Sequential rescue and repair of stalled and damaged ribosome by bacterial PrfH and RtcB

In bacteria, rescue of stalled ribosomes due to 3’-truncated mRNAs is carried out by the ubiquitous trans-translation system as well as alternative ribosome-rescue factors such as ArfA and ArfB. It is unclear, however, how the stalled ribosomes caused by ribosomal damages are rescued. Here, we report that a bacterial system composed of PrfH and RtcB not only rescues a stalled ribosome resulting from a specific damage in the decoding center but also repairs the damage afterwards. Peptide release assays reveal that PrfH is only active with the damaged ribosome, but not with the intact one. A 2.55-angstrom cryo-EM structure of PrfH in complex with the damaged 70S ribosome provides molecular insight into specific recognition of the damage site by PrfH. RNA repair assays demonstrate that PrfH-coupled RtcB efficiently repairs the damaged 30S ribosomal subunit, but not the damaged tRNAs. Thus, our studies have uncovered a biological operation by a pair of bacterial enzymes, aiming to reverse the potentially lethal damage inflicted by an invading ribotoxin for cell survival.

Multiplicity of carotene patterns derives from competition between phytoene desaturase diversification and biological environments

Phytoene desaturases catalyse from two to six desaturation reactions on phytoene, generating a large diversity of molecules that can then be cyclised and produce, depending on the organism, many different carotenoids. We constructed a phylogenetic tree of a subset of phytoene desaturases from the CrtI family for which functional data was available. We expressed in a bacterial system eight codon optimized CrtI enzymes from different clades. Analysis of the phytoene desaturation reactions on crude extracts showed that three CrtI enzymes can catalyse up to six desaturations, forming tetradehydrolycopene. Kinetic data generated using a subset of five purified enzymes demonstrate the existence of characteristic patterns of desaturated molecules associated with various CrtI clades. The kinetic data was also analysed using a classical Michaelis–Menten kinetic model, showing that variations in the reaction rates and binding constants could explain the various carotene patterns observed. Competition between lycopene cyclase and the phytoene desaturases modified the distribution between carotene intermediates when expressed in yeast in the context of the full β-carotene production pathway. Our results demonstrate that the desaturation patterns of carotene molecules in various biological environments cannot be fully inferred from phytoene desaturases classification but is governed both by evolutionary-linked variations in the desaturation rates and competition between desaturation and cyclisation steps.

ATP-dependent RNA helicase domain of the ZC3H41 protein from Trypanosoma brucei: expression, purification and crystallization

A fragment of the Trypanosoma brucei ZC3H41 protein encompassing the ATP-dependent RNA helicase domain was successfully subcloned for expression in a bacterial system (Escherichia coli). Following expression, the protein was purified and crystallized using the vapor-diffusion method. The protein crystals were optimized at a 1:1 protein:reservoir solution ratio using PPGBA 2000. The optimized crystals diffracted to a d min of 3.15 Å. The collected data revealed preliminary structural information regarding this newly discovered protein.

The E. coli NudL enzyme is a Nudix hydrolase that cleaves CoA and its derivatives

The process of bacterial coenzyme A (CoA) degradation has remained unknown despite the otherwise detailed characterization of the CoA synthesis pathway over 30 years ago. Numerous enzymes capable of CoA degradation have been identified in other domains of life that belong to the Nudix superfamily of hydrolases, but the molecule responsible for this process in the model bacterial system of E. coli remains a mystery. We report here that E. coli contains two such Nudix enzymes capable of CoA degradation into 4’-phosphopantetheine and 3’,5’-adenosine monophosphate. The E. coli enzymes NudC and NudL were cloned in various promoter-fusion constructs in order to purify them as soluble active enzymes and characterize their ability to catalyze the phosphohydrolysis of CoA. NudC, an enzyme known to hydrolyze NADH as its principal substrate, demonstrated the ability to hydrolyze CoA, among other coenzymes, at comparable rates to eukaryotic Nudix hydrolases. NudL, a previously uncharacterized enzyme, demonstrated the ability to cleave only CoA and CoA-related molecules at a rate orders of magnitude slower than its eukaryotic orthologs. NudC and NudL therefore represent a previously uncharacterized pathway of CoA degradation in the highly studied E. coli system. While the two enzymes display some substrate overlap, their respective activities imply that NudC may play a role as a general coenzyme hydrolase, while NudL specifically targets CoA. These data further suggest a role for these enzymes in the regulation of bacterial CoA-RNA.

An intelligent vancomycin release system for preventing surgical site infections of bone tissues

An intelligent anti-bacterial system can be constructed on implants during surgery.