Roshan Kukreja

Biologically Active Novel Conformational State of Botulinum, the Most Poisonous Poison

Botulinum neurotoxins (serotypes A-G), the most toxic substances known to humankind, cause flaccid muscle paralysis by blocking acetylcholine release at nerve-muscle junctions through a very specific and exclusive endopeptidase activity against SNARE proteins of presynaptic exocytosis machinery. We have examined polypeptide folding of the endopeptidase moiety of botulinum neurotoxin/A (the light chain) under conditions of its optimal enzymatic activity and have found that one of its stable conformational states is a molten-globule, which retains over 60% of its optimal enzyme activity. More importantly, we have discovered that the light chain acquires a novel pre-imminent molten-globule enzyme conformation at the physiologically relevant temperature, 37 °C. The pre-imminent molten-globule enzyme form also exhibited the maximum endopeptidase activity against its intracellular substrate, SNAP-25 (synaptosomal associated protein of 25 kDa). These findings will not only open new avenues to design effective diagnostics and antidotes against botulism but also provide new information on enzymatically active molten-globule or molten-globule like structures.

Immunological characterization of the subunits of type A botulinum neurotoxin and different components of its associated proteins

Botulinum neurotoxins (BoNTs) constitute a family of seven structurally similar but antigenically distinct proteins produced by different strains of Clostridium botulinum. Type A botulinum neurotoxin (BoNT/A) is produced along with 6 neurotoxin associated proteins (NAPs) including hemagglutinin (Hn-33) through polycistronic expression of a clustered group of genes to form a complex (BoNT/AC). The presence of NAPs enhances the oral toxicity of the neurotoxin significantly. Hn-33 makes up the largest fraction of NAPs in BoNT/AC and strongly protects BoNT/A against proteases of the GI tract. BoNT in its complex form is also used in therapeutic and cosmetic applications to treat several neuromuscular disorders. In this study immunological reactivity of BoNT/A in its purified and complex forms, neurotoxin associated proteins, and Hn-33 have been examined using enzyme-linked immunosorbent assay (ELISA). Antibodies raised against the whole complex reacted 60 times better with the complex and 35 times better with Hn-33 and NAPs compared to the purified neurotoxin suggesting stronger immunogenicity of NAPs over that of purified neurotoxin and a higher potential of BoNT/AC and its associated proteins to induce host immune response. This observation also suggests that Hn-33 and other NAPs could potentially be employed as adjuvants for development of vaccines against botulism and could be a good surrogate for botulinum diagnostics. ELISA binding curves of BoNT/AC and BoNT/A with antibodies raised against BoNT/A indicate that BoNT/A in its purified and complex forms induces equal immunogenic response and a 2.5-fold higher immunogenic response compared to BoNT/A light and heavy chains. We have also discovered a new protein, an intimin analog, present within the complex preparation of BoNT/A which shows dramatically high immunoreactivity.

Clostridial neurotoxins as a drug delivery vehicle targeting nervous system.

Several neuronal disorders require drug treatment using drug delivery systems for specific delivery of the drugs for the targeted tissues, both at the peripheral and central nervous system levels. We describe a review of information currently available on the potential use of appropriate domains of clostridial neurotoxins, tetanus and botulinum, for effective drug delivery to neuronal systems. While both tetanus and botulinum neurotoxins are capable of delivering drugs the neuronal cells, tetanus neurotoxin is limited in clinical use because of general immunization of population against tetanus. Botulinum neurotoxin which is also being used as a therapeutic reagent has strong potential for drug delivery to nervous tissues.

Microarray analysis of differentially regulated genes in human neuronal and epithelial cell lines upon exposure to type A botulinum neurotoxin.

