Protein secretion controlled by a synthetic gene in Escherichia coli

The inability of Escherichia coli to secrete proteins in growth medium is one of the major drawbacks in its use in genetic engineering. A synthetic gene, homologous to the one coding for the kil peptide of pColE1, was made and cloned under the control of the lac promoter, in order to obtain the inducible secretion of homologous or heterologous proteins by E. coli. The efficiency of this synthetic gene to promote secretion was assayed by analysing the production and secretion of two proteins, the R-TEM1 beta-lactamase, and the alpha-amylase from Bacillus licheniformis. This latter protein was expressed in E. coli from its gene either on the same plasmid as the kil gene or on a different plasmid. The primary effect of the induction of the kil gene is the overproduction of the secreted proteins. When expressed at a high level, the kil gene promotes the overproduction of all periplasmic proteins and the total secretion in the culture medium of both the beta-lactamase or the alpha-amylase. This secretion is semi-selective for most periplasmic proteins are not secreted. The kil peptide induces the secretion of homologous or heterologous proteins in two steps, first acting on the cytoplasmic membrane, then permeabilizing the outer membrane. This system, which is now being assayed at the fermentor scale, is the first example of using a synthetic gene to engineer a new property into a bacterial strain.     

Cell toxicity caused by products of the p(L) operon of bacteriophage lambda.

Induction of a lambda prophage causes the death of the host cell even in the absence of phage replication and lytic functions due to expression of functions from the lambda p(L) operon. We genetically modified the lambda prophage to determine which lambda p(L) operon functions were involved in cell killing. Viability assays and flow cytometry were used to monitor cell death and filamentation. The kil gene was shown to cause cell death and filamentation as described previously. Another killing activity was mapped within the p(L) operon to the gam gene. Inspection of the DNA sequence showed that there are two possible translation start points for both kil and gam. In both cases, the shorter of the two possible products could cause cell killing. The shorter products were also sufficient for the known filamentation and recombination activities of the respective Kil and Gam functions. The expression level of the p(L) operon is down-regulated by Cro repressor. In the absence of Cro, higher p(L) expression levels allow either Kil or Gam to be lethal or growth inhibitory, whereas at lowered expression in Cro-repressed conditions, only Kil is lethal. The filamentation function of Kil and recombination activity of Gam are unaffected at Cro-repressed levels of expression.     

Expression of the cloned ColE1 kil gene in normal and Kilr Escherichia coli

The kil gene of the ColE1 plasmid was cloned under control of the lac promoter. Its expression under this promoter gave rise to the same pattern of bacterial cell damage and lethality as that which accompanies induction of the kil gene in the colicin operon by mitomycin C. This confirms that cell damage after induction is solely due to expression of kil and is independent of the cea or imm gene products. Escherichia coli derivatives resistant to the lethal effects of kil gene expression under either the normal or the lac promoter were isolated and found to fall into several classes, some of which were altered in sensitivity to agents that affect the bacterial envelope.     

Molecular cloning and characterization of the recA gene of Pseudomonas aeruginosa PAO.

The recA gene of Pseudomonas aeruginosa PAO has been isolated and introduced into Escherichia coli K-12. Resistance to killing by UV irradiation was restored in several RecA-E. coli K-12 hosts by the P. aeruginosa gene, as was resistance to methyl methanesulfonate. Recombination proficiency was also restored, as measured by HfrH-mediated conjugation and by the ability to propagate Fec-phage lambda derivatives. The cloned P. aeruginosa recA gene restored both spontaneous and mitomycin C-stimulated induction of lambda prophage in lysogens of a recA strain of E. coli K-12.     

Cloning and expression in Escherichia coli of a recA-like gene from Bacteroides fragilis

The recombinant plasmid pHG100, containing a 5.2-kb DNA fragment from Bacteroides fragilis, complemented defects in homologous recombination, DNA repair and prophage induction to various levels in an Escherichia coli recA mutant strain. There was no DNA homology between the cloned B. fragilis recA-like gene and E. coli chromosomal DNA. pHG100 produced two proteins with Mr of approx. 39,000 and 37,000 which cross-reacted with antibodies raised against E. coli RecA protein. The production of these proteins was not increased after UV induction. The cloned B. fragilis recA-like gene product did not enhance the production of native but defective E. coli RecA protein after UV irradiation.     

Postsegregational killing mediated by the P1 phage "addiction module" phd-doc requires the Escherichia coli programmed cell death system mazEF

"Addiction modules" consist of two genes; the product of the second is long lived and toxic, while the product of the first is short lived and antagonizes the lethal action of the toxin. The extrachromosomal addiction module phd-doc, located on the P1 prophage, is responsible for the postsegregational killing effect (death of plasmid-free cells). The Escherichia coli chromosomal addiction module analogue, mazEF, is responsible for the induction of programmed cell death. Here we show that the postsegregational killing mediated by the P1 phd-doc module depends on the presence of the E. coli mazEF system. In addition, we demonstrate that under conditions of postsegregational killing, mediated by phd-doc, protein synthesis of E. coli is inhibited. Based on our findings, we suggest the existence of a coupling between the phd-doc and mazEF systems.     

