Engineering Novosphingobium aromaticivorans to produce cis,cis-muconic acid from biomass aromatics.

The platform chemical cis,cis-muconic acid (ccMA) provides facile access to a number of monomers used in the synthesis of commercial plastics. It is also a metabolic intermediate in the ß-ketoadipic acid pathway of many bacteria and, therefore, a current target for microbial production from abundant renewable resources via metabolic engineering. This study investigates Novosphingobium aromaticivorans DSM12444 as a chassis for the production of ccMA from biomass aromatics. The N. aromaticivorans genome predicts that it encodes a previously uncharacterized protocatechuic acid (PCA) decarboxylase and a catechol 1,2-dioxygenase, which would be necessary for the conversion of aromatic metabolic intermediates to ccMA. This study confirmed the activity of these two enzymes in vitro and compared their activity to ones that have been previously characterized and used in ccMA production. From these results, we generated one strain that is completely derived from native genes and a second that contains genes previously used in microbial engineering synthesis of this compound. Both of these strains exhibited stoichiometric production of ccMA from PCA and produced greater than 100% yield of ccMA from the aromatic monomers that were identified in liquor derived from alkaline pretreated biomass. Our results show that a strain completely derived from native genes and one containing homologs from other hosts are both capable of stoichiometric production of ccMA from biomass aromatics. Overall, this work combines previously unknown aspects of aromatic metabolism in N. aromaticivorans and the genetic tractability of this organism to generate strains that produce ccMA from deconstructed biomass.IMPORTANCEThe production of commodity chemicals from renewable resources is an important goal toward increasing the environmental and economic sustainability of industrial processes. The aromatics in plant biomass are an underutilized and abundant renewable resource for the production of valuable chemicals. However, due to the chemical composition of plant biomass, many deconstruction methods generate a heterogeneous mixture of aromatics, thus making it difficult to extract valuable chemicals using current methods. Therefore, recent efforts have focused on harnessing the pathways of microorganisms to convert a diverse set of aromatics into a single product. Novosphingobium aromaticivorans DSM12444 has the native ability to metabolize a wide range of aromatics and, thus, is a potential chassis for conversion of these abundant compounds to commodity chemicals. This study reports on new features of N. aromaticivorans that can be used to produce the commodity chemical cis,cis-muconic acid from renewable and abundant biomass aromatics.

Production of carotenoids from aromatics and pretreated lignocellulosic biomass by Novosphingobium aromaticivorans.

IMPORTANCE: There is economic and environmental interest in generating commodity chemicals from renewable resources, such as lignocellulosic biomass, that can substitute for chemicals derived from fossil fuels. The bacterium Novosphingobium aromaticivorans is a promising microbial platform for producing commodity chemicals from lignocellulosic biomass because it can produce these from compounds in pretreated lignocellulosic biomass, which many industrial microbial catalysts cannot metabolize. Here, we show that N. aromaticivorans can be engineered to produce several valuable carotenoids. We also show that engineered N. aromaticivorans strains can produce these lipophilic chemicals concurrently with the extracellular commodity chemical 2-pyrone-4,6-dicarboxylic acid when grown in a complex liquor obtained from alkaline pretreated lignocellulosic biomass. Concurrent microbial production of valuable intra- and extracellular products can increase the economic value generated from the conversion of lignocellulosic biomass-derived compounds into commodity chemicals and facilitate the separation of water- and membrane-soluble products.

Aromatic Dimer Dehydrogenases from Novosphingobium aromaticivorans Reduce Monoaromatic Diketones.

