Understanding the effect of the nature of the nucleobase in the loops on the stability of the i-motif structure

The nature and the length of loops connecting cytosine tracts in i-motif structures may affect their stability. In this work, the influence of the nature of the nucleobases located in two of the loops of an intramolecular i-motif is studied using spectroscopy, separation techniques, and multivariate data analysis. The insertion of bases other than thymine induces an additional acid-base equilibrium with pKa ∼ 4.5. The presence of two guanine bases in the loops, placed opposite to each other, decreases the thermal stability of the structure. In contrast, thymine and cytosine bases in these positions stabilize the structure. © the Owner Societies 2016.Anna Sadurnı´ (University of Barcelona) is acknowledged for carrying out some experiments. We acknowledge funding from the Spanish government (BFU2014-52864-R, CTQ2012-38616- C02-02 and CTQ2014-52588-R). This research has been recognized by the regional Catalan authorities (2014 SGR 1106).Peer reviewe

Understanding the effect of the nature of the nucleobase in the loops on the stability of the i-motif structure

The nature and length of loops connecting cytosine tracts in i-motif structures may affect their stability. In this work, the influence of the nature of the nucleobases located in two of the loops of an intramolecular i-motif is studied using spectroscopy, separation techniques, and multivariate data analysis. Insertion of bases other than thymine induces an additional acid-base equilibrium with pKa~4.5. The presence of two guanine bases in the loops, placed opposite to each other, decreases the thermal stability of the structure. In contrast, thymine and cytosine bases in these positions stabilize the structur

DNA structure directs positioning of the mitochondrial genome packaging protein Abf2p.

The mitochondrial genome (mtDNA) is assembled into nucleo-protein structures termed nucleoids and maintained differently compared to nuclear DNA, the involved molecular basis remaining poorly understood. In yeast (Saccharomyces cerevisiae), mtDNA is a ∼80 kbp linear molecule and Abf2p, a double HMG-box protein, packages and maintains it. The protein binds DNA in a non-sequence-specific manner, but displays a distinct 'phased-binding' at specific DNA sequences containing poly-adenine tracts (A-tracts). We present here two crystal structures of Abf2p in complex with mtDNA-derived fragments bearing A-tracts. Each HMG-box of Abf2p induces a 90° bend in the contacted DNA, causing an overall U-turn. Together with previous data, this suggests that U-turn formation is the universal mechanism underlying mtDNA compaction induced by HMG-box proteins. Combining this structural information with mutational, biophysical and computational analyses, we reveal a unique DNA binding mechanism for Abf2p where a characteristic N-terminal flag and helix are crucial for mtDNA maintenance. Additionally, we provide the molecular basis for A-tract mediated exclusion of Abf2p binding. Due to high prevalence of A-tracts in yeast mtDNA, this has critical relevance for nucleoid architecture. Therefore, an unprecedented A-tract mediated protein positioning mechanism regulates DNA packaging proteins in the mitochondria, and in combination with DNA-bending and U-turn formation, governs mtDNA compaction

i-motif structures in long cytosine-rich sequences found upstream of the promoter region of the SMARCA4 gen

Cytosine-rich oligonucleotides are capable of forming complex structures known as i-motif with increasingly studied biological properties. The study of sequences prone to form i-motifs located near the promoter region of genes may be difficult because these sequences not only contain repeats of cytosine tracts of disparate length but also these may be separated by loops of varied nature and length. In this work, the formation of an intramolecular i-motif structures by a long sequence located upstream of the promoter region of the SMARCA4 gene has been demonstrated. Nuclear Magnetic Resonance, Circular Dichroism, Gel Electrophoresis, Size-Exclusion Chromatography, and multivariate analysis have been used. Not only the wild sequence (5'-TC3T2GCTATC3TGTC2TGC2TCGC3T2G2TCATGA2C4-3') has been studied but also several other truncated and mutated sequences. Despite the apparent complex sequence, the results showed that the wild sequence may form a relatively stable and homogeneous unimolecular i-motif structure, both in terms of pH or temperature. The model ligand TMPyP4 destabilizes the structure, whereas the presence of 20% (w/v) PEG200 stabilized it slightly. This finding opens the door to the study of the interaction of these kind of i-motif structures with stabilizing ligands or proteins

The human mitochondrial transcription factor A is a versatile G-quadruplex binding protein

