Structure and function of Buthus eupeus scorpion neurotoxins

At present the investigation of the complex mechanism of the signal conductance between nerve cells and their target organ is closely connected with application of neurotoxins as a valuable tool for study of important sites involved in nerve transmission. Particular interest is attributed to neurotoxins from scorpion venoms which slow down the inactivation rate of fast sodium channels of the excitable membrane. Fifteen different toxins have been isolated from Buthus eupeus scorpion venom by means of the combination of gel and ion exchange chromatography. The homologous insectotoxins I₁, I₃, I₄, and I₅ belong to the new structural type of scorpion toxins. The essential features of these toxins are low molecular weight (ca. 4000) and the presence of two or three methionine residues in their amino acid compositions. The complete amino acid sequences of two insectotoxins and one mammalian toxin have been estimated. All mammalian neurotoxins in concentration from 10^?9M to 10^?7M slow down the inactivation rate of fast sodium channels. The direct covalent binding of photosensitive radioactive neurotoxin derivatives presents one of the most effective approaches to the localization of the functionally important components of the fast sodium channels. Thus far 2,4-dinitro-5-fluorophenylazide has been used for chemical modification of the mammalian neurotoxin M₁₀. The prepared monosubstituted photosensitive neurotoxin derivative possessed a high biological activity according to the voltage clamp data. The neurotoxin derivative has been iodinated by ¹²⁵I, the resulted product being both radioactively and photoaffinity labeled. Both native neurotoxin M₁₀ and sea anemone toxin competitively inhibit the reception of the scorpion toxin derivative by rat brain synaptosomes. It was shown that covalent toxin-receptor complexes are composed of two protein components with molecular weights 76,000 and 51,000, being near equal for synaptosomes, neuroblastoma cells, and crab nerve plasma membranes.     

Interaction of polypeptide neurotoxins with a receptor site associated with voltage-sensitive sodium channels

Anthopleurin A, a polypeptide toxin from the Pacific sea anemone Anthopleura xanthogrammica, enhances persistent activation of voltage-sensitive sodium channels by the alkaloid toxins veratridine and batrachotoxin with K0.5 = 20 nM. This effect is inhibited by depolarization. There is a close correlation between enhancement of sodium channel activation and block of [125I]scorpion toxin binding by unlabeled scorpion toxin, sea anemone toxin II from Anemonia sulcata, and Anthopleurin A, indicating that these three polypeptide toxins interact with a common receptor site in modifying sodium channel function. Photo-activable derivatives of scorpion toxin label a single Mr approximately 250,000 polypeptide chain at the polypeptide toxin receptor site. Labeling is blocked by unlabeled scorpion toxin or depolarization and is not observed in variant neuroblastoma clones, which lack sodium channels. These results identify a protein component of the polypeptide toxin receptor site of voltage-sensitive sodium channels.     

Brevetoxin derivatives that inhibit toxin activity

BACKGROUND: The brevetoxins are marine neurotoxins that interfere with the normal functions of the voltage-gated Na(+) channel. We have identified two brevetoxin derivatives that do not exhibit pharmacological properties typical of the brevetoxins and that function as brevetoxin antagonists. RESULTS: PbTx-3 and benzoyl-PbTx-3 elicited Na(+) channel openings during steady-state depolarizations; however, two PbTx-3 derivatives retained their ability to bind to the receptor, but did not elicit Na(+) channel openings. alpha-Naphthoyl-PbTx-3 acted as a PbTx-3 antagonist but did not affect Na(+) channels that were not exposed to PbTx-3. beta-Naphthoyl-PbTx-3 reduced openings of Na(+) channels that were not exposed to PbTx-3. CONCLUSIONS: Some modifications to the brevetoxin molecule do not alter either the binding properties or the activity of these toxins. Larger modifications to the K-ring sidechain do not interfere with binding but have profound effects on their pharmacological properties. This implies a critical function for the K-ring sidechain of the native toxin.     

