M. Victòria Nogués

Mammalian antimicrobial proteins and peptides: overview on the RNase A superfamily members involved in innate host defence

The review starts with a general outlook of the main mechanisms of action of antimicrobial proteins and peptides, with the final aim of understanding the biological function of antimicrobial RNases, and identifying the key events that account for their selective properties. Although most antibacterial proteins and peptides do display a wide-range spectrum of action, with a cytotoxic activity against bacteria, fungi, eukaryotic parasites and viruses, we have only focused on their bactericidal activity. We start with a detailed description of the main distinctive structural features of the bacteria target and on the polypeptides, which act as selective host defence weapons.Following, we include an overview of all the current available information on the mammalian RNases which display an antimicrobial activity. There is a wealth of information on the structural, catalytic mechanism and evolutionary relationships of the RNase A superfamily. The bovine pancreatic RNase A (RNase A), the reference member of the mammalian RNase family, has been the main research object of several Nobel laureates in the 60s, 70s and 80s. A potential antimicrobial function was only recently suggested for several members of this family. In fact, the recent evolutionary studies indicate that this protein family may have started off with a host defence function. Antimicrobial RNases constitute an interesting example of proteins involved in the mammalian innate immune defence system. Besides, there is wealth of available information on the mechanism of action of short antimicrobial peptides, but little is known on larger polypeptides, that is, on proteins. Therefore, the identification of the mechanisms of action of antimicrobial RNases would contribute to the understanding of the proteins involved in the innate immunity.

Eosinophil cationic protein high-affinity binding to bacteria-wall lipopolysaccharides and peptidoglycans.

The eosinophil cationic protein (ECP) is an eosinophil-secreted RNase involved in the immune host defense, with a cytotoxic activity against a wide range of pathogens. The protein displays antimicrobial activity against both Gram-negative and Gram-positive strains. The protein can destabilize lipid bilayers, although the action at the membrane level can only partially account for its bactericidal activity. We have now shown that ECP can bind with high affinity to the bacteria-wall components. We have analyzed its specific association to lipopolysaccharides (LPSs), its lipid A component, and peptidoglycans (PGNs). ECP high-affinity binding capacity to LPSs and lipid A has been analyzed by a fluorescent displacement assay, and the corresponding dissociation constants were calculated using the protein labeled with a fluorophor. The protein also binds in vivo to bacteria cells. Ultrastructural analysis of cell bacteria wall and morphology have been visualized by scanning and transmission electron microscopy in both Escherichia coli and Staphylococcus aureus strains. The protein damages the bacteria surface and induces the cell population aggregation on E. coli cultures. Although both bacteria strain cells retain their shape and no cell lysis is patent, the protein can induce in E. coli the outer membrane detachment. ECP also activates the cytoplasmic membrane depolarization in both strains. Moreover, the depolarization activity on E. coli does not require any pretreatment to overcome the outer membrane barrier. The protein binding to the bacteria-wall surface would represent a first encounter step key in its antimicrobial mechanism of action.

AMPA: an automated web server for prediction of protein antimicrobial regions

SUMMARY AMPA is a web application for assessing the antimicrobial domains of proteins, with a focus on the design on new antimicrobial drugs. The application provides fast discovery of antimicrobial patterns in proteins that can be used to develop new peptide-based drugs against pathogens. Results are shown in a user-friendly graphical interface and can be downloaded as raw data for later examination. AVAILABILITY AMPA is freely available on the web at http://tcoffee.crg.cat/apps/ampa. The source code is also available in the web. CONTACT marc.torrent@upf.edu; david.andreu@upf.edu SUPPLEMENTARY INFORMATION Supplementary data are available at Bioinformatics online.

