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.     

Feasible and reliable quantification of mRNA in Arabidopsis thaliana using optical thin-film biosensor chips

mRNA quantification is very important in molecular biological researches.Traditional spectrophotometric method cannot distinguish DNA,rRNA and tRNA species from mRNA.Northern blot can be used for mRNA quantification but is known to be time consuming.To rapidly detect mRNA levels,we developed an optical thin-film biosensor chip based method,to quantify mRNA in samples.After total RNA was extracted,the mRNA with poly(A)tails was reverse transcribed with oligo(dT)20 primers and dNTPs mixed with digoxigenin(DIG)-11-dUTP.The transcribed first strand cDNA was hybridized with oligo(dA)20 nucleotide probes spotted on optical thin-film biosensor chips.Excess first strand cDNA,single-strand RNA,and mis-matcbed DNA/DNA hybrids were removed by washing.The perfect-matched DNA/DNA hybrid was detected with anti-DIG-AP(alkaline phosphatase)conjugate and then incubated with NBT/BCIP substrate for color development.The range of the color is from purplish red to blue,according to the cDNA mass deposited on chip surface.Detection of mRNA levels from Arabidopsis samples proved that this method is feasible for mRNA quantification,and has great potential for application in mRNA quantification in various organisms.     

Small nucleolar RNAs that guide modification in trypanosomatids: repertoire, targets, genome organisation, and unique functions

Small nucleolar RNAs constitute a family of newly discovered non-coding small RNAs, most of which function in guiding RNA modifications. Two prevalent types of modifications are 2'-O-methylation and pseudouridylation. The modification is directed by the formation of a canonical small nucleolar RNA-target duplex. Initially, RNA-guided modification was shown to take place on rRNA, but recent studies suggest that small nuclear RNA, mRNA, tRNA, and the trypanosome spliced leader RNA also undergo guided modifications. Trypanosomes contain more modifications and potentially more small nucleolar RNAs than yeast, and the increased number of modifications may help to preserve ribosome function under adverse environmental conditions during the cycling between the insect and mammalian host. The genome organisation in clusters carrying the two types of small nucleolar RNAs, C/D and H/ACA-like RNAs, resembles that in plants. However, the trypanosomatid H/ACA RNAs are similar to those found in Archaea and are composed of a single hairpin that may represent the primordial H/ACA RNA. In this review we summarise this new field of trypanosome small nucleolar RNAs, emphasising the open questions regarding the number of small nucleolar RNAs, the repