Directed evolution of Mycobacterium tuberculosis ß-lactamase reveals gatekeeper residue that regulates antibiotic resistance and catalytic efficiency.

Directed evolution can be a powerful tool for revealing the mutational pathways that lead to more resistant bacterial strains. In this study, we focused on the bacterium Mycobacterium tuberculosis, which is resistant to members of the ß-lactam class of antibiotics and thus continues to pose a major public health threat. Resistance of this organism is the result of a chromosomally encoded, extended spectrum class A ß-lactamase, BlaC, that is constitutively produced. Here, combinatorial enzyme libraries were selected on ampicillin to identify mutations that increased resistance of bacteria to ß-lactams. After just a single round of mutagenesis and selection, BlaC mutants were evolved that conferred 5-fold greater antibiotic resistance to cells and enhanced the catalytic efficiency of BlaC by 3-fold compared to the wild-type enzyme. All isolated mutants carried a mutation at position 105 (e.g., I105F) that appears to widen access to the active site by 3.6 Å while also stabilizing the reorganized topology. In light of these findings, we propose that I105 is a 'gatekeeper' residue of the active site that regulates substrate hydrolysis by BlaC. Moreover, our results suggest that directed evolution can provide insight into the development of highly drug resistant microorganisms.

Genetic toggling of alkaline phosphatase folding reveals signal peptides for all major modes of transport across the inner membrane of bacteria.

Prediction of export pathway specificity in prokaryotes is a challenging endeavor due to the similar overall architecture of N-terminal signal peptides for the Sec-, SRP- (signal recognition particle), and Tat (twin arginine translocation)-dependent pathways. Thus, we sought to create a facile experimental strategy for unbiased discovery of pathway specificity conferred by N-terminal signals. Using a limited collection of Escherichia coli strains that allow protein oxidation in the cytoplasm or, conversely, disable protein oxidation in the periplasm, we were able to discriminate the specific mode of export for PhoA (alkaline phosphatase) fusions to signal peptides for all of the major modes of transport across the inner membrane (Sec, SRP, or Tat). Based on these findings, we developed a mini-Tn5 phoA approach to isolate pathway-specific export signals from libraries of random fusions between exported proteins and the phoA gene. Interestingly, we observed that reduced PhoA was exported in a Tat-independent manner when targeted for Tat export in the absence of the essential translocon component TatC. This suggests that initial docking to TatC serves as a key specificity determinant for Tat-specific routing of PhoA, and in its absence, substrates can be rerouted to the Sec pathway, provided they remain compatible with the Sec export mechanism. Finally, the utility of our approach was demonstrated by experimental verification that four secreted proteins from Mycobacterium tuberculosis carrying putative Tat signals are bona fide Tat substrates and thus represent potential Tat-dependent virulence factors in this important human pathogen.

Identification of a twin-arginine translocation system in Pseudomonas syringae pv. tomato DC3000 and its contribution to pathogenicity and fitness.

The bacterial plant pathogen Pseudomonas syringae pv. tomato DC3000 (DC3000) causes disease in Arabidopsis thaliana and tomato plants, and it elicits the hypersensitive response in nonhost plants such as Nicotiana tabacum and Nicotiana benthamiana. While these events chiefly depend upon the type III protein secretion system and the effector proteins that this system translocates into plant cells, additional factors have been shown to contribute to DC3000 virulence and still many others are likely to exist. Therefore, we explored the contribution of the twin-arginine translocation (Tat) system to the physiology of DC3000. We found that a tatC mutant strain of DC3000 displayed a number of phenotypes, including loss of motility on soft agar plates, deficiency in siderophore synthesis and iron acquisition, sensitivity to copper, loss of extracellular phospholipase activity, and attenuated virulence in host plant leaves. In the latter case, we provide evidence that decreased virulence of tatC mutants likely arises from a synergistic combination of (i) compromised fitness of bacteria in planta; (ii) decreased efficiency of type III translocation; and (iii) cytoplasmically retained virulence factors. Finally, we demonstrate a novel broad-host-range genetic reporter based on the green fluorescent protein for the identification of Tat-targeted secreted virulence factors that should be generally applicable to any gram-negative bacterium. Collectively, our evidence supports the notion that virulence of DC3000 is a multifactorial process and that the Tat system is an important virulence determinant of this phytopathogenic bacterium.

Dissecting the twin-arginine translocation pathway using genome-wide analysis.

A recently discovered route for protein export, known as the twin-arginine translocation (Tat) pathway, has received much attention owing to several atypical characteristics that distinguish it from other transport mechanisms. For instance, recent evidence has clearly established that this pathway only transports folded polypeptides. Moreover, several studies have demonstrated a vital role for the Tat pathway in bacterial pathogenesis. In this review, we discuss genomic approaches that have been employed to determine the prevalence and capacity of the Tat system and how the information generated from these approaches is helping to connect Tat transport to bacterial physiology and virulence.