Project description:During the development of the nervous system embryonic neurons are incorporated into neural networks that underlie behaviour. For example, during embryogenesis in Drosophila, motor neurons in every body segment are wired into the circuitry that drives the simple peristaltic locomotion of the larva. Very little is known about the way in which the necessary central synapses are formed in such a network or how their properties are controlled. One possibility is that presynaptic and postsynaptic elements form relatively independently of each other. Alternatively, there might be an interaction between presynaptic and postsynaptic neurons that allows for adjustment and plasticity in the embryonic network. Here we have addressed this issue by analysing the role of synaptic transmission in the formation of synaptic inputs onto identified motorneurons as the locomotor circuitry is assembled in the Drosophila embryo. We targeted the expression of tetanus toxin light chain (TeTxLC) to single identified neurons using the GAL4 system. TeTxLC prevents the evoked release of neurotransmitter by enzymatically cleaving the synaptic-vesicle-associated protein neuronal-Synaptobrevin (n-Syb) [1]. Unexpectedly, we found that the cells that expressed TeTxLC, which were themselves incapable of evoked release, showed a dramatic reduction in synaptic input. We detected this reduction both electrophysiologically and ultrastructurally.

Project description:BACKGROUND:Light chain (LC) and heavy chain carboxyterminal subdomain (HCC) fragments are the most important parts of tetanus neurotoxin (TeNT) which play key roles in toxicity and binding of TeNT, respectively. In the present study, these two fragments were cloned and expressed in a prokaryotic system and their identity was confirmed using anti-TeNT specific polyclonal and monoclonal antibodies. METHODS:LC and HCC gene segments were amplified from Clostridium tetani genomic DNA by PCR, cloned into pET28b(+) cloning vector and transformed in Escherichia coli (E. coli) BL21(DE3) expression host. Recombinant proteins were then purified through His-tag using Nickel-based chromatography and characterized by SDS-PAGE, Western blotting and ELISA techniques. RESULTS:Recombinant light chain and HCC fragments were successfully cloned and expressed in (E. coli) BL21 (DE3). Optimization of the induction protocol resulted in production of high levels of HCC (~35% of total bacterial protein) and to lesser extends of LC (~5%). Reactivity of the His-tag purified proteins with specific polyclonal and monoclonal antibodies confirmed their renatured structure and identity. CONCLUSION:Our results indicate successful cloning and production of recombinant LC and HCC fragments of TeNT. These two recombinant proteins are potentially useful tools for screening and monitoring of anti-TeNT antibody response and vaccine production.

Project description:We developed a novel strategy for conditional silencing of synaptic transmission in specific neuronal types in transgenic animals. We generated a recombinant protein termed immuno-tetanus toxin (ITet), which contains a monoclonal antibody variable region for human interleukin-2 receptor alpha-subunit (IL-2Ralpha) fused to tetanus toxin light chain. ITet was designed to transiently suppress transmitter release from target neurons genetically engineered to express human IL-2Ralpha via proteolytic cleavage of vesicle-associated membrane protein-2 (VAMP-2). The in vivo actions of ITet were investigated by using mutant mice that express IL-2Ralpha in striatal neurons under the control of the gene encoding dopamine D(2) receptor. Unilateral ITet injection into the striatum induced rotational behavior in the mutant mice and the rotations gradually reversed to the normal level. The behavioral alteration was accompanied by a transient decrease in the striatal VAMP-2 level and depolarization-evoked transmitter release in synaptic target region. However, ITet injection caused no structural change in striatal cells and nerve terminals in the mutants. These data indicate that ITet acts on striatal neurons bearing human IL-2Ralpha and temporally reduces their VAMP-2 content, thereby causing the blockade of transmitter release. Our ITet technology provides a useful approach for inducible and reversible control of synaptic transmission in specific neuronal types in the brain.

Project description:Tetanus toxin is a powerful neurotoxin known to inhibit neurotransmitter release. The tetanus toxin light chain is a metalloprotease that cleaves some members of the synaptobrevin gene family with high specificity. Here, we report the expression of a synthetic gene encoding the tetanus toxin light chain in the seminiferous epithelium of transgenic mice. Spermatogenesis was severely impaired and mature spermatozoa were completely absent. Late spermatids exhibited pleomorphic shapes and acrosomal distortions. The number of Leydig cells was greatly increased. In situ hybridization analysis revealed that the toxin acts on Sertoli cells. Affected cells exhibited an aberrant distribution of actin filaments and many cells contained large vacuoles. Our results demonstrate that tetanus toxin is active in non-neuronal cells and suggest an important function for members of the synaptobrevin gene family during the late stages of spermatogenesis.

Project description:An approach for enhancing antibody affinity is to engineer Chelating Recombinant Antibodies (CRAbs) which consist of two tandemly linked single-chain Fvs (scFvs) that bind to distinct non-overlapping epitopes on the antigen molecule leading to a synergistic decrease in K(D). In order to develop this technology, the aim of this present study was to identify scFvs which can simultaneously bind to the tetanus toxin heavy chain C-terminal sub-domain (H(c)), characterise their bio-physical properties and determine their functional efficacy. Over 50 antibodies specific for Hc were isolated from a human scFv phagemid library and found to bind specifically to the C-terminal sub-domain of H(c) (H(c)C clones), the N-terminal sub-domain (HcN clones) or junctional epitopes on the whole Hc fragment only (HcJ clones). Fifteen clones were assayed in a pairwise competition binding study. The revealed, with few exceptions, that H(c)C clones were able to simultaneously bind to the toxin with H(c)N or H(c)J clones. All other combinations competed for binding. Interestingly, we also observed cooperative binding with many non-competing scFv pairings which may impact upon the binding mechanism of CRAbs. We found that 14/15 clones neutralised toxin activity in a ganglioside binding assay and this effect was strongly related to affinity. This included clones that did not bind to the H(c)C sub-domain which is responsible for direct interaction with gangliosides on nerve cells. For 7 scFvs that underwent further characterisation we found broad variations in propensity for multimerisation, affinity and potency. The diverse array of clones characterised in this paper can be used to construct CRAbs and will prove useful in further characterisation of toxin biology and in measuring the effects of polyclonal antibody therapy.

