Reverse transcription-PCR assay to verify gene integrity within plasmid constructs for plant transformation

We have developed a rapid and simple RT-PCR based method to check the integrity of chimeric genes within plasmid constructs for plant transformation. It exploits the Agrobacterium tumefaciens-mediated transient expression of plasmid constructs in plant tissue. Total RNA was isolated from tobacco leaves co-cultivated for 3 days with Agrobacterium tumefaciens harbouring the plant transformation vectors constructed in our laboratory. First strand cDNA synthesis with oligo(dT) primers generate a pool of cDNA that was used for PCR amplification with primers specific for each of the genes present within the constructs. PCR amplification reactions were successful for all chimeric genes tested, thus confirming their intactness and suitability to be used for stable plant transformation.     

A PCR-based method for isolation of genomic DNA flanking a known DNA sequence

We describe a simple PCR-based method for the isolation of genomic DNA that lies adjacent to a known DNA sequence. The method is based on the directional cloning of digested genomic DNA into the multiple cloning site of a pUC-based plasmid to generate a limited genomic library. The library is plated onto a number of selective LA plates which are incubated overnight, and recombinant plasmid DNA is then isolated from resistant colonies pooled from each plate. PCR amplification is performed on the pooled recombinant plasmid DNAs using primers specific for the pUC vector and the known genomic sequence. The combination of efficient directional cloning and bacterial transformation gives relative enrichment for the genomic sequence of interest and generates a simple DNA template, enabling easy amplification by PCR.     

Vectors for plant transformation and cosmid libraries.

A series of vectors has been constructed for the purpose of introducing cloned DNAs into plant genomes, using Agrobacterium tumefaciens-mediated transformation methods. One of these vectors, pCIT20, is a plasmid that contains a multiple cloning site (MCS), and a marker (Hph) that confers hygromycin resistance to plant cells. The others are all cosmid vectors which allow insertion of up to 46 kb of plant genomic DNA, and which also contain all of the necessary sequences for A. tumefaciens-mediated plant transformation. The cosmid vectors either contain a Hph marker (pCIT30), or a kanamycin-resistance marker (pCIT101-104). Three of the cosmid vectors (pCIT30, pCIT101, and pCIT103) carry bacteriophage T7 and SP6 promoters flanking the cloning Bg/II site, for synthesis of end-specific RNAs. The end-specific RNAs may be used as probes when labeled with radioactive or biotinylated nucleotides, for example, in a chromosome-walking experiment. The other two cosmid vectors (pCIT102 and pCIT104) carry restriction sites flanking the insertion site (XhoI) for convenient release of the insert by restriction digests. These sites, in combination with sites internal to the insert, allow the generation of end fragments for subcloning or labeling probes. These vectors should be valuable for isolation and analysis of plant genes, using transformation, library screening, and chromosome-walking approaches.     

Genomic fingerprints produced by PCR with consensus tRNA gene primers.

The polymerase chain reaction using only a single 'consensus' tRNA gene primer, or a pair of primers facing outward from tRNA genes, amplifies a set of DNA fragments in bacterial, plant and animal genomic DNAs. Presumably, these PCR fingerprints are mainly derived from the regions between closely linked tRNA genes. The pattern of the PCR products is determined by which genomes and which primer(s) are used. Genomic fingerprints are largely conserved within a species and, in bacteria, most products in the fingerprint are conserved between closely related species. Thus, PCR with tRNA gene consensus primers helps to identify species and genera.     

Chromosomal walking of flanking regions from short known sequences in GC-rich plant genomic DNA

High-efficiency thermal asymmetric interlaced (HE-TAIL) PCR is a modified thermal asymmetric interlaced (TAIL) method for finding unknown genomic DNA sequences adjacent to known sequences in GC-rich plant DNA. Necessary modifications to obtain high-efficiency amplification of flanking sequences are the inclusion of 2 control reactions during tertiary cycling and the design of long gene-specific primers, which can be used during single-step annealing-extension PCR. The modified protocol is suitable to walk from short known sequences, such as sequence-tagged sites (STS), expressed sequence tags (EST), or short exon sequences, and enables researchers to clone full-length open reading frames (ORFs) without library screening. Moreover, the HE-TAIL method can be used to identify DNA sequences flanking T-DNA insertions or to isolate promoter regions. Although individual steps are limited to about 4 kb, multiple steps can be done to walk upstream or downstream of known regions.     

