炭疽毒素及其细胞受体的研究进展

炭疽毒素由 3种蛋白组成 :保护性抗原 (protectiveantigen ,PA)、致死因子 (lethalfactor,LF)和水肿因子 (edemafactor ,EF) .综述炭疽毒素研究的最新进展 .主要介绍炭疽毒素的关键致病因子———LF的结构与功能 ,炭疽毒素膜转运成分PA的结构及其受体 (anthraxtoxinreceptor ,ATR)和其cDNA克隆的结构 ,并讨论了在炭疽的治疗、预防和毒素在肿瘤治疗中的可能应用 .     

重组炭疽水肿因子的表达与生物活性分析

炭疽毒素包括3种蛋白因子,即保护性抗原（PA）、致死因子（LF）和水肿因子（EF）。EF是钙调蛋白依耐的腺苷酸环化酶,可使细胞cAMP浓度升高,导致宿主防御能力下降。为深入研究炭疽毒素的作用机理,构建了原核表达质粒,在大肠杆菌中表达出重组EF（rEF）。经鉴定,rEF以可溶形式表达于细菌胞质中。经过金属螯和层析、阳离子交换层析和凝胶层析,每升诱导培养物可获得约5mg 重组蛋白。用重组蛋白免疫家兔获得了兔多抗,能够在细胞试验中中和rEF,体外细胞试验显示rEF具有很好的生物活性,在J774A.1和CHO细胞试验中,能与LF共同竞争和PA的结合位点,相互抑制。上述工作为深入研究炭疽毒素的作用机理,开发针对EF的毒素抑制剂打下基础     

针对炭疽保护性抗原不同结构域的中和性单克隆抗体的筛选和鉴定

炭疽保护性抗原（PA）是炭疽毒素的重要组分,同时也是现有炭疽疫苗的主要有效成分,在炭疽杆菌的致病与免疫中发挥关键作用。以重组PA为免疫原,采用B淋巴细胞杂交瘤技术,结合炭疽毒素敏感细胞的毒性中和试验,大量筛选抗PA单克隆抗体,获得了9株炭疽毒素中和性单抗。进一步分析表明这些单抗以IgG1亚类为主,分别识别PA 3个结构域的4个不同中和表位区。针对结构域2的4株单抗识别同一表位区,其中3株单抗的中和活性强于抗PA多抗;针对结构域4的4株单抗识别两个不同表位区;另有1株单抗识别位于结构域3的表位。实验结果提示PA具有多个中和表位,分别位于其不同结构域,其中结构域2、4包含主要中和表位。实验中获得的针对不同表位的中和性单抗为深入研究PA的免疫保护机理提供了工具,也为研制针对炭疽毒素的被动免疫制剂和治疗药物打下基础。     

产生炭疽杆菌抗原的一种新的限定培养基

<正>炭疽杆菌的三组分毒素是由三种多肽成份组成的一种复合毒素或毒性物质:水肿因子(EF;因子I)、保护性抗原(PA;因子Ⅱ)和致死因子(LF;因子Ⅲ)。没有     

茯苓多糖PCP-Ⅰ增强抗原特异性体液免疫反应的机制研究

目的:以炭疽芽孢杆菌保护性抗原(PA)为模式抗原,对茯苓多糖PCP-Ⅰ作为疫苗佐剂增强抗原特异性体液免疫反应的机制进行研究。方法:PCP-Ⅰ混合PA免疫BALB/c小鼠,分别采用ELISA和毒素中和实验,检测免疫后小鼠血清中PA特异性(anti-PA)抗体和炭疽毒素中和抗体;采用流式细胞术检测树突状细胞(DC)经PCP-Ⅰ体外刺激后的成熟情况,及二免后7 d小鼠脾脏中生发中心(GC)B细胞和滤泡状辅助T细胞(Tfh)的频率。结果:相对于单独PA免疫组,200μg PCP-Ⅰ能够显著提高二免后2周小鼠血清中anti-PA抗体和毒素中和抗体的水平(5.38×10~3vs 6.48×10~1,8.7×10~1vs 1.54×10~1)。PCP-Ⅰ与PA混合刺激培养DC,CD80和MHC-Ⅱ分子阳性细胞频率(82.2%,74.9%)显著高于PA刺激组(51.7%,46.8%)。二免后7 d,PA+PCP-Ⅰ组小鼠脾脏中Tfh细胞频率略高于PA组(4.97%vs 4.20%),GC B细胞频率显著高于PA组(7.73%vs 6.30%)。结论:PCP-Ⅰ可通过促进DC成熟和增强生发中心反应来增强抗原特异性体液免疫反应。     

