Prospects for the genetic manipulation of lactobacilli

Medical and molecular biophysical techniques as substantial tools in the era of mRNA-based vaccine technology

The COVID-19 pandemic prompted the advancement of vaccine technology using mRNA delivery into the host cells. Consequently, mRNA-based vaccines have emerged as a practical approach against SARS-CoV-2 owing to their inherent properties, such as cost-effectiveness, rapid manufacturing, and preservation. These features are vital, especially in resource-constrained regions. Nevertheless, the design of mRNA-based vaccines is intricately intertwined with the refinement of biophysical technologies, thereby establishing their high potential. The preparation of mRNA-based vaccines involves a sequence of phases combining medical and molecular biophysical technologies. Furthermore, their efficiency depends on the capability to optimize their positive attributes, thus paving the way for their subsequent preclinical and clinical evaluations. Using biophysical techniques, the characterization of nucleic acids extends from their initial formulation to their cellular internalization abilities and encapsulation in biomolecule complexes, such as lipid nanoparticles (LNPs), for designing mRNA-based LNPs. Furthermore, nanoparticles are subjected to a series of careful screening steps to assess their physical and chemical characteristics before achieving an optimum formulation suitable for preclinical and clinical studies. This review provides a comprehensive understanding of the fundamental role of biophysical techniques in the complex development of mRNA-based vaccines and their role in the recent success during the COVID-19 pandemic.

Efficient secretion of the model antigen M6-gp41E in Lactobacillus plantarum NCIMB 8826

Four Lactobacillus strains (Lb. plantarum NCIMB 8826, Lb. paracasei LbTGS1.4, Lb. casei ATCC 393 and Lb. fermentum KLD) were tested for their ability to produce and secrete heterologous proteins. These strains were first screened with an alpha-amylase reporter under the control of a set of expression or expression/secretion signals from various lactic acid bacteria. With most of the constructions tested, the level of extracellular production was highest in Lb. plantarum NCIMB 8826, and lowest in Lb. paracasei LbTGS1.4. These two strains were next assayed using a model antigen consisting of the N-terminal part of the M6 protein from Streptococcus pyogenes fused to the linear epitope ELDKWAS from human immunodeficiency virus gp41 protein. Secretion of this heterologous protein was inefficient in Lb. paracasei LbTGS1.4, which accumulated a large intracellular pool of the unprocessed precursor, whereas Lb. plantarum NCIMB 8826 was able to secrete the antigen to a level as high as 10 mg l-1.

Genetics of lactobacilli: plasmids and gene expression

This paper reviews the present knowledge of the structure and properties of small (< 5 kb) plasmids present in Lactobacillus spp. The data show that plasmids from Lactobacillus spp., like many plasmids from other Gram-positive bacteria, display a modular organization and replicate by a mechanism of rolling circle replication. Structurally, plasmids from lactobacilli are closely related to plasmids from other Gram-positive bacteria. They contain elements (plus- and minus origin of replication, element(s) for control of plasmid replication, mobilization function) showing extensive similarity to analogous elements in plasmids from these other organisms. It is believed that lactobacilli have acquired such elements by intra- and/or intergenic transfer mechanisms. The first part of the review is concluded with a description of plasmid vectors with a Lactobacillus replicon and integrative vectors, including data concerning their structural and segregational stability. In the second part of this review we describe the progress that has been made during the last few years in identifying and characterizing elements that control expression of genetic information in lactobacilli. Based on the sequence of eleven identified and twenty presumed promoters, some preliminary conclusions can be drawn regarding the structure of Lactobacillus promoters. A typical Lactobacillus promoter shows significant similarity to promoters from E. coli and B. subtilis. An analysis of published sequences of seventy genes indicates that the region encompassing the translation start codon AUG also shows extensive similarity to that of E. coli and B. subtilis. Codon usage of Lactobacillus genes is not random and shows interspecies as well as intraspecies heterogeneity. Interspecies differences may, in part, be explained by differences in G+C content of different lactobacilli. Differences in gene expression levels can, to a large extent, account for intraspecies differences of codon usage bias. Finally, we review the knowledge that has become available concerning protein secretion and heterologous gene expression in lactobacilli. This part is concluded with a compilation of data on the expression in Lactobacillus of heterologous genes under the control of their own promoter or under control of a Lactobacillus promoter.

