Oligodeoxyribonucleotide ligation to single-stranded cDNAs: a new tool for cloning 5'' ends of mRNAs and for constructing cDNA libraries by in vitro amplification.

Cloning full length cDNAs is a difficult task especially if mRNAs are not abundant or if tissue is only available in limited amounts. Current strategies are based on in vitro amplification of cDNAs after adding a homopolymeric tail at the 3' end of the ss-cDNA. Since subsequent amplification steps yield unspecific amplified DNA mostly due to non-specific annealing of the reverse primer containing a homopolymeric tail, we have devised a new strategy based on the ligation of single-stranded oligodeoxyribonucleotide to the 3' end of single-stranded cDNAs. The efficiency of the strategy was assessed by analyzing the 5' ends of the rat pineal gland tryptophan hydroxylase messenger. The 5' end of the least abundant messenger (0.005% of total mRNAs) could be cloned without selection. Sixty percent of the analyzed clones correspond to TPH. This technique revealed a 5-nt stretch not apparent using dG tailing strategy. The potentiality of the method for generating cDNAs libraries was tested with 10(4) PC12 cells. In this library, the abundance of tyrosine hydroxylase clones (0.03%) correlated well with the abundance of the corresponding messenger, showing that no major distortion was introduced into the construction of the library.     

Characterization of size-fractionated cDNA libraries generated by the in vitro recombination-assisted method.

We here modified a previously reported method for the construction of cDNA libraries by employing an in vitro recombination reaction to make it more suitable for comprehensive cDNA analysis. For the evaluation of the modified method, sets of size-selected cDNA libraries of four different mouse tissues and human brain were constructed and characterized. Clustering analysis of the 3' end sequence data of the mouse cDNA libraries indicated that each of the size-fractionated libraries was complex enough for comprehensive cDNA analysis and that the occurrence rates of unidentified cDNAs varied considerably depending on their size and on the tissue source. In addition, the end sequence data of human brain cDNAs thus generated showed that this method decreased the occurrence rates of chimeric clones by more than fivefold compared to conventional ligation-assisted methods when the cDNAs were larger than 5 kb. To further evaluate this method, we entirely sequenced 13 human unidentified cDNAs, named KIAA1990-KIAA2002, and characterized them in terms of the predicted protein sequences and their expression profiles. Taking all these results together, we here conclude that this new method for the construction of size-fractionated cDNA libraries makes it possible to analyze cDNAs efficiently and comprehensively.     

A rapid single-stranded cloning strategy for producing a sequential series of overlapping clones for use in DNA sequencing: application to sequencing the corn mitochondrial 18 S rDNA

A simple new procedure was described for producing a sequential series of overlapping clones for use in DNA sequencing. The technique used single-stranded M13 DNA and complementary DNA oligomers to form specific cleavage and ligation substrates. It was, therefore, independent of the sequence of the DNA cloned into the vector. Deletions of varying sizes were generated from one end of the insert through the 3' to 5' exonuclease activity of T4 DNA polymerase. The approximate size of the deletion and therefore the starting point for DNA sequencing could be estimated by electrophoresis of the subcloned phage DNA on a agarose gel. This greatly reduced the number of templates that must be sequenced to obtain a complete sequence. The entire procedure could be carried out in one tube in less than a day. The procedure was used to subclone and sequence the maize mitochondrial 18 S rDNA and 5' flanking region (2622 bases) in less than a week. Other applications of oligomers and single-stranded DNA in the construction of insertions, deletions, and cDNAs are discussed.     

Vector-capping: a simple method for preparing a high-quality full-length cDNA library.

Full-length cDNAs play an essential role in identifying genes and determining their promoter regions. Here we describe a simple method for constructing a full-length cDNA library, which has the following advantages: (i) it consists of only three steps including direct ligation between a vector and a cDNA strand using T4 RNA ligase, (ii) it contains neither a PCR process generating mutations nor restriction enzyme treatment causing truncation of cDNA, (iii) the intactness of cDNA is assured due to the presence of an additional dGMP at its 5' end, (iv) approximately 95% of cDNA clones are full-length when cultured cells or fresh tissues are used, (v) several micrograms of total RNA without mRNA purification is sufficient for preparation of a library containing >10(5) independent clones, and (vi) a long-sized full-length cDNA up to 9.5 kbp can be cloned. This method will accelerate comprehensive gene analysis in a variety of eukaryotes.     

Cloning full-length, cap-trapper-selected cDNAs by using the single-strand linker ligation method.

We have developed the single-strand linker ligation method (SSLLM), which uses DNA ligase to add a dsDNA linker to single-stranded (ss) full-length cDNA. The linkers have random 6-bp (dN6 or dGN5) 3' overhangs that can ligate to any cDNA sequence, thereby facilitating the production of cDNA libraries with titers exceeding 1 x 10(6) independent clones. We confirmed that the 5' ends of cDNA inserts cloned by using SSLLM are full-length and include the 5' untranslated regions. The great advantage of our method is that the elimination of the GC tail simplifies the sequencing and protein translation of the full-length clones. Further, our method tags ss cDNAs more efficiently than does the traditional RNA ligase reaction.     

Principles of microRNA-target recognition

MicroRNAs (miRNAs) are short non-coding RNAs that regulate gene expression in plants and animals. Although their biological importance has become clear, how they recognize and regulate target genes remains less well understood. Here, we systematically evaluate the minimal requirements for functional miRNA-target duplexes in vivo and distinguish classes of target sites with different functional properties. Target sites can be grouped into two broad categories. 5' dominant sites have sufficient complementarity to the miRNA 5' end to function with little or no support from pairing to the miRNA 3' end. Indeed, sites with 3' pairing below the random noise level are functional given a strong 5' end. In contrast, 3' compensatory sites have insufficient 5' pairing and require strong 3' pairing for function. We present examples and genome-wide statistical support to show that both classes of sites are used in biologically relevant genes. We provide evidence that an average miRNA has approximately 100 target sites, indicating that miRNAs regulate a large fraction of protein-coding genes and that miRNA 3' ends are key determinants of target specificity within miRNA families.     

In situ screening for genes expressed preferentially in secondary mesenchyme cells of sea urchin embryos

In sea urchin embryos, four types of non-skeletogenic mesodermal cells are derived from secondary mesenchyme cells (SMCs). Although determining the complete lineage of SMCs is currently a high-priority goal, specific markers for each type of SMC-derived cell in Hemicentrotus pulcherrimus are unavailable. To identify genes preferentially expressed in the various types of SMC-derived cells, we constructed a cDNA library of the archenteron isolated from late gastrulae. Both the 5' and 3' ends of 1,050 cDNAs randomly selected from 7,500 picked clones were sequenced. Based on the sequence at the 3' end, the cDNAs were grouped into 671 independent clusters. Among these, 605 clusters were analysed by whole-mount in situ hybridisation; 28% (170 clusters) exhibited differential expression patterns, while 24% were ubiquitously expressed and 48% did not show any staining. Of 170 clusters showing differential expression patterns, 33 clusters were differentially expressed in SMC-derived cells. From these clusters, several genes were obtained that were specifically or predominantly expressed in each type of SMCs, including coelomic pouch cells in which specific expression patterns have not been reported previously, and hence will be useful for lineage studies. Furthermore, in situ hybridisation revealed the existence of a new type or subpopulation of SMCs distributed sparsely in the blastocoel.     

A simple and rapid method for cloning insect vitellogenin cDNAs

We describe a simple and rapid method for cloning insect vitellogenin (Vg) cDNAs. The method relies on the facts that insect Vg amino acid sequences can be aligned confidently along their entire lengths and that a short, highly conserved GL/ICG motif and up to nine cysteine residues that follow at conserved locations are present near the C-termini. An adaptor-ligated double-strand cDNA library is constructed from poly(A)+ RNA prepared from vitellogenic female fat body tissues using a commercial kit, and subjected to PCR with each of the degenerate nucleotide sequences for the GL/ICG motif and the adaptor sequence as primers. The PCR products (0.7-0.9 kb, representing the 3' portion) are cloned, the nucleotide sequences are determined, and the deduced amino acid sequences are aligned with the known insect Vg sequences starting from the GL/ICG motif. Gene-specific primers corresponding to the sequences near the 5'-termini of the initial clones and the adaptor sequence are employed to obtain the remaining 5' portion of the Vg cDNAs. The method was successfully applied to the bean bug Plautia stali (Heteroptera), revealing three Vg genes.