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“小动物”的分子细胞学:对(和)的个人回忆

Molecular Cytology of 'Little Animals': Personal Recollections of (and ).

作者信息

Nanninga Nanne

机构信息

Molecular Cytology, Swammerdam Institute for Life Sciences (SILS), University of Amsterdam, 1098 XH Amsterdam, The Netherlands.

出版信息

Life (Basel). 2023 Aug 21;13(8):1782. doi: 10.3390/life13081782.

DOI:10.3390/life13081782
PMID:37629639
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10455606/
Abstract

This article relates personal recollections and starts with the origin of electron microscopy in the sixties of the previous century at the University of Amsterdam. Novel fixation and embedding techniques marked the discovery of the internal bacterial structures not visible by light microscopy. A special status became reserved for the freeze-fracture technique. By freeze-fracturing chemically fixed cells, it proved possible to examine the morphological effects of fixation. From there on, the focus switched from bacterial structure as such to their cell cycle. This invoked bacterial physiology and steady-state growth combined with electron microscopy. Electron-microscopic autoradiography with pulses of [H] Dap revealed that segregation of replicating DNA cannot proceed according to a model of zonal growth (with envelope-attached DNA). This stimulated us to further investigate the sacculus, the peptidoglycan macromolecule. In particular, we focused on the involvement of penicillin-binding proteins such as PBP2 and PBP3, and their role in division. Adding aztreonam (an inhibitor of PBP3) blocked ongoing divisions but not the initiation of new ones. A PBP3-independent peptidoglycan synthesis (PIPS) appeared to precede a PBP3-dependent step. The possible chemical nature of PIPS is discussed.

摘要

本文讲述了个人回忆,始于上世纪六十年代阿姆斯特丹大学电子显微镜的起源。新颖的固定和包埋技术标志着发现了光学显微镜下不可见的细菌内部结构。冷冻断裂技术具有特殊地位。通过对化学固定的细胞进行冷冻断裂,证明可以研究固定的形态学效应。从那时起,重点从细菌结构本身转向了它们的细胞周期。这引发了细菌生理学和稳态生长与电子显微镜的结合。用[H] Dap脉冲进行的电子显微镜放射自显影显示,复制DNA的分离不能按照区域生长模型(DNA附着于包膜)进行。这促使我们进一步研究细胞壁,即肽聚糖大分子。特别是,我们关注青霉素结合蛋白如PBP2和PBP3的参与及其在分裂中的作用。添加氨曲南(PBP3抑制剂)可阻断正在进行的分裂,但不影响新分裂的起始。一种不依赖PBP3的肽聚糖合成(PIPS)似乎先于依赖PBP3的步骤。文中讨论了PIPS可能的化学性质。

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