Elio Pizzo

Ribonuclease/angiogenin inhibitor 1 regulates stress-induced subcellular localization of angiogenin to control growth and survival.

Summary Angiogenin (ANG) promotes cell growth and survival. Under growth conditions, ANG undergoes nuclear translocation and accumulates in the nucleolus where it stimulates rRNA transcription. When cells are stressed, ANG mediates the production of tRNA-derived stress-induced small RNA (tiRNA), which reprograms protein translation into a survival mechanism. The ribonucleolytic activity of ANG is essential for both processes but how this activity is regulated is unknown. We report here that ribonuclease/angiogenin inhibitor 1 (RNH1) controls both the localization and activity of ANG. Under growth conditions, ANG is located in the nucleus and is not associated with RNH1 so that the ribonucleolytic activity is retained to ensure rRNA transcription. Cytoplasmic ANG is associated with and inhibited by RNH1 so that random cleavage of cellular RNA is prevented. Under stress conditions, ANG is localized to the cytoplasm and is concentrated in stress granules where it is not associated with RNH1 and thus remains enzymatically active for tiRNA production. By contrast, nuclear ANG is associated with RNH1 in stressed cells to ensure that the enzymatic activity is inhibited and no unnecessary rRNA is produced to save anabolic energy. Knockdown of RNH1 abolished stress-induced relocalization of ANG and decreased cell growth and survival.

Ribonucleases with angiogenic and bactericidal activities from the Atlantic salmon

The importance of fish in vertebrate evolution has been better recognized in recent years after the intense work carried out on fish genomics. The recent discovery that fish genomes comprise homologs of ribonucleases, studied before only in tetrapods, and the isolation of ribonucleases from zebrafish have suggested an experimental model for studying fish and vertebrate evolution. Thus, the cDNAs encoding the RNases from the Atlantic salmon were expressed, and the recombinant RNases (Ss‐RNase‐1 and Ss‐RNase‐2) were isolated and characterized as both proteins and for their biological activities. Salmon RNases are less active than RNase A in degrading RNA, but are both sensitive to the action of the human cytosolic RNase inhibitor. The two enzymes possess both angiogenic and bactericidal activities. However, catalytically inactivated Ss‐RNases do not exert any angiogenic activity, but preserve their full bactericidal activity, which is surprisingly preserved even when the enzyme proteins are fully denatured. Analyses of the conformational stability of the two RNases has revealed that they are as stable as typical RNases of the superfamily, and Ss‐RNase‐2, the most active as an enzyme, is also the most resistant to thermal and chemical denaturation. The implications of these findings in terms of the evolution of early RNases, in particular of the physiological significance of the angiogenic and bactericidal activities of fish RNases, are analyzed and discussed.

Ribonucleases and Angiogenins from Fish

For the first time fish RNases have been isolated and characterized. Their functional and structural properties indicate that they belong to the RNase A superfamily (or tetrapod RNase superfamily), now more appropriately described as the vertebrate RNase superfamily. Our findings suggest why previously repeated efforts to isolate RNases from fish tissues have met with no success; fish RNases have a very low ribonucleolytic activity, and their genes have a low sequence identity with those of mammalian RNases. The investigated RNases are from the bony fish Danio rerio (or zebrafish). Their cDNAs have been cloned and expressed, and the three recombinant proteins have been purified to homogeneity. Their characterization has revealed that they have indeed a very low RNA-degrading activity, when compared with that of RNase A, the superfamily prototype, but comparable with that of mammalian angiogenins; that two of them have angiogenic activity that is inhibited by the cytosolic RNase inhibitor. These data and a phylogenetic analysis indicate that angiogenic fish RNases are the earliest diverging members of the vertebrate superfamily, suggesting that ribonucleases with angiogenic activity were the ancestors of all ribonucleases in the superfamily. They later evolved into both mammalian angiogenins and, through a successful phylogenesis, RNases endowed with digestive features or with diverse bioactivities.

