Cellular localization of the Escherichia coli SpoT protein.

The SpoT protein of Escherichia coli serves as a source of degradation as well as an apparent source of synthesis of (p)ppGpp. Since the subcellular localization of SpoT might be a clue to its function, we have used SpoT-specific antisera to analyze cell extracts fractionated on sucrose gradients. We find that the SpoT protein is not bound to ribosomes or to either inner or outer membrane fractions. Although the SpoT protein is found in large aggregates, its localization is probably cytosolic.     

Guanosine 5'-diphosphate 3'-diphosphate (ppGpp) synthetic activities on Escherichia coli SpoT domains

Escherichia coli SpoT protein, with 702 amino acid residues, is a bifunctional enzyme catalyzing both guanosine 5'-diphosphate 3'-diphosphate (ppGpp) degradation and its synthesis. First, we investigated how many domains are included in SpoT protein, by limited hydrolysis of the protein with serine proteases, alpha-chymotrypsin, and elastase. Based on the results, we deduced that SpoT protein is composed of two major domains, an N-terminal half domain from Met1 to Phe373 and a C-terminal half domain from Glu374 to Asn702 (C-terminal end). In addition, by a further alpha-chymotrypsin digestion, two cleaved sites were found at Arg196 in the N-terminal half domain (D12) and at Lys475 in the C-terminal half domain (D34), to produce four minor domains, D1, D2, D3, and D4. Next, plasmids expressing the two major domains (D12 and D34) and four minor domains (D1, D2, D3, and D4) were constructed. Consequently, the deduced SpoT minor domains as well as the major domains were expressed as stable protein units, except for D4. D4 may also be folded into a stable protein in E. coli cells, since high expression of D4 from a plasmid results in host cell lethality. E. coli relA -, spoT- double null strains expressing D1, D2, and D12 recovered cell growth in M9 minimal medium, but the transformants of D3, D4, and D34 did not grow in the minimal medium. This indicates that ppGpp synthetic activities could be restricted in the N-terminal half domain (D12, D1, and D2).     

Accumulation of ppGpp in a relA mutant of Escherichia coli during amino acid starvation

In Escherichia coli, amino acid starvation triggers the rapid synthesis of two guanosine polyphosphates, pppGpp and ppGpp (the 3'-pyrophosphates of GTP and GDP, respectively). Determination of the turnover rate of the ppGpp pool indicated that during serine deprivation, as opposed to other amino acid starvations, the rate of ppGpp degradation is dramatically decreased. This results in a slow but significant accumulation of this regulatory nucleotide in a relA mutant during serine starvation. Similar ppGpp accumulation can be seen during serine starvation in different serine auxotrophic mutants carrying different relA alleles. On the other hand, no ppGpp accumulation is induced in various relaxed strains by serine hydroxamate treatment.     

Cross-species complementation of the indispensable Escherichia coli era gene highlights amino acid regions essential for activity.

Era is an essential GTP binding protein in Escherichia coli. Two homologs of this protein, Sgp from Streptococcus mutans and Era from Coxiella burnetii, can substitute for the essential function of Era in E. coli. Site-specific and randomly generated Era mutants which may indicate regions of the protein that are of functional importance are described.     

Polyribosome metabolism in Escherichia coli starved for an amino acid

Most polyribosomes are inferred to be inert in starving cells, but some are in a dynamic state, since (1) messenger RNA continues to enter polyribosomes; (2) about 20 to 40% of the polyribosomes are labile after rifampycin addition; (3) β-galactosidase can be induced with a lag period no more than three times as long as in growing cells; and (4) the apparent rate of synthesis of protein chains, judged by the distribution of pulse-labeled protein between ribosomes and soluble protein, is about half that in growing cells.     

SecY is an indispensable component of the protein secretory machinery of Escherichia coli

Using a reconstitution system for protein translocation, the involvement of SecY in the translocation of secretory proteins across the cytoplasmic membrane of Escherichia coli was studied. Anti-SecY antibodies raised against the N- and C-terminal sequences prevented the functional reconstitution of the translocation system. Depletion of SecY from the solubilized membrane preparation was performed by treatment with anti-SecY IgG, followed by removal of IgG with protein A-agarose. The SecY-depleted preparation was inactive as to functional reconstitution. However, reconstitution with it was demonstrated in the presence of a protein fraction, which was released from the anti-SecY immunoprecipitate upon addition of the SecY fragment used to raise the antibody. Reconstitution with the SecY-depleted membrane fraction was also demonstrated in the presence of a purified SecY preparation. OmpT proteinase specifically cleaved SecY in the solubilized membrane preparation. The cleavage was accompanied by a decrease in the reconstituted activity. Based on these findings we conclude that SecY is an indispensable component of the secretory machinery.     

