The Visu conference is organized by the Commissariat à l'Energie Atomique (CEA) at Bruyères le Chatel. It aims at gathering various actors (from industry and academia) of the visualization french community. This conference is an opportunity to communicate recent results and to discuss about the challenges to come in scientific visualization.

To know more about this event: http://visu2011.imag.fr/

We strongly recommend you to have a look at David Goodsell's homepage: http://mgl.scripps.edu/people/goodsell/illustration/mycoplasma

- import PDB files

- create isosurface of molecular object

- highlight residues of interest

- calculate distance between residues pairs

- import and export in 3D formats

- model DNA and export the result in PDB

- visualize a 3D scene with Level of Detail

- import a file with x,y,z coordinates and convert it into a DNA representation

We will soon provide video tutorials.

Graphite MicroMégas is the result of a collaboration between the Fourmentin-Guilbert Scientific Foundation (http://www.fourmentinguilbert.org/) and INRIA (Samuel Hornus, Bruno Levy; http://alice.loria.fr/).

It runs on Linux, Windows and Mac OSX. The tool is in Beta stage, and it is hoped that users will provide feedback. If you are interested in using this free software, please contact us at: info[at] lifeexplorer.eu or samuel.hornus [at] inria.fr

A video is available here: http://www.newscientist.com/blogs/nstv/2011/02/hiv-as-youve-never-seen-it-before.html

The 3D scenes used for making the illustrations are downloadable in the Download section of the website.

"Goodsell's artworks illuminated the beauty and wonder of biology at the molecular scale. I had studied biochemistry and attended numerous lectures by molecular biologists but had always glazed over with all the jargon and abbreviations they would use in describing their work. Goodsell's drawings revealed for me the connections of molecules inside our living cells and made me appreciate why scientists are so excited about what was being discovered. Inspired by his work, I set out to create my first cell membrane animation with receptors and other molecules on the surface of a stem cell. This resulted in the animation that can be seen in my Colony Stimulating Factor animation, which I made around 1999."

See the complete interview at: http://www.ami.org/2011/interview-with-drew-berry.html

Drew's webpages at WEHI: http://www.wehi.edu.au/education/wehitv/

D.Larivière, E.Fourmentin (Fondation Fourmentin-Guilbert), O. Mavré (LISAA)

N. Dubarry, M.-L. Bonné, F.-X. Barre (Centre de Génétique Moléculaire, CNRS, Gif/Yvette)

In E. coli, at least 11 proteins are known to participate in the division process : FtsZ, ZipA, FtsA, ZapA, FtsK, FtsQ, FtsL, FtsB, FtsW, FtsI, FtsN. An early step in bacterial cytokinesis is the formation of a FtsZ ring like structure at the site of septation, which contracts as the cell divides. Strucural and microscopic studies led to the proposal that FtsZ may function as a cytoskeletal element in prokaryotes, analogous to tubulin in eukaryotes. 

Before cell contraction, FtsA, ZipA, ZapA and FtsK are recruited at the FtsZ ring. FtsA, ZipA and ZapA have been shown to interact with FtsZ, to drive its polymerisation and to promote FtsZ filament bundling thereby contributing to the spatio-temporal tuning of the Z-ring. Additionnal functions of FtsA and ZipA may be to link the membrane with the FtsZ rings in order to stabilize or organize the rings. FtsK is a DNA translocase that coordinates chromosome segregation and cell division in bacteria. In addition to its role as activator of XerCD site-specific recombination, FtsK can translocate double-stranded DNA rapidly and directionally and reverse direction. Finally, FtsA and FtsK seem to interact with and target other division proteins and their lack results in a cell unable to contract.

Picture 1 shows two microscopy images of a dividing E.coli cell : the large one in red, obtained by Christian Lesterlin (CGM-CNRS, Gif), clearly shows DNA (stained by DAPI) trapped at the septum ; the small one, obtained by Nelly Dubarry, shows a wild-type E. coli cell observed by differential-interference microscopy.  

Pictures 2 to 4 shows a very first model of the septosome in the final stage of the division process and created with the LifeExplorer software. This model includes 177 proteins : 2 double-rings with 96 FtsZ proteins (in yellow), 51 FtsA proteins (in dark blue), 6 ZipA Cter (in red), 10 ZapA tetramer bridging two FtsZ rings, 2 FtsK hexamer (Cter : 6  alpha, beta and gamma domains).

Only one portion of DNA is shown. This 678 DNA bp has been created using DNA tools of The International Center for Genetic Engineering and Biotechnology (ICGEB) in Trieste (Vlahovicek K, Kajan L, Pongor S. DNA analysis servers: plot.it, bend.it, model.it and IS. Nucleic Acids Res. 2003 Jul 1;31(13):3686-7. PMID: 12824394).

All proteins has been created from their PDB structure using the UCSF Chimera Multiscale models tool generating low-resolution surfaces (T.D. Goddard, C.C. Huang, and T.E. Ferrin, "Software extensions to UCSF Chimera for interactive visualization of large molecular assemblies" Structure 13:473 (2005). PMID: 15766548).

