Prospects for the genetic manipulation of lactobacilli

Abstract Efforts are underway in a number of laboratories around the world to develop methods for the improvement of Lactobacillus strains by recombinant DNA techniques. Research has centered on: (i) characterization and construction of chimeric shuttle vectors based on endogenous Lactobacillus plasmids which are capable of replicating in lactobacilli; (ii) molecular cloning of genes and operons from lactobacilli encoding important pathways such as the lactose : phospho enol pyruvate phosphotransferase system, phosphogalactoside-β- d -galactohydrolase, and β-galactosidase; and (iii) methods for introduction of genes in vivo and in vitro through conjugation, transfection and transformation. The lack of natural gene exchange systems has prompted research efforts to devise a protoplast transformation system. Initial early successes in gene cloning, vector development, transfection, conjugation, protoplast fusion and, recently, transformation, have laid the ground-work for rapid development of gene exchange systems for the genus.     

Recent Advances in the Physiology and Genetics of Amino Acid-Producing Bacteria

Abstract

Corynebacterium glutamicum and its close relatives, C. flavum and C. lactofennentum, have been used for over 3 decades in the industrial production of amino acids by fermentation. Since 1984, several research groups have started programs to develop metabolic engineering principles for amino acid-producing Corynebacferium strains. Initially, the programs concentrated on the isolation of genes encoding (deregulated) biosynthetic enzymes and the development of general molecular biology tools such as cloning vectors and DNA transfer methods. With most of the genes and tools now available, recombinant DNA technology can be applied in strain improvement. To accomplish these improvements, it is critical and advantageous to understand the mechanisms of gene expression and regulation as well as the biochemistry and physiology of the species being engineered. This review explores the advances made in the understanding and application of amino acid-producing bacteria in the early 1990s.     

Chitinolytic activity of bacteria

Chitinolytic bacteria play an important role in degradation of chitin, one of the most abundant biopolymers in nature. These microorganisms synthesize specific enzymes, that catalyze hydrolysis of beta-1,4-glycosidic bonds in low-digestible chitin polymers, turning it into low-molecular, easy to digest compounds. During last decades many bacterial chitinolytic enzymes have been studied and characterized, mainly for their potential applications in agriculture, industry and medicine. Several chitinase classifications have been proposed, either on the base of substrate specificity or amino acid sequence similarities. X-ray crystallography and NMR spectroscopy techniques enabled the determination of three dimensional structure of some chitinases, what was helpful in explaining their catalytic mechanism. Development of biotechnology and molecular biology enables a deep research in regulation and cloning of bacterial chitinase genes.     

Cloning and characterization of a Streptomyces antibioticus ATCC11891 cyclophilin related to Gram negative bacteria cyclophilins

Cyclophilins are folding helper enzymes and represent a family of the enzyme class of peptidyl-prolyl cis-trans isomerases. Here, we report the molecular cloning and biochemical characterization of SanCyp18, an 18-kDa cyclophilin from Streptomyces antibioticus ATCC11891 located in the cytoplasm and constitutively expressed during development. Amino acid sequence analysis revealed a much higher homology to cyclophilins from Gram negative bacteria than to known cyclophilins from Streptomyces or other Gram positive bacteria. SanCyp18 is inhibited weakly by CsA, with a K(i) value of 21 microM, similar to cyclophilins from Gram negative bacteria. However, this value is more than 20-fold higher than the K(i) values reported for cyclophilins from other Gram positive bacteria, which makes SanCyp18 unique within this group. The presence of SanCyp18 in Streptomyces is likely due to horizontal gene transmission from Gram-negative bacteria to Streptomyces.     

土壤细菌类克隆群落及其结构的生态学特征

以16SrDNA分析方法为基础,获得来自不同土壤环境的细菌克隆群落（Cloning community),并分析了这些土壤细菌群落结构特征,在不同土壤环境中,细菌种类非常丰富,但其多样性将受到植被,土壤水分或土壤层次等因子的影响,表层土壤环境中细菌种类最丰富,多样性最高,且基因型中无明显的优势类群,不同土壤环境间细菌群落的相似性好低,表明群落结构以及空间隔离的复杂性。     

Application of DNA-DNA colony hybridization to the detection of catabolic genotypes in environmental samples

