Adult honeybee's resistance against Paenibacillus larvae larvae, the causative agent of the American foulbrood.

American foulbrood is a widespread disease of honeybee larvae caused by the spore-forming bacterium Paenibacillus larvae subsp. larvae. Spores represent the infectious stage; when ingested by a larva they germinate in the midgut. The rod-shaped vegetative forms penetrate the larva's intestinal tissue and start multiplying rapidly, which finally kills the larva. Spores fed to adult honeybees, however, do not harm the bees. We investigated this phenomenon. Specifically, we studied the influence of the adult honeybee midgut on the vegetative growth and on the germination of spores of P. larvae larvae. We focused on two groups of adult workers that are likely to have large numbers of spores in their gastrointestinal tracts in infected colonies: middle-aged bees, which are known to remove or cannibalize dead larvae and clean brood cells, and winterbees, which do not have frequent chances to defecate. We found that midgut extract from winterbees and worker-aged bees of different colonies almost completely inhibited the growth of the vegetative stage of P. larvae larvae and suppressed the germination of spores. The inhibiting substance or substances from the adult midgut are very temperature stable: they still show about 60% of their growth-inhibiting capacity against this bacterium after 15 min at 125 degrees C. We established a method to test growth-inhibiting factors against P. larvae larvae in vitro.     

Heterologous expression of green fluorescent protein in Paenibacillus larvae, the causative agent of American Foulbrood of honey bees

Aims: We aimed at expressing heterologous proteins in Paenibacillus larvae, the causative agent of American Foulbrood of honey bees, as a prerequisite for future studies on the molecular pathogenesis of P. larvae infections. Methods and Results: For this purpose, we established a protocol for the transformation of the plasmid pAD43‐25 carrying a functional GFP gene sequence (gfpmut3a) into different P. larvae strains representing the two most relevant P. larvae genotypes ERIC I and ERIC II. We determined the optimal field strength for electroporation and the optimal regeneration time after transformation. Stable GFP expression could be detected in the mutants during their entire life cycles and even after sporulation and re‐germination. Conclusions: This method is suitable not only for the expression of GFP in P. larvae but also for the expression of heterologous proteins or GFP‐tagged proteins in P. larvae. Mutants can be used for infection assays because GFP expression remained stable after sporulation and re‐germination. Significance and Impact of the Study: This method provides the first true molecular tool for P. larvae and, therefore, is an immense advancement from what we had previously at our hands for the study of P. larvae pathogenesis.     

Lack of interaction between the milky disease bacterium Paenibacillus popilliae and stilbene-derived optical brighteners in Japanese beetle larvae

Optical brighteners cansynergistically enhance nucleopolyhedrovirusinfectivity to lepidopteran larvae by blockingthe sloughing of infected primary midgut cellsand inhibiting the formation of the peritrophicmembrane in the hosts. Because of similaritiesin the route of infection, we investigatedwhether optical brighteners would also enhanceinfection with the milky disease bacterium,Paenibacillus popilliae, of Japanesebeetle, Popillia japonica, larvae. Thelarvae were kept in soil mixed with P.popilliae spore preparations and the opticalbrighteners Blankophor BBH, P167, or RKH withperennial ryegrass provided as food. Noenhancing effect of any of the opticalbrighteners on P. popilliae infection wasobserved at a concentration of 0.1% (w/w). Rather, when mixed into the soil at 0.02, 0.1,or 0.5% (w/w) BBH reduced P. popilliaeinfection at the highest rate.     

