Cloning, expression, and purification of a functional nonacetylated mammalian mitochondrial chaperonin 10

An intact mouse mitochondrial chaperonin 10 has been cloned, sequenced, and overexpressed in Escherichia coli as a fusion protein harboring an oligohistidine tail at its COOH terminus. The latter was added to simplify protein purification. The purified protein is free of contaminating groES from the bacterial host cells. Edman degradation reveals that the initiator Met residue of the recombinant protein is removed in vivo, similar to the authentic chaperonin 10 purified from rat liver mitochondria. However, in contrast to the latter, the amino-terminal Ala residue of the recombinant protein is not acetylated; the molecular mass determined by electrospray ionization mass spectrometry is 12,350.9 +/- 2.6 daltons, in agreement with that predicted for the nonacetylated protein (12,351.2 daltons). Facilitated protein folding experiments with ribulose-biphosphate carboxylase, under "nonpermissive" in vitro conditions, demonstrate that the recombinant protein is fully functional with groEL. Thus, both the initial rates of protein folding and final yields observed with this heterologous combination are virtually identical to those obtained with groEL and groES. More important, like the authentic protein purified from mitochondria, the recombinant mitochondrial chaperonin 10, but not groES, is functionally compatible with the heptameric chaperonin 60 of mammalian mitochondria.

Cloning, sequencing and expression of stress genes from the ethanol-producing bacterium Zymomonas mobilis: the groESL operon

Zymomonas mobilis is unique among bacteria in its ability to produce high levels of ethanol (EtOH) during fermentation. Elevated EtOH concentration, like elevated temperature, is a microbial stress and a universal inducer of stress proteins. For Z. mobilis, exposure to high levels of EtOH represents a natural stress. By using a simple strategy which combines the genetic tools of Escherichia coli and Bacillus subtilis, we have cloned genes encoding two of the most abundant stress proteins in Z. mobilis, GroES and GroEL. Both genes were expressed at high levels in E. coli. Despite the unique environment (EtOH concentrations of above 10%) in which the translated products from these genes function in Z. mobilis, the amino-acid sequences encoded were remarkably similar to their homologues from bacteria which are not known to accumulate EtOH. Two small regions were observed, however, which appear more similar to Saccharomyces cerevisiae hsp60 (groEL homologue) than to E. coli or the concensus. These may be related to EtOH tolerance.

Protein chaperones and protein folding

A universal strategy for obtaining maximal protein expression or refolding remains elusive; however, headway has been made toward understanding these processes in vivo. The observation of reversible protein aggregation, asymmetry in protein-chaperone complexes, redox effects on disulfide formation, and the sequential involvement of multiple chaperones and foldases may suggest new approaches. Such new approaches include immobilized catalysts and manipulation of the bacterial periplasm.

Heat shock- and alkaline pH-induced proteins of Campylobacter jejuni: characterization and immunological properties

The protein response to physiological stress was characterized in Campylobacter jejuni 81176 after exposure to heat and pH shock and following periods of recovery. Immunoreactivities of major stress-related proteins were determined with anti-Campylobacter immune rabbit serum and intestinal lavage fluid. Distinct proteins with molecular masses ranging from 10 to 120 kDa were induced and/or released by selective heat or pH treatments. The most notable responses were those of two proteins with apparent molecular masses of 45 and 64 kDa that were induced and two other proteins of 10 and 12 kDa that were released by selective heat shock, alkaline pH treatment, or both. On the basis of N-terminal sequence analysis and immunological cross-reactivity data, the 64- and 10-kDa proteins were the C. jejuni homologs of Escherichia coli GroEL and GroES proteins, respectively. Enhanced chemiluminescence Western blotting (immunoblotting) revealed that all four proteins were among the major protein antigens recognized by anti-Campylobacter rabbit serum immunoglobulin G (IgG) and immune rabbit intestinal lavage IgA (secretory IgA). The results of this investigation suggest that the C. jejuni 10-, 12-, 45-, and 64-kDa proteins and a number of minor stress-related proteins deserve further evaluation of their respective roles in Campylobacter pathogenesis and immunity.

Increased solubility of trimethoprim-resistant type S1 DHFR from Staphylococcus aureus in Escherichia coli cells overproducing the chaperonins GroEL and GroES

The production of the trimethoprim-resistant type S1 dihydrofolate reductase (DHFR) from Staphylococcus aureus in Escherichia coli cells overproducing the chaperonins GroEL and GroES is described. The simultaneous overproduction of the chaperonins with DHFR results in an increased solubility of the enzyme. We compare the time course of production of active type S1 DHFR by measuring enzyme activity in cells overproducing or not overproducing the chaperonins. Although co-overproduction of the chaperonins reduces the total production level of type S1 DHFR, the amount of soluble and active DHFR is increased several-fold in comparison with cells producing only DHFR. Thus, the higher concentrations of GroES and GroEL in cells overproducing the chaperonins partially protect DHFR from aggregation, resulting in higher concentrations of soluble and active DHFR in the cell. Furthermore, we also demonstrate that the chaperonins can improve in vitro refolding yields of type S1 DHFR. These results suggest that it is possible to purify suitable amounts of trimethoprim-resistant type S1 DHFR for X-ray crystallographic studies.

Low-light image analysis of transgenic organisms using bacterial luciferase as a marker

Methods for measurement of a novel light-emitting reporter gene system in bacteria, yeast, plant cells, plant tissues and intact plant organs are described. The principle underlying the assay procedures is the bacterial luciferase catalysed oxidation of reduced flavin mononucleotide (FMNH2) in the presence of the ten carbon aldehyde decanal, to yield FMN, decanoic acid, water and a photon of light at 490 nm which can be captured by X-ray film, a photomultiplier tube or, for in vivo measurements, an image-intensifier coupled to a video camera. This light measuring assay system is sensitive, easy to use, inexpensive, does not require radioactivity, and has been used successfully for rapid detection of bacterial transformants, the quantitative measurement of transient and stable gene expression in bacteria and yeast, and in vivo measurement of temporal and spatial gene expression throughout plant and animal development.