应用改构的炭疽毒素作为靶向肿瘤细胞的药物递送系统及其效果评价

目的:通过改造炭疽毒素保护性抗原Protective Antigen (PA)及致死因子Lethal Factor (LF),尝试建立更加广谱的新型炭疽毒素靶向给药系统并对其递送效率进行定量评价.方法:采用基因工程手段,分别构建了3种改构的天然炭疽毒素保护性抗原PA及炭疽毒素的LF N端融合海肾荧光素酶(Luciferase)的LFn-linker-Luc的大肠杆菌重组表达体系.利用CCK-8法评价改构PA和LF共同作用肿瘤细胞后的细胞存活率;利用改构PA和LFn-linker-Luc与肿瘤细胞共孵育,通过测定细胞内荧光素酶活性,评价改构PA靶向肿瘤细胞的效果.结果:体外酶解实验证明构建的改构PA蛋白能够被正确地酶解成目的大小的片段;改构PA和LF共同作用肿瘤细胞能够显著降低细胞存活率;利用LFn-linker-Luc能够评价改构PA的靶向效率,PA蛋白的改构方式与其递送效率相关.结论:设计并改构的炭疽毒素药物递送系统,能够实现特异性靶向肿瘤细胞的效果,并具有更广谱的作用效果,为研制新型广谱抗肿瘤药物提供了新的思路和方法.     

人用炭疽菌苗的研究进展

<正>炭疽是一种人兽共患的急性传染病,羊、牛、马等家畜易患本病,人由于接触炭疽病畜或屠宰、剥食而受染。炭疽的病原体是炭疽杆菌,是一种需氧芽胞杆菌。炭疽菌的毒力除决定于染色体基因外,还与两个编码质粒致病因子有关:一个是荚膜质粒(编码pxo2),主要是聚—D—谷氨酸,在体内能抑制细胞的吞噬作用,在体外能阻断菌体胞壁上的噬菌体受体,故常称为侵袭因子,有助于病菌在体内繁殖扩散和建立感染;另一个是炭疽毒素质粒(编码pxo1),由致死因子(LF)、水肿因子(EF)和保护性抗原(PA)三种成分组成。三种成分单独注射动物未证明有毒素活性,但若将LF加PA静脉注射可致死小白鼠、大白鼠和豚鼠。EF加PA皮内注射可引起豚鼠和家兔皮肤水肿。三种毒素成分的分子量在80～90KDa之间,可能PA结合     

从鼠源到全人源单克隆抗体制备技术及改造策略的研究进展

单克隆抗体(单抗)因其专一性、高效价、低耐药性等显著优势,已成为生物制药业行业发展最快的领域之一,并成功用于治疗多种癌症、自身免疫病和其他疾病等。从最初的鼠源性单抗发展至现今的全人源单抗,新的制备技术不断涌现,如单细胞分选和测序技术等。同时,通过改变全人源单抗的糖基化水平、优化单抗亲和力成熟技术等,有助于进一步提高其稳定性、亲和力。目前,全人源单抗的疗效和安全性仍受到行业关注,也面临很多挑战,如何平衡在降低其免疫原性的同时,进一步提高其亲和力等,仍寄希望于新的技术或策略。     

A型肉毒毒素单克隆抗体的制备和鉴定

目的:制备并鉴定抗A型肉毒毒素重链C端(BoNT/AHc)鼠源单抗。方法:以BoNT/AHc蛋白为抗原免疫小鼠,利用杂交瘤技术获得鼠源单抗,通过抗体分型、SDS-PAGE、Western印迹及ELISA法分析鉴定。结果:筛选得到3株鼠单抗1B1、1B2、1C6,重链类型均为IgG1,轻链类型均为κ型;3株纯化抗体的纯度达90%以上,均能与抗原BoNT/AHc特异性结合,亲和力常数分别为1.43×10~8、2.31×10~8、1.44×10~9L/mol;叠加ELISA结果显示3株抗体与抗原BoNT/AHc结合位点相同或相近。结论:筛选得到3株能与BoNT/AHc特异性结合的鼠源单抗,为A型肉毒毒素中和抗体的研发,以及快速有效的肉毒毒素检测方法的建立奠定了基础。     

炭疽受体CMG2-Fc 融合蛋白在CHO 细胞中的表达、纯化与鉴定

目的:构建炭疽受体CMG2和人IgG1 Fc片段融合基因载体,转染CHO细胞并通过毒素中和试验检测CMG2-Fc拮抗炭疽毒素(PA+LF)的能力。方法:将含有CMG2胞外区1-217AA片度基因和人IgG1的Fc片段基因共同连接入pcDNA3.1载体转染CHO细胞并筛选高表达CMG2-Fc的CHO细胞系,通过小鼠RAW264.7巨噬细胞保护试验检测CMG2-Fc拮抗炭疽毒素的能力。结果:获得了表达CMG2-Fc的细胞株,毒素中和实验显示该蛋白可以有效抑制炭疽毒素引起的细胞损伤。结论:CMG2-Fc能够保护小鼠巨噬细胞免受炭疽毒素攻击,提示其可以作为抗毒素治疗炭疽感染。     