In-fusion assembly: seamless engineering of multidomain fusion proteins, modular vectors, and mutations

In-Fusion can join any two pieces of DNA that have a 15-bp overlap at their ends. The result is equivalent to a recombination event at the ends of the DNAs. The 15-bp overlap may be engineered by inclusion in primers used to PCR amplify a segment of DNA. Originally described for inserting one piece of DNA into a restriction enzyme-digested plasmid, we have found In-Fusion can join four or more pieces of DNA in a single reaction. We used this insight to construct seamless fusion proteins, modular vectors with readily interchangeable segments, and novel mutagenesis strategies. Replacement In-Fusion can be used to delete any desired DNA segment in a plasmid and replace it with any desired new DNA segment without limitations on position or size.     

Re-usable DNA template for the polymerase chain reaction.

DNA covalently bound to an uncharged nylon membrane was used for consecutive amplifications of several different genes by PCR. Successful PCR amplifications were obtained for membrane-bound genomic and plasmid DNA. Membrane-bound genomic DNA templates were re-used at least 15 times for PCR with specific amplification of the desired gene each time. PCR amplifications of specific sequences of p53, p16, CYP1A1, CYP2D6, GSTM1 and GSTM3 were performed independently on the same strips of uncharged nylon membrane containing genomic DNA. PCR products were subjected to restriction fragment length polymorphism analysis, single-strand conformational polymorphism analysis and/or dideoxy sequencing to confirm PCR-amplified gene sequences. We found that PCR fragments obtained by amplification from bound genomic DNA as template were identical in sequence to those of PCR products obtained from free genomic DNA in solution. PCR was performed using as little as 5 ng genomic or 4 fg plasmid DNA bound to membrane. These results suggest that DNA covalently bound to membrane can be re-used for sample-specific PCR amplifications, providing a potentially unlimited source of DNA for PCR.     

Rapid amplification of genomic ends (RAGE) as a simple method to clone flanking genomic DNA

This report describes the amplification of upstream genomic sequences using the polymerase chain reaction (PCR) based solely on downstream DNA information from a cDNA clone. In this novel and rapid technique, genomic DNA (gDNA) is first incubated with a restriction enzyme that recognizes a site within the 5′ end of a gene, followed by denaturation and polyadenylation of its free 3′ ends with terminal transferase. The modified gDNA is then used as template for PCR using a gene-specific primer complementary to a sequence in the 3′ end of its cDNA and an anchored deoxyoligothymidine primer. A second round of PCR is then performed with a second, nested gene-specific primer and the anchor sequence primer. The resulting PCR product is cloned and its sequence determined. Three independent plant genomic clones were isolated using this method that exhibited complete sequence identity to their cDNAs and to the primers used in the amplification.     

Development of a versatile cassette for directional genome walking using cassette ligation-mediated PCR and its application in the cloning of complete lipolytic genes from Bacillus species

Since the invention of the PCR technology, adaptation techniques to clone DNA fragments flanking the known sequence continue to be developed. We describe a perfectly annealed cassette available in almost unlimited quantities with variable sticky-and blunt-end restriction enzyme recognition sites for efficient restriction and ligation with the restricted target genomic DNA. The cassette provides a 200-bp sequence, which is used to design a variety of cassette-specific primers. The dephosphorylation prevents cassette self-ligation and creates a nick at the cassette: target genome DNA ligation site suppressing unspecific PCR amplifications. We introduce the single-strand amplification PCR (SSA-PCR) technique where a lone known locus-specific primer is firstly used to enrich the targeted template DNA strand resulting in significant PCR product specificity during the second round conventional nested PCR. The distance between the known locus-specific primer and the nearest location of the restriction enzyme used determined the length of the obtained PCR product. We used this technique to walk downstream into the isochorismatase and upstream into the hypothetical conserved genes flanking the mature extracellular lipase gene from Bacillus licheniformis. We further demonstrated the potential of the technique as a cost-effective method during PCR-based prospecting for novel genes by designing "universal" degenerate primers that detected homologues of Family VII bacterial lipolytic genes in Bacillus species. The cassette ligation-mediated PCR was used to clone complete nucleotide sequences encoding functional lipolytic genes from B. licheniformis and Bacillus pumilus.     

