Ursula Liebl

Coherent reaction dynamics in a bacterial cytochrome c oxidase

Biological reactions in protein complexes involve structural dynamics spanning many orders of magnitude in time. In standard descriptions of catalysis by enzymes, the transition state between reactant and product is reached by thermal, stochastic motion. In the ultrashort time domain, however, the protein moiety and cofactor motions leading to altered conformations can be coherent rather than stochastic in nature. Such coherent motions may play a key role in controlling the accessibility of the transition state and explain the high efficiency of the reaction. Here we present evidence for coherent population transfer to the product state during an ultrafast reaction catalysed by a key enzyme in aerobic organisms. Using the enzyme cytochrome c oxidase aa3 from the bacterium Paracoccus denitrificans, we have studied haem dynamics during the photo-initiated ultrafast transfer of carbon monoxide from haem a3 to CuB by femtosecond spectroscopy. The ground state of the unliganded a3 species is populated in a stepwise manner in time, indicating that the reaction is mainly governed by coherent vibrations (47 cm-1). The reaction coordinate involves conformational relaxation of the haem group and we suggest that ligand transfer also contributes.

Interaction of Carbon Monoxide with the Apoptosis-Inducing Cytochrome c-Cardiolipin Complex

The interaction of mitochondrial cytochrome (cyt) c with cardiolipin (CL) is involved in the initial stages of apoptosis. This interaction can lead to destabilization of the heme-Met80 bond and peroxidase activity [Basova, L. V., et al. (2007) Biochemistry 46, 3423-3434]. We show that under these conditions carbon monoxide (CO) binds to cyt c, with very high affinity ( approximately 5 x 10(7) M(-1)), in contrast to the native cyt c protein involved in respiratory electron shuttling that does not bind CO. Binding of CO to the cyt c-CL complex inhibits its peroxidase activity. Photodissociated CO from the cyt c-CL complex shows <20% picosecond geminate rebinding and predominantly bimolecular rebinding, with a second-order rate constant of approximately 10(7) M(-1) s(-1), an order of magnitude higher than in myoglobin. These findings contrast with those of Met80X mutant cyt c, where picosecond geminate recombination dominates due to the rigidity of the protein. Our data imply that CL leads to substantial changes in protein conformation and flexibility, allowing access of ligands to the heme. Together with the findings that (a) approximately 30 CL per cyt c are required for full CO binding and (b) salt-induced dissociation indicates that the two negative headgroup charges interact with approximately 5 positive surface charges of the protein, these results are consistent with a CL anchorage model with an acyl chain impaled in the protein [Kalanxhi, E., and Wallace, C. J. A. (2007) Biochem. J. 407, 179-187]. The affinity of CO for the complex is high enough to envisage an antiapoptotic effect of nanomolar CO concentrations via inhibition of the cyt c peroxidase activity.

Catalytic Mechanism and Structure of Viral Flavin-Dependent Thymidylate Synthase Thyx.

By using biochemical and structural analyses, we have investigated the catalytic mechanism of the recently discovered flavin-dependent thymidylate synthase ThyX from Paramecium bursaria chlorella virus-1 (PBCV-1). Site-directed mutagenesis experiments have identified several residues implicated in either NADPH oxidation or deprotonation activity of PBCV-1 ThyX. Chemical modification by diethyl pyrocarbonate and mass spectroscopic analyses identified a histidine residue (His53) crucial for NADPH oxidation and located in the vicinity of the redox active N-5 atom of the FAD ring system. Moreover, we observed that the conformation of active site key residues of PBCV-1 ThyX differs from earlier reported ThyX structures, suggesting structural changes during catalysis. Steady-state kinetic analyses support a reaction mechanism where ThyX catalysis proceeds via formation of distinct ternary complexes without formation of a methyl enzyme intermediate.

