contributed equally to this workThe catalytic determinants for the cleavage and ligation reactions mediated by the hairpin ribozyme are integral to the polyribonucleotide chain. We describe experiments that place G8, a critical guanosine, at the active site, and point to an essential role in catalysis. Cross-linking and modeling show that formation of a catalytic complex is accompanied by a conformational change in which N1 and O6 of G8 become closely apposed to the scissile phosphodiester. UV cross-linking, hydroxyl-radical footprinting and native gel electrophoresis indicate that G8 variants inhibit the reaction at a step following domain association, and that the tertiary structure of the inactive complex is not measurably altered. Rate±pH pro®les and¯uores-cence spectroscopy show that protonation at the N1 position of G8 is required for catalysis, and that modi®cation of O6 can inhibit the reaction. Kinetic solvent isotope analysis suggests that two protons are transferred during the rate-limiting step, consistent with rate-limiting cleavage chemistry involving concerted deprotonation of the attacking 2¢-OH and protonation of the 5¢-O leaving group. We propose mechanistic models that are consistent with these data, including some that invoke a novel keto±enol tautomerization.
The complex formed by the hairpin ribozyme and its substrate consists of two independently folding domains which interact to form a catalytic structure. Fluorescence resonance energy transfer methods permit us to study reversible transitions of the complex between open and closed forms. Results indicate that docking of the domains is required for both the cleavage and ligation reactions. Docking is rate-limiting for ligation (2 min-1) but not for cleavage, where docking (0.5 min-1) precedes a rate-limiting conformational transition or slow-reaction chemistry. Strikingly, most modifications to the RNA (such as a G+1A mutation in the substrate) or reaction conditions (such as omission of divalent metal ion cofactors) which inhibit catalysis do so by preventing docking. This demonstrates directly that mutations and modifications which inhibit a step following substrate binding are not necessarily involved in catalysis. An improved kinetic description of the catalytic cycle is derived, including specific structural transitions.
Diabetic patients are more susceptible to the development of chronic wounds than non-diabetics. The impaired healing properties of these wounds, which often develop debilitating bacterial infections, significantly increase the rate of lower extremity amputation in diabetic patients. We hypothesize that bacterial biofilms, or sessile communities of bacteria that reside in a complex matrix of exopolymeric material, contribute to the severity of diabetic wounds. To test this hypothesis, we developed an in vivo chronic wound, diabetic mouse model to determine the ability of the opportunistic pathogen, Pseudomonas aeruginosa, to cause biofilm-associated infections. Utilizing this model, we observed that diabetic mice with P. aeruginosa-infected chronic wounds displayed impaired bacterial clearing and wound closure in comparison with their non-diabetic littermates. While treating diabetic mice with insulin improved their overall health, it did not restore their ability to resolve P. aeruginosa wound infections or speed healing. In fact, the prevalence of biofilms and the tolerance of P. aeruginosa to gentamicin treatment increased when diabetic mice were treated with insulin. Insulin treatment was observed to directly affect the ability of P. aeruginosa to form biofilms in vitro. These data demonstrate that the chronically wounded diabetic mouse appears to be a useful model to study wound healing and biofilm infection dynamics, and suggest that the diabetic wound environment may promote the formation of biofilms. Further, this model provides for the elucidation of mechanistic factors, such as the ability of insulin to influence antimicrobial effectiveness, which may be relevant to the formation of biofilms in diabetic wounds.
Coralyne is a DNA-binding antitumor antibiotic whose structure contains four fused aromatic rings. The interaction of coralyne with the DNA triplexes poly(dT).poly(dA).poly(dT) and poly[d(TC)].poly[d(GA)].poly[d(C+T)] was investigated by using three techniques. First, Tm values were measured by thermal denaturation analysis. Upon binding coralyne, both triplexes showed Tm values that were increased more than those of the corresponding duplexes. A related drug, berberinium, in which one of the aromatic rings is partially saturated, gave much smaller changes in Tm. Second, the fluorescence of coralyne is quenched in the presence of DNA, allowing the measurement of binding parameters by Scatchard analysis. The binding isotherms were biphasic, which was interpreted in terms of strong intercalative binding and much weaker stacking interactions. In the presence of 2 mM Mg2+, the binding constants to poly(dT).poly-(dA).poly(dT) and poly[d(TC)].poly[d(GA)].poly[(C+T)] were 3.5 x 10(6) M-1 and 1.5 x 10(6) M-1, respectively, while the affinity to the parent duplexes was at least 2 orders of magnitude lower. In the absence of 2 mM Mg2+, the binding constants to poly[d(TC)].poly[d(GA)].poly[d(C+T)] and poly-[d(TC)].poly[d(GA)] were 40 x 10(6) M-1 and 15 x 10(6) M-1, respectively. Thus coralyne shows considerable preference for the triplex structure but little sequence specificity, unlike ethidium, which will only bind to poly(dT).poly(dA).poly(dT). Further evidence for intercalation of coralyne was provided by an increase in the relative fluorescence quantum yield at 260 nm upon binding of coralyne to triplexes as well as an absence of quenching of fluorescence in the presence of Fe[(CN)6]4-.(ABSTRACT TRUNCATED AT 250 WORDS)
We have examined the tertiary structure of the ligand-activated glmS ribozyme by a combination of methods with the aim of evaluating the magnitude of RNA conformational change induced by binding of the cofactor, glucosamine 6-phosphate (GlcN6P). Hydroxyl radical footprinting of a trans-acting ribozyme complex identifies several sites of solvent protection upon incubation of the RNA in Mg(2+)-containing solutions, providing initial evidence of the tertiary fold of the ribozyme. Under these folding conditions and at GlcN6P concentrations that saturate the ligand-induced cleavage reaction, we do not observe changes to this pattern. Cross-linking with short-wave UV light of the complex yielded similar overall results. In addition, ribozyme-substrate complexes cross-linked in the absence of GlcN6P could be gel purified and then activated in the presence of ligand. One of these active cross-linked species links the base immediately 3' of the cleavage site to a highly conserved region of the ribozyme core and could be catalytically activated by ligand. Combined with recent studies that argue that GlcN6P acts as a coenzyme in the reaction, our data point to a riboswitch mechanism in which ligand binds to a prefolded active site pocket and assists in catalysis via a direct participation in the reaction chemistry, the local influence on the geometry of the active site constituents, or a combination of both mechanisms. This mode of action is different from that observed for other riboswitches characterized to date, which act by inducing secondary and tertiary structure changes.
