Crystal structure of a wild-type Cre recombinase-loxP synapse reveals a novel spacer conformation suggesting an alternative mechanism for DNA cleavage activation

Escherichia coli phage P1 Cre recombinase catalyzes the site-specific recombination of DNA containing loxP sites. We report here two crystal structures of a wild-type Cre recombinase–loxP synaptic complex corresponding to two distinct reaction states: an initial pre-cleavage complex, trapped using a phosphorothioate modification at the cleavable scissile bond that prevents the recombination reaction, and a 3′-phosphotyrosine protein–DNA intermediate resulting from the first strand cleavage. In contrast to previously determined Cre complexes, both structures contain a full tetrameric complex in the asymmetric unit, unequivocally showing that the anti-parallel arrangement of the loxP sites is an intrinsic property of the Cre–loxP recombination synapse. The conformation of the spacer is different to the one observed for the symmetrized loxS site: a kink next to the scissile phosphate in the top strand of the pre-cleavage complex leads to unstacking of the TpG step and a widening of the minor groove. This side of the spacer is interacting with a ‘cleavage-competent’ Cre subunit, suggesting that the first cleavage occurs at the ApT step in the top strand. This is further confirmed by the structure of the 3′-phosphotyrosine intermediate, where the DNA is cleaved in the top strands and covalently linked to the ‘cleavage-competent’ subunits. The cleavage is followed by a movement of the C-terminal part containing the attacking Y324 and the helix N interacting with the ‘non-cleaving’ subunit. This rearrangement could be responsible for the interconversion of Cre subunits. Our results also suggest that the Cre-induced kink next to the scissile phosphodiester activates the DNA for cleavage at this position and facilitates strand transfer.     

Role of cysteine amino acid residues on the RNA binding activity of human thymidylate synthase

The role of cysteine sulfhydryl residues on the RNA binding activity of human thymidylate synthase (TS) was investigated by mutating each cysteine residue on human TS to a corresponding alanine residue. Enzymatic activities of TS:C43A and TS:C210A mutant proteins were nearly identical to wild-type TS, while TS:C180A and TS:C199A mutants expressed >80% of wild-type enzyme activity. In contrast, TS:C195A was completely inactive. Mutant proteins, TS:C195A, TS:C199A and TS:C210A, retained RNA binding activity to nearly the same degree as wild-type human TS. RNA binding activity of TS:C43A was reduced by 30% when compared to wild-type TS, while TS:C180A was completely devoid of RNA binding activity. In vitro translation studies confirmed that mutant proteins TS:C43A, TS:C195A, TS:C199A and TS:C210A, significantly repressed human TS mRNA translation, while TS:C180A was unable to do so. To confirm the in vivo significance of the cysteine sulfhydryl residue, mutant proteins TS:C180A and TS:C195A were each expressed in human colon cancer HCT-C18:TS(–) cells that expressed a functionally inactive TS. A recombinant luciferase reporter gene under the control of a TS-response element was co-transfected into these same cells, and luciferase activity increased in the presence of the TS:C195A mutant TS protein to a level similar to that observed upon expression of wild-type TS protein. In contrast, luciferase activity remained unchanged in cells expressing the TS:C180A mutant protein. Taken together, these findings identify Cys-180 as a critical residue for the in vitro and in vivo translational regulatory effects of human TS.     

Characterisation of mutations in 77 patients with X-linked myotubular myopathy,including a family with a very mild phenotype

X-linked myotubular myopathy is characterised by neonatal hypotonia, muscle weakness and respiratory distress in affected males, leading often to early death, although prolonged survival is observed in milder forms, or as a result of prolongation of ventilation support. It is caused by mutations in the MTM1 gene, which encodes a phosphatase called myotubularin, which has been highly conserved during evolution, down to yeasts ( S. cerevisiae and S. pombe). To date, 251 mutations have been identified in unrelated families, corresponding to 158 different disease-associated mutations, which are widespread throughout the gene. We have found additional mutations in 77 patients, including 35 novel ones. We identified a missense mutation N180K in a 67-year-old grandfather (the oldest known patient with an MTM1 mutation), previously suspected to have autosomal centronuclear myopathy, and in his two grandsons also mildly affected. Mild and moderate phenotypes associated with novel missense mutations and with a translation initiation defect mutation are discussed, as well as severe phenotypes associated with particular novel mutations. With the present report, 192 different mutations in the MTM1 gene have been described in 328 families. The spectrum of mutations is now enlarged from the very severe classic neonatal phenotype to very mild phenotype allowing survival to the age of 67 years.     

