The Noc region of Ti plasmid C58 codes for arginase and ornithine cyclodeaminase

Plant tumors induced by Agrobacterium tumefaciens synthesize a group of substances (opines) which can serve as sole source of carbon and nitrogen for the bacteria. We investigate Ti-plasmid-coded genes and enzymes involved in catabolism of the opine N2-(1,3-dicarboxypropyl)-L-arginine (nopaline) with a novel approach: expression and mapping of protein-coding regions in Escherichia coli minicells, followed by identification of enzyme functions in the heterologous E. coli background. The results show that a specific part of the nopaline catabolism (Noc) region of Ti plasmid C58 is packed with closely spaced protein-coding regions which can be expressed into polypeptides of distinct sizes in E. coli. We identify and map three enzyme activities: nopaline oxidase, arginase and ornithine cyclodeaminase, an unusual protein converting ornithine directly into proline. Nopaline oxidase requires two different Noc-gene-encoded proteins for function and the latter two enzymes are new discoveries in the Noc region. These three enzyme activities together constitute a catabolic pathway leading from nopaline through arginine and ornithine to proline.     

Expression of the nopaline synthase gene in Escherichia coli

The Agrobacterium tumor-inducing (Ti) plasmid pTiT37 encodes nopaline synthase (NOS) gene (nos) with eukaryotic promoter elements that is expressed in transformed plant cells but not in the bacterial host. We have fused the nos gene to the Escherichia coli trp promoter, and observed synthesis of NOS in E. coli. The nopaline produced by this enzyme is excreted into the culture medium. NOS is enzymatically active at 30 degrees C but not 37 degrees C, as based on nopaline production. NOS protein is produced at both temperatures, based on production in minicells.     

Cloning and expression of Thiobacillus versutus aspartate-semialdehyde dehydrogenase gene in Escherichia coli

The Thiobacillus versutus asd gene coding for aspartate-semialdehyde dehydrogenase was cloned in Escherichia coli cells using pBR322 as a vector. The gene was expressed independently of its orientation, suggesting that E. coli RNA polymerase recognized T. versutus promoter sequence. The T. versutus DNA coded protein, of the molecular weight 44,000, was identified by the analysis of the proteins produced by minicells.     

Cloning and expression of the Escherichia coli recA gene in Bacillus subtilis

By means of homopolymer dG-dC tailing, using PstI linearized pBR327 as vector, we constructed small plasmids containing the entire Escherichia coli recA gene. The 1.8-kb inserts were recloned in the Bacillus subtilis expression vector pPL608 in a B. subtilis recE4 strain. Analysis of plasmid-coded proteins showed expression of the E. coli recA gene both in minicells and whole cells of B. subtilis. Expression was under control of the bacteriophage SP02 promoter, which is part of pPL608. A recA-expressing plasmid completely abolished the transformation deficiency of the recE4 mutant as well as its sensitivity to mitomycin C (MC). The expressed recA gene also restored recombination in other B. subtilis strains lacking the recE gene product. These results indicate a high similarity between the functions of the E. coli RecA and B. subtilis RecE proteins.     

Topographical distribution of penicillin-binding proteins in the Escherichia coli membrane.

The penicillin-binding proteins (PBPs) found in the membranes of Escherichia coli X925 minicells (primarily cell ends or septa) were compared with those found in rod-shaped cells (primarily sidewalls) in an effort to determine whether certain PBPs are unevenly distributed over the bacterial cell membrane. The seven major PBPs of E. coli were all present in minicell membranes. PBP 1B was altered in minicells, however, appearing as two bands on sodium dodecyl sulfate-polyacrylamide gels rather than the usual three. PBP 2, which is needed for longitudinal growth of the cell but not for septum formation, was significantly reduced in minicell membranes. This observation is consistent with the fact that minicells contain very little sidewall material and raises the possibility that the specialized function of PBP 2 may be determined or regulated by its uneven topographical distribution in the membrane. None of the PBPs appeared to be selectively enriched in minicell membranes.     

Phosphoenolpyruvate:sugar phosphotransferase system of Bacillus subtilis: cloning of the region containing the ptsH and ptsI genes and evidence for a crr-like gene.

