Metabolic deprivation: a lead to containment in bacterial releases.

Microbial releases : viruses, bacteria, fungi Pub Date : 1994-07-01

W Klingmüller

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Abstract

Experiments were carried out in non-sterile soil, with or without several substrates (sucrose, citrate, lactose) as energy source, and with or without bacterial inoculates able or unable to utilize these substrates. The bacteria were Enterobacter agglomerans, Escherichia coli, Pseudomonas aeruginosa or Pseudomonas aureofaciens; they either did or did not contain plasmid RP4. It was found that sucrose is degraded by the indigenous microflora and/or free soil enzymes to give extracellular glucose and fructose, to support growth and plasmid transfer of all inoculated bacteria, e.g. sucrose-positive and sucrose-negative bacteria. In contrast, the growth and plasmid transfer of inoculates which do not degrade citrate is reduced in soil containing that substrate when compared to such inoculates which do degrade citrate. The growth and plasmid transfer of inoculates which do not degrade lactose is reduced strongly in soil containing that substrate, when compared to such inoculates which do degrade lactose. Lactose is degraded slowly in soil by the indigenous microflora, without giving rise to extracellular glucose. These findings indicate a possible way to achieve biological containment, via genetic defects in metabolic pathways.

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代谢剥夺:导致控制细菌释放。

实验在非无菌土壤中进行，有或没有几种基质(蔗糖、柠檬酸盐、乳糖)作为能量来源，有或没有细菌接种能够或不能利用这些基质。细菌为聚集肠杆菌、大肠杆菌、铜绿假单胞菌和金黄色假单胞菌;它们含有或不含有质粒RP4。研究发现，蔗糖可被本地菌群和/或自由土壤酶降解，生成胞外葡萄糖和果糖，以支持所有接种细菌(如蔗糖阳性和蔗糖阴性细菌)的生长和质粒转移。相反，与能降解柠檬酸盐的接种剂相比，不能降解柠檬酸盐的接种剂的生长和质粒转移在含有该基质的土壤中减少。与能降解乳糖的接种物相比，不能降解乳糖的接种物的生长和质粒转移在含有该底物的土壤中被强烈地减少。乳糖在土壤中被原生菌群缓慢降解，不产生细胞外葡萄糖。这些发现表明了通过代谢途径中的遗传缺陷实现生物遏制的可能方法。

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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Microbial releases : viruses, bacteria, fungi

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