Comparative susceptibility and immune responses of Asian and European honey bees to the American foulbrood pathogen,Paenibacillus larvae

American foulbrood (AFB) disease is caused by Paenibacillus larvae. Currently, this pathogen is widespread in the European honey bee— Apis mellifera. However, little is known about infectivity and pathogenicity of P. lan'ae in the Asiatic cavity-nesting honey bees, Apis cerana. Moreover, comparative knowledge of P. larvae infectivity and pathogenicity between both honey bee species is scarce. In this study, we examined susceptibility, larval mortality, survival rate and expression of genes encoding antimicrobial peptides (AMPs) including defensin, apidaecin, abaecin, and hymenoptaecin in A. mellifera and A. cerana when infected with P. larvae. Our results showed similar effects of P. larvae on the survival rate and patterns of AMP gene expression in both honey bee species when bee larvae are infected with spores at the median lethal concentration (LC5 0 ) for A. mellifera. All AMPs of infected bee larvae showed significant upregulation compared with noninfected bee larvae in both honey bee species. However, larvae of A. cerana were more susceptible than A. mellifera when the same larval ages and spore concentration of P. larvae were used. It also appears that A. cerana showed higher levels of AMP expression than A. mellifera. This research provides the first evidence of survival rate, LC50 and immune response profiles of Asian honey bees, A. cerana, when infected by P. larvae in comparison with the European honey bee, A. mellifera.     

Regional distribution of Paenibacillus larvae subspecies larvae, the causative organism of American foulbrood, in honey bee colonies of the Western United States

We examined honey bee, Apis mellifera L., colonies pollinating almonds in California during February 2003 for Paenibacillus larvae subsp. Larvae, the causative organism of the virulent brood disease American foulbrood. Colonies originating from the Rocky Mountain area and California had significantly higher numbers (P < 0.05) of bacterial colony-forming units (CFUs) (408 and 324 per 30 adult bees, respectively) than colonies from the upper Midwest (1.28). Colonies from the northwestern, central, and southwestern United States had intermediate CFU or bacterial colony levels. Operations positive for P. larvae larvae were relatively uniform at approximately 70-80%, and no regional significant differences were found. Percentages of colonies with high CFUs (> or = 400 per 30 bees) differed significantly, with those from the Rocky Mountain region having 8.73% compared with those of the upper Midwest with 0%. The significance of CFU levels was evaluated by inoculating healthy colonies with diseased immatures and sampling adult bees. The number of CFUs detected per diseased immature was conservatively estimated to be approximately 399 CFUs per 30 adult bees. We defined this spore level as 1 disease equivalent. Based on this, 3.86% colonies in our survey had 1 or more disease equivalent number of P. larvae larvae CFUs. Operations with high P. larvae larvae spore levels in their colonies will likely observe American foulbrood if prophylaxis is not practiced diligently.     

American Foulbrood in honeybees and its causative agent,Paenibacillus larvae

After more than a century of American Foulbrood (AFB) research, this fatal brood infection is still among the most deleterious bee diseases. Its etiological agent is the Gram-positive, spore-forming bacterium Paenibacillus larvae. Huge progress has been made, especially in the last 20 years, in the understanding of the disease and of the underlying host-pathogen interactions. This review will place these recent developments in the study of American Foulbrood and of P. larvae into the general context of AFB research.     

The distribution of Paenibacillus larvae spores in adult bees and honey and larval mortality, following the addition of American foulbrood diseased brood or spore-contaminated honey in honey bee (Apis mellifera) colonies

Within colony transmission of Paenibacillus larvae spores was studied by giving spore-contaminated honey comb or comb containing 100 larvae killed by American foulbrood to five experimental colonies respectively. We registered the impact of the two treatments on P. larvae spore loads in adult bees and honey and on larval mortality by culturing for spores in samples of adult bees and honey, respectively, and by measuring larval survival. The results demonstrate a direct effect of treatment on spore levels in adult bees and honey as well as on larval mortality. Colonies treated with dead larvae showed immediate high spore levels in adult bee samples, while the colonies treated with contaminated honey showed a comparable spore load but the effect was delayed until the bees started to utilize the honey at the end of the flight season. During the winter there was a build up of spores in the adult bees, which may increase the risk for infection in spring. The results confirm that contaminated honey can act as an environmental reservoir of P. larvae spores and suggest that less spores may be needed in honey, compared to in diseased brood, to produce clinically diseased colonies. The spore load in adult bee samples was significantly related to larval mortality but the spore load of honey samples was not.     

