Lina De Smet

Comprehensive Bee Pathogen Screening in Belgium Reveals Crithidia mellificae as a New Contributory Factor to Winter Mortality

Since the last decade, unusually high honey bee colony losses have been reported mainly in North-America and Europe. Here, we report on a comprehensive bee pathogen screening in Belgium covering 363 bee colonies that were screened for 18 known disease-causing pathogens and correlate their incidence in summer with subsequent winter mortality. Our analyses demonstrate that, in addition to Varroa destructor, the presence of the trypanosomatid parasite Crithidia mellificae and the microsporidian parasite Nosema ceranae in summer are also predictive markers of winter mortality, with a negative synergy being observed between the two in terms of their effects on colony mortality. Furthermore, we document the first occurrence of a parasitizing phorid fly in Europe, identify a new fourth strain of Lake Sinai Virus (LSV), and confirm the presence of other little reported pathogens such as Apicystis bombi, Aphid Lethal Paralysis Virus (ALPV), Spiroplasma apis, Spiroplasma melliferum and Varroa destructor Macula-like Virus (VdMLV). Finally, we provide evidence that ALPV and VdMLV replicate in honey bees and show that viruses of the LSV complex and Black Queen Cell Virus tend to non-randomly co-occur together. We also noticed a significant correlation between the number of pathogen species and colony losses. Overall, our results contribute significantly to our understanding of honey bee diseases and the likely causes of their current decline in Europe.

Standard methods for virus research in Apis mellifera

Summary Honey bee virus research is an enormously broad area, ranging from subcellular molecular biology through physiology and behaviour, to individual and colony-level symptoms, transmission and epidemiology. The research methods used in virology are therefore equally diverse. This article covers those methods that are very particular to virological research in bees, with numerous cross-referrals to other BEEBOOK papers on more general methods, used in virology as well as other research. At the root of these methods is the realization that viruses at their most primary level inhabit a molecular, subcellular world, which they manipulate and interact with, to produce all higher order phenomena associated with virus infection and disease. Secondly, that viruses operate in an exponential world, while the host operates in a linear world and that much of the understanding and management of viruses hinges on reconciling these fundamental mathematical differences between virus and host. The article concentrates heavily on virus propagation and methods for detection, with minor excursions into surveying, sampling management and background information on the many viruses found in bees.

Respiration and Growth of Shewanella oneidensis MR-1 Using Vanadate as the Sole Electron Acceptor

Shewanella oneidensis MR-1 is a free-living gram-negative gamma-proteobacterium that is able to use a large number of oxidizing molecules, including fumarate, nitrate, dimethyl sulfoxide, trimethylamine N-oxide, nitrite, and insoluble iron and manganese oxides, to drive anaerobic respiration. Here we show that S. oneidensis MR-1 is able to grow on vanadate as the sole electron acceptor. Oxidant pulse experiments demonstrated that proton translocation across the cytoplasmic membrane occurs during vanadate reduction. Proton translocation is abolished in the presence of protonophores and the inhibitors 2-heptyl-4-hydroxyquinoline N-oxide and antimycin A. Redox difference spectra indicated the involvement of membrane-bound menaquinone and cytochromes c, which was confirmed by transposon mutagenesis and screening for a vanadate reduction-deficient phenotype. Two mutants which are deficient in menaquinone synthesis were isolated. Another mutant with disruption in the cytochrome c maturation gene ccmA was unable to produce any cytochrome c and to grow on vanadate. This phenotype could be restored by complementation with the pEC86 plasmid expressing ccm genes from Escherichia coli. To our knowledge, this is the first report of E. coli ccm genes being functional in another organism. Analysis of an mtrB-deficient mutant confirmed the results of a previous paper indicating that OmcB may function as a vanadate reductase or may be part of a vanadate reductase complex.

Widespread occurrence of honey bee pathogens in solitary bees

Solitary bees and honey bees from a neighbouring apiary were screened for a broad set of putative pathogens including protists, fungi, spiroplasmas and viruses. Most sampled bees appeared to be infected with multiple parasites. Interestingly, viruses exclusively known from honey bees such as Apis mellifera Filamentous Virus and Varroa destructor Macula-like Virus were also discovered in solitary bees. A microsporidium found in Andrena vaga showed most resemblance to Nosema thomsoni. Our results suggest that bee hives represent a putative source of pathogens for other pollinators. Similarly, solitary bees may act as a reservoir of honey bee pathogens.

BeeDoctor, a versatile MLPA-based diagnostic tool for screening bee viruses.