The Buried Diversity of Bovine Seminal Ribonuclease: Shape and Cytotoxicity of the Swapped Non-covalent Form of the Enzyme

Bovine seminal ribonuclease exists in the native state as an equilibrium mixture of a swapped and an unswapped dimer. The molecular envelope and the exposed surface of the two isomers are practically indistinguishable and their diversity is almost completely buried in the interior of the protein. Surprisingly, the cytotoxic and antitumor activity of the enzyme is a peculiar property of the swapped dimer. This buried diversity comes into light in the reducing environment of the cytosol, where the unswapped dimer dissociates into monomers, whereas the swapped one generates a metastable dimeric form (NCD-BS) with a quaternary assembly that allows the molecule to escape the protein inhibitor of ribonucleases. The stability of this quaternary shape was mainly attributed to the combined presence of Pro19 and Leu28. We have prepared and fully characterized by X-ray diffraction the double mutant P19A/L28Q (PALQ) of the seminal enzyme. While the swapped and unswapped forms of the mutant have structures very similar to that of the corresponding wild-type forms, the non-covalent form (NCD-PALQ) adopts an opened quaternary structure, different from that of NCD-BS. Moreover, model building clearly indicates that NCD-PALQ can be easily sequestered by the protein inhibitor. In agreement with these results, cytotoxic assays have revealed that PALQ has limited activity, whereas the single mutants P19A and L28Q display cytotoxic activity against malignant cells almost as large as the wild-type enzyme. The significant increase in the antitumor activity, brought about by the substitution of just two residues in going from the double mutant to the wild-type enzyme, suggests a new strategy to improve this important biological property by strengthening the interface that stabilizes the quaternary structure of NCD-BS.

A new RNase sheds light on the RNase/angiogenin subfamily from zebrafish.

Recently, extracellular RNases of the RNase A superfamily, with the characteristic CKxxNTF sequence signature, have been identified in fish. This has led to the recognition that these RNases are present in the whole vertebrate subphylum. In fact, they comprise the only enzyme family unique to vertebrates. Four RNases from zebrafish (Danio rerio) have been previously reported and have a very low RNase activity; some of these are endowed, like human angiogenin, with powerful angiogenic and bactericidal activities. In the present paper, we report the three-dimensional structure, the thermodynamic behaviour and the biological properties of a novel zebrafish RNase, ZF-RNase-5. The investigation of its structural and functional properties, extended to all other subfamily members, provides an inclusive description of the whole zebrafish RNase subfamily.

Enforcing the positive charge of N-termini enhances membrane interaction and antitumor activity of bovine seminal ribonuclease

Binding to cell membrane, followed by translocation into the cytosol and RNA degradation, is a necessary requirement to convert a ribonuclease into a cytotoxin for malignant tumor cells. In this paper, we investigate the membrane binding attitude of bovine seminal ribonuclease (BS-RNase) and its variant G38K-BS-RNase, bearing an enforced cluster of positive charges at the N-termini surface. By using a combination of biophysical techniques, including CD, SPR and ESR, we find for the two proteins a common, two-step mechanism of interaction with synthetic liposomes, an initial binding to the bilayer surface, driven by electrostatic interactions, followed by a shallow penetration in the lipid core. Protein binding effectively perturbs lipid packing and dynamics. Remarkably, the higher G38K-BS-RNase membrane interacting capability well correlates with its increased cytotoxicity for tumor cells. Overall, these studies shed light on the mechanism of membrane binding and perturbation, proving definitely the importance of electrostatic interactions in the cytotoxic activity of BS-RNase, and provide a rational basis to design proteins with anticancer potential.

