Metaxia Vlassi

Gromita: a fully integrated graphical user interface to gromacs 4.

Gromita is a fully integrated and efficient graphical user interface (GUI) to the recently updated molecular dynamics suite Gromacs, version 4. Gromita is a cross-platform, perl/tcl-tk based, interactive front end designed to break the command line barrier and introduce a new user-friendly environment to run molecular dynamics simulations through Gromacs. Our GUI features a novel workflow interface that guides the user through each logical step of the molecular dynamics setup process, making it accessible to both advanced and novice users. This tool provides a seamless interface to the Gromacs package, while providing enhanced functionality by speeding up and simplifying the task of setting up molecular dynamics simulations of biological systems. Gromita can be freely downloaded from http://bio.demokritos.gr/gromita/.

Phosphorylation of the arginine/serine repeats of lamin B receptor by SRPK1—Insights from molecular dynamics simulations

BACKGROUND Arginine/serine (RS) repeats are found in several proteins in metazoans with a wide variety of functions, many of which are regulated by SR protein kinase 1 (SRPK1)-mediated phosphorylation. Lamin B receptor (LBR) is such a protein implicated in chromatin anchorage to the nuclear envelope. METHODS Molecular dynamics simulations were used to investigate the conformation of two LBR peptides containing four (human-) and five (turkey-orthologue) consecutive RS dipeptides, in their unphosphorylated and phosphorylated forms and of a conserved peptide, in isolation and in complex with SRPK1. GST pull-down assays were employed to study LBR interactions. RESULTS Unphosphorylated RS repeats adopt short, transient helical conformations, whereas serine phosphorylation induces Arginine-claw-like structures. The SRSRSRSPGR peptide, overlapping with the LBR RS repeats, docks into the known, acidic docking groove of SRPK1, in an extended conformation. Phosphorylation by SRPK1 is necessary for the association of LBR with histone H3. CONCLUSIONS The C-terminal region of the LBR RS domain constitutes a recognition platform for SRPK1, which uses the same recognition mechanism for LBR as for substrates with long RS domains. This docking may promote unfolding of the RS repeats destined to be phosphorylated. Phosphorylation induces Arginine-claw-like conformations, irrespective of the RS-repeat length, that may facilitate interactions with basic partners. GENERAL SIGNIFICANCE Our results shed light on the conformational preferences of an important class of repeats before and after their phosphorylation and support the idea that even short RS domains may be constituents of recognition platforms for SRPK1, thus adding to knowledge towards a full understanding of their phosphorylation mechanism.

Identification of residues in the TPR domain of Ssn6 responsible for interaction with the Tup1 protein

Ssn6, a yeast protein that comprises 10 tandem tetratricopeptide repeat (TPR) motifs, associates with Tup1 repressor protein and acts as a transcriptional corepressor. In this report we identify point mutations in the TPR1 of Ssn6 that disrupt Tup1 interaction. Furthermore, we construct a 3D model of the TPR domain of Ssn6, which is responsible for Tup1 binding, based on the known structure of protein phosphatase 5. According to this model all selected mutations reduce the ability of Ssn6 to interact with Tup1 by affecting the structural integrity of TPR1 and/or the correct spatial arrangement of TPR1 relative to TPR2 and TPR3.

SRPK1 and Akt Protein Kinases Phosphorylate the RS Domain of Lamin B Receptor with Distinct Specificity: A Combined Biochemical and In Silico Approach

Activated Akt has been previously implicated in acting on RS domain-containing proteins. However, it has been questioned whether its action is direct or it is mediated by co-existing SR kinase activity. To address this issue we studied in detail the phosphorylation of Lamin B Receptor (LBR) by Akt. Using synthetic peptides and a set of recombinant proteins expressing mutants of the LBR RS domain we now demonstrate that while all serines of the RS domain represent more or less equal phosphoacceptor sites for SRPK1, Ser80 and Ser82 are mainly targeted by Akt. 3D-modeling combined with molecular dynamics (MD) simulations show that amongst short, overlapping LBR RS-containing peptides complying with the minimum Akt recognition consensus sequence, only those bearing phosphosites either at Ser80 or Ser82 are able to fit into the active site of Akt, at least as effectively as its known substrate, GSK3-β. Combined our results provide evidence that Akt kinases directly phosphorylate an RS domain-containing protein and that both the residues N-terminal the phosphosite and at position +1 are essential for Akt specificity, with the latter substrate position being compatible with the arginine residue of RS-repeats.