Antibacterial activity of three Leuconostoc strains isolated from vacuum-packaged processed meats

One hundred and fifty lactic acid bacteria (LAB) isolated from vacuum-packaged processed meats were screened for antagonistic activity against various food spoilage microorganisms and foodborne pathogens. Nineteen strains produced bacteriocins active against closely related LAB and Listeria strains. Leuconostoc carnosum (LA54a and TA26b) and Leuconostoc mesenteroides subspecies dextranicum (TA33a) produced bacteriocins that were susceptible to proteolytic enzymes, but not to catalase, lysozyme or chloroform. They were heat stable up to 100 degrees C for thirty minutes at pH 2 to 7, and exerted a bacteriolytic effect. Bacteriocin production by all Leuconostoc strains was growth associated, occurring at incubation temperatures of 0 degrees C to 30 degrees C and initial medium pH 4.5 to 7.5. Probing of plasmid DNA from the three Leuconostoc strains with an oligonucleotide probe homologous to the nucleotide sequence of leucocin A-UAL 187 indicated plasmid-mediated bacteriocin production. Homology of the three Leuconostoc bacteriocin-coding genes to the amino-terminal end of the leucocin A-UAL 187 gene from Leuconostoc gelidum UAL 187 is therefore suggested. This evidence implies that all three Leuconostoc strains produce type 2, Listeria active bacteriocins.

Gene replacement in Lactobacillus helveticus

An efficient method for gene replacement in Lactobacillus helveticus CNRZ32 was developed by utilizing pSA3 as an integration vector. This plasmid is stably maintained in CNRZ32 at 37 degrees C but is unstable at 45 degrees C. This method consisted of a two-step gene-targeting technique: (i) chromosomal integration of a plasmid carrying an internal deletion in the gene of interest via homologous recombination and (ii) excision of the vector and the wild-type gene via homologous recombination, resulting in gene replacement. By using this procedure, the chromosomal X-prolyl dipeptidyl aminopeptidase gene (pepXP) of CNRZ32 was successfully inactivated.

Functional analysis of the Lactococcus lactis usp45 secretion signal in the secretion of a homologous proteinase and a heterologous alpha-amylase

The ups45 gene encodes the major extracellular protein from Lactococcus lactis. The deduced sequence of the 27 residue leader peptide revealed the tripartite characteristics of a signal peptide. This leader peptide directed the efficient secretion of the homologous proteinase (PrtP) in L. lactis, indicating that the putative signal peptide of PrtP can be replaced by the 27 residue Usp45 leader peptide. In addition, the 27 residue leader peptide could be used to secrete the Bacillus stearothermophilus alpha-amylase, encoded by the amyS gene. Fusion of the usp45 promoter region and various parts of the leader sequence to an amyS gene devoid of its signal sequence, showed that in Escherichia coli the first 19, 20, and 27 residues of the Usp45 leader are able to direct alpha-amylase secretion. In L. lactis the shorter signal peptides did not result in secretion of alpha-amylase, providing experimental evidence for the hypothesis that gram-positive bacteria require a longer signal peptide for secretion than gram-negative organisms.

