Species-specific gene duplication in Clostridia produces variations of cholesterol-dependent cytolysin with different cytotoxicity.

Cholesterol-dependent cytolysin (CDC) is a bacterial toxin that binds to eukaryotic cholesterol-containing membranes, forms oligomeric complexes, and is inserted into the bilayer to create large aqueous pores. Recently, we reported a species-specific duplication of the hemolysin gene in group III Clostridium botulinum. The duplicated genes (bly1 and bly2) encoded two separate CDC proteins (botulinolysins; BLY1 and BLY2). Here, we aimed to investigate whether BLY1 and BLY2 exert differential cytotoxicity. We isolated two bly genes from C. botulinum and evaluated the cytotoxicity of two recombinant BLY proteins (rBLY1 and rBLY2) in HeLa, IEC-6, and NRK cells. rBLYs were cytotoxic to equine erythrocytes. rBLY1 showed higher hemolytic activity than rBLY2. rBLY2 showed no or very weak cytotoxicity to the HeLa, IEC-6, and NRK cells, whereas rBLY1 showed high cytotoxicity to these cells. The comparison of the amino acid sequence of BLYs with those of other CDCs revealed that the already-known amino acid residues involved in cholesterol-containing membrane recognition, oligomerization, and insertion into membranes are well conserved in both BLYs. However, several amino acid substitutions were observed in the conserved regions, particularly in L2 and L3 regions involved in cell binding. These findings suggest that gene duplication in group III C. botulinum evolved distinct functional specializations, and differential cytotoxicity of BLY1 and BLY2 could be due to the amino acid substitution in the conserved regions. However, the structural and functional comparisons of the two BLYs are essential to gain insights into the function of the CDCs.

Complete subunit structure of serotype C and D botulinum progenitor toxin complex induces vacuolation in the specific epithelial cell line.

Clostridium botulinum produces seven botulinum neurotoxin (BoNT) serotypes. In nature, BoNT exists as a part of the progenitor toxin complex (PTC) through associations with neurotoxin associated proteins (NAPs), including nontoxic nonhemagglutinin and hemagglutinin (HA) complex, consists of HA-70, HA-17 and HA-33. Because PTC displays higher oral toxicity than pure BoNTs, NAPs play a critical role in food poisoning. In a previous study, we demonstrated that the NAP complex in mature large-sized PTC (L-PTC) from serotypes C and D concomitantly induced cell death and cytoplasmic vacuolation in the rat intestinal epithelial cell line IEC-6. Here, we found that the serotype D NAP complex induces only cytoplasmic vacuolation in the normal rat kidney cell line NRK-52E without reducing cell viability. NAP complexes from serotype A and B L-PTCs did not affect cell viability or cytoplasmic vacuolation in IEC-6 and NRK-52E cells. Furthermore, we assessed the effect of immature L-PTCs with fewer HA-33/HA-17 trimers (two HA-33 and one HA-17) than mature L-PTCs on cell viability and cytoplasmic vacuolation in IEC-6 and NRK-52E cells. As a result, mature L-PTCs with the maximum number of HA-33/HA-17 trimers displayed the greatest potency. Consequently, the reduction in cell viability and vacuolation induction are related to the number of HA-33/HA-17 trimers in PTC. The discovery of an epithelial cell model where botulinum PTC specifically induces vacuolization may help clarify the unknown cytotoxicity of PTC, which plays an important role in the trans-epithelial transport of the toxin.

Atomic force microscopic image data of botulinum neurotoxin complexes with different molecular sizes.

This data article provides atomic force microscopy (AFM) amplitude images of botulinum toxin complex (TC) molecules produced by Clostridium botulinum serotype D strain. C. botulinum produces different-sized TC molecules, such as a complex of botulinum neurotoxin and nontoxic nonhemagglutinin proteins (M-TC) and complex of M-TC and hemagglutinin subcomplex (L-TC). In this data article, the M and L-TC produced by serotype D strain 4947 were imaged by AFM. The M-TC molecule had a globular structure with a 30.5-nm diameter and a 2.1-nm height, while the L-TC molecule had a distinct structure in which several spheres were connected to a globular structure that was 40.7 nm in diameter and 3.5 nm in height.