The long-term decline of managed honeybee hives in the world has drawn significant attention to the scientific community and bee-keeping industry. A high pathogen load is believed to play a crucial role in this phenomenon, with the bee viruses being key players. Most of the currently characterized honeybee viruses (around twenty) are positive stranded RNA viruses. Techniques based on RNA signatures are widely used to determine the viral load in honeybee colonies. High throughput screening for viral loads necessitates the development of a multiplex polymerase chain reaction approach in which different viruses can be targeted simultaneously. A new multiparameter assay, called “BeeDoctor”, was developed based on multiplex-ligation probe dependent amplification (MLPA) technology. This assay detects 10 honeybee viruses in one reaction. “BeeDoctor” is also able to screen selectively for either the positive strand of the targeted RNA bee viruses or the negative strand, which is indicative for active viral replication. Due to its sensitivity and specificity, the MLPA assay is a useful tool for rapid diagnosis, pathogen characterization, and epidemiology of viruses in honeybee populations. “BeeDoctor” was used for screening 363 samples from apiaries located throughout Flanders; the northern half of Belgium. Using the “BeeDoctor”, virus infections were detected in almost eighty percent of the colonies, with deformed wing virus by far the most frequently detected virus and multiple virus infections were found in 26 percent of the colonies.

Comparative characterization and expression analysis of the four Old Yellow Enzyme homologues from Shewanella oneidensis indicate differences in physiological function.

Shewanella oneidensis contains four genes that encode proteins that have high sequence identity with yeast OYE (Old Yellow Enzyme, an NADPH oxidoreductase), the well-studied archetype of the OYE protein family. The present paper describes the first comparative study of OYEs that are present in a single bacterial species, performed to gain insight into their biochemical properties and physiological importance. The four proteins [named SYE1-SYE4 (Shewanella Yellow Enzyme 1-4)] were expressed as glutathione S-transferase fusion proteins in Escherichia coli. The yield of SYE2, however, was too low for further characterization, even after expression attempts in S. oneidensis. The SYE1, SYE3 and SYE4 proteins were found to have characteristics similar to those of other OYE family members. They were identified as flavoproteins that catalyse the reduction of different alpha,beta-unsaturated carbonyl compounds and form charge transfer complexes with a range of phenolic compounds. Whereas the properties of SYE1 and SYE3 were very similar, those of SYE4 were clearly different in terms of ligand binding, catalytic efficiency and substrate specificity. Also, the activity of SYE4 was found to be NADPH-dependent, whereas SYE1 and SYE3 had a preference for NADH. It has been suggested that yeast OYE protects the actin cytoskeleton from oxidative stress. There are indications that bacterial OYEs are also involved in the oxidative stress response, but their exact role is unclear. Induction studies in S. oneidensis revealed that yeast and bacterial OYEs may share a common physiological role, i.e. the protection of cellular components against oxidative damage. As only SYE4 was induced under oxidative stress conditions, however, a functional divergence between bacterial OYEs is likely to exist.

Gastric epithelial cell death caused by Helicobacter suis and Helicobacter pylori γ‐glutamyl transpeptidase is mainly glutathione degradation‐dependent

Helicobacter (H.) suis is the most prevalent non‐H. pylori Helicobacter species colonizing the stomach of humans suffering from gastric disease. In the present study, we aimed to unravel the mechanism used by H. suis to induce gastric epithelial cell damage. H. suis lysate induced mainly apoptotic death of human gastric epithelial cells. Inhibition of γ‐glutamyl transpeptidase (GGT) activity present in H. suis lysate and incubation of AGS cells with purified native and recombinant H. suis GGT showed that this enzyme was partly responsible for the observed apoptosis. Supplementation of H. suis or H. pylori GGT‐treated cells with glutathione strongly enhanced the harmful effect of both enzymes and resulted in the induction of oncosis/necrosis, demonstrating that H. suis and H. pylori GGT‐mediated degradation of glutathione and the resulting formation of glutathione degradation products play a direct and active role in the induction of gastric epithelial cell death. This was preceded by an increase of extracellular H2O2 concentrations, generated in a cell‐independent manner and causing lipid peroxidation. In conclusion, H. suis and H. pylori GGT‐mediated generation of pro‐oxidant glutathione degradation products brings on cell damage and causes apoptosis or necrosis, dependent on the amount of extracellular glutathione available as a GGT substrate.