9 – Pancreatic Ribonucleases

Publisher Summary This chapter reviews recent data on several aspects of the catalytic mechanism of pancreatic RNases as well as some molecular properties such as carbohydrate content and folding and unfolding pathways. This chapter begins with a discussion on reaction catalyzed by pancreatic ribonucleases. The depolymerization of RNA by RNase is described as taking place in two steps: in the first step there is a transphosphorylation reaction from the 5′ position of one nucleotide to the 2′ position of the adjacent nucleotide with the formation of a 2′,3′-cyclic phosphodiester. In the second step, the 2′,3′-cyclic phosphodiester is hydrolyzed to a 3′ nucleotide. The description of this reaction has been a source of ambiguity with respect to the mechanism, especially as to the role of the 2′,3′-cyclic phosphodiesters. This chapter explains concepts related to the specificity of reaction and catalytic mechanism. It also describes structure and functions of substrate-binding subsites. An overview of structure and function of carbohydrate moiety is presented. The chapter concludes with a discussion on folding/unfolding studies of reduced/native RNase A.

Comparison of human RNase 3 and RNase 7 bactericidal action at the Gram-negative and Gram-positive bacterial cell wall

The eosinophil cationic protein/RNase 3 and the skin‐derived RNase 7 are two human antimicrobial RNases involved in host innate immunity. Both belong to the RNase A superfamily and share a high cationicity and a common structural architecture. However, they present significant divergence at their primary structures, displaying either a high number of Arg or Lys residues, respectively. Previous comparative studies with a membrane model revealed two distinct mechanisms of action for lipid bilayer disruption. We have now compared their bactericidal activity, identifying some features that confer specificity at the bacterial cell wall level. RNase 3 displays a specific Escherichia coli cell agglutination activity, which is not shared by RNase 7. The RNase 3 agglutination process precedes the bacterial death and lysis event. In turn, RNase 7 can trigger the release of bacterial cell content without inducing any cell aggregation process. We hypothesize that the RNase 3 agglutination activity may depend on its high affinity for lipopolysaccharides and the presence of an N‐terminal hydrophobic patch, and thus could facilitate host clearance activity at the infection focus by phagocytic cells. The present study suggests that the membrane disruption abilities do not solely explain the protein bacterial target preferences and highlights the key role of antimicrobial action at the bacterial cell wall level. An understanding of the interaction between antimicrobial proteins and their target at the bacterial envelope should aid in the design of alternative peptide‐derived antibiotics.

Surface-exposed amino acids of eosinophil cationic protein play a critical role in the inhibition of mammalian cell proliferation.

Eosinophil cationic protein (ECP) is a ribonuclease secreted from activated eosinophils that may cause tissue injure as a result of eosinophilic inflammation. ECP possesses bactericidal, antiviral and helminthotoxic activity and inhibits mammalian cell growth. The mechanism by which ECP exerts its toxicity is not known but it has been related to the ability of the protein to destabilise lipid bilayers. We have assessed the involvement of some cationic and aromatic surface exposed residues of ECP in the inhibition of proliferation of mammalian cell lines. We have constructed ECP mutants for the selected residues and assessed their ability to prevent cell growth. Trp10 and Trp35 together with the adjacent stacking residue are critical for the damaging effect of ECP on mammalian cell lines. These residues are also crucial for the membrane disruption activity of ECP. Other exposed aromatic residues packed against arginines (Arg75-Phe76 and Arg121-Tyr122) and specific cationic amino acids (Arg101and Arg104) of ECP play a secondary role in the cell growth inhibition. This may be related to the ability of the protein to bind carbohydrates such as those found on the surface of mammalian cells.

Exploring new biological functions of amyloids: bacteria cell agglutination mediated by host protein aggregation.

Antimicrobial proteins and peptides (AMPs) are important effectors of the innate immune system that play a vital role in the prevention of infections. Recent advances have highlighted the similarity between AMPs and amyloid proteins. Using the Eosinophil Cationic Protein as a model, we have rationalized the structure-activity relationships between amyloid aggregation and antimicrobial activity. Our results show how protein aggregation can induce bacteria agglutination and cell death. Using confocal and total internal reflection fluorescence microscopy we have tracked the formation in situ of protein amyloid-like aggregates at the bacteria surface and on membrane models. In both cases, fibrillar aggregates able to bind to amyloid diagnostic dyes were detected. Additionally, a single point mutation (Ile13 to Ala) can suppress the protein amyloid behavior, abolishing the agglutinating activity and impairing the antimicrobial action. The mutant is also defective in triggering both leakage and lipid vesicle aggregation. We conclude that ECP aggregation at the bacterial surface is essential for its cytotoxicity. Hence, we propose here a new prospective biological function for amyloid-like aggregates with potential biological relevance.

