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.

Biophysical analysis of Arabidopsis protein-only RNase P alone and in complex with tRNA provides a refined model of tRNA binding.

RNase P is a universal enzyme that removes 5' leader sequences from tRNA precursors. The enzyme is therefore essential for maturation of functional tRNAs and mRNA translation. RNase P represents a unique example of an enzyme that can occur either as ribonucleoprotein or as protein alone. The latter form of the enzyme, called protein-only RNase P (PRORP), is widespread in eukaryotes in which it can provide organellar or nuclear RNase P activities. Here, we have focused on Arabidopsis nuclear PRORP2 and its interaction with tRNA substrates. Affinity measurements helped assess the respective importance of individual pentatricopeptide repeat motifs in PRORP2 for RNA binding. We characterized the PRORP2 structure by X-ray crystallography and by small-angle X-ray scattering in solution as well as that of its complex with a tRNA precursor by small-angle X-ray scattering. Of note, our study reports the first structural data of a PRORP-tRNA complex. Combined with complementary biochemical and biophysical analyses, our structural data suggest that PRORP2 undergoes conformational changes to accommodate its substrate. In particular, the catalytic domain and the RNA-binding domain can move around a central hinge. Altogether, this work provides a refined model of the PRORP-tRNA complex that illustrates how protein-only RNase P enzymes specifically bind tRNA and highlights the contribution of protein dynamics to achieve this specific interaction.

The CBS domain protein MJ0729 of Methanocaldococcus jannaschii is a thermostable protein with a pH-dependent self-oligomerization.

CBS domains are small protein motifs, usually associated in tandems, that are involved in binding to adenosyl groups. In humans, several genetic diseases have been associated with mutations in CBS domains, and then, they can be considered as promising targets for the rational design of new drugs. However, there are no structural studies describing their oligomerization states, conformational preferences, and stability. In this work, the oligomerization state, the stability, and conformational properties of the CBS domain protein MJ0729 from Methanocaldococcus jannaschii were explored by using a combination of hydrodynamic (namely, ultracentrifugation, DLS, DOSY-NMR, and gel filtration) and spectroscopic techniques (fluorescence, circular dichroism, NMR, and FTIR). The results indicate that the protein had a pH-dependent oligomerization equilibrium: at pH 7, the dominant species is a dimer, where each monomer is a two-CBS domain protein, and at pH 4.5-4.8, the dominant species is a tetramer, with an oblong shape, as shown by X-ray. Deconvolution of the FTIR spectra indicates that the monomer at physiological pH has 26% alpha-helical structure and 17% beta-sheet, with most of the structure disordered. These results are similar to the percentages of secondary structure of the monomer in the resolved tetrameric X-ray structure (21% of alpha-helical structure and 7% of beta-sheet). At pH 2.5, there was a decrease in the level of secondary structure of the monomer, and formation of intermolecular hydrogen bonds, as shown by FTIR, suggesting the presence of high-molecular weight species. The physiological dimeric species is thermal and chemically very stable with a thermal midpoint of approximately 99 degrees C, as shown by both DSC and FTIR; the GdmCl chemical midpoint of the dimeric species occurs in a single step and was greater than 4 M.

Crystallization and preliminary crystallographic analysis of merohedrally twinned crystals of MJ0729, a CBS-domain protein from Methanococcus jannaschii.

CBS domains are small protein motifs, usually associated in tandem, that are implicated in binding to adenosyl groups. Several genetic diseases in humans have been associated with mutations in CBS sequences, which has made them very promising targets for rational drug design. Trigonal crystals of the CBS-domain protein MJ0729 from Methanococcus jannaschii were grown by the vapour-diffusion method at acidic pH. Preliminary analysis of nine X-ray diffraction data sets using Yeates statistics and Britton plots showed that slight variation in the pH as well as in the buffer used in the crystallization experiments led to crystals with different degrees of merohedral twinning that may vary from perfect hemihedral twinning to perfect tetartohedral twinning.