Youri Timsit

Hydration and recognition of methylated CpG steps in DNA.

The analysis of the hydration pattern around methylated CpG steps in three high resolution (1.7, 2.15 and 2.2 Å) crystal structures of A‐DNA decamers reveals that the methyl groups of cytosine residues are well hydrated. In comparing the native structure with two structurally distinct forms of the decamer d(CCGCCGGCGG) fully methylated at its CpG steps, this study shows also that in certain structural and sequence contexts, the methylated cytosine base can be more hydrated that the unmodified one. These water molecules seem to be stabilized in front of the methyl group through the formation C–H···O interactions. In addition, these structures provide the first observation of magnesium cations bound to the major groove of A‐DNA and reveal two distinct modes of metal binding in methylated and native duplexes. These findings suggest that methylated cytosine bases could be recognized by protein or DNA polar residues through their tightly bound water molecules.

Helical Chirality: a Link between Local Interactions and Global Topology in DNA

DNA supercoiling plays a major role in many cellular functions. The global DNA conformation is however intimately linked to local DNA-DNA interactions influencing both the physical properties and the biological functions of the supercoiled molecule. Juxtaposition of DNA double helices in ubiquitous crossover arrangements participates in multiple functions such as recombination, gene regulation and DNA packaging. However, little is currently known about how the structure and stability of direct DNA-DNA interactions influence the topological state of DNA. Here, a crystallographic analysis shows that due to the intrinsic helical chirality of DNA, crossovers of opposite handedness exhibit markedly different geometries. While right-handed crossovers are self-fitted by sequence-specific groove-backbone interaction and bridging Mg2+ sites, left-handed crossovers are juxtaposed by groove-groove interaction. Our previous calculations have shown that the different geometries result in differential stabilisation in solution, in the presence of divalent cations. The present study reveals that the various topological states of the cell are associated with different inter-segmental interactions. While the unstable left-handed crossovers are exclusively formed in negatively supercoiled DNA, stable right-handed crossovers constitute the local signature of an unusual topological state in the cell, such as the positively supercoiled or relaxed DNA. These findings not only provide a simple mechanism for locally sensing the DNA topology but also lead to the prediction that, due to their different tertiary intra-molecular interactions, supercoiled molecules of opposite signs must display markedly different physical properties. Sticky inter-segmental interactions in positively supercoiled or relaxed DNA are expected to greatly slow down the slithering dynamics of DNA. We therefore suggest that the intrinsic helical chirality of DNA may have oriented the early evolutionary choices for DNA topology.

Cruciform structures and functions.

In this paper, a structure-function analysis of B-DNA self-fitting is reviewed in the light of recent oligonucleotide crystal structures. Their crystal packings provided a high-resolution view of B-DNA helices closely and specifically fitted by groove-backbone interaction, a natural and biologically relevant manner to assemble B-DNA helices. In revealing that new properties of the DNA molecule emerge during condensation, these crystallographic studies have pointed to the biological importance of DNA—DNA interactions.

The role of disordered ribosomal protein extensions in the early steps of eubacterial 50 S ribosomal subunit assembly.

Although during the past decade research has shown the functional importance of disorder in proteins, many of the structural and dynamics properties of intrinsically unstructured proteins (IUPs) remain to be elucidated. This review is focused on the role of the extensions of the ribosomal proteins in the early steps of the assembly of the eubacterial 50 S subunit. The recent crystallographic structures of the ribosomal particles have revealed the picture of a complex assembly pathway that condenses the rRNA and the ribosomal proteins into active ribosomes. However, little is know about the molecular mechanisms of this process. It is thought that the long basic r-protein extensions that penetrate deeply into the subunit cores play a key role through disorder-order transitions and/or co-folding mechanisms. A current view is that such structural transitions may facilitate the proper rRNA folding. In this paper, the structures of the proteins L3, L4, L13, L20, L22 and L24 that have been experimentally found to be essential for the first steps of ribosome assembly have been compared. On the basis of their structural and dynamics properties, three categories of extensions have been identified. Each of them seems to play a distinct function. Among them, only the coil-helix transition that occurs in a phylogenetically conserved cluster of basic residues of the L20 extension appears to be strictly required for the large subunit assembly in eubacteria. The role of α helix-coil transitions in 23 S RNA folding is discussed in the light of the calcium binding protein calmodulin that shares many structural and dynamics properties with L20.

Crystallization of DNA.

