Transmembrane Signaling in Chimeras of the Escherichia coli Aspartate and Serine Chemotaxis Receptors and Bacterial Class III Adenylyl Cyclases

The Escherichia coli chemoreceptors for serine (Tsr) and aspartate (Tar) and several bacterial class III adenylyl cyclases (ACs) share a common molecular architecture; that is, a membrane anchor that is linked via a cytoplasmic HAMP domain to a C-terminal signal output unit. Functionality of both proteins requires homodimerization. The chemotaxis receptors are well characterized, whereas the typical hexahelical membrane anchor (6TM) of class III ACs, suggested to operate as a channel or transporter, has no known function beyond a membrane anchor. We joined the intramolecular networks of Tsr or Tar and two bacterial ACs, Rv3645 from Mycobacterium tuberculosis and CyaG from Arthrospira platensis, across their signal transmission sites, connecting the chemotaxis receptors via different HAMP domains to the catalytic AC domains. AC activity in the chimeras was inhibited by micromolar concentrations of l-serine or l-aspartate in vitro and in vivo. Single point mutations known to abolish ligand binding in Tar (R69E or T154I) or Tsr (R69E or T156K) abrogated AC regulation. Co-expression of mutant pairs, which functionally complement each other, restored regulation in vitro and in vivo. Taken together, these studies demonstrate chemotaxis receptor-mediated regulation of chimeric bacterial ACs and connect chemical sensing and AC regulation.     

HAMP domain-mediated signal transduction probed with a mycobacterial adenylyl cyclase as a reporter

HAMP domains, ～55 amino acid motifs first identified in histidine kinases, adenylyl cyclases, methyl-accepting chemotaxis proteins, and phosphatases, operate as signal mediators in two-component signal transduction proteins. A bioinformatics study identified a coevolving signal-accepting network of 10 amino acids in membrane-delimited HAMP proteins. To probe the functionality of this network we used a HAMP containing mycobacterial adenylyl cyclase, Rv3645, as a reporter enzyme in which the membrane anchor was substituted by the Escherichia coli chemotaxis receptor for serine (Tsr receptor) and the HAMP domain alternately with that from the protein Af1503 of the archaeon Archaeoglobus fulgidus or the Tsr receptor. In a construct with the Tsr-HAMP, cyclase activity was inhibited by serine, whereas in a construct with the HAMP domain from A. fulgidus, enzyme activity was not responsive to serine. Amino acids of the signal-accepting network were mutually swapped between both HAMP domains, and serine signaling was examined. The data biochemically tentatively established the functionality of the signal-accepting network. Based on a two-state gearbox model of rotation in HAMP domain-mediated signal propagation, we characterized the interaction between permanent and transient core residues in a coiled coil HAMP structure. The data are compatible with HAMP rotation in signal propagation but do not exclude alternative models for HAMP signaling. Finally, we present data indicating that the connector, which links the α-helices of HAMP domains, plays an important structural role in HAMP function.     

Expression of the halobacterial transducer protein HtrII from Natronomonas pharaonis in Escherichia coli

Archaeal phototaxis is mediated by sensory rhodopsins which form complexes with their cognate transducers. Whereas the receptors sensory rhodopsin I and sensory rhodopsin II (SRII) have been expressed in Escherichia coli (E. coli) only shortened fragments of HtrII from Natronomonas pharaonis (NpHtrII) are available. Here we describe the heterologous expression of full length NpHtrII which was achieved in yields of up to 0.9 mg per litre cell culture. Gel filtration analysis reveals the tendency of the transducer to form dimers and higher-order oligomers which was also observed when complexed to NpSRII. A circular dichroism (CD) spectrum of NpHtrII is comparable to those obtained for the E. coli chemoreceptors indicating a similar folding with predominantly alpha-helical structure. NpHtrII dissociates from the NpSRII/HtrII complex with an apparent K(D) of about 0.6 microM. Photocycle kinetics of the complex is comparable to that obtained for NpSRII in complex with a truncated transducer with slight differences in the M-decay. The data indicate that the heterologously expressed NpHtrII adopt a native like structure, providing the means for elucidating transmembrane signal transduction and activation of microbial signalling cascades.     

