Bacteriophage lambda vector for transducing a cDNA clone library into mammalian cells.

We have developed a bacteriophage lambda vector (lambda NMT) that permits efficient transduction of mammalian cells with a cDNA clone library constructed with the pcD expression vector (H. Okayama and P. Berg, Mol. Cell. Biol. 3:280-289, 1983). The phage vector contains a bacterial gene (neo) fused to the simian virus 40 early-region promoter and RNA processing signals, providing a dominant-acting selectable marker for mammalian transformation. The phage DNA can accommodate pcD-cDNA recombinants with cDNA of up to about 9 kilobases without impairing the ability of the phage DNA to be packaged in vitro and propagated in vivo. Transfecting cells with the lambda NMT-pcD-cDNA recombinant phage yielded G418-resistant clones at high frequency (approximately 10(-2]. Cells that also acquired a particular cDNA segment could be detected among the G418-resistant transformants by a second selection or by a variety of screening protocols. Reconstitution experiments indicated that the vector could transduce 1 in 10(6) cells for a particular phenotype if the corresponding cDNA was present as 1 functional cDNA clone per 10(5) clones in the cDNA library. This expectation was confirmed by obtaining two hypoxanthine-guanine phosphoribosyltransferase (HPRT)-positive transductants after transfecting 10(7) HPRT-deficient mouse L cells with a simian virus 40-transformed human fibroblast cDNA library incorporated into the lambda NMT phage vector. These transductants contained the human HPRT cDNA sequences and expressed active human HPRT.     

Isolation and characterization of bovine and mouse terminal deoxynucleotidyltransferase cDNAs expressible in mammalian cells.

We have isolated nearly full-length cDNA clones of terminal deoxynucleotidyltransferase (TdT) from calf thymus and mouse lymphoma cDNA libraries. The libraries were constructed using the pcD vector system which permits the expression of cDNA inserts in mammalian cells. The bovine TdT cDNA clone contains an open reading frame coding for 520 amino acids, Mr 59,678. The mouse TdT cDNA clone contains an open reading frame of 1,587 bp, whose translated cDNA encodes a 60,004 dalton protein. The mouse TdT cDNA clone contains 60 bp in the 3' end region of the coding sequence not found in the bovine TdT cDNA sequence, otherwise, the clones share about 80% homology. A possible nuclear-localization-sequence (Pro-Arg-Lys-Lys-Arg-Pro-Arg) was conserved in the N-terminal region in the mouse and bovine cDNA clones. Bovine and mouse cDNAs transfected into COS7 monkey fibroblasts directed the synthesis of enzymatically active protein of Mr 60,000 which was detected immunologically using polyclonal rabbit antibody against bovine TdT. Bovine TdT expressed in COS7 cells by nearly full-length cDNA clone was localized in the nucleus and the translational product of pOK103 lacking the nuclear-localization-sequence was localized in the cytoplasm.     

An inducible expression vector for both fission and budding yeast

We have developed a vector system for inducible gene expression in both fission yeast (Schizosaccharomyces pombe) and budding yeast (Saccharomyces cerevisiae). The autonomously replicating expression vector contains multiple glucocorticoid response elements, rendering a linked promoter inducible 20-70-fold by glucocorticoid hormones in the presence of the mammalian glucocorticoid receptor. A polylinker with several unique cloning sites allows insertion of cDNAs of interest. Glucocorticoids are gratuitous signalling molecules in yeast, exerting little or no effect on the expression of genes other than those fused to the regulated promoter.     

Haemonchus contortus: evaluation of two signal sequence trapping systems for detection of secreted molecules

Given that signal sequences between secreted proteins of different species can be interchanged, it is reasonable to expect that both mammalian and yeast signal sequence trapping (SST) systems would secrete Haemonchus contortus proteins with similar efficiency and quality. To determine if H. contortus cDNAs that contain a signal sequence could re-establish secretion of a reporter protein, mammalian and yeast SST vectors were designed, 10 H. contortus genes selected, and their respective cDNAs cloned into these two SST vectors. The selected molecules included genes known to code for excretory/secretory or membrane-bound proteins as potential test 'positives', and genes known to code for non-secreted proteins as test 'negatives'. While differentiation between secretion and non-secretion was evident in both systems, the results indicated greater efficiency was achieved when the mammalian system was used. Therefore, mammalian SST using COS cells would be a more useful tool to screen H. contortus cDNA libraries for potential secreted and type-1 integral membrane proteins than yeast SST.     

Cytoplasmic RNA extraction from fresh and frozen mammalian tissues

The quality of collections of expressed sequence tags andfull-length cDNAs is adversely affected by the presence of "junk" clones derivedfrom unspliced or partially spliced RNAs present in conventional total RNA preparations. One can overcome this problem by using intact cytoplasmic RNA to create cDNA libraries, but the methods in the literature that describe the preparation of RNA only work well for extracting cultured cells. Cell lines are not as diverse as one would like, and to clone comprehensive sets of human and model organism full-length cDNAs, libraries have to be prepared from tissue samples. Thus, we have developed a robust and inexpensive method that allows intact cytoplasmic RNA to be extracted from both fresh and frozen mammalian tissues. A mouse full-length, cap-trapped cDNA library prepared with RNA using this new procedure had excellent characteristics.     

Cloning of open reading frames and promoters from the Saccharomyces cerevisiae genome: construction of genomic libraries of random small fragments

We have developed a novel efficient method, carrier-facilitated insertion, to insert small (150-600 bp) DNA fragments into plasmid vectors. This method employs a carrier segment of vector DNA to circumvent the difficulties in ligating two fragments together to generate a recombinant circle efficiently. We have used carrier-facilitated insertion to construct three genomic libraries of random (DNase I-generated) fragments from the Saccharomyces cerevisiae genome. One of these was an expression library, and the other two were promoter-cloning libraries. 87-90% of the Escherichia coli colonies in each library contained recombinant plasmids, and less than 3% of the recombinants contained more than one insert. Detection of open reading frames among the inserts in the expression library was accomplished by testing for beta-galactosidase activity. This methodology, unencumbered by the intrinsic disproportionality of cDNA libraries, can be used to identify and clone DNA that codes for a specific antigenic determinant. When used in combination with a method to detect and isolate random constitutive, repressible and inducible yeast promoters, these libraries should permit a comprehensive analysis of the yeast genome and its expression.     

Global amplification of cDNA from limiting amounts of tissue. An improved method for gene cloning and analysis

In this study we present an improved polymerase chain reaction (PCR)-based methodology to generate large amounts of high-quality complementary DNA (cDNA) from small amounts of initial total RNA. Global amplification of cDNA makes it possible to simultaneously clone many cDNAs and to construct directional cDNA libraries from a sequence-abundance-normalized cDNA population, and also permits rapid amplification of cDNA ends (RACE), from a limited amount of starting material. The priming of cDNAs with an adapter oligo-deoxythymidine (oligo-dT) primer and the ligation of a modified oligonucleotide to the 3′ end of single-stranded cDNAs, through the use of T4 RNA ligase, generates known sequences on either end of the cDNA population. This helps in the global amplification of cDNAs and in the sequence-abundance normalization of the cDNA population through the use of PCR. Utilization of a long-range PCR enzyme mix to amplify the cDNA population helps to reduce bias toward the preferential amplification of shorter molecules. Incorporation of restriction sites in the PCR primers allows the amplified cDNAs to be directionally cloned into appropriate cloning vectors to generate cDNA libraries. RACE-PCR done with biotinylated primers and streptavidin-coated para-magnetic particles are used for the efficient isolation of either full-length coding or noncoding strands.     

Construction of a human full-length cDNA bank

We aimed to construct a full-length cDNA bank from an entire set of human genes and to analyze the function of a protein encoded by each cDNA. To achieve this purpose, a multifunctional phagemid shuttle vector, pKAl, was constructed for preparing a high-quality cDNA library composed of full-length cDNA clones which can be sequenced and expressed in vitro and in mammalian cells without subcloning the cDNA fragment into other vectors. Using this as a vector primer, we have prepared a prototype of the bank composed of full-length cDNAs encoding 236 human proteins whose amino acid sequences are identical or similar to known proteins. Most cDNAs contain a putative cap site sequence, some of which show a pyrimidine-rich conserved sequence exhibiting polymorphism. It was confirmed that the vector permits efficient in vitro translation, expression in mammalian cells and the preparation of nested deletion mutants.     

cDNA selection with YACs

Identification of expressed sequence tags (ESTs) in large genomic segments is an important step in positional cloning and genomic mapping studies. A simple and efficient polymerase chain reaction (PCR)-based approach is described here to identify coding sequences in large genomic fragments of DNA cloned in vectors such as yeast artificial chromosome (YAC) vectors. The method is based on blocking of sequences such as repetitive and GC rich sequences in the genomic DNA immobilized on nylon paper discs prior to hybridization of the discs to cDNA library, and recovery of the selected cDNAs by the PCR. Single or multiple cDNA libraries can be used in the selection procedure. The procedure has been used successfully also with total yeast DNA containing a YAC.     