Characteristics of microspheres formed in PCR with bacterial genomic DNA or plasmid DNA as templates

Earlier, we discovered that, along with linear DNA fragments, nano- and microparticles of DNA and their aggregates are formed in the PCR with yeast genomic DNA used as a template and gene-specific or partially complementary primers. The size of the microparticles (microspheres) varied in the range of 0.5 to 3–4 μm. Only thermostable KlenTaq polymerase but not Taq polymerase could effectively generate microspheres. In this work, we demonstrate that KlenTaq polymerase can produce microspheres of variable size (1 to 7 μm in diameter) if genomic DNA of the bacterium Acidithiobacillus ferrooxidans and partially complementary primers are present in the PCR mixture. Conditions for generation of DNA microparticles in PCR with Taq-polymerase and bacterial genomic DNA as template were also elaborated. It was also found that mainly large microspheres of up to 7 μm accumulated in PCR with plasmid DNAs used as templates and gene-specific primers in the presence of KlenTaq polymerase or mixtures of KlenTaq and Pfu polymerases. Besides, small aggregates, as well as linear branched structures and three-dimensional conglomerates of fused microspheres, were also revealed in the PCR mixtures. UV absorption spectra of native DNA microspheres and microspheres that had undergone heating at 93°C were registered. The key role of Mg²⁺ cations in the formation and stabilization of the microsphere structure was established.     

Design and testing of a plant-specific PCR primer for ecological and evolutionary studies

A polymerase chain reaction (PCR) primer, 28KJ (5-GGCGGTAAATTCCGTCC-3), was developed to specifically amplify plant DNA. This primer is located approximately 250 bases downstream of the 5′ end of the 28S ribosomal RNA gene, and it was used in combination with the universal primer 28C. The specificity of this primer combination was tested against 31 angiosperms, 9 conifers, 1 alga and 30 fungi (21 basidiomycetes and 9 ascomycetes). Both herbarium specimens and fresh samples were tested. The 28KJ/28C primer combination successfully amplified all angiosperm and conifer DNAs, but no fungal or algal DNAs. Plant DNA was amplified from plant/fungal symbioses (ectomycorrhizae of conifers and ericoid mycorrhizae of Ericaceous plants), and the plants involved in these symbioses were identified by comparing DNA sequences or restriction enzyme digest patterns of the mycorrhizal DNAs to those of known plant samples. These methods allow rapid and accurate identification of plant associates in complex plant/ fungal systems when the identity of the roots is unclear.     

Bacterial contamination of in vitro plant cultures: confounding effects on somaclonal variation and detection of contamination in plant tissues

Bacterial contamination represents a serious problem for plant tissue culture research and applications. Bacterial interference with normal plant physiology and morphology can generate misleading conclusions if the presence of bacteria is ignored. Bacterial contaminants in in vitro plant culture are typically detected by direct observation; thus, it is assumed that cultures without visible symptoms are bacteria free. Here, we demonstrate that contaminating Bacillus DNA in plant DNA solutions from asymptomatic plants can interfere with the analysis of somaclonal variation in chrysanthemum. We studied somaclonal variation in chrysanthemum using short semi-specific PCR primers based on conserved motifs in NBS–LRR disease resistance genes and in mobile elements. Instead of true somaclonal variation we found three polymorphic bands derived from contaminant bacterial DNA in plant extracts. Although the detection of asymptomatic bacteria in in vitro plant cultures is a major issue, we found that it has not been adequately addressed to date, particularly for studies on somaclonal variation. We reviewed the most commonly cited contaminant bacteria in in vitro plant culture and designed specific 16S rRNA gene-based PCR primers for the main genera causing contamination (Bacillus, Pseudomonas, Staphylococcus, Lactobacillus, Erwinia/Enterobacter and Xanthomonas). Using a panel of pure bacterial DNAs, artificial mixes of bacterial/plant DNAs, and in vitro plant cultures with and without visible contamination we demonstrated that our primers are in most instances both reliable and sensitive, and appropriate for the identification and tracking of the most frequent bacterial contaminants in plant in vitro cultures. Implications of bacterial identification to molecular analysis of somaclonal variation and plant culture decontamination are discussed.     

Development of Streptococcus gordonii‐specific quantitative real‐time polymerase chain reaction primers based on the nucleotide sequence of rpoB

In this study, Streptococcus gordonii‐specific quantitative real‐time polymerase chain reaction (qPCR) primers, RTSgo‐F2/RTSgo‐R2, were developed based on the nucleotide sequences of RNA polymerase β‐subunit gene (rpoB). The specificity of the RTSgo‐F2/RTSgo‐R2 primers was assessed by conventional PCR on 99 strains comprising 63 oral bacterial species, including the type strain and eight clinical isolates of S. gordonii. PCR products were amplified from the genomic DNAs of only S. gordonii strains. The qPCR primers were able to detect as little as 40 fg of S. gordonii genomic DNA at a cycle threshold value of 33. These findings suggest that these qPCR primers detect S. gordonii with high specificity and sensitivity.     

Ligation-independent cloning of PCR products (LIC-PCR).

