Douglas J. Beecher

Requirement of flhA for Swarming Differentiation, Flagellin Export, and Secretion of Virulence-Associated Proteins in Bacillus thuringiensis

Bacillus thuringiensis is being used worldwide as a biopesticide, although increasing evidence suggests that it is emerging as an opportunistic human pathogen. While phospholipases, hemolysins, and enterotoxins are claimed to be responsible for B. thuringiensis virulence, there is no direct evidence to indicate that the flagellum-driven motility plays a role in parasite-host interactions. This report describes the characterization of a mini-Tn10 mutant of B. thuringiensis that is defective in flagellum filament assembly and in swimming and swarming motility as well as in the production of hemolysin BL and phosphatidylcholine-preferring phospholipase C. The mutant strain was determined to carry the transposon insertion in flhA, a flagellar class II gene encoding a protein of the flagellar type III export apparatus. Interestingly, the flhA mutant of B. thuringiensis synthesized flagellin but was impaired in flagellin export. Moreover, a protein similar to the anti-sigma factor FlgM that acts in regulating flagellar class III gene transcription was not detectable in B. thuringiensis, thus suggesting that the flagellar gene expression hierarchy of B. thuringiensis differs from that described for Bacillus subtilis. The flhA mutant of B. thuringiensis was also defective in the secretion of hemolysin BL and phosphatidylcholine-preferring phospholipase C, although both of these virulence factors were synthesized by the mutant. Since complementation of the mutant with a plasmid harboring the flhA gene restored swimming and swarming motility as well as secretion of toxins, the overall results indicate that motility and virulence in B. thuringiensis may be coordinately regulated by flhA, which appears to play a crucial role in the export of flagellar as well as nonflagellar proteins.

Evidence for Contribution of Tripartite Hemolysin BL, Phosphatidylcholine-Preferring Phospholipase C, and Collagenase to Virulence of Bacillus cereus Endophthalmitis

ABSTRACT Bacillus cereus causes a highly fulminant endophthalmitis which usually results in blindness. We previously concluded that hemolysin BL (HBL), a tripartite necrotizing pore-forming toxin, is a probable endophthalmitis virulence factor because it is highly toxic to retinal tissue in vitro and in vivo. We also determined that B. cereus produces additional retinal toxins that might contribute to virulence. Here we fractionated crudeB. cereus culture supernatant by anion-exchange chromatography and found that in vitro retinal toxicity was also associated with phosphatidylcholine-preferring phospholipase C (PC-PLC). The pure enzyme also caused retinal necrosis in vivo. We showed that phosphatidylinositol-specific PLC and sphingomyelinase were nontoxic and that two hemolysins, cereolysin O and a novel hemolysin designated hemolysin IV, were marginally toxic in vitro. The histopathology of experimental septic endophthalmitis in rabbits mimicked the pathology produced by pure HBL, and both HBL and PC-PLC were detected at toxic concentrations in infected vitreous fluid. Bacterial cells were first seen associated with the posterior margin of the lens and eventually were located throughout the lens cortex. Detection of collagenase in the vitreous humor suggested that infiltration was facilitated by the breakdown of the protective collagen lens capsule by that enzyme. This work supports our conclusion that HBL contributes to B. cereus virulence and implicates PC-PLC and collagenase as additional virulence factors.

Swarming motility in Bacillus cereus and characterization of a fliY mutant impaired in swarm cell differentiation

This report describes a new behavioural response of Bacillus cereus that consists of a surface-induced differentiation of elongated and hyperflagellated swarm cells exhibiting the ability to move collectively across the surface of the medium. The discovery of swarming motility in B. cereus paralleled the isolation of a spontaneous non-swarming mutant that was found to carry a deletion of fliY, the homologue of which, in Bacillus subtilis, encodes an essential component of the flagellar motor-switch complex. However, in contrast to B. subtilis, the fliY mutant of B. cereus was flagellated and motile, thus suggesting a different role for FliY in this organism. The B. cereus mutant was completely deficient in chemotaxis and in the secretion of the L2 component of the tripartite pore-forming necrotizing toxin, haemolysin BL, which was produced exclusively by the wild-type strain during swarm-cell differentiation. All the defects in the fliY mutant of B. cereus could be complemented by a plasmid harbouring the B. cereus fliY gene. These results demonstrate that the activity of fliY is required for swarming and chemotaxis in B. cereus, and suggest that swarm-cell differentiation is coupled with virulence in this organism.

Cooperative, synergistic and antagonistic haemolytic interactions between haemolysin BL, phosphatidylcholine phospholipase C and sphingomyelinase from Bacillus cereus

Haemolysis of erythrocytes from different species (sheep, bovine, swine and human), caused by various combinations of phosphatidylcholine (PC)-preferring phospholipase C (PC-PLC), sphingomyelinase (SMase) and the three-component, pore-forming toxin haemolysin BL (HBL) from Bacillus cereus was analysed. The lytic potency of HBL did not correlate with phospholipid (PL) content, but lysis by the individual or combined enzymes did. SMase alone lysed ruminant erythrocytes, which contain 46-53% sphingomyelin (SM). The cooperative action of PC-PLC and SMase was needed to lyse swine and human erythrocytes (22-31% PC and 28-25% SM). SMase synergistically enhanced haemolysis caused by HBL for all erythrocytes tested, which all contained >25% SM. PC-PLC enhanced HBL haemolysis only in cells containing significant amounts of PC (swine, 22% PC; human, 31% PC). Unexpectedly, PC-PLC inhibited HBL lysis of sheep erythrocytes (<2% PC) and enhanced the discontinuous haemolysis pattern that is characteristic of HBL in sheep blood agar. Inhibition and pattern enhancement was abolished by washing PC-PLC-treated erythrocytes or by adding EDTA, suggesting that enzymic alteration of the membrane is not involved, but that zinc in the active site is required, perhaps to facilitate binding. These observations highlight the potential for cooperative and synergistic interactions among virulence factors in B. cereus infections and dependence of these effects on tissue composition.

