Constantinos E. Vorgias

Characterization of a cell-wall acid phosphatase (PhoAp) in Aspergillus fumigatus

In the filamentous fungus Aspergillus fumigatus, the vast majority of the cell-wall-associated proteins are secreted proteins that are in transit in the cell wall. These proteins can be solubilized by detergents and reducing agents. Incubation of a SDS/beta-mercaptoethanol-treated cell-wall extract with various recombinant enzymes that hydrolyse cell-wall polysaccharides resulted in the release of a unique protein in minute amounts only after incubation of the cell wall in the presence of 1,3-beta-glucanase. Sequence analysis and biochemical studies showed that this glycoprotein, with an apparent molecular mass of 80 kDa, was an acid phosphatase (PhoAp) that was active on both phosphate monoesters and phosphate diesters. PhoAp is a glycosylphosphatidylinositol-anchored protein that was recovered in the culture filtrate and cell-wall fraction of A. fumigatus after cleavage of its anchor. It is also a phosphate-repressible acid phosphatase. The absence of PhoAp from a phosphate-rich medium was not associated with a reduction in fungal growth, indicating that this cell-wall-associated protein does not play a role in the morphogenesis of A. fumigatus.

Protein kinases as targets for cancer treatment

In various types of malignancies, conventional forms of therapy (surgery, radiation and chemotherapy) are often ineffective, as well as harmful. In the last few years, a convergence of scientific advances has enabled the identification of molecular targets and signaling pathways specific to cancer cells, resulting in therapies with enhanced selectivity and efficacy and reduced toxicity. Compound validation has relied on target validation first, although some of the most successful drugs often have effects outside of their postulated mechanism. Protein kinases represent such molecular targets; considerable research effort has been devoted to the development of targeted drugs that inhibit the action of pathogenic kinases, and clinical studies performed so far have validated the positive effects of kinase inhibitors for cancer treatment. In this review, the specificity, mechanism of action and antitumor activity of several new small-molecule inhibitors of tyrosine and serine/threonine kinases are discussed.

De novo purification scheme and crystallization conditions yield high-resolution structures of chitinase A and its complex with the inhibitor allosamidin.

The purification scheme of chitinase A (ChiA) from S. marcescens has been extensively revised. The pure enzyme crystallizes readily under new crystallization conditions. The ChiA crystal structure has been refined to 1.55 A resolution and the crystal structure of ChiA co-crystallized with the inhibitor allosamidin has been refined to 1.9 A resolution. Allosamidin is located in the deep active-site tunnel of ChiA and interacts with three important residues: Glu315, the proton donor of the catalysis, Asp313, which adopts two conformations in the native structure but is oriented towards Glu315 in the inhibitor complex, and Tyr390, which lies opposite Glu315 in the active-site tunnel.

Phosphorylation of CK1δ: identification of Ser370 as the major phosphorylation site targeted by PKA in vitro and in vivo

The involvement of CK1 (casein kinase 1) delta in the regulation of multiple cellular processes implies a tight regulation of its activity on many different levels. At the protein level, reversible phosphorylation plays an important role in modulating the activity of CK1delta. In the present study, we show that PKA (cAMP-dependent protein kinase), Akt (protein kinase B), CLK2 (CDC-like kinase 2) and PKC (protein kinase C) alpha all phosphorylate CK1delta. PKA was identified as the major cellular CK1deltaCK (CK1delta C-terminal-targeted protein kinase) for the phosphorylation of CK1delta in vitro and in vivo. This was implied by the following evidence: PKA was detectable in the CK1deltaCK peak fraction of fractionated MiaPaCa-2 cell extracts, PKA shared nearly identical kinetic properties with those of CK1deltaCK, and both PKA and CK1deltaCK phosphorylated CK1delta at Ser370 in vitro. Furthermore, phosphorylation of CK1delta by PKA decreased substrate phosphorylation of CK1delta in vitro. Mutation of Ser370 to alanine increased the phosphorylation affinity of CK1delta for beta-casein and the GST (gluthatione S-transferase)-p53 1-64 fusion protein in vitro and enhanced the formation of an ectopic dorsal axis during Xenopus laevis development. Anchoring of PKA and CK1delta to centrosomes was mediated by AKAP (A-kinase-anchoring protein) 450. Interestingly, pre-incubation of MiaPaCa-2 cells with the synthetic peptide St-Ht31, which prevents binding between AKAP450 and the regulatory subunit RII of PKA, resulted in a 6-fold increase in the activity of CK1delta. In summary, we conclude that PKA phosphorylates CK1delta, predominantly at Ser370 in vitro and in vivo, and that site-specific phosphorylation of CK1delta by PKA plays an important role in modulating CK1delta-dependent processes.