Comparison of the membrane interaction mechanism of two antimicrobial RNases: RNase 3/ECP and RNase 7

Eosinophil cationic protein (ECP/RNase 3) and the skin derived ribonuclease 7 (RNase 7) are members of the RNase A superfamily. RNase 3 is mainly expressed in eosinophils whereas RNase 7 is primarily secreted by keratinocytes. Both proteins present a broad-spectrum antimicrobial activity and their bactericidal mechanism is dependent on their membrane destabilizing capacities. Using phospholipid vesicles as membrane models, we have characterized the protein membrane association process. Confocal microscopy experiments using giant unilamellar vesicles illustrate the morphological changes of the liposome population. By labelling both lipid bilayers and proteins we have monitored the kinetic of the process. The differential protein ability to release the liposome aqueous content was evaluated together with the micellation and aggregation processes. A distinct morphology of the protein/lipid aggregates was visualized by transmission electron microscopy and the proteins overall secondary structure in a lipid microenvironment was assessed by FTIR. Interestingly, for both RNases the membrane interaction events take place in a different behaviour and timing: RNase 3 triggers first the vesicle aggregation, while RNase 7 induces leakage well before the aggregation step. Their distinct mechanism of action at the membrane level may reflect different in vivo antipathogen functions.

Lipopolysaccharide neutralization by antimicrobial peptides: a gambit in the innate host defense strategy.

Antimicrobial peptides (AMPs) are nowadays understood as broad multifunctional tools of the innate immune system to fight microbial infections. In addition to its direct antimicrobial action, AMPs can modulate the host immune response by promoting or restraining the recruitment of cells and chemicals to the infection focus. Binding of AMPs to lipopolysaccharide is a critical step for both their antimicrobial action and their immunomodulatory properties. On the one hand, removal of Gram-negative bacteria by AMPs can be an effective strategy to prevent a worsened inflammatory response that may lead to septic shock. On the other hand, by neutralizing circulating endotoxins, AMPs can successfully reduce nitric oxide and tumor necrosis factor-α production, hence preventing severe tissue damage. Furthermore, AMPs can also interfere with the Toll-like receptor 4 recognition system, suppressing cytokine production and contributing to modulate the inflammatory response. Here, we review the immune system strategies devised by AMPs to avoid an exacerbated inflammatory response and thus prevent a fatal end to the host.

Eosinophil cationic protein (ECP) can bind heparin and other glycosaminoglycans through its RNase active site.

The eosinophil cationic protein (ECP) is an eosinophil‐secreted RNase involved in the immune host defense, with a cytotoxic activity against a wide range of pathogens. During inflammation and eosinophilia disorders, ECP is secreted to the inflammation area, where it would contribute to the immune response. ECP secretion causes also severe damage to the host own tissues. ECP presents a high affinity for heparin and this property might be crucial for its immunomodulating properties, antipathogen action, and its toxicity against eukaryotic cells. ECP, also known as human RNase 3, belongs to the mammalian RNase A superfamily and its RNase activity is required for some of its biological properties. We have now proven that ECP heparin binding affinity depends on its RNase catalytic site, as the enzymatic activity is blocked by heparin. We have applied molecular modeling to analyze ECP binding to heparin representative probes, and identified protein residues at the catalytic and substrate binding sites that could contribute to the interaction. ECP affinity for heparin and other negatively charged glycosaminoglycans (GAGs) can explain not only its binding to the eukaryote cells glycocalix but also the reported high affinity for the specific carbohydrates at bacteria cell wall, promoting its antimicrobial action. Copyright