Investigating the structural stability of the Tup1‐interaction domain of Ssn6: Evidence for a conformational change on the complex

Ssn6, a tetratricopeptide repeat (TPR) containing protein, associates with the Tup1 repressor to form a global transcriptional co‐repressor complex, which is conserved across species. The three N‐terminal TPR repeats of Ssn6, out of a total of 10, are involved in this particular interaction. Our previously reported 3D‐modeling and mutagenesis data suggested that the structural integrity of TPR1 and its correct positioning relatively to TPR2 are crucial for Tup1 binding. In this study, we first investigate the structural stability of the Tup1 binding domain of Ssn6, in pure form, through a combination of CD spectroscopy and limited proteolysis mapping. The obtained data were next combined with molecular dynamics simulations and disorder/order predictions. This combined study revealed that, although competent to fold, in the absence of Tup1, TPR1 is partially unfolded with its helix B being highly dynamic exposing an apolar surface to the solvent. Subsequent CD spectroscopy on this domain complexed with a Tup1 fragment comprising its Ssn6 binding region provided strong evidence for a conformational change consisting of acquisition of α‐helical structure with simultaneous stabilization of a coiled‐coil configuration upon complex formation. We propose that this conformational change occurs largely in the TPR1 of Ssn6 and is in accord with the concept of folding coupled to binding, proposed for other TPR domains. A possible implication of the structural flexibility of Ssn6 TPR1 in Tup1 recognition is discussed and a novel mode of interaction is proposed for this particular TPR‐mediated complex. Proteins 2008.

Structural Parameters for Proteins Derived from the Atomic Resolution (1.09 Å) Structure of a Designed Variant of the ColE1 ROP Protein

The crystal structure of a designed variant of the ColE1 repressor of primer (ROP) protein has been refined with SHELXL93 to a resolution of 1.09 A. The final model with 510 non-H protein atoms, 576 H atoms in calculated positions and 114 water molecules converged to a standard R factor of 10% using unrestrained blocked full-matrix refinement. For all non-H atoms six-parameter anisotropic thermal parameters have been refined. The majority of atomic vibrations have a preferred orientation which is approximately perpendicular to the bundle axis; analysis with the TLS method [Schomaker & Trueblood (1968). Acta Cryst. B24, 63-77] showed a relatively good agreement between the individual atomic displacements and a rigid-body motion of the protein. Disordered residues with multiple conformations form clusters on the surface of the protein; six C-terminal residues have been omitted from the refined model due to disorder. Part of the solvent structure forms pentagonal or hexagonal clusters which bridge neighbouring protein molecules. Some water molecules are also conserved in wild-type ROP. The unrestrained blocked full-matrix least-squares refinement yielded reliable estimates of the standard deviations of the refined parameters. Comparison of these parameters with the stereochemical restraints used in various protein refinement programs showed statistically significant differences. These restraints should be adapted to the refinement of macromolecules by taking into account parameters determined from atomic resolution protein structures.

Peptide with Built-In Conformational Constraints: Structure of Z-(Aib)7-OtBu

C4oH65N7Olo.2H20, Mr = 803.1, triclinic, Pi, a = 10.082(3), b = 15.523 (5), c= 16.301 (5)/~, a = 87.32 (3), 13 = 77.00 (3), y = 79.70 (2) °, V = 2445.7 (8)/It 3, Z = 2, Dx = 1.09 g cm-3, A(Cu Ka)= 1.5418 A, /z = 6.1 cm-~, F(000) = 868, T = 293 K, final R = 0.077 for 5187 observed reflections. The peptide adopts a 3m-helical conformation consisting of five consecutive 10-atom hydrogen-bonded fl-turns of type III. Both helical senses (left- and right-handed) are present in the crystal. The molecules are hydrogen bonded head-to-tail in the crystal forming infinitely long helical columns along the direction [1 TO].

