Molecular cloning of lactose genes in dairy lactic streptococci: the phospho-beta-galactosidase and beta-galactosidase genes and their expression products

The mesophilic (S. lactis and S. cremoris) and thermophilic (S. thermophilus) dairy lactic streptococci, which are used in industrial dairy fermentations, contain two different lactose hydrolysing enzymes, a phospho-beta-galactosidase and a beta-galactosidase. The central role of these enzymes in the pathways used for lactose transport and degradation is discussed along with their properties and distributions in lactic streptococci. In addition, recent results on the cloning, expression and sequence organization of the genes for the mesophilic phospho-beta-galactosidase and thermophilic beta-galactosidase are reviewed. Original data are presented concerning heterologous gene expression in the study of lactose hydrolysis in lactic streptococci. These include 1) the purification of the S. lactis phospho-beta-galactosidase from an overproducing Escherichia coli, and 2) the expression of the E. coli beta-galactosidase (lacZ) gene in S. lactis employing a lactic streptococcal expression vector.     

Genetics of lactose utilization in lactic acid bacteria

Abstract: Lactose utilization is the primary function of lactic acid bacteria used in industrial dairy fermentations. The mechanism by which lactose is transported determines largely the pathway for the hydrolysis of the internalized disaccharide and the fate of the glucose and galactose moieties. Biochemical and genetic studies have indicated that lactose can be transported via phosphotransferase systems, transport systems dependent on ATP binding cassette proteins, or secondary transport systems including proton symport and lactose-galactose antiport systems. The genetic determinants for the group translocation and secondary transport systems have been identified in lactic acid bacteria and are reviewed here. In many cases the lactose genes are organized into operons or operon-like structures with a modular organization, in which the genes encoding lactose transport are tightly linked to those for lactose hydrolysis. In addition, in some cases the genes involved in the galactose metabolism are linked to or co-transcribed with the lactose genes, suggesting a common evolutionary pathway. The lactose genes show characteristic configurations and very high sequence identity in some phylogenetically distant lactic acid bacteria such as Leuconostoc and Lactobacillus or Lactococcus and Lactobacillus . The significance of these results for the adaptation of lactic acid bacteria to the industrial milk environment in which lactose is the sole energy source is discussed.     

Improving dairy starter cultures

It has long been recognized that various dairying-relevant properties of mesophilic lactic streptococci are unstable traits. During the past ten years it has become increasingly clear that these instabilities are due to loss of plasmids during growth of the bacteria. The plasmid-linkage of these properties has accelerated the identification and delineation of their genetic determinants and recently genes important for dairying have been cloned and expressed in a number of bacterial species, including plasmid-free lactic streptococci. The prospects for improving dairy starter cultures by enhancing and stabilizing the expression of dairying-relevant plasmid-borne genes look promising.     

Simple and rapid method for isolating large plasmid DNA from lactic streptococci.

A procedure for the rapid isolation of plasmid DNA larger than 30 megadaltons from lactic streptococci is described. This protocol can be used on a preparative scale to isolate sufficient quantities of plasmid DNA required for restriction analysis, cloning, or transformation experiments. A scaled-down protocol is very useful for rapidly screening the plasmid content of streptococcal strains. With this methodology, previously undetected large plasmids were observed.     

Vector plasmids and the strategy of molecular cloning for streptococci

The experiments on elaboration of gene engineering methodology for streptococci are described. Two vectors were constructed for DNA cloning in streptococci on the basis of plasmids pSM19035 and pIP2501. Some of the plasmids occurred to be valuable vectors for molecular cloning in bacilli. Peculiarities of the transformation mechanism in streptococci were found to impede the molecular cloning. The recombination technique of cloning was successfully used in the streptococcal system.     

Exploiting the yeast Saccharomyces cerevisiae for the study of the organization and evolution of complex genomes

Yeast artificial chromosome (YAC) cloning systems have advanced the analysis of complex genomes considerably. They permit the cloning of larger fragments than do bacterial artificial chromosome systems, and the cloned material is more easily modified. We recently developed a novel YAC cloning system called transformation-associated recombination (TAR) cloning. Using in vivo recombination in yeast, TAR cloning selectively isolates, as circular YACs, desired chromosome segments or entire genes from complex genomes. The ability to do that without constructing a representative genomic library of random clones greatly facilitates analysis of gene function and its role in disease. In this review, we summarize how recombinational cloning techniques have advanced the study of complex genome organization, gene expression, and comparative genomics.     

Novel streptococcal-integration shuttle vectors for gene cloning and inactivation.