Electrospray mass spectrometry of neuac oligomers associated with the c fragment of the tetanus toxin

The Clostridial neurotoxins, botulinum and tetanus, gain entry into motor neurons by binding to the sialic or N-acetylneuraminic acid (NeuAc) residues of gangliosides and specific protein receptors attached to the cell's surface. While the C-fragment of tetanus toxin (TetC) has been identified to be the ganglioside binding domain, remarkably little is known about how this domain discriminates between the structural features of different gangliosides. We have used electrospray ionization mass spectrometry (ESI-MS) to examine the formation of complexes between TetC and carbohydrates containing NeuAc groups to determine how NeuAc residues contribute to ganglioside binding. ESI-MS was used to obtain an estimate of the dissociation constants (KD values) for TetC binding to a number of related NeuAc-containing carbohydrates (sialyllactose and disialyllactose), as well as six (NeuAc)n oligomers (n = 1-6). KD values were found to range between approximately 10-35 microM. The strength of the interactions between the C fragment and (NeuAc)n are consistent with the topography of the targeting domain of tetanus toxin and the nature of its carbohydrate binding sites. These results suggest that the targeting domain of tetanus toxin contains two binding sites that can accommodate NeuAc (or a dimer) and that NeuAc may play an important role in ganglioside binding and molecular recognition, a process critical for normal cell function and one frequently exploited by toxins, bacteria, and viruses to facilitate their entrance into cells.     

Quantitative mass spectrometry for bacterial protein toxins--a sensitive, specific, high-throughput tool for detection and diagnosis

Matrix-assisted laser-desorption time-of-flight (MALDI-TOF) mass spectrometry (MS) is a valuable high-throughput tool for peptide analysis. Liquid chromatography electrospray ionization (LC-ESI) tandem-MS provides sensitive and specific quantification of small molecules and peptides. The high analytic power of MS coupled with high-specificity substrates is ideally suited for detection and quantification of bacterial enzymatic activities. As specific examples of the MS applications in disease diagnosis and select agent detection, we describe recent advances in the analyses of two high profile protein toxin groups, the Bacillus anthracis toxins and the Clostridium botulinum neurotoxins. The two binary toxins produced by B. anthracis consist of protective antigen (PA) which combines with lethal factor (LF) and edema factor (EF), forming lethal toxin and edema toxin respectively. LF is a zinc-dependent endoprotease which hydrolyzes specific proteins involved in inflammation and immunity. EF is an adenylyl cyclase which converts ATP to cyclic-AMP. Toxin-specific enzyme activity for a strategically designed substrate, amplifies reaction products which are detected by MALDI-TOF-MS and LC-ESI-MS/MS. Pre-concentration/purification with toxin specific monoclonal antibodies provides additional specificity. These combined technologies have achieved high specificity, ultrasensitive detection and quantification of the anthrax toxins. We also describe potential applications to diseases of high public health impact, including Clostridium difficile glucosylating toxins and the Bordetella pertussis adenylyl cyclase.     

Ligand-binding assays for cyanobacterial neurotoxins targeting cholinergic receptors

Toxic cyanobacterial blooms are a threat to public health because of the capacity of some cyanobacterial species to produce potent hepatotoxins and neurotoxins. Cyanobacterial neurotoxins are involved in the rapid death of wild and domestic animals by targeting voltage gated sodium channels and cholinergic synapses, including the neuromuscular junction. Anatoxin-a and its methylene homologue homoanatoxin-a are potent agonists of nicotinic acetylcholine receptors. Since the structural determination of anatoxin-a, several mass spectrometry-based methods have been developed for detection of anatoxin-a and, later, homoanatoxin-a. Mass spectrometry-based techniques provide accuracy, precision, selectivity, sensitivity, reproducibility, adequate limit of detection, and structural and quantitative information for analyses of cyanobacterial anatoxins from cultured and environmental cyanobacterial samples. However, these physicochemical techniques will only detect known toxins for which toxin standards are commercially available, and they require highly specialized laboratory personnel and expensive equipment. Receptor-based assays are functional methods that are based on the mechanism of action of a class of toxins and are thus, suitable tools for survey of freshwater reservoirs for cyanobacterial anatoxins. The competition between cyanobacterial anatoxins and a labelled ligand for binding to nicotinic acetylcholine receptors is measured radioactively or non-radioactively providing high-throughput screening formats for routine detection of this class of neurotoxins. The mouse bioassay is the method of choice for marine toxin monitoring, but has to be replaced by fully validated functional methods. In this paper we review the ligand-binding assays developed for detection of cyanobacterial and algal neurotoxins targeting the nicotinic acetylcholine receptors and for high-throughput screening of novel nicotinic agents.     

Isolation and characterization of a novel lepidopteran-selective toxin from the venom of South Indian red scorpion, Mesobuthus tamulus

Background

Scorpion venom contains insect and mammal selective toxins. We investigated the venom of the South Indian red scorpion, Mesobuthus tamulus for the purpose of identifying potent insecticidal peptide toxins.