Leuconostoc lactis beta-galactosidase is encoded by two overlapping genes

A 16-kb BamHI fragment of the lactose plasmid pNZ63 from Leuconostoc lactis NZ6009 was cloned in Escherichia coli MC1061 by using pACYC184 and was found to express a functional beta-galactosidase. Deletion and complementation analysis showed that the coding region for beta-galactosidase was located on a 5.8-kb SalI-BamHI fragment. Nucleotide sequence analysis demonstrated that this fragment contained two partially overlapping genes, lacL (1,878 bp) and lacM (963 bp), that could encode proteins with calculated sizes of 72,113 and 35,389 Da, respectively. The L. lactis beta-galactosidase was overproduced in E. coli by using a lambda pL expression system. Two new proteins with M(r)s of 75,000 and 36,000 appeared upon induction of PL. The N-terminal sequences of these proteins corresponded to those deduced from the lacL and lacM gene sequences. Mutation and deletion analysis showed that lacL expression is essential for LacM production and that both the lacL and lacM genes are required for the production of a functional beta-galactosidase in E. coli. The deduced amino acid sequences of the LacL and LacM proteins showed considerable identity with the sequences of the N- and C-terminal parts, respectively, of beta-galactosidases from other lactic acid bacteria or E. coli. DNA and protein sequence alignments suggest that the L. lactis lacL and lacM genes have been generated by an internal deletion in an ancestral beta-galactosidase gene.

Construction and characterization of shuttle plasmids for lactic acid bacteria and Escherichia coli

The chimeric plasmid pBN183 was first constructed in Escherichia coli by ligating the BamHI-digested E. coli plasmid pBR322 and a Bg/II-linearized streptococcal plasmid, pNZ18. The pBN183 transformed E. coli to ApR at a frequency of (8.2 +/- 1.2) x 10(5) colony forming units (CFU)/microgram DNA. Electrotransformation of Streptococcus thermophilus with pBN183 yielded CmR, ApS clones at a frequency of (2.6 +/- 0.3) x 10(1) CFU/microgram DNA. Plasmid screening with pBN183-transformed S. thermophilus clones revealed that ca. 70% of these transformants contained deleted plasmids. Plasmid pBN183A, a pBN183 deletion mutant lacking one copy of a tandemly arranged, highly homologous DNA sequence, was isolated for further study. It transformed E. coli to ApR and S. thermophilus to CmR with frequencies of (4.8 +/- 0.1) x 10(5) and (8.1 +/- 0.2) x 10(2) CFU/microgram DNA, respectively. Screening of S. thermophilus transformants did not show the presence of deleted plasmids. Based on the structure of pBN183A, a new shuttle plasmid, pDBN183, was constructed from pBN183 by removal of the small (1.2 kb) Sa/I fragment. Transformation frequencies of pDBN183 were (5.0 +/- 1.3) x 10(5) and (4.6 +/- 0.2) x 10(2) CFU/microgram DNA with E. coli and S. thermophilus, respectively. In contrast to the parent pBN183, only 17% of the pDBN183-transformed S. thermophilus contained deleted plasmids. Plasmid copy numbers of the three vectors in E. coli were estimated at 17-18 per chromosome. The three plasmids conferred ApR and CmR to E. coli, but only CmR to S. thermophilus. The insertion of a Streptomyces cholesterol oxidase gene (choA) into pDBN183 did not affect the plasmid's stability in Lactobacillus casei, but resulted in deletion of the recombinant DNA in S. thermophilus.

Mobilization and location of the genetic determinant of chloramphenicol resistance from Lactobacillus plantarum caTC2R

The mobilization of a nonconjugative plasmid (pCaT) that mediates chloramphenicol resistance in Lactobacillus plantarum caTC2R was achieved by comobilization with the conjugative plasmid pAM beta 1. The conjugation studies confirmed that the 8.5-kb pCaT in L. plantarum caTC2R contains the gene responsible for chloramphenicol resistance and that the plasmid has several unique restriction sites which make it useful for genetic studies in Carnobacterium spp. Cloning studies showed that the gene responsible for chloramphenicol resistance is located in the 2.6-kb EcoRV-SalI region of pCaT. This was confirmed by probing the 3.0-kb BglII fragment of pCaT with a biotin-labeled 1.6-kb BstEII-HpaII fragment from the streptococcal-derived plasmid pVA797(Cmr). Expression of chloramphenicol resistance in Carnobacterium as well as in other Lactobacillus species was achieved by electrotransformation using donor DNA from pCaT.

