青霉素酶基因异源表达及该酶分解牛奶中残留青霉素的研究

以获得大量青霉素酶并将其用于分解牛奶中残留青霉素为目的, 通过PCR方法从蜡样芽孢杆菌ATCC10987基因组中获得了青霉素酶基因, 将该基因克隆至表达载体pET28a(+)中, 并转化到E. coli BL21中; 在IPTG诱导下对目的蛋白进行SDS-PAGE和酶活分析, 结果显示最大酶活力可达到480.0 U/mL; 利用Ni2+亲合层析柱纯化目的蛋白, 纯化后的目的蛋白纯度超过90%; 采用高碘酸钠氧化法制备固定化的青霉素酶, 并利用该固定化酶将牛奶(含0.5 U青霉素G/mL)中的青霉素分解到浓度小于4 ppb程度。     

青霉素酶基因异源表达及该酶分解牛奶中残留青霉素的研究

以获得大量青霉素酶并将其用于分解牛奶中残留青霉素为目的,通过PCR方法从蜡样芽孢杆菌ATCC10987基因组中获得了青霉素酶基因,将该基因克隆至表达载体pET28a( )中,并转化到E. coli BL21中;在IPTG诱导下对目的蛋白进行SDS-PAGE和酶活分析,结果显示最大酶活力可达到480.0 U/mL;利用Ni2 亲合层析柱纯化目的蛋白,纯化后的目的蛋白纯度超过90%;采用高碘酸钠氧化法制备固定化的青霉素酶,并利用该固定化酶将牛奶(含0.5 u青霉素G/mL)中的青霉素分解到浓度小于4 ppb程度.     

Preparation of gram quantities of a purified R-factor-mediated penicillinase from Escherichia coli strain W3310

Purified penicillinase, in gram quantities, has been prepared from Escherichia coli strain W3310 by using methods developed to handle large amounts of material. The final product had a specific enzyme activity of 3.08 units/mug of protein, which was over twice as high as that reported previously (Datta & Richmond, 1966). The purified enzyme was similar to that from E. coli strain TEM, but different in molecular weight and some other respects. The differences observed may be a result of the greater purity obtained.     

Cloning of the genes for penicillinase, penP and penI, of Bacillus licheniformis in some vector plasmids and their expression in Escherichia coli, Bacillus subtilis, and Bacillus licheniformis.

By using plasmid pMB9, penicillinase genes (penP and penI) from both the wild-type and constitutive strains of Bacillus licheniformis 9945A were cloned in EScherichia coli. When a low-copy-number plasmid was used, both wild-type and constitutive penicillinase genes could be transferred into Bacillus subtilis. However, when a high-copy-number plasmid was used, only the genes of the wild type could be transferred. These recombinant plasmids in B. subtilis could all be transferred by the protoplast transformation procedure into B. licheniformis. Transformants of E. coli were resistant to ampicillin (20 micrograms/ml) in spite of the low penicillinase activities (7 U/mg of cells). However, transformants of B. subtilis and B. licheniformis were sensitive to ampicillin (20 micrograms/ml) even in high penicillinase activities (more than 10,000 U/mg of cells). The secretion of penicillinase was rarely observed in E. coli. In contrast, penicillinases secreted from transformants of B. subtilis and B. licheniformis were around 30 and 60% of the total activities, respectively. We took advantage of the plasmids to permit the construction of hetero- and mero-polyploid structures in host cells, and we discuss a regulatory mechanism of penicillinase synthesis in B. licheniformis.     

Glyceride-cysteine lipoproteins and secretion by Gram-positive bacteria.

The membrane penicillinases of Bacillus licheniformis and Bacillus cereus are lipoproteins with N-terminal glyceride thioether modification identical to that of the Escherichia coli outer membrane lipoprotein. They are readily labeled with [3H]palmitate present during exponential growth. At the same time, a few other proteins in each organism become labeled and can be detected by fluorography after sodium dodecyl sulfate-polyacrylamide gel electrophoresis of total membrane proteins. We distinguish these proteins from the O-acyl proteolipids by demonstrating the formation of glyceryl cysteine sulfone after performic acid oxidation and hydrolysis of the protein. By this criterion, B. licheniformis and B. cereus contain sets of lipoproteins larger in average molecular weight than that of E. coli. Members of the sets probably are under a variety of physiological controls, as indicated by widely differing relative labeling intensity in different media. The set in B. licheniformis shares with membrane penicillinase a sensitivity to release from protoplasts by mild trypsin treatment, which suggests similar orientation on the outside of the membrane. At least one protein is the membrane-bound partner of an extracellular hydrophilic protein, the pair being related as membrane and exopenicillinases are. We propose that the lipoproteins of gram-positive organisms are the functional equivalent of periplasmic proteins in E. coli and other gram-negative bacteria, prevented from release by anchorage to the membrane rather than by a selectively impermeable outer membrane.     