Mutations in the HFE, TFR2, and SLC40A1 genes in patients with hemochromatosis

Hereditary hemochromatosis causes iron overload and is associated with a variety of genetic and phenotypic conditions. Early diagnosis is important so that effective treatment can be administered and the risk of tissue damage avoided. Most patients are homozygous for the c.845G>A (p.C282Y) mutation in the HFE gene; however, rare forms of genetic iron overload must be diagnosed using a specific genetic analysis. We studied the genotype of 5 patients who had hyperferritinemia and an iron overload phenotype, but not classic mutations in the HFE gene. Two patients were undergoing phlebotomy and had no iron overload, 1 with metabolic syndrome and no phlebotomy had mild iron overload, and 2 patients had severe iron overload despite phlebotomy. The patients' first-degree relatives also underwent the analysis. We found 5 not previously published mutations: c.-408_-406delCAA in HFE, c.1118G>A (p.G373D), c.1473G>A (p.E491E) and c.2085G>C (p.S695S) in TFR2; and c.-428_-427GG>TT in SLC40A1. Moreover, we found 3 previously published mutations: c.221C>T (p.R71X) in HFE; c.1127C>A (p.A376D) in TFR2; and c.539T>C (p.I180T) in SLC40A1. Four patients were double heterozygous or compound heterozygous for the mutations mentioned above, and the patient with metabolic syndrome was heterozygous for a mutation in the TFR2 gene. Our findings show that hereditary hemochromatosis is clinically and genetically heterogeneous and that acquired factors may modify or determine the phenotype.     

Physiological sites of deamidation and methyl esterification in sensory transducers of Halobacterium salinarum

In Halobacterium salinarum, up to 18 sensory transducers (Htrs) relay environmental stimuli to an intracellular signaling system to induce tactic responses. As known from the extensively studied enterobacterial system, sensory adaptation to persisting stimulus intensities involves reversible methylation of certain transducer glutamate residues, some of which originate from glutamine residues by deamidation. This study analyzes the in vivo deamidation and methylation of membrane-bound Htrs under physiological conditions. Electrospray ionization tandem mass spectrometry of chromatographically separated proteolytic peptides identified 19 methylation sites in 10 of the 12 predicted membrane-spanning Htrs. Matrix-assisted laser desorption/ionization mass spectrometry additionally detected three sites in two soluble Htrs. Sensory transducers contain a cytoplasmic coiled-coil region, composed of hydrophobic heptads, seven-residue repeats in which the first and the fourth residues are mostly hydrophobic. All identified Htr methylations occurred at glutamate residues at the second and/or third position of such heptads. In addition to singly methylated pairs of glutamate and/or glutamine residues, we identified singly methylated aspartate-glutamate and alanine-glutamate pairs and doubly methylated glutamate pairs. The largest methylatable regions detected in Htrs comprise six heptads along the coiled coil. One methylated glutamate residue was detected outside of such a region, in the signaling region of Htr14. Our analysis produced evidence supporting the predicted methyltransferase and methylesterase activities of halobacterial CheR and CheB, respectively. It furthermore demonstrated that CheB is required for Htr deamidations, at least at a specific glutamine-glutamate pair in Htr2 and a specific aspartate-glutamine pair in Htr4. Compared to previously reported methods, the described approach significantly facilitates the identification of physiological transducer modification sites.     

Small-angle X-ray scattering reveals the solution structure of a bacteriophytochrome in the catalytically active Pr state

