The KH and S1 domains of Escherichia coli polynucleotide phosphorylase are necessary for autoregulation and growth at low temperature

Maura Epifanía Matus-Ortega , Maria Elena Regonesi , Alberto Piña-Escobedo , Paolo Tortora , Gianni Dehò , Jaime García-Mena
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引用次数: 39

Abstract

PNPase is a phosphate-dependent exonuclease of Escherichia coli required for growth in the cold. In this work we explored the effect of specific mutations in its two RNA binding domains KH and S1 on RNA binding, enzymatic activities, autoregulation and ability to grow at low temperature. We removed critical motifs that stabilize the hydrophobic core of each domain, as well as made a complete deletion of both (ΔKHS1) that severely impaired PNPase binding to RNA. Nevertheless, a residual RNA binding activity, possibly imputable to catalytic binding, could be observed even in the ΔKHS1 PNPase. These mutations also resulted in significant changes in the kinetic behavior of both phosphorolysis and polymerization activities of the enzyme, in particular for the double mutant Pnp-ΔKHS1-H. Additionally, PNPases with mutations in these RNA binding domains did not autoregulate efficiently and were unable to complement the growth defect of a chromosomal Δpnp mutation at 18 °C. Based on these results it appears that in E. coli the RNA binding domains of PNPase, in particular the KH domain, are vital at low temperature, when the stem–loop structures present in the target mRNAs are more stable and a machinery capable to degrade structured RNA may be essential.

大肠杆菌多核苷酸磷酸化酶的KH和S1结构域是低温下自我调节和生长所必需的
PNPase是大肠杆菌在寒冷环境中生长所必需的一种磷酸依赖的核酸外切酶。在这项工作中,我们探讨了其两个RNA结合域KH和S1的特异性突变对RNA结合、酶活性、自动调节和低温生长能力的影响。我们去除了稳定每个结构域疏水核心的关键基序,并完全删除了这两个基序(ΔKHS1),严重损害了PNPase与RNA的结合。然而,即使在ΔKHS1 PNPase中也可以观察到残留的RNA结合活性,这可能归因于催化结合。这些突变还导致酶的磷酸化和聚合活性的动力学行为发生显著变化,特别是双突变体Pnp-ΔKHS1-H。此外,在这些RNA结合区域发生突变的PNPases不能有效地自动调节,并且不能在18°C下补充染色体Δpnp突变的生长缺陷。基于这些结果,似乎在大肠杆菌中,PNPase的RNA结合结构域,特别是KH结构域,在低温下是至关重要的,当目标mrna中的茎环结构更稳定时,能够降解结构化RNA的机制可能是必不可少的。
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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