Lignin is a potential source of valuable chemicals, but its chemical depolymerization results in a heterogeneous mixture of aromatics and other products. Microbes could valorize depolymerized lignin by converting multiple substrates into one or a small number of products. In this study, we describe the ability of Novosphingobium aromaticivorans to metabolize 1-(4-hydroxy-3-methoxyphenyl)propane-1,2-dione (G-diketone), an aromatic Hibbert diketone that is produced during formic acid-catalyzed lignin depolymerization. By assaying genome-wide transcript levels from N. aromaticivorans during growth on G-diketone and other chemically-related aromatics, we hypothesized that the Lig dehydrogenases, previously characterized as oxidizing ß-O-4 linkages in aromatic dimers, were involved in G-diketone metabolism by N. aromaticivorans. Using purified N. aromaticivorans Lig dehydrogenases, we found that LigL, LigN, and LigD each reduced the Cα ketone of G-diketone in vitro but with different substrate specificities and rates. Furthermore, LigL, but not LigN or LigD, also reduced the Cα ketone of 2-hydroxy-1-(4-hydroxy-3-methoxyphenyl)propan-1-one (GP-1) in vitro, a derivative of G-diketone with the Cß ketone reduced, when GP-1 was provided as a substrate. The newly identified activity of these Lig dehydrogenases expands the potential range of substrates utilized by N. aromaticivorans beyond what has been previously recognized. This is beneficial both for metabolizing a wide range of natural and non-native depolymerized lignin substrates and for engineering microbes and enzymes that are active with a broader range of aromatic compounds. IMPORTANCE Lignin is a major plant polymer composed of aromatic units that have value as chemicals. However, the structure and composition of lignin have made it difficult to use this polymer as a renewable source of industrial chemicals. Bacteria like Novosphingobium aromaticivorans have the potential to make chemicals from lignin not only because of their natural ability to metabolize a variety of aromatics but also because there are established protocols to engineer N. aromaticivorans strains to funnel lignin-derived aromatics into valuable products. In this work, we report a newly discovered activity of previously characterized dehydrogenase enzymes with a chemically modified by-product of lignin depolymerization. We propose that the activity of N. aromaticivorans enzymes with both native lignin aromatics and those produced by chemical depolymerization will expand opportunities for producing industrial chemicals from the heterogenous components of this abundant plant polymer.

Redundancy in aromatic O-demethylation and ring opening reactions in Novosphingobium aromaticivorans and their impact in the metabolism of plant derived phenolics.

Lignin is a plant heteropolymer composed of phenolic subunits. Because of its heterogeneity and recalcitrance, the development of efficient methods for its valorization still remains an open challenge. One approach to utilize lignin is its chemical deconstruction into mixtures of monomeric phenolic compounds followed by biological funneling into a single product. Novosphingobium aromaticivorans DSM12444 has been previously engineered to produce 2-pyrone-4,6-dicarboxylic acid (PDC) from depolymerized lignin by simultaneously metabolizing multiple aromatics through convergent routes involving the intermediates 3-methoxygallic acid (3-MGA) and protocatechuic acid (PCA). We investigated enzymes predicted to be responsible for O-demethylation and oxidative aromatic ring opening, two critical reactions involved in the metabolism of phenolics compounds by N. aromaticivorans The results showed the involvement of DesA in O-demethylation of syringic and vanillic acids, LigM in O-demethylation of vanillic acid and 3-MGA, and a new O-demethylase, DmtS, in the conversion of 3-MGA into gallic acid (GA). In addition, we found that LigAB was the main aromatic ring opening dioxygenase involved in 3-MGA, PCA, and GA metabolism, and that a previously uncharacterized dioxygenase, LigAB2, had high activity with GA. Our results indicate a metabolic route not previously identified in N. aromaticivorans that involves O-demethylation of 3-MGA to GA. We predict this pathway channels ∼15% of the carbon flow from syringic acid, with the rest following ring opening of 3-MGA. The new knowledge obtained in this study allowed for the creation of an improved engineered strain for the funneling of aromatic compounds that exhibits stoichiometric conversion of syringic acid into PDC.IMPORTANCE For lignocellulosic biorefineries to effectively contribute to reduction of fossil fuel use, they need to become efficient at producing chemicals from all major components of plant biomass. Making products from lignin will require engineering microorganisms to funnel multiple phenolic compounds to the chemicals of interest, and N. aromaticivorans is a promising chassis for this technology. The ability of N. aromaticivorans to efficiently and simultaneously degrade many phenolic compounds may be linked to having functionally redundant aromatic degradation pathways and enzymes with broad substrate specificity. A detailed knowledge of aromatic degradation pathways is thus essential to identify genetic engineering targets to maximize product yields. Furthermore, knowledge of enzyme substrate specificity is critical to redirect flow of carbon to desired pathways. This study described an uncharacterized pathway in N. aromaticivorans and the enzymes that participate in this pathway, allowing the engineering of an improved strain for production of PDC from lignin.