Among the seven serotypes (A-G), type A botulinum neurotoxin (BoNT/A) is the most prevalent etiologic agent and the most potent serotype to cause foodborne botulism, characterized by flaccid muscle paralysis. Upon ingestion, BoNT/A crosses epithelial cell barriers to reach lymphatic and circulatory systems and blocks acetylcholine release at the pre-synaptic cholinergic nerve terminals of neuromuscular junctions (NMJs) resulting in paralysis. One of the unique features of BoNT/A intoxication is its neuroparalytic longevity due to its persistent catalytic activity. The persistent presence of the toxin inside the cell can induce host cell responses. To understand the pathophysiology and host response at the cellular level, gene expression changes upon exposure of human HT-29 colon carcinoma (epithelial) and SH-SY5Y neuroblastoma cell lines to BoNT/A complex were investigated using microarray analysis. In HT-29 cells, 167 genes were up-regulated while 60 genes were down-regulated, whereas in SH-SY5Y cells about 223 genes were up-regulated and 18 genes were down-regulated. Modulation of genes and pathways involved in neuroinflammatory, ubiquitin-proteasome degradation, phosphatidylinositol, calcium signaling in SH-SY5Y cells, and genes relevant to focal adhesion, cell adhesion molecules, adherens and gap junction related pathways in HT-29 cells suggest a massive host response to BoNT/A. A clear differential response in epithelial and neuronal cells indicates that the genes affected may play a distinct role in BoNTs cellular mode of action, involving these two types of host cells.

Molecular Basis of Activation of Endopeptidase Activity of Botulinum Neurotoxin Type E

Botulinum neurotoxins (BoNTs) are a group of large proteins that are responsible for the clinical syndrome of botulism. The seven immunologically distinct serotypes of BoNTs (A-G), each produced by various strains of Clostridium botulinum, act on the neuromuscular junction by blocking the release of the neurotransmitter acetylcholine, thereby resulting in flaccid muscle paralysis. BoNTs are synthesized as single inactive polypeptide chains that are cleaved by endogenous or exogenous proteases to generate the active dichain form of the toxin. Nicking of the single chain BoNT/E to the dichain form is associated with 100-fold increase in toxicity. Here we investigated the activation mechanism of botulinum neurotoxin type E upon nicking and subsequent reduction of disulfide bond. It was observed that nicking of BoNT/E significantly enhances its endopeptidase activity and that at the physiological temperature of 37 degrees C the reduced form of nicked BoNT/E adopts a dynamically flexible conformation resulting from the exposure of hydrophobic segments and facilitating optimal cleavage of its substrate SNAP-25. Such reduction-induced increase in the flexibility of the polypeptide folding provides a rationale for the mechanism of BoNT/E endopeptidase against its intracellular substrate, SNAP-25, and complements current understanding of the mechanistics of interaction between the substrate and BoNT endopeptidase.

Expression, purification and comparative characterisation of enzymatically deactivated recombinant botulinum neurotoxin type A

Botulinum Neurotoxin (BoNT) is responsible for botulism, a severe and often deadly disease. Light chain of BoNT behaves as endopeptidase, cleaving the SNARE proteins, and inhibits the neurotransmitter release. A double-mutant E224A/E262A full-length BoNT Type A was successfully cloned and expressed in E. coli. The purified protein lacks the endopeptidase activity involved in the toxic action, and is structurally compatible with the native BoNT/A. Thus this molecule not only can be used as a safe surrogate for study of BoNT, but also can be potentially used as an antidote against botulism, and as a vaccine candidate for botulism.

Botulinum neurotoxin: unique folding of enzyme domain of the most-poisonous poison

Botulinum neurotoxin (BoNT), the most toxic substance known to mankind, is the first example of the fully active molten globule state. To understand its folding mechanism, we performed urea denaturation experiments and theoretical modeling using BoNT serotype A (BoNT/A). We found that the extent of BoNT/A denaturation from the native state (N) shows a nonmonotonic dependence on urea concentration indicating a unique multistep denaturation process, N → I1 I2 U, with two intermediate states I1 and I2. BoNT/A loses almost all its secondary structure in 3.75 M urea (I1), yet it displays a native-like secondary structure in 5 M urea (I2). This agrees with the results of theoretical modeling, which helped to determine the molecular basis of unique behavior of BoNT/A in solution. Except for I2, all the states revert back to full enzymatic activity for SNAP-25 including the unfolded state U stable in 7 M urea. Our results stress the importance of structural flexibility in the toxin’s mechanism of survival and action, an unmatched evolutionary trait from billion-year-old bacteria, which also correlates with the long-lasting enzymatic activity of BoNT inside neuronal cells. BoNT/A provides a rich model to explore protein folding in relation to functional activity.

