Instituto de Investigaciones Biotecnológicas, Universidad Nacional de San Martín (UNSAM)-Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), Escuela de Bio y Nanotecnologías (EByN), Universidad Nacional de San Martín, San Martín, Buenos Aires, Argentina.
mBio. 2023 Feb 28;14(1):e0333822. doi: 10.1128/mbio.03338-22. Epub 2023 Jan 9.
Host cell egress is a critical step in the life cycle of intracellular pathogens, especially in microbes capable of establishing chronic infections. The Gram-negative bacterium Brucella belongs to such a group of pathogens. Even though much has been done to understand how Brucella avoids killing and multiplies in its intracellular niche, the mechanism that this bacterium deploys to egress from the cell to complete its cycle has been poorly studied. In the manuscript, we quantify the kinetics of bacterial egress and show that Brucella exploits multivesicular bodies to exit host cells. For the first time, we visualized the process of egress in real time by live video microscopy and showed that a population of intracellular bacteria exit from host cells in vacuoles containing multivesicular body-like features. We observed the colocalization of Brucella with two multivesicular markers, namely, CD63 and LBPA, both during the final stages of the intracellular life cycle and in egressed bacteria. Moreover, drugs that either promote or inhibit multivesicular bodies either increased or decreased the number of extracellular bacteria, respectively. Our results strongly suggest that Brucella hijacks multivesicular bodies to exit the host cells to initiate new infection events. How intracellular bacterial pathogens egress from host cells has been poorly studied. This is particularly important because this stage of the infectious cycle can have a strong impact on how the host resolves the infection. Brucella is an intracellular pathogen that infects mammals, including humans, and causes a chronic debilitating illness. The bacterium has evolved a plethora of mechanisms to invade host cells, avoid degradation in the endocytic pathway, and actively multiply within a specialized intracellular compartment. However, how this pathogen exits from infected cells to produce reinfection and complete its life cycle is poorly understood. In the manuscript, we shed some light on the mechanisms that are exploited by Brucella to egress from host cells. We observed for the first time the egress of Brucella from infected cells by time-lapse video microscopy, and we found that the bacterium exits in vesicles containing multivesicular bodies (MVBs) features. Moreover, the drug manipulation of MVBs resulted in the alteration of bacterial egress efficiency. Our results indicate that Brucella hijacks MVBs to exit host cells and that this strongly contributes to the reinfection cycle.
宿主细胞外吐是细胞内病原体生命周期中的一个关键步骤,尤其是在能够建立慢性感染的微生物中。革兰氏阴性菌布鲁氏菌就属于此类病原体。尽管已经做了很多工作来了解布鲁氏菌如何避免在其细胞内小生境中被杀死和繁殖,但这种细菌用于从细胞中逸出以完成其周期的机制尚未得到很好的研究。在本文中,我们量化了细菌外吐的动力学,并表明布鲁氏菌利用多泡体从宿主细胞中逸出。我们首次通过实时视频显微镜实时观察到外吐过程,并显示一群细胞内细菌从含有多泡体样特征的空泡中从宿主细胞中逸出。我们观察到布鲁氏菌与两种多泡体标记物 CD63 和 LBPA 的共定位,无论是在细胞内生命周期的最后阶段还是在逸出的细菌中都是如此。此外,促进或抑制多泡体的药物分别增加或减少了细胞外细菌的数量。我们的研究结果强烈表明,布鲁氏菌劫持多泡体从宿主细胞中逸出,以启动新的感染事件。 细胞内细菌病原体如何从宿主细胞中逸出尚未得到很好的研究。这一点尤其重要,因为感染周期的这一阶段会对宿主如何解决感染产生强烈影响。布鲁氏菌是一种感染哺乳动物(包括人类)并引起慢性虚弱疾病的细胞内病原体。该细菌已经进化出多种机制来入侵宿主细胞、避免在吞噬途径中降解,并在专门的细胞内隔室中积极繁殖。然而,这种病原体如何从受感染的细胞中逸出以产生再感染并完成其生命周期仍知之甚少。在本文中,我们揭示了布鲁氏菌从宿主细胞中逸出所利用的一些机制。我们首次通过延时视频显微镜观察到布鲁氏菌从感染细胞中的逸出,我们发现细菌从含有多泡体 (MVB) 特征的小泡中逸出。此外,MVB 的药物操纵导致细菌外吐效率的改变。我们的结果表明,布鲁氏菌劫持 MVB 从宿主细胞中逸出,这强烈促进了再感染周期。
