Structure-Based Design of an RNase Chimera for Antimicrobial Therapy

Bacterial resistance to antibiotics urges the development of alternative therapies. Based on the structure-function of antimicrobial members of the RNase A superfamily, we have developed a hybrid enzyme. Within this family, RNase 1 exhibits the highest catalytic activity and the lowest cytotoxicity; in contrast, RNase 3 shows the highest bactericidal action, alas with a reduced catalytic activity. Starting from both parental proteins, we designed a first RNase 3/1-v1 chimera. The construct had a catalytic activity much higher than RNase 3, unfortunately without reaching an equivalent antimicrobial activity. Thus, two new versions were created with improved antimicrobial properties. Both of these versions (RNase 3/1-v2 and -v3) incorporated an antimicrobial loop characteristic of RNase 3, while a flexible RNase 1-specific loop was removed in the latest construct. RNase 3/1-v3 acquired both higher antimicrobial and catalytic activities than previous versions, while retaining the structural determinants for interaction with the RNase inhibitor and displaying non-significant cytotoxicity. Following, we tested the constructs’ ability to eradicate macrophage intracellular infection and observed an enhanced ability in both RNase 3/1-v2 and v3. Interestingly, the inhibition of intracellular infection correlates with the variants’ capacity to induce autophagy. We propose RNase 3/1-v3 chimera as a promising lead for applied therapeutics.

Magnetite Nanoparticles Functionalized with RNases against Intracellular Infection of Pseudomonas aeruginosa

Current treatments against bacterial infections have severe limitations, mainly due to the emergence of resistance to conventional antibiotics. In the specific case of Pseudomonas aeruginosa strains, they have shown a number of resistance mechanisms to counter most antibiotics. Human secretory RNases from the RNase A superfamily are proteins involved in a wide variety of biological functions, including antimicrobial activity. The objective of this work was to explore the intracellular antimicrobial action of an RNase 3/1 hybrid protein that combines RNase 1 high catalytic and RNase 3 bactericidal activities. To achieve this, we immobilized the RNase 3/1 hybrid on Polyetheramine (PEA)-modified magnetite nanoparticles (MNPs). The obtained nanobioconjugates were tested in macrophage-derived THP-1 cells infected with Pseudomonas aeruginosa PAO1. The obtained results show high antimicrobial activity of the functionalized hybrid protein (MNP-RNase 3/1) against the intracellular growth of P. aeruginosa of the functionalized hybrid protein. Moreover, the immobilization of RNase 3/1 enhances its antimicrobial and cell-penetrating activities without generating any significant cell damage. Considering the observed antibacterial activity, the immobilization of the RNase A superfamily and derived proteins represents an innovative approach for the development of new strategies using nanoparticles to deliver antimicrobials that counteract P. aeruginosa intracellular infection.

Multiple ribonuclease A family members cleave transfer RNAs in response to stress

ABSTRACTDuring stress, changes in gene expression are critical for cell survival. Stress-induced tRNA cleavage has been implicated in various cellular processes, where tRNA fragments play diverse regulatory roles. Angiogenin (ANG), a member of the RNase A superfamily, induces cleavage of tRNAs resulting in the formation of tRNA-derived stress-induced RNAs (tiRNAs) that contribute to translational reprogramming aiming at cell survival. The role of other stress-induced RNases in tRNA cleavage is poorly understood. Using gene editing and biochemical approaches, we show that other members of the RNase A family are capable of targeting tRNAs in stress-responsive manner. We show that in the absence of ANG, these RNases also promote the production of tiRNAs. Moreover, specific stresses (such as treatment with sodium arsenite) activate cleavage of universal 3’-CCA termini of tRNAs in ANG-independent fashion in living cells. We conclude that multiple RNase A family members are capable of targeting tRNAs in a stress-specific manner in vivo.

Structural and biophysical characterization of human RNase 6

Human members of the RNase A superfamily include eight rapidly evolving homologous enzymes with varying ribonucleolytic activity. All eight canonical members are characterized by the presence of two histidines and a lysine forming the catalytic triad, in addition to strictly conserved cysteines involved in the formation of 3 or 4 disulfide bridges essential for structural integrity. Despite these architectural and catalytic similarities, human RNases are functionally diverse and their biological activities remain elusive. Apart from degrading RNA with varying degrees of efficiency, these structural homologues have acquired a variety of distinct biological functions, including anti-bactericidal, cytotoxic, angiogenic, immunosuppressive, anti-tumoral and/or anti-viral activities. Among human members of this vertebrate-specific family, RNase 6 and RNase 8 have never been structurally resolved. To better understand its biological function and to characterize its molecular interactions with RNA and/or potential unknown ligands, we present the three-dimensional structure of human RNase 6 in its apo form. While the enzyme shares similar structural features with other members of the RNase A superfamily, we emphasize interesting differences unique to RNase 6 that may be pertaining to its unique biological function. Additional NMR, CD and ITC biophysical characterization in presence of RNA ligands will also be presented.

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.