Shuttle plasmid vectors for Lactobacillus casei and Escherichia coli with a minus origin

Recombinant plasmids which can be used as shuttle vectors between Escherichia coli and the industrially used strains of Lactobacillus casei were constructed. They have replication regions closely related to those of pUB110 and are likely to replicate by a rolling-circle mechanism via a plus-strand-specific DNA intermediate in L. casei. Both orientations of palA from the staphylococcal plasmid pC194 and those of the intergenic region from coliphage M13 are identified as active minus origins in L. casei, in contrast to the pAM alpha 1 delta 1-derived BA3 minus origin which does not function in L. casei. Stability of the plasmids increased in L. casei when one of these two active minus origins was inserted. All the DNA sequences of the constructed vectors were known.

Use of DNA probes in the study of silage colonization by Lactobacillus and Pediococcus strains

A technique to monitor lactic acid bacteria inoculants in silage, based on specific DNA probes, was developed and used to evaluate the colonization properties of two strains of Lactobacillus plantarum and one strain of Pediococcus pentosaceus which were used as maize silage inoculants in farm conditions. The results indicated that these three strains were able to dominate the natural microflora of the silage, representing more than the 95% of the bacterial biomass of the maize silage. These studies indicate that the colony hybridization with specific DNA probes may be an effective method for monitoring bacteria and evaluating the colonization properties of inoculants in maize silage.

Complementation of the inability of Lactobacillus strains to utilize D-xylose with D-xylose catabolism-encoding genes of Lactobacillus pentosus

The inability of two Lactobacillus strains to ferment D-xylose was complemented by the introduction of Lactobacillus pentosus genes encoding D-xylose isomerase, D-xylulose kinase, and a D-xylose catabolism regulatory protein. This result opens the possibility of using D-xylose fermentation as a food-grade selection marker for Lactobacillus spp.

Galactose utilization in Lactobacillus helveticus: isolation and characterization of the galactokinase (galK) and galactose-1-phosphate uridyl transferase (galT) genes

By complementing appropriate gal lesions in Escherichia coli K802, we were able to isolate the galactokinase (galK) and galactose-1-phosphate uridyl transferase (galT) genes of Lactobacillus helveticus. Tn10 transposon mutagenesis, together with in vivo complementation analysis and in vitro enzyme activity measurements, allowed us to map these two genes. The DNA sequences of the genes and the flanking regions were determined. These revealed that the two genes are organized in the order galK-galT in an operonlike structure. In an in vitro transcription-translation assay, the galK and galT gene products were identified as 44- and 53-kDa proteins, respectively, data which corresponded well with the DNA sequencing data. The deduced amino acid sequence of the galK gene product showed significant homologies to other prokaryotic and eukaryotic galactokinase sequences, whereas galactose-1-phosphate uridyl transferase did not show any sequence similarities to other known proteins. This observation, together with a comparison of known gal operon structures, suggested that the L. helveticus operon developed independently to a translational expression unit having a different gene order than that in E. coli, Streptococcus lividans, or Saccharomyces cerevisiae. DNA sequencing of the flanking regions revealed an open reading frame downstream of the galKT operon. It was tentatively identified as galM (mutarotase) on the basis of the significant amino acid sequence homology with the corresponding Streptococcus thermophilus gene.

Single-stranded DNA plasmid, vector construction and cloning of Bacillus stearothermophilus alpha-amylase in Lactobacillus

Vector plasmids were constructed by ligating chloramphenicol and erythromycin resistance genes to TaqI-digested DNA of a cryptic plasmid from Lactobacillus plantarum. The minimal region of Lactobacillus plasmid DNA that was required for DNA replication was defined and a single-stranded DNA intermediate replication system was observed. Homologies with other origins of replication of plasmids from Gram-positive bacteria, replicating via rolling circle mechanism, were found. It was shown that the constructed vectors, named pPSC20 and pPSC22, were transformable into L. plantarum, Lactobacillus acidophilus, Lactobacillus reuteri, Lactobacillus fermentum, Lactobacillus helveticus, Lactococcus lactis subsp. lactis, Bacillus subtilis, and Escherichia coli. Using plasmid pPSC22, the alpha-amylase gene of Bacillus stearothermophilus was cloned and expressed in several Lactobacillus species.

