Full-length cDNA cloning utilizing the polymerase chain reaction, a degenerate oligonucleotide sequence and a universal mRNA primer.

A full-length cDNA was selectively amplified by the polymerase chain reaction (PCR) utilizing a primer pair consisting of a "universal" 21-base synthetic deoxyoligonucleotide (oligo dT 17GGCC) and a specific degenerate deoxyoligonucleotide sequence (DOS) derived from the N-terminal amino acid sequence. This double-stranded amplified cDNA was uni-directionally cloned into M13mp19 utilizing two restriction sites that had been previously incorporated into the termini of the universal and specific DOS primers. Cloning of the specific cDNA via this PCR amplification with the universal/specific DOS primer pair approach was confirmed by screening with a second DOS contiguous with the DOS employed to prime second (sense)-strand cDNA synthesis. This technique allows for the selective full-length cDNA cloning of low-abundance mRNAs from a single-protein sequence determination.     

PrimerCE: Designing Primers for Cloning and Gene Expression

A number of primer design programs have been developed for diverse applications. However, none of these programs can be used to design primers for gene cloning aimed at expressing protein. Here we report the design of PrimerCE, which can be used to cover the whole process of gene cloning and expression. The main features of PrimerCE include inspection of restriction enzyme recognition sequence, open reading frame verification, stop codon inspection, base adjustment, primer optimization, sequence assembly and protein analysis. In addition to this, the program can be modified based on the different needs of users, e.g. new vector sequence and restriction enzyme recognition sequences can be integrated. With the use of PrimerCE, a pair of primers can be designed within minutes. The program has been proven to be efficient in designing primers in our high throughput cloning and gene expression experiments. The software is freely available at .     

Seamless gene engineering using RNA- and DNA-overhang cloning

Here we describe two methods for generating DNA fragments with single-stranded overhangs, like those generated by the activity of many restriction enzymes, by simple methods that do not involve DNA digestion. The methods, RNA-overhang cloning (ROC) and DNA-overhang cloning (DOC), generate polymerase chain reaction (PCR) products composed of double-stranded (ds) DNA flanked by single-stranded (ss) RNA or DNA overhangs. The overhangs can be used to recombine DNA fragments at any sequence location, creating "perfect" chimeric genes composed of DNA fragments that have been joined without the insertion, deletion, or alteration of even a single base pair. The ROC method entails using PCR primers that contain regions of RNA sequence that cannot be copied by certain thermostable DNA polymerases. Using such a chimeric primer in PCR would yield a product with a 5' overhang identical to the sequence of the RNA component of the primer, which can be used for directional ligation of the amplified product to other preselected DNA molecules. This method provides complete control over both the length and sequence of the overhangs, and eliminates the need for restriction enzymes as tools for gene engineering.     

Rapid amplification of genomic DNA ends bynla III partial digestion and polynucleotide tailing

We report a simple and efficient method, which combines restriction endonuclease digestion and deoxynucleotide tailing, for cloning unknown genomic sequences adjacent to a known sequence. Total genomic DNA is partially digested with the frequent-cutting restriction enzymeNla III. A homo-oligomeric cytosine tail is added by terminal transferase. The tailed DNA fragments are used as the template for cloning flanking regions from all sequences of interest. A first round PCR amplification is performed with a gene-specific primer and the selective (modified polyguanine) anchor primer complementary to the cytosine tail and theNla III recognition site, with a universal amplification primer sequence at its 5′ end. This is followed by another PCR amplification with a nested gene-specific primer and the universal amplification primer. Finally, the amplified products are fractionated, cloned, and sequenced. Using this method, we cloned the upstream region of a salt-induced gene based upon a partial cDNA clone (RSC5-U) obtained from sunflower (Helianthus annuus L.).     

LoxP-directed cloning: use of Cre recombinase as a universal restriction enzyme.

We have developed a novel way to use the Cre/loxP system for in vitro manipulation of DNA and a technique to clone DNA into circular episomes. The method is fast, reliable, and allowsflexible cloning of DNA fragments into episomes containing a loxP site. We show that a loxP site can serve as a universal target site to clone a DNA fragment digested with any restriction enzyme(s). This technique abolishes the need for compatible restriction sites in cloning vectors and targets by generating custom-designed 5' 3', or blunt ends in the desired orientation and reading frame in the vector Therefore, this method eliminates the limitations encountered when DNA fragments are cloned into vectors with a confined number of cloning sites. The 34-bp loxP sequence assures uniqueness, even when large episomes are manipulated. We present three examples, including the manipulation of a bacterial artificial chromosome. Because DNA manipulation takes place at a loxP site, we refer to this technique as loxP-directed cloning.     