Expression cloning of oncogenes by retroviral transfer of cDNA libraries.

a cDNA library transfer system based on retroviral vectors has been developed for expression cloning in mammalian cells. The use of retroviral vectors results in stable cDNA transfer efficiencies which are at least 100-fold higher than those achieved by transfection and therefore enables the transfer and functional screening of very large libraries. In our initial application of retroviral transfer of cDNA libraries, we have selected for cDNAs which induce oncogenic transformation of NIH 3T3 fibroblasts, as measured by loss of contact inhibition of proliferation. Nineteen different transforming cDNAs were isolated from a total of 300,000 transferred cDNA clones. Three of these cDNAs were derived from known oncogenes (raf-1, lck, and ect2), while nine others were derived from genes which had been cloned previously but were not known to have the ability to transform fibroblasts (beta-catenin, thrombin receptor, phospholipase C-gamma 2 and Spi-2 protease inhibitor genes). The Spi-2 cDNA was expressed in antisense orientation and therefore is likely to act as an inhibitor of an endogenous transformation suppressor. Seven novel cDNAs with transforming activities, including those for three new members of the CDC24 family of guanine nucleotide exchange factors, were also cloned from the retroviral cDNA libraries. Retroviral transfer of libraries should be generally useful for cloning cDNAs which confer selectable phenotypes on many different types of mammalian cells.     

A simple and efficient procedure for generating stable expression libraries by cDNA cloning in a retroviral vector.

cDNA expression cloning is a powerful method for the rescue and identification of genes that are able to confer a readily identifiable phenotype on specific cell types. Retroviral vectors provide several advantages over DNA-mediated gene transfer for the introduction of expression libraries into eukaryotic cells since they can be used to express genes in a wide range of cell types, including those that form important experimental systems such as the hemopoietic system. We describe here a straightforward and efficient method for generating expression libraries by using a murine retroviral vector. Essentially, the method involves the directional cloning of cDNA into the retroviral vector and the generation of pools of stable ecotropic virus producing cells from this DNA. The cells so derived constitute the library, and the virus they yield is used to infect appropriate target cells for subsequent functional screening. We have demonstrated the feasibility of this procedure by constructing several large retroviral libraries (10(5) to 10(6) individual clones) and then using one of these libraries to isolate cDNAs for interleukin-3 and granulocyte-macrophage colony-stimulating factor on the basis of the ability of these factors to confer autonomous growth on the factor-dependent hemopoietic cell line FDC-P1. Moreover, the frequency at which these factor-independent clones were isolated approximated the frequency at which they were represented in the original plasmid library. These results suggest that expression cloning with retroviruses is a practical and efficient procedure and should be a valuable method for the isolation of important regulatory genes.     

High-efficiency transformation of mammalian cells by plasmid DNA.

We describe a simple calcium phosphate transfection protocol and neo marker vectors that achieve highly efficient transformation of mammalian cells. In this protocol, the calcium phosphate-DNA complex is formed gradually in the medium during incubation with cells and precipitates on the cells. The crucial factors for obtaining efficient transformation are the pH (6.95) of the buffer used for the calcium phosphate precipitation, the CO2 level (3%) during the incubation of the DNA with the cells, and the amount (20 to 30 micrograms) and the form (circular) of DNA. In sharp contrast to the results with circular DNA, linear DNA is almost inactive. Under these conditions, 50% of mouse L(A9) cells can be stably transformed with pcDneo, a simian virus 40-based neo (neomycin resistance) marker vector. The NIH3T3, C127, CV1, BHK, CHO, and HeLa cell lines were transformed at efficiencies of 10 to 50% with this vector and the neo marker-incorporated pcD vectors that were used for the construction and transduction of cDNA expression libraries as well as for the expression of cloned cDNA in mammalian cells.     

Electroporation-mediated transfection of mammalian cells with crude plasmid DNA preparations

We designed a simple and reproducible electroporation-mediated transfection procedure with which to screen mammalian expression vector-constructed cDNA libraries. Using a specific chamber composed of five parallel electrodes, the recipient cells can be electroporated separately with 40 plasmid DNA preparations in a single experiment. Over 300 crude plasmids prepared from E. coli (DH-5) carrying a pcD2neo-vector-derived cDNA library were tested. The efficiency of stable transfection by electroporation with crude plasmid DNA preparations was 10-times higher than with the CsCl-purified plasmid DNA. When the crude plasmids were digested with RNase, the efficiency of stable transfection markedly decreased, indicating that the contaminating bacterial RNA in the crude plasmid preparations has a strong carrier effect during the electroporation. Even when salmon sperm DNA or genomic DNA from the recipient cells was used as the carrier of the purified plasmid, the efficiency was not higher than that using the crude preparations. This procedure is useful not only for screening a number of cDNAs but also for routinely introducing biologically active foreign genes into cultured mammalian cells.