Incompatibility of Lactobacillus Vectors with Replicons Derived from Small Cryptic Lactobacillus Plasmids and Segregational Instability of the Introduced Vectors

Three new Lactobacillus vectors based on cryptic Lactobacillus plasmids were constructed. The shuttle vector pLP3537 consists of a 2.3-kb plasmid from Lactobacillus pentosus MD353, an erythromycin resistance gene from Staphylococcus aureus plasmid pE194, and pUC19 as a replicon for Escherichia coli . The vectors pLPE317 and pLPE323, which do not contain E. coli sequences, were generated by introducing the erythromycin resistance gene of pE194 into a 1.7- and a 2.3-kb plasmid from L. pentosus MD353, respectively. These vectors and the shuttle vector pLP825 (M. Posno, R. J. Leer, J. M. M. van Rijn, B. C. Lokman, and P. H. Pouwels, p. 397-401, in A. T. Ganesan and J. A. Hoch, ed., Genetics and biotechnology of bacilli, vol. 2, 1988) could be introduced by electroporation into Lactobacillus casei, L. pentosus, L. plantarum, L. acidophilus, L. fermentum , and L. brevis strains with similar efficiencies. Transformation efficiencies were strain dependent and varied from 10 2 to 10 7 transformants per μg of DNA. Plasmid DNA analysis of L. pentosus MD353 transformants revealed that the introduction of pLP3537 or pLPE323 was invariably accompanied by loss of the endogenous 2.3-kb plasmid. Remarkably, pLPE317 could only be introduced into an L. pentosus MD353 strain that had been previously cured of its endogenous 1.7-kb plasmid. The curing phenomena are most likely to be explained by the incompatibility of the vectors and resident plasmids. Lactobacillus vectors are generally rapidly lost when cells are cultivated in the absence of selective pressure. However, pLPE323 is stable in three of four Lactobacillus strains tested so far.

In vitro expression of Lac-PTS and tagatose 1,6-bisphosphate aldolase genes from Lactococcus lactis subsp. cremoris plasmid pDI-21

A 4.4-kb EcoR1-EcoR1 DNA fragment from the Lactococcus lactis subsp. cremoris plasmid pDI-21 encoded the tagatose 1,6-bisphosphate (TBP) aldolase gene and the Lac-PTS genes. In vitro transcription-translation using Escherichia coli S30 extract showed the synthesis of 41,000-, 23,000- and 12,000-dalton proteins which correspond to the TBP-aldolase, Lac-PTS enzyme II, and factor III proteins respectively.

Cloning and expression of alpha-amylase from Bacillus amyloliquefaciens in a stable plasmid vector in Lactobacillus plantarum

Lactobacillus plantarum is used in a wide range of agricultural and food fermentations. In this paper we report the introduction of alpha-amylase into the organism from Bacillus amyloliquefaciens on a stable recombinant plasmid. The genetically manipulated organism grew on MRSB medium supplemented with starch and it may be a prototype for the development of lactobacilli able to use an increased range of substrates in commercial fermentations.

Applications for biotechnology: present and future improvements in lactic acid bacteria

The lactic acid bacteria are involved in the manufacture of fermented foods from raw agricultural materials such as milk, meat, vegetables, and cereals. These fermented foods are a significant part of the food processing industry and are often prepared using selected strains that have the ability to produce desired products or changes efficiently. The application of genetic engineering technology to improve existing strains or develop novel strains for these fermentations is an active research area world-wide. As knowledge about the genetics and physiology of lactic acid bacteria accumulates, it becomes possible to genetically construct strains with characteristics shaped for specific purposes. Examples of present and future applications of biotechnology to lactic acid bacteria to improve product quality are described. Studies of the basic biology of these bacteria are being actively conducted and must be continued, in order for the food fermentation industry to reap the benefits of biotechnology.