Modification and processing of Bacillus licheniformis prepenicillinase in Escherichia coli. Fate of mutant penicillinase lacking lipoprotein modification site

We have previously shown that Bacillus licheniformis prepenicillinase is modified and processed to form membrane-bound penicillinase in Escherichia coli which contains N-acylglyceride-cysteine27 at the NH2 terminus. In the present study, we have constructed, by in vitro site-directed mutagenesis, two mutant penicillinase genes in which the modification site (the 27th cysteine residue in prepenicillinase) is either converted into serine (penPSer27) or is deleted along with the preceding four residues (Ala23 to Cys27, delta penP2327). The modification, processing, and subcellular localization of these two mutant penicillinases in E. coli cells were studied. Our results indicate that the delta penP2327 deletion mutant prepenicillinase is largely metabolically inert and the unmodified and uncleaved form is associated with the membrane fraction; a small fraction (about 7-9%) appears to contain glyceride-modified prepenicillinase (presumably at the Cys-21 position) which is not cleaved. In contrast, the Cys-27 in equilibrium Ser-27 point mutant prepenicillinase is processed into two forms which contain Asn-29 and Ser-35 at their NH2 termini, respectively, and the bulk of the processed penicillinase appears to be located in the peri-plasm. These results are discussed in terms of the substrate specificities of signal peptidases in E. coli.     

Drug Resistance of Enteric Bacteria

The strains of gram-negative rod bacteria which are resistant to α-aminobenzylpenicillin and do not harbor the R factors were selected from our stock cultures of clinical origin. It was found that all strains produced β-lactamases which are species-specific in their substrate profiles and classified into three groups; 1) Typical cephalosporinase in the strains of Escherichia freundii, Aerobacter aerogenes, Arizona, Proteus morganii, Proteus rettgeri, Proteus inconstans and a strain GN633 of the Serratia group. 2) Cephalosporinase in the strains of Proteus vulgaris and a strain GN629 of the Serratia group, which has a property of penicillinase to some extent. 3) Penicillinase in the strains of Escherichia coli, Klebsiella pneumoniae and Proteus mirabilis. It was found that cephalosporinase was generally inducible enzyme, penicillinase was constitutive, and the penicillinase synthesized by the strains carrying R factors belonged to the third group. Penicillinases of two R factors, RGN14 and RGN238 which were isolated in this laboratory and belonged to the penicillinase of the third group, were studied by comparing their substrate profiles and immunological properties. It was demonstrated that penicillinases of RGN14 and RGN238 differed each other, while the penicillinase of K. pneumoniae was quite similar to that of RGN14 both enzymologically and immunologically.     

Effect of in vitro DNA rearrangement in the NH2-terminal region of the penicillinase gene from Bacillus licheniformis on the mode of expression in Bacillus subtilis

We have constructed secretion vector plasmids that have unique BglII sites within or near the signal sequence of Bacillus licheniformis penicillinase, and have also constructed penicillinase cartridges that lack either one, two or three of the processing sites for the membrane-bound, exo-large and exo-small enzymes. Each of these penicillinase cartridges was cloned on secretion vectors in Bacillus subtilis, and enzyme production was examined. The presence of both the signal sequence and the three host-specific processing sites on the secretion vector was required for an effective expression of the enzyme in B. subtilis. The presence of any of the processing sites on the cartridge reduced the accumulation of penicillinase in the culture medium. When a vector plasmid lacking part of the hydrophobic region of the signal sequence and lacking the three processing sites was used, total penicillinase production decreased and enzyme accumulation in the medium was extremely low, despite the complete or incomplete presence of the processing sites on the cartridge. Molecular mass determination of these extracellular penicillinases suggested the existence of a new cleavage site for the enzyme.     

