Protein degradation by a component of the chaperonin-linked protease ClpP.

In cells, proteins are synthesized, function, and degraded (dead). Protein synthesis (spring) is important for the life of proteins. However, how proteins die is equally important for organisms. Proteases are secreted from cells and used as nutrients to break down external proteins. Proteases degrade unwanted and harmful cellular proteins. In eukaryotes, a large enzyme complex called the proteasome is primarily responsible for cellular protein degradation. Prokaryotes, such as bacteria, have similar protein degradation systems. In this review, we describe the structure and function of the ClpXP complex in the degradation system, which is an ATP-dependent protease in bacterial cells, with a particular focus on ClpP.

Probing for optimal photoaffinity linkers of benzophenone-based photoaffinity probes for adenylating enzymes.

The adenylation (A) domain of non-ribosomal peptide synthetases (NRPSs) catalyzes the adenylation reaction with substrate amino acids and ATP. Leveraging the distinct substrate specificity of A-domains, we previously developed photoaffinity probes for A-domains based on derivatization with a 5'-O-N-(aminoacyl)sulfamoyl adenosine (aminoacyl-AMS)-appended clickable benzophenone. Although our photoaffinity probes with different amino acid warheads enabled selective detection, visualization, and enrichment of target A-domains in proteomic environments, the effects of photoaffinity linkers have not been investigated. To explore the optimal benzophenone-based linker scaffold, we designed seven photoaffinity probes for the A-domains with different lengths, positions, and molecular shapes. Using probes 2-8 for the phenylalanine-activating A-domain of gramicidin S synthetase A (GrsA), we systematically investigated the binding affinity and labeling efficiency of the endogenous enzyme in a live producer cell. Our results indicated that the labeling efficiencies of probes 2-8 tended to depend on their binding affinities rather than on the linker length, flexibility, or position of the photoaffinity group. We also identified that probe 2 with a 4,4'-diaminobenzophenone linker exhibits the highest labeling efficiency for GrsA with fewer non-target labeling properties in live cells.

Development of a chemical scaffold for inhibiting nonribosomal peptide synthetases in live bacterial cells.

The adenylation (A) domain is essential for non-ribosomal peptide synthetases (NRPSs), which synthesize various peptide-based natural products, including virulence factors, such as siderophores and genotoxins. Hence, the inhibition of A-domains could attenuate the virulence of pathogens. 5'-O-N-(Aminoacyl or arylacyl)sulfamoyladenosine (AA-AMS) is a bisubstrate small-molecule inhibitor of the A-domains of NRPSs. However, the bacterial cell permeability of AA-AMS is typically a problem owing to its high hydrophilicity. In this study, we investigated the influence of a modification of 2'-OH in the AMS scaffold with different functional groups on binding to target enzymes and bacterial cell penetration. The inhibitor 7 with a cyanomethyl group at 2'-OH showed desirable inhibitory activity against both recombinant and intracellular gramicidin S synthetase A (GrsA) in the gramicidin S-producer Aneurinibacillus migulanus ATCC 9999, providing an alternative scaffold to develop novel A-domain inhibitors.

Proteolytic Regulation in the Biosynthesis of Natural Product Via a ClpP Protease System.

Protein degradation is a tightly regulated biological process that maintains bacterial proteostasis. ClpPs are a highly conserved family of serine proteases that associate with the AAA + ATPase (an ATPase associated with diverse cellular activities) to degrade protein substrates. Identification and biochemical characterization of protein substrates for the AAA + ATPase-dependent ClpP degradation systems are considered essential for gaining an understanding of the molecular operation of the complex ClpP degradation machinery. Consequently, expanding the repertoire of protein substrates that can be degraded in vitro and within bacterial cells is necessary. Here, we report that AAA + ATPase-ClpP proteolytic complexes promote degradation of the secondary metabolite surfactin synthetases SrfAA, SrfAB, and SrfAC in Bacillus subtilis. On the basis of in vitro and in-cell studies coupled with activity-based protein profiling of nonribosomal peptide synthetases, we showed that SrfAC is targeted to the ClpC-ClpP proteolytic complex, whereas SrfAA is hydrolyzed not only by the ClpC-ClpP proteolytic complex but also by different ClpP proteolytic complexes. Furthermore, SrfAB does not appear to be a substrate for the ClpC-ClpP proteolytic complex, thereby implying that other ClpP proteolytic complexes are involved in the degradation of this surfactin synthetase. Natural product biosynthesis is regulated by the AAA + ATPase-ClpP degradation system, indicating that protein degradation plays a role in the regulatory stages of biosynthesis. However, few studies have examined the regulation of protein degradation levels. Furthermore, SrfAA, SrfAB, and SrfAC were identified as protein substrates for AAA + ATPase-ClpP degradation systems, thereby contributing to a better understanding of the complex ClpP degradation machinery.

[Protein degradation in bacteria: focus on the ClpP protease].

Proteins in the cells are born (synthesized), work, and die (decomposed). In the life of a protein, its birth is obviously important, but how it dies is equally important in living organisms. Proteases secreted into the outside of cells are used to decompose the external proteins and the degradation products are taken as the nutrients. On the other hand, there are also proteases that decompose unnecessary or harmful proteins which are generated in the cells. In eukaryotes, a large enzyme complex called the proteasome is primarily responsible for degradation of such proteins. Bacteria, which are prokaryotes, have a similar system as the proteasome. We would like to explain the bacterial degradation system of proteins or the death of proteins, which is performed by ATP-dependent protease Clp, with a particular focus on the ClpXP complex, and with an aspect as a target for antibiotics against bacteria.

Role of the thiosugar ring in the inhibitory activity of salacinol, a potent natural α-glucosidase inhibitor.

Herein, ring-cleaved (24) and truncated (25) analogues of an azasugar, 1-deoxynojirimycin (23), exhibited inhibitory activity (Ki = 4-10 µM) equal to that of the parent compound (1, Ki = 14 µM). Based on this structure-activity relationship (SAR), four ring-cleaved (26a-26c and 27c) and three truncated (28a-28c) analogues of salacinol (1), a potent thiosugar-ring-containing α-glucosidase inhibitor, were synthesised. Bioassay results revealed that all the synthetics were inactive, indicating that the 5-membered thiosugar ring of 1 played an essential role in the potent activities of sulfonium-type inhibitors. The present findings are interesting and important in understanding the function of salacinol, considering that the observed inhibitory activity trend was contrary to the SAR observed in aza-compounds (23, 24, and 25) in a previous study, which suggested that the cyclic structure did not contribute to their strong inhibitory activity.