Results

A lepidopteran-selective toxin (Buthus tamulus insect toxin; ButaIT) has been isolated from this venom. The primary structure analysis reveals that it is a single polypeptide composed of 37 amino acids cross-linked by four disulfide bridges with high sequence homology to other short toxins such as Peptide I, neurotoxin P2, Lqh-8/6, chlorotoxin, insectotoxin I5A, insect toxin 15 and insectotoxin I1. Three dimensional modeling using Swiss automated protein modeling server reveals that this toxin contains a short α-helix and three antiparallel β-strands, similar to other short scorpion toxins. This toxin is selectively active on Heliothis virescens causing flaccid paralysis but was non-toxic to blowfly larvae and mice.

Conclusion

This is the first report of a Heliothine selective peptide toxin. Identification of diverse insect selective toxins offer advantages in employing these peptides selectively for pest control.     

Computer modeling of binding of diverse weak toxins to nicotinic acetylcholine receptors

Weak toxins are the "three-fingered" snake venoms toxins grouped together by having an additional disulfide in the N-terminal loop I. In general, weak toxins have low toxicity, and biological targets have been identified for some of them only, recently by detecting the effects on the nicotinic acetylcholine receptors (nAChR). Here the methods of docking and molecular dynamics simulations are used for comparative modeling of the complexes between four weak toxins of known spatial structure (WTX, candoxin, bucandin, gamma-bungarotoxin) and nAChRs. WTX and candoxin are those toxins whose blocking of the neuronal alpha7- and muscle-type nAChR has been earlier shown in binding assays and electrophysiological experiments, while for the other two toxins no such activity has been reported. Only candoxin and WTX are found here to give stable solutions for the toxin-nAChR complexes. These toxins appear to approach the binding site similarly to short alpha-neurotoxins, but their final position resembles that of alpha-cobratoxin, a long alpha-neurotoxin, in the complex with the acetylcholine-binding protein. The final spatial structures of candoxin and WTX complexes with the alpha7 neuronal or muscle-type nAChR are very similar and do not provide immediate answer why candoxin has a much higher affinity than WTX, but both of them share a virtually irreversible mode of binding to one or both these nAChR subtypes. Possible explanation comes from docking and MD simulations which predict fast kinetics of candoxin association with nAChR, no gross changes in the toxin conformation (with smaller toxin flexibility on alpha7 nAChR), while slow WTX binding to nAChR is associated with slow irreversible rearrangement both of the tip of the toxin loop II and of the binding pocket residues locking finally the toxin molecule. Computer modeling showed that the additional disulfide in the loop I is not directly involved in receptor binding of WTX and candoxin, but it stabilizes the structure of loop I which plays an important role in toxin delivery to the binding site. In summary, computer modeling visualized possible modes of binding for those weak toxins which interact with the nAChR, provided no solutions for those weak toxins whose targets are not the nAChRs, and demonstrated that the additional disulfide in loop I cannot be a sound criteria for joining all weak toxins into one group; the conclusion about the diversity of weak toxins made from computer modeling is in accord with the earlier phylogenetic analysis.     

Moving pieces in a proteomic puzzle: mass fingerprinting of toxic fractions from the venom of Tityus serrulatus (Scorpiones, Buthidae).

Scorpion venoms are very complex mixtures of molecules, most of which are peptides that display different kinds of biological activity. These venoms have been studied in the light of their pharmacological targets and their constituents are able to bind specifically to a variety of ionic channels located in prey tissues, resulting in neurotoxic effects. Toxins that modulate Na(+), K(+), Ca(++) and Cl(-) currents have been described in scorpion venoms. Mass spectrometry was employed to analyze toxic fractions from the venom of the Brazilian scorpion Tityus serrulatus in order to shed light on the molecular composition of this venom and to facilitate the search for novel pharmacologically active compounds. T. serrulatus venom was first subjected to gel filtration to separate its constituents according to their molecular size. The resultant fractions II and III, which account for 90 and 10% respectively of the whole venom toxic effect, were further analyzed by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS), on-line liquid chromatography/electrospray mass spectrometry (LC/ESMS) and off-line LC/MALDI-TOFMS in order to establish their mass fingerprints. The molecular masses in fraction II were predominantly between 6500 and 7500 Da. This corresponds to long-chain toxins that mainly act on voltage-gated Na(+) channels. Fraction III is more complex and predominantly contained molecules with masses between 2500 and 5000 Da. This corresponds to the short-chain toxin family, most of which act on K(+) channels, and other unknown peptides. Finally, we were able to measure the molecular masses of 380 different compounds present in the two fractions investigated. To our knowledge, this is the largest number of components ever detected in the venom of a single animal species. Some of the toxins described previously from T. serrulatus venom could be detected by virtue of their molecular masses. The interpretation of this large set of data has provided us with useful proteomic information on the venom, and the implications of these findings are discussed.     