Crystallographic analysis of a thermoactive nitrilase.

The nitrilase superfamily is a large and diverse superfamily of enzymes that catalyse the cleavage of various types of carbon-nitrogen bonds using a Cys-Glu-Lys catalytic triad. Thermoactive nitrilase from Pyrococcus abyssi (PaNit) hydrolyses small aliphatic nitriles like fumaro- and malononitryl. Yet, the biological role of this enzyme is unknown. We have analysed several crystal structures of PaNit: without ligands, with an acetate ion bound in the active site and with a bromide ion in the active site. In addition, docking calculations have been performed for fumaro- and malononitriles. The structures provide a proof for specific binding of the carboxylate ion and a general affinity for negatively changed ligands. The role of residues in the active site is considered and an enzymatic reaction mechanism is proposed in which Cys146 acts as the nucleophile, Glu42 as the general base, Lys113/Glu42 as the general acid, WatA as the hydrolytic water and Nζ_Lys113 and N_Phe147 form the oxyanion hole.

Insights into the role of the (α + β) insertion in the TIM-barrel catalytic domain, regarding the stability and the enzymatic activity of Chitinase A from Serratia marcescens

Chitinase A (ChiA) from Serratia marcescens is a mesophilic enzyme with high catalytic activity and high stability. The crystal structure of ChiA has revealed a TIM-barrel fold of the catalytic domain, an (alpha+beta) insertion between the B7 beta-strand and A7 alpha-helix of the TIM-barrel, an FnIII domain at the N-terminus of the molecule and a hinge region that connects the latter to the catalytic domain. In this study, the role of the (alpha+beta) domain on the stability, catalytic activity and specificity of the enzyme was investigated by deleting this domain and studying the enzymatic and structural properties of the resulting truncated enzyme. The obtained data clearly show that by removing the (alpha+beta) domain, the thermal stability of the enzyme is substantially reduced, with an apparent T(m) of 42.0+/-1.0 degrees C, compared to the apparent T(m) of 58.1+/-1.0 degrees C of ChiA at pH 9.0. The specific activity of ChiADelta(alpha+beta) was substantially decreased, the pH optimum was shifted from 6.5 to 5.0 and the substrate and product specificities were altered.

The thermostability of DNA-binding protein HU from mesophilic, thermophilic, and extreme thermophilic bacteria

Abstract. Based on primary structure comparison between four highly homologous DNA-binding proteins (HUs) displaying differential thermostability, we have employed in vitro site-directed mutagenesis to decipher their thermostability mechanism at the molecular level. The contribution of the 11 amino acids that differ between the thermophilic HUBst from Bacillus stearothermophilus (Tm=61.6°C) and the mesophilic HUBsu from Bacillus subtilis (Tm=39.7°C) was evaluated by replacing these amino acids in HUBst with their mesophilic counterparts. Among 11 amino acids, three residues, Gly-15, Glu-34, and Val-42, which are highly conserved in the thermophilic HUs, have been found to be responsible for the thermostability of HUBst. These amino acids in combination (HUBst-G15E/E34D/V42I) reduce the thermostability of the protein (Tm=45.1°C) at the level of its mesophilic homologue HUBsu. By replacing these amino acids in HUBsu with their thermophilic counterparts, the HUBsu-E15G/D34E/I42V mutant was generated with thermostability (Tm=57.8°C) at the level of thermophilic HUBst. Employing the same strategy, we generated several mutants in the extremely thermophilic HUTmar from Thermotoga maritima (Tm=80.5°C), and obtained data consistent with the previous results. The triplet mutant HUTmar-G15E/E34D/V42I (Tm=35.9°C) converted the extremely thermophilic protein HUTmar to mesophilic. The various forms of HU proteins were overproduced in Escherichia coli, highly purified, and the thermostability of the mutants confirmed by circular dichroism spectroscopy. The results presented here were elucidated on the basis of the X-ray structure of HUBst and HUTmar (our unpublished results), and their mechanism was proposed at the molecular level. The results clearly show that three individual local interactions located at the helix-turn-helix part of the protein are responsible for the stability of HU proteins by acting cooperatively in a common mechanism for thermostability.