Suppression of induction of SOS functions in an Escherichia coli tif-1 mutant by plasmid R100.1.

The tif-1 mutation in the recA gene of Escherichia coli caused, at 40 degrees C, lethal cell filamentation, induction of the recA protein, mutagenesis, and, in lambda lysogens, prophage induction. The presence of plasmid R100.1 in tif-1 strains suppressed tif-mediated cell filamentation and killing, recA protein induction, and prophage induction in lysogens. It also reduced mutagenesis in a tif-1 sfiA11(R100.1) strain. Plasmids F'lac, P1, and pMB9, in contrast, had little or no effect on tif-mediated induction of lambda. The presence of R100.1 did not inhibit the induction of the recA protein or of lambda by ultraviolet irradiation or mitomycin C treatment of tif-1(R100.1) or tif-1(lambda)(R100.1) strains.     

Influence of the recA- mutation on spontaneous filamentation and the titer of the lambda phage in ylonB- mutants of E. coli K12 (lambda)]

A study was made of the effect of recA- mutation on the spontaneous filament formation and the spontaneous induction of the lambda prophage in the E. coli K12 strain bearing lonB- mutation. It was revealed that in the absence of a functionally-active product of the recA- gene the lonB- strain of E. coli K12 displayed but a partial depression of spontaneous formation of filamentous forms and of spontaneous induction of the lambda prophage.     

lon gene product of Escherichia coli is a heat-shock protein

The product of the pleiotropic gene lon is a protein with protease activity and has been tentatively identified as protein H94.0 on the reference two-dimensional gel of Escherichia coli proteins. Purified Lon protease migrated with the prominent cellular protein H94.0 in E. coli K-12 strains. Peptide map patterns of Lon protease and H94.0 were identical. A mutant form of the protease had altered mobility during gel electrophoresis. An E. coli B/r strain that is known to be defective in Lon function contained no detectable H94.0 protein under normal growth conditions. Upon a shift to 42 degrees C, however, the Lon protease was induced to high levels in K-12 strains and a small amount of protein became detectable at the H94.0 location in strain B/r. Heat induction of Lon protease was dependent on the normal allele of the regulatory gene, htpR, establishing lon as a member of the high-temperature-production regulon of E. coli.     

Prophage lambda induction caused by mini-F plasmid genes

Summary When bacterial cells harboring a temperaturesensitive replication plasmid, which carries the particular ccd segment of a mini-F plasmid, are transferred to 42°C, cell division is inhibited after incubation for an appropriate time. The inhibition occurs, when the copy number of the plasmid decreases to become critically low, about one per cell (Ogura and Hiraga 1983 b). In phage lysogens carrying this type of plasmid, the prophage is induced in a small portion of the cell population under the same conditions, in addition to the inhibition of cell division in most of cells. The prophage induction, but not the inhibition of normal cell division, depends on normal recA function. Both induction of prophage and inhibition of cell division are suppressed by the simultaneous presence of a replication proficient plasmid carrying the ccdA gene. We discuss molecular mechanisms of the ccd function that couples host cell division to plasmid proliferation and induces the prophage. Additionally, we propose a hypothesis that the ccd mechanism of F plasmid contributes to indirect induction of prophage by an F plasmid damaged by UV-irradiation and then introduced into a lysogen via conjugation.Abbreviations kb kilobase pairs. m.o.i., multiplicity of infection     

Amplification of the Bacillus subtilis maf gene results in arrested septum formation.

The Bacillus subtilis homolog of the Escherichia coli morphogene orfE (of the mre operon) has been identified. The determinant is located on the chromosome immediately upstream of the mreBCD-minCD (divIVB) operon. The Maf protein shares substantial amino acid sequence identity with the E. coli OrfE protein. Introduction of the B. subtilis maf determinant on a multicopy plasmid into B. subtilis cells results in an inhibition of septation, which leads to extensive filamentation and loss of viability in the transformed cell population. Insertional inactivation of maf indicated that this gene is not essential for cell division.     

Borrelia burgdorferi ftsZ plays a role in cell division

ftsZ is essential for cell division in many microorganisms. In Escherichia coli and Bacillus subtilis, FtsZ plays a role in ring formation at the leading edge of the cell division septum. An ftsZ homologue is present in the Borrelia burgdorferi genome (ftsZ(Bbu)). Its gene product (FtsZ(Bbu)) is strongly homologous to other bacterial FtsZ proteins, but its function has not been established. Because loss-of-function mutants of ftsZ(Bbu) might be lethal, the tetR/tetO system was adapted for regulated control of this gene in B. burgdorferi. Sixty-two nucleotides of an ftsZ(Bbu) antisense DNA sequence under the control of a tetracycline-responsive modified hybrid borrelial promoter were cloned into pKFSS1. This construct was electroporated into a B. burgdorferi host strain carrying a chromosomally located tetR under the control of the B. burgdorferi flaB promoter. After induction by anhydrotetracycline, expression of antisense ftsZ RNA resulted in generation of filamentous B. burgdorferi that were unable to divide and grew more slowly than uninduced cells. To determine whether FtsZ(Bbu) could interfere with the function of E. coli FtsZ, ftsZ(Bbu) was amplified from chromosomal DNA and placed under the control of the tetracycline-regulated hybrid promoter. After introduction of the construct into E. coli and induction with anhydrotetracycline, overexpression of ftsZ(Bbu) generated a filamentous phenotype. This suggested interference of ftsZ(Bbu) with E. coli FtsZ function and confirmed the role of ftsZ(Bbu) in cell division. This is the first report of the generation of a B. burgdorferi conditional lethal mutant equivalent by tetracycline-controlled expression of antisense RNA.     

