Raffaele Raucci

Functional and structural features of adipokine family.

In the mid-1990s, the interest in adipose tissue was revived by the discovery of leptin. Since then numerous other hormones have been isolated from white adipose tissue that has no longer considered an inert tissue mainly devoted to energy storage but emerged as an active participant in regulating physiologic and pathologic processes, including immunity and inflammation. Adipose tissue produces and releases a variety of proinflammatory and anti-inflammatory factors, including the adipokines, as well as cytokines and chemokines. Proinflammatory molecules produced by adipose tissue have been implicated as active participants in the development of insulin resistance and the increased risk of cardiovascular disease associated with obesity. In contrast, reduced leptin levels might predispose to increased susceptibility to infection caused by reduced T-cell responses in malnourished individuals. Altered adipokine levels have been observed in a variety of inflammatory conditions, although their pathogenic role has not been completely clarified. In this paper we want to review: (i) the role of adipose tissue in different biological processes, (ii) the functional and structural description of all the known adipokines subdivided in different subfamilies, (iii) the adipokine involvement in obesity and cancers, and (iv) the adipokine interactome.

Genealogy of an ancient protein family: the Sirtuins, a family of disordered members

BackgroundSirtuins genes are widely distributed by evolution and have been found in eubacteria, archaea and eukaryotes. While prokaryotic and archeal species usually have one or two sirtuin homologs, in humans as well as in eukaryotes we found multiple versions and in mammals this family is comprised of seven different homologous proteins being all NAD-dependent de-acylases. 3D structures of human SIRT2, SIRT3, and SIRT5 revealed the overall conformation of the conserved core domain but they were unable to give a structural information about the presence of very flexible and dynamically disordered regions, the role of which is still structurally and functionally unclear. Recently, we modeled the 3D-structure of human SIRT1, the most studied member of this family, that unexpectedly emerged as a member of the intrinsically disordered proteins with its long disordered terminal arms. Despite clear similarities in catalytic cores between the human sirtuins little is known of the general structural characteristics of these proteins. The presence of disorder in human SIRT1 and the propensity of these proteins in promoting molecular interactions make it important to understand the underlying mechanisms of molecular recognition that reasonably should involve terminal segments. The mechanism of recognition, in turn, is a prerequisite for the understanding of any functional activity. Aim of this work is to understand what structural properties are shared among members of this family in humans as well as in other organisms.ResultsWe have studied the distribution of the structural features of N- and C-terminal segments of sirtuins in all known organisms to draw their evolutionary histories by taking into account average length of terminal segments, amino acid composition, intrinsic disorder, presence of charged stretches, presence of putative phosphorylation sites, flexibility, and GC content of genes. Finally, we have carried out a comprehensive analysis of the putative phosphorylation sites in human sirtuins confirming those sites already known experimentally for human SIRT1 and 2 as well as extending their topology to all the family to get feedback of their physiological functions and cellular localization.ConclusionsOur results highlight that the terminal segments of the majority of sirtuins possess a number of structural features and chemical and physical properties that strongly support their involvement in activities of recognition and interaction with other protein molecules. We also suggest how a multisite phosphorylation provides a possible mechanism by which flexible and intrinsically disordered segments of a sirtuin supported by the presence of positively or negatively charged stretches might enhance the strength and specificity of interaction with a particular molecular partner.

Common structural interactions between the receptors CXCR3, CXCR4 and CXCR7 complexed with their natural ligands, CXCL11 and CXCL12, by a modeling approach

Chemokine receptor trio composed by CXCR3, CXCR4 and CXCR7 represents a hard and interesting challenge for cancer biology because these three receptors are found to be over-expressed in different cancers as well as to bind the same chemokines. In fact, CXCR4 interacts with CXCL12, CXCR7 not only with CXCL12 but also with CXCL11, that is a natural ligand for CXCR3. For these reasons, it seems necessary to define and to identify the structural determinants of CXCR3, CXCR4 and CXCR7 and their related physic-chemical properties that permit them to bind CXCL11 and CXCL12. Hence in this paper we show the modeling of CXCR7 and its complex with CXCL11 and CXCL12 compared to CXCR3/CXCL11 and CXCR4/CXCL12. Our results show that (i) CXCR3, CXCR4 and CXCR7 present similar trans-membrane helices and different conformations of N-terminal and C-terminal regions as well as of three extracellular loops, and (ii) the predominant interaction between the three receptors and the two chemokines are on hydrophobic and electrostatic basis. Moreover, our data confirm that CXCL12 binds to CXCR7 with higher affinity than to CXCR4. Methodologically, we can also conclude that our computational strategy is adequate to model correctly the interactions between these chemokines and their receptors; therefore, our models represent a good structural basis to design and develop peptides able to block contemporaneously CXCR3, CXCR4 and CXCR7 receptor trio.