Restriction Site-dependent PCR: An Efficient Technique for Fast Cloning of New Genes of Microorganisms

New bioactive proteins need to be screened from various microorganismsfor the increasing need for industrial and pharmaceutical peptide,proteins, or enzymes. A novel polymerase chain reaction (PCR)method, restriction site-dependent PCR (RSD-PCR), was designedfor rapid new genes cloning from genomic DNA. RSD-PCR strategyis based on these principles: (i) restriction sites dispersethroughout genomes are candidacy for universal pairing; (ii)a universal primer is a combination of a 3'-end of selectedrestriction sites, and a 5'-end of degenerated sequence. A two-roundPCR protocol was designed and optimized for the RSD-PCR: amplifythe single strand target template from genomic DNA by a specificprimer and amplify the target gene by using the specific primerand one of the universal RSD-primers. The optimized RSD-PCRwas successfully applied in chromosome walking using specificinternal primers, and cloning of new genes using degeneratedprimers derived from NH₂-terminal amino acid sequence of protein.     

Improving quality of expressed sequence tag (EST) databases: recovery of reversed, antisense cDNA sequences

Expressed sequence tag (EST) databases contain a significant number (5-20%) of reversed, antisense, cDNA sequences that can be recognized by the label "reversed clone: similarity on wrong strand" in the annotations to the sequence. Despite this high number of altered sequences, no attempt has been made to explain the alteration in molecular terms, or to evaluate their effect on the quality of the information curated in EST databases. In this paper we try to explain the way these altered sequences are originated, and propose a plausible mechanism: a "double priming" of the first strand oligo-dT primer at both ends of nascent cDNAs. In this way, a symmetrical cDNA intermediate is generated, an intermediate that can be cloned after partial digestion with the restriction enzyme used for the directional cloning. Furthermore, when "secondary" priming takes place inside the cDNA, the chain synthesized is prone to be truncated prematurely, with the subsequent loss of upstream information. One of the most subtle effects of this cloning alteration is the generation of virtual open reading frames (ORFs) in sequences with no homologues available for comparison. Nevertheless, and according to our model and our data, the "double priming mechanism" does not shift the ORF effected, so antisense sequences should be considered as normal ones after a simple transformation in their inverse-complementary forms.     

RF cloning: a restriction-free method for inserting target genes into plasmids

Restriction-free (RF) cloning provides a simple, universal method to precisely insert a DNA fragment into any desired location within a circular plasmid, independent of restriction sites, ligation, or alterations in either the vector or the gene of interest. The technique uses a PCR fragment encoding a gene of interest as a pair of primers in a linear amplification reaction around a circular plasmid. In contrast to QuickChange site-directed mutagenesis, which introduces single mutations or small insertions/deletions, RF cloning inserts complete genes without the introduction of unwanted extra residues. The absence of any alterations to the protein as well as the simplicity of both the primer design and the procedure itself makes it suitable for high-throughput expression and ideal for structural genomics.     

DNA sequencing by a subcloning-walking strategy using a specific and semi-random primer in the polymerase chain reaction.

In its basic concept, in vitro DNA amplification by the polymerase chain reaction (PCR) is restricted to those instances in which segments of known sequence flank the fragment to be amplified. Recently, techniques have been developed for amplification of unknown DNA sequences. These techniques, however, are dependent on the presence of suitable restriction endonuclease sites. Here, we describe a strategy for PCR amplification of DNA that lies outside the boundaries of known sequence. It is based on the use of one specific primer, homologous to the known sequence, and one semi-random primer. Restriction sites in the 5' proximal regions of both primers allow for cloning of the amplified DNA in a suitable sequencing vector or any other vector. It was shown by sequence analysis that the cloned DNA fragments represent contiguous DNA fragments that are flanked at one side by the sequence of the specific primer. When omitting the semi-random primer, a single clone was obtained, which originated from PCR amplification of target DNA by the specific primer in both directions.     