Chemical Synthesis, 3D Structure,and ASIC Binding Site of the Toxin Mambalgin‐2

Mambalgins are a novel class of snake venom components that exert potent analgesic effects mediated through the inhibition of acid‐sensing ion channels (ASICs). The 57‐residue polypeptide mambalgin‐2 (Ma‐2) was synthesized by using a combination of solid‐phase peptide synthesis and native chemical ligation. The structure of the synthetic toxin, determined using homonuclear NMR, revealed an unusual three‐finger toxin fold reminiscent of functionally unrelated snake toxins. Electrophysiological analysis of Ma‐2 on wild‐type and mutant ASIC1a receptors allowed us to identify α‐helix 5, which borders on the functionally critical acidic pocket of the channel, as a major part of the Ma‐2 binding site. This region is also crucial for the interaction of ASIC1a with the spider toxin PcTx1, thus suggesting that the binding sites for these toxins substantially overlap. This work lays the foundation for structure–activity relationship (SAR) studies and further development of this promising analgesic peptide.     

Toxins as Tools in Neurochemistry

Neurotoxins have evolved as molecules targeted specifically against molecules with an important function in the nervous system. Because of their selectivity they have been used as probes for detecting and characterizing key proteins of the nerve cell. Ion channels involved in the propagation of the action potential, proteins of presynaptic neurotransmitter exocytosis, and most importantly, neurotransmitter receptors have been and are presently being analyzed, in some cases already at atomic level by a combination of the tools of neurotoxins, molecular biology, and patch clamp electrophysiology. In this review a selection of these toxins is presented, together with their targets in the nervous system. Special emphasis is given to the recent breakthroughs in our understanding of the mechanism of action of tetanus and botulinum toxins and to the neurotoxins ranging from the plant alkaloid strychnine to the peptide toxins from poisonous snakes, which were fundamental in elucidating ligand-gated ion channels like the glycine and nicotinic acetylcholine receptors.     

Chemical Synthesis, 3D Structure,and ASIC Binding Site of the Toxin Mambalgin‐2

Mambalgins are a novel class of snake venom components that exert potent analgesic effects mediated through the inhibition of acid‐sensing ion channels (ASICs). The 57‐residue polypeptide mambalgin‐2 (Ma‐2) was synthesized by using a combination of solid‐phase peptide synthesis and native chemical ligation. The structure of the synthetic toxin, determined using homonuclear NMR, revealed an unusual three‐finger toxin fold reminiscent of functionally unrelated snake toxins. Electrophysiological analysis of Ma‐2 on wild‐type and mutant ASIC1a receptors allowed us to identify α‐helix 5, which borders on the functionally critical acidic pocket of the channel, as a major part of the Ma‐2 binding site. This region is also crucial for the interaction of ASIC1a with the spider toxin PcTx1, thus suggesting that the binding sites for these toxins substantially overlap. This work lays the foundation for structure–activity relationship (SAR) studies and further development of this promising analgesic peptide.     

Anthrax fusion protein therapy of cancer

Most patients with cancer are treated with chemotherapy but die from progressive disease or toxicities of therapy. Current chemotherapy regimens primarily use cytotoxic drugs which damage cell DNA or impair cell proliferation in both malignant and normal tissues. After several treatment courses, the patients' tumor cells often overexpress multi-drug resistance genes which prevent further tumor cytoreduction. Novel agents which can kill such resistant tumor cells are needed. One such class of agents are targeted peptide toxins. Targeted peptide toxins consist of peptide toxins covalently linked to tumor selective peptide ligands. These molecules bind tumor cell surface receptors, internalize, and facilitate transfer of the toxin catalytic domains to the cytosol. Once in the cytosol, the enzyme activity leads to cell death. A number of plant, bacterial and fungal toxins have been used, and clinical trials with several of these have produced complete remissions in chemoresistant neoplasms. Nevertheless, there is a continuing need for novel targeted toxins. Many patients have pre-existing antibodies against the currently clinically used toxins and many toxins are inactive when used for myeloid malignancies where internalized proteins are rapidly routed and degraded in lysosomes. Anthrax toxins are the cytotoxic components of Bacillus anthracis. While the bacteria has been the source of serious illness, deaths and global anxieties related to past or future bioterrorism, the isolated toxins do not pose public health hazards. In fact, toxin treated patients will likely develop protective antibodies. Anthrax toxin is an excellent choice for tumor cell surface targeting. Other than U.S. military personnel immunized during the Gulf War, most people lack pre-existing antibodies. This may change in the future due to threats of additional terrorist acts, but for the present few patients will have antibodies to anthrax proteins. The separate subunits for binding, translocation and cell killing facilitate genetic engineering to yield tumor-specific cell killing. The toxins are more potent than most of the other peptide toxins and may yield highly efficacious targeted molecules. This essay will review anthrax toxin structure-function, preliminary experiments with re-targeted anthrax toxin and potential designs for new ligand-anthrax therapeutics.     

