Dirk W. Heinz

Structure of Internalin, a Major Invasion Protein of Listeria monocytogenes, in Complex with Its Human Receptor E-Cadherin

Listeria monocytogenes, a food-borne bacterial pathogen, enters mammalian cells by inducing its own phagocytosis. The listerial protein internalin (InlA) mediates bacterial adhesion and invasion of epithelial cells in the human intestine through specific interaction with its host cell receptor E-cadherin. We present the crystal structures of the functional domain of InlA alone and in a complex with the extracellular, N-terminal domain of human E-cadherin (hEC1). The leucine rich repeat (LRR) domain of InlA surrounds and specifically recognizes hEC1. Individual interactions were probed by mutagenesis and analytical ultracentrifugation. These include Pro16 of hEC1, a major determinant for human susceptibility to L. monocytogenes infection that is essential for intermolecular recognition. Our studies reveal the structural basis for host tro-pism of this bacterium and the molecular deception L. monocytogenes employs to exploit the E-cadherin system.

Crystal structure of coproporphyrinogen III oxidase reveals cofactor geometry of Radical SAM enzymes.

‘Radical SAM’ enzymes generate catalytic radicals by combining a 4Fe–4S cluster and S‐adenosylmethionine (SAM) in close proximity. We present the first crystal structure of a Radical SAM enzyme, that of HemN, the Escherichia coli oxygen‐independent coproporphyrinogen III oxidase, at 2.07 Å resolution. HemN catalyzes the essential conversion of coproporphyrinogen III to protoporphyrinogen IX during heme biosynthesis. HemN binds a 4Fe–4S cluster through three cysteine residues conserved in all Radical SAM enzymes. A juxtaposed SAM coordinates the fourth Fe ion through its amide nitrogen and carboxylate oxygen. The SAM sulfonium sulfur is near both the Fe (3.5 Å) and a neighboring sulfur of the cluster (3.6 Å), allowing single electron transfer from the 4Fe–4S cluster to the SAM sulfonium. SAM is cleaved yielding a highly oxidizing 5′‐deoxyadenosyl radical. HemN, strikingly, binds a second SAM immediately adjacent to the first. It may thus successively catalyze two propionate decarboxylations. The structure of HemN reveals the cofactor geometry required for Radical SAM catalysis and sets the stage for the development of inhibitors with antibacterial function due to the uniquely bacterial occurrence of the enzyme.

Extending the Host Range of Listeria monocytogenes by Rational Protein Design

In causing disease, pathogens outmaneuver host defenses through a dedicated arsenal of virulence determinants that specifically bind or modify individual host molecules. This dedication limits the intruder to a defined range of hosts. Newly emerging diseases mostly involve existing pathogens whose arsenal has been altered to allow them to infect previously inaccessible hosts. We have emulated this chance occurrence by extending the host range accessible to the human pathogen Listeria monocytogenes by the intestinal route to include the mouse. Analyzing the recognition complex of the listerial invasion protein InlA and its human receptor E-cadherin, we postulated and verified amino acid substitutions in InlA to increase its affinity for E-cadherin. Two single substitutions increase binding affinity by four orders of magnitude and extend binding specificity to include formerly incompatible murine E-cadherin. By rationally adapting a single protein, we thus create a versatile murine model of human listeriosis.

Crystal structure of 5‐aminolevulinate synthase, the first enzyme of heme biosynthesis, and its link to XLSA in humans

5‐Aminolevulinate synthase (ALAS) is the first and rate‐limiting enzyme of heme biosynthesis in humans, animals, other non‐plant eukaryotes, and α‐proteobacteria. It catalyzes the synthesis of 5‐aminolevulinic acid, the first common precursor of all tetrapyrroles, from glycine and succinyl‐coenzyme A (sCoA) in a pyridoxal 5′‐phosphate (PLP)‐dependent manner. X‐linked sideroblastic anemias (XLSAs), a group of severe disorders in humans characterized by inadequate formation of heme in erythroblast mitochondria, are caused by mutations in the gene for erythroid eALAS, one of two human genes for ALAS. We present the first crystal structure of homodimeric ALAS from Rhodobacter capsulatus (ALASRc) binding its cofactor PLP. We, furthermore, present structures of ALASRc in complex with the substrates glycine or sCoA. The sequence identity of ALAS from R. capsulatus and human eALAS is 49%. XLSA‐causing mutations may thus be mapped, revealing the molecular basis of XLSA in humans. Mutations are found to obstruct substrate binding, disrupt the dimer interface, or hamper the correct folding. The structure of ALAS completes the structural analysis of enzymes in heme biosynthesis.