Swarming Behavior of and Hemolysin BL Secretion by Bacillus cereus

ABSTRACT An association between swarming and hemolysin BL secretion was observed in a collection of 42 Bacillus cereus isolates (P = 0.029). The highest levels of toxin were detected in swarmers along with swarm cell differentiation (P = 0.021), suggesting that swarming B. cereus strains may have a higher virulence potential than nonswarming strains.

Failure of intravitreal dexamethasone to diminish inflammation or retinal toxicity in an experimental model of Bacillus cereus endophthalmitis

Purpose. To determine whether the usual clinical dose of intravitreal dexamethasone can attenuate intraocular inflammation and retinal necrosis in a rabbit model of fulminant Bacillus cereus endophthalmitis induced by crude exotoxins. Methods. Thirty-six eyes from pigmented mongrel rabbits received intravitreal injections of varying concentrations of crude B. cereus exotoxins with or without concomitant injections of 400 µg of dexamethasone sodium phosphate (0.1% solution). After ophthalmoscopic examination at 4 or 18 hr postinjection, the animals were killed and histopathologic findings graded. Results. Intraocular inflammation and retinal necrosis scores in eyes receiving both exotoxins and dexamethasone did not differ significantly from eyes receiving exotoxins alone for any exotoxin dose at 4 or 18 hr. The severity of retinal necrosis increased with toxin dose and was nearly maximal after 4 hr. Intraocular inflammation also generally increased with dose, but continued to increase until 18 hr. Conclusions. Standard clinical doses of intravitreal dexamethasone do not appear to attenuate the intraocular inflammatory or tissue response to secreted B. cereus exotoxins. Other treatment modalities including vitrectomy, to decrease exotoxin load, and exotoxin inhibitors may be necessary for the effective treatment of B. cereus endophthalmitis.

The Bacillus cereus group.

Publisher Summary Bacillus cereus food poisoning and knowledge of its virulence mechanisms is still in its infancy. The diarrhoeal and emetic food poisoning syndromes that it causes are mild, and the necrotic infections that it causes are relatively rare consequently, extensive efforts to understand its pathogenesis have only recently begun in earnest. B. cereus produces an exceptional number of products that are conventionally regarded as virulence factors. The roles of specific factors in pathogenesis except that the cyclic polypeptide toxin cereulide induces vomiting, and the haemolysin BL (HBL) family of tripartite toxins appears to contribute significantly to diarrhoeal food poisoning. Virulence is essentially always multi-factorial; this chapter presents a survey of currently identified virulence factors and outlines their potential or demonstrated contributions to virulence. The mechanisms of B. cereus virulence are still poorly understood. HBL possesses all of the physicochemical and biological characteristics historically associated with diarrhoeal food poisoning activity, but it is not produced by all B. cereus isolates associated with food poisoning.

Botulinum Neurotoxin Type A: Limited Proteolysis by Endoproteinase Glu-C and α-Chymotrypsin Enhanced Following Reduction; Identification of the Cleaved Sites and Fragments

Botulinum neurotoxin (NT) serotype A is a ∼150-kDa dichain protein. Posttranslational nicking of the single-chain NT (residues Pro 1–Leu 1295) by the protease(s) endogenous to Clostridium botulinum excises 10 residues, leaving Pro 1–Lys 437 and Ala 448–Leu 1295 in the ∼50-kDa light (L) and ∼100-kDa heavy (H) chains, respectively, connected by a Cys 429–Cys 453 disulfide and noncovalent bonds [Krieglstein et al. (1994), J. Protein Chem.13, 49–57]. The L chain is a metalloprotease, while the amino- and carboxy-terminal halves of the H chain have channel-forming and receptor-binding activities, respectively [Montecucco and Schiavo (1995), Q. Rev. Biophys.28, 423–472]. Endoproteinase Glu-C and α-chymotrypsin were used for controlled digestion at pH 7.4 of the ∼150-kDa dichain NT and the isolated ∼100-kDa H chain (i.e., freed from the L chain) in order to map the cleavage sites and isolate the proteolytic fragments. The dichain NT appeared more resistant to cleavage by endoproteinase Glu-C than the isolated H chain. In contrast, the NT with its disulfide(s) reduced showed rapid digestion of both chains, including a cleavage between Glu 251 and Met 252 (resulting in ∼30- and ∼20-kDa fragments of the L chain) which was not noted unless the NT was reduced. Interestingly, an adjacent bond, Tyr 249–Tyr 250, was noted earlier [DasGupta and Foley (1989), Biochimie71, 1193–1200] to undergo “self-cleavage” following reductive separation of the L chain from the H chain. The site Tyr–Tyr–Glu–Met (residues 249–252) appears to become exposed following reduction of Cys 429–Cys 453 disulfide. Identification of Glu 669–Ile 670 and Tyr 683–Ile 684 as protease-susceptible sites demonstrated for the first time that at least two peptide bonds in the segment of the H chain (residues 659–684), part of which (residues 659–681) is thought to interact with the endosomal membranes and forms channels [Oblatt-Montal et al., (1995), Protein Sci.4, 1490–1497], are exposed on the surface of the NT. Two of the fragments of the H chain we generated and purified by chromatography are suitable for structure–function studies; the ∼85- and ∼45-kDa fragments beginning at residue Leu 544 and Ser 884, respectively (both extend presumably to Leu 1295) contain the channel-forming segment and receptor-binding segments, respectively. In determining partial amino acid sequences of 10 fragments, a total of 149 amino acids in the 1275-residue NT were chemically identified.