Genetic transformation of Lactobacillus casei by electroporation

Lactobacillus casei IAM1045 was transformed with a plasmid pAM beta 1-1, a tra deleted derivative of pAM beta 1, by electroporation. Effective transformation was achieved in electroporation buffers of a wide range of pH values, and in all phases of cell growth tested, with highest frequency in the early log phase. Polyethylene glycol increased the transformation frequency, whereas divalent cations such as Mg2+, Ca2+ and Mn2+ at 0.25 mM decreased the frequency by 2 to 3 orders. Highly efficient transformation of approximately 10(-4)/viable cell was achieved under optimal conditions. A plasmid harboring the trpD, C, F, B and A genes from L casei RNL7 was introduced by electroporation into tryptophan auxotrophic L casei JCM1053. The resulting transformant was found to express the trp genes introduced.

Characterization of a plasmid from the ruminal bacterium Selenomonas ruminantium

A 4.8-kilobase-pair plasmid was isolated from the ruminal bacterium selenomonas ruminantium HD4 by using a sodium carbonate-EDTA washing buffer to improve cell lysis (R.G. Dean, S.A. Martin, and C. Carver, Lett. Appl. Microbiol. 8:45-48, 1989). This plasmid, designated pSR1, appears to be quite stable. No evidence of plasmid DNA was detected in S. ruminantium D or GA192. All three strains were tested for antibiotic resistance, and all were kanamycin resistant (MIC, 25 to 50 micrograms/ml). Only strain D was tetracycline resistant (MIC, 25 micrograms/ml), and all strains were sensitive to ampicillin (MIC, 1 microgram/ml). pSR1 was cloned into pBR322, and a map of pSR1 was constructed by using HindIII, ClAI, BamHI, and PvuII. Although ClaI, BamHI, ScaI, and EcoRV digested recombined plasmid isolated from Escherichia coli, these restriction endonucleases were not effective in digesting plasmid isolated directly from S. ruminantium HD4.

Genetic transfer systems for delivery of plasmid deoxyribonucleic acid to Lactobacillus acidophilus ADH: conjugation, electroporation, and transduction

Lactobacillus acidophilus ADH is a bacteriocin-producing human isolate that adheres to human fetal intestinal cells and human ileal cells. We have employed both electroporation and conjugation methodologies to transfer various plasmids to L. acidophilus ADH. Furthermore, we have demonstrated transduction of plasmid DNA within this strain by a temperate bacteriophage (phi adh) harbored by L. acidophilus ADH. Plasmid pGK12 was introduced into strain ADH by electroporation at frequencies as high as 3.3 X 10(5) transformants/micrograms of plasmid DNA. Transconjugants of strain ADH were recovered at frequencies of 10(-2) (pAMB1), 10(-4) (pVA797::Tn917), and 10(-4) (pVA797) per donor cell after filter-mating with Lactococcus lactis ssp. lactis. Plasmid pGK12 was transduced from a phage phi adh lysogen into a recipient strain of L. acidophilus ADH at an average frequency of 3.4 X 10(-8) transductants/pfu. Transformants, transconjugants, or transductants were verified by both phenotype and plasmid profile for acquisition of plasmid DNA. The ability to transfer plasmids and mobilize DNA sequences by electroporation, conjugation, and transduction will augment our efforts to define and characterize the activities of L. acidophilus in the intestinal tract.

Expression and nucleotide sequence of the Lactobacillus bulgaricus beta-galactosidase gene cloned in Escherichia coli