Structure–function relationship and evolutionary history of the human selenoprotein M (SelM) found over-expressed in hepatocellular carcinoma

In humans we know 25 selenoproteins that play important roles in redox regulation, detoxification, immune-system protection and viral suppression. In particular, selenoprotein M (SelM) may function as thiol disulfide oxidoreductase that participates in the formation of disulfide bonds, and can be implicated in calcium responses. However, it presents a redox motif (CXXU), where U is a selenocysteine, and may also function as redox regulator because its decreased or increased expression regulated by dietary selenium alters redox homeostasis. No data are reported in literature about its involvement in cancer but only in neurodegenerative diseases. In this paper we evaluated the SelM expression in two hepatoma cell lines, HepG2 and Huh7, compared to normal hepatocytes. The results suggested its involvement in hepatocellular carcinoma (HCC) as well as its possible use to follow the progression of this cancer as putative marker. The aim of this study has been to analyze the structure-function relationships of SelM. Hence, firstly we studied the evolutionary history of this protein by phylogenetic analysis and GC content of genes from various species. So, we modeled the three-dimensional structure of the human SelM evaluating its energetic stability by molecular dynamics simulations. Moreover, we modeled some of its mutants to obtain structural information helpful for structure-based drug design.

Peptide Folding Problem: A Molecular Dynamics Study on Polyalanines Using Different Force Fields

In the last decade many advances have been made on molecular dynamics simulations and different force fields were developed from the combination of differentiable functions of the atomic coordinates to represent the system energy and of parameters that describe the geometric and energetic properties of inter-particle interactions. However, it has been shown that very subtle modifications to commonly used molecular mechanical potentials can significantly alter the behavior of those potentials inducing stabilizing or destabilizing effects in the patterns of peptides or proteins. In this article we describe the behavior of polyalanine peptides under the influence of various “force fields”. The polyalanines were chosen as study model since their structural features were already studied experimentally and thus our computational results were easily comparable with the experimental ones. In particular, three peptides composed of 8, 10 and 12 alanine residues were subjected to molecular dynamics simulations using 12 different force fields to understand what is the most appropriate force field to properly simulate their folding. Our results showed that Amber99ϕ is the best force field able to generate helical conformations in agreement with experimental data.

Peptides targeting chemokine receptor CXCR4: structural behavior and biological binding studies.

CXCR4 is a G‐protein‐coupled receptor involved in a number of physiological processes in the hematopoietic and immune systems. CXCL12/CXCR4 axis plays a central role in diseases, such as HIV, cancer, WHIM syndrome, rheumatoid arthritis, pulmonary fibrosis, and lupus and, hence, indicated as putative therapeutic target. Although multiple CXCR4 antagonists have been developed, there is only one marketed drug, plerixafor, indicated for stem cell mobilization in poor mobilizer patients. In this work, we have designed and synthesized two peptides, six and seven residues long, using as template the N‐terminal region of CXCL12; analyzed their conformations by CD, NMR, and molecular dynamics simulations; simulated their complexes with CXCR4 by docking methods; and validated these data by in vitro studies. The results showed that the two peptides are rather flexible in aqueous solution lacking ordered secondary structure elements and present a promising affinity for CXCR4. This affinity is not revealed for CXCR7, indicating a specificity for CXCR4. Copyright

An overview of the sequence features of N- and C-terminal segments of the human chemokine receptors.

Chemokine receptors play a crucial role in the cellular signaling enrolling extracellular ligands chemotactic proteins which recruit immune cells. They possess seven trans-membrane helices, an extracellular N-terminal region with three extracellular hydrophilic loops being important for search and recognition of specific ligand(s), and an intracellular C-terminal region with three intracellular loops that couple G-proteins. Although the functional aspects of the terminal segments of the extra-and intra-cellular G proteins are universally identified, the molecular basis on which they rest are still unclear because they are not definable by means of X-rays due to their high mobility and are not easy to study in the membrane. The purpose of this work is to define which physical-chemical properties of the terminal segments of the human chemokine receptors are at the basis of their functional mechanisms. Therefore, we have evaluated their physical-chemical properties in terms of amino acid composition, local flexibility, disorder propensity, net charge distribution and putative sites of post-translational modifications. Our results support the conclusion that all 19 C-terminal and N-terminal segments of human chemokine receptors are very flexible due to the systematic presence of intrinsic disorder. Although, the purpose of this plasticity clearly appears that of controlling and modulating the binding of ligands, we provide evidence that the overlap of linearly charged stretches, intrinsic disorder and post-translational modification sites, consistently found in these motives, is a necessary feature to exert the function. The role of the intrinsic disorder has been discussed considering the structural information coming from intrinsically disordered model compounds which support the view that the chemokine terminals have to be considered as strong polyampholytes or polyelectrolytes where conformational ensembles and structural transitions between them are modulated by charge fraction variations. Also the role of post-translational modifications has been found coherent with this view because, changing the charge fraction, they guide structural transitions between ensembles. Moreover, we have also considered our results from an evolutionary point of view in order to understand if the features found in humans were also present in other species. Our data evidenced that the structural features of the human terminals of the chemokine receptors were shared and evolutionarily conserved particularly among mammals. This means that the various organisms not only tolerate but select intrinsic disorder for the terminal regions of their receptors, reflecting constraints that point to molecular recognition. In conclusion the terminal segments of chemokine receptors must be considered as strong polyampholytes where the charge fraction variations induced by post-translational modifications are the driving physico-chemical feature able to adapt the conformations of the terminal segments to their functions.