Amino-acid composition and terminal amino acids of the toxins of the venom of the central Asian cobra

Conclusions 1. The amino-acid compositions of two neurotoxins from the venom of the Central Asian cobra have been established. The N-terminal amino-acid residue of toxin (I) is isoleucine and that of toxin (II) leucine. There is the same sequence from the C-end of both toxins — Cys-Asn-Asn-COOH.2. The role of the individual functional groups (-amino groups and disulfide bridges) of the amino acids in the lethal action of the toxins has been investigated and discussed.Institute of Biochemistry, Academy of Sciences of the Uzbek SSR. Translated from Khimiya Prirodnykh Soedinenii, No. 1, pp. 62–64, January–February, 1974.     

A Protein‐Based Pentavalent Inhibitor of the Cholera Toxin B‐Subunit

Protein toxins produced by bacteria are the cause of many life‐threatening diarrheal diseases. Many of these toxins, including cholera toxin (CT), enter the cell by first binding to glycolipids in the cell membrane. Inhibiting these multivalent protein/carbohydrate interactions would prevent the toxin from entering cells and causing diarrhea. Here we demonstrate that the site‐specific modification of a protein scaffold, which is perfectly matched in both size and valency to the target toxin, provides a convenient route to an effective multivalent inhibitor. The resulting pentavalent neoglycoprotein displays an inhibition potency (IC₅₀) of 104 pM for the CT B‐subunit (CTB), which is the most potent pentavalent inhibitor for this target reported thus far. Complexation of the inhibitor and CTB resulted in a protein heterodimer. This inhibition strategy can potentially be applied to many multivalent receptors and also opens up new possibilities for protein assembly strategies.     

Staphylococcus aureus bicomponent gamma-hemolysins, HlgA, HlgB, and HlgC, can form mixed pores containing all components

Staphylococcal gamma-hemolysins are bicomponent toxins forming a protein family with leucocidins and alpha-toxin. Two active toxins (AB and CB) can be formed combining one of the class-S components, HlgA or HlgC, with the class-F component HlgB. These two gamma-hemolysins form pores with marked similarities to alpha-toxin in terms of conductance, nonlinearity of the current-voltage curve, and channel stability in the open state. AB and CB pores, however, are cation-selective, whereas alpha-toxin is anion-selective. gamma-Hemolysins' pores are hetero-oligomers formed by three or four copies of each component (indicated as 3A3B and 3C3B or 4A4B and 4C4B). Point mutants located on a beta-strand of the class-S component that forms part of the protomer-protomer contact region can prevent oligomer assembly. Interestingly, these mutants inhibit growth of pores formed not only by their natural components but also by nonstandard components. This lead to the hypothesis that mixed ABC pores could also be formed. By studying the conductance of pores, assembled in the presence of all three components (in different ratios), it was observed that the magnitudes expected for mixed pores were, indeed, present. We conclude that the gamma-hemolysin/leucocidin bicomponent toxin family may form a larger than expected number of active toxins by cross-combining various S and F components.     

