Solution structure and properties of AlgH from Pseudomonas aeruginosa.

In Pseudomonas aeruginosa, the algH gene regulates the cellular concentrations of a number of enzymes and the production of several virulence factors, and is suggested to serve a global regulatory function. The precise mechanism by which the algH gene product, the AlgH protein, functions is unknown. The same is true for AlgH family members from other bacteria. In order to lay the groundwork for understanding the physical underpinnings of AlgH function, we examined the structure and physical properties of AlgH in solution. Under reducing conditions, results of NMR, electrophoretic mobility, and sedimentation equilibrium experiments indicate AlgH is predominantly monomeric and monodisperse in solution. Under nonreducing conditions intra and intermolecular disulfide bonds form, the latter promoting AlgH oligomerization. The high-resolution solution structure of AlgH reveals alpha/beta-sandwich architecture fashioned from ten beta strands and seven alpha helices. Comparison with available structures of orthologues indicates conservation of overall structural topology. The region of the protein most strongly conserved structurally also shows the highest amino acid sequence conservation and, as revealed by hydrogen-deuterium exchange studies, is also the most stable. In this region, evolutionary trace analysis identifies two clusters of amino acid residues with the highest evolutionary importance relative to all other AlgH residues. These frame a partially solvent exposed shallow hydrophobic cleft, perhaps identifying a site for intermolecular interactions. The results establish a physical foundation for understanding the structure and function of AlgH and AlgH family proteins and should be of general importance for further investigations of these and related proteins.

Proton-induced reactivity of NO⁻ from a {CoNO}8 complex.

Research on the one-electron reduced analogue of NO, namely nitroxyl (HNO/NO(-)), has revealed distinguishing properties regarding its utility as a therapeutic. However, the fleeting nature of HNO requires the design of donor molecules. Metal nitrosyl (MNO) complexes could serve as potential HNO donors. The synthesis, spectroscopic/structural characterization, and HNO donor properties of a {CoNO}(8) complex in a pyrrole/imine ligand frame are reported. The {CoNO}(8) complex [Co(LN4(PhCl))(NO)] (1) does not react with established HNO targets such as Fe(III) hemes or Ph3P. However, in the presence of stoichiometric H(+) 1 behaves as an HNO donor. Complex 1 readily reacts with [Fe(TPP)Cl] or Ph3P to afford the {FeNO}(7) porphyrin or Ph3P═O/Ph3P═NH, respectively. In the absence of an HNO target, the {Co(NO)2}(10) dinitrosyl (3) is the end product. Complex 1 also reacts with O2 to yield the corresponding Co(III)-η(1)-ONO2 (2) nitrato analogue. This report is the first to suggest an HNO donor role for {CoNO}(8) with biotargets such as Fe(III)-porphyrins.

Determinants of affinity and activity of the anti-sigma factor AsiA.

The AsiA protein is a T4 bacteriophage early gene product that regulates transcription of host and viral genes. Monomeric AsiA binds tightly to the sigma(70) subunit of Escherichia coli RNA polymerase, thereby inhibiting transcription from bacterial promoters and phage early promoters and coactivating transcription from phage middle promoters. Results of structural studies have identified amino acids at the protomer-protomer interface in dimeric AsiA and at the monomeric AsiA-sigma(70) interface and demonstrated substantial overlap in the sets of residues that comprise each. Here we evaluate the contributions of individual interfacial amino acid side chains to protomer-protomer affinity in AsiA homodimers, to monomeric AsiA affinity for sigma(70), and to AsiA function in transcription. Sedimentation equilibrium, dynamic light scattering, electrophoretic mobility shift, and transcription activity measurements were used to assess affinity and function of site-specific AsiA mutants. Alanine substitutions for solvent-inaccessible residues positioned centrally in the protomer-protomer interface of the AsiA homodimer, V14, I17, and I40, resulted in the largest changes in free energy of dimer association, whereas alanine substitutions at other interfacial positions had little effect. These residues also contribute significantly to AsiA-dependent regulation of RNA polymerase activity, as do additional residues positioned at the periphery of the interface (K20 and F21). Notably, the relative contributions of a given amino acid side chain to RNA polymerase inhibition and activation (MotA-independent) by AsiA are very similar in most cases. The mainstay for intermolecular affinity and AsiA function appears to be I17. Our results define the core interfacial residues of AsiA, establish roles for many of the interfacial amino acids, are in agreement with the tenets underlying protein-protein interactions and interfaces, and will be beneficial for a general, comprehensive understanding of the mechanistic underpinnings of bacterial RNA polymerase regulation.

