Epigenetic rewriting at centromeric DNA repeats leads to increased chromatin accessibility and chromosomal instability.

Background: Centromeric regions of human chromosomes contain large numbers of tandemly repeated α-satellite sequences. These sequences are covered with constitutive heterochromatin which is enriched in trimethylation of histone H3 on lysine 9 (H3K9me3). Although well studied using artificial chromosomes and global perturbations, the contribution of this epigenetic mark to chromatin structure and genome stability remains poorly known in a more natural context.

MNHN-Tree-Tools: a toolbox for tree inference using multi-scale clustering of a set of sequences.

Summary: Genomic sequences are widely used to infer the evolutionary history of a given group of individuals. Many methods have been developed for sequence clustering and tree building. In the early days of genome sequencing, these were often limited to hundreds of sequences but due to the surge of high throughput sequencing, it is now common to have millions of sampled sequences at hand.

Diversity and distribution of alpha satellite DNA in the genome of an Old World monkey: Cercopithecus solatus.

Background: Alpha satellite is the major repeated DNA element of primate centromeres. Evolution of these tandemly repeated sequences has led to the existence of numerous families of monomers exhibiting specific organizational patterns. The limited amount of information available in non-human primates is a restriction to the understanding of the evolutionary dynamics of alpha satellite DNA.

Proliferation-dependent positioning of individual centromeres in the interphase nucleus of human lymphoblastoid cell lines.

The cell nucleus is a highly organized structure and plays an important role in gene regulation. Understanding the mechanisms that sustain this organization is therefore essential for understanding genome function. Centromeric regions (CRs) of chromosomes have been known for years to adopt specific nuclear positioning patterns, but the significance of this observation is not yet completely understood.

Polyamide fluorescent probes for visualization of repeated DNA sequences in living cells.

DNA imaging in living cells usually requires transgenic approaches that modify the genome. Synthetic pyrrole-imidazole polyamides that bind specifically to the minor groove of double-stranded DNA (dsDNA) represent an attractive approach for in-cell imaging that does not necessitate changes to the genome. Nine hairpin polyamides that target mouse major satellite DNA were synthesized.

Analysis of nuclear organization with TANGO, software for high-throughput quantitative analysis of 3D fluorescence microscopy images.

The cell nucleus is a highly organized cellular organelle that contains the genome. An important step to understand the relationships between genome positioning and genome functions is to extract quantitative data from three-dimensional (3D) fluorescence imaging. However, such approaches are limited by the requirement for processing and analyzing large sets of images.

CDK11(p58) kinase activity is required to protect sister chromatid cohesion at centromeres in mitosis.

The cyclin-dependent kinase CDK11(p58) is specifically expressed at G2/M phase. CDK11(p58) depletion leads to different cell cycle defects such as mitotic arrest, failure in centriole duplication and centrosome maturation, and premature sister chromatid separation. We report that upon CDK11 depletion, loss of sister chromatid cohesion occurs during mitosis but not during G2 phase.

TANGO: a generic tool for high-throughput 3D image analysis for studying nuclear organization.

Motivation: The cell nucleus is a highly organized cellular organelle that contains the genetic material. The study of nuclear architecture has become an important field of cellular biology. Extracting quantitative data from 3D fluorescence imaging helps understand the functions of different nuclear compartments.

A capture approach for supercoiled plasmid DNA using a triplex-forming oligonucleotide.

Proteins that recognize and bind specific sites in DNA are essential for regulation of numerous biological functions. Such proteins often require a negative supercoiled DNA topology to function correctly. In current research, short linear DNA is often used to study DNA-protein interactions.

In vitro selection of oligonucleotides that bind double-stranded DNA in the presence of triplex-stabilizing agents.

A SELEX approach has been developed in order to select oligonucleotides that bind double-stranded DNA in the presence of a triplex-stabilizing agent, and was applied to a target sequence containing an oligopurine-oligopyrimidine stretch. After only seven rounds of selection, the process led to the identification of oligonucleotides that were able to form triple helices within the antiparallel motif. Inspection of the selected sequences revealed that, contrary to GC base pair which were always recognized by guanines, recognition of AT base pair could be achieved by either adenine or thymine, depending on the sequence context.

Multicolor detection of combed DNA molecules using quantum dots.

DNA combing is a useful strategy for manipulating single DNA molecules and has a wide range of applications in genetics, single molecule studies, and nanobiotechnology. Visualization of combed DNA molecules is usually performed by using DNA binding organic dyes. Such dyes are not suitable in all circumstances, especially because of their photoreactivity.