Project description:Background: Synaptic transmission is required for functional maturation of the CNS and to induce gene transcription involved in neuronal plasticity. Our aim is to identify genes that are transcriptionally regulated by synaptic transmission during development. cDNA microarrays will be used to compare gene expression in normal embryos and embryos with no synaptic transmission. Using the Gal4 UAS system, the tetanus toxin light fragment (TET) will be expressed throughout the nervous system. The effects of TET are well characterised: the synaptic protein n-Synaptobrevin is cleaved, blocking evokes vesicle fusion in TET expressing neurons and as a result synaptic transmission is blocked. Embryos expressing an inactive, mutant version of TET (iTET) show no detectable phenotype. Thus a comparison of gene expression in iTET expressing embryos and TET expressing embryos focuses our screen cleanly and specifically on genes that are regulated by synaptic transmission. At the end of larval life, during metamorphosis, there is a second phase of nervous system development with the same requirement for neural circuit differentiation and maturation as in the embryo. We will compare gene expression in TET expressing and iTET expressing pupae to identify genes which are regulated by synaptic transmission in this second phase of nervous system development. We will focus our analysis on genes which are similarly regulated in both systems. Plan: elav Gal4 (expressed in all the neurons) for the embryos and Heat Shock Gal4 (which allows a temporally controlled expression) for the pupae are used to drive UAS TET and UAS iTET throughout the nervous system. Crosses are set up with flies homozygous for Gal4 or UAS transgenes, so that all the progeny have the same genotype. Total RNA is extracted from 500 carefully staged embryos that have been collected at the time of hatching. Pupae are heat shocked at 24 hours after puparium formation, and heads are then collected 5 days after puparium formation. TET expressing pupae are paralysed but morphologically normal whereas iTET expressing pupae emerge as normal adults. Total RNA will be extracted from 250 heads of each genotype. Probes made from TET and iTET expressing embryos extracts will be hybridised together to the chip and so will be probes made from TET and iTET expressing pupae extracts. Genes regulated in both systems will be compared together.

Project description:The clostridial neurotoxins (CNTs), botulinum toxin and tetanus toxin, are the most toxic proteins for humans. Neurotoxicity is based upon the specificity of the CNTs for neural host receptors and substrates. CNTs are organized into three domains, a Light Chain (LC) that is a metalloprotease and a Heavy Chain (HC) that has two domains, an N-terminal LC translocation domain (HCN) and a C-terminal receptor binding domain (HCC). While catalysis and receptor binding functions of the CNTs have been developed, our understanding of LC translocation is limited. This is due to the intrinsic complexity of the translocation process and limited tools to assess the step-by-step events in LC translocation. Recently, we developed a novel, cell-based TT-reporter to measure LC translocation as the translocation of a ?-lactamase reporter across a vesicle membrane in neurons. Using this approach, we identified a role for a cis-Loop, located within the HCN, in LC translocation. In this commentary, we describe our current understanding of how CNTs mediate LC translocation and place the role of the cis-Loop in the LC translocation process relative to other independent functions that have been implicated in LC translocation. Understanding the basis for LC translocation will enhance the use of CNTs in vaccine development and as human therapies.

Project description:Clostridial botulinum neurotoxins (BoNTs) inhibit synaptic exocytosis; intoxication requires the di-chain protein to undergo conformational changes in response to pH and redox gradients across the endosomal membrane with consequent formation of a protein-conducting channel by the heavy chain (HC) that translocates the light chain (LC) protease into the cytosol, colocalizing it with the substrate SNARE proteins. We investigate the dynamics of protein translocation across membranes using a sensitive single-molecule assay to track translocation events with millisecond resolution on lipid bilayers and on membrane patches of Neuro 2A cells. Translocation of BoNT/A LC by the HC is observed in real time as changes of channel conductance: the channel is occluded by the light chain during transit, and open after completion of translocation and release of cargo, acting intriguingly similar to the protein-conducting/translocating channels of the endoplasmic reticulum, mitochondria, and chloroplasts. Our findings support the notion of an interdependent, tight interplay between the HC transmembrane chaperone and the LC cargo that prevents LC aggregation and dictates the productive passage of cargo through the channel and completion of translocation. The protein-conducting channel of BoNT, a key element in the process of neurotoxicity, emerges therefore as a target for antidote discovery - a novel paradigm of paramount significance to health science and biodefense.

Project description:Quantitative comparison of the amino acid compositions of the heavy and light chains of tetanus toxin by the method of Cornish-Bowden [(1983) Methods Enzymol. 91, 60-75)] suggests strongly that there is sequence homology between the two chains and that the heavy chain has two similar halves. Examination (by electrophoresis in polyacrylamide gels in the presence of sodium dodecyl sulphate) of peptides produced from the chains by proteolytic cleavage supports this idea.

Project description:1. Charge-shift electrophoresis showed that cholera toxin and its subunits have no hydrophobic surfaces. 2. Amino-acid composition and sequence data suggested that the proteins have no masked hydrophobic regions. 3. The A subunit of cholera toxin may interact with polar molecules in the membrane to exert its effect inside the cell. 4. The only hydrophobic part of tetanus toxin was the H-chain.