Non-toxic expression in Escherichia coli of a plasmid-encoded gene for phage T4 lysozyme

The phage T4 gene coding for lysozyme has been cloned into a plasmid under control of the (trp/lac) hybrid tac promoter and expressed in Escherichia coli with no significant toxic effect to actively growing cells. E. coli D1210 (lacIq) transformed with this plasmid produced active T4 lysozyme at levels up to 2% of the cellular protein after induction with isopropyl-beta-D-thiogalactoside. A strain producing active lysozyme was shown to be under a selective disadvantage when co-cultured with a similar strain producing inactive lysozyme. Purified strains, however, are reasonably stable in culture and under normal storage conditions.     

Identification and characterization of an essential gene in Listeria monocytogenes using an inducible gene expression system

The Listeria monocytogenes gene lmo1594 is a homolog of the Bacillus subtilis cell division gene ezrA. EzrA is a negative regulator of FtsZ ring formation, which is required for efficient cell division as it regulates the frequency and position of Z-rings in the cell and prevents aberrant polar cell division. Previously identified as a putative high pressure (HP) resistance mechanism; conferring enhanced barotolerance when heterologously expressed against an Escherichia coli background; the aim of the current study was to investigate whether lmo1594 plays a role in listerial barotolerance. When the creation of a deletion mutant proved unsuccessful, the role of lmo1594 was addressed by creating a conditional knockout mutant which demonstrated that the gene is in fact essential for cell survival and growth in L. monocytogenes. In order to investigate the effect of lmo1594 on barotolerance, the gene was over-expressed. The over-expression of lmo1594 increased survival levels in L. monocytogenes treated at 300 MPa, but survival levels similar to those of the wild-type strain were observed when treated at a higher pressure (≥400 MPa). In conclusion, this study reveals for the first time that lmo1594 is absolutely essential for listerial cell growth and survival, and also plays an important role in listerial barotolerance.     

Expression of the genome of Mu-like phage D3112 specific for Pseudomonas aeruginosa in Escherichia coli and Pseudomonas putida cells

The behavior of Escherichia coli cells carrying RP4 plasmid which contains the genome of a Mu-like D3112 phage specific for Pseudomonas aeruginosa was studied. Two different types of D3112 genome expression were revealed in E. coli. The first is BP4-dependent expression. In this case, expression of certain D3112 genes designated as "kil" only takes place when RP4 is present. As a result, cell division stops at 30 degrees C and cells form filaments. Cell division is not blocked at 42 degrees C. The second type of D3112 genome expression is RP4-independent. A small number of phage is produced independently of RP4 plasmid but this does not take place at 42 degrees C. No detectable quantity of the functionally active repressor of the phage was determined in E. coli (D3112). It is possible that the only cause for cell stability of E. coli (D3112) or E. coli (RP4::D3112) at 42 degrees C in the absence of the repressor is the fact of an extremely poor expression of D3112. In another heterologous system, P. putida both ways of phage development (lytic and lysogenic) are observed. This special state of D3112 genome in E. coli cells is proposed to be named "conditionally expressible prophage" or, in short, "conex-phage", to distinguish it from a classical lysogenic state when stability is determined by repressor activity. Specific blockade of cell division, due to D3112 expression, was also found in P. putida cells. It is evident that the kil function of D3112 is not specific to recognize the difference between division machinery of bacteria belonging to distinct species or genera. Protein synthesis is needed to stop cell division and during a short time period this process could be reversible. Isolation of E. coli (D3112) which lost RP4 plasmid may be regarded as an evidence for D3112 transposition in E. coli. Some possibilities for using the system to look for E. coli mutants with modified expression of foreign genes are considered.     

Dissociation of tsl-tif-Induced Filamentation and recA Protein Synthesis in Escherichia coli K-12

In Escherichia coli, expression of the tif-1 mutation (in the recA gene) induces the "SOS response" at 40 degrees C, including massive synthesis of the recA(tif) protein, cell filamentation, appearance of new repair and mutagenic activities, and prophage induction. Expression of the tsl-1 mutation (in the lexA gene) induces massive synthesis of the recA protein and cell filamentation at 42 degrees C, although other SOS functions are not induced. In this paper we show that the septation inhibition induced in tif and tsl strains at 42 degrees C is not due to the presence of a high concentration of recA protein since (i) no recA mutants (相似文献