疑似蛇毒液样品的纳升级超高效液相色谱-高分辨质谱分析鉴定

针对5个疑似蛇毒毒液及其沾染样品,基于纳升级超高效液相色谱-四极杆-静电场轨道阱高分辨质谱（Nano LC-MS/HRMS）技术,结合尺寸排阻色谱分离,建立了一种蛋白质种类及物种归属的严格鉴定方法。5个样品经尺寸排阻色谱分离后均得到3个洗脱峰,分别冻干后以胰蛋白酶进行溶液内酶解处理并进行液相色谱-高分辨质谱分析鉴定。首先采用全扫描-数据依赖型MS/MS（Full MS/dd MS²）采集模式对样品中的肽段信息进行非靶向采集,依次与Swiss-Prot、蛇亚目（Serpentes）、游蛇科（Colubroidea）、眼镜蛇科（Elapidae）、眼镜蛇亚科（Elapinae）、眼镜蛇属（Naja）蛋白质数据库逐级收缩比对;再筛选符合肽谱匹配度、肽段错误发现率小于1%和特征肽段数目大于等于2的蛋白质,共鉴定到32种蛋白质均来自中华眼镜蛇（Naja atra）,可归属于Naja atra的10个家族,主要为三指毒素、金属蛋白酶、磷脂酶A2等。最后,采用平行反应监测模式选取每种蛋白质的两条特征肽段进行靶向验证,当两条特征肽段均满足“至少75%的y⁺和b⁺离子的Δm/z小于5 ppm”时,方认为鉴定到了样品中的某一蛋白质。最终鉴定出5个样品均含有Naja atra蛇毒。此鉴定方法研究系统、严格,可为蛇毒中毒司法鉴定以及毒药物研究等提供有效的技术支持。     

The difference between the mechanism of 67Ga accumulation and 59Fe accumulation in cultured tumor cells

It is well known that the mechanism of 67Ga accumulation into tumor cells is mediated with transferrin receptor as well as iron. The present study was designed to explore the difference between the mechanism of gallium accumulation and that of iron by using mouse leukemic cell line L5178Y. When monensin which inhibits the recycle of transferrin receptor was added to the incubated system, accumulation of 59Fe and 67Ga was clearly diminished compared with that of control. However, inhibition of 59Fe accumulation was more remarkable than that of 67Ga. Furthermore, monensin has a action of Na+ ionophore which decreases Na+ gradient between the inside and the outside of the plasma membrane. Following administration of monensin, 67Ga accumulation was diminished according to the loss of the Na+ gradient. On the other hand, following administration of valinomycin, 67Ga accumulation was not affected by the loss of the K+ gradient. From these results, it was suggested that the mechanism of 67Ga accumulation into tumor cells differed from that of 59Fe and transferrin receptor and Na+ gradient of tumor cells played an important role on 67Ga accumulation into tumor cells.     

Absolute potassium cation affinities (PCAs) in the gas phase

The potassium cation affinities (PCAs) of 136 ligands (20 classes) in the gas phase were established by hybrid density functional theory calculations (B3-LYP with the 6-311+G(3df,2p) basis set). For these 136 ligands, 70 experimental values are available for comparison. Except for five specific PCA values-those of phenylalanine, cytosine, guanine, adenine (kinetic-method measurement), and Me(2)SO (by high-pressure mass spectrometric equilibrium measurement)-our theoretical estimates and the experimental affinities are in excellent agreement (mean absolute deviation (MAD) of 4.5 kJ mol(-1)). Comparisons with previously reported theoretical PCAs are also made. The effect of substituents on the modes of binding and the PCAs of unsubstituted parent ligands are discussed. Linear relations between Li+/Na+ and K+ affinities suggest that for the wide range of ligands studied here, the nature of binding between the cations and a given ligand is similar, and this allows the estimation of PCAs from known Li+ and/or Na+ affinities. Furthermore, empirical equations relating the PCAs of ligands with their dipole moments, polarizabilities (or molecular weights), and the number of binding sites were established. Such equations offer a simple method for estimating the PCAs of ligands not included in the present study.     

Sensitive detection of type G botulinum neurotoxin through Endopep-MS peptide substrate optimization

Clostridium botulinum produces botulinum neurotoxins (BoNTs) that are one of the most poisonous substances. In order to respond to public health emergencies, there is a need to develop sensitive and specific methods for detecting botulinum toxin in various clinical matrices. Our laboratory has developed a mass spectrometry-based Endopep-MS assay that is able to rapidly detect and differentiate BoNT serotypes A–G by immunoaffinity capture of toxins and detection of unique cleavage products of peptide substrates. To improve the sensitivity of the Endopep-MS assay for the detection of BoNT serotype G, we report here the optimization of synthetic peptide substrates through systematic substitution, deletion, and incorporation of unnatural amino acids. Our data show that the resulting optimized peptides produced a significant improvement (two orders of magnitude) in assay sensitivity and allowed the detection of 0.01 mouseLD₅₀ toxin present in buffer solution.