Background id='Par1' class='Para'>The cysteine-rich neurotoxins from elapid venoms are primarily responsible for human and animal envenomation; however, their low concentration i'/>
Heterologous expression, protein folding and antibody recognition of a neurotoxin from the Mexican coral snake Emphasis Type="Italic"Micrurus laticorallis/Emphasis
Heterologous expression, protein folding and antibody recognition of a neurotoxin from the Mexican coral snake Emphasis Type="Italic"Micrurus laticorallis/Emphasis
class="Heading">Background id="Par1" class="Para">The cysteine-rich neurotoxins from elapid venoms are primarily responsible for human and animal envenomation; however, their low concentration in the venom may hamper the production of efficient elapid antivenoms. Therefore, the aim of the present study was to produce fully active elapid neurotoxic immunogens for elapid antivenom production. class="Heading">Method id="Par2" class="Para">Cysteine-rich neurotoxins showed recombinant expression in two strains of E. coli, and were purified using affinity chromatography and reverse-phase HPLC (rpHPLC). class="Heading">Results id="Par3" class="Para">The cDNA of the four disulfide-bridged peptide neurotoxin Mlat1 was cloned into a modified expression vector, pQE30, which was transfected into two different E. coli strains. The recombinant toxin (HisrMlat1) was found only in inclusion bodies in M15 strain cells, and in both inclusion bodies and cytoplasm in Origami strain cells. The HisrMlat1 from inclusion bodies from M15 cells was solubilized using guanidine hydrochloride, and then purified by rpHPLC. It showed various contiguous fractions having the same molecular mass, indicating that HisrMlat1 was oxidized after cell extraction forming different misfolded disulfide bridge arrangements without biological activity. In vitro folding conditions of the misfolded HisrMlat1 generated a biologically active HisrMlat1. On the other hand, the HisrMlat1 from the cytoplasm from Origami cells was already soluble, and then purified by HPLC. It showed a single fraction with neurotoxic activity; so, no folding steps were needed. The in vitro folded HisrMlat1 from M15 cells and the cytoplasmic soluble HisrMlat1from Origami cells were indistinguishable in their structure and neurotoxicity. Rabbit polyclonal antibodies raised up against biologically active HisrMlat1 recognized the native Mlat1 (nMlat1) from the whole venom of M. laticorallis. In addition, HisrMlat1 was recognized by horse polyclonal antibodies obtained from the immunization of elapid species from sub-Saharan Africa. class="Heading">Conclusion id="Par4" class="Para">HisrMlat1 shows increased biological activities compared to the native peptide, and may be used as an immunizing agent in combination with other toxic components such phospholipases type A2 for elapid antivenom production.
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机译:class =“ Heading”>背景 id =“ Par1” class =“ Para”>来自弹性毒液的富含半胱氨酸的神经毒素主要负责人和动物的毒化。然而,它们在毒液中的浓度低可能会阻碍高效的抗蛇毒血清的产生。因此,本研究的目的是产生用于产生抗蛇毒的全活性弹性神经毒性免疫原。 class =“ Heading”>方法 id =“ Par2” class =“ Para”富含半胱氨酸的神经毒素在两种 E菌株中显示重组表达。大肠杆菌,并使用亲和色谱和反相HPLC(rpHPLC)进行纯化。 class =“ Heading”>结果 id =“ Par3” class =“ Para” >将四个二硫键桥接的肽神经毒素Mlat1的cDNA克隆到修饰的表达载体pQE30中,将其转染到两个不同的 E中。大肠杆菌菌株。重组毒素(HisrMlat1)仅在M15菌株细胞的包涵体中发现,在折纸菌株细胞的包涵体和细胞质中均发现。使用盐酸胍溶解来自M15细胞包涵体的HisrMlat1,然后通过rpHPLC纯化。它显示了具有相同分子量的各种连续馏分,表明HisrMlat1在细胞提取后被氧化,形成了不同的错折叠的二硫键,没有生物活性。错误折叠的HisrMlat1的体外折叠条件产生了具有生物活性的HisrMlat1。另一方面,来自折纸细胞的细胞质中的HisMlat1已经可溶,然后通过HPLC纯化。它显示出具有神经毒性活性的单个部分;因此,不需要折叠步骤。体外折叠的M15细胞的HisrMlat1和折纸细胞的胞质可溶性HisrMlat1在结构和神经毒性方面没有区别。产生抗生物活性HisrMlat1的兔多克隆抗体从 M的整个毒液中识别出天然Mlat1(nMlat1)。 laticorallis 。此外,HisMlat1被免疫来自撒哈拉以南非洲地区的弹性物种获得的马多克隆抗体识别。 class =“ Heading”>结论 id =“ Par4” class =“ Para“> HisrMlat1与天然肽相比,具有更高的生物学活性,可与其他有毒成分(如A2型磷脂酶)结合用作免疫剂,以实现抗蛇毒的生产。
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