ST8Sia2 polysialyltransferase protects against infection by Trypanosoma cruzi

Bruno Rafael Barboza, Janaina Macedo da Silva, Lays Adrianne Mendonca Trajano-Silva, Vinicius de Morais Gomes, Deivid Martins Santos, Antonio Moreira Marques-Neto, Simon Ngao Mule, Juliana Borsoi, Carolina Borsoi Moraes, Martina Muhlenhoff, Walter Colli, Suely K N Marie, Lygia V Pereira, Maria Julia Manso Alves, Giuseppe Palmisano
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Abstract

Glycosylation is one of the most structurally and functionally diverse co- and post-translational modifications in a cell. Addition and removal of glycans, especially to proteins and lipids, characterize this process which have important implications in several biological processes. In mammals, the repeated enzymatic addition of a sialic acid unit to underlying sialic acids (Sia) by polysialyltransferases, including ST8Sia2, leads to the formation of a sugar polymer called polysialic acid (polySia). The functional relevance of polySia has been extensively demonstrated in the nervous system. However, the role of polysialylation in infection is still poorly explored. Previous reports have shown that Trypanosoma cruzi (T. cruzi), a flagellated parasite that causes Chagas disease (CD), changes host sialylation of glycoproteins. To understand the role of host polySia during T. cruzi infection, we used a combination of in silico and experimental tools. We observed that T. cruzi reduces both the expression of the ST8Sia2 and the polysialylation of target substrates. We also found that chemical and genetic inhibition of host ST8Sia2 increased the parasite load in mammalian cells. These findings suggest a novel approach to interfere with parasite infections through modulation of host polysialylation.
ST8Sia2多唾液转移酶对克氏锥虫感染有保护作用
糖基化是细胞中结构和功能最多样化的共翻译修饰和翻译后修饰之一。聚糖的添加和去除,特别是在蛋白质和脂质上的添加和去除,是这一过程的特征,在几个生物过程中具有重要意义。在哺乳动物中,通过包括ST8Sia2在内的多唾液基转移酶,将唾液酸单位反复加到底层唾液酸(Sia)中,导致形成一种称为多唾液酸(polySia)的糖聚合物。多囊症的功能相关性已在神经系统中得到广泛证实。然而,多唾液酰化在感染中的作用仍然很少被探索。以前的报道表明,克氏锥虫(T.克氏锥虫)是一种引起恰加斯病(CD)的鞭毛寄生虫,可改变宿主唾液糖蛋白的酰化。为了了解宿主多囊虫在克氏锥虫感染过程中的作用,我们采用了计算机和实验相结合的方法。我们观察到克氏锥虫降低了ST8Sia2的表达和靶底物的多唾液化。我们还发现宿主ST8Sia2的化学和遗传抑制增加了哺乳动物细胞中的寄生虫负荷。这些发现提示了一种通过调节宿主多唾液化来干扰寄生虫感染的新方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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