Ultrafast ligand rebinding in the heme domain of the oxygen sensors FixL and Dos: General regulatory implications for heme-based sensors

Heme-based oxygen sensors are part of ligand-specific two-component regulatory systems, which have both a relatively low oxygen affinity and a low oxygen-binding rate. To get insight into the dynamical aspects underlying these features and the ligand specificity of the signal transduction from the heme sensor domain, we used femtosecond spectroscopy to study ligand dynamics in the heme domains of the oxygen sensors FixL from Bradyrhizobium japonicum (FixLH) and Dos from Escherichia coli (DosH). The heme coordination with different ligands and the corresponding ground-state heme spectra of FixLH are similar to myoglobin (Mb). After photodissociation, the excited-state properties and ligand-rebinding kinetics are qualitatively similar for FixLH and Mb for CO and NO as ligands. In contrast to Mb, the transient spectra of FixLH after photodissociation of ligands are distorted compared with the ground-state difference spectra, indicating differences in the heme environment with respect to the unliganded state. This distortion is particularly marked for O2. Strikingly, heme–O2 recombination occurs with efficiency unprecedented for heme proteins, in ≈5 ps for ≈90% of the dissociated O2. For DosH–O2, which shows 60% sequence similarity to FixLH, but where signal detection and transmission presumably are quite different, a similarly fast recombination was found with an even higher yield. Altogether these results indicate that in these sensors the heme pocket acts as a ligand-specific trap. The general implications for the functioning of heme-based ligand sensors are discussed in the light of recent studies on heme-based NO and CO sensors.

Discovery of Intracellular Heme-binding Protein HrtR, Which Controls Heme Efflux by the Conserved HrtB-HrtA Transporter in Lactococcus lactis

Background: Heme is an essential cofactor yet toxic in free form, necessitating strict intracellular control. Results: A heme sensor regulates the conserved hrtBA genes in Lactococcus lactis, whose products mediate heme efflux. Conclusion: L. lactis controls heme homeostasis by sensing intracellular heme and activating heme efflux. Significance: The use of an intracellular heme sensor to control heme efflux constitutes a novel paradigm for bacterial heme homeostasis. Most commensal and food bacteria lack heme biosynthesis genes. For several of these, the capture of environmental heme is a means of activating aerobic respiration metabolism. Our previous studies in the Gram-positive bacterium Lactococcus lactis showed that heme exposure strongly induced expression of a single operon, called here hrtRBA, encoding an ortholog of the conserved membrane hrt (heme-regulated transporter) and a unique transcriptional regulator that we named HrtR. We show that HrtR expressed as a fusion protein is a heme-binding protein. Heme iron interaction with HrtR is non-covalent, hexacoordinated, and involves two histidines, His-72 and His-149. HrtR specifically binds a 15-nt palindromic sequence in the hrtRBA promoter region, which is needed for hrtRBA repression. HrtR-DNA binding is abolished by heme addition, which activates expression of the HrtB-HrtA (HrtBA) transporter in vitro and in vivo. The use of HrtR as an intracellular heme sensor appears to be conserved among numerous commensal bacteria, in contrast with numerous Gram-positive pathogens that use an extracellular heme-sensing system, HssRS, to regulate hrt. Finally, we show for the first time that HrtBA permease controls heme toxicity by its direct and specific efflux. The use of an intracellular heme sensor to control heme efflux constitutes a novel paradigm for bacterial heme homeostasis.

The pH dependence of the redox midpoint potential of the 2Fe2S cluster from cytochrome b6f complex (the ‘Rieske centre’)

The pH dependence of the redox midpoint potential (Em) of the Rieske centre from spinach cytochrome b6f complex was studied by EPR. The Em was found to be independent of pH up to pH 8 and to decrease at higher pH values. The slope of the decrease above the pK value was roughly consistent with the involvement of a dissociable proton on the oxidized form of the cluster. The Em in the pH-independent region (i.e. <pH 8) was determined to be +320 mV. This is in contrast to the original value (Em = + 290 mV) reported by Malkin and Aparicio (Biochem. Biophys. Res. Commun. 63 (1975) 1157–1160) and confirms the results reported more recently (Em = 310 − 320 mV) by Malkin (FEBS Lett. 131 (1981) 169–172) and Nitschke et al. (Biochim. Biophys. Acta 974 (1989) 223–226).