The Lactobacillus bulgaricus beta-galactosidase gene was cloned on a ca. 7-kilobase-pair HindIII fragment in the vector pKK223-3 and expressed in Escherichia coli by using its own promoter. The nucleotide sequence of the gene and approximately 400 bases of 3'- and 5'-flanking sequences was determined. The amino acid sequence of the beta-galactosidase, deduced from the nucleotide sequence of the gene, yielded a monomeric molecular mass of ca. 114 kilodaltons, slightly smaller than the E. coli lacZ and Klebsiella pneumoniae lacZ enzymes but larger than the E. coli evolved (ebgA) beta-galactosidase. The cloned beta-galactosidase was found to be indistinguishable from the native enzyme by several criteria. From amino acid sequence alignments, the L. bulgaricus beta-galactosidase has a 30 to 34% similarity to the E. coli lacZ, E. coli ebgA, and K. pneumoniae lacZ enzymes. There are seven regions of high similarity common to all four of these beta-galactosidases. Also, the putative active-site residues (Glu-461 and Tyr-503 in the E. coli lacZ beta-galactosidase) are conserved in the L. bulgaricus enzyme as well as in the other two beta-galactosidases mentioned above. The conservation of active-site amino acids and the large regions of similarity suggest that all four of these beta-galactosidases evolved from a common ancestral gene. However, these enzymes are quite different from the thermophilic beta-galactosidase encoded by the Bacillus stearothermophilus bgaB gene.

Transport of amino acids in Lactobacillus casei by proton-motive-force-dependent and non-proton-motive-force-dependent mechanisms

Lactobacillus casei 393 cells which were energized with glucose (pH 6.0) took up glutamine, asparagine, glutamate, aspartate, leucine, and phenylalanine. Little or no uptake of several essential amino acids (valine, isoleucine, arginine, cysteine, tyrosine, and tryptophan) was observed. Inhibition studies indicated that there were at least five amino acid carriers, for glutamine, asparagine, glutamate/aspartate, phenylalanine, or branched-chain amino acids. Transport activities had pH optima between 5.5 and 6.0, but all amino acid carriers showed significant activity even at pH 4.0. Leucine and phenylalanine transport decreased markedly when the pH was increased to 7.5. Inhibitors which decreased proton motive force (delta p) nearly eliminated leucine and phenylalanine uptake, and studies with de-energized cells and membrane vesicles showed that an artificial electrical potential (delta psi) of at least -100 mV was needed for rapid uptake. An artificial delta p was unable to drive glutamine, asparagine, or glutamate uptake, and transport of these amino acids was sensitive to a decline in intracellular pH. When intracellular pH was greater than 7.7, glutamine, asparagine, or glutamate was transported rapidly even though the proton motive force had been abolished by inhibitors.

Evidence for the conjugal transfer of the broad host range plasmid pIP501 into strains of Lactobacillus helveticus

The conjugative broad host range plasmid pIP501 was transferred from Streptococcus faecalis to a series of strains of lactic streptococci used commercially as dairy starter cultures. With these transconjugants as donors the plasmid was exconjugated to two strains of Lactobacillus helveticus and a commercially used strain of Strep. thermophilus. There was evidence that the plasmid could transfer between isogenic derivatives of one of the strains of Lact. helveticus. Transfer from Lact. helveticus to Strep. faecalis was also detected but at a low frequency. There was no evidence for the conjugal transfer of plasmid pIP501 into a strain of Lact. bulgaricus by exconjugation from either lactic streptococci or Lactobacillus sp.

Identification and cloning of a plasmid-encoded erythromycin resistance determinant from Lactobacillus reuteri

Plasmid analysis, plasmid curing, cloning, and hybridization experiments were used to study four Lactobacillus reuteri strains showing high resistance to erythromycin. Plasmid curing with acriflavine resulted in a loss of erythromycin resistance in a frequency of 1-10%. For three of the strains this was accompanied by a loss of a 6.9-MDa plasmid, which was shown to be identical for the different strains and designated pLUL631. The erythromycin (erm) gene was located on a 5.5-MDa plasmid in the fourth strain. A restriction map of pLUL631 was constructed and the location of the erm gene on the plasmid was identified by cloning in Escherichia coli. By using a Streptococcus lactis-E. coli shuttle vector, the erm gene was also transformed to S. lactis and expressed. The erm gene from L. reuteri was shown to be related to the erm gene from pIP501 (Streptococcus agalactiae) by DNA-DNA hybridization.