Tracking of single quantum dot labeled EcoRV sliding along DNA manipulated by double optical tweezers.

Fluorescence microscopy provides a powerful method to directly observe single enzymes moving along a DNA held in an extended conformation. In this work, we present results from single EcoRV enzymes labeled with quantum dots which interact with DNA manipulated by double optical tweezers. The application of quantum dots facilitated accurate enzyme tracking without photobleaching whereas the tweezers allowed us to precisely control the DNA extension.

A three-branched DNA template for carbon nanotube self-assembly into nanodevice configuration.

We report here the first realization of an artificial branched DNA template where a single wall carbon nanotube is positioned with the necessary geometry of an individually gated field effect transistor.

Sliding and jumping of single EcoRV restriction enzymes on non-cognate DNA.

The restriction endonuclease EcoRV can rapidly locate a short recognition site within long non-cognate DNA using 'facilitated diffusion'. This process has long been attributed to a sliding mechanism, in which the enzyme first binds to the DNA via nonspecific interaction and then moves along the DNA by 1D diffusion. Recent studies, however, provided evidence that 3D translocations (hopping/jumping) also help EcoRV to locate its target site.

Biophysical analysis of triple-helix formation.

Two methods for DNA triple-helix analysis are described in this unit: a gel-shift assay based on the slower electrophoretic migration of a triplex in a polyacrylamide gel under nondenaturing conditions, and an optical method in which the thermal denaturation of the triple helix is followed by UV spectrophotometry. Both methods give valuable information on the characteristics of DNA triple-helix formation and triplex stability under different conditions.

Multiple topological labeling for imaging single plasmids.

Sequence-specific labeling methods for double-stranded DNA are required for mapping protein binding sites or specific DNA structures on circular DNA molecules by high-resolution imaging techniques such as electron and atomic force microscopies. Site-specific labeling can be achieved by ligating a DNA fragment to a stem-loop-triplex-forming oligonucleotide, thereby forming a topologically linked complex. The superhelicity of the plasmid is not altered and the process can be applied to two different target sites simultaneously, using DNA fragments of different sizes.

Stem-loop oligonucleotides as tools for labelling double-stranded DNA.

We report on a sequence-specific double-stranded DNA labelling strategy in which a stem-loop triplex forming oligonucleotide (TFO) is able to encircle its DNA target. Ligation of this TFO to either a short hairpin oligonucleotide or a long double-stranded DNA fragment leads to the formation of a topological complex. This process requires the hybridization of both extremities of the TFO to each other on a few base pairs.

Detection of single DNA molecules by multicolor quantum-dot end-labeling.

Observation of DNA-protein interactions by single molecule fluorescence microscopy is usually performed by using fluorescent DNA binding agents. However, such dyes have been shown to induce cleavage of the DNA molecule and perturb its interactions with proteins. A new method for the detection of surface-attached DNA molecules by fluorescence microscopy is introduced in this paper.

Ligand-mediated transcription elongation control using triplex-based padlock oligonucleotides.

Triplex-forming oligonucleotides (TFOs) provide useful tools for the artificial regulation of gene expression at the transcriptional level. They can become topologically linked to their DNA target upon circularization, thereby forming very stable triple helical structures. These "padlock oligonucleotides" are able to interfere with transcription elongation when their target site is located in the transcribed region of a gene.

Sequence-specific fluorescent labeling of double-stranded DNA observed at the single molecule level.

Fluorescent labeling of a short sequence of double-stranded DNA (dsDNA) was achieved by ligating a labeled dsDNA fragment to a stem-loop triplex forming oligonucleotide (TFO). After the TFO has wound around the target sequence by ligand-induced triple helix formation, its extremities hybridize to each other, leaving a dangling single-stranded sequence, which is then ligated to a fluorescent dsDNA fragment using T4 DNA ligase. A non-repeated 15 bp sequence present on lambda DNA was labeled and visualized by fluorescence microscopy after DNA combing.

Coupling of a targeting peptide to plasmid DNA using a new type of padlock oligonucleotide.

We have recently described a new method for attaching padlock oligonucleotides to supercoiled plasmid DNA at specific sequences. A variant of this method has been developed in order to allow the coupling of targeting moieties to plasmids using a convenient strategy. After sequence-specific winding around the double-stranded target DNA sequence by ligand-induced triple helix formation, the extremities of a triplex-forming oligonucleotide hybridize to each other, leaving a dangling single-stranded sequence, which is then ligated to a hairpin oligonucleotide using T4 DNA ligase.