FtsZ : PDB 2VAW; FtsA : PDB 1E4F; ZipA : PDB 1F7W; ZapA tetramer : PDB 1W2E; FtsK hexamer : PDB 2IUU; Gamma domain : PDB 2J5P

Next steps : Insertion of membranar proteins; modelling of XerCD site-specific recombination; modelling of FtsZ-ring formation; insertion of more FtsK motors under the form of monomers and hexamer; insertion of one supplementary portion of DNA; ...

References :

W. Margolin, "FtsZ and the division of prokaryotic cells and organelles", Nature Reviews Molecular Cell Biology 6, 2005

Bigot et al, “FtsK, a literate chromosome segregation machine”, Molecular Microbiology 64 (6), 2007

T. H. Massey et al, “Double-Stranded DNA Translocation: Structure and Mechanism of Hexameric FtsK”, Molecular Cell 23, 2006

M.A. Oliva et al, "Structural insights into FtsZ protofilament formation", Nature Structural and Molecular Biology 11, 2004

A. Vendeville et al, "An inventory of the bacterial macromolecular components and their spatial organization", FEMS Microbiology Reviews 35 (2), 2011

Before cell contraction, FtsA, ZipA, ZapA and FtsK are recruited at the FtsZ ring. FtsA, ZipA and ZapA have been shown to interact with FtsZ, to drive its polymerisation and to promote FtsZ filament bundling thereby contributing to the spatio-temporal tuning of the Z-ring. Additionnal functions of FtsA and ZipA may be to link the membrane with the FtsZ rings in order to stabilize or organize the rings. FtsK is a DNA translocase that coordinates chromosome segregation and cell division in bacteria. In addition to its role as activator of XerCD site-specific recombination, FtsK can translocate double-stranded DNA rapidly and directionally and reverse direction. Finally, FtsA and FtsK seem to interact with and target other division proteins and their lack results in a cell unable to contract.

Picture 1 shows two microscopy images of a dividing E.coli cell : the large one in red, obtained by Christian
Lesterlin (CGM-CNRS, Gif), clearly shows DNA (stained by DAPI) trapped at the septum ; the small one, obtained by Nelly Dubarry, shows a wild-type E. coli cell observed by differential-interference microscopy.  

Pictures 2 to 4 shows a very first model of the septosome in the final stage of the division process and
created with the LifeExplorer software. This model includes 177 proteins : 2 double-rings with 96 FtsZ
proteins (in yellow), 51 FtsA proteins (in dark blue), 6 ZipA Cter (in red), 10 ZapA tetramer bridging two
FtsZ rings, 2 FtsK hexamer (Cter : 6  alpha, beta and gamma domains).

Only one portion of DNA is shown. This 678 DNA bp has been created using DNA tools of The International Center for Genetic Engineering and Biotechnology (ICGEB) in Trieste
(Vlahovicek K, Kajan L, Pongor S. DNA analysis servers: plot.it, bend.it, model.it and IS. Nucleic Acids Res. 2003 Jul 1;31(13):3686-7. PMID: 12824394).

All proteins has been created from their PDB structure using the UCSF Chimera Multiscale models tool generating low-resolution surfaces (T.D. Goddard, C.C. Huang, and T.E. Ferrin, "Software extensions to UCSF Chimera for interactive visualization of large molecular assemblies" Structure 13:473 (2005). PMID: 15766548).

FtsZ : PDB 2VAW; FtsA : PDB 1E4F; ZipA : PDB 1F7W; ZapA tetramer : PDB 1W2E; FtsK hexamer : PDB 2IUU; Gamma domain : PDB 2J5P

Next steps : Insertion of membranar proteins; modelling of XerCD site-specific recombination; modelling of FtsZ-ring formation; insertion of more FtsK motors under the form of monomers and hexamer; insertion of one supplementary portion of DNA; ...

References :

W. Margolin : FtsZ and the division of prokaryotic cells and organelles. Nature Reviews Molecular Cell Biology 6, 862-871 (November 2005).

Bigot et al., “FtsK, a literate chromosome segregation machine”, Molecular Microbiology (2007) 64 (6) 1434–1441

T. H. Massey et al, “Double-Stranded DNA Translocation: Structure and Mechanism of Hexameric FtsK”, Molecular Cell 23, 457–469, August 18, 2006

M.A. Oliva et al, "Structural insights into FtsZ protofilament formation", Nature Structural and Molecular Biology 11, 1243-1250 (2004)

The Z-ring before contraction containing about 2000 FtsZ proteins (800 nm diameter) is superimposed with the whole machinery close to the septum closure. FtsK monomers are attached to the Z-ring through a 200 nm linker not represented.

See for more information :

W. Margolin : FtsZ and the division of prokaryotic cells and organelles. Nature Reviews Molecular Cell Biology 6, 862-871 (November 2005).
S. Bigot, V. Sivanathan, C. Possoz F.-X. Barre and F. Cornet : FtsK, a literate chromosome segregation machine. Molecular Microbiology (2007) 64(6), 1434–1441