CNC - Center for Neuroscience and Cell Biology, University of Coimbra, Coimbra, Portugal.
X-PROT, Cantanhede, Portugal.
mBio. 2021 Dec 21;12(6):e0305921. doi: 10.1128/mBio.03059-21. Epub 2021 Dec 7.
Rickettsiae are obligate intracellular Gram-negative bacteria transmitted by arthropod vectors. Despite their reduced genomes, the function(s) of the majority of rickettsial proteins remains to be uncovered. APRc is a highly conserved retropepsin-type protease, suggested to act as a modulator of other rickettsial surface proteins with a role in adhesion/invasion. However, APRc's function(s) in bacterial pathogenesis and virulence remains unknown. This study demonstrates that APRc targets host serum components, combining nonimmune immunoglobulin (Ig)-binding activity with resistance to complement-mediated killing. We confirmed nonimmune human IgG binding in extracts of different rickettsial species and intact bacteria. Our results revealed that the soluble domain of APRc is capable of binding to human (h), mouse, and rabbit IgG and different classes of human Ig (IgG, IgM, and IgA) in a concentration-dependent manner. APRc-hIgG interaction was confirmed with total hIgG and normal human serum. APRc-hIgG displayed a binding affinity in the micromolar range. We provided evidence of interaction preferentially through the Fab region and confirmed that binding is independent of catalytic activity. Mapping the APRc region responsible for binding revealed the segment between amino acids 157 and 166 as one of the interacting regions. Furthermore, we demonstrated that expression of the full-length protease in Escherichia coli is sufficient to promote resistance to complement-mediated killing and that interaction with IgG contributes to serum resistance. Our findings position APRc as a novel Ig-binding protein and a novel moonlighting immune evasion factor of , contributing to the arsenal of virulence factors utilized by these intracellular pathogens to aid in host colonization. Many organisms are pathogenic to humans, causing severe infections, like Rocky Mountain spotted fever and Mediterranean spotted fever. However, immune evasion mechanisms and pathogenicity determinants in rickettsiae are far from being resolved. We provide evidence that the highly conserved rickettsial retropepsin-type protease APRc displays nonimmune immunoglobulin (Ig)-binding activity and participates in serum resistance. APRc emerges then as a novel Ig-binding protein from Gram-negative bacteria and the first to be identified in . Bacterial surface proteins capable of Ig binding are known to be multifunctional and key players in immune evasion. We demonstrate that APRc is also a novel moonlighting protein, exhibiting different actions on serum components and acting as a novel evasin. This work strengthens APRc as a virulence factor in and its significance as a potential therapeutic target. Our findings significantly contribute to a deeper understanding of the virulence strategies used by intracellular pathogens to subvert host immune responses.
立克次体是一种专性细胞内革兰氏阴性细菌,通过节肢动物载体传播。尽管它们的基因组较小,但大多数立克次体蛋白的功能仍有待发现。APRc 是一种高度保守的 retropepsin 型蛋白酶,被认为是一种调节其他立克次体表面蛋白的调节剂,在黏附和入侵中起作用。然而,APRc 在细菌发病机制和毒力中的作用尚不清楚。本研究表明,APRc 靶向宿主血清成分,将非免疫免疫球蛋白(Ig)结合活性与对补体介导杀伤的抗性结合在一起。我们在不同立克次体物种和完整细菌的提取物中证实了非免疫人 IgG 结合。我们的结果表明,APRc 的可溶性结构域能够以浓度依赖的方式结合人(h)、鼠和兔 IgG 以及不同类别的人 Ig(IgG、IgM 和 IgA)。APRc-hIgG 相互作用已在总 hIgG 和正常人类血清中得到证实。APRc-hIgG 显示出微摩尔范围内的结合亲和力。我们提供了通过 Fab 区域进行相互作用的证据,并证实结合与催化活性无关。映射负责结合的 APRc 区域表明,氨基酸 157 至 166 之间的片段是相互作用区域之一。此外,我们证明了全长蛋白酶在大肠杆菌中的表达足以促进对补体介导杀伤的抗性,并且与 IgG 的相互作用有助于血清抗性。我们的研究结果将 APRc 定位为一种新型的 Ig 结合蛋白和一种新型的多功能免疫逃避因子,有助于这些细胞内病原体利用的毒力因子库,以帮助宿主定植。许多生物体对人类具有致病性,导致严重感染,如落基山斑点热和地中海斑点热。然而,立克次体的免疫逃避机制和致病性决定因素还远未得到解决。我们提供的证据表明,高度保守的立克次体 retropepsin 型蛋白酶 APRc 显示出非免疫免疫球蛋白(Ig)结合活性,并参与血清抗性。APRc 随后作为革兰氏阴性细菌中的一种新型 Ig 结合蛋白出现,也是首次在 中被发现。能够结合 Ig 的细菌表面蛋白已知具有多功能性,是免疫逃避的关键因素。我们证明 APRc 也是一种新型的多功能蛋白,对血清成分具有不同的作用,并作为一种新型的逃避因子发挥作用。这项工作加强了 APRc 在 中的毒力因子地位及其作为潜在治疗靶点的意义。我们的发现极大地促进了对细胞内病原体用来颠覆宿主免疫反应的毒力策略的更深入理解。
