Covalently and ionically, dually crosslinked chitosan nanoparticles block quorum sensing and affect bacterial cell growth on a cell-density dependent manner.

In our efforts to improve the quality and stability of chitosan nanoparticles (NPs), we describe here a new type of chitosan NPs dually crosslinked with genipin and sodium tripolyphosphate (TPP) that display quorum quenching activity. These NPs were created using a simplified and robust procedure that resulted in improved physicochemical properties and enhanced stability. This procedure involves the covalent crosslinking of chitosan with genipin, followed by the formation of chitosan NPs by ionic gelation with TPP. We have optimized the conditions to obtain genipin pre-crosslinked nanoparticles (PC-NPs) with positive ς-potential (~ +30 mV), small diameter (~130 nm), and low size distributions (PdI = 0.1-0.2). PC-NPs present physicochemical properties that are comparable to those of other dually crosslinked chitosan NPs fabricated with different protocols. In contrast to previously characterized NPs, however, we found that PC-NPs strongly reduce the acyl homoserine lactone (AHL)-mediated quorum sensing response of an Escherichia coli fluorescent biosensor. Thus, PC-NPs combine, in a single design, the stability of dually crosslinked chitosan NPs and the quorum quenching activity of ionically crosslinked NPs. Similar to other chitosan NPs, the mode of action of PC-NPs is consistent with the existence of a "stoichiometric ratio" of NP/bacterium, at which the positive charge of the NPs counteracts the negative ς-potential of the bacterial envelope. Notably, we found that the time of the establishment of the "stoichiometric ratio" is a function of the NP concentration, implying that these NPs could be ideal for applications aiming to target of bacterial populations at specific cell densities. We are confident that our PC-NPs are up-and-coming candidates for the design of efficient anti-quorum sensing and a new generation antimicrobial strategies.

Effect of the ultrastructure of chitosan nanoparticles in colloidal stability, quorum quenching and antibacterial activities.

We have fabricated two types of crosslinked chitosan-based nanoparticles (NPs), namely (1) ionically crosslinked with tripolyphosphate (TPP), designated as IC-NPs and (2) dually co-crosslinked (ionically and covalently with TPP and genipin, respectively) termed CC-NPs. The two types of NPs were physichochemically characterized by means of DLS-NIBS, synchrotron SAXS and M3-PALS (zeta potential). First, we found that covalent co-crosslinking of ionically pre-crosslinked nanoparticles yielded monodisperse CC-NPs in the size range of ∼200 nm, whereas the parental IC-NPs remained highly polydisperse. While both types of chitosan nanoparticles displayed a core-shell structure, as determined by synchrotron SAXS, only the structure of CC-NPs remained stable at long incubation times. This enhanced structural robustness of CC-NPs was likely responsible of their superior colloidal stability even in biological medium. Second, we explored the antimicrobial and quorum sensing inhibition activity of both types of nanoparticles. We found that CC-NPs had lower long-term toxicity than IC-NPs. In contrast, sub-lethal doses of IC-NPs consistently displayed higher levels of quorum quenching activity than CC-NPs. Thus, this work underscores the influence of the NP's ultrastructure on their colloidal and biological properties. While the cellular and molecular mechanisms at play are yet to be fully elucidated, our results broaden the spectrum of use of chitosan-based nanobiomaterialsin the development of antibiotic-free approaches against Gram-negative pathogenic bacteria.

Mutational analysis of the conserved bases C1402 and A1500 in the center of the decoding domain of Escherichia coli 16 S rRNA reveals an important tertiary interaction.

Interactions within the decoding center of the 30 S ribosomal subunit have been investigated by constructing all 15 possible mutations at nucleotides C1402 and A1500 in helix 44 of 16 S rRNA. As expected, most of the mutations resulted in highly deleterious phenotypes, consistent with the high degree of conservation of this region and its functional importance. A total of seven mutants were viable under conditions where the mutant ribosomes comprised 100 % of the ribosomal pool. A suppressor mutation specific for the C1402U-A1500G mutant was isolated at position 1520 in helix 45 of 16 S rRNA. In addition, lack of dimethylation of A1518/A1519 caused by mutation of the ksgA methylase enhanced the deleterious effect of many of the 1402/1500 mutations. These data suggest that a higher-order interaction between helices 44 and 45 in 16 S rRNA is important for the proper functioning of the ribosome. This is consistent with the recent high-resolution crystal structures of the 30 S subunit, which show a tertiary interaction between the 1402/1500 region of helix 44 and the dimethyl A stem loop.

Isolation of kasugamycin resistant mutants in the 16 S ribosomal RNA of Escherichia coli.

Three ribosomal RNA mutations conferring resistance to the antibiotic kasugamycin were isolated using a strain of Escherichia coli in which all of the rRNA is transcribed from a plasmid-encoded rrn operon. The mutations, A794G, G926A, and A1519C, mapped to universally conserved sites in the 16 S RNA gene. Site-directed mutagenesis studies showed that virtually all mutations at these three sites conferred kasugamycin resistance and had very slight effects on cell growth. It has been known for many years that the absence of post-transcriptional modification at A1519 and the adjacent A1518 in strains lacking a functional KsgA methylase produces a kasugamycin resistance phenotype. Mutations at A1519 conferred kasugamycin resistance and had minor effects on cell growth, whereas mutations at 1518 did not confer resistance and increased the doubling time of the cells dramatically. Expression of mutations at A1518/A1519 in a methylase deficient ksgA(-)strain had divergent effects on the phenotype of the rRNA mutants, suggesting that the base identity at either position does not affect methylation at the adjacent site. Residues A794 and G926 are protected from chemical modification by kasugamycin and tRNA, and have been implicated in the initiation of protein synthesis. Despite the universal conservation and functional importance of these residues, the results presented here show that the identity of the bases is not critical for ribosomal function.