Singh Sanjay, Miura Kazutoyo, Zhou Hong, Muratova Olga, Keegan Brian, Miles Aaron, Martin Laura B, Saul Allan J, Miller Louis H, Long Carole A
Antigen Research Section, Malaria Vaccine Development Branch, National Institute of Allergy and Infectious Diseases/National Institutes of Health, TW1, Rockville, Maryland 20852, USA.
Infect Immun. 2006 Aug;74(8):4573-80. doi: 10.1128/IAI.01679-05.
A number of malarial blood-stage candidate vaccines are currently being tested in human clinical trials, but our understanding of the relationship between clinical immunity and data obtained from in vitro assays remains inadequate. An in vitro assay which could reliably predict protective immunity in vivo would facilitate vaccine development. Merozoite surface protein1 (MSP1) is a leading blood-stage malaria vaccine candidate, and anti-MSP1 antibodies from individuals that are clinically immune to malaria inhibit the invasion of Plasmodium merozoites into erythrocytes in vitro. Using expression in Escherichia coli and subsequent refolding, we have produced two allelic forms of MSP1(42) (FVO and 3D7). Aotus nancymai monkeys were immunized with MSP1(42)-FVO, MSP1(42)-3D7, or a combination of FVO and 3D7 allelic forms, (MSP1(42)-C1) and were subsequently challenged with Plasmodium falciparum FVO parasites. Sera obtained prior to challenge were tested by standardized enzyme-linked immunosorbent assay (ELISA) to determine antibody titer, and immunoglobulin G (IgG) fractions were also obtained from the same sera; the IgG fractions were tested in an in vitro growth inhibition (GI) assay to evaluate biological activity of the antibodies. Regardless of the immunogen used, all monkeys that had >200,000 ELISA units against MSP1(42)-FVO antigen before challenge controlled their infections. By contrast, all monkeys whose purified IgGs gave <60% inhibition activity in an in vitro GI assay with P. falciparum FVO required treatment for high parasitemia after challenge. There is a strong correlation between ELISA units (Spearman rank correlation of greater than 0.75) or GI activity (Spearman rank correlation of greater than 0.70) and protective immunity judged by various parameters (e.g., cumulative parasitemia or day of patency). These data indicate that, in this monkey model, the ELISA and GI assay values can significantly predict protective immunity induced by a blood-stage vaccine, and they support the use of these assays as part of evaluation of human clinical trials of MSP1-based vaccines.
目前有多种疟疾血液期候选疫苗正在人体临床试验中进行测试,但我们对临床免疫与体外试验所得数据之间关系的理解仍不充分。一种能够可靠预测体内保护性免疫的体外试验将有助于疫苗研发。裂殖子表面蛋白1(MSP1)是主要的血液期疟疾疫苗候选物,来自对疟疾具有临床免疫力个体的抗MSP1抗体在体外可抑制疟原虫裂殖子侵入红细胞。通过在大肠杆菌中表达并随后复性,我们制备了MSP1(42)的两种等位基因形式(FVO和3D7)。用MSP1(42)-FVO、MSP1(42)-3D7或FVO和3D7等位基因形式的组合(MSP1(42)-C1)免疫南美白狨猴,随后用恶性疟原虫FVO株进行攻击。攻击前采集的血清通过标准化酶联免疫吸附测定(ELISA)检测抗体滴度,同时也从相同血清中获得免疫球蛋白G(IgG)组分;IgG组分在体外生长抑制(GI)试验中进行检测,以评估抗体的生物学活性。无论使用何种免疫原,所有在攻击前针对MSP1(42)-FVO抗原的ELISA单位>200,000的猴子都控制住了感染。相比之下,所有纯化IgG在针对恶性疟原虫FVO的体外GI试验中抑制活性<60%的猴子在攻击后因高寄生虫血症需要治疗。ELISA单位(Spearman等级相关性大于0.75)或GI活性(Spearman等级相关性大于0.70)与通过各种参数(如累积寄生虫血症或发病天数)判断的保护性免疫之间存在很强的相关性。这些数据表明,在该猴子模型中,ELISA和GI试验值能够显著预测血液期疫苗诱导的保护性免疫,并且支持将这些试验用作基于MSP1疫苗人体临床试验评估的一部分。