高通量分析表明,吞噬成功的时间尺度取决于目标韧性。

IF 2.9 Q2 BIOPHYSICS
Biophysics reviews Pub Date : 2021-09-01 Epub Date: 2021-09-30 DOI:10.1063/5.0057071
Layla A Bakhtiari, Marilyn J Wells, Vernita D Gordon
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引用次数: 3

摘要

吞噬细胞免疫细胞可以通过吞噬病原体来清除体内的病原体。细菌生物膜是细菌群落,它们在基质中结合在一起,使生物膜具有自由游动细菌所不存在的粘弹性机械特性。由于中性粒细胞太小,无法吞噬整个生物膜,如果要利用吞噬作用清除感染,它必须能够一次分离并吞噬一些细菌。我们最近发现靶弹性与吞噬成功率之间存在负相关。早期的工作使用了耗时的人工分析中性粒细胞和荧光珠的显微照片。在这里,我们介绍并验证了流式细胞术是一种快速、高通量的技术,它可以将每次实验分析的中性粒细胞数量增加两个数量级,同时还可以将分析所需的时间从数小时减少到数分钟。我们还介绍了聚丙烯酰胺凝胶在吞噬试验中的应用。聚丙烯酰胺凝胶的可调性扩展了我们可以研究的力学参数空间,我们发现高韧性和屈服应变,即使具有低弹性,也会影响吞噬成功率及其时间尺度。对于具有低产量菌株和由此产生的低韧性的硬凝胶,当中性粒细胞与凝胶孵育6小时时,吞噬成功率几乎是仅孵育1小时后的四倍。相反,对于具有高产量应变和高韧性的软凝胶,成功的吞噬对时间的敏感性要低得多,从1到6小时的孵育增加不到2倍。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

High-throughput assays show the timescale for phagocytic success depends on the target toughness.

High-throughput assays show the timescale for phagocytic success depends on the target toughness.

Phagocytic immune cells can clear pathogens from the body by engulfing them. Bacterial biofilms are communities of bacteria that are bound together in a matrix that gives biofilms viscoelastic mechanical properties that do not exist for free-swimming bacteria. Since a neutrophil is too small to engulf an entire biofilm, it must be able to detach and engulf a few bacteria at a time if it is to use phagocytosis to clear the infection. We recently found a negative correlation between the target elasticity and phagocytic success. That earlier work used time-consuming, manual analysis of micrographs of neutrophils and fluorescent beads. Here, we introduce and validate flow cytometry as a fast and high-throughput technique that increases the number of neutrophils analyzed per experiment by two orders of magnitude, while also reducing the time required to do so from hours to minutes. We also introduce the use of polyacrylamide gels in our assay for engulfment success. The tunability of polyacrylamide gels expands the mechanical parameter space we can study, and we find that high toughness and yield strain, even with low elasticity, also impact the phagocytic success as well as the timescale thereof. For stiff gels with low-yield strain, and consequent low toughness, phagocytic success is nearly four times greater when neutrophils are incubated with gels for 6 h than after only 1 h of incubation. In contrast, for soft gels with high-yield strain and consequent high toughness, successful engulfment is much less time-sensitive, increasing by less than a factor of two from 1 to 6 h incubation.

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