A heterodimeric glutathione S-transferase that stereospecifically breaks lignin's ß(R)-aryl ether bond reveals the diversity of bacterial ß-etherases.

Lignin is a heterogeneous polymer of aromatic subunits that is a major component of lignocellulosic plant biomass. Understanding how microorganisms deconstruct lignin is important for understanding the global carbon cycle and could aid in developing systems for processing plant biomass into valuable commodities. Sphingomonad bacteria use stereospecific glutathione S-transferases (GSTs) called ß-etherases to cleave the ß-aryl ether (ß-O-4) bond, the most common bond between aromatic subunits in lignin. Previously characterized bacterial ß-etherases are homodimers that fall into two distinct GST subclasses: LigE homologues, which cleave the ß(R) stereoisomer of the bond, and LigF homologues, which cleave the ß(S) stereoisomer. Here, we report on a heterodimeric ß-etherase (BaeAB) from the sphingomonad Novosphingobium aromaticivorans that stereospecifically cleaves the ß(R)-aryl ether bond of the di-aromatic compound ß-(2-methoxyphenoxy)-γ-hydroxypropiovanillone (MPHPV). BaeAB's subunits are phylogenetically distinct from each other and from other ß-etherases, although they are evolutionarily related to LigF, despite the fact that BaeAB and LigF cleave different ß-aryl ether bond stereoisomers. We identify amino acid residues in BaeAB's BaeA subunit important for substrate binding and catalysis, including an asparagine that is proposed to activate the GSH cofactor. We also show that BaeAB homologues from other sphingomonads can cleave ß(R)-MPHPV and that they may be as common in bacteria as LigE homologues. Our results suggest that the ability to cleave the ß-aryl ether bond arose independently at least twice in GSTs and that BaeAB homologues may be important for cleaving the ß(R)-aryl ether bonds of lignin-derived oligomers in nature.

Novosphingobium aromaticivorans uses a Nu-class glutathione S-transferase as a glutathione lyase in breaking the ß-aryl ether bond of lignin.

As a major component of plant cell walls, lignin is a potential renewable source of valuable chemicals. Several sphingomonad bacteria have been identified that can break the ß-aryl ether bond connecting most phenylpropanoid units of the lignin heteropolymer. Here, we tested three sphingomonads predicted to be capable of breaking the ß-aryl ether bond of the dimeric aromatic compound guaiacylglycerol-ß-guaiacyl ether (GGE) and found that Novosphingobium aromaticivorans metabolizes GGE at one of the fastest rates thus far reported. After the ether bond of racemic GGE is broken by replacement with a thioether bond involving glutathione, the glutathione moiety must be removed from the resulting two stereoisomers of the phenylpropanoid conjugate ß-glutathionyl-γ-hydroxypropiovanillone (GS-HPV). We found that the Nu-class glutathione S-transferase NaGSTNu is the only enzyme needed to remove glutathione from both (R)- and (S)-GS-HPV in N. aromaticivorans We solved the crystal structure of NaGSTNu and used molecular modeling to propose a mechanism for the glutathione lyase (deglutathionylation) reaction in which an enzyme-stabilized glutathione thiolate attacks the thioether bond of GS-HPV, and the reaction proceeds through an enzyme-stabilized enolate intermediate. Three residues implicated in the proposed mechanism (Thr51, Tyr166, and Tyr224) were found to be critical for the lyase reaction. We also found that Nu-class GSTs from Sphingobium sp. SYK-6 (which can also break the ß-aryl ether bond) and Escherichia coli (which cannot break the ß-aryl ether bond) can also cleave (R)- and (S)-GS-HPV, suggesting that glutathione lyase activity may be common throughout this widespread but largely uncharacterized class of glutathione S-transferases.