A new procedure has been developed for the efficient cloning of complex PCR mixtures, resulting in libraries exclusively consisting of recombinant clones. Recombinants are generated between PCR products and a PCR-amplified plasmid vector. The procedure does not require the use of restriction enzymes, T4 DNA ligase or alkaline phosphatase. The 5'-ends of the primers used to generate the cloneable PCR fragments contain an additional 12 nucleotide (nt) sequence lacking dCMP. As a result, the amplification products include 12-nt sequences lacking dGMP at their 3'-ends. The 3'-terminal sequence can be removed by the action of the (3'----5') exonuclease activity of T4 DNA polymerase in the presence of dGTP, leading to fragments with 5'-extending single-stranded (ss) tails of a defined sequence and length. Similarly, the entire plasmid vector is amplified with primers homologous to sequences in the multiple cloning site. The vector oligos have additional 12-nt tails complementary to the tails used for fragment amplification, permitting the creation of ss-ends with T4 DNA polymerase in the presence of dCTP. Circularization can occur between vector molecules and PCR fragments as mediated by the 12-nt cohesive ends, but not in mixtures lacking insert fragments. The resulting circular recombinant molecules do not require in vitro ligation for efficient bacterial transformation. We have applied the procedure for the cloning of inter-ALU fragments from hybrid cell-lines and human cosmid clones.     

弓形虫特异DNA片段顺序分析及体外基因扩增

从弓形虫(ZS_2株)基因组文库中筛选出了一个弓形虫特异DNA片段的克隆,对克隆的片段进行了部分顺序分析。根据所得DNA顺序,自行设计并合成特异的寡核苷酸引物对,建立了体外扩增弓形虫特异DNA顺序的聚合酶链反应(PCR)方法。4种不同来源的弓形虫株DNA、人工感染弓形虫的三头幼猪白细胞和胸腺DNA经过PCR扩增,均出现特异的扩增条带;而正常人、正常幼猪外围血白细胞、正常小鼠脾脏、恶性疟原虫、卡氏肺孢子虫、溶组织内阿米巴和人巨细胞病毒DNA均不出现特异的扩增条带。对扩增产物进行了Southern印迹和限制性内切酶图谱分析,证明该PCR产物是弓形虫DNA特异的顺序。该方法可测出少至1pg的弓形虫DNA或1个弓形虫体的裂解液。本文分析的DNA顺序和设计合成的引物顺序数据,经电脑DNA数据库检索,证明无相同的顺序。本方法并具有简便、快速等优点,便于推广应用。     

Analysis of the virogenes related to the rhesus monkey endogenous type C retrovirus in monkeys and apes.

Molecular hybridization studies were carried out by using a [3H]complementary DNA (cDNA) probe to compare the endogenous type C retrovirus of rhesus monkeys (MMC-1) with other known retroviruses and related sequences in various primate DNAs. The genomic RNA of the endogenous type C retrovirus of stumptail monkeys (MAC-1) was found to be highly related to the MMC-1 cDNA probe, whereas the other retroviral RNAs tested showed no homology. Related sequences were found in Old World monkey DNAs and to a lesser extent in gorilla dn chimpanzee DNAs. No homology was detected between MMC-1 cDNA and DNA of gibbon, orangutan, or human origin. Restriction endonuclease analysis of genomic DNA indicated that many of the several hundred sequences related to MMC-1 in rhesus monkey DNA differed from that integrated into DNA of infected canine cells. Gorilla and chimpanzee DNAs contained a specific restriction endonuclease fragment of the MMC-1 genome.     

Identification of bacterial DNA markers for the detection of human fecal pollution in water

We used genome fragment enrichment and bioinformatics to identify several microbial DNA sequences with high potential for use as markers in PCR assays for detection of human fecal contamination in water. Following competitive solution-phase hybridization of total DNA from human and pig fecal samples, 351 plasmid clones were sequenced and were determined to define 289 different genomic DNA regions. These putative human-specific fecal bacterial DNA sequences were then analyzed by dot blot hybridization, which confirmed that 98% were present in the source human fecal microbial community and absent from the original pig fecal DNA extract. Comparative sequence analyses of these sequences suggested that a large number (43.5%) were predicted to encode bacterial secreted or surface-associated proteins. Deoxyoligonucleotide primers capable of annealing to a subset of 26 of the candidate sequences predicted to encode factors involved in interactions with host cells were then used in the PCR and did not amplify markers in DNA from any additional pig fecal specimens. These 26 PCR assays exhibited a range of specificity in tests with 11 other animal sources, with more than half amplifying markers only in specimens from dogs or cats. Four assays were more specific, detecting markers only in specimens from humans, including those from 18 different human populations examined. We then demonstrated the potential utility of these assays by using them to detect human fecal contamination in several impacted watersheds.