Stannous fluoride forms aggregates between outer and inner membranes leading to membrane rupture of Porphyromonas gingivalis and Prevotella pallens.

IF 3 Q1 DENTISTRY, ORAL SURGERY & MEDICINE

Frontiers in oral health Pub Date : 2024-06-26 eCollection Date: 2024-01-01 DOI:10.3389/froh.2024.1427008

Sancai Xie, Vighter Iberi, Ying Boissy, Cheryl S Tansky, Tom Huggins, Niranjan Ramji, Aaron R Biesbrock

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Abstract

Objective: Stannous has been shown to bind to free lipopolysaccharides, thus preventing them from binding to TLR receptors. This study was undertaken to determine the histomorphological mechanism of stannous binding to anaerobic bacteria.

Methods: Two bacteria associated with gingivitis and advanced periodontal disease, Porphyromonas gingivalis (P. gingivalis) and Prevotella pallens (P. pallens), were cultured in 25-1,000 μM of stannous fluoride and stannous chloride for 48 h. The growth rate was estimated using absorbance OD600. Bacterial cells were then fixed and processed for transmission electron microscopy (TEM) analysis.

Results: Stannous fluoride inhibited proliferation of both P. gingivalis and P. pallens in a dose-dependent manner. There was a statistically significant suppression of the growth curve starting at 100 μM for P. pallens (P = 0.050) and 200 μM for P. gingivalis (P = 0.039). TEM analysis revealed a thick layer of polysaccharides (19.8 nm) in P. gingivalis. The outer and inner membranes were clearly visible with low electron densities in both bacteria. Stannous diffused into bacterial membranes and formed precipitates in the areas spanning outer and inner membranes and below inner membranes. Precipitates varied in size ranging from 46.4 to 84.5 nm in length, and 18.4 to 35.9 nm in width. The membranes were disintegrated in the region where stannous formed precipitates. Cytosolic contents were leaked out, and in several cases, small vesicles were formed. Stannous precipitates were more abundant in numbers and larger in size in bacteria treated with high concentrations (100-300 μM) than in low concentrations (25-50 μM) of stannous fluoride. Furthermore, most of the bacteria were disintegrated in the groups treated with 100-300 μM stannous fluoride. At low concentrations (25 μM), stannous fluoride formed complexes primarily around outer membranes, to which lipopolysaccharides are anchored. Stannous chloride results showed similar trends, but it was less potent than stannous fluoride.

Conclusion: Stannous fluoride can penetrate bacteria, bind to the constituents of the membrane and form precipitates between outer and inner membranes and beneath inner membranes. These large precipitates damaged the integrity of membranes and allowed cytosolic contents to be leaked out. Stannous complexes formed at the outer membranes, even at low concentrations (25 μM).

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氟化亚锡在外膜和内膜之间形成聚集体，导致牙龈卟啉单胞菌（Porphyromonas gingivalis）和苍白前驱菌（Prevotella pallens）的膜破裂。

目的研究表明，亚锡可与游离脂多糖结合，从而阻止其与TLR受体结合。本研究旨在确定亚锡与厌氧菌结合的组织形态学机制：方法：将两种与牙龈炎和晚期牙周病有关的细菌--牙龈卟啉单胞菌（P. gingivalis）和苍白前孢子菌（P. pallens）--在 25-1,000 μM 的氟化亚锡和氯化亚锡中培养 48 小时。利用吸光度 OD600 估算生长速度。然后固定细菌细胞并进行透射电子显微镜（TEM）分析：结果：氟化亚锡以剂量依赖的方式抑制了牙龈脓杆菌和苍白脓杆菌的增殖。从 100 μM 开始，P. pallens（P = 0.050）和 P. gingivalis（P = 0.039）的生长曲线分别受到统计学意义上的显著抑制。TEM 分析显示，牙龈脓胞中有一层厚厚的多糖（19.8 nm）。两种细菌的外膜和内膜清晰可见，电子密度较低。亚锡扩散到细菌膜中，在跨越外膜和内膜的区域以及内膜下方形成沉淀物。沉淀物大小不一，长度从 46.4 纳米到 84.5 纳米不等，宽度从 18.4 纳米到 35.9 纳米不等。在亚锡形成沉淀的区域，膜被破坏。细胞膜内容物渗出，有几个还形成了小囊泡。与低浓度（25-50 μM）的氟化亚锡相比，高浓度（100-300 μM）的氟化亚锡沉淀物数量更多，体积更大。此外，在使用 100-300 μM 氟化亚锡处理的组中，大多数细菌都被分解了。在低浓度（25 μM）下，氟化亚锡主要在外膜周围形成复合物，脂多糖固定在外膜上。氯化亚锡的结果显示出类似的趋势，但其效力低于氟化亚锡：结论：氟化亚锡能穿透细菌，与膜的成分结合，并在外膜和内膜之间以及内膜下方形成沉淀。这些大型沉淀物破坏了膜的完整性，使细胞膜内容物渗出。即使浓度很低（25 μM），外膜上也会形成亚锡复合物。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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