In Vitro Enzymatic Depolymerization of Lignin with Release of Syringyl, Guaiacyl, and Tricin Units.

New environmentally sound technologies are needed to derive valuable compounds from renewable resources. Lignin, an abundant polymer in terrestrial plants comprised predominantly of guaiacyl and syringyl monoaromatic phenylpropanoid units, is a potential natural source of aromatic compounds. In addition, the plant secondary metabolite tricin is a recently discovered and moderately abundant flavonoid in grasses. The most prevalent interunit linkage between guaiacyl, syringyl, and tricin units is the ß-ether linkage. Previous studies have shown that bacterial ß-etherase pathway enzymes catalyze glutathione-dependent cleavage of ß-ether bonds in dimeric ß-ether lignin model compounds. To date, however, it remains unclear whether the known ß-etherase enzymes are active on lignin polymers. Here we report on enzymes that catalyze ß-ether cleavage from bona fide lignin, under conditions that recycle the cosubstrates NAD+ and glutathione. Guaiacyl, syringyl, and tricin derivatives were identified as reaction products when different model compounds or lignin fractions were used as substrates. These results demonstrate an in vitro enzymatic system that can recycle cosubstrates while releasing aromatic monomers from model compounds as well as natural and engineered lignin oligomers. These findings can improve the ability to produce valuable aromatic compounds from a renewable resource like lignin.IMPORTANCE Many bacteria are predicted to contain enzymes that could convert renewable carbon sources into substitutes for compounds that are derived from petroleum. The ß-etherase pathway present in sphingomonad bacteria could cleave the abundant ß-O-4-aryl ether bonds in plant lignin, releasing a biobased source of aromatic compounds for the chemical industry. However, the activity of these enzymes on the complex aromatic oligomers found in plant lignin is unknown. Here we demonstrate biodegradation of lignin polymers using a minimal set of ß-etherase pathway enzymes, the ability to recycle needed cofactors (glutathione and NAD+) in vitro, and the release of guaiacyl, syringyl, and tricin as depolymerized products from lignin. These observations provide critical evidence for the use and future optimization of these bacterial ß-etherase pathway enzymes for industrial-level biotechnological applications designed to derive high-value monomeric aromatic compounds from lignin.

A Cardiolipin-Deficient Mutant of Rhodobacter sphaeroides Has an Altered Cell Shape and Is Impaired in Biofilm Formation.

UNLABELLED: Cell shape has been suggested to play an important role in the regulation of bacterial attachment to surfaces and the formation of communities associated with surfaces. We found that a cardiolipin synthase (Δcls) mutant of the rod-shaped bacterium Rhodobacter sphaeroides--in which synthesis of the anionic, highly curved phospholipid cardiolipin (CL) is reduced by 90%--produces ellipsoid-shaped cells that are impaired in biofilm formation. Reducing the concentration of CL did not cause significant defects in R. sphaeroides cell growth, swimming motility, lipopolysaccharide and exopolysaccharide production, surface adhesion protein expression, and membrane permeability. Complementation of the CL-deficient mutant by ectopically expressing CL synthase restored cells to their rod shape and increased biofilm formation. Treating R. sphaeroides cells with a low concentration (10 µg/ml) of the small-molecule MreB inhibitor S-(3,4-dichlorobenzyl)isothiourea produced ellipsoid-shaped cells that had no obvious growth defect yet reduced R. sphaeroides biofilm formation. This study demonstrates that CL plays a role in R. sphaeroides cell shape determination, biofilm formation, and the ability of the bacterium to adapt to its environment. IMPORTANCE: Membrane composition plays a fundamental role in the adaptation of many bacteria to environmental stress. In this study, we build a new connection between the anionic phospholipid cardiolipin (CL) and cellular adaptation in Rhodobacter sphaeroides. We demonstrate that CL plays a role in the regulation of R. sphaeroides morphology and is important for the ability of this bacterium to form biofilms. This study correlates CL concentration, cell shape, and biofilm formation and provides the first example of how membrane composition in bacteria alters cell morphology and influences adaptation. This study also provides insight into the potential of phospholipid biosynthesis as a target for new chemical strategies designed to alter or prevent biofilm formation.