SWISS-MODEL: An automated protein homology-modeling server

SWISS-MODEL (http://swissmodel.expasy.org) is a server for automated comparative modeling of three-dimensional (3D) protein structures. It pioneered the field of automated modeling starting in 1993 and is the most widely-used free web-based automated modeling facility today. In 2002 the server computed 120 000 user requests for 3D protein models. SWISS-MODEL provides several levels of user interaction through its World Wide Web interface: in the 'first approach mode' only an amino acid sequence of a protein is submitted to build a 3D model. Template selection, alignment and model building are done completely automated by the server. In the 'alignment mode', the modeling process is based on a user-defined target-template alignment. Complex modeling tasks can be handled with the 'project mode' using DeepView (Swiss-PdbViewer), an integrated sequence-to-structure workbench. All models are sent back via email with a detailed modeling report. WhatCheck analyses and ANOLEA evaluations are provided optionally. The reliability of SWISS-MODEL is continuously evaluated in the EVA-CM project. The SWISS-MODEL server is under constant development to improve the successful implementation of expert knowledge into an easy-to-use server.     

Microtubule dynamics: new surprises from an old MAP

Dis1/XMAP215 family microtubule-binding proteins are essential for cell division in animals, plants and fungi, suggesting a conserved cell-division mechanism used by all eukaryotes. Two new studies, however, reveal that different family members can have very different effects on microtubule dynamics.     

Chromosome cohesion and separation: from men and molecules

Sister chromatid cohesion and separation are fundamental for accurate genome inheritance over cell generations. Work over recent years has established the existence of a chromosomal protein complex, cohesin, that connects sister chromatids from the time they are generated in S phase onwards, and which is destroyed at the onset of anaphase through cleavage by the protease separase. Over the last year, the function of cohesin has been investigated in higher eukaryotes, including humans, with results that have uncovered important new aspects of this process. The first structural views of cohesin have become available, and significant steps been made towards a mechanistic understanding of chromosome cohesion. Studies on separase have revealed new levels of regulation of chromosome segregation.     

Multiple colonization of Madagascar and Socotra by colubrid snakes: evidence from nuclear and mitochondrial gene phylogenies

Colubrid snakes form a speciose group of unclarified phylogeny. Their almost cosmopolitan distribution could be interpreted as a product of plate-tectonic vicariance. We used sequences of the nuclear c-mos, the mitochondrial cytochrome b and the 16S rRNA genes in 41 taxa to elucidate the relationships between the endemic colubrid genera found in Madagascar and in the Socotra archipelago. The well-resolved trees indicate multiple origins of both the Malagasy and the Socotran taxa. The Malagasy genus Mimophis was nested within the Psammophiinae, and the Socotran Hemerophis was closely related to Old World representatives of the former genus Coluber. The remaining 14 genera of Malagasy colubrids formed a monophyletic sister group of the Socotran Ditypophis (together forming the Pseudoxyrhophiinae). Molecular-clock estimates place the divergence of Malagasy and Socotran colubrids from their non-insular sister groups into a time-frame between the Eocene and Miocene. Over-seas rafting is the most likely hypothesis for the origin of at least the Malagasy taxa. The discovery of a large monophyletic clade of colubrids endemic to Madagascar indicates a need for taxonomic changes. The relationship of this radiation to the Socotran Ditypophis highlights the potential of the Indian Ocean islands to act as an evolutionary reservoir for lineages that have become extinct in Africa and Asia.