Fluorescence in situ hybridization (FISH) analysis of the interactions between honeybee larvae and Paenibacillus larvae, the causative agent of American foulbrood of honeybees (Apis mellifera)

American foulbrood (AFB) is a bacterial disease of honeybee larvae caused by the spore-forming bacterium Paenibacillus larvae. Although AFB and its aetiological agent are described now for more than a century, the general and molecular pathogenesis of this notifiable disease is poorly understood. We used fluorescence in situ hybridization (FISH) performed with P. larvae-specific, 16S rRNA-targeted oligonucleotide probes to analyse the early steps in the pathogenesis of American foulbrood. The following chain of events could be demonstrated: (i) the spores germinate in the midgut lumen, (ii) the vegetative bacteria massively proliferate within the midgut before, and (iii) they start to locally breach the epithelium and invade the haemocoel. The paracellular route was shown to be the main mechanism for invasion contrasting earlier hypotheses of phagocytosis of P. larvae. Invasion coincided with the death of the host implicating that the penetration of the midgut epithelium is a critical step determining the time of death.     

Ultrastructure of American foulbrood disease pathogenesis in larvae of the worker honey bee,Apis mellifera

Using electron microscopy, the pathogenesis of American foulbrood disease was followed from ingestion of Bacillus larvae spores by young, susceptible honey bee larvae to death of the host and sporulation of the pathogen. Interaction between the host peritrophic membrane and B. larvae vegetatives is described. Phagocytosis was demonstrated to be a mechanism of entry of pathogen into host midgut cells. No evidence of enzymatic digestion of peritrophic membrane or host-cell microvilli was found during the initial interaction of pathogen and host midgut cell, although eventual lysis of host gut cells may have been the result of enzymatic activity. Following entry of bacteria into the hemocoel, host death resulted from systemic bacteremia.     

Strain- and genotype-specific differences in virulence of Paenibacillus larvae subsp. larvae, a bacterial pathogen causing American foulbrood disease in honeybees

Virulence variations of Paenibacillus larvae subsp. larvae, the causative agent of American foulbrood disease of honeybees, were investigated by analysis of 16 field isolates of this pathogen, belonging to three previously characterized genotypes, as well as the type strain (ATCC 9545) of P. larvae subsp. larvae, with exposure bioassays. We demonstrated that the strain-specific 50% lethal concentrations varied within an order of magnitude and that differences in amount of time for the pathogen to kill 100% of the infected hosts (LT100) correlated with genotype. One genotype killed rather quickly, with a mean LT100 of 7.8 +/- 1.7 days postinfection, while the other genotypes acted more slowly, with mean LT100s of 11.2 +/- 0.8 and 11.6 +/- 0.6 days postinfection.     

Diagnosis of American foulbrood in honey bees: a synthesis and proposed analytical protocols

Worldwide, American foulbrood (AFB) is the most devastating bacterial disease of the honey bee (Apis mellifera). Because the distinction between AFB and powdery scale disease is no longer considered valid, the pathogenic agent has recently been reclassified as one species Paenibacillus larvae, eliminating the subspecies designations Paenibacillus larvae subsp. larvae and Paenibacillus larvae subsp. pulvifaciens. The creamy or dark brown, glue-like larval remains of infected larvae continue to provide the most obvious clinical symptom of AFB, although it is not conclusive. Several sensitive and selective culture media are available for isolation of this spore-forming bacterium, with the type of samples that may be utilized for detection of the organism being further expanded. PCR methods for identification and genotyping of the pathogen have now been extensively developed. Nevertheless, biochemical profiling, bacteriophage sensitivity, immunotechniques and microscopy of suspect bacterial strains are entirely adequate for routine identification purposes.     