Changes of 5＇ Terminal Nucleotides of PCR Primers Causing Variable T-A Cloning Efficiency

T-A cloning takes advantage of the unpaired adenosyl residue added to the 3＇ terminus of amplified DNAs by Taq and other thermostable DNA polymerase and uses a Ilnearlzed plasmld vector with a protruding 3＇ thymldylate residue at each of Its 3＇ termini to clone polymerase chain reaction （PCR）-derived DNA fragments. It Is a simple, reliable, and efficient Ilgatlon-dependent cloning method for PCR products, but the drawback of variable cloning efficiency occurs during application. In the present work, the relationship between variable T-A cloning efficiency and the different 5＇ end nucleotlde base of primers used In PCR amplification was studied. The results showed that different cloning efficiency was obtained with different primer pairs containing A, T, C and G at the 5＇ terminus respectively. The data shows that when the 5＇ end base of primer pair was adenosyl, more white colonies could be obtained In cloning the corresponding PCR product In comparison with other bases. And the least white colonies were formed when using the primer pair with 5＇ cytldylate end. The gluanylate end primers resulted In almost the same cloning efficiency In the white colonies amount as the thymldylate end primer did, and this efficiency was much lower than that of adenosyl end primers. This presumably is a consequence of variability In 3＇dA addition to PCR products mediated by Taq polymerase. Our results offer instructions for primer design for researchers who choose T-A cloning to clone PCR products.     

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.     

PlasmaDNA: a free, cross-platform plasmid manipulation program for molecular biology laboratories

Background

Most molecular biology experiments, and the techniques associated with this field of study, involve a great deal of engineering in the form of molecular cloning. Like all forms of engineering, perfect information about the starting material is crucial for successful completion of design and strategies.

Results

We have generated a program that allows complete in silico simulation of the cloning experiment. Starting with a primary DNA sequence, PlasmaDNA looks for restriction sites, open reading frames, primer annealing sequences, and various common domains. The databases are easily expandable by the user to fit his most common cloning needs. PlasmaDNA can manage and graphically represent multiple sequences at the same time, and keeps in memory the overhangs at the end of the sequences if any. This means that it is possible to virtually digest fragments, to add the digestion products to the project, and to ligate together fragments with compatible ends to generate the new sequences. Polymerase Chain Reaction (PCR) fragments can also be virtually generated using the primer database, automatically adding to the fragments any 5' extra sequences present in the primers.

Conclusion

PlasmaDNA is a program available both on Windows and Apple operating systems, designed to facilitate molecular cloning experiments by building a visual map of the DNA. It then allows the complete planning and simulation of the cloning experiment. It also automatically updates the new sequences generated in the process, which is an important help in practice. The capacity to maintain multiple sequences in the same file can also be used to archive the various steps and strategies involved in the cloning of each construct. The program is freely available for download without charge or restriction.     

An efficient synthetic primer for the M13 cloning dideoxy sequencing system

The deoxytetradecamer d(AAAACGACGGCCAG) has been shown to be an excellent universal primer for sequence determination of DNA cloned into the bacteriophage M13 mp7, mp8, and mp9 series. This new primer offers several advantages over others currently available and it has been used to define the cloning of Hinf I fragments of bacteriophage S13 DNA into the Eco RI site of M13 mp7, utilizing the homologous complementary base pairing of the two restriction sites. Of the four possible sequence derivatives of the Hinf I GANTC recognition site, only those corresponding to GAATC and GATTC have been found at cloning sites in chimeras.     

转录因子DREB1A基因的克隆与Gateway克隆技术构建植物表达载体

目的:研究转录因子DREB1A在植物抗渗透胁迫反应中的作用,并探讨利用Gateway克隆技术构建植物表达载体的方法。方法:根据GenBank中登录的DREB1A基因的全长mRNA序列设计引物,克隆了拟南芥的转录因子DREBIA基因。根据Gateway克隆技术的要求,设计含有attB接头的引物,利用高保真的PlatinumpfxDNA聚合酶,通过PCR方法在克隆基因的两端加上B序列。通过BP反应将包含有attB接头的PCR产物克隆到含有attP的donor载体上以产生Entry克隆,通过LR反应将已经重组入Entry载体的DREB1A基因再克隆到pH2GW7双元载体。结果:对重组载体pH2GW7-DREB1A的鉴定结果表明成功构建了DREB1A基因的植物表达载体。结论:利用Gateway克隆技术构建植物表达载体简便易行,该结果为遗传转化研究奠定了基础。     

A novel, rapid method for the isolation of terminal sequences from yeast artificial chromosome (YAC) clones.