Carbenicillin-hydrolyzing penicillinases of Proteus mirabilis and the PSE-type penicillinases of Pseudomonas aeruginosa

Three carbenicillin-hydrolyzing penicillinases were found in Proteus mirabilis strains, N-3, N-29, and GN79. The former two strains were isolated in 1978, but strain GN79 was one of our stock cultures isolated in 1965. These penicillinases closely resembled each other, and the PSE-1 and PSE-4 enzymes produced by Pseudomonas aeruginosa, in their substrate profiles and kinetic properties for hydrolyzing various beta-lactams. However, differences were found in their molecular weights and isoelectric points which ranged from 22,000 to 27,000 and from 6.0 to 6.9, respectively. The antiserum against the purified penicillinase of N-29 cross-reacted with the enzyme of N-3 and inhibited its activity by more than 80%. The antiserum also reacted with the PSE-1 and PSE-4 enzymes. The antiserum did not react with the penicillinase from strain GN79 and the PSE-2 and PSE-3 enzymes of P. aeruginosa. Enzyme production in N-3 and N-29 was mediated by R plasmids.     

The penicillinase of Bacillus licheniformis is an outer membrane protein in Escherichia coli.

The cloned gene coding for Bacillus licheniformis penicillinase (penP) was introduced into Escherichia coli in a heat-inducible lambda Qam vector. After induction, significant amounts of penicillinase were synthesized in the new host. The cellular location of the penicillinase was found to be almost exclusively the outer membrane fraction of E. coli, and virtually no soluble penicillinase was found. According to sodium dodecyl sulfate-gel electrophoresis, the size of the penicillinase from E. coli was identical to that of the membrane-bound form of the B. licheniformis penicillinase. Gel filtration in the presence of Triton X-100 suggested that the penicillinase from E. coli had amphiphilic properties, as does B. licheniformis membrane penicillinase. These results show that the export of the penicillinase to the outer membrane of E. coli involves the cleavage of the signal peptide from the prepenicillinase, giving an outer membrane component indistinguishable from the membrane penicillinase of B. licheniformis.     

Comparative studies on extracellular penicillinases of the same structural gene, penP, expressed in Bacillus licheniformis and Bacillus subtilis

Extracellular penicillinases produced by Bacillus licheniformis ATCC 9945A and Bacillus subtilis from the same structural gene, penP, were compared. The two strains secreted the same exo-large penicillinase (mol. wt, 305000; isoelectric point, pI = 5.00-5.04; NH2-terminal amino acid, Ser). In contrast, the exo-small enzyme from Bacillus subtilis (mol. wt, 29500; pI = 5.00-5.04; NH2-terminal amino acid, Glu or Asn) was slightly different from that of Bacillus licheniformis (mol. wt, 29500; pI = 5.13; NH2-terminal amino acid, Lys). The difference in the NH2-terminal residue is most probably due to differences in degradation by host-specific proteolytic enzymes.     

Molecular cloning and nucleotide sequence of the type I beta-lactamase gene from Bacillus cereus

The gene for the type I beta-lactamase from Bacillus cereus has been cloned in Bacillus subtilis and Escherichia coli. In B. subtilis, penicillinase activity is detected and the enzyme is secreted. In E. coli, the gene confers ampicillin resistance. The cloned insert is 4.3 kb in length and DNA sequencing has revealed the location of the gene, its promoter and signal peptide.     

Excretion of the penicillinase of an alkalophilic Bacillus sp. through the Escherichia coli outer membrane.

Two plasmids containing the penicillinase gene of alkalophilic Bacillus sp. strain 170, pEAP1 and pEAP2, were constructed. Most of the penicillinase produced by Escherichia coli, which carried these plasmids, was found in the culture medium. This excretion is caused by the cloned DNA fragment which contains some component that changes the outer membrane of E. coli.     

High-production mutant Claviceps purpurea 59 accumulating secoclavines

Abstract A new cloning vehicle, pEAP37 was constructed to develop the excretion system of Escherichia coli . This plasmid, derived from pEAP1, carried the penicillinase gene from an alkalophilic Bacillus sp. and the chloramphenicol acetyltransferase gene from pBR329 as selective markers. The Bacillus N-4 cellulase gene, Bacillus 1139 cellulase gene and Aeromonas sp. 212 xylanase L gene was inserted into pEAP37, and the distribution of the plasmid-encoded enzymes was analyzed. Most of these enzyme activities were found in the periplasmic space of E. coli when these extracellular enzyme genes were inserted into pBR322. On the other hand, most of these activities were observed in the culture medium when inserted into pEAP37.     

