Subtraction of cap-trapped full-length cDNA libraries to select rare transcripts

The normalization and subtraction of highly expressed cDNAs from relatively large tissues before cloning dramatically enhanced the gene discovery by sequencing for the mouse full-length cDNA encyclopedia, but these methods have not been suitable for limited RNA materials. To normalize and subtract full-length cDNA libraries derived from limited quantities of total RNA, here we report a method to subtract plasmid libraries excised from size-unbiased amplified lambda phage cDNA libraries that avoids heavily biasing steps such as PCR and plasmid library amplification. The proportion of full-length cDNAs and the gene discovery rate are high, and library diversity can be validated by in silico randomization.     

Cloning full-length cDNA of grapevine chrome mosaic nepovirus

Full-length cDNA copies of the genomic RNAs of grapevine chrome mosaic virus were obtained and cloned in Escherichia coli by a one-step procedure. The cloning protocol included size selections by agarose-gel electrophoresis of both the single-stranded and the double-stranded full-length cDNAs. First-strand cDNA synthesis was primed with oligodeoxythymidine while second-strand synthesis was primed with specific synthetic oligodeoxynucleotides, allowing cloning of the 3' poly(A) and of the last 5' nucleotides of the viral RNA template. For the 7.2-kb and 4.4-kb viral RNAs, up to 20% and 80%, respectively, of the clones were found to be full-length. Even for large templates, this procedure allows fast and efficient cloning of full-length cDNAs.     

Construction of small RNA cDNA libraries for deep sequencing

Small RNAs (21-24 nucleotides) including microRNAs (miRNAs) and small interfering RNAs (siRNAs) are potent regulators of gene expression in both plants and animals. Several hundred genes encoding miRNAs and thousands of siRNAs have been experimentally identified by cloning approaches. New sequencing technologies facilitate the identification of these molecules and provide global quantitative expression data in a given biological sample. Here, we describe the methods used in our laboratory to construct small RNA cDNA libraries for high-throughput sequencing using technologies such as MPSS, 454 or SBS.     

A dual-labeling method for identifying differentially expressed genes: use in the identification of cDNA clones that hybridize to RNAs whose abundance in tomato flowers is potentially regulated by gibberellins

A method for identifying cDNA clones that hybridize to differentially expressed RNAs is described. Briefly, the RNA population in which the RNAs of interest are more abundant is used as a template for the synthesis of 35S-labeled cDNAs and another RNA population in which the RNAs of interest are less abundant is used as a template for the synthesis of 32P-labeled cDNAs. The labeled cDNAs are pooled and hybridized to plaque or colony lifts constructed from a cDNA library. Clones that hybridize to RNAs that are differentially expressed are identified using differential autoradiography/fluorography to discriminate between the 32P and 35S isotopes. We have used this method to identify cDNA clones that hybridize to mRNAs that are more abundant in the flowers of wild-type tomato than in the flowers of mutants that have low endogenous levels of gibberellins.     

Sweating the small stuff: microRNA discovery in plants

The class of small RNAs known as microRNAs (miRNAs) has a demonstrated role in the negative regulation of gene expression in both plants and animals. These small molecules have been shown to play a critical role in a wide range of developmental and physiological pathways. Although hundreds of different miRNAs have now been identified using cloning and computational approaches, characterization of their targets and biological roles has been more limited. New sequencing technologies promise to accelerate the sequencing of small RNAs and additional genetic and genomic strategies are being applied to assess their regulatory function on RNA targets. These technologies will enable the identification of large numbers of small RNAs from diverse species, and comparative genomics approaches based on these data are likely to identify additional miRNAs. Combined with bioinformatics and experimental approaches to separate miRNAs from short-interfering RNAs (siRNAs), the pace of miRNA discovery is likely to accelerate, leading to an improved understanding of miRNA function and biological significance.     

An efficient and sensitive method for preparing cDNA libraries from scarce biological samples

The preparation and high-throughput sequencing of cDNA libraries from samples of small RNA is a powerful tool to quantify known small RNAs (such as microRNAs) and to discover novel RNA species. Interest in identifying the small RNA repertoire present in tissues and in biofluids has grown substantially with the findings that small RNAs can serve as indicators of biological conditions and disease states. Here we describe a novel and straightforward method to clone cDNA libraries from small quantities of input RNA. This method permits the generation of cDNA libraries from sub-picogram quantities of RNA robustly, efficiently and reproducibly. We demonstrate that the method provides a significant improvement in sensitivity compared to previous cloning methods while maintaining reproducible identification of diverse small RNA species. This method should have widespread applications in a variety of contexts, including biomarker discovery from scarce samples of human tissue or body fluids.     

Analysis of male sterile mutations in the mouse using haploid stage expressed cDNA probes

A differential hybridization screening procedure has identified cDNAs which correspond to RNAs which are expressed in mouse testis and at lower levels in liver and spleen. The sensitivity of this procedure is such that approximately 0.5% of 1.4 X 10(4) cDNA clones are revealed as "testis specific". We have focused on ten cDNA clones which have been used to identify RNAs expressed in the haploid phase of spermatogenesis. Using Northern blots to analyse RNA isolated from the testes of mutant mice (Tfm/Y and Sxr/+) blocked at specific stages in spermatogenesis or RNA from sexually immature mice, 8 clones have been identified which correspond to RNAs expressed uniquely or at much higher levels in meiotic or post meiotic cells.     

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.     