RNA Arbitrarily Primed PCR and Fourier Transform Infrared Spectroscopy Reveal Plasticity in the Acid Tolerance Response of Streptococcus macedonicus

ABSTRACT We have previously reported that an acid tolerance response (ATR) can be induced in Streptococcus macedonicus cells at mid-log phase after autoacidification, transient exposure to acidic pH, or acid habituation, as well as at stationary phase. Here, we compared the transcriptional profiles of these epigenetic phenotypes, by RNA arbitrarily primed PCR (RAP-PCR), and their whole-cell chemical compositions, by Fourier transform infrared spectroscopy (FT-IR). RAP-PCR fingerprints revealed significant differences among the phenotypes, indicating that gene expression during the ATR is influenced not only by the growth phase but also by the treatments employed to induce the response. The genes coding for the mannose-specific IID component, the 1,2-diacylglycerol 3-glucosyltransferase, the 3-oxoacyl-acyl carrier protein, the large subunit of carbamoyl-phosphate synthase, and a hypothetical protein were found to be induced at least under some of the acid-adapting conditions. Furthermore, principal component analysis of the second-derivative-transformed FT-IR spectra segregated S. macedonicus phenotypes individually in all spectral regions that are characteristic for major cellular constituents like the polysaccharides of the cell wall, fatty acids of the cell membrane, proteins, and other compounds that absorb in these regions. These findings provide evidence for major changes in cellular composition due to acid adaptation that were clearly different to some extent among the phenotypes. Overall, our data demonstrate the plasticity in the ATR of S. macedonicus, which reflects the inherent ability of the bacterium to adjust the response to the distinctiveness of the imposed stress condition, probably to maximize its adaptability.

HU Protein Induces Incoherent DNA Persistence Length

HU is a highly conserved protein that is believed to play an important role in the architecture and dynamic compaction of bacterial DNA. Its ability to control DNA bending is crucial for functions such as transcription and replication. The effects of HU on the DNA structure have been studied so far mainly by single molecule methods that require us to apply stretching forces on the DNA and therefore may perturb the DNA-protein interaction. To overcome this hurdle, we study the effect of HU on the DNA structure without applying external forces by using an improved tethered particle motion method. By combining the results with DNA curvature analysis from atomic force microscopy measurements we find that the DNA consists of two different curvature distributions and the measured persistence length is determined by their interplay. As a result, the effective persistence length adopts a bimodal property that depends primarily on the HU concentration. The results can be explained according to a recently suggested model that distinguishes single protein binding from cooperative protein binding.

COMPACTION AND SUPERCOILING OF SINGLE, LONG DNA MOLECULES BY HU PROTEIN

The bacterial cell contains the highly conserved protein HU in abundance. To characterize its architectural role, we studied the elastic behavior of single, supercoilable DNA molecules (tens of kilobases long) in solution with HU from B. stearothermophilus (BstHU) by a micromanipulation assay. We point out quantitative yet notable differences to the behavior of HU from E. coli (EcoHU) observed by others. Our main contribution here, however, is to characterize the interaction of BstHU with single molecules of DNA in arbitrary states of supercoiling. BstHU clearly distinguishes under- and overwound substrates, breaking the characteristic symmetry in the elastic response of bare DNA. We demonstrate that BstHU shifts the preferred linking number of the complex, consistent with a model in which bound proteins untwist the double helix. The model qualitatively explains various features, such as overall compaction and weaker dependence on supercoiling, by a softening of the DNA to twist and bending. Previously reported reversal of binding effects at protein concentrations above a threshold also extends to supercoiling. All observed effects are highly sensitive to salt concentrations. Their range and magnitude lend HU great versatility in dynamically altering the physical properties and organization of the nucleoid.