Comparison of the Structural and Functional Properties of RNase A and BS-RNase: A Stepwise Mutagenesis Approach

The original structure of bovine seminal ribonuclease (BS‐RNase), solved in 1993, represents a milestone in the story of protein structure, because it represented the first X‐ray structure showing two polypeptide chains entangled through their terminal regions. It is generally assumed that this structural feature is the basis of several special biological activities, including a potent antitumor activity, but this has not been yet definitely proved. To assess this hypothesis, in this article we have analyzed the effects of the N‐terminal hinge region and/or of Arg80 on the swapping propensity and cytotoxicity in newly designed proteins, using a covalent dimeric variant of bovine pancreatic ribonuclease (RNase A) as scaffold. All the proteins have a very poor cytotoxic activity, independently on the swapping propensity, that can even reach the same value of native BS‐RNase. Overall our data suggest that the swapping represents still an essential requisite for the cytotoxic activity, because it keeps the dimeric structure stable even in the reducing cytosolic environment, but other features are essential to design dimeric antitumor ribonucleases, including a strong positive potential at the N‐terminal face and a quaternary structure able to evade the cytosolic ribonuclease inhibitor, with or without the interchain disulfide bridges.

A novel method for detection of selenomethionine incorporation in protein crystals via Raman microscopy.

Multiwavelength anomalous dispersion (MAD) is the most widespread approach in structural biology for the determination of the crystal structure of a novel protein. Mass spectrometry is currently used to evaluate the selenomethionine (SeMet) content in solution, but excluding fluorescence spectroscopy at the absorption edge, no other routine method to check the SeMet incorporation and storage in the crystal state is yet available. Raman microscopy is an increasingly popular tool in physical biochemistry, with applications ranging from studies of ligand binding to secondary-structure analysis. Here, a novel methodological development is presented for the analysis via Raman microscopy of SeMet-labelled protein crystals to be used for MAD crystallography. The method is described and supported by validation and application to two novel proteins (a betagamma-crystallin-like protein and a DNA-binding protein). Markers of the SeMet residues are in the range 570-600 cm(-1), where proteins do not usually show Raman bands.

An intron-less βγ-crystallin-type gene from the sponge Geodia cydonium

Abstract We report the cloning of a gene encoding a βγ-crystallin-type protein from a porifera, the Geodia cydonium sponge. The data provide direct, conclusive evidence of the existence of such a gene in the genome of an early diverged metazoan. The cloned gene is found to contain no introns, while proto-splice sites are identified in the nucleotide sequence at positions where introns are located in homologous, very recently diverged vertebrate genes. These findings are discussed in the light of the debate between the introns-late and introns-early theories.

A new cryptic cationic antimicrobial peptide from human apolipoprotein E with antibacterial activity and immunomodulatory effects on human cells

Cationic antimicrobial peptides (AMPs) possess fast and broad‐spectrum activity against both Gram‐negative and Gram‐positive bacteria, as well as fungi. It has become increasingly evident that many AMPs, including those that derive from fragments of host proteins, are multifunctional and able to mediate various immunomodulatory functions and angiogenesis. Among these, synthetic apolipoprotein‐derived peptides are safe and well tolerated in humans and have emerged as promising candidates in the treatment of various inflammatory conditions. Here, we report the characterization of a new AMP corresponding to residues 133–150 of human apolipoprotein E. Our results show that this peptide, produced either by chemical synthesis or by recombinant techniques in Escherichia coli, possesses a broad‐spectrum antibacterial activity. As shown for several other AMPs, ApoE (133–150) is structured in the presence of TFE and of membrane‐mimicking agents, like SDS, or bacterial surface lipopolysaccharide (LPS), and an anionic polysaccharide, alginate, which mimics anionic capsular exo‐polysaccharides of several pathogenic microorganisms. Noteworthy, ApoE (133–150) is not toxic toward several human cell lines and triggers a significant innate immune response, assessed either as decreased expression levels of proinflammatory cytokines in differentiated THP‐1 monocytic cells or by the induction of chemokines released from PBMCs. This novel bioactive AMP also showed a significant anti‐inflammatory effect on human keratinocytes, suggesting its potential use as a model for designing new immunomodulatory therapeutics.