Single-molecule tracking of sub-millisecond domain motion in calmodulin.

We used single-pair fluorescence resonance energy transfer (spFRET) to track distance changes between domains of fluorescently labeled calmodulin (CaM) on the sub-millisecond time scale. In most cases, CaM remained in the same conformational substate over time periods of up to 1 ms, showing that conformational interchange occurs on a longer time scale. However, in some instances, apparent transitions between conformational substates could be detected. The magnitude of sub-millisecond motion within the dominant conformational substate also revealed fluctuations in distance between domains that were dependent on pH and ionic strength.

Structural and functional effects of tryptophans inserted into the membrane-binding and substrate-binding sites of human group IIA phospholipase A2.

Phospholipase A(2) (PLA(2)) enzymes become activated by binding to biological membranes and hydrolyze phospholipids to free fatty acids and lyso-phospholipids, the precursors of inflammatory mediators. To understand the functional significance of amino acid residues at key positions, we have studied the effects of the substitution of Val(3) (membrane binding surface) and Phe(5) (substrate binding pocket) of human group IIA PLA(2) by tryptophan on the structure and function of the enzyme. Despite the close proximity of the sites of mutations, the V3W mutation results in substantial enhancement of the enzyme activity, whereas the F5W mutant demonstrates significantly suppressed activity. A structural analysis of all three proteins free in buffer and bound to membranes indicates that large differences in activities result from distinct conformational changes in PLA(2)s upon membrane binding. Although PLA(2) and the V3W mutant demonstrate a decrease in helical content and an increase in helix flexibility, the F5W mutant experiences partial distortion of the alpha-helical structure presumably resulting from the tendency of Trp(5) to insert into the membrane. Furthermore, whereas the PLA(2) and the V3W mutant bind to the membrane at similar and apparently productive-mode orientation, the F5W mutant binds to membranes with a distinctly different orientation. It is suggested that both the stimulatory effect of the V3W mutation and the inhibitory effect of the F5W mutation result from the high affinity of Trp for the membrane-water interface. Although Trp(3) at the membrane binding face of PLA(2) facilitates the proper membrane binding of the enzyme, Trp(5) in the internal substrate binding site causes partial unwinding of the N-terminal helix in order to interact with the membrane.

Sampling unfolding intermediates in calmodulin by single-molecule spectroscopy.

We used single-pair fluorescence resonance energy transfer (spFRET) measurements to characterize denatured and partially denatured states of the multidomain calcium signaling protein calmodulin (CaM) in both its apo and Ca(2+)-bound forms. The results demonstrate the existence of an unfolding intermediate. A CaM mutant (CaM-T34C-T110C) was doubly labeled with fluorescent probes AlexaFlour 488 and Texas Red at opposing globular domains. Single-molecule distributions of the distance between fluorophores were obtained by spFRET at varying levels of the denaturant urea. Multiple conformational states of CaM were observed, and the amplitude of each conformation was dependent on urea concentration, with the amplitude of an extended conformation increasing upon denaturation. The distributions at intermediate urea concentrations could not be adequately described as a combination of native and denatured conformations, showing that CaM does not denature via a two-state process and demonstrating that at least one intermediate is present. The intermediate conformations formed upon addition of urea were different for Ca(2+)-CaM and apoCaM. An increase in the amplitude of a compact conformation in CaM was observed for apoCaM but not for Ca(2+)-CAM upon the addition of urea. The changes in the single-molecule distributions of CaM upon denaturation can be described by either a range of intermediate structures or by the presence of a single unfolding intermediate that grows in amplitude upon denaturation. A model for stepwise unfolding of CaM is suggested in which the domains of CaM unfold sequentially.

Mediating molecular recognition by methionine oxidation: conformational switching by oxidation of methionine in the carboxyl-terminal domain of calmodulin.

