Abstract
Zinc ions play indispensable roles in biological chemistry. However, bacteria have an impressive ability to acquire Zn(2+) from the environment, making it exceptionally difficult to achieve Zn(2+) deficiency, and so a comprehensive understanding of the importance of Zn(2+) has not been attained. Reduction of the Zn(2+) content of Escherichia coli growth medium to 60 nm or less is reported here for the first time, without recourse to chelators of poor specificity. Cells grown in Zn(2+)-deficient medium had a reduced growth rate and contained up to five times less cellular Zn(2+). To understand global responses to Zn(2+) deficiency, microarray analysis was conducted of cells grown under Zn(2+)-replete and Zn(2+)-depleted conditions in chemostat cultures. Nine genes were up-regulated more than 2-fold (p < 0.05) in cells from Zn(2+)-deficient chemostats, including zinT (yodA). zinT is shown to be regulated by Zur (zinc uptake regulator). A mutant lacking zinT displayed a growth defect and a 3-fold lowered cellular Zn(2+) level under Zn(2+) limitation. The purified ZinT protein possessed a single, high affinity metal-binding site that can accommodate Zn(2+) or Cd(2+). A further up-regulated gene, ykgM, is believed to encode a non-Zn(2+) finger-containing paralogue of the Zn(2+) finger ribosomal protein L31. The gene encoding the periplasmic Zn(2+)-binding protein znuA showed increased expression. During both batch and chemostat growth, cells "found" more Zn(2+) than was originally added to the culture, presumably because of leaching from the culture vessel. Zn(2+) elimination is shown to be a more precise method of depleting Zn(2+) than by using the chelator N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine.
Highlights
Almost all biological interactions depend upon contacts between precisely structured protein domains, and Zn2ϩ may be used to facilitate correct folding and stabilize the domain [1, 2]
Despite its indispensable role in biology, as with all metals, Zn2ϩ can become toxic if accumulated to excess
Outten and O’Halloran [3] found that the minimal Zn2ϩ content required for growth in E. coli is 2 ϫ 105 atoms/cell, which corresponds to a total cellular Zn2ϩ concentration of 0.2 mM, ϳ2000 times the Zn2ϩ concentration found in the medium
Summary
ROLES FOR HIGH AFFINITY ZINC BINDING BY ZinT, ZINC TRANSPORT AND ZINC-INDEPENDENT PROTEINS*□S. During the course of this work, a paper was published [9] in which the authors conclude that ZinT (formerly YodA) “is involved in periplasmic zinc binding and either the subsequent import or shuttling of zinc to periplasmic zinc-containing proteins under zinc-limiting conditions.”. This conclusion was drawn from experiments in which Zn2ϩ levels in the medium were lowered only by reducing the amount of Zn2ϩ added, without metal extraction or chelation. The authors note that TPEN has been reported to bind Cd2ϩ, Co2ϩ, Ni2ϩ, and Cu2ϩ more tightly than it binds Zn2ϩ, and 34 of the 101 differentially regulated
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
