Nadia Izadi-Pruneyre

Heme uptake across the outer membrane as revealed by crystal structures of the receptor-hemophore complex.

Gram-negative bacteria use specific heme uptake systems, relying on outer membrane receptors and excreted heme-binding proteins (hemophores) to scavenge and actively transport heme. To unravel the unknown molecular details involved, we present 3 structures of the Serratia marcescens receptor HasR in complex with its hemophore HasA. The transfer of heme over a distance of 9 Å from its high-affinity site in HasA into a site of lower affinity in HasR is coupled with the exergonic complex formation of the 2 proteins. Upon docking to the receptor, 1 of the 2 axial heme coordinations of the hemophore is initially broken, but the position and orientation of the heme is preserved. Subsequently, steric displacement of heme by a receptor residue ruptures the other axial coordination, leading to heme transfer into the receptor.

The heme transfer from the soluble HasA hemophore to its membrane-bound receptor HasR is driven by protein-protein interaction from a high to a lower affinity binding site.

HasA is an extracellular heme binding protein, and HasR is an outer membrane receptor protein from Serratia marcescens. They are the initial partners of a heme internalization system allowing S. marcescens to scavenge heme at very low concentrations due to the very high affinity of HasA for heme (Ka = 5,3 × 1010 m-1). Heme is then transferred to HasR, which has a lower affinity for heme. The mechanism of the heme transfer between HasA and HasR is largely unknown. HasR has been overexpressed and purified in holo and apo forms. It binds one heme molecule with a Ka of 5 × 106 m-1 and shows the characteristic absorbance spectrum of a low spin heme iron. Both holoHasA and apoHasA bind tightly to apoHasR in a 1:1 stoichiometry. In this study we show that heme transfer occurs in vitro in the purified HasA·HasR complex, demonstrating that heme transfer is energy- and TonB complex-independent and driven by a protein-protein interaction. We also show that heme binding to HasR involves two conserved histidine residues.

Deciphering the structural role of histidine 83 for heme binding in hemophore HasA.

Heme carrier HasA has a unique type of histidine/tyrosine heme iron ligation in which the iron ion is in a thermally driven two spin states equilibrium. We recently suggested that the H-bonding between Tyr75 and the invariantly conserved residue His83 modulates the strength of the iron-Tyr75 bond. To unravel the role of His83, we characterize the iron ligation and the electronic properties of both wild type and H83A mutant by a variety of spectroscopic techniques. Although His83 in wild type modulates the strength of the Tyr-iron bond, its removal causes detachment of the tyrosine ligand, thus giving rise to a series of pH-dependent equilibria among species with different axial ligation. The five coordinated species detected at physiological pH may represent a possible intermediate of the heme transfer mechanism to the receptor.

Comparative analysis of structural and dynamic properties of the loaded and unloaded hemophore HasA: functional implications.

A heme-acquisition system present in several Gram-negative bacteria requires the secretion of hemophores. These extracellular carrier proteins capture heme and deliver it to specific outer membrane receptors. The Serratia marcescens HasA hemophore is a monodomain protein that binds heme with a very high affinity. Its alpha/beta structure, as that of its binding pocket, has no common features with other iron- or heme-binding proteins. Heme is held by two loops L1 and L2 and coordinated to iron by an unusual ligand pair, H32/Y75. Two independent regions of the hemophore beta-sheet are involved in HasA-HasR receptor interaction. Here, we report the 3-D NMR structure of apoHasA and the backbone dynamics of both loaded and unloaded hemophore. While the overall structure of HasA is very similar in the apo and holo forms, the hemophore presents a transition from an open to a closed form upon ligand binding, through a large movement, of up to 30 A, of loop L1 bearing H32. Comparison of loaded and unloaded HasA dynamics on different time scales reveals striking flexibility changes in the binding pocket. We propose a mechanism by which these structural and dynamic features provide the dual function of heme binding and release to the HasR receptor.

Functional aspects of the heme bound hemophore HasA by structural analysis of various crystal forms.