The recent development of yeast artificial chromosome (YAC) vectors has provided a system for cloning fragments that are over ten times larger than those that can be cloned in more established systems. We have developed a method for the rapid isolation of terminal sequences from YAC clones. The YAC clone is digested with a range of restriction enzymes, a common linker is ligated to the DNA fragments and terminal sequences are amplified using a vector specific primer and a linker specific primer. Sequence data derived from these terminal specific products can be used to design primers for a further round of screening to isolate overlapping clones. The method also provides a convenient method of generating Sequence Tagged Sites for the mapping of complex genomes.     

A universal cloning vector using vaccinia topoisomerase I

Vaccinia DNA topoisomerase I (TOPO) charged vectors with a sticky T are routinely used to clone polymerase chain reaction (PCR) products with an extra A at their 3′ end (TOPO TA Cloning from Invitrogen). TOPO charged blunt vectors are used to clone blunt end PCR products (TOPO Blunt Cloning). Here, we demonstrate that both TOPO TA vectors and TOPO Blunt vectors can be used to clone PCR products with either a blunt end or an extra A at the 3′ end. We further demonstrate that these vectors can be used to clone sticky end DNA generated with restriction enzymes. In summary, these TOPO vectors can be used as universal cloning vectors.     

A family of high-copy-number plasmid vectors with single end-label sites for rapid nucleotide sequencing

A set of plasmid vectors was developed which allows fast sequencing by the chemical degradation method. These high-copy-number vectors are derivatives of the plasmid pUC8 containing different multiple-purpose cloning sites flanked by unique recognition sequences for the restriction enzymes BstEII, Tth111I and Eco81I as sites for end-labelling DNA. Due to their partially asymmetric recognition sequences, each of these three restriction sites can be singly end-labelled by a filling-in reaction with selected nucleotides. This allows easy single end-labelling of any cloned DNA fragment for sequencing by the chemical degradation method without any isolation and purification step after the labelling reaction. In addition, the nucleotide sequence of the complementary strand from the same end can be determined by the dideoxy chain termination procedure using the universal M13 primers. In most of the new vectors, the reading frame of the lacZ' gene is retained, allowing identification of cloned fragments.     

Targeted gene walking polymerase chain reaction.

We describe a modification of a polymerase chain reaction method called 'targeted gene walking' that can be used for the amplification of unknown DNA sequences adjacent to a short stretch of known sequence by using the combination of a single, targeted sequence specific PCR primer with a second, nonspecific 'walking' primer. This technique can replace conventional cloning and screening methods with a single step PCR protocol to greatly expedite the isolation of sequences either upstream or downstream from a known sequence. A number of potential applications are discussed, including its utility as an alternative to cloning and screening for new genes or cDNAs, as a method for searching for polymorphic sites, restriction endonuclease or regulatory regions, and its adaptation to rapidly sequence DNA of lengthy unknown regions that are contiguous to known genes.     

PCR-based diversity estimates of artificial and environmental 18S rRNA gene libraries

ABSTRACT. Environmental clone libraries constructed using small subunit ribosomal RNA (rRNA) or other gene-specific primers have become the standard molecular approach for identifying microorganisms directly from their environment. This technique includes an initial polymerase chain reaction (PCR) amplification step of a phylogenetically useful marker gene using universal primers. Although it is acknowledged that such primers introduce biases, there have been few studies if any to date systematically examining such bias in eukaryotic microbes. We investigated some implications of such bias by constructing clone libraries using several universal primer pairs targeting rRNA genes. Firstly, we constructed artificial libraries using a known mix of small cultured pelagic arctic algae with representatives from five major lineages and secondly we investigated environmental samples using several primer pairs. No primer pair retrieved all of the original algae in the artificial clone libraries and all showed a favorable bias toward the dinoflagellate Polarella glacialis and a bias against the prasinophyte Micromonas and a pennate diatom. Several other species were retrieved by only one primer pair tested. Despite this, sequences from nine environmental libraries were diverse and contained representatives from all major eukaryotic clades expected in marine samples. Further, libraries from the same sample grouped together using Bray–Curtis clustering, irrespective of primer pairs. We conclude that environmental PCR-based techniques are sufficient to compare samples, but the total diversity will probably always be underestimated and relative abundance estimates should be treated with caution.