Michael Kokkinidis

Structure of the ColE1 rop protein at 1.7 A resolution

Structural details of the Rop protein from plasmid ColE1 are presented, with a description of the X-ray crystal structure determination and refinement at a nominal resolution of 1.7 A. The 63 amino acid protein is a dimer. Each monomer consists almost entirely of two alpha helices, the whole molecule forming a highly regular four-alpha-helix bundle. This may be approximated by a four-stranded rope with a radius of 7.0 A, a left-handed helical twist and a pitch of 172.5 A. The packing constraints for this novel type of coiled-coil structure are given. The protein acts in the control of plasmid replication via regulation of an RNA-RNA interaction in a manner not yet understood in atomic detail.

Conserved features of type III secretion

Type III secretion systems (TTSSs) are essential mediators of the interaction of many Gram‐negative bacteria with human, animal or plant hosts. Extensive sequence and functional similarities exist between components of TTSS from bacteria as diverse as animal and plant pathogens. Recent crystal structure determinations of TTSS proteins reveal extensive structural homologies and novel structural motifs and provide a basis on which protein interaction networks start to be drawn within the TTSSs, that are consistent with and help rationalize genetic and biochemical data. Such studies, along with electron microscopy, also established common architectural design and function among the TTSSs of plant and mammalian pathogens, as well as between the TTSS injectisome and the flagellum. Recent comparative genomic analysis, bioinformatic genome mining and genome‐wide functional screening have revealed an unsuspected number of newly discovered effectors, especially in plant pathogens and uncovered a wider distribution of TTSS in pathogenic, symbiotic and commensal bacteria. Functional proteomics and analysis further reveals common themes in TTSS effector functions across phylogenetic host and pathogen boundaries. Based on advances in TTSS biology, new diagnostics, crop protection and drug development applications, as well as new cell biology research tools are beginning to emerge.

Controlling the enzymatic activity of a restriction enzyme by light

For many applications it would be desirable to be able to control the activity of proteins by using an external signal. In the present study, we have explored the possibility of modulating the activity of a restriction enzyme with light. By cross-linking two suitably located cysteine residues with a bifunctional azobenzene derivative, which can adopt a cis- or trans-configuration when illuminated by UV or blue light, respectively, enzymatic activity can be controlled in a reversible manner. To determine which residues when cross-linked show the largest “photoswitch effect,” i.e., difference in activity when illuminated with UV vs. blue light, > 30 variants of a single-chain version of the restriction endonuclease PvuII were produced, modified with azobenzene, and tested for DNA cleavage activity. In general, introducing single cross-links in the enzyme leads to only small effects, whereas with multiple cross-links and additional mutations larger effects are observed. Some of the modified variants, which carry the cross-links close to the catalytic center, can be modulated in their DNA cleavage activity by a factor of up to 16 by illumination with UV (azobenzene in cis) and blue light (azobenzene in trans), respectively. The change in activity is achieved in seconds, is fully reversible, and, in the case analyzed, is due to a change in Vmax rather than Km.

Playing the Harp : Evolution of Our Understanding of hrp/hrc Genes

With the advent of recombinant DNA techniques, the field of molecular plant pathology witnessed dramatic shifts in the 1970s and 1980s. The new and conventional methodologies of bacterial molecular genetics put bacteria center stage. The discovery in the mid-1980s of the hrp/hrc gene cluster and the subsequent demonstration that it encodes a type III secretion system (T3SS) common to Gram negative bacterial phytopathogens, animal pathogens, and plant symbionts was a landmark in molecular plant pathology. Today, T3SS has earned a central role in our understanding of many fundamental aspects of bacterium-plant interactions and has contributed the important concept of interkingdom transfer of effector proteins determining race-cultivar specificity in plant-bacterium pathosystems. Recent developments in genomics, proteomics, and structural biology enable detailed and comprehensive insights into the functional architecture, evolutionary origin, and distribution of T3SS among bacterial pathogens and support current research efforts to discover novel antivirulence drugs.

Structure of HrcQB-C, a conserved component of the bacterial type III secretion systems

Type III secretion systems enable plant and animal bacterial pathogens to deliver virulence proteins into the cytosol of eukaryotic host cells, causing a broad spectrum of diseases including bacteremia, septicemia, typhoid fever, and bubonic plague in mammals, and localized lesions, systemic wilting, and blights in plants. In addition, type III secretion systems are also required for biogenesis of the bacterial flagellum. The HrcQB protein, a component of the secretion apparatus of Pseudomonas syringae with homologues in all type III systems, has a variable N-terminal and a conserved C-terminal domain (HrcQB-C). Here, we report the crystal structure of HrcQB-C and show that this domain retains the ability of the full-length protein to interact with other type III components. A 3D analysis of sequence conservation patterns reveals two clusters of residues potentially involved in protein–protein interactions. Based on the analogies between HrcQB and its flagellum homologues, we propose that HrcQB-C participates in the formation of a C-ring-like assembly.

