Iron-mediated Oxidation Induces Conformational Changes within the Redox-sensing Protein HbpS

HbpS is an extracellular oligomeric protein, which has been shown to act in concert with the two-component system SenS-SenR during the sensing of redox stress. HbpS can bind and degrade heme under oxidative stress conditions, leading to a free iron ion. The liberated iron is subsequently coordinated on the protein surface. Furthermore, HbpS has been shown to modulate the phosphorylation state of the sensor kinase SenS as, in the absence of oxidative stress conditions, HbpS inhibits SenS autophosphorylation whereas the presence of heme or iron ions and redox-stressing agents enhances it. Using HbpS wild type and mutants as well as different biochemical and biophysical approaches, we show that iron-mediated oxidative stress induces both secondary structure and overall intrinsic conformational changes within HbpS. We demonstrate in addition that HbpS is oxidatively modified, leading to the generation of highly reactive carbonyl groups and tyrosine-tyrosine bonds. Further examination of the crystal structure and subsequent mutational analyses allowed the identification of the tyrosine residue participating in dityrosine formation, which occurs between two monomers within the octomeric assembly. Therefore, it is proposed that oxidative modifications causing structural and conformational changes are responsible for the control of SenS and hence of the HbpS-SenS-SenR signaling cascade.     

The heme-binding protein HbpS regulates the activity of the <Emphasis Type="Italic">Streptomyces reticuli</Emphasis> iron-sensing histidine kinase SenS in a redox-dependent manner

The SenS/SenR system of Streptomyces reticuli regulates the expression of the redox regulator FurS, the catalase-peroxidase CpeB and the heme-binding protein HbpS. SenS/SenR is also proposed to participate in sensing redox changes, mediated by HbpS. Here, we show in vitro that heme-free HbpS represses the autokinase activity of SenS; whereas hemin-treated HbpS considerably enhances SenS autophosphorylation under redox conditions using either H₂O₂ or DTT. The presence of iron ions alone or in combination with H₂O₂ or DTT also leads to significantly increased phosphorylation levels of SenS. Further comparative physiological studies using the S. reticuli WT, a S. reticuli hbpS mutant and a S. reticuli senS-senR mutant corroborates the importance of HbpS and the SenS/SenR system for resistance against high concentrations of iron ions and hemin in vivo. Hence SenS/SenR and HbpS act in concert as a novel three-component system which detects redox stress, mediated by iron ions and heme.     

The three-component signalling system HbpS–SenS–SenR as an example of a redox sensing pathway in bacteria

The two-component system SenS–SenR and the extracellular HbpS protein of the cellulose degrader Streptomyces reticuli have been shown to act in concert as a novel system which detects redox stress. In vivo and in vitro experiments have led to the hypothesis that HbpS binds and degrades heme, communicating the extracellular presence of heme and oxidative stress to the membrane-embedded sensor histidine kinase SenS via a bound iron. The response regulator SenR would then up-regulate downstream signalling cascades, leading to the appropriate gene expression levels for bacterial survival in an oxidative environment. Sequence analysis has shown that homologs of HbpS and SenS–SenR exist in a number of ecologically and medically relevant bacterial species, suggesting the existence of a previously undescribed bacterial oxidative stress-response pathway common to both Gram-negative and Gram-positive bacteria. The presented report reviews the current knowledge of the function of this novel protein family consisting of an accessory protein and its cognate two-component system, which could be more properly described as a three-component system.     

The Oligomeric Assembly of the Novel Haem-Degrading Protein HbpS Is Essential for Interaction with Its Cognate Two-Component Sensor Kinase

HbpS, a novel protein of previously unknown function from Streptomyces reticuli, is up-regulated in response to haemin- and peroxide-based oxidative stress and interacts with the SenS/SenR two-component signal transduction system. In this study, we report the high-resolution crystal structures (2.2 and 1.6 Å) of octomeric HbpS crystallized in the presence and in the absence of haem and demonstrate that iron binds to surface-exposed lysine residues of an octomeric assembly. Based on an analysis of the crystal structures, we propose that the iron atom originates from the haem group and report subsequent biochemical experiments that demonstrate that HbpS possesses haem-degrading activity in vitro. Further examination of the crystal structures has identified amino acids that are essential for assembly of the octomer. The role of these residues is confirmed by biophysical experiments. Additionally, we show that while the octomeric assembly state of HbpS is not essential for haem-degrading activity, the assembly of HbpS is required for its interaction with the cognate sensor kinase, SenS. Homologs of HbpS and SenS/SenR have been identified in a number of medically and ecologically relevant bacterial species (including Vibrio cholerae, Klebsiella pneumoniae, Corynebacterium diphtheriae, Arthrobacter aurescens and Pseudomonas putida), suggesting the existence of a previously undescribed bacterial oxidative stress-response pathway common to Gram-negative and Gram-positive bacteria. Thus, the data presented provide the first insight into the function of a novel protein family and an example of an iron-mediated interaction between an accessory protein and its cognate two-component sensor kinase.     