Regulation of protein synthesis inEscherichia coli by amino acid analogues

Эффект phenylserine, аналоговый от Фенилаланин, и по proteosynthesis на создание искусственных β-galactosidase был изучен в разных штаммов Escherichia коли-либо аминокисл от. Было установлено, что в Escherichia титр сер (вс-gly) вс-phenylserine препятствует включе нию от аланин и β-galactosidase формирование в присутствии этих важнейших аминокислот. В среднесрочной его недостатками стимулируется как включение и β-galactosidase синтез. Включение аминокисл от и формирование энзима не были затронуты в Escherichia титр phe-в полной средой. В недостаткам и среднего phenylserine увеличился регистра ции, но не влияет на β-galactosidase синте за. Было также установле но, что phenylserine-1-14C была включена в белк и из Escherichia коли-phe. Стимуляторы эффект в phenylserine Escherichia титр услуг, gly-было расследовано и было установлено, чт о аналог было разбито и benzaldehyde глицин. Механизм действия эт ого Аналог на разных в идов недостатками мутантов из Escherichia коли обсуждается.     

ppGpp cycle in Escherichia coli.

Summary Kinetics of accumulation and degradation of ppGpp and pppGpp were analysed in spoT ⁺ and spoT strains of Escherichia coli. The experimental data in this paper indicate that on degradation ppGpp is not converted to pppGpp but instead is converted to GDP which is in turn phosphorylated to GTP. In addition the data are consistent with the idea the pppGpp is a direct precursor of ppGpp. We propose that ppGpp is metabolised according to the following pathway: GTP-pppGpp-ppGpp-GDP-GTP, which we call the ppGpp cycle. Coupled with the observations in spoT strains we assume that ppGpp blocks its own synthesis by inhibiting the synthesis of pppGpp but not the interconversion of the two nucleotides.     

Metabolic costs of amino acid and protein production in Escherichia coli

Escherichia coli is the most popular microorganism for the production of recombinant proteins and is gaining increasing importance for the production of low-molecular weight compounds such as amino acids. The metabolic cost associated with the production of amino acids and (recombinant) proteins from glucose, glycerol and acetate was determined using three different computational techniques to identify those amino acids that put the highest burden on the biosynthetic machinery of E. coli. Comparing the costs of individual amino acids, we find that methionine is the most expensive amino acid in terms of consumed mol of ATP per molecule produced, while leucine is the most expensive amino acid when taking into account the cellular abundances of amino acids. Moreover, we show that the biosynthesis of a large number of amino acids from glucose and particularly from glycerol provides a surplus of energy, which can be used to balance the high energetic cost of amino acid polymerization.     

Synthesis, no synthesis, or synthesis and degradation of ribosomal ribonucleic acid in various Escherichia coli strains starved for an amino acid

A standard stringent strain of Escherichia coli makes little or no ribosomal ribonucleic acid (RNA) during starvation for an essential amino acid, whereas the isogenic relaxed strain makes both ribosomal and messenger RNA. A third class of strains was found which continues to make ribosomal RNA during starvation, but the RNA made is apparently unstable. There is little accumulation of RNA in the third class of strains, and few complete newly formed chains of (3)H-ribosomal RNA are observed in sedimentation analyses, even after long labeling times.     

Identification of a 21 amino acid peptide conferring 3-hydroxypropionic acid stress-tolerance to Escherichia coli

We report the identification of a novel small open reading frame in Escherichia coli. The sORF (called iroK) encodes a 21 amino cid peptide, which when translated confers a 133% (ca. 20 g/L) increase in resistance to 3-hydroxypropionic acid. We show that iroK conferred tolerance is additive to previously identified tolerance mechanisms involving relief of inhibited metabolism, yet does not involve altered 3-HP transport. This result demonstrates the continued surprises that microbial genomes hold and emphasize the importance of comprehensive discovery methods in future strain and metabolic engineering efforts.