Enzymatically enhanced ultrastructure expansion microscopy unlocks expansion of in vitro Toxoplasma gondii cysts.

IF 3.7 2区 生物学 Q2 MICROBIOLOGY mSphere Pub Date : 2024-09-25 Epub Date: 2024-08-27 DOI:10.1128/msphere.00322-24
Kseniia Bondarenko, Floriane Limoge, Kayvon Pedram, Mathieu Gissot, Joanna C Young
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Abstract

Expansion microscopy (ExM) is an innovative approach to achieve super-resolution images without using super-resolution microscopes, based on the physical expansion of the sample. The advent of ExM has unlocked the detail of super-resolution images for a broader scientific circle, lowering the cost and entry skill requirements for the field. One of its branches, ultrastructure expansion microscopy (U-ExM), has become popular among research groups studying apicomplexan parasites, including the acute stage of Toxoplasma gondii infection. Here, we show that the chronic cyst-forming stage of Toxoplasma, however, resists U-ExM expansion, impeding precise protein localization. We then solve the in vitro cyst's resistance to denaturation required for successful U-ExM. As the cyst's main structural protein CST1 contains a mucin domain, we added an enzymatic digestion step using the pan-mucinase StcE prior to the expansion protocol. This allowed full expansion of the cysts in fibroblasts and primary neuronal cell culture without disrupting immunofluorescence analysis of parasite proteins. Using StcE-enhanced U-ExM, we clarified the localization of the GRA2 protein, which is important for establishing a normal cyst, observing GRA2 granules spanning across the CST1 cyst wall. The StcE-U-ExM protocol allows accurate pinpointing of proteins in the bradyzoite cyst, which will greatly facilitate investigation of the underlying biology of cyst formation and its vulnerabilities.

Importance: Toxoplasma gondii is an intracellular parasite capable of establishing long-term chronic infection in nearly all warm-blooded animals. During the chronic stage, parasites encapsulate to form cysts predominantly in neurons and skeletal muscle. Current anti-Toxoplasma drugs do not eradicate chronic parasites, leaving a reservoir of infection. The cyst is critical for disease transmission and pathology, yet it is harder to study, with the function of many chronic-stage proteins still unknown. Ultrastructure expansion microscopy, a new method to overcome the light microscopy's diffraction limit by physically expanding the sample, allowed in-depth studies of acute Toxoplasma infection. We show that Toxoplasma cysts resist expansion using standard protocol, but an additional enzymatic digestion with the mucinase StcE allows full expansion. This protocol offers new avenues for examining the chronic stage, including precise spatial organization of cyst-specific proteins, linking these locations to morphological structures, and detailed investigations of components of the durable cyst wall.

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酶促超微结构扩展显微镜揭示了体外弓形虫囊肿的扩展过程。
膨胀显微镜(ExM)是一种无需使用超分辨显微镜就能获得超分辨图像的创新方法,它以样品的物理膨胀为基础。ExM 的出现为更广泛的科学界揭开了超分辨率图像的神秘面纱,降低了该领域的成本和入门技能要求。超微结构扩展显微镜(U-ExM)是其分支之一,在研究弓形虫寄生虫(包括弓形虫感染的急性期)的研究小组中很受欢迎。在这里,我们发现弓形虫的慢性囊肿形成阶段会抵制 U-ExM 扩增,从而阻碍蛋白质的精确定位。然后,我们解决了体外囊肿抗变性的问题,这是 U-ExM 成功所必需的。由于囊肿的主要结构蛋白 CST1 含有一个粘蛋白结构域,我们在扩增方案之前增加了一个使用泛粘蛋白酶 StcE 进行酶解的步骤。这样,囊肿就能在成纤维细胞和原代神经元细胞培养中完全扩增,而不会影响寄生虫蛋白的免疫荧光分析。利用 StcE 增强 U-ExM,我们明确了 GRA2 蛋白的定位,GRA2 蛋白对建立正常囊肿非常重要,我们观察到 GRA2 颗粒横跨 CST1 囊壁。StcE-U-ExM方案可精确定位缓虫包囊中的蛋白质,这将极大地促进对包囊形成的潜在生物学及其脆弱性的研究:弓形虫是一种细胞内寄生虫,几乎能在所有温血动物体内建立长期慢性感染。在慢性阶段,寄生虫主要在神经元和骨骼肌中包裹形成囊肿。目前的抗弓形虫药物无法根除慢性寄生虫,从而留下了一个感染库。囊肿对疾病的传播和病理变化至关重要,但却较难研究,许多慢性期蛋白质的功能仍不清楚。超微结构扩展显微镜是一种通过物理扩展样本来克服光学显微镜衍射极限的新方法,可对弓形虫急性感染进行深入研究。我们的研究表明,弓形虫囊肿在使用标准方案时会抗拒扩张,但使用粘蛋白酶 StcE 进行额外的酶解后,囊肿就能完全扩张。该方案为研究慢性阶段提供了新的途径,包括囊肿特异性蛋白质的精确空间组织、将这些位置与形态结构联系起来以及对持久囊壁成分的详细研究。
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来源期刊
mSphere
mSphere Immunology and Microbiology-Microbiology
CiteScore
8.50
自引率
2.10%
发文量
192
审稿时长
11 weeks
期刊介绍: mSphere™ is a multi-disciplinary open-access journal that will focus on rapid publication of fundamental contributions to our understanding of microbiology. Its scope will reflect the immense range of fields within the microbial sciences, creating new opportunities for researchers to share findings that are transforming our understanding of human health and disease, ecosystems, neuroscience, agriculture, energy production, climate change, evolution, biogeochemical cycling, and food and drug production. Submissions will be encouraged of all high-quality work that makes fundamental contributions to our understanding of microbiology. mSphere™ will provide streamlined decisions, while carrying on ASM''s tradition for rigorous peer review.
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