The ability of the guanine-rich strand of the human mitochondrial DNA (mtDNA) to form G-quadruplex structures (G4s) has been recently highlighted, suggesting potential functions in mtDNA replication initiation and mtDNA stability. G4 structures in mtDNA raise the question of their recognition by factors associated with the mitochondrial nucleoid. The mitochondrial transcription factor A (TFAM), a highmobility group (HMG)-box protein, is the major binding protein of human mtDNA and plays a critical role in its expression and maintenance. HMG-box proteins are pleiotropic sensors of DNA structural alterations. Thus, we investigated and uncovered a surprising ability of TFAM to bind to DNA or RNA G4 with great versatility, showing an affinity similar than to double-stranded DNA. The recognition of G4s by endogenous TFAM was detected in mitochondrial extracts by pull-down experiments using a G4-DNA from the mtDNA conserved sequence block II (CSBII). Biochemical characterization shows that TFAM binding to G4 depends on both the G-quartets core and flanking single-stranded overhangs. Additionally, it shows a structure-specific binding mode that differs from B-DNA, including G4- dependent TFAM multimerization. These TFAM-G4 interactions suggest functional recognition of G4s in the mitochondria

HIV-1 Protease and Reverse Transcriptase Control the Architecture of Their Nucleocapsid Partner

The HIV-1 nucleocapsid is formed during protease (PR)-directed viral maturation, and is transformed into pre-integration complexes following reverse transcription in the cytoplasm of the infected cell. Here, we report a detailed transmission electron microscopy analysis of the impact of HIV-1 PR and reverse transcriptase (RT) on nucleocapsid plasticity, using in vitro reconstitutions. After binding to nucleic acids, NCp15, a proteolytic intermediate of nucleocapsid protein (NC), was processed at its C-terminus by PR, yielding premature NC (NCp9) followed by mature NC (NCp7), through the consecutive removal of p6 and p1. This allowed NC co-aggregation with its single-stranded nucleic-acid substrate. Examination of these co-aggregates for the ability of RT to catalyse reverse transcription showed an effective synthesis of double-stranded DNA that, remarkably, escaped from the aggregates more efficiently with NCp7 than with NCp9. These data offer a compelling explanation for results from previous virological studies that focused on i) Gag processing leading to nucleocapsid condensation, and ii) the disappearance of NCp7 from the HIV-1 pre-integration complexes. We propose that HIV-1 PR and RT, by controlling the nucleocapsid architecture during the steps of condensation and dismantling, engage in a successive nucleoprotein-remodelling process that spatiotemporally coordinates the pre-integration steps of HIV-1. Finally we suggest that nucleoprotein remodelling mechanisms are common features developed by mobile genetic elements to ensure successful replication

VIH-1, protéine de nucléocapside, ADN, Flap central et quartets de guanine (assemblages et modelages in vitro)

PARIS-BIUSJ-Thèses (751052125) / SudocPARIS-BIUSJ-Physique recherche (751052113) / SudocSudocFranceF

Multiple topological labeling for imaging single plasmids

International audienc

G-quartets direct assembly of HIV-1 nucleocapsid protein along single-stranded DNA

The d(TTGGGGGGTACAGTGCA) sequence, derived from the human immunodeficiency virus type 1 (HIV-1) central DNA flap, can form in vitro an intermolecular parallel DNA quadruplex. This work demonstrates that the HIV-1 nucleocapsid protein (NCp) exhibits a high affinity (10(8) M(–1)) for this quadruplex. This interaction is predominantly hydrophobic, maintained by a stabilization between G-quartet planes and the C-terminal zinc finger of the protein. It also requires 5 nt long tails flanking the quartets plus both the second zinc-finger and the N-terminal domain of NCp. The initial binding nucleates an ordered arrangement of consecutive NCp along the four single-stranded tails. Such a process requires the N-terminal zinc finger, and was found to occur for DNA site sizes shorter than usual in a sequence-dependent manner. Concurrently, NCp binding is efficient on a G′2 quadruplex also derived from the HIV-1 central DNA flap. Apart from their implication within the DNA flap, these data lead to a model for the nucleic acid architecture within the viral nucleocapsid, where adjacent single-stranded tails and NCp promote a compact assembly of NCp and nucleic acid growing from stably and primary bound NCp