Ultra-rapid real-time PCR for the detection of Paenibacillus larvae, the causative agent of American Foulbrood (AFB)

A novel micro-PCR-based detection method, termed ultra-rapid real-time PCR, was applied to the development of a rapid detection for Paenibacillus larvae (P. larvae) which is the causative agent of American Foulbrood (AFB). This method was designed to detect the 16S rRNA gene ofP. larvae with a micro-scale chip-based real-time PCR system, GenSpector^® TMC-1000, which has uncommonly fast heating and cooling rates (10 °C per second) and small reaction volume (6 μl). In the application of ultra-rapid real-time PCR detection to an AFB-infected larva, the minimum detection time was 7 min and 54 s total reaction time (30 cycles), including the melting temperature analysis. To the best of our knowledge, this novel detection method is one of the most rapid real-time PCR-based detection tools.     

Paenibacillus associated with milky disease in Central and South American scarabs

Thirty-one isolates of bacteria causing milky disease in scarab larvae collected in Central and South America were identified as Paenibacillus popilliae or Paenibacillus lentimorbus by use of DNA similarity analysis. The isolates were more similar to each other than to the North American isolates that are the type strains of the species. All of the bacteria of both species produced parasporal bodies, a characteristic previously believed to be unique to P. popilliae. Screening of the bacteria using PCR with parasporal protein primers revealed differences among the parasporal protein genes of P. popilliae isolates and between the parasporal genes of P. popilliae and P. lentimorbus. In contrast to P. popilliae from North America, none of the isolates from Central and South America was resistant to vancomycin, an indication of an interesting geographic distribution of the resistance genes.     

Fatty Acids in Bacillus larvae, Bacillus lentimorbus, and Bacillus popilliae

The types of fatty acids produced by two strains each of Bacillus larvae, B. lentimorbus, and B. popilliae, and their distribution patterns, were studied by gas-liquid chromatography. All six organisms produced eight major fatty acids: six branched (iso-C(14), -C(15), -C(16), and -C(17), and anteiso-C(15) and -C(17)), two normal (n-C(14) and -C(16)), and two minor (n-C(15) and monounsaturated n-C(16)). In addition, some other trace acids were produced. Branched-chain fatty acids accounted for 54 to 85% of the total fatty acids. These compositions are similar to those previously found with 26 strains of 12 species of the genus Bacillus. Thus, an abundance of branched-chain fatty acids seems to be a characteristic of the biochemical nature of the genus Bacillus. It is noteworthy that marked differences between the nutritional requirements of the three insect pathogens used in the present study and those of the other 12 species of the genus Bacillus studied previously are not significantly reflected in their fatty acid composition.     

A PCR-based method that permits specific detection of Paenibacillus larvae subsp. larvae, the cause of American Foulbrood of honey bees, at the subspecies level

AIMS: A reliable procedure for the identification of Paenibacillus larvae subsp. larvae, the causal agent of American Foulbrood disease of honey bees (Apis mellifera L.) based on the polymerase chain reaction (PCR) and subspecies - specific primers is described. METHODS AND RESULTS: By using ERIC-PCR, an amplicon of ca 970 bp was found among P. l. larvae strains but not in other closely related species. Based on the nucleotide sequence data of this amplicon, we designed the pair of oligonucleotides KAT 1 and KAT 2, which were assayed as primers in a PCR reaction. A PCR amplicon of the expected size ca 550 bp was only found in P. l. larvae strains. CONCLUSIONS: This PCR assay provides a specific detection for P. l. larvae. SIGNIFICANCE AND IMPACT OF THE STUDY: The developed PCR assay is highly specific because can differentiate Paenibacillus larvae subsp. larvae from the closely related Paenibacillus larvae subsp. pulvifaciens. The technique can be directly used to detect presence or absence of P. l. larvae spores in honey bee brood samples and contaminated honeys.