Publisher Summary The first step in a crystallographic study is the production of large, well-diffracting crystals. Although DNA oligonucleotides are easy to crystallize, good diffracting crystals are less common. To understand the DNA crystallization processes, it is necessary to consider the specific properties of a DNA molecule, to determine the physicochemical parameters that favor the three-dimensional assembly of the molecules, and to analyze the intermolecular contacts of the packing. An interesting observation that emerges from packing analysis is the importance of sequence for the organization of B-DNA molecules in the crystalline state. B-form DNA exhibits a larger variety of packings in which all parts of the molecule can participate in intermolecular contacts in a specific manner. In this case, it is possible to generate defined crystal organizations by designing packing driving boxes in the sequence. In contrast, A- and Z-form crystals are not directly sequence dependent, and each form of DNA exhibits only one packing arrangement. The different behavior of B-DNA is because of the existence of two easily accessible grooves and this emphasizes its suitability for molecular recognition. It is clear that packing interactions can be good models of molecular recognition processes.

Coexistence of two protein folding states in the crystal structure of ribosomal protein L20

The recent finding of intrinsically unstructured proteins defies the classical structure–function paradigm. However, owing to their flexibility, intrinsically unstructured proteins generally escape detailed structural investigations. Consequently little is known about the extent of conformational disorder and its role in biological functions. Here, we present the X‐ray structure of the unbound ribosomal protein L20, the long basic amino‐terminal extension of which has been previously interpreted as fully disordered in the absence of RNA. This study provides the first detailed picture of two protein folding states trapped together in a crystal and indicates that unfolding occurs in discrete regions of the whole protein, corresponding mainly to RNA‐binding residues. The electrostatic destabilization of the long α‐helix and a structural communication between the two L20 domains are reminiscent of those observed in calmodulin. The detailed comparison of the two conformations observed in the crystal provides new insights into the role of unfolded extensions in ribosomal assembly.

Left-handed DNA crossovers. Implications for DNA-DNA recognition and structural alterations.

The close approach of DNA segments participates in many biological functions including DNA condensation and DNA processing. Previous crystallographic studies have shown that B-DNA self-fitting by mutual groove-backbone interaction produces right-handed DNA crossovers. These structures have opened new perspectives on the role of close DNA-DNA interactions in the architecture and activity the DNA molecule. In the present study, the analysis of the crystal packing of two B-DNA decamer duplexes d(CCIIICCCGG) and d(CCGCCGGCGG) reveals the existence of new modes of DNA crossing. Symmetric left-handed crossovers are produced by mutual fitting of DNA grooves at the crossing point. New sequence patterns contribute to stabilize longitudinal fitting of the sugar-phosphate backbone into the major groove. In addition, the close approach of DNA segments greatly influences the DNA conformation in a sequence dependent manner. This study provides new insights into the role of DNA sequence and structure in DNA-DNA recognition. In providing detailed molecular views of DNA crossovers of opposite chirality, this study can also help to elucidate the role of symmetry and chirality in the recognition of complex DNA structures by protein dimers or tetramers, such as topoisomerase II and recombinase enzymes. These results are discussed in the context of the possible relationships between DNA condensation and DNA processing.

DNA Self-Assembly: From Chirality to Evolution

Transient or long-term DNA self-assembly participates in essential genetic functions. The present review focuses on tight DNA-DNA interactions that have recently been found to play important roles in both controlling DNA higher-order structures and their topology. Due to their chirality, double helices are tightly packed into stable right-handed crossovers. Simple packing rules that are imposed by DNA geometry and sequence dictate the overall architecture of higher order DNA structures. Close DNA-DNA interactions also provide the missing link between local interactions and DNA topology, thus explaining how type II DNA topoisomerases may sense locally the global topology. Finally this paper proposes that through its influence on DNA self-assembled structures, DNA chirality played a critical role during the early steps of evolution.

Cytosine, the double helix and DNA self-assembly

DNA self‐assembly has crucial implications in reading out the genetic information in the cell and in nanotechnological applications. In a recent paper, self‐assembled DNA crystals displaying spectacular triangular motifs have been described (Zheng et al., 2009 ). The authors claimed that their data demonstrate the possibility to rationally design well‐ordered macromolecular 3D DNA lattice with precise spatial control using sticky ends. However, the authors did not recognize the fundamental features that control DNA self‐assembly in the lateral direction. By analysing available crystallographic data and simulating a DNA triangle, we show that the double helix geometry, sequence‐specific cytosine–phosphate interactions and divalent cations are in fact responsible for the precise spatial assembly of DNA. Copyright

Convergent evolution of MutS and topoisomerase II for clamping DNA crossovers and stacked Holliday junctions.

Abstract This study shows that topoisomerase II and MutS proteins share a structural motif that has, in its dimeric form, a suitable geometry for clamping the two arms of either right-handed DNA crossovers or their isostructural stacked Holliday junctions. This defines a new protein family selected by convergent evolution for sensing DNA topology and binding recombination intermediates. This study also proposes that MutS binding on 2-fold right-handed crossover provides a mechanism for strand discrimination during DNA translocation.