The early humoral immune response to Bacillus anthracis toxins in patients infected with cutaneous anthrax

Bacillus anthracis, the causative agent of anthrax, produces a tripartite toxin composed of two enzymatically active subunits, lethal factor (LF) and edema factor (EF), which, when associated with a cell-binding component, protective antigen (PA), form lethal toxin and edema toxin, respectively. In this preliminary study, we characterized the toxin-specific antibody responses observed in 17 individuals infected with cutaneous anthrax. The majority of the toxin-specific antibody responses observed following infection were directed against LF, with immunoglobulin G (IgG) detected as early as 4 days after the onset of symptoms in contrast to the later and lower EF- and PA-specific IgG responses. Unlike the case with infection, the predominant toxin-specific antibody response of those immunized with the US anthrax vaccine absorbed and UK anthrax vaccine precipitated licensed anthrax vaccines was directed against PA. We observed that the LF-specific human antibodies were, like anti-PA antibodies, able to neutralize toxin activity, suggesting the possibility that they may contribute to protection. We conclude that an antibody response to LF might be a more sensitive diagnostic marker of anthrax than to PA. The ability of human LF-specific antibodies to neutralize toxin activity supports the possible inclusion of LF in future anthrax vaccines.     

Western blot analysis of the exotoxin components from Bacillus anthracis separated by isoelectric focusing gel electrophoresis

The components of the Bacillus anthracis exotoxins, protective antigen (PA), lethal factor (LF), and edema factor (EF), from 24 isolates were separated by isoelectric focusing gel electrophoresis and detected by Western blot with monoclonal antibodies. Only two isoforms each were observed for PA and EF. Four isoforms were identified for LF. The biological activities of both lethal toxin and edema toxin were measured by using in vitro cell-based assays. This study provides another method of characterizing various isolates of B. anthracis by determining the isoelectric points of the exotoxin components and may be useful in the development of protective vaccines against B. anthracis infection.     

Postinfection and postvaccinal antianthrax immunity in human subjects

Antibodies to Bacillus anthracis protective antigen (PA) and to the lethal factor (LF) of B. anthracis exotoxin in the blood sera of anthrax patients and of subjects with a history of the disease, as well as of persons immunized with STI live vaccine, were studied by the heterogeneous enzyme immunoassay. In 1-6 years after convalescence the levels of anti-PA and anti-LF antibodies (at 75% and 96% detection rates respectively) were higher than on weeks 1-4 from the onset of the disease. In persons having had anthrax antibodies belonged mainly to IgG, and the anti-LF antibody level was higher than the anti-PA antibody level. In persons immunized with STI vaccine the detection rate of antibodies somewhat increased in 2-7 months after immunization, reaching, on the average, 72%, the antibody levels after primary immunization and regular annual booster immunization being similar. In 1-2 years after primary (booster) immunization the isolation rate of antibodies decreases to 21%. Specific features of postinfectious and postvaccinal immunity to anthrax and problems of retrospective diagnosis of this disease are discussed.     

Nasal immunization with the mixture of PA63, LF, and a PGA conjugate induced strong antibody responses against all three antigens

A new generation anthrax vaccine is expected to target not only the anthrax protective antigen (PA) protein, but also other virulent factors of Bacillus anthracis. It is also expected to be amenable for rapid mass immunization of a large number of people. This study aimed to address these needs by designing a prototypic triantigen nasal anthrax vaccine candidate that contained a truncated PA (rPA63), the anthrax lethal factor (LF), and the capsular poly-gamma-D-glutamic acid (gammaDPGA) as the antigens and a synthetic double-stranded RNA (dsRNA), polyriboinosinic-polyribocytodylic acid (poly(I:C)) as the adjuvant. This study identified the optimal dose of nasal poly(I:C) in mice, demonstrated that nasal immunization of mice with the LF was capable of inducing functional anti-LF antibodies (Abs), and showed that nasal immunization of mice with the prototypic triantigen vaccine candidate induced strong immune responses against all three antigens. The immune responses protected macrophages against an anthrax lethal toxin challenge in vitro and enabled the immunized mice to survive a lethal dose of anthrax lethal toxin challenge in vivo. The anti-PGA Abs were shown to have complement-mediated bacteriolytic activity. After further optimization, this triantigen nasal vaccine candidate is expected to become one of the newer generation anthrax vaccines.     