Metabolism of Multiple Aromatic Compounds in Corn Stover Hydrolysate by Rhodopseudomonas palustris.

Lignocellulosic biomass hydrolysates hold great potential as a feedstock for microbial biofuel production, due to their high concentration of fermentable sugars. Present at lower concentrations are a suite of aromatic compounds that can inhibit fermentation by biofuel-producing microbes. We have developed a microbial-mediated strategy for removing these aromatic compounds, using the purple nonsulfur bacterium Rhodopseudomonas palustris. When grown photoheterotrophically in an anaerobic environment, R. palustris removes most of the aromatics from ammonia fiber expansion (AFEX) treated corn stover hydrolysate (ACSH), while leaving the sugars mostly intact. We show that R. palustris can metabolize a host of aromatic substrates in ACSH that have either been previously described as unable to support growth, such as methoxylated aromatics, and those that have not yet been tested, such as aromatic amides. Removing the aromatics from ACSH with R. palustris, allowed growth of a second microbe that could not grow in the untreated ACSH. By using defined mutants, we show that most of these aromatic compounds are metabolized by the benzoyl-CoA pathway. We also show that loss of enzymes in the benzoyl-CoA pathway prevents total degradation of the aromatics in the hydrolysate, and instead allows for biological transformation of this suite of aromatics into selected aromatic compounds potentially recoverable as an additional bioproduct.

Using solutes and kinetics to probe large conformational changes in the steps of transcription initiation.

Small solutes are useful probes of large conformational changes in RNA polymerase-promoter interactions and other biopolymer processes. In general, a large effect of a solute on an equilibrium constant (or rate constant) indicates a large change in water-accessible biopolymer surface area in the corresponding step (or transition state), resulting from conformational changes, interface formation, or both. Here, we describe nitrocellulose filter binding assays from series used to determine the urea dependence of open complex formation and dissociation with Escherichia coli RNA polymerase and phage λPR promoter DNA. Then, we describe the subsequent data analysis and interpretation of these solute effects.

Probing the protein-folding mechanism using denaturant and temperature effects on rate constants.

Protein folding has been extensively studied, but many questions remain regarding the mechanism. Characterizing early unstable intermediates and the high-free-energy transition state (TS) will help answer some of these. Here, we use effects of denaturants (urea, guanidinium chloride) and temperature on folding and unfolding rate constants and the overall equilibrium constant as probes of surface area changes in protein folding. We interpret denaturant kinetic m-values and activation heat capacity changes for 13 proteins to determine amounts of hydrocarbon and amide surface buried in folding to and from TS, and for complete folding. Predicted accessible surface area changes for complete folding agree in most cases with structurally determined values. We find that TS is advanced (50-90% of overall surface burial) and that the surface buried is disproportionately amide, demonstrating extensive formation of secondary structure in early intermediates. Models of possible pre-TS intermediates with all elements of the native secondary structure, created for several of these proteins, bury less amide and hydrocarbon surface than predicted for TS. Therefore, we propose that TS generally has both the native secondary structure and sufficient organization of other regions of the backbone to nucleate subsequent (post-TS) formation of tertiary interactions. The approach developed here provides proof of concept for the use of denaturants and other solutes as probes of amount and composition of the surface buried in coupled folding and other large conformational changes in TS and intermediates in protein processes.

Revised sequence and annotation of the Rhodobacter sphaeroides 2.4.1 genome.

The DNA sequences of chromosomes I and II of Rhodobacter sphaeroides strain 2.4.1 have been revised, and the annotation of the entire genomic sequence, including both chromosomes and the five plasmids, has been updated. Errors in the originally published sequence have been corrected, and ~11% of the coding regions in the original sequence have been affected by the revised annotation.

Maximizing reductant flow into microbial H2 production.