The C-terminus of calmodulin (CaM) functions as a sensor of oxidative stress, with oxidation of methionine 144 and 145 inducing a nonproductive association of the oxidized CaM with the plasma membrane Ca(2+)-ATPase (PMCA) and other target proteins to downregulate cellular metabolism. To better understand the structural underpinnings and mechanism of this switch, we have engineered a CaM mutant (CaM-L7) that permits the site-specific oxidation of M144 and M145, and we have used NMR spectroscopy to identify structural changes in CaM and CaM-L7 and changes in the interactions between CaM-L7 and the CaM-binding sequence of the PMCA (C28W) due to methionine oxidation. In CaM and CaM-L7, methionine oxidation results in nominal secondary structural changes, but chemical shift changes and line broadening in NMR spectra indicate significant tertiary structural changes. For CaM-L7 bound to C28W, main chain and side chain chemical shift perturbations indicate that oxidation of M144 and M145 leads to large tertiary structural changes in the C-terminal hydrophobic pocket involving residues that comprise the interface with C28W. Smaller changes in the N-terminal domain also involving residues that interact with C28W are observed, as are changes in the central linker region. At the C-terminal helix, (1)H(alpha), (13)C(alpha), and (13)CO chemical shift changes indicate decreased helical character, with a complete loss of helicity for M144 and M145. Using (13)C-filtered, (13)C-edited NMR experiments, dramatic changes in intermolecular contacts between residues in the C-terminal domain of CaM-L7 and C28W accompany oxidation of M144 and M145, with an essentially complete loss of contacts between C28W and M144 and M145. We propose that the inability of CaM to fully activate the PMCA after methionine oxidation originates in a reduced helical propensity for M144 and M145, and results primarily from a global rearrangement of the tertiary structure of the C-terminal globular domain that substantially alters the interaction of this domain with the PMCA.

Cloning, high yield overexpression, purification, and characterization of AlgH, a regulator of alginate biosynthesis in Pseudomonas aeruginosa.

The most common cause of mortality among cystic fibrosis sufferers is infection by antibiotic resistant strains of Pseudomonas aeruginosa. Means to control these strains continue to be an important goal. An integral component of the ability of many of these strains to defy antibiotic therapies is the protection afforded by the mucoexopolysaccharide alginate. Production of alginate by P. aeruginosa is tightly regulated at the transcriptional level. AlgH, a putative transcriptional regulator, is involved in regulating alginate biosynthesis as well as nucleoside diphosphate kinase activity and succinyl coenzyme A synthetase activity in P. aeruginosa. Sequence homologues are found in many bacterial species. Here, we describe a method for high level overexpression and high yield/high purity production of AlgH for biophysical and functional studies. The algH gene was cloned and AlgH was overexpressed in Escherichia coli using a commercially available vector with an inducible T7 promoter. We purified the recombinantly produced protein using a rapid classical purification scheme. The yield of purified protein, either isotopically labeled for NMR studies or unlabeled, is excellent (30-37 mg of purified protein per liter of minimal media culture), as is the purity (>95% pure). Analysis of the secondary structure using circular dichroism and NMR indicates that the protein is comprised of both beta-sheet and alpha-helical secondary structural elements. Heteronuclear NMR spectra indicate that AlgH is a monodisperse, folded globular protein. This rapid, high yield, and high purity method for AlgH production will permit further biophysical characterization of this protein including high resolution structural studies.

Conformational substates of calmodulin revealed by single-pair fluorescence resonance energy transfer: influence of solution conditions and oxidative modification.

A calmodulin (CaM) mutant (T34,110C-CaM) doubly labeled with fluorescence probes AlexaFluor 488 and Texas Red in opposing domains (CaM-DA) has been used to examine conformational heterogeneity in CaM by single-pair fluorescence resonance energy transfer (spFRET). Burst-integrated FRET efficiencies of freely diffusing CaM-DA single molecules yielded distributions of distance between domains of CaM-DA. We recently reported distinct conformational substates of Ca(2+)-CaM-DA and apoCaM-DA, with peaks in the distance distributions centered at approximately 28 A, 34-38 A, and 55 A [Slaughter et al. (2004) J. Phys. Chem. B 108, 10388-10397]. In the present study, shifts in the amplitudes and center distances of the conformational substates were detected with variation in solution conditions. The amplitude of an extended conformation was observed to change as a function of Ca(2+) over a free Ca(2+) range that is consistent with binding to the high affinity, C-terminal Ca(2+) binding sites, suggesting the existence of communication between lobes of CaM. Lowering pH shifted the relative amplitudes of the conformations, with a marked increase in the presence of the compact conformations and an almost complete absence of the extended conformation. In addition, the single-molecule distance distribution of apoCaM-DA at reduced ionic strength was shifted to longer distance and showed evidence of an increase in conformational heterogeneity relative to apoCaM-DA at physiological ionic strength. Oxidation of methionine residues in CaM-DA produced a substantial increase in the amplitude of the extended conformation relative to the more compact conformation. The results are considered in light of a hypothesis that suggests that electrostatic interactions between charged amino acid side chains play an important role in determining the most stable CaM conformation under varying solution conditions.