The protein HasA from the Gram negative bacteria Serratia marcescens is the first hemophore to be described at the molecular level. It participates to the shuttling of heme from hemoglobin to the outer membrane receptor HasR, which in turn releases it into the bacterium. HasR alone is also able to take up heme from hemoglobin but synergy with HasA increases the efficiency of the system by a factor of about 100. This iron acquisition system allows the bacteria to survive with hemoglobin as the sole iron source. Here we report the structures of a new crystal form of HasA diffracting up to 1.77Å resolution as well as the refined structure of the trigonal crystal form diffracting to 3.2Å resolution. The crystal structure of HasA at high resolution shows two possible orientations of the heme within the heme‐binding pocket, which probably are functionally involved in the heme‐iron acquisition process. The detailed analysis of the three known structures reveals the molecular basis regulating the relative affinity of the heme/hemophore complex. Proteins 2000;41:202–210.

Mapping the Interaction between the Hemophore HasA and Its Outer Membrane Receptor HasR Using CRINEPT−TROSY NMR Spectroscopy

The first step of heme acquisition by Gram-negative pathogenic bacteria through the so-called heme acquisition system, Has, requires delivery of the heme from the extracellular hemophore protein HasA to a specific outer membrane receptor, HasR. CRINEPT-TROSY NMR experiments in DPC micelles were here used to obtain information on the intermediate HasA-HasR complex in solution. A stable protein-protein adduct is detected both in the presence and in the absence of heme. Structural information on the complexed form of HasA is obtained from chemical shift mapping and statistical analysis of the spectral fingerprint of the protein NMR spectra obtained under different conditions. This approach shows the following: (i) only three different conformations are possible for HasA in solution: one for the isolated apoprotein, one for the isolated holoprotein, and one for the complexed protein, that is independent of the presence of the heme; (ii) the structure of the hemophore in the complex resembles the open conformation of the apoprotein; (iii) the surface contact area between HasA and HasR is independent of the presence of the heme, involving loop L1, loop L2, and the beta2-beta6 strands; (iv) upon complex formation the heme group is transferred from holoHasA to HasR.

Novel Heme Ligand Displacement by CO in the Soluble Hemophore HasA and Its Proximal Ligand Mutants : Implications for Heme Uptake and Release

HasASM, a hemophore secreted by the Gram-negative bacteria Serratia marcescens, extracts heme from host hemoproteins and shuttles it to HasRSM, a specific hemophore outer membrane receptor. Heme iron in HasASM is in a six-coordinate ferric state. It is linked to the protein by the heretofore uncommon axial ligand set, His32 and Tyr75. A third residue of the heme pocket, His83, plays a crucial role in heme ligation through hydrogen bonding to Tyr75. The vibrational frequencies of coordinated carbon monoxide constitute a sensitive probe of trans ligand field, FeCO structure, and electrostatic landscape of the distal heme pockets of heme proteins. In this study, carbonyl complexes of wild-type (WT) HasASM and its heme pocket mutants His32Ala, Tyr75Ala, and His83Ala were characterized by resonance Raman spectroscopy. The CO complexes of WT HasASM, HasASM(His32Ala), and HasASM(His83Ala) exhibit similar spectral features and fall above the line that correlates nuFe-CO and nuC-O for proteins having a proximal imidazole ligand. This suggests that the proximal ligand field in these CO adducts is weaker than that for heme-CO proteins bearing a histidine axial ligand. In contrast, the CO complex of HasASM(Tyr75Ala) has resonance Raman signatures consistent with ImH-Fe-CO ligation. These results reveal that in WT HasASM, the axial ImH side chain of His32 is displaced by CO. This is in contrast to other heme proteins known to have the His/Tyr axial ligand set, wherein the phenolic side chain of the Tyr ligand dissociates upon CO addition. The displacement of His32 and its stabilization in an unbound state is postulated to be relevant to heme uptake and/or release.