Developing microbes into a sustainable source of hydrogen gas (H2) will require maximizing intracellular reductant flow toward the H2-producing enzymes. Recent attempts to increase H2 production in dark fermentative bacteria include increasing oxidation of organic substrates through metabolic engineering and expression of exogenous hydrogenases. In photofermentative bacteria, H2 production can be increased by minimizing reductant flow into competing pathways such as biomass formation and the Calvin cycle. One method of directing reductant toward H2 production being investigated in oxygenic phototrophs, which could potentially be applied to other H2-producing organisms, is the tethering of electron donors and acceptors, such as hydrogenase and photosystem I, to create new intermolecular electron transfer pathways.

Pathways involved in reductant distribution during photobiological H(2) production by Rhodobacter sphaeroides.

We used global transcript analyses and mutant studies to investigate the pathways that impact H(2) production in the photosynthetic bacterium Rhodobacter sphaeroides. We found that H(2) production capacity is related to the levels of expression of the nitrogenase and hydrogenase enzymes and the enzymes of the Calvin-Benson-Bassham pathway.

One-step DNA melting in the RNA polymerase cleft opens the initiation bubble to form an unstable open complex.

Though opening of the start site (+1) region of promoter DNA is required for transcription by RNA polymerase (RNAP), surprisingly little is known about how and when this occurs in the mechanism. Early events at the lambdaP(R) promoter load this region of duplex DNA into the active site cleft of Escherichia coli RNAP, forming the closed, permanganate-unreactive intermediate I(1). Conversion to the subsequent intermediate I(2) overcomes a large enthalpic barrier. Is I(2) open? Here we create a burst of I(2) by rapidly destabilizing open complexes (RP(o)) with 1.1 M NaCl. Fast footprinting reveals that thymines at positions from -11 to +2 in I(2) are permanganate-reactive, demonstrating that RNAP opens the entire initiation bubble in the cleft in a single step. Rates of decay of all observed thymine reactivities are the same as the I(2) to I(1) conversion rate determined by filter binding. In I(2), permanganate reactivity of the +1 thymine on the template (t) strand is the same as the RP(o) control, whereas nontemplate (nt) thymines are significantly less reactive than in RP(o). We propose that: (i) the +1(t) thymine is in the active site in I(2); (ii) conversion of I(2) to RP(o) repositions the nt strand in the cleft; and (iii) movements of the nt strand are coupled to the assembly and DNA binding of the downstream clamp and jaw that occurs after DNA opening and stabilizes RP(o). We hypothesize that unstable open intermediates at the lambdaP(R) promoter resemble the unstable, transcriptionally competent open complexes formed at ribosomal promoters.

Probing DNA binding, DNA opening, and assembly of a downstream clamp/jaw in Escherichia coli RNA polymerase-lambdaP(R) promoter complexes using salt and the physiological anion glutamate.

Transcription by all RNA polymerases (RNAPs) requires a series of large-scale conformational changes to form the transcriptionally competent open complex RP(o). At the lambdaP(R) promoter, Escherichia coli sigma(70) RNAP first forms a wrapped, closed 100 bp complex I(1). The subsequent step opens the entire DNA bubble, creating the relatively unstable (open) complex I(2). Additional conformational changes convert I(2) to the stable RP(o). Here we probe these events by dissecting the effects of Na(+) salts of Glu(-), F(-), and Cl(-) on each step in this critical process. Rapid mixing and nitrocellulose filter binding reveal that the binding constant for I(1) at 25 degrees C is approximately 30-fold larger in Glu(-) than in Cl(-) at the same Na(+) concentration, with the same log-log salt concentration dependence for both anions. In contrast, both the rate constant and equilibrium constant for DNA opening (I(1) to I(2)) are only weakly dependent on salt concentration, and the opening rate constant is insensitive to replacement of Cl(-) with Glu(-). These very small effects of salt concentration on a process (DNA opening) that is strongly dependent on salt concentration in solution may indicate that the backbones of both DNA strands interact with polymerase throughout the process and/or that compensation is present between ion uptake and release. Replacement of Cl(-) with Glu(-) or F(-) at 25 degrees C greatly increases the lifetime of RP(o) and greatly reduces its salt concentration dependence. By analogy to Hofmeister salt effects on protein folding, we propose that the excluded anions Glu(-) and F(-) drive the folding and assembly of the RNAP clamp/jaw domains in the conversion of I(2) to RP(o), while Cl(-) does not. Because the Hofmeister effect of Glu(-) or F(-) largely compensates for the destabilizing Coulombic effect of any salt on the binding of this assembly to downstream promoter DNA, RP(o) remains long-lived even at 0.5 M Na(+) in Glu(-) or F(-) salts. The observation that Esigma(70) RP(o) complexes are exceedingly long-lived at moderate to high Glu(-) concentrations argues that Esigma(70) RNAP does not dissociate from strong promoters in vivo when the cytoplasmic glutamate concentration increases during osmotic stress.