Seven new streptococcal integration shuttle vectors have been constructed which contain different antibiotic-resistance-encoding genes capable of expression in both Streptococcus sp. and Escherichia coli. These plasmids can replicate in E. coli, but not in streptococci because of the absence of a streptococcal origin of replication. The size, antibiotic resistance, and number of unique restriction sites available for cloning for each plasmid are as follows: pSF141 (7.6 kb, CmR and KmR, 7 sites), pSF143 (5.7 kb, TcR, 6 sites), pSF148 (7.3 kb, CmR and SpR, 7 sites), pDL285 (3.4 kb, KmR, 3 sites), pDL286 (3.1 kb, SpR, 4 sites), pSF151 (3.5 kb, KmR, 10 sites), pSF152 (3.2 kb, SpR, 9 sites). If these plasmids carry a fragment of streptococcal DNA they can specifically integrate into the chromosome via Campbell-like, homologous recombination. Therefore, they should be useful for gene inactivation, cloning, chromosomal walking, or linkage analysis in streptococci. The availability of these integration plasmids resistant to different antibiotics, along with the previously described plasmid, pVA891 (ErR), should also allow the construction of mutants possessing multiple insertionally inactivated genes useful for a variety of genetic studies.     

Current data on the cloning of virulence factors of pathogenic Streptococci

The data on the cloning of the main pathogenic determinants of group A streptococci including M-protein, erythrogenic toxin, streptokinase, streptolysin O are analyzed. The scientific importance and the possible ways to use the data obtained after cloning are discussed. The hypothesis on the operon system of a number of streptococcal virulence factors regulation is discussed. Construction of vector systems for streptococcal genes cloning is summarized.     

Plasmid-directed mechanisms for bacteriophage defense in lactic streptococci

Abstract Genetic studies with lactic streptococci have identified a variety of plasmids coding for systems that interfere with phage adsorption, direct restriction and modification activities, and disrupt various stages in the phage lytic cycle. This review describes mechanisms of phage defense that are plasmid-directed in lactic streptococci, examines the physical and genetic properties of the plasmids involved, and discusses genetic strategies for construction of phage-insensitive starter cultures for dairy fermentations.     

Functional properties of plasmids in lactic streptococci

Plasmid biology has become an important area of investigation in dairy starter cultures since it now appears that some properties, vital for successful milk fermentations, are coded by genes located on plasmid DNA. Some of these metabolic properties observed in lactic streptococci have been clearly established as being plasmid-mediated. Examples would be lactose utilization and in Streptococcus lactis subsp. diacetylactis the ability to produce a bacteriocin-like substance. Phenotypic and physical evidence for plasmid linkage has been obtained for other traits such as citrate, sucrose, galactose, glucose, mannose, and xylose utilization, proteinase activity, modification/restriction systems, as well as for nisin production. Further genetic evidence is now needed to confirm plasmid association to these properties. For some characteristics the association with plasmids is highly speculative and is solely based on the phenotypic loss of a metabolic property. In this category would be sensitivity to agglutinins, sensitivity to the lactoperoxidase-thiocyanate-hydrogen peroxide inhibitory system, arginine hydrolysis, and slime production. Other properties which appear plasmid-mediated in lactic streptococci and which will be discussed include inorganic ion resistance, drug resistance, and diplococcin production.     

Development of broad-host-range vectors for expression of cloned genes in Pseudomonas

The cloning and expression of genes in Pseudomonas have been difficult, until now, due to the absence of vector systems that contain multiple restriction sites downstream from promoter sequences that are functional in Pseudomonas. We report here the construction of several broad-host-range vectors that can be utilized in either Pseudomonas or Escherichia coli and that rely on easily selectable antibiotic resistance markers with multiple cloning sites. These vectors were constructed by inserting the entire pUC13 sequence into derivatives of the RSF1010 wide-host-range plasmid. From this construction, other derivatives were obtained, specifically a lacZ::KmR fusion gene which provides an easily selectable marker in both E. coli and Pseudomonas. These vectors have been used to express the Pseudomonas putida cytochrome P450 monoxygenase gene in a P450-deficient P. putida strain. Thus, these vectors allow for the cloning, expression and selection of Pseudomonas genes in Pseudomonas by complementation.     

A new simple method of curing plasmids in lactic streptococci (Streptococcus cremoris; Streptococcus lactis, plasmids)

A simple method for curing plasmid DNA from lactic streptococci is described. When strains of lactic streptococci are grown overnight at 32 degrees C in an unbuffered medium (M17-) and held at the same temperature for an extended period (96 h), the acid environment induces loss of plasmid DNA of different sizes. If the process of growth in M17- broth followed by extended incubation at 32 degrees C is repeated, most of the plasmids are lost, as revealed by gel electrophoretic profiles of DNA. The method is simple and efficient in curing plasmids of lactic streptococci without use of any mutagenic chemical.     

Quikgene: a gene synthesis method integrated with ligation-free cloning

Gene synthesis is a convenient tool that is widely used to make genes for a variety of purposes. All current protocols essentially take inside-out approaches to assemble complete genes using DNA oligonucleotides or intermediate fragments. Here we present an efficient method that integrates gene synthesis and cloning into one step. Our method, which is evolved from QuikChange mutagenesis, can modify, extend, or even de novo synthesize relatively large genes. The genes are inserted directly into vectors without ligations or subcloning. We de novo synthesized a 600-bp gene through multiple steps of polymerase chain reaction (PCR) directly into a bacterial expression vector. This outside-in gene synthesis method is called Quikgene. Furthermore, we have defined an overlap region of a minimum of nine nucleotides in insertion primers that is sufficient enough to circularize PCR products for efficient transformation, allowing one to significantly reduce the lengths of primers. Taken together, our protocol greatly extends the current length limit for QuikChange insertion. More importantly, it combines gene synthesis and cloning into one step. It has potential applications for high-throughput structural genomics.     