A kinetic approach to the dependence of dissimilatory metal reduction by Shewanella oneidensis MR-1 on the outer membrane cytochromes c OmcA and OmcB

The Gram‐negative bacterium Shewanella oneidensis MR‐1 shows a remarkably versatile anaerobic respiratory metabolism. One of its hallmarks is its ability to grow and survive through the reduction of metallic compounds. Among other proteins, outer membrane decaheme cytochromes c OmcA and OmcB have been identified as key players in metal reduction. In fact, both of these cytochromes have been proposed to be terminal Fe(III) and Mn(IV) reductases, although their role in the reduction of other metals is less well understood. To obtain more insight into this, we constructed and analyzed omcA, omcB and omcA/omcB insertion mutants of S. oneidensis MR‐1. Anaerobic growth on Fe(III), V(V), Se(VI) and U(VI) revealed a requirement for both OmcA and OmcB in Fe(III) reduction, a redundant function in V(V) reduction, and no apparent involvement in Se(VI) and U(VI) reduction. Growth of the omcB– mutant on Fe(III) was more affected than growth of the omcA– mutant, suggesting OmcB to be the principal Fe(III) reductase. This result was corroborated through the examination of whole cell kinetics of OmcA‐ and OmcB‐dependent Fe(III)‐nitrilotriacetic acid reduction, showing that OmcB is ∼ 11.5 and ∼ 6.3 times faster than OmcA at saturating and low nonsaturating concentrations of Fe(III)‐nitrilotriacetic acid, respectively, whereas the omcA– omcB– double mutant was devoid of Fe(III)‐nitrilotriacetic acid reduction activity. These experiments reveal, for the first time, that OmcA and OmcB are the sole terminal Fe(III) reductases present in S. oneidensis MR‐1. Kinetic inhibition experiments further revealed vanadate (V2O5) to be a competitive and mixed‐type inhibitor of OmcA and OmcB, respectively, showing similar affinities relative to Fe(III)‐nitrilotriacetic acid. Neither sodium selenate nor uranyl acetate were found to inhibit OmcA‐ and OmcB‐dependent Fe(III)‐nitrilotriacetic acid reduction. Taken together with our growth experiments, this suggests that proteins other than OmcA and OmcB play key roles in anaerobic Se(VI) and U(VI) respiration.

Structural and mutagenesis studies on the cytochrome c peroxidase from Rhodobacter capsulatus provide new insights into structure-function relationships of bacterial di-heme peroxidases.

Cytochrome c peroxidases (CCP) play a key role in cellular detoxification by catalyzing the reduction of hydrogen peroxide to water. The di-heme CCP from Rhodobacter capsulatus is the fastest enzyme (1060 s-1), when tested with its physiological cytochrome c substrate, among all di-heme CCPs characterized to date and has, therefore, been an attractive target to investigate structure-function relationships for this family of enzymes. Here, we combine for the first time structural studies with site-directed mutagenesis and spectroscopic studies of the mutant enzymes to investigate the roles of amino acid residues that have previously been suggested to be important for activity. The crystal structure of R. capsulatus at 2.7 Å in the fully oxidized state confirms the overall molecular scaffold seen in other di-heme CCPs but further reveals that a segment of about 10 amino acids near the peroxide binding site is disordered in all four molecules in the asymmetric unit of the crystal. Structural and sequence comparisons with other structurally characterized CCPs suggest that flexibility in this part of the molecular scaffold is an inherent molecular property of the R. capsulatus CCP and of CCPs in general and that it correlates with the levels of activity seen in CCPs characterized, thus, far. Mutagenesis studies support the spin switch model and the roles that Met-118, Glu-117, and Trp-97 play in this model. Our results help to clarify a number of aspects of the debate on structure-function relationships in this family of bacterial CCPs and set the stage for future studies.

The 285 kDa Bap/RTX hybrid cell surface protein (SO4317) of Shewanella oneidensis MR-1 is a key mediator of biofilm formation.

Shewanella oneidensis, a Gram-negative bacterium with unusual respiratory versatility, is found in soil and sediment environments, and sporadically as an opportunistic pathogen in humans and aquatic animals. The ability to form biofilms is a critical factor in the environmental spread and survival of this bacterium. We subjected S. oneidensis MR-1 to random transposon insertion mutagenesis to identify genes contributing to the ability of the organism to form biofilms on polystyrene surfaces. Follow-up of the clone that was most heavily impaired in biofilm formation led to the identification of a novel 285 kDa multi-domain protein which we have termed biofilm-promoting factor A (BpfA). BpfA is secreted by a type I secretion system to the cell surface, where it is a requisite for biofilm development. The BpfA-dependent biofilm phenotype is positively modulated by sub to low millimolar amounts of calcium. Intriguingly, BpfA features structural motifs and sequence fingerprints that can be traced back to bacterial Bap-family and RTX family proteins, two protein families harboring putative and established calcium binding sites.