Bacterial glycoprofiling by using random sequence peptide microarrays.

Current analytical methods have been slow in addressing the growing need for glyco-analysis. A new generation of more empirical high-throughput (HTP) tools is needed to aid the advance of this important field. To this end, we have developed a new HTP screening platform for identification of surface-immobilized peptides that specifically bind O-antigenic glycans of bacterial lipopolysaccharides (LPS). This method involves screening of random sequence peptide libraries in addressable high-density microarray format with the newly developed luminescent LPS-quantum dot micelles. Screening of LPS fractions from O111:B4 and O55:B5 serotypes of E. coli on a microarray consisting of 10,000 20-mer peptide features revealed minor differences, while comparison of LPS from E. coli O111:B4 and P. aeruginosa produced sets of highly specific peptides. Peptides strongly binding to the E. coli LPS were highly enriched in aromatic and cationic amino acids, and most of these inhibited growth of E. coli. Flow cytometry and isothermal titration calorimetry (ITC) experiments showed that some of these peptides bind LPS in-solution with a K(d) of 1.75 microM. Peptide selections against P. aeruginosa were largely composed of hydrogen-bond forming amino acids in accordance with dramatic compositional differences in O-antigenic glycans in E. coli and P. aeruginosa. While the main value of this approach lies in the ability to rapidly differentiate bacterial and possibly other complex glycans, the peptides discovered here can potentially be used off-array as antiendotoxic and antimicrobial lead compounds, and on-array/on-bead as diagnostic and affinity reagents.

Peptide microarrays for carbohydrate recognition.

An application of high density random sequence peptide microarrays for rapid and reliable identification of artificial carbohydrate receptors is reported.

Hydrogen bonds between the alpha and beta subunits of the F1-ATPase allow communication between the catalytic site and the interface of the beta catch loop and the gamma subunit.

F(1)-ATPase mutations in Escherichia coli that changed the strength of hydrogen bonds between the alpha and beta subunits in a location that links the catalytic site to the interface between the beta catch loop and the gamma subunit were examined. Loss of the ability to form the hydrogen bonds involving alphaS337, betaD301, and alphaD335 lowered the k(cat) of ATPase and decreased its susceptibility to Mg(2+)-ADP-AlF(n) inhibition, while mutations that maintain or strengthen these bonds increased the susceptibility to Mg(2+)-ADP-AlF(n) inhibition and lowered the k(cat) of ATPase. These data suggest that hydrogen bonds connecting alphaS337 to betaD301 and betaR323 and connecting alphaD335 to alphaS337 are important to transition state stabilization and catalytic function that may result from the proper alignment of catalytic site residues betaR182 and alphaR376 through the VISIT sequence (alpha344-348). Mutations betaD301E, betaR323K, and alphaR282Q changed the rate-limiting step of the reaction as determined by an isokinetic plot. Hydrophobic mutations of betaR323 decreased the susceptibility to Mg(2+)-ADP-AlF(n)() inhibition and lowered the number of interactions required in the rate-limiting step yet did not affect the k(cat) of ATPase, suggesting that betaR323 is important to transition state formation. The decreased rate of ATP synthase-dependent growth and decreased level of lactate-dependent quenching observed with alphaD335, betaD301, and alphaE283 mutations suggest that these residues may be important to the formation of an alternative set of hydrogen bonds at the interface of the alpha and beta subunits that permits the release of intersubunit bonds upon the binding of ATP, allowing gamma rotation in the escapement mechanism.

Interactions of gamma T273 and gamma E275 with the beta subunit PSAV segment that links the gamma subunit to the catalytic site Walker homology B aspartate are important to the function of Escherichia coli F1F0 ATP synthase.

In Escherichia coli F(1)F(o) ATP synthase, gammaT273 mutants that eliminate the ability to form a hydrogen bond to betaV265 were incapable of ATP synthase-dependent growth and ATPase-dependent proton pumping, had very low rates of ATPase activity catalyzed by purified F(1), and had significantly decreased sensitivity to inhibition by Mg(2+)-ADP-AlF(n) species, while gammaT273D and gammaT273N mutants which maintained or increased the hydrogen bond strength maintained or increased catalytic activity. The betaP262G mutation that increases the potential flexibility of the rigid sleeve that surrounds the gamma subunit C-terminus also virtually eliminated ATPase activity and susceptibility to Mg(2+)-ADP-AlF(n) inhibition. The gammaE275 mutants that retained the ability to form the betaV265 hydrogen bond had higher ATPase activity than those that eliminated the hydrogen bond. These results provide evidence that the ability to form hydrogen bonds between betaV265 and the gamma subunit C-terminus contributes significantly to the rate-limiting step of catalysis and to the ability of the F(1)F(o) ATP synthase to use a proton gradient to drive ATP synthesis. The loss of activity observed with betaP262G may result from increased flexibility conferred by glycine that decreases the efficiency of communication between the gamma subunit-betaV265 hydrogen bonds and the Walker B aspartate at the catalytic site. The partial loss of coupling observed with gammaT273 mutants that eliminate the betaV265 hydrogen bond is consistent with participation of this hydrogen bond in the escapement mechanism for ATP synthesis in which interactions between the gamma subunit and (alphabeta)(3) ring prevent rotation until the empty catalytic site binds substrate.