Emma Langella

Structural and inhibition insights into carbonic anhydrase CDCA1 from the marine diatom Thalassiosira weissflogii

Carbonic anhydrases (CAs) catalyze with high efficiency the reversible hydration of carbon dioxide, an essential reaction for many biological processes, such as photosynthesis, respiration, renal tubular acidification, and bone resorption. Diatoms, which are one of the most common types of phytoplankton and are widespread in oceans, possess CAs fundamental for acquisition of inorganic carbon. Recently, in the marine diatom Thalassiosira weissflogii a novel enzyme, CDCA1, naturally using Cd in its active site, has been isolated and categorized in a new CA class, namely zeta-CA. This enzyme, which consists of three repeats (R1, R2 and R3), is a cambialistic carbonic anhydrase that can spontaneously exchange Zn or Cd at its active centre, presumably an adaptative advantage for diatoms that grow fast in the metal-poor environment of the surface ocean. In this paper we completed the characterization of this enzyme, reporting the X-ray structure of the last repeat, CDCA1-R3 in its cadmium-bound form, and presenting a model of the full length protein obtained by docking approaches. Results show that CDCA1 has a quite compact not symmetric structure, characterized by two covalently linked R1-R2 and R2-R3 interfaces and a small non-covalent R1-R3 interface. The three dimensional arrangement shows that most of the non-conserved aminoacids of the three repeats are located at the interface regions and that the active sites are far from each other and completely accessible to the substrate. Finally, a detailed inhibition study of CDCA1-R3 repeat in both cadmium- and zinc- bound form has been performed with sulfonamides and sulfamates derivatives. The results have been compared with those previously reported for other CA classes, namely alpha- and beta-classes, and correlated with the structural features of these enzymes.

Assessing the acid–base and conformational properties of histidine residues in human prion protein (125–228) by means of pKa calculations and molecular dynamics simulations

A thorough study of the acid–base behavior of the four histidines and the other titratable residues of the structured domain of human prion protein (125–228) is presented. By using multi‐tautomer electrostatic calculations, average titration curves have been built for all titratable residues, using the whole bundles of NMR structures determined at pH 4.5 and 7.0. According to our results, (1) only histidine residues are likely to be involved in the first steps of the pH‐driven conformational transition of prion protein; (2) the pKas of His140 and His177 are ≈7.0, whereas those of His155 and His187 are < 5.5. 10‐ns long molecular dynamics simulations have been performed on five different models, corresponding to the most significant combinations of histidine protonation states. A critical comparison between the available NMR structures and our computational results (1) confirms that His155 and His187 are the residues whose protonation is involved in the conformational rearrangement of huPrP in mildly acidic condition, and (2) shows how their protonation leads to the destructuration of the C‐terminal part of HB and to the loss of the last turn of HA that represent the crucial microscopic steps of the rearrangement. Proteins 2006.

Acylpeptide Hydrolase Inhibition as Targeted Strategy to Induce Proteasomal Down-Regulation

Acylpeptide hydrolase (APEH), one of the four members of the prolyl oligopeptidase class, catalyses the removal of N-acylated amino acids from acetylated peptides and it has been postulated to play a key role in protein degradation machinery. Disruption of protein turnover has been established as an effective strategy to down-regulate the ubiquitin-proteasome system (UPS) and as a promising approach in anticancer therapy. Here, we illustrate a new pathway modulating UPS and proteasome activity through inhibition of APEH. To find novel molecules able to down-regulate APEH activity, we screened a set of synthetic peptides, reproducing the reactive-site loop of a known archaeal inhibitor of APEH (SsCEI), and the conjugated linoleic acid (CLA) isomers. A 12-mer SsCEI peptide and the trans10-cis12 isomer of CLA, were identified as specific APEH inhibitors and their effects on cell-based assays were paralleled by a dose-dependent reduction of proteasome activity and the activation of the pro-apoptotic caspase cascade. Moreover, cell treatment with the individual compounds increased the cytoplasm levels of several classic hallmarks of proteasome inhibition, such as NFkappaB, p21, and misfolded or polyubiquitinylated proteins, and additive effects were observed in cells exposed to a combination of both inhibitors without any cytotoxicity. Remarkably, transfection of human bronchial epithelial cells with APEH siRNA, promoted a marked accumulation of a mutant of the cystic fibrosis transmembrane conductance regulator (CFTR), herein used as a model of misfolded protein typically degraded by UPS. Finally, molecular modeling studies, to gain insights into the APEH inhibition by the trans10-cis12 CLA isomer, were performed. Our study supports a previously unrecognized role of APEH as a negative effector of proteasome activity by an unknown mechanism and opens new perspectives for the development of strategies aimed at modulation of cancer progression.

Does tetracycline bind helix 2 of prion? An integrated spectroscopical and computational study of the interaction between the antibiotic and α helix 2 human prion protein fragments

We demonstrate here that tetracycline (TC) can strongly interact (KD′ = 189 ± 7 nM) with model peptides derived from the C‐terminal globular domain of the prion protein, hPrP [173‐195], and that interaction concerns residues within the C‐terminal half of the helix 2, a short region previously indicated as endowed with ambivalent conformational behavior and implicated in PrP conversion to the β‐sheet‐rich, infective scrapie variant. Data have been confirmed by binding studies with the N‐terminal truncated 180‐195 variant that displays a dissociation constant of 483 ± 30 nM. Remarkably, TC does not influence the structure of the N‐terminally fluoresceinated peptides that both show α‐helical conformations. Docking calculations and molecular dynamics simulations suggest a direct, strong interaction of the antibiotic with exposed side chain functional groups of threonines 190‐193 on the solvent‐exposed surface of helix 2. Proteins 2007