N-terminal region of human chemokine receptor CXCR3: Structural analysis of CXCR3(1–48) by experimental and computational studies

Our study on the highly charged N-terminal peptide of the human chemokine receptor CXCR3 by spectroscopic methods in solution and by means of molecular dynamics simulations showed that the charge content modulates the intrinsic structural preference of its flexible backbone. Collectively, our findings suggest that the structural organization of a protein should be seen as a part of a continuum in which the ratio between electrostatic and hydrophobic interactions and the intrinsic flexibility are important properties used to optimize the folding. When this ratio changes and the structure is intrinsically flexible, the structural organization of the system moves along the continuum of the possible conformational states. By all this combined information, one can describe the structure of CXCR3(1-48) as an ensemble of conformations. In fact, the peptide shows stretches of negative charges embedded in a flexible sequence which can be used to maximize promiscuous interactions relevant to molecular recognition but globally the peptide appears as a poly-structured globule-like ensemble that is dynamically stabilized by H-bonds. We have approached the study of the most populated ensembles with subset selection to explain our experimental data also by evidencing that the changes into the fraction of charged residues discriminate between dynamically poly-structured states, conceivably because of small free energy barriers existing between the different conformations of CXCR3(1-48). Therefore, the overlap of a highly flexible backbone, negatively charged residues and sites which can be modified by post-translational modifications represent the structural organization that controls the molecular mechanisms underlying the biological functions carried out by CXCR3(1-48).

The N-terminal Region of CXCL11 as Structural Template for CXCR3 Molecular Recognition: Synthesis, Conformational Analysis, and Binding Studies

The chemokines and their receptors play a key role in immune and inflammatory responses by promoting recruitment and activation of different subpopulations of leukocytes. The membrane receptor CXCR3 binds three chemokines, CXCL9, CXCL10, and CXCL11, and its involvement is recognized in many inflammatory diseases and cancers. Therefore, the inhibition of CXCR3 pathway through interactions with three ligands was indicated as putative therapeutic target for the treatment of these diseases, and some inhibitory compounds have already been described in the literature. Recently, we studied the interaction between CXCR3 and its three natural ligands and showed that three CXCR3 ligands bound the receptor mainly by their N‐terminal regions using aromatic and electrostatic interactions, and, in particular, CXCL11 had the highest affinity for CXCR3. In light of these results, we focused our attention on what structural region(s) of CXCL11 interacted with CXCR3 and what were the structural features. Therefore, we have synthesized three peptides, corresponding to the N‐terminal region of CXCL11, but with different aromatic amino acids, analyzed their conformations by circular dichroism, NMR, and molecular dynamics simulations, simulated their complexes with CXCR3 by docking methods, and validated these data by in vitro studies. The results showed that two peptides were able to bind CXCR3 and to mimic the molecular recognition of CXCL11 and demonstrated that N‐terminal region of CXCL11 can be used as template and starting point to obtain new molecules by de novo design approaches.

Structure–fluctuation–function relationships of seven pro-angiogenic isoforms of VEGFA, important mediators of tumorigenesis

Vascular endothelial growth factor A (VEGFA) has different biological activities and plays a central role in tumor proliferation, angiogenesis and metastasis. Different VEGFA isoforms are generated by alternative splice site selection of exons 6, 7 and 8. In this paper, we analyzed the physical and chemical properties of the VEGFA exon 6 sequence, and modeled the three-dimensional structures of the regions corresponding to exons 6, 7 and 8 of six different pro-angiogenic isoforms of VEGFA in comparison to the experimental structure of VEGFA_165 by a combined approach of fold recognition and comparative modeling strategies and molecular dynamics simulations. Our results showed that i) exon 6 is a very flexible polycation with high disordered propensity, features well conserved in all mammals, ii) the structures of all the isoforms are stabilized by H-bond sub-networks organized around HUB residues and, iii) the charge content of exon 6 modulates the intrinsic structural preference of its flexible backbone, which can be described as an ensemble of conformations. Moreover, complexes between NRP-1 and VEGFA isoforms were modeled by molecular docking to study what isoforms are able to bind NRP-1. The analysis of complexes evidenced that VEGFA_121, VEGFA_145, VEGFA_183, VEGFA_189 and VEGFA_206, containing exons 7 and 8a, are able to interact with NRP-1 because they have the key regions of exons 7b and/or 8a. An overview of the isoforms shows how the fluctuations are the main guidance of their biological function. MD simulations also provide insights into factors that stabilize the binding regions of isoforms.