The application of preexisting DNA hybridization techniques was investigated for potential in determining populations of specific gene sequences in environmental samples. Cross-hybridizations among two degradative plasmids, TOL and NAH, and two cloning vehicles, pLAFR1 and RSF1010, were determined. The detection limits for the TOL plasmid against a nonhomologous plasmid-bearing bacterial background was ascertained. The colony hybridization technique allowed detection of one colony containing TOL plasmid among 10(6) Escherichia coli colonies of nonhomologous DNA. Comparisons between population estimates derived from growth on selective substrates and from hybridizations were examined. Findings indicated that standard sole carbon source enumeration procedures for degradative populations lead to overestimations due to nonspecific growth of other bacteria on the microcontaminant carbon sources present in the media. Population estimates based on the selective growth of a microcosm population on two aromatic substrates (toluene and naphthalene) and estimates derived from DNA-DNA colony hybridizations, using the TOL or NAH plasmid as a probe, corresponded with estimates of substrate mineralization rates and past exposure to environmental contaminants. The applications of such techniques are hoped to eventually allow enumeration of any specific gene sequences in the environment, including both anabolic and catabolic genes. In addition, this procedure should prove useful in monitoring recombinant DNA clones released into environmental situations.     

Delivery systems for gene therapy

The structure of DNA was unraveled by Watson and Crick in 1953, and two decades later Arber, Nathans and Smith discovered DNA restriction enzymes, which led to the rapid growth in the field of recombinant DNA technology. From expressing cloned genes in bacteria to expressing foreign DNA in transgenic animals, DNA is now slated to be used as a therapeutic agent to replace defective genes in patients suffering from genetic disorders or to kill tumor cells in cancer patients. Gene therapy provides modern medicine with new perspectives that were unthinkable two decades ago. Progress in molecular biology and especially, molecular medicine is now changing the basics of clinical medicine. A variety of viral and non-viral possibilities are available for basic and clinical research. This review summarizes the delivery routes and methods for gene transfer used in gene therapy.     

Cancer,Viruses, and Mass Migration: Paul Berg’s Venture into Eukaryotic Biology and the Advent of Recombinant DNA Research and Technology, 1967–1980

The existing literature on the development of recombinant DNA technology and genetic engineering tends to focus on Stanley Cohen and Herbert Boyer’s recombinant DNA cloning technology and its commercialization starting in the mid-1970s. Historians of science, however, have pointedly noted that experimental procedures for making recombinant DNA molecules were initially developed by Stanford biochemist Paul Berg and his colleagues, Peter Lobban and A. Dale Kaiser in the early 1970s. This paper, recognizing the uneasy disjuncture between scientific authorship and legal invention in the history of recombinant DNA technology, investigates the development of recombinant DNA technology in its full scientific context. I do so by focusing on Stanford biochemist Berg’s research on the genetic regulation of higher organisms. As I hope to demonstrate, Berg’s new venture reflected a mass migration of biomedical researchers as they shifted from studying prokaryotic organisms like bacteria to studying eukaryotic organisms like mammalian and human cells. It was out of this boundary crossing from prokaryotic to eukaryotic systems through virus model systems that recombinant DNA technology and other significant new research techniques and agendas emerged. Indeed, in their attempt to reconstitute ‹life’ as a research technology, Stanford biochemists’ recombinant DNA research recast genes as a sequence that could be rewritten thorough biochemical operations. The last part of this paper shifts focus from recombinant DNA technology’s academic origins to its transformation into a genetic engineering technology by examining the wide range of experimental hybridizations which occurred as techniques and knowledge circulated between Stanford biochemists and the Bay Area’s experimentalists. Situating their interchange in a dense research network based at Stanford’s biochemistry department, this paper helps to revise the canonized history of genetic engineering’s origins that emerged during the patenting of Cohen–Boyer’s recombinant DNA cloning procedures.     

Application of DNA-DNA colony hybridization to the detection of catabolic genotypes in environmental samples.

