[非洲锥虫与人类的分子对话]。

E Pays
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引用次数: 0

摘要

人类在非洲大陆的进化起源要求抵抗地方性寄生虫,特别是非洲锥虫(原型:布鲁氏锥虫)。因此,正如A. Laveran在1902年发现的那样,人类血清具有有效的先天免疫系统来对抗这些寄生虫。然而,两个布氏体克隆体,分别被称为布氏体罗得西亚锥虫和布氏体冈比亚锥虫,成功地逃脱了这种免疫系统,使它们能够在人类体内生长,并引起昏睡病。我们已经确定了允许布氏罗得西亚锥虫抵抗人血清锥虫酶解的基因,这使我们发现锥虫酶解因子是载脂蛋白L1 (apoL1)。ApoL1是一种人类特异性血清蛋白,与高密度脂蛋白颗粒结合,高密度脂蛋白颗粒还含有另一种人类特异性蛋白,称为“触珠蛋白相关蛋白”(Hpr)。血红蛋白(Hb)与Hpr结合后,携带apol1的HDL颗粒通过与寄生虫表面的Hp-Hb复合物受体结合而被锥虫大量吸收。内吞作用后,apoL1通过在溶酶体膜上产生阴离子孔杀死寄生虫。在我们的实验室中,已经构建了apoL1的突变版本,它不再被罗得西亚锥虫的抗性蛋白中和,因此能够杀死这种人类病原体。出乎意料的是,我们最近发现类似的突变确实存在于自然界中:在非洲人和最近非洲血统的美国人身上,即使是这些突变的单个等位基因也可以防止布氏罗得西亚锥虫感染,但代价是当双等位基因出现时,终末期肾病的发病率很高。尽管这些apoL1突变对肾脏有潜在的危害,但它们的自然选择证据突出了人类进化中对锥虫的抗性的重要性。突变apoL1触发终末期肾病的机制目前正在研究中。
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[Molecular dialogue between African trypanosomes and humans].

The evolutionary origin of Man in the African continent has imposed the requirement to resist endemic parasites, in particular African trypanosomes (prototype: Trypanosoma brucei). Therefore, human serum is provided with an efficient system of innate immunity against these parasites, as discovered by A. Laveran in 1902. However, two T. brucei clones, termed T. b. rhodesiense and T. b. gambiense, managed to escape this immunity system, enabling them to grow in humans where they cause sleeping sickness. We have identified the gene allowing T. b. rhodesiense to resist trypanolysis by human serum, which led us to discover that the trypanolytic factor is apolipoprotein L1 (apoL1). ApoL1 is a human-specific serum protein bound to HDL particles that also contain another human-specific protein termed "haptoglobin-related protein " (Hpr). Following the binding of hemoglobin (Hb) to Hpr, the apoL1-bearing HDL particles are avidly taken up by the trypanosome through their binding to a parasite surface receptor for the Hp-Hb complex. After endocytosis apoL1 kills the parasite by generating anionic pores in the lysosomal membrane. In our laboratory, mutant versions of apoL1 have been constructed, which are no longer neutralized by the resistance protein of T. b. rhodesiense and are therefore able to kill this human pathogen. Unexpectedly, we have recently discovered that similar mutants do actually exist in nature : in Africans and Americans of recent African origin, even a single allele of these mutants allows protection against infection by T. b. rhodesiense, but the price to pay is a high frequency of end-stage renal disease when doubly allelic. The evidence of natural selection of these apoL1 mutations despite their deleterious potential for kidneys highlights the importance of the resistance to trypanosomes in the evolution of Man. The mechanism by which mutant apoL1 triggers end-stage renal disease is currently studied.

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