House fly cytochrome b5 exhibits kinetically trapped hemin and selectivity in hemin binding.

We report that cytochrome b(5) (cyt b(5)) from Musca domestica (house fly) is more thermally stable than all other microsomal (Mc) cytochromes b(5) that have been examined to date. It also exhibits a much higher barrier to equilibration of the two isomeric forms of the protein, which differ by a 180 degrees rotation about the alpha-gamma-meso axis of hemin (ferric heme). In fact, hemin is kinetically trapped in a nearly statistical 1.2:1 ratio of rotational forms in freshly expressed protein. The equilibrium ratio (5.5:1) is established only upon incubation at temperatures above 37 degrees C. House fly Mc cyt b(5) is only the second b-hemoprotein that has been shown to exhibit kinetically trapped hemin at room temperature or above, the first being cyt b(5) from the outer membrane of rat liver mitochondria (rat OM cyt b(5)). Finally, we show that the small excess of one orientational isomer over the other in freshly expressed protein results from selective binding of hemin by the apoprotein, a phenomenon that has not heretofore been established for any apocyt b(5).

Oxidation of Met144 and Met145 in calmodulin blocks calmodulin dependent activation of the plasma membrane Ca-ATPase.

Methionine oxidation in calmodulin (CaM) isolated from senescent brain results in an inability to fully activate the plasma membrane (PM) Ca-ATPase, which may contribute to observed increases in cytosolic calcium levels under conditions of oxidative stress and biological aging. To identify the functional importance of the oxidation of Met(144) and Met(145) near the carboxyl-terminus of CaM, we have used site-directed mutagenesis to substitute leucines for methionines at other positions in CaM, permitting the site-specific oxidation of Met(144) and Met(145). Prior to their oxidation, the CaM-dependent activation of the PM-Ca-ATPase by these CaM mutants is similar to that of wild-type CaM. Likewise, oxidation of individual methionines has a minimal effect on the CaM concentration necessary for half-maximal activation of the PM-Ca-ATPase. These results are consistent with previous suggestions that no single methionine within CaM is essential for activation of the PM-Ca-ATPase. Oxidation of either Met(144) and Met(145) or all nine methionines in CaM results in an equivalent inhibition of the PM-Ca-ATPase, resulting in a 50-60% reduction in the level of enzyme activation. Oxidation of Met(144) is largely responsible for the decreased extent of enzyme activation, suggesting that this site is critical in modulating the sensitivity of CaM to oxidant-induced loss-of-function. These results are discussed in terms of a possible functional role for Met(144) and Met(145) in CaM as redox sensors that function to modulate calcium homeostasis and energy metabolism in response to conditions of oxidative stress.

Characterization of the interactions between the bacteriophage T4 AsiA protein and RNA polymerase.

The anti-sigma factor AsiA effects a change in promoter specificity of the Escherichia coli RNA polymerase via interactions with two conserved regions of the sigma(70) subunit, denoted 4.1 and 4.2. Free AsiA is a symmetrical homodimer. Here, we show that AsiA is monomeric when bound to sigma(70) and that a subset of the residues that contribute to the homodimer interface also contributes to the interface with sigma(70). AsiA interacts primarily with C-terminal sections of regions 4.1 and 4.2, which show remarkable sequence similarity. An AsiA monomer can simultaneously, and apparently cooperatively, bind both isolated regions 4.1 and 4.2 at preferred, distinct subsites, whereas region 4.1 alone or region 4.2 alone can interact with either subsite. These results suggest structural and functional plasticity in the interaction of AsiA with sigma(70) and support the notion of discrete roles for regions 4.1 and 4.2 in transcription regulation by AsiA. Furthermore, we show that AsiA inhibits recognition of the -35 consensus promoter element by region 4 of sigma(70) indirectly, as the residues on region 4 responsible for AsiA binding are distinct from those involved in DNA binding. Finally, we show that AsiA must directly disrupt the interaction of region 4 with the RNA polymerase beta subunit flap domain, resulting in a distance change between region 2 and region 4 of sigma(70). Thus, a new paradigm for transcription regulation by AsiA is emerging, whereby the distance between the DNA binding domains in sigma(70) is regulated, and promoter recognition specificity is modulated, by mediating the interactions of the sigma region 4 with the beta subunit flap domain.