Identification and cloning of localized maternal RNAs from Xenopus eggs

A central question in developmental biology is to explain how cells in different regions of an embryo acquire different developmental fates. We have begun to address this question by investigating whether specific RNAs are localized within a frog egg. Differential screening of a cDNA library shows that most maternal RNAs are uniformly distributed along the animal-vegetal axis. However, we find that a rare class of maternal RNAs is localized. cDNA clones of four localized RNAs have been characterized. Three of these cDNAs are derived from maternal RNAs that are concentrated in the animal hemisphere of unfertilized eggs and remain localized through the early blastula stage. One cDNA is derived from a maternal RNA found almost exclusively in the vegetal hemisphere at both stages. These studies show that some informational molecules, specifically RNAs, are localized in eggs and are inherited by particular blastomeres.     

Second-strand cDNA synthesis with E. coli DNA polymerase I and RNase H: the fate of information at the mRNA 5' terminus and the effect of E. coli DNA ligase

A simple method for generating cDNA libraries has been described (1) in which RNase H-DNA polymerase I-mediated second-strand cDNA synthesis primes from an RNA oligonucleotide derived from the 5' (capped) end of mRNA. The size of this oligonucleotide and the fate of the information corresponding to the RNA during subsequent cloning have not been established. We show here that the 5'-most RNA primer varies in length from 8 to 21 nucleotides, and that information corresponding to the length of the RNA primer is normally lost during cloning. A modification of the second-strand cDNA synthesis procedure is described which allows cloning of all, or almost all, of the primer sequence information. In addition, we show that the presence of E. coli DNA ligase during second-strand cDNA synthesis can increase the length of the cDNA clones obtained from long RNAs. Cloning by addition of linkers provides the greatest chance of obtaining near full-length cDNA clones from long mRNAs.     

Expression sequence tag-specific full-length cDNA cloning: actin cDNAs

Current strategies for cDNA cloning are based on construction of cDNA libraries and colony screening. The process of obtaining a full-length cDNA clone can be highly time and labor intensive. Using the human actin gene as a model target cDNA, we have developed an RNA-capture method for rapid cloning of full-length cDNAs. The approach involves the capture of mRNA with expressed sequence tag (EST)-derived, biotin labeled antisense "capture" primers and streptavidin-coated magnetic beads. Full-length cDNA is then synthesized from purified EST-specific mRNA and cloned directly into plasmid vectors. The results of using beta-actin-based capture primers on cytoplasmic RNA were the isolation of both beta- and gamma-actin cDNA clones. Of the 16 actin-specific cDNA clones analyzed, 15 (93%) were full-length. This approach for cloning full-length cDNAs from available ESTs or partial cDNA sequences will facilitate a more rapid and efficient characterization of gene structure and function.     

Exploration of small RNAs

For several decades, only a limited number of noncoding RNAs, such as ribosomal and transfer RNA, have been studied in any depth. In recent years, additional species of noncoding RNAs have increasingly been discovered. Of these, small RNA species attract particular interest because of their essential roles in processes such as RNA silencing and modifications. Detailed analyses revealed several pathways associated with the function of small RNAs. Although these pathways show evolutional conservation, there are substantial differences. Advanced technologies to profile RNAs have accelerated the field further resulting in the discovery of an increasing number of novel species, suggesting that we are only just beginning to appreciate the complexity of small RNAs and their functions. Here, we review recent progress in novel small RNA exploration, including discovered small RNA species, their pathways, and devised technologies.     

A technique to enzymatically construct libraries which express short hairpin RNA of arbitrary stem length

Short interfering RNAs (siRNAs) and short hairpin RNAs (shRNAs) usually used for RNA interference (RNAi) are double-stranded RNAs (dsRNAs) of 21 base pairs. However, siRNAs and shRNAs of longer stem length have been reported to show more potent gene silencing. Here, we report a new technique to enzymatically construct shRNA libraries containing clones from firefly luciferase cDNA and Jurkat cDNA. The technique allowed the efficacious generation of shRNAs of arbitrary stem length as desired, providing the clones which potently silenced the specified gene expression and presenting a high efficiency rate of gene silencing. Our results indicate that the technique permits the rapid, efficient, and low-cost preparation of genomewide shRNA expression libraries not only for humans and mice but also for sorts of biological species and that the relevant libraries are applicable for the search of genes related to phenotype changes and of new targets for drug discovery.     

Bacterial Artificial Chromosomes: A Functional Genomics Tool for the Study of Positive-strand RNA Viruses

Reverse genetics, an approach to rescue infectious virus entirely from a cloned cDNA, has revolutionized the field of positive-strand RNA viruses, whose genomes have the same polarity as cellular mRNA. The cDNA-based reverse genetics system is a seminal method that enables direct manipulation of the viral genomic RNA, thereby generating recombinant viruses for molecular and genetic studies of both viral RNA elements and gene products in viral replication and pathogenesis. It also provides a valuable platform that allows the development of genetically defined vaccines and viral vectors for the delivery of foreign genes. For many positive-strand RNA viruses such as Japanese encephalitis virus (JEV), however, the cloned cDNAs are unstable, posing a major obstacle to the construction and propagation of the functional cDNA. Here, the present report describes the strategic considerations in creating and amplifying a genetically stable full-length infectious JEV cDNA as a bacterial artificial chromosome (BAC) using the following general experimental procedures: viral RNA isolation, cDNA synthesis, cDNA subcloning and modification, assembly of a full-length cDNA, cDNA linearization, in vitro RNA synthesis, and virus recovery. This protocol provides a general methodology applicable to cloning full-length cDNA for a range of positive-strand RNA viruses, particularly those with a genome of >10 kb in length, into a BAC vector, from which infectious RNAs can be transcribed in vitro with a bacteriophage RNA polymerase.