Role of the Iron Axial Ligands of Heme Carrier HasA in Heme Uptake and Release

Background: In the bacterial heme carrier HasA, an open to closed transition occurs with heme binding. Results: Axial heme ligand mutants H32A and Y75A are both in a closed conformation. Conclusion: Simultaneous binding of both axial heme ligands is not required for the closure of loop L1 in HasA. Significance: The H32A mutant of HasA mimics a proposed structure involved in heme transfer to its partner HasR. The hemophore protein HasA from Serratia marcescens cycles between two states as follows: the heme-bound holoprotein, which functions as a carrier of the metal cofactor toward the membrane receptor HasR, and the heme-free apoprotein fishing for new porphyrin to be taken up after the heme has been delivered to HasR. Holo- and apo-forms differ for the conformation of the two loops L1 and L2, which provide the axial ligands of the iron through His32 and Tyr75, respectively. In the apo-form, loop L1 protrudes toward the solvent far away from loop L2; in the holoprotein, closing of the loops on the heme occurs upon establishment of the two axial coordination bonds. We have established that the two variants obtained via single point mutations of either axial ligand (namely H32A and Y75A) are both in the closed conformation. The presence of the heme and one out of two axial ligands is sufficient to establish a link between L1 and L2, thanks to the presence of coordinating solvent molecules. The latter are stabilized in the iron coordination environment by H-bond interactions with surrounding protein residues. The presence of such a water molecule in both variants is revealed here through a set of different spectroscopic techniques. Previous studies had shown that heme release and uptake processes occur via intermediate states characterized by a Tyr75-iron-bound form with open conformation of loop L1. Here, we demonstrate that these states do not naturally occur in the free protein but can only be driven by the interaction with the partner proteins.

Modulation by Substrates of the Interaction between the HasR Outer Membrane Receptor and Its Specific TonB-like Protein, HasB

TonB is a cytoplasmic membrane protein required for active transport of various essential substrates such as heme and iron siderophores through the outer membrane receptors of Gram-negative bacteria. This protein spans the periplasm, contacts outer membrane transporters by its C-terminal domain, and transduces energy from the protonmotive force to the transporters. The TonB box, a relatively conserved sequence localized on the periplasmic side of the transporters, has been shown to directly contact TonB. While Serratia marcescens TonB functions with various transporters, HasB, a TonB-like protein, is dedicated to the HasR transporter. HasR acquires heme either freely or via an extracellular heme carrier, the hemophore HasA, that binds to HasR and delivers heme to the transporter. Here, we study the interaction of HasR with a HasB C-terminal domain and compare it with that obtained with a TonB C-terminal fragment. Analysis of the thermodynamic parameters reveals that the interaction mode of HasR with HasB differs from that with TonB, the difference explaining the functional specificity of HasB for HasR. We also demonstrate that the presence of the substrate on the extracellular face of the transporter modifies, via enthalpy-entropy compensation, the interaction with HasB on the periplasmic face. The transmitted signal depends on the nature of the substrate. While the presence of heme on the transporter modifies only slightly the nature of interactions involved between HasR and HasB, hemophore binding on the transporter dramatically changes the interactions and seems to locally stabilize some structural motifs. In both cases, the HasR TonB box is the target for those modifications.

The Structure of HasB Reveals a New Class of TonB Protein Fold

TonB is a key protein in active transport of essential nutrients like vitamin B12 and metal sources through the outer membrane transporters of Gram-negative bacteria. This inner membrane protein spans the periplasm, contacts the outer membrane receptor by its periplasmic domain and transduces energy from the cytoplasmic membrane pmf to the receptor allowing nutrient internalization. Whereas generally a single TonB protein allows the acquisition of several nutrients through their cognate receptor, in some species one particular TonB is dedicated to a specific system. Despite a considerable amount of data available, the molecular mechanism of TonB-dependent active transport is still poorly understood. In this work, we present a structural study of a TonB-like protein, HasB dedicated to the HasR receptor. HasR acquires heme either free or via an extracellular heme transporter, the hemophore HasA. Heme is used as an iron source by bacteria. We have solved the structure of the HasB periplasmic domain of Serratia marcescens and describe its interaction with a critical region of HasR. Some important differences are observed between HasB and TonB structures. The HasB fold reveals a new structural class of TonB-like proteins. Furthermore, we have identified the structural features that explain the functional specificity of HasB. These results give a new insight into the molecular mechanism of nutrient active transport through the bacterial outer membrane and present the first detailed structural study of a specific TonB-like protein and its interaction with the receptor.