Differential role of molten globule and protein folding in distinguishing unique features of botulinum neurotoxin

Botulinum neurotoxins (BoNTs) are proteins of great interest not only because of their extreme toxicity but also paradoxically for their therapeutic applications. All the known serotypes (A-G) have varying degrees of longevity and potency inside the neuronal cell. Differential chemical modifications such as phosphorylation and ubiquitination have been suggested as possible mechanisms for their longevity, but the molecular basis of the longevity remains unclear. Since the endopeptidase domain (light chain; LC) of toxin apparently survives inside the neuronal cells for months, it is important to examine the structural features of this domain to understand its resistance to intracellular degradation. Published crystal structures (both botulinum neurotoxins and endopeptidase domain) have not provided adequate explanation for the intracellular longevity of the domain. Structural features obtained from spectroscopic analysis of LCA and LCB were similar, and a PRIME (PReImminent Molten Globule Enzyme) conformation appears to be responsible for their optimal enzymatic activity at 37°C. LCE, on the other hand, was although optimally active at 37°C, but its active conformation differed from the PRIME conformation of LCA and LCB. This study establishes and confirms our earlier finding that an optimally active conformation of these proteins in the form of PRIME exists for the most poisonous poison, botulinum neurotoxin. There are substantial variations in the structural and functional characteristics of these active molten globule related structures among the three BoNT endopeptidases examined. These differential conformations of LCs are important in understanding the fundamental structural features of proteins, and their possible connection to intracellular longevity could provide significant clues for devising new countermeasures and effective therapeutics.

The Botulinum Neurotoxin Complex and the Role of Ancillary Proteins

All seven known serotypes of botulinum neurotoxin (BoNT) are produced in the form of a complex with a group of neurotoxin-associated proteins (NAPs). The BoNT complex is encoded by a gene cluster regulated by its own transcription factor, and the proteins coded by polycistronic messenger ribonucleic acid (mRNA) self-assemble into complexes of 300–900 kDa. Types A, B, C, D, and G complexes contain hemagglutinin (HA), whereas types E and F complexes do not contain HA. Sequence homology among respective BoNTs and NAPs range from 55.3 to 98.5 %, and all the proteins in the BoNT complex belong to a stable class of protein with high longevity inside mammalian cells. A new 250-kDa protein (P-250) with high immunogenicity has been identified in the BoNT/A complex which is not part of the neurotoxin gene cluster. The 33-kDa hemagglutinin (HA-33) is the most abundant NAP. The HA-33 is protease resistant and is highly immunogenic. HA-33 appears to play an important role in the translocation of the neurotoxin across the gut wall, enhancing the endopeptidase activity of BoNT and protection of BoNT against proteases. The role of other NAPs is not as clear, and their role in the biology of the bacteria is not understood at all. BoNT complexes are used as therapeutic product, although a therapeutic product without NAPs appears to retain the properties of the complex-based products. NAPs in therapeutic products may have other subtle long-term effects which need to be investigated.

The botulinum toxin as a therapeutic agent: molecular and pharmacological insights

Botulinum neurotoxins (BoNTs), the most potent toxins known to mankind, are metal- loproteases that act on nerve-muscle junctions to block exocytosis through a very specific and exclusive endopeptidase activity against soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins of presynaptic vesicle fusion machinery. This very ability of the toxins to produce flaccid muscle paralysis through chemical denervation has been put to good use, and these potentially lethal toxins have been licensed to treat an ever expanding list of medical disorders and more popularly in the field of esthetic medicine. In most cases, therapeutic BoNT preparations are high-molecular-weight protein complexes consisting of BoNT, complexing proteins, and excipients. There is at least one isolated BoNT, which is free of complexing proteins in the market (Xeomin ® ). Each commercially available BoNT formulation is unique, differing mainly in molecular size and composition of complexing proteins, biological activity, and antigenicity. BoNT serotype A is marketed as Botox ® , Dysport ® , and Xeomin ® , while