Location of receptor-binding region of protective antigen from Bacillus anthracis

The pag gene, which codes for protective antigen (PA), a common component of the lethal and edema toxins of Bacillus anthracis, was cloned and expressed in Escherichia coli. Nested deletions of pag were generated into the C-terminus coding region. Recombinant proteins were analyzed by Western blot with either an anti-PA polyclonal antisera or two monoclonal antibodies that neutralized lethal toxin and edema toxin activities by inhibiting the binding of PA to cell receptors. Localization of the receptor binding domain within the C-terminal region of PA was suggested by the inability of the monoclonal antibodies 3B6 and 14B7 to recognize the recombinant proteins expressed by C-terminal deletions of the pag gene.     

Proteome analysis of mouse macrophages treated with anthrax lethal toxin

Anthrax toxin produced by Bacillus anthracis is a tripartite toxin comprising of protective antigen (PA), lethal factor (LF) and edema factor (EF). PA is the receptor-binding component, which facilitates the entry of LF or EF into the cytosol. EF is a calmodulin-dependent adenylate cyclase that causes edema whereas LF is a zinc metalloprotease and leads to necrosis of macrophages. It is also important to note that the exact mechanism of LF action is still unclear. With this view in mind, in the present study, we investigated a proteome wide effect of anthrax lethal toxin (LT) on mouse macrophage cells (J774A.1). Proteome analysis of LT-treated and control macrophages revealed 41 differentially expressed protein spots, among which phosphoglycerate kinase I, enolase I, ATP synthase (beta subunit), tubulin beta2, gamma-actin, Hsp70, 14-3-3 zeta protein and tyrosine/tryptophan-3-monooxygenase were found to be down-regulated, while T-complex protein-1, vimentin, ERp29 and GRP78 were found to be up-regulated in the LT-treated macrophages. Analysis of up- and down-regulated proteins revealed that primarily the stress response and energy generation proteins play an important role in the LT-mediated macrophage cell death.     

Anthrax biosensor, protective antigen ion channel asymmetric blockade

The significant threat posed by biological agents (e.g. anthrax, tetanus, botulinum, and diphtheria toxins) (Inglesby, T. V., O'Toole, T., Henderson, D. A., Bartlett, J. G., Ascher, M. S., Eitzen, E., Friedlander, A. M., Gerberding, J., Hauer, J., Hughes, J., McDade, J., Osterholm, M. T., Parker, G., Perl, T. M., Russell, P. K., and Tonat, K. (2002) J. Am. Med. Assoc. 287, 2236-2252) requires innovative technologies and approaches to understand the mechanisms of toxin action and to develop better therapies. Anthrax toxins are formed from three proteins secreted by fully virulent Bacillus anthracis, protective antigen (PA, 83 kDa), lethal factor (LF, 90 kDa), and edema factor (EF, 89 kDa). Here we present electrophysiological measurements demonstrating that full-length LF and EF convert the current-voltage relationship of the heptameric PA63 ion channel from slightly nonlinear to highly rectifying and diode-like at pH 6.6. This effect provides a novel method for characterizing functional toxin interactions. The method confirms that a previously well characterized PA63 monoclonal antibody, which neutralizes anthrax lethal toxin in animals in vivo and in vitro, prevents the binding of LF to the PA63 pore. The technique can also detect the presence of anthrax lethal toxin complex from plasma of infected animals. The latter two results suggest the potential application of PA63 nanopore-based biosensors in anthrax therapeutics and diagnostics.     

A Dual-Purpose Protein Ligand for Effective Therapy and Sensitive Diagnosis of Anthrax

This article reports the design of a bivalent protein ligand with dual use in therapy and diagnosis of anthrax caused by Bacillus anthracis. The ligand specifically binds to PA and thereby blocks the intracellular delivery of LF and EF toxins that, respectively, cause cell lysis and edema. The ligand is a chimeric scaffold with two PA-binding domains (called VWA) linked to an IgG-Fc frame. Molecular modeling and binding measurements reveal that the VWA-Fc dimer binds to PA with high affinity (K (D) = 0.2 nM). An in vitro bio-luminescence assay shows that VWA-Fc (at nanomolar concentration) protects mouse macrophages from lysis by PA/LF. In vivo studies demonstrate that VWA-Fc at low doses ( approximately 50 mug/animal) are able to rescue animals from lethal doses of PA/LF and B. anthracis spores. Finally, VWA-Fc is utilized as the capture molecule in the sensitive (down to 30 picomolar) detection of PA using surface plasmon resonance.