Mechanistic studies of the SufS-SufE cysteine desulfurase: evidence for sulfur transfer from SufS to SufE

SufS is a cysteine desulfurase of the suf operon shown to be involved in iron-sulfur cluster biosynthesis under iron limitation and oxidative stress conditions. The enzyme catalyzes the conversion of L-cysteine to L-alanine and sulfide through the intermediate formation of a protein-bound cysteine persulfide in the active site. SufE, another component of the suf operon, has been previously shown to bind tightly to SufS and to drastically stimulate its cysteine desulfurase activity. Working with Escherichia coli proteins, we here demonstrate that a conserved cysteine residue in SufE at position 51 is essential for the SufS/SufE cysteine desulfurase activity. Mass spectrometry has been used to demonstrate (i). the ability of SufE to bind sulfur atoms on its cysteine 51 and (ii). the direct transfer of the sulfur atom from the cysteine persulfide of SufS to SufE. A reaction mechanism is proposed for this novel two-component cysteine desulfurase.     

Monoclonal antibodies to horse cytochrome c expressing four distinct idiotypes distribute among two sites on the native protein

Antibody-secreting hybridoma cell lines produced from BALB/c mice that had been immunized with horse cytochrome c (cyt c) conjugated to hemocyanin yielded six hybridoma subclones that produced four monoclonal antibodies (mAb) with different patterns of cross-reactivity with a panel of evolutionarily variant cyt c. The recognition sites for three of these mAb lay in the same region of the intact molecule, because two of the mAb were sensitive to the amino acid residue present at sequence position 44, with one requiring threonine at position 47. The fourth mAb bound in another region of the molecule at a site that involves either residue 60 or residue 89. Synthetic peptides that included these residues did not react with these mAb, indicating that these sites may require interactions from noncontiguous regions of the molecule to bind antibody. The association constants for the interaction of the mAb with horse cyt c were very similar and of the order of 10(10) M-1. Specificity studies with anti-idiotypic sera and competition assays between mAb for binding to horse cyt c confirmed that the six positive hybridoma subclones produced from this fusion produced mAb that had one of these four distinct specificities. The idiotypes of these four mAb were serologically distinct, and were derived from Vh genes of the J558 family.     

Biosynthesis of rat insulin-like growth factor II. II. Localization of mature rat insulin-like growth factor II (7484 daltons) to the amino terminus of the approximately 20-kilodalton biosynthetic precursor by radiosequence analysis

In previous studies, we have identified possible biosynthetic precursors of rat insulin-like growth factor II (rIGF-II) using specific immunoprecipitation, approximately 22-kDa prepro-rIGF-II and 20-kDa pro-rIGF-II. We now provide chemical evidence that amino acid sequences corresponding to mature 7484-dalton rIGF-II are present at the NH2 terminus of the putative approximately 20-kDa pro-rIGF-II. BRL-3A cultures have been labeled individually with several radioactive amino acid precursors, the cells have been lysed, and the lysates have been immunoprecipitated with antiserum to rIGF-II. Following electrophoresis of the immunoprecipitated proteins, labeled approximately 20-kDa pro-rIGF-II was eluted from the gels and subjected to automated radiosequence analysis. Discrete peaks of radioactivity were observed in 12 of the first 30 cycles of Edman degradation. The deduced partial amino acid sequence was identical at each position with that of mature 7484-dalton rIGF-II. These results directly demonstrate that mature rIGF-II sequences are present in the approximately 20-kDa protein, as required if the approximately 20-kDa protein were pro-rIGF-II. In addition, they localize the 7484-dalton rIGF-II to the NH2 terminus of the precursor molecule. A second NH2-terminal sequence differing only in the absence of the NH2-terminal residue, alanine, also was present in an approximately equal amount. Similar NH2-terminal heterogeneity has been reported for 7484-dalton rIGF-II and most likely reflects ambiguity in the cleavage sites for the signal peptidase.     

The Extracellular Heme-binding Protein HbpS from the Soil Bacterium Streptomyces reticuli Is an Aquo-cobalamin Binder

The extracellular protein HbpS from Streptomyces reticuli interacts with iron ions and heme. It also acts in concert with the two-component sensing system SenS-SenR in response to oxidative stress. Sequence comparisons suggested that the protein may bind a cobalamin. UV-visible spectroscopy confirmed binding (K_d = 34 μm) to aquo-cobalamin (H₂OCbl⁺) but not to other cobalamins. Competition experiments with the H₂OCbl⁺-coordinating ligand CN⁻ and comparison of mutants identified a histidine residue (His-156) that coordinates the cobalt ion of H₂OCbl⁺ and substitutes for water. HbpS·Cobalamin lacks the Asp-X-His-X-X-Gly motif seen in some cobalamin binding enzymes. Preliminary tests showed that a related HbpS protein from a different species also binds H₂OCbl⁺. Furthermore, analyses of HbpS-heme binding kinetics are consistent with the role of HbpS as a heme-sensor and suggested a role in heme transport. Given the high occurrence of HbpS-like sequences among Gram-positive and Gram-negative bacteria, our findings suggest a great functional versatility among these proteins.     