The application of preexisting DNA hybridization techniques was investigated for potential in determining populations of specific gene sequences in environmental samples. Cross-hybridizations among two degradative plasmids, TOL and NAH, and two cloning vehicles, pLAFR1 and RSF1010, were determined. The detection limits for the TOL plasmid against a nonhomologous plasmid-bearing bacterial background was ascertained. The colony hybridization technique allowed detection of one colony containing TOL plasmid among 10(6) Escherichia coli colonies of nonhomologous DNA. Comparisons between population estimates derived from growth on selective substrates and from hybridizations were examined. Findings indicated that standard sole carbon source enumeration procedures for degradative populations lead to overestimations due to nonspecific growth of other bacteria on the microcontaminant carbon sources present in the media. Population estimates based on the selective growth of a microcosm population on two aromatic substrates (toluene and naphthalene) and estimates derived from DNA-DNA colony hybridizations, using the TOL or NAH plasmid as a probe, corresponded with estimates of substrate mineralization rates and past exposure to environmental contaminants. The applications of such techniques are hoped to eventually allow enumeration of any specific gene sequences in the environment, including both anabolic and catabolic genes. In addition, this procedure should prove useful in monitoring recombinant DNA clones released into environmental situations.     

Occurrence of two 5-aminolevulinate biosynthetic pathways in Streptomyces nodosus subsp. asukaensis is linked with the production of asukamycin

We report the results of cloning genes for two key biosynthetic enzymes of different 5-aminolevulinic acid (ALA) biosynthetic routes from Streptomyces. The genes encode the glutamyl-tRNAGlu reductase (GluTR) of the C5 pathway and the ALA synthase (ALAS) of the Shemin pathway. While Streptomyces coelicolor A3(2) synthesizes ALA via the C5 route, both pathways are operational in Streptomyces nodosus subsp. asukaensis, a producer of asukamycin. In this strain, the C5 route produces ALA for tetrapyrrole biosynthesis; the ALA formed by the Shemin pathway serves as a precursor of the 2-amino-3-hydroxycyclopent-2-enone moiety (C5N unit), an antibiotic component. The growth of S. nodosus and S. coelicolor strains deficient in the GluTR genes (gtr) is strictly dependent on ALA or heme supplementation, whereas the defect in the ALAS-encoding gene (hemA-asuA) abolishes the asukamycin production in S. nodosus. The recombinant hemA-asuA gene was expressed in Escherichia coli and in Streptomyces, and the encoded enzyme activity was demonstrated both in vivo and in vitro. The hemA-asuA gene is situated within a putative cluster of asukamycin biosynthetic genes. This is the first report about the cloning of genes for two different ALA biosynthetic routes from a single bacterium.     

Actinomycetes--the test-organisms of genetic engineering

The paper contains a short review of the data on using the methods of genetic engineering in studies of genetics and molecular biology in Streptomyces. The techniques of DNA introduction into actinomycetes and wide-spread vectors are briefly described. The origin of the actinomycete plasmids as chromosomal segments capable of autonomous replication is discussed. In this view, it is suggested that genetic instability in actinomycetes is connected with excision of specific DNA sequences from the chromosome at frequencies characteristic of recombination events. Also, amplification of short DNA segments within the chromosome resulting in tandem repeats is a consequence of unequal crossing over between direct repeats flanking the amplifying DNA and, possibly, of induction of replication of this DNA. The data on molecular cloning of actinomycete genes for primary metabolism and those for resistance to and biosynthesis of antibiotics, on using actinomycetes as the hosts for foreign genes to be expressed, as well as on analysis of nucleotide sequences of actinomycete DNA, are presented.     

Genes without frontiers?

For bacteria, the primary genetic barrier against the genetic exchange of DNA that is not self-transmissible is dissimilarity in the bacterial DNA sequences concerned. Genetic exchange by homologous recombination is frequent among close bacterial relatives and recent experiments have shown that it can enable the uptake of closely linked nonhomologous foreign DNA. Artificial vectors are mosaics of mobile DNA elements from free-living bacterial isolates and so bear a residual similarity to their ubiquitous natural progenitors. This homology is tightly linked to the multitude of different DNA sequences that are inserted into synthetic vectors. Can homology between vector and bacterial DNA enable the uptake of these foreign DNA inserts? In this review we investigate pUC18 as an example of an artificial vector and consider whether its homology to broad host-range antibiotic resistance transposons and plasmid origins of replication could enable the uptake of insert DNA in the light of studies of homology-facilitated foreign DNA uptake. We also discuss the disposal of recombinant DNA, its persistence in the environment and whether homologies to pUC18 may exist in naturally competent bacteria. Most DNA that is inserted into the cloning site of artificial vectors would be of little use to a bacterium, but perhaps not all.     