The genes ptsI and ptsH, which encode, respectively, enzyme I and Hpr, cytoplasmic proteins involved in the phosphoenolpyruvate:sugar phosphotransferase system, were cloned from Bacillus subtilis. A plasmid containing a 4.1-kilobase DNA fragment was shown to complement Escherichia coli mutations affecting the ptsH and ptsI genes. In minicells this plasmid expressed two proteins with the molecular weights expected for Hpr and enzyme I. Therefore, ptsH and ptsI are adjacent in B. subtilis, as in E. coli. In E. coli a third gene (crr), involved in glucose translocation and also in catabolite repression, is located downstream from the ptsHI operon. The 4.1-kilobase fragment from B. subtilis was shown to contain a gene that enables an E. coli crr mutant to use glucose. This gene, unlike the E. coli crr gene, was located to the left of ptsH.     

Modification, processing, and subcellular localization in Escherichia coli of the pCloDF13-encoded bacteriocin release protein fused to the mature portion of beta-lactamase.

A fusion between the pCloDF13-derived bacteriocin release protein and beta-lactamase was constructed to investigate the subcellular localization and posttranslational modification of the bacteriocin release protein in Escherichia coli. The signal sequence and 25 of the 28 amino acid residues of the mature bacteriocin release protein were fused to the mature portion of beta-lactamase. The hybrid protein (Mr, 31,588) was expressed in minicells and whole cells and possessed full beta-lactamase activity. Immunoblotting of subcellular fractions revealed that the hybrid protein is present in both the cytoplasmic and outer membranes of E. coli. Radioactive labeling experiments in the presence or absence of globomycin showed that the hybrid protein is modified with a diglyceride and fatty acids and is processed by signal peptidase II, as is the murein lipoprotein. The results indicated that the pCloDF13-encoded bacteriocin release protein is a lipoprotein which is associated with both membranes of E. coli cells.     

Efficiency of phage protein synthesis in lambda-infected E. coli minicells

Phage lambda major head protein, the gene E product, has been identified among other phage proteins synthesized in lambda-infected Escherichia coli minicells, separated by SDS-acrylamide gel electrophoresis. On stained gels, the same protein has also been detected among total (bacterial and phage) proteins of lambda-infected minicells. The contribution of lambda proteins to the total protein content of lambda-infected minicells was found to be about 12% following 30 min lambda-infection. The inhibition of lambda early protein synthesis (shown by other authors in nucleate bacterial cells) practically does not occur in minicells; this may be the reason of the observed high efficiency of phage protein synthesis.     

Expression of the nodulation gene nod C of Rhizobium meliloti in Escherichia coli: role of the nod C gene product in nodulation

The nod C gene of Rhizobium meliloti encodes a protein of mol. wt. 44 000 which is highly conserved in at least three Rhizobium species. In order to overproduce this protein, a gene fusion of lambda cI repressor sequences to a large fragment of nod C was constructed. The fusion was placed under control of the tac promoter on plasmid pEA305 to yield pJS1035. IPTG-induced Escherichia coli cells harbouring pJS1035 accumulated the cI-nod C hybrid protein up to 19% of total cellular protein. The synthesis of the hybrid protein drastically inhibits the growth rate of the bacterium. The fusion protein was purified by gel and hydroxyapatite chromatography in the presence of SDS. Antibodies raised against the purified fusion protein precipitated the mol. wt. 44 000 nod C proteins of R. meliloti and of the broad-host range Rhizobium strain NGR234, which were both expressed in E. coli mini-cells. The hybrid protein is associated with the outer membrane of E. coli cells, and the cI-nod C fusion protein appears to be an integral membrane protein. Nodulation of alfalfa by R. meliloti and of clover by R. trifolii was markedly inhibited (approximately 50%) by the addition of antibodies against the hybrid protein to plant growth medium and inoculum.     

Failure to trigger the autolytic enzymes in minicells of Escherichia coli

Minicells from Escherichia coli P678-54 are refractory towards procedures known to induce bacteriolysis of DNA-containing E. coli cells. Although still engaged in murein synthesis, minicells could not be lysed by penicillin G. Likewise, endogenous overproduction of the cloned soluble lytic transglycosylase, the predominant murein hydrolytic activity in E. coli, failed to lyse minicells. Furthermore, induction of the phage MS2 lysis protein, a hydrophobic protein assumed to trigger the autolytic system of the host, did not result in bacteriolysis. It is concluded that the murein hydrolases present in minicells are under a tight cellular control.     