Application of the resident plasmid integration technique to construct a strain of Streptococcus godronii able to express the Bacillus circulans cycloisomaltooligosaccharide glucanotransferase gene,and secrete its active gene product

A novel transformation technique, resident plasmid integration, for the cloning of foreign DNA in oral streptococci was described recently (T. Shiroza and H. K. Kuramitsu, Plasmid, 1995, 34, 85–95). This technique is based on the integration of linearized foreign genes by recombination-proficient bacteria onto a resident plasmid, if an appropriate selection marker is flanked by the same anchor sites present in the resident plasmid. Since the transforming vehicles for this system included a pUC-derived replication origin, the high level expression in Escherichia coli cells hindered the cloning of certain genes. In the present study, new plasmids were constructed, two resident plasmids, four integration plasmids, and four cloning plasmids, all of which possess the medium-copy number replication origin, p15A ori, isolated from pACYC177. The resident plasmids consisted of the following three components: the p15A ori (0.65-kb BglII fragment), the pVA380-1 basic replicon functional in mutans streptococci (2.5-kb BamHI fragment), and either an erythromycin resistance or a spectinomycin resistance gene (0.9- or 1.1-kb BamHI fragment, respectively). Most of the basic replicon of pVA380-1, except for the 3′-portion of the 0.2-kb region, in the resident plasmid was replaced with a kanamycin resistance gene to construct the four integration plasmids. Therefore, the upstream and downstream anchor sites for the double cross-over event in this new system were 0.65-kb p15A ori and the 0.2-kb portion of the 3′-end of pVA380-1 replicon, respectively. This system was used to clone the gene coding for cycloisomaltooligosaccharide glucanotransferase which produces cycloisomaltooligosaccharide, a potent inhibitor of oral streptococcal glucosyltransferase, isolated from Bacillus circulans chromosome, into Streptococcus gordonii, and its gene product was successfully secreted into the culture media. Plasmids described here should be useful tools for introducing heterologous DNA into resident plasmids following integration in oral streptococci.     

Construction of shuttle cloning vectors for Bacteroides fragilis and use in assaying foreign tetracycline resistance gene expression

Shuttle vectors capable of replication in both Escherichia coli and Bacteroides fragilis have been developed. Conjugal transfer of these plasmids from E. coli to B. fragilis is facilitated by inclusion of the origin of transfer of the IncP plasmid RK2. The vectors pDK1 and pDK2 provide unique sites for cloning selectable markers in Bacteroides. pOA10 is a cosmid vector containing the replication region of pCP1 necessary for maintenance in Bacteroides. pDK3, pDK4.1, and pDK4.2 contain the Bacteroides clindamycin resistance gene allowing selection and maintenance in B. fragilis of plasmids containing inserted DNA fragments. pDK3 was used to test the expression in B. fragilis of five foreign tetracycline resistance (TcR) genes. The tetA, -B, and -C markers from facultative gram-negative bacteria, as well as a TcR determinant from Clostridium perfringens, did not express TcR in B. fragilis. The tetM gene, originally described in streptococci, encoded a small but reproducible increase of TcR in Bacteroides. These studies demonstrate the utility of shuttle vectors for introducing cloned genes into Bacteroides and underscore the differences in gene expression in these anaerobes.     

Use of mammalian cell expression cloning systems to identify genes for cytokines, receptors, and regulatory proteins.

Mammalian cell expression cloning has become a standard technique for the isolation of mammalian genes or cDNAs. Its advantage is that the biological functions of the gene of interest are used for cloning. Therefore, the identified cDNAs or genes should be functional in vivo, and there is no need for physical or chemical information about the gene products, so that protein purification in sufficient quantity to raise antibodies or to obtain amino acid sequences is not necessary. Here, we summarize recent progress in mammalian cell cloning systems, and discuss the possible directions in which this technique will lead.     

Systems for applied gene control in Saccharomyces cerevisiae

Saccharomyces cerevisiae is frequently used in biotechnology, including fermentative processes in food production, heterologous protein production and high throughput developments for biomedicine. Accurate expression of selected genes is essential for all these areas. Systems that can be regulated are particularly useful because they allow controlling the timing and levels of gene expression. We examine here new expression systems that have been described, including improvements of classical ones and new strategies of artificial gene control that have been applied in functional genomics.     

高等植物赤霉素生物合成及其调节研究进展

主要介绍近年来高等植物中生物活性GAs的生物合成,拟南芥GA生物合成途径中关键酶基因（GA1－GA5）的克隆和GA3基因CYP701A3的母（Saccharomyces cerevisiae）中的成功表达。评述了活性GAs对赤霉不生物合成的反馈抑制作用和反馈调节中信号的传递和接收问题。高等植物中光周期对GA生物合成的调节主要是在20－氧化和／或3β－羟基化步骤。