The SalI (SalGI) restriction-modification system of Streptomyces albus G

The salIR and salM genes of Streptomyces albus G specify the SalGI (SalI) restriction enzyme and its cognate methyltransferase, respectively. These enzymes are responsible for restriction and modification of bacteriophages. Some phages carry genes that interfere with SalI-specific modification. The sal genes have been cloned in a Streptomyces host-vector system. Use of the cloned DNA as a hybridization probe reveals that sal mutants frequently arise from transposition of a DNA segment of approx. 1 kb into the sal genes. Some, but not all, other bacteria that produce SalGI isoschizomers contain nucleotide sequences that hybridize with sal DNA.     

Description of a PCR-based technique for DNA splicing and mutagenesis by producing 5' overhangs with run through stop DNA synthesis utilizing Ara-C

Background  

Splicing of DNA molecules is an important task in molecular biology that facilitates cloning, mutagenesis and creation of chimeric genes. Mutagenesis and DNA splicing techniques exist, some requiring restriction enzymes, and others utilize staggered reannealing approaches.     

Uncultured soil bacteria are a reservoir of new antibiotic resistance genes

Antibiotic resistance genes are typically isolated by cloning from cultured bacteria or by polymerase chain reaction (PCR) amplification from environmental samples. These methods do not access the potential reservoir of undiscovered antibiotic resistance genes harboured by soil bacteria because most soil bacteria are not cultured readily, and PCR detection of antibiotic resistance genes depends on primers that are based on known genes. To explore this reservoir, we isolated DNA directly from soil samples, cloned the DNA and selected for clones that expressed antibiotic resistance in Escherichia coli. We constructed four libraries that collectively contain 4.1 gigabases of cloned soil DNA. From these and two previously reported libraries, we identified nine clones expressing resistance to aminoglycoside antibiotics and one expressing tetracycline resistance. Based on the predicted amino acid sequences of the resistance genes, the resistance mechanisms include efflux of tetracycline and inactivation of aminoglycoside antibiotics by phosphorylation and acetylation. With one exception, all the sequences are considerably different from previously reported sequences. The results indicate that soil bacteria are a reservoir of antibiotic resistance genes with greater genetic diversity than previously accounted for, and that the diversity can be surveyed by a culture-independent method.     

Advances in molecular cloning

“Molecular cloning” meaning creation of recombinant DNA molecules has impelled advancement throughout life sciences. DNA manipulation has become easy due to powerful tools showing exponential growth in applications and sophistication of recombinant DNA technology. Cloning genes has become simple what led to an explosion in the understanding of gene function by seamlessly stitching together multiple DNA fragments or by the use of swappable gene cassettes, maximizing swiftness and litheness. A novel archetype might materialize in the near future with synthetic biology techniques that will facilitate quicker assembly and iteration of DNA clones, accelerating the progress of gene therapy vectors, recombinant protein production processes and new vaccines by in vitro chemical synthesis of any in silico-specified DNA construct. The advent of innovative cloning techniques has opened the door to more refined applications such as identification and mapping of epigenetic modifications and high-throughput assembly of combinatorial libraries. In this review, we will examine the major breakthroughs in cloning techniques and their applications in various areas of biological research that have evolved mainly due to easy construction of novel expression systems.     

Cloning and expression of a new bacteriophage (SHPh) DNA ligase isolated from sewage

During the last 50 years, major advances in molecular biology and biotechnology have been attributed to the discovery of enzymes that allow molecular cloning of important genes. One of these enzymes that has been widely acknowledged for its role in the development of biotechnology is the T4 DNA ligase. This enzyme joins the break in the DNA backbone structure by creating a phosphodiester bond between 5′ PO₄ and 3′ OH ends, in an ATP dependent multi-step reaction, thus allowing the ligation of related and foreign DNA sequences. Due to its role in modern DNA recombinant technology, there is a high demand on DNA ligase to allow the ligation of target DNA inserts into a chosen vector as part of DNA cloning technology. To closely look at ligase sequence diversity, a bacteriophage that infects DH5α (commercial lab strain of Escherichia coli) was isolated from sewage system in Hebron, Palestine. The DNA ligase gene of this phage was cloned and its sequence was compared to the NCBI database. The new bacteriophage ligase, named (South Hebron Phage, SHPh) DNA ligase, shows homology to T even bacteriophage DNA ligases posted in the NCBI database with 35 nucleotide differences, an indication of existed diversity among T even DNA ligation enzymes that can be used as markers in phage classification.     