The stability of the archaeal HU histone-like DNA-binding protein from Thermoplasma volcanium.

The complete genome analysis of the archaeon Thermoplasma volcanium has revealed a gene assigned to encode the histone-like DNA-binding protein HU. Thermoplasma volcanium is a moderate thermophile growing around 60°C and it is adaptable to aerobic and anaerobic environment and therefore it is unique as a candidate for the origin of eukaryotic nuclei in the endosymbiosis hypothesis. The HU protein is the major component of the bacterial nuclei and therefore it is an important protein to be studied. The gene for HUTvo protein (huptvo) was cloned from the genomic DNA of T. volcanium and overexpressed in Escherichia coli. A fast and efficient purification scheme was established to produce an adequate amount of bioactive protein for biochemical and biophysical studies. Highly purified HUTvo was studied for its DNA-binding activity and thermostability. As studied by circular dichroism and high-precision differential scanning microcalorimetry, the thermal unfolding of HUTvo protein is reversible and can be well described by a two-state model with dissociation of the native dimeric state into denatured monomers. The ∆G versus T profile for HUTvo compared to the hyperthermophilic marine eubacterial counterpart from Thermotoga maritima, HUTmar, clearly shows that the archaeal protein has adopted a less efficient molecular mechanism to cope with high temperature. The molecular basis of this phenomenon is discussed.

Equilibrium Heat-induced Denaturation of Chitinase 40 from Streptomyces thermoviolaceus

High‐precision differential scanning calorimetry (DSC) and circular dichroism (CD) have been employed to study the thermal unfolding of chitinase 40 (Chi40) from Streptomyces thermoviolaceus. Chi40 belongs to family 18 of glycosyl hydrolase superfamily bearing a catalytic domain with a “TIM barrel”‐like fold, which exhibits deviations from the (β/α)8 fold. The thermal unfolding is reversible at pH = 8.0 and 9.0. The denatured state is characterized by extensive structural changes with respect to the native. The process is characterized by slow relaxation kinetics. Even slower refolding rates are recorded upon cooling. It is shown that the denaturation calorimetric data obtained at slow heating rate (0.17 K/min) are in excellent agreement with equilibrium data obtained by extrapolation of the experimental results to zero scanning rate. Analysis of the DSC results reveals that the experimental data can be successfully fitted using either a nontwo‐state sequential model involving one equilibrium intermediate, or an independent transitions model involving the unfolding of two Chi40 energetic domains to intermediate states. The stability of the native state with respect to the final denatured state is estimated, ΔG = 24.0 kcal/mol at 25°C. The thermal results are in agreement with previous findings from chemical denaturation studies of a wide variety of (β/α)8 barrel proteins, that their unfolding is a nontwo‐state process, always involving at least one unfolding intermediate. Proteins 2006.

Mutational analysis of TSC1 and TSC2 genes in Tuberous Sclerosis Complex patients from Greece

Tuberous sclerosis complex (TSC) is a rare autosomal dominant disorder causing benign tumors in the brain and other vital organs. The genes implicated in disease development are TSC1 and TSC2. Here, we have performed mutational analysis followed by a genotype-phenotype correlation study based on the clinical characteristics of the affected individuals. Twenty unrelated probands or families from Greece have been analyzed, of whom 13 had definite TSC, whereas another 7 had a possible TSC diagnosis. Using direct sequencing, we have identified pathogenic mutations in 13 patients/families (6 in TSC1 and 7 in TSC2), 5 of which were novel. The mutation identification rate for patients with definite TSC was 85%, but only 29% for the ones with a possible TSC diagnosis. Multiplex ligation-dependent probe amplification (MLPA) did not reveal any genomic rearrangements in TSC1 and TSC2 in the samples with no mutations identified. In general, TSC2 disease was more severe than TSC1, with more subependymal giant cell astrocytomas and angiomyolipomas, higher incidence of pharmacoresistant epileptic seizures, and more severe neuropsychiatric disorders. To our knowledge, this is the first comprehensive TSC1 and TSC2 mutational analysis carried out in TSC patients in Greece.