex (PIC) resulting from completion of reverse transcription is translocated through the nuclear pore. The PIC nucleoprotein architecture is poorly understood but contains at least two HIV-1 proteins initially from the virion core, namely integrase (IN) and the viral protein r (Vpr). We next present a set of electron micrographs supporting that Vpr behaves as a DNA architectural protein, initiating multiple DNA bridges over more than 500 base pairs (bp). These complexes are shown to interact with NCp7 bound to single-stranded nucleic acid regions that are thought to maintain IN binding during dsDNA synthesis, concurrently with nucleocapsid complex dismantling. This unexpected binding of Vpr conveniently leads to a compacted but filamentous folding of the vDNA that should favor its nuclear import. Finally, nucleocapsid-like aggregates engaged in dsDNA synthesis appear to efficiently bind to F-actin filaments, a property that may be involved in targeting complexes to the nuclear envelope. More generally, this article highlights unique possibilities offered by in vitro reconstitution approaches combined with macromolecular imaging to gain insights into the mechanisms that alter the nucleoprotein architecture of the HIV-1 genome, ultimately enabling its insertion into the nuclear chromatin.

Single-Molecule Spectroscopic Study of Dynamic Nanoscale DNA Bending Behavior of HIV-1 Nucleocapsid Protein

We have studied the conformational dynamics associated with the nanoscale DNA bending induced by human immunodeficiency virus type 1 (HIV-1) nucleocapsid (NC) protein using single-molecule Förster resonance energy transfer (SM-FRET). To gain molecular-level insights into how the HIV-1 NC locally distorts the structures of duplexed DNA segments, the dynamics, reversibility, and sequence specificity of the DNA bending behavior of NC have been systematically studied. We have performed SM-FRET measurements on a series of duplexed DNA segments with varying sequences, lengths, and local structures in the presence of the wide-type HIV-1 NC and NC mutants lacking either the basic N-terminal domain or the zinc fingers. On the basis of the SM-FRET results, we have proposed a possible mechanism for the NC-induced DNA bending in which both NC's zinc fingers and N-terminal domain are found to play crucial roles. The SM-FRET results reported here add new mechanistic insights into the biological behaviors and functions of HIV-1 NC as a retroviral DNA-architectural protein which may play critical roles in the compaction, nuclear import, and integration of the proviral DNA during the retroviral life cycle.