Protein flexibility and enzymatic catalysis.

The dynamic nature of protein structures has been recognized, established, and accepted as an intrinsic fundamental property with major consequences to their function. Nowadays, proteins are considered as networks of continuous motions, which reflect local flexibility and a propensity for global structural plasticity. Protein-protein and protein-small ligand interactions, signal transduction and assembly of macromolecular machines, allosteric regulation and thermal enzymatic adaptation are processes which require structural flexibility. In general, enzymes represent an attractive class among proteins in the study of protein flexibility and they can be used as model systems for understanding the implications of protein fluctuations to biological function. Flexibility of the active site is considered as a requirement for reduction of free energy barrier and acceleration of the enzymatic reaction while there is growing evidence which concerns the connection between flexibility and substrate turnover rate. Moreover, the role of conformational flexibility has been well established in connection with the accessibility of the active site, the binding of substrates and ligands, and release of products, stabilization and trapping of intermediates, orientation of the substrate into the binding cleft, adjustment of the reaction environment, etc.

Protein plasticity to the extreme: changing the topology of a 4-α-helical bundle with a single amino acid substitution

BACKGROUND Conventional wisdom has it that two proteins sharing 98.4% sequence identity have nearly identical three-dimensional structures. Here we provide a counter-example to this statement by showing that a single amino acid substitution can change the topology of a homodimeric 4-alpha-helical bundle protein. RESULTS We have determined the high-resolution crystal structure of a 4-alpha-helical protein with a single alanine to proline mutation in the turn region, and show that this single amino acid substitution leads to a complete reorganisation of the whole molecule. The protein is converted from the canonical left-handed all-antiparallel form, to a right-handed mixed parallel and antiparallel bundle, which to the best of our knowledge and belief represents a novel topological motif for this class of proteins. CONCLUSIONS The results suggest a possible new mechanism for the creation and evolution of topological motifs, show the importance of loop regions in determining the allowable folding pathways, and illustrate the malleability of protein structures.

Characterization of a Photosystem II core and its three-dimensional crystals.

A photosystem II core from spinach containing the chlorophyll-binding proteins 47 kDa, 43 kDa, the reaction center proteins D1, D2 and cytochromeb559 and three low molecular weight polypeptides (MW < 10 kDa) was isolated, its three-dimensional crystals were prepared, and both core and crystals were studied by spectroscopic techniques and electron microscopy. The absorption spectra of the crystallized form of the core indicate a specific orientation of the various pigments within the crystal.

In silico analysis reveals multiple putative type VI secretion systems and effector proteins in Pseudomonas syringae pathovars

Type VI secretion systems (T6SS) of Gram-negative bacteria form injectisomes that have the potential to translocate effector proteins into eukaryotic host cells. In silico analysis of the genomes in six Pseudomonas syringae pathovars revealed that P. syringae pv. tomato DC3000, pv. tabaci ATCC 11528, pv. tomato T1 and pv. oryzae 1-6 each carry two putative T6SS gene clusters (HSI-I and HSI-II; HSI: Hcp secretion island), whereas pv. phaseolicola 1448A and pv. syringae B728 each carry one. The pv. tomato DC3000 HSI-I and pv. tomato T1 HSI-II possess a highly similar organization and nucleotide sequence, whereas the pv. tomato DC3000, pv. oryzae 1-6 and pv. tabaci 11528 HSI-II are more divergent. Putative effector orthologues vary in number among the strains examined. The Clp-ATPases and IcmF orthologues form distinct phylogenetic groups: the proteins from pv. tomato DC3000, pv. tomato T1, pv. oryzae and pv. tabaci 11528 from HSI-II group together with most orthologues from other fluorescent pseudomonads, whereas those from pv. phaseolicola, pv. syringae, pv. tabaci, pv. tomato T1 and pv. oryzae from HSI-I group closer to the Ralstonia solanacearum and Xanthomonas orthologues. Our analysis suggests multiple independent acquisitions and possible gene attrition/loss of putative T6SS genes by members of P. syringae.

Coiled-coils in type III secretion systems: structural flexibility, disorder and biological implications

Recent structural studies and analyses of microbial genomes have consolidated the understanding of the structural and functional versatility of coiled‐coil domains in proteins from bacterial type III secretion systems (T3SS). Such domains consist of two or more α‐helices forming a bundle structure. The occurrence of coiled‐coils in T3SS is considerably higher than the average predicted occurrence in prokaryotic proteomes. T3SS proteins comprising coiled‐coil domains are frequently characterized by an increased structural flexibility, which may vary from localized structural disorder to the establishment of molten globule‐like state. The propensity for coiled‐coil formation and structural disorder are frequently essential requirements for various T3SS functions, including the establishment of protein–protein interaction networks and the polymerization of extracellular components of T3SS appendages. Possible correlations between the frequently observed N‐terminal structural disorder of effectors and the T3SS secretion signal are discussed. The results for T3SS are also compared with other Gram‐negative secretory systems.