Escherichia coli ribosomal protein S1 is required for the translation initiation of messenger RNAs, in particular when their Shine–Dalgarno sequence is degenerated. Closely related forms of the protein, composed of the same number of domains (six), are found in all Gram-negative bacteria. More distant proteins, generally formed of fewer domains, have been identified, by sequence similarities, in Gram-positive bacteria and are also termed ‘S1 proteins’. However in the absence of functional information, it is generally difficult to ascertain their relationship with Gram-negative S1. In this article, we report the solution structure of the fourth and sixth domains of the E. coli protein S1 and show that it is possible to characterize their β-barrel by a consensus sequence that allows a precise identification of all domains in Gram-negative and Gram-positive S1 proteins. In addition, we show that it is possible to discriminate between five domain types corresponding to the domains 1, 2, 3, 4–5 and 6 of E. coli S1 on the basis of their sequence. This enabled us to identify the nature of the domains present in Gram-positive proteins and, subsequently, to probe the filiations between all forms of S1.
Escherichia coli (E. coli) remains the most efficient widely-used host for recombinant protein production. Well-known genetics, high transformation efficiency, cultivation simplicity, rapidity and inexpensiveness are the main factors that contribute to the selection of this host. With the advent of the post-genomic era has come the need to express in this bacterium a growing number of genes originating from different organisms. Unfortunately, many of these genes severely interfere with the survival of E. coli cells. They lead to bacteria death or cause significant defects in bacteria growth that dramatically decrease expression capabilities. In this paper, we review special strategies and genetics tools successfully used to express, in E. coli, highly toxic genes. Suppression of basal expression from leaky inducible promoters, suppression of read-through transcription from cryptic promoters, tight control of plasmids copy numbers and proteins production as inactive (but reversible) forms are among the solutions presented and discussed. Special expression vectors and modified E. coli strains are listed and their effectiveness illustrated with key examples, some of which are related to our study of the highly toxic phage T4 restriction endoribonuclease RegB. We mainly selected those strategies and tools that permit E. coli normal growth until the very moment of highly toxic gene induction. Expression then occurs efficiently before cells die. Because they do not target a particular toxic effect, these strategies and tools can be used to express a wide variety of highly toxic genes.
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