Late steps in the formation of E. coli RNA polymerase-lambda P R promoter open complexes: characterization of conformational changes by rapid [perturbant] upshift experiments.

The formation of the transcriptionally competent open complex (RP(o)) by Escherichia coli RNA polymerase at the lambda P(R) promoter involves at least three steps and two kinetically significant intermediates (I(1) and I(2)). Understanding the sequence of conformational changes (rearrangements in the jaws of RNA polymerase, DNA opening) that occur in the conversion of I(1) to RP(o) requires: (1) dissecting the rate constant k(d) for the dissociation of RP(o) into contributions from individual steps and (2) isolating and characterizing I(2). To deconvolute k(d), we develop experiments involving rapid upshifts to elevated concentrations of RP(o)-destabilizing solutes ("perturbants": urea and KCl) to create a burst in the population of I(2). At high concentrations of either perturbant, k(d) approaches the same [perturbant]-independent value, interpreted as the elementary rate constant k(-2) for I(2)-->I(1). The large effects of [urea] and [salt] on K(3) (the equilibrium constant for I(2) is in equilibrium with RP(o)) indicate that a large-scale folding transition in polymerase occurs and a new interface with the DNA forms late in the mechanism. We deduce that I(2) at the lambda P(R) promoter is always unstable relative to RP(o), even at 0 degrees C, explaining previous difficulties in detecting it by using temperature downshifts. The division of the large positive enthalpy change between the late steps of the mechanism suggests that an additional unstable intermediate (I(3)) may exist between I(2) and RP(o).

Solute probes of conformational changes in open complex (RPo) formation by Escherichia coli RNA polymerase at the lambdaPR promoter: evidence for unmasking of the active site in the isomerization step and for large-scale coupled folding in the subsequent conversion to RPo.

Transcription initiation is a multistep process involving a series of requisite conformational changes in RNA polymerase (R) and promoter DNA (P) that create the open complex (RP(o)). Here, we use the small solutes urea and glycine betaine (GB) to probe the extent and type of surface area changes in the formation of RP(o) between Esigma(70) RNA polymerase and lambdaP(R) promoter DNA. Effects of urea quantitatively reflect changes in amide surface and are particularly well-suited to detect coupled protein folding events. GB provides a qualitative probe for the exposure or burial of anionic surface. Kinetics of formation and dissociation of RP(o) reveal strikingly large effects of the solutes on the final steps of RP(o) formation: urea dramatically increases the dissociation rate constant k(d), whereas GB decreases the rate of dissociation. Formation of the first kinetically significant intermediate I(1) is disfavored in urea, and moderately favored by GB. GB slows the rate-determining step that converts I(1) to the second kinetically significant intermediate I(2); urea has no effect on this step. The most direct interpretation of these data is that recognition of promoter DNA in I(1) involves only limited conformational changes. Notably, the data support the following hypotheses: (1) the negatively charged N-terminal domain of sigma(70) remains bound in the "jaws" of polymerase in I(1); (2) the subsequent rate-determining isomerization step involves ejecting this domain from the jaws, thereby unmasking the active site; and (3) final conversion to RP(o) involves coupled folding of the mobile downstream clamp of polymerase.