Identification of vaccine candidates against severe malaria

鉴定针对严重疟疾的候选疫苗

• 批准号: 8627536
• 负责人: ANDREW V OLEINIKOV
• 金额: $ 37.29万
• 依托单位: FLORIDA ATLANTIC UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-03-01 至 2016-02-29
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8627536
• 关键词: 5 year old; Adhesions; Africa; African; Anemia; Antibodies; Antibody Formation; Antigens; Area; Binding; Biological Assay; Blocking Antibodies; CD36 gene; Cerebral Malaria; Child; Clinical; Cohort Studies; Complex; Data; Disease; Disease susceptibility; Endothelium; Epidemiology; Epitopes; Erythrocyte Membrane; Erythrocytes; Evaluation; Family; Grant; Hospitalization; ICAM1 gene; Immune response; Immunity; Immunoglobulin G; Immunologic Epidemiology; Individual; Life; Malaria; Malaria Vaccines; Measures; Mediating; Membrane Proteins; Methods; Organ; Parasitemia; Parasites; Pattern; Placenta; Plasma; Plasmodium falciparum; Pregnancy; Protein Family; Proteins; Receptor Cell; Recurrence; Resistance; Respiratory distress; Sampling; Serum; Severity of illness; Source; Surface; Syndrome; Testing; Time; Vaccines; Variant; Virulence; Work; acquired immunity; aged; base; collected works; genome wide association study; genome-wide; killings; member; mortality; novel vaccines; prevent; public health relevance; receptor; receptor binding; vaccine candidate; vaccine development; vascular bed

DESCRIPTION (provided by applicant): The long-term aim of this work is to identify vaccine candidates to prevent severe malaria syndromes through understanding natural protective immune response. Plasmodium falciparum parasite-infected erythrocytes (IE) adhere to the host endothelium and to red blood cells. The adhesion is mediated by a large family (~60 members) of parasite multidomain variant proteins called PfEMP1. They express on the surface of IE in a mutually-exclusive manner. IE adhesion may result in severe complications including cerebral malaria, pregnancy malaria, severe anemia and respiratory distress, major contributors to malaria mortality. Severe malaria episodes are rare and almost never occur more than 1 or 2 times in a lifetime. This epidemiology supports our first hypothesis that only a limited number of parasite lines, possibly expressing particular variants of PfEMP1 that determine specific parasite adhesion, may be the source of severe disease. Immunological profiling of sera for reactivity against different antigens is an important method for assessing acquired immunity and identifying potential vaccine candidates. However, relating immune responses to malaria resistance is not straightforward since exposed individuals are typically infected repeatedly throughout life, and develop diversified immune responses against multiple antigens, in many cases without comprehensible relevance to disease severity. Our second hypothesis is that functional antibody responses that inhibit adhesion of IE to host receptors are likely to have a stronger association to protection from severe malaria. Extensive studies in pregnancy malaria strongly support both our hypotheses. During our previous work we collected thousands of serum samples obtained in longitudinal cohort studies of children living in malaria endemic areas of Africa. We also constructed functional genome-wide PfEMP1 domain arrays and used them to identify domains that bind specifically to the two main adhesion host receptors in malaria (ICAM1 and CD36). We further demonstrated that total anti-domain IgG and functional antibodies (that block adhesion of PfEMP1 domain to its receptor) can be quantified in the plasma samples using our multiplexed high throughput sample-sparing platform. To better understand the protective humoral immune responses in severe malaria, we propose the following specific aims: 1) Measure serum total IgG reactivity against a genome-wide array of PFEMP1 domains, and measure functional serum activity that inhibits CD36 and ICAM1 receptor binding to relevant PFEMP1 domains. We will test about 5000 children's sera including ~200-400 severe malaria cases. 2) Associate defined antibody responses (total and functional) against PfEMP1 domains with disease parameters and protection against severe disease. We will perform a broad range of statistical analyses using the longitudinal data obtained in Aim 1. This would be the first genome-wide study of seroreactivity and a comprehensive study of functional immune responses against PfEMP1 proteins. This study may provide candidates for development of vaccines against severe malaria.

描述（由申请人提供）：这项工作的长期目标是通过了解自然保护性免疫反应来确定预防严重疟疾综合征的候选疫苗。恶性疟原虫感染的红细胞（IE）粘附于宿主内皮细胞和红细胞。粘附由称为PfEMP 1的寄生虫多结构域变体蛋白的大家族（~60个成员）介导。它们在IE的表面以相互排斥的方式表达。IE粘附可能导致严重的并发症，包括脑型疟疾、妊娠期疟疾、严重贫血和呼吸窘迫，这些是疟疾死亡率的主要原因。严重的疟疾发作是罕见的，一生中几乎不会发生超过1或2次。这种流行病学支持我们的第一个假设，即只有有限数量的寄生虫株，可能表达PfEMP 1的特定变体，决定特定的寄生虫粘附，可能是严重疾病的来源。 针对不同抗原的血清反应性的免疫学分析是评估获得性免疫和鉴定潜在疫苗候选物的重要方法。然而，将免疫应答与疟疾抗性联系起来并不简单，因为暴露个体通常在一生中反复感染，并对多种抗原产生多样化的免疫应答，在许多情况下与疾病严重程度没有可理解的相关性。我们的第二个假设是，抑制IE粘附到宿主受体的功能性抗体反应可能与预防严重疟疾有更强的关联。对妊娠期疟疾的广泛研究有力地支持了我们的假设。 在我们之前的工作中，我们收集了数千份来自非洲疟疾流行区儿童纵向队列研究的血清样本。我们还构建了全基因组功能PfEMP 1结构域阵列，并使用它们来识别与疟疾中两种主要粘附宿主受体（ICAM 1和CD 36）特异性结合的结构域。我们进一步证明，使用我们的多重高通量样品保留平台，可以在血浆样品中定量总抗结构域IgG和功能性抗体（阻断PfEMP 1结构域与其受体的粘附）。为了更好地理解严重疟疾中的保护性体液免疫应答，我们提出了以下具体目标：1）测量针对全基因组阵列的PFEMP 1结构域的血清总IgG反应性，并测量抑制CD 36和ICAM 1受体与相关PFEMP 1结构域结合的功能性血清活性。我们将检测约5000名儿童的血清，包括约200-400名严重疟疾病例。2)将针对PfEMP 1结构域的确定抗体应答（总体和功能性）与疾病参数和针对严重疾病的保护相关联。我们将使用目标1中获得的纵向数据进行广泛的统计分析。这将是第一个全基因组的血清反应性研究和对PfEMP 1蛋白的功能性免疫反应的全面研究。这项研究可能为开发针对严重疟疾的疫苗提供候选者。