Insights into the mechanism of interaction between trehalose-conjugated beta-sheet breaker peptides and Aβ(1–42) fibrils by molecular dynamics simulations

An attractive strategy to contrast the Alzheimer disease (AD) is represented by the development of β-sheet breaker peptides (BSB). β-sheet breakers constitute a class of compounds which have shown a good efficacy in preventing the Aβ fibrillogenesis; however, their mechanism of action has not been precisely understood. In this context, we have studied the structural basis underlying the inhibitory effect of Aβ(1-42) fibrillogenesis explicated by two promising trehalose-conjugated BSB peptides using an all-atom molecular dynamics (MD) approach. Our simulations suggest that the binding on the two protofibril ends occurs through different binding modes. In particular, binding on the odd edge (chain A) is guided by a well defined hydrophobic cleft, which is common to both ligands. Moreover, targeting chain A entails a significant structure destabilization leading to a partial loss of β structure and is an energetically favoured process. A significant contribution of the trehalose moiety to the stability of the complexes emerged from our results. The energetically favoured hydrophobic cleft detected on chain A could represent a good starting point for the design of new molecules with improved anti-aggregating features.

A Combined Crystallographic and Theoretical Study Explains the Capability of Carboxylic Acids to Adopt Multiple Binding Modes in the Active Site of Carbonic Anhydrases.

Carboxylates are the least investigated class of inhibitors of carbonic anhydrases (CAs). Here we explain the versatility of binding of these molecules to CAs by examining a new adduct of hCA II with N-carboxymethyl-saccharin.

Exploring the catalytic mechanism of the first dimeric Bcp: Functional, structural and docking analyses of Bcp4 from Sulfolobus solfataricus

The detoxification from peroxides in Sulfolobus solfataricus is performed by the Bacterioferritin comigratory proteins (Bcps), Bcp1 (Sso2071), Bcp2 (Sso2121), Bcp3 (Sso2255) and Bcp4 (Sso2613), antioxidant enzymes belonging to one of the subfamilies of the Peroxiredoxins. In this paper we report on the functional, structural and docking analyses of Bcp4, characterized by the CXXXXC motif in the active site. Bcp4 represents the first dimeric Bcp so far investigated. Biochemical studies showed that the protein has a non-covalent dimeric structure and adopts an atypical 2-Cys catalytic mechanism. The X-ray structure of the double mutant C45S/C50S, representative of the fully reduced enzyme state, described the protein dimeric arrangement. Finally, concurrent availability of the crystallographic structure of the monomeric Bcp1 allowed comparative analysis of the interaction with Protein Disulfide Oxidoreductase SsPDO (Sso0192), involved in the reduction of both Bcp1 and Bcp4, through a protein-protein docking approach.

Cadmium-Containing Carbonic Anhydrase CDCA1 in Marine Diatom Thalassiosira weissflogii

The Carbon Concentration Mechanism (CCM) allows phytoplakton species to accumulate the dissolved inorganic carbon (DIC) necessary for an efficient photosynthesis even under carbon dioxide limitation. In this mechanism of primary importance for diatoms, a key role is played by carbonic anhydrase (CA) enzymes which catalyze the reversible hydration of CO2, thus taking part in the acquisition of inorganic carbon for photosynthesis. A novel CA, named CDCA1, has been recently discovered in the marine diatom Thalassiosira weissflogii. CDCA1 is a cambialistic enzyme since it naturally uses Cd2+ as catalytic metal ion, but if necessary can spontaneously exchange Cd2+ to Zn2+. Here, the biochemical and structural features of CDCA1 enzyme will be presented together with its putative biotechnological applications for the detection of metal ions in seawaters.

Insights into the role of reactive sulfhydryl groups of carbonic anhydrase III and VII during oxidative damage

Abstract Carbonic anhydrases (CAs) III and VII are two cytosolic isoforms of the α-CA family which catalyze the physiological reaction of carbon dioxide hydration to bicarbonate and proton. Despite these two enzymes share a 49% sequence identity and present a very similar three-dimensional structure, they show profound differences when comparing the specific activity for CO2 hydration reaction, with CA VII being much more active than CA III. Recently, CA III and CA VII have been proposed to play a new role as scavenger enzymes in cells where oxidative damage occurs. Here, we will examine functional and structural features of these two isoforms giving insights into their newly proposed protective role against oxidative stress.

Conformational studies of chiral d-Lys-PNA and achiral PNA system in binding with DNA or RNA through a molecular dynamics approach

The growing interest in peptide nucleic acid (PNA) oligomers has led to the development of a very wide variety of PNA derivatives. Among others, the introduction of charged chiral groups on a PNA oligomer has proven effective in improving DNA binding ability, complexation direction and cellular uptake. In particular, the introduction of three adjacent chiral monomers based on D-Lys in the middle of the PNA sequence (D-Lys-PNA) has produced noteworthy results in modulating the directionality of the binding with the DNA complementary strand and in mismatch detection. Here, through a molecular dynamics approach, a comparative study has been carried out to investigate the structural properties that drive the interaction of the chiral D-Lys-PNA and the corresponding achiral PNA system with DNA as well as RNA complementary strands, starting from the crystal structure of D-Lys-PNA in complex with DNA. The results obtained complement experimental data and indicate that the binding with the RNA molecule, compared to DNA, is differently affected by the addition of three D-Lys groups on the PNA backbone, suggesting that this modification could be taken into account for the development of new PNA-based molecules able to discriminate between DNA and RNA.