Molecular cloning and expression of Bacillus licheniformis beta-lactamase gene in Escherichia coli and Bacillus subtilis.

The chromosomal beta-lactamase (penicillinase, penP) gene from Bacillus licheniformis 749/C has been cloned in Escherichia coli. The locations of the target sites for various restriction enzymes on the 4.2-kilobase EcoRI fragment were determined. By matching the restriction mapping data with the potential nucleotide sequences of the penP gene deduced from known protein sequence, we established the exact position of the penP gene on the fragment. A bifunctional plasmid vector carrying the penP gene, plasmid pOG2165, was constructed which directs the synthesis of the heterologous beta-lactamase in both E. coli and Bacillus subtilis hosts. The protein synthesized in E. coli and B. subtilis is similar in size to the processed beta-lactamase made in B. licheniformis. Furthermore, the beta-lactamase made in B. subtilis is efficiently secreted by the host into the culture medium, indicating that B. subtilis is capable of carrying out the post-translational proteolytic cleavage(s) to convert the membrane-bound precursor enzyme into the soluble extracellular form.     

Penicillinases of Klebsiella pneumoniae and Their Phylogenetic Relationship to Penicillinases Mediated by R Factors

On the assumption that the penicillinase determinants on a group of R factors conferring ampicillin resistance have a phylogenetically close relationship to the penicillinase gene of the Klebsiella group, the penicillinases from four strains of K. pneumoniae, GN69, GN1103R⁻, GN422, and GN118, were purified 230- to 1,000-fold and compared with the known two R-factor-mediated penicillinases. By gel filtration on Sephadex G-75, the molecular weights were estimated to be 17,400, 18,100, 20,000 and 18,300, respectively, which are slightly lower than those of the R-factor penicillinases. The isoelectric points of the Klebsiella penicillinases were not in agreement with those of the R-factor penicillinases. All the enzymes showed a pH optimum between 6.3 to 7.2 and a temperature optimum of 45 C, and those properties, together with behavior towards inhibitors, were about the same as those in the R-factor penicillinases. The substrate specificity and the Michaelis constants of the Klebsiella penicillinases for penicillins and cephaloridine were broadly similar to those of the R-factor penicillinases, however, some variations were found even among the four penicillinases of K. pneumoniae. The reactivities of the four penicillinases of K. pneumoniae with the antiserum against one R-factor penicillinase were tested, and three of the four Klebsiella penicillinases were found to be indistinguishable immunologically from both R-factor penicillinases. The remaining Klebsiella penicillinase, from GN1103R⁻, showed an immunological partial homology with the R-factor penicillinases.     

Bacillus subtilis secretes a foreign protein by the signal sequence of Bacillus amyloliquefaciens neutral protease

Summary We constructed a secretion plasmid in which a truncated penicillinase gene of Bacillus licheniformis was introduced at the end of the signal peptide coding region of a Bacillus amyloliquefaciens neutral protease gene. A Bacillus subtilis recombinant secreted about 140 mg/liter of the penicillinase into the medium. Analysis of the purified product revealed that it was a mixture of two penicillinases containing one or two additional amino acids at the NH₂-terminus of B. licheniformis exo-small penicillinase.     

Penicillinase-releasing protease of Bacillus licheniformis: purification and general properties.

The membrane penicillinase of Bacillus licheniformis 749/C is a phospholipoprotein which differs from the exoenzyme in that it has an additional sequence of 24 amino acid residues and a phosphatidylserine at the NH2 terminus. In exponential-phase cultures, the conversion of membrane penicillinase to exoenzyme occurs at neutral and alkaline pH. An enzyme that will cleave the membrane penicillinase to yield the exoenzyme is present (in small amounts) in exponential-phase cells and is released during their conversion to protoplasts. The enzyme is found in the filtrate of a stationary-phase culture of the uninduced penicillinase-inducible strain 749 and has been purified to apparent homogeneity from this source. The protease has an approximate molecular weight of 21,500 and requires Ca2+ ions for stabilization. It has a pH optimum of 7.0 to 9.5 for hydrolysis of casein and for the cleavage of membrane penicillinase. Both activities are inhibited by diisopropylfluorophosphate; hence, the enzyme is a serine protease. This enzyme may be entirely responsible for the formation of exopenicillinase by this organism, since the other neutral and alkaline proteases of strain 749 have little, if any, activity in releasing exopenicillinase. The enzyme has been termed penicillinase-releasing protease.