Identification of three urease accessory proteins that are required for urease activation in Arabidopsis

Urease is a nickel-containing urea hydrolase involved in nitrogen recycling from ureide, purine, and arginine catabolism in plants. The process of urease activation by incorporation of nickel into the active site is a prime example of chaperone-mediated metal transfer to an enzyme. Four urease accessory proteins are required for activation in Klebsiella aerogenes. In plants urease accessory proteins have so far been only partially defined. Using reverse genetic tools we identified four genes that are necessary for urease activity in Arabidopsis (Arabidopsis thaliana; ecotypes Columbia and N?ssen). Plants bearing T-DNA or Ds element insertions in either the structural gene for urease or in any of the three putative urease accessory genes AtureD, AtureF, and AtureG lacked the corresponding mRNAs and were defective in urease activity. In contrast to wild-type plants, the mutant lines were not able to support growth with urea as the sole nitrogen source. To investigate whether the identified accessory proteins would be sufficient to support eukaryotic urease activation, the corresponding cDNAs were introduced into urease-negative Escherichia coli. In these bacteria, urease activity was observed only when all three plant accessory genes were coexpressed together with the plant urease gene. Remarkably, plant urease activation occurred as well in cell-free E. coli extracts, but only in extracts from cells that had expressed all three accessory proteins. The future molecular dissection of the plant urease activation process may therefore be performed in vitro, providing a powerful tool to further our understanding of the biochemistry of chaperone-mediated metal transfer processes in plants.     

Functional expression and characterization of a bacterial light-harvesting membrane protein in Escherichia coli and cell-free synthesis systems

Heterologous expression of a bacterial light-harvesting (LH) integral membrane protein was attempted using Escherichia coli cells and cell-free synthesis systems prepared from E. coli extracts. The alpha-apoprotein of LH1 complex from purple photosynthetic bacterium Rhodospirillum rubrum was overexpressed as a recombinant protein with a histidine (His6) tag added to the carboxyl terminus. Both of the expression systems produced alpha-apoprotein in a fully functional form as can judged by its ability to form a structural subunit with native beta-apoprotein and the pigment molecule bacteriochlorophyll a. The expression product in E. coli appears to be located in the inner cell membrane and can be almost completely extracted by 0.5% (w/v) Triton X-100. Circular dichroism measurement indicated that the expressed alpha-apoproteins from both systems had alpha-helical contents essentially identical with that of the native one. About two thirds of the alpha-apoprotein expressed in E. coli was found to have the amino terminal methionine residue modified by a formyl group. About one third of the alpha-apoprotein expressed in the cell-free system was found to be oxidized at the side chain of the amino terminal methionine residue. Functional expression of the alpha-apoprotein using the cell-free system provides an useful example for producing highly hydrophobic integral membrane proteins with relatively large quantities sufficient for biophysical and structural analysis.     

Expression of cloned plasmid regions encoding colonization factor antigen I (CFA/I) in Escherichia coli

Molecular cloning from a plasmid encoding colonization factor antigen I (CFA/I) and heat-stable enterotoxin isolated two regions, 1 and 2, that are required for the production of CFA/I fimbriae. The level of CFA/I synthesis measured by ELISA was similar in an Escherichia coli K12 strain carrying regions 1 and 2 cloned separately on compatible plasmid vectors to that in the same strain containing the parental plasmid. The structural gene for the CFA/I fimbrial subunit was within region 1. This region directed production in E. coli minicells of at least six independent polypeptides, of which the fimbrial subunit and at least three others appeared to be synthesized as precursor molecules that underwent processing. Cloned DNA containing CFA/I region 2 specified three polypeptides in minicells. Attempts to reduce the size of the cloned region 1 resulted in a derivative plasmid that carried the CFA/I structural gene but did not complement a region-2 recombinant plasmid to restore production of CFA/I fimbriae.