Phytochromes are light-sensing macromolecules that are part of a two component phosphorelay system controlling gene expression. Photoconversion between the Pr and Pfr forms facilitates autophosphorylation of a histidine in the dimerization domain (DHp). We report the low-resolution structure of a bacteriophytochrome (Bph) in the catalytic (CA) Pr form in solution determined by small-angle X-ray scattering (SAXS). Ab initio modeling reveals, for the first time, the domain organization in a typical bacteriophytochrome, comprising an chromophore binding and phytochrome (PHY) N terminal domain followed by a C terminal histidine kinase domain. Homologous high-resolution structures of the light-sensing chromophore binding domain (CBD) and the cytoplasmic part of a histidine kinase sensor allows us to model 75% of the structure with the remainder comprising the phytochrome domain which has no 3D representative in the structural database. The SAXS data reveal a dimeric Y shaped macromolecule and the relative positions of the chromophores (biliverdin), autophosphorylating histidine residues and the ATP molecules in the kinase domain. SAXS data were collected from a sample in the autophosphorylating Pr form and reveal alternate conformational states for the kinase domain that can be modeled in an open (no-catalytic) and closed (catalytic) state. This model suggests how light-induced signal transduction can stimulate autophosphorylation followed by phosphotransfer to a response regulator (RR) in the two-component system.     

The S-helix determines the signal in a Tsr receptor/adenylyl cyclase reporter

A signaling or S-helix has been identified as a conserved, up to 50-residue-long segment in diverse sensory proteins. It is present in all major bacterial lineages and in euryarchea and eukaryotes. A bioinformatic analysis shows that it connects upstream receiver and downstream output domains, e.g. in histidine kinases and bacterial adenylyl cyclases. The S-helix is modeled as a two-helical parallel coiled coil. It is predicted to prevent constitutive activation of the downstream signaling domains in the absence of ligand-binding. We identified an S-helix of about 25 residues in the adenylyl cyclase CyaG from Arthrospira maxima. Deletion of the 25 residue segment connecting the HAMP and catalytic domains in a chimera with the Escherichia coli Tsr receptor changed the response to serine from inhibition to stimulation. Further examination showed that a deletion of one to three heptads plus a presumed stutter, i.e. 1, 2, or 3 × 7 + 4 amino acids, is required and sufficient for signal reversion. It was not necessary that the deletions be continuous, as removal of separated heptads and presumed stutters also resulted in signal reversion. Furthermore, insertion of the above segments between the HAMP and cyclase catalytic domains similarly resulted in signal reversion. This indicates that the S-helix is an independent, segmented module capable to reverse the receptor signal. Because the S-helix is present in all kingdoms of life, e.g. in human retinal guanylyl cyclase, our findings may be significant for many sensory systems.     

Signal transmission through the HtrII transducer alters the interaction of two alpha-helices in the HAMP domain

A conformational change of the transducer HtrII upon photoexcitation of the associated photoreceptor sensory rhodopsin II (SRII) was investigated by monitoring the kinetics of volume changes and the diffusion coefficient (D) of the complex during the photochemical reaction cycle. To localize the region of the transducer responsible, we truncated it at various positions in the cytoplasmic HAMP (histidine kinases, adenylyl cyclases, methyl-accepting chemotaxis proteins, and phosphatases) domain. The truncations do not alter receptor binding, which is dependent primarily on membrane-embedded domain interactions. We found that the light-induced reduction in D occurs in transducers of lengths 120 and 157 residues (Tr120 and Tr157), which are both predicted to contain a HAMP domain consisting of two amphipathic α-helices (AS-1 and AS-2). In contrast, the change in D was abolished in a transducer of 114 amino acid residues (Tr114), which lacks a distal portion of the second α-helix AS-2. The volume changes in SRII-Tr114 are comparable in amplitude and kinetics with those in SRII-Tr120 and SRII-Tr157, confirming the integrity of the complex, which was previously concluded from the similar SRII binding affinity and similar blocking of SRII proton transport by full-length HtrII and Tr114. Our results indicate that a substantial conformational change occurs in the HAMP domain during SRII-HtrII signaling. The data presented here are the first demonstration of stimulus-induced conformational changes of a HAMP domain and provide evidence that the presence of AS-2 is crucial for the conformational alterations. The reduction in diffusion coefficient is likely to due to structural changes in the AS-1 and AS-2 helices such that hydrogen bonding with the surrounding water molecules is increased, thereby increasing friction with the solvent. Similar structural changes may be a general feature in HAMP domain switching, which occurs in diverse signaling proteins, including sensor kinases, taxis receptors/transducers, adenylyl cyclases, and phosphatases.