The stability of triplex DNA was investigated in the presence of the polyamines spermine and spermidine by four different techniques. First, thermal-denaturation analysis of poly[d(TC)].poly[d(GA)] showed that at low ionic strength and pH 7, 3 microM spermine was sufficient to cause dismutation of all of the duplex to the triplex conformation. A 10-fold higher concentration of spermidine produced a similar effect. Second, the kinetics of the dismutation were measured at pH 5 in 0.2 M NaCl. The addition of 500 microM spermine increased the rate by at least 2-fold. Third, in 0.2 M NaCl, the mid-point of the duplex-to-triplex dismutation occurred at a pH of 5.8, but this was increased by nearly one pH unit in the presence of 500 microM spermine. Fourth, intermolecular triplexes can also form in plasmids that contain purine.pyrimidine inserts by the addition of a single-stranded pyrimidine. This was readily demonstrated at pH 7.2 and 25 mM ionic strength in the presence of 100 microM spermine or spermidine. In 0.2 M NaCl, however, 1 mM polyamine is required. Since, in the eucaryotic nucleus, the polyamine concentration is in the millimolar range, then appropriate purine-pyrimidine DNA sequences may favor the triplex conformation in vivo.
The complex between the hairpin ribozyme and its substrate consists of two domains that must interact in order to form a catalytic complex, yet experimental evidence concerning the points of interaction between the two domains has been lacking. Here, we report the use of hydroxyl radical footprinting to define the interface between the two domains. Cations that support very efficient ribozyme catalysis (magnesium and cobalt(III) hexammine) lead to the formation of a docked complex that features several regions of protection, indicating a solvent-inaccessible core within the tertiary structure of the complex. Cations that are suboptimal in cleavage reactions do not produce complexes with regions of reduced solvent accessibility. Nucleotides encompassing the substrate cleavage site (c-2, a-1, g+1, and u+2) are strongly protected, suggesting their internalization into the catalytic core. Four distinct segments of the ribozyme are protected, including G11-A14, C25-C27, A38, and U42-A43. Protection of these sites is eliminated when g+1, an essential base at the cleavage site, is replaced by A. In addition, mutations which are known to decrease the fraction of docked complexes decrease or eliminate formation of a solvent-inaccessible core. Taken together, these observations demonstrate that we have identified the catalytic core of the active hairpin ribozyme-substrate complex.
Pseudomonas aeruginosa displays tremendous metabolic diversity, controlled in part by the abundance of transcription regulators in the genome. We have been investigating P. aeruginosa's response to the host, particularly changes regulated by the hostderived quaternary amines choline and glycine betaine (GB). We previously identified GbdR as an AraC family transcription factor that directly regulates choline acquisition from host phospholipids (via binding to plcH and pchP promoters), is required for catabolism of the choline metabolite GB, and is an activator that induces transcription in response to GB or dimethylglycine. Our goal was to characterize the GbdR regulon in P. aeruginosa by using genetics and chemical biology in combination with transcriptomics and in vitro DNA-binding assays. Here we show that GbdR activation regulates transcription of 26 genes from 12 promoters, 11 of which have measureable binding to GbdR in vitro. The GbdR regulon includes the genes encoding GB, dimethylglycine, sarcosine, glycine, and serine catabolic enzymes and the BetX and CbcXWV quaternary amine transport proteins. We characterized the GbdR consensus binding site and used it to identify that the recently characterized acetylcholine esterase gene, choE (PA4921), is also regulated by GbdR. The regulon member not directly controlled by GbdR is the secreted lipase gene lipA, which was also the only regulon member repressed under GbdR-activating conditions. Determination of the GbdR regulon provides deeper understanding of how GbdR links bacterial metabolism and virulence. Additionally, identification of two uncharacterized regulon members suggests roles for these proteins in response to choline metabolites.
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