Protein engineering of cytochrome c by semisynthesis: substitutions at glutamic acid 66

We have used protein semisynthesis to prepare four analogues of horse cytochrome c, in which the glutamic acid residue at position 66 has been removed and replaced by norvaline, glutamine, lysine and, as a methodological control, glutamic acid. This residue is quite strongly conserved in mitochondrial cytochrome c, and forms part of a cluster of acidic residues that occurs in all cytochromes c but whose function is obscure. Comparative studies of the physical and biochemical properties of the analogues have now disclosed two specific roles for Glu66 in the protein. It contributes significantly to the stabilization of the active conformation of the protein, probably by salt bridge formation, and it appears to participate in the redox-state-dependent ATP-binding site of cytochrome c. Our results also support two general views of the role of surface charged residues in cytochrome c, namely that their disposition influences both redox potential, through the electrostatic field felt at the redox centre, and the kinetics of electron transfer, through the dipole moment they generate.     

Cardiolipin switch in mitochondria: shutting off the reduction of cytochrome c and turning on the peroxidase activity

Upon interaction with anionic phospholipids, particularly mitochondria-specific cardiolipin (CL), cytochrome c (cyt c) loses its tertiary structure and its peroxidase activity dramatically increases. CL-induced peroxidase activity of cyt c has been found to be important for selective CL oxidation in cells undergoing programmed death. During apoptosis, the peroxidase activity and the fraction of CL-bound cyt c markedly increase, suggesting that CL may act as a switch to regulate cyt c's mitochondrial functions. Using cyclic voltammetry and equilibrium redox titrations, we show that the redox potential of cyt c shifts negatively by 350-400 mV upon binding to CL-containing membranes. Consequently, functions of cyt c as an electron transporter and cyt c reduction by Complex III are strongly inhibited. Further, CL/cyt c complexes are not effective in scavenging superoxide anions and are not effectively reduced by ascorbate. Thus, both redox properties and functions of cyt c change upon interaction with CL in the mitochondrial membrane, diminishing cyt c's electron donor/acceptor role and stimulating its peroxidase activity.     

A nuclear Overhauser effect study of the heme crevice in the resting state and compound I of horseradish peroxidase: evidence for cation radical delocalization to the proximal histidine

The assignment of resolved hyperfine-shifted resonances in high-spin resting state horseradish peroxidase (HRP) and its double-oxidized reactive form, compound I (HRP-I), has been carried out by using the nuclear Overhauser effect (NOE) starting with the known heme methyl assignments in each species. In spite of the efficient spin-lattice relaxation and very broad resonances, significant NOEs were observed for all neighboring pyrrole substituents, which allowed the assignment of the elusive propionate alpha-methylene protons. In the resting state HRP, this leads directly to the identity of the proximal His-170 H beta peaks. The determination that one of the most strongly contact-shifted single proton resonances in HRP-I does not arise from the porphyrin dictates that the cation radical must be delocalized to some amino acid residue. The relaxation properties of the non-heme contact-shifted signal in HRP-I support the identity of this contributing residue as the proximal His-170. Detailed analysis of changes in both contact shift pattern and NOEs indicates that compound I formation is accompanied by a approximately 5 degree rotation of the 6-propionate group. The implication of a porphyrin cation radical delocalized over the proximal histidine for the proposed location of the solely amino acid centered radical in compound I of related cytochrome c peroxidase is discussed.     

Rhizobium meliloti fixGHI sequence predicts involvement of a specific cation pump in symbiotic nitrogen fixation.

We present genetic and structural analyses of a fix operon conserved among rhizobia, fixGHI from Rhizobium meliloti. The nucleotide sequence of the operon suggests it may contain a fourth gene, fixS. Adjacent open reading frames of this operon showed an overlap between TGA stop codons and ATG start codons in the form of an ATGA motif suggestive of translational coupling. All four predicted gene products contained probable transmembrane sequences. FixG contained two cysteine clusters typical of iron-sulfur centers and is predicted to be involved in a redox process. FixI was found to be homologous with P-type ATPases, particularly with K+ pumps from Escherichia coli and Streptococcus faecalis but also with eucaryotic Ca2+, Na+/K+, H+/K+, and H+ pumps, which implies that FixI is a pump of a specific cation involved in symbiotic nitrogen fixation. Since prototrophic growth of fixI mutants appeared to be unimpaired, the predicted FixI cation pump probably has a specifically symbiotic function. We suggest that the four proteins FixG, FixH, FixI, and FixS may participate in a membrane-bound complex coupling the FixI cation pump with a redox process catalyzed by FixG.