Role of Arginine 220 in the Oxygen Sensor FixL from Bradyrhizobium japonicum

In the heme-based oxygen sensor protein FixL, conformational changes induced by oxygen binding to the heme sensor domain regulate the activity of a neighboring histidine kinase, eventually restricting expression of specific genes to hypoxic conditions. The conserved arginine 220 residue is suggested to play a key role in the signal transduction mechanism. To obtain detailed insights into the role of this residue, we replaced Arg220 by histidine (R220H), glutamine (R220Q), glutamate (R220E), and isoleucine (R220I) in the heme domain FixLH from Bradyrhizobium japonicum. These mutations resulted in dramatic changes in the O2 affinity with Kd values in the order R220I < R220Q < wild type < R220H. For the R220H and R220Q mutants, residue 220 interacts with the bound O2 or CO ligands, as seen by resonance Raman spectroscopy. For the oxy-adducts, this H-bond modifies the π acidity of the O2 ligand, and its strength is correlated with the back-bonding-sensitive ν4 frequency, the koff value for O2 dissociation, and heme core-size conformational changes. This effect is especially strong for the wild-type protein where Arg220 is, in addition, positively charged. These observations strongly suggest that neither strong ligand fixation nor the displacement of residue 220 into the heme distal pocket are solely responsible for the reported heme conformational changes associated with kinase activity regulation, but that a significant decrease of the heme π* electron density because of strong back-bonding toward the oxygen ligand also plays a key role.

Evidence for a unique Rieske iron-sulphur centre in Heliobacterium chlorum

An iron sulphur centre (g z = 2.035, g y =1.89, g x =1.81), which can be observed in both whole cells and isolated plasma membranes of Heliobacterium chlorum, was identified as a Rieske centre on the basis of its sensitivity to the inhibitors 2,5‐dibromo‐3‐methyl‐6‐isopropyl‐benzoquinone (DBMIB), 5‐(n‐undecyl)‐6‐hydroxy‐4,7‐dioxobenzothiazole (UHDBT) and stigmatellin as well as on the basis of its orientation (gx, is oriented perpendicular and g y is oriented parallel to the membrane plane). Its midpoint potential is unusually low (E m,7= +120 ± 10 mV) and does not depend on pH in the range between pH 6.5 and pH 8.0. The effects of the inhibitors on the EPR spectrum are altered compared to Rieske centres in other systems. The significance of the low E m is discussed with regard to the overall midpoint potentials of the electron transfer chain in Heliobacterium chlorum.

Flavin-Dependent Thymidylate Synthase ThyX Activity: Implications for the Folate Cycle in Bacteria

Although flavin-dependent ThyX proteins show thymidylate synthase activity in vitro and functionally complement thyA defects in heterologous systems, direct proof of their cellular functions is missing. Using insertional mutagenesis of Rhodobacter capsulatus thyX, we constructed the first defined thyX inactivation mutant. Phenotypic analyses of the obtained mutant strain confirmed that R. capsulatus ThyX is required for de novo thymidylate synthesis. Full complementation of the R. capsulatus thyX::spec strain to thymidine prototrophy required not only the canonical thymidylate synthase ThyA but also the dihydrofolate reductase FolA. Strikingly, we also found that addition of exogenous methylenetetrahydrofolate transiently inhibited the growth of the different Rhodobacter strains used in this work. To rationalize these experimental results, we used a mathematical model of bacterial folate metabolism. This model suggests that a very low dihydrofolate reductase activity is enough to rescue significant thymidylate synthesis in the presence of ThyX proteins and is in agreement with the notion that intracellular accumulation of folates results in growth inhibition. In addition, our observations suggest that the presence of flavin-dependent thymidylate synthase X provides growth benefits under conditions in which the level of reduced folate derivatives is compromised.

Flavin-dependent thymidylate synthase X limits chromosomal DNA replication

We have investigated the hitherto unexplored possibility that differences in the catalytic efficiencies of thymidylate synthases ThyX and ThyA, enzymes that produce the essential DNA precursor dTMP, have influenced prokaryotic genome evolution. We demonstrate that DNA replication speed in bacteria and archaea that contain the low-activity ThyX enzyme is up to 10-fold decreased compared with species that contain the catalytically more efficient ThyA. Our statistical studies of >400 genomes indicated that ThyA proteins are preferred for the replication of large genomes, providing further evidence that the thymidylate metabolism is limiting expansion of prokaryotic genomes. Because both ThyX and ThyA participate in frequent reciprocal gene replacement events, our observations indicate that the bacterial metabolism continues to modulate the size and composition of prokaryotic genomes. We also propose that the increased kinetic efficiency of thymidylate synthesis has contributed to extending the prokaryotic evolutionary potential.