Molecular characterization of soil microorganisms: effect of industrial pollution on distribution and biodiversity

The present study aimed to investigate variations in the diversity of the indigenous bacterial and fungal populations in contaminated soil. Soil samples were collected from highly contaminated agricultural soil adjacent to an industrial drain in the Nile Delta named the “Defsho” drain, located at the city of Kafr El-Dawar, 20 km south of Alexandria (Longitude 30.12917 and Latitude 31.13972). PCR has become a popular tool for the retrieval of the natural environmental rRNA genes that represent native microbial species. Soil DNA was extracted and the 16S and 18S rRNA genes were amplified using polymerase chain reaction (PCR) and gene cloning. About 5,000 clones were obtained and genotyped using denaturing high performance liquid chromatography (DHPLC) to fingerprinting the biodiversity in the soil. Clones, which give different peaks with DHPLC, were then subjected to partial sequencing. Five prokaryotic and two eukaryotic out of 1,000 recombinant clones were randomly selected and further studied by DNA sequencing analysis. These clones were designated PT and ET for prokaryotes and eukaryotes, respectively. Results confirmed the hazardous effects of pollution on the distribution and biodiversity of soil microorganisms where most of the native beneficial microorganisms were disappeared or non-cultured under these stressed conditions compared to the normal non-polluted soils in the same governorate which is certainly affecting soil fertility and productivity. Five prokaryotic (PT) and two eukaryotic (ET) recombinant clones were randomly selected and further studied by DNA sequence analysis. DNA sequencing revealed that most of the identified bacteria are members of the class Proteobacteria; subdivision Gammaproteobacteria; order Enterobacteriales and family Enterobacteriaceae. Two PT clones (PT2 and PT4) were identified as Shigella flexneri 301-AF499895; members of PT1 and PT3 were related to Escherichia sp. and the uncultured bacterium S000009863 while PT5 was uncultured bacterium-S000331457 in addition to unclassified member of Desulfobacteriaceae, subdivision Deltaproteobacteria. ET1 was uncultured Trichocomaceae clone HC-B1/1-AF548306 and ET2 represents uncultured fungus clone SBS8w47f-AY681463, respectively. In conclusion, the significant decline in the genetic diversity in Defsho soil emphasized the hazardous effect of the industrial pollution on the biodiversity, stability and functioning of the native microbial population. Results also proved the efficiency of molecular characterization as precise and fast techniques for determining soil biodiversity compared to the traditional cultivation methods.     

In situ detection and localization of bioluminescent streptomyces coelicolor in liquid and soil by photon imaging

The successful cloning of the bioluminescence genes from marine bacteria offers the chance to use the bioluminescence phenotype as a marker for environmental monitoring purposes. This work describes a video camera based technique which allows both the sensitive detection and determination of the spatial distribution of luminescent Streptomyces coelicolor pellets and filaments within liquid and soil samples.     

First insight into the genome of an uncultivated crenarchaeote from soil

Molecular phylogenetic surveys based on the characterization of 16S rRNA genes have revealed that soil is an environment particularly rich in microbial diversity. A clade of crenarchaeota (archaea) has frequently been detected among many other novel lineages of uncultivated bacteria. In this study we have initiated a genomic approach for the characterization of uncultivated microorganisms from soil. We have developed a procedure based on a two-phase electrophoresis technique that allows the fast and reliable purification of concentrated and clonable, high molecular weight DNA. From this DNA we have constructed complex large-insert genomic libraries. Using archaea-specific 16S rRNA probes we have isolated a 34 kbp fragment from a 900 Mbp fosmid library of soil DNA. The clone contained a complete 16S/23S rRNA operon and 17 genes encoding putative proteins. Phylogenetic analyses of the rRNA genes and of several protein encoding genes (e.g. DNA polymerase, FixAB, glycosyl transferase) confirmed the specific affiliation of the genomic fragment with the non-thermophilic clade of the crenarchaeota. Content and structure of the genomic fragment indicated that the archaea from soil differ significantly from their previously studied uncultivated marine relatives. The protein encoding genes gave the first insights into the physiological potential of these organisms and can serve as a basis for future genomic and functional genomic studies.