Structure and function of enzymes in heme biosynthesis.

Tetrapyrroles like hemes, chlorophylls, and cobalamin are complex macrocycles which play essential roles in almost all living organisms. Heme serves as prosthetic group of many proteins involved in fundamental biological processes like respiration, photosynthesis, and the metabolism and transport of oxygen. Further, enzymes such as catalases, peroxidases, or cytochromes P450 rely on heme as essential cofactors. Heme is synthesized in most organisms via a highly conserved biosynthetic route. In humans, defects in heme biosynthesis lead to severe metabolic disorders called porphyrias. The elucidation of the 3D structures for all heme biosynthetic enzymes over the last decade provided new insights into their function and elucidated the structural basis of many known diseases. In terms of structure and function several rather unique proteins were revealed such as the V‐shaped glutamyl‐tRNA reductase, the dipyrromethane cofactor containing porphobilinogen deaminase, or the “Radical SAM enzyme” coproporphyrinogen III dehydrogenase. This review summarizes the current understanding of the structure–function relationship for all heme biosynthetic enzymes and their potential interactions in the cell.

Structure of the Human Receptor Tyrosine Kinase Met in Complex with the Listeria Invasion Protein InlB

The tyrosine kinase Met, the product of the c-met proto-oncogene and the receptor for hepatocyte growth factor/scatter factor (HGF/SF), mediates signals critical for cell survival and migration. The human pathogen Listeria monocytogenes exploits Met signaling for invasion of host cells via its surface protein InlB. We present the crystal structure of the complex between a large fragment of the human Met ectodomain and the Met-binding domain of InlB. The concave face of the InlB leucine-rich repeat region interacts tightly with the first immunoglobulin-like domain of the Met stalk, a domain which does not bind HGF/SF. A second contact between InlB and the Met Sema domain locks the otherwise flexible receptor in a rigid, signaling competent conformation. Full Met activation requires the additional C-terminal domains of InlB which induce heparin-mediated receptor clustering and potent signaling. Thus, although it elicits a similar cellular response, InlB is not a structural mimic of HGF/SF.

Targeting DnaN for tuberculosis therapy using novel griselimycins

New for old—TB drug development Tuberculosis (TB) is a global health threat for which there is only lengthy drug treatment. Patients need to consume multiple tablets over several months and frequently fail to complete their treatment. Consequently, drug-resistant strains of the pathogen have emerged, which add to the threat. Kling et al. revisited a natural product called griselimycin, extracted from the same organism that produced the prototype anti-TB drug, streptomycin. Unmodified griselimycin has poor pharmacological properties. However, one synthetic derivative had improved oral uptake and penetrated cells of the immune system that harbor the TB mycobacterium. In combination with other drugs, the griselimycin derivative showed high potency in mice with TB. Science, this issue p. 1106 A griselimycin-derived drug that blocks the DNA polymerase sliding clamp is a potent anti-tuberculosis lead. The discovery of Streptomyces-produced streptomycin founded the age of tuberculosis therapy. Despite the subsequent development of a curative regimen for this disease, tuberculosis remains a worldwide problem, and the emergence of multidrug-resistant Mycobacterium tuberculosis has prioritized the need for new drugs. Here we show that new optimized derivatives from Streptomyces-derived griselimycin are highly active against M. tuberculosis, both in vitro and in vivo, by inhibiting the DNA polymerase sliding clamp DnaN. We discovered that resistance to griselimycins, occurring at very low frequency, is associated with amplification of a chromosomal segment containing dnaN, as well as the ori site. Our results demonstrate that griselimycins have high translational potential for tuberculosis treatment, validate DnaN as an antimicrobial target, and capture the process of antibiotic pressure-induced gene amplification.

V-Shaped Structure of Glutamyl-tRNA Reductase, the First Enzyme of tRNA-Dependent Tetrapyrrole Biosynthesis.

Processes vital to life such as respiration and photosynthesis critically depend on the availability of tetrapyrroles including hemes and chlorophylls. tRNA‐dependent catalysis generally is associated with protein biosynthesis. An exception is the reduction of glutamyl‐tRNA to glutamate‐1‐semialdehyde by the enzyme glutamyl‐tRNA reductase. This reaction is the indispensable initiating step of tetrapyrrole biosynthesis in plants and most prokaryotes. The crystal structure of glutamyl‐tRNA reductase from the archaeon Methanopyrus kandleri in complex with the substrate‐like inhibitor glutamycin at 1.9 Å resolution reveals an extended yet planar V‐shaped dimer. The well defined interactions of the inhibitor with the active site support a thioester‐mediated reduction process. Modeling the glutamyl‐tRNA onto each monomer reveals an extensive protein–tRNA interface. We furthermore propose a model whereby the large void of glutamyl‐tRNA reductase is occupied by glutamate‐1‐semialdehyde‐1,2‐mutase, the subsequent enzyme of this pathway, allowing for the efficient synthesis of 5‐aminolevulinic acid, the common precursor of all tetrapyrroles.

The crystal structure of SdsA1, an alkylsulfatase from Pseudomonas aeruginosa, defines a third class of sulfatases

Pseudomonas aeruginosa is both a ubiquitous environmental bacterium and an opportunistic human pathogen. A remarkable metabolic versatility allows it to occupy a multitude of ecological niches, including wastewater treatment plants and such hostile environments as the human respiratory tract. P. aeruginosa is able to degrade and metabolize biocidic SDS, the detergent of most commercial personal hygiene products. We identify SdsA1 of P. aeruginosa as a secreted SDS hydrolase that allows the bacterium to use primary sulfates such as SDS as a sole carbon or sulfur source. Homologues of SdsA1 are found in many pathogenic and some nonpathogenic bacteria. The crystal structure of SdsA1 reveals three distinct domains. The N-terminal catalytic domain with a binuclear Zn2+ cluster is a distinct member of the metallo-β-lactamase fold family, the central dimerization domain ensures resistance to high concentrations of SDS, whereas the C-terminal domain provides a hydrophobic groove, presumably to recruit long aliphatic substrates. Crystal structures of apo-SdsA1 and complexes with substrate analog and products indicate an enzymatic mechanism involving a water molecule indirectly activated by the Zn2+ cluster. The enzyme SdsA1 thus represents a previously undescribed class of sulfatases that allows P. aeruginosa to survive and thrive under otherwise bacteriocidal conditions.

In situ structural analysis of the Yersinia enterocolitica injectisome

Injectisomes are multi-protein transmembrane machines allowing pathogenic bacteria to inject effector proteins into eukaryotic host cells, a process called type III secretion. Here we present the first three-dimensional structure of Yersinia enterocolitica and Shigella flexneri injectisomes in situ and the first structural analysis of the Yersinia injectisome. Unexpectedly, basal bodies of injectisomes inside the bacterial cells showed length variations of 20%. The in situ structures of the Y. enterocolitica and S. flexneri injectisomes had similar dimensions and were significantly longer than the isolated structures of related injectisomes. The crystal structure of the inner membrane injectisome component YscD appeared elongated compared to a homologous protein, and molecular dynamics simulations documented its elongation elasticity. The ring-shaped secretin YscC at the outer membrane was stretched by 30–40% in situ, compared to its isolated liposome-embedded conformation. We suggest that elasticity is critical for some two-membrane spanning protein complexes to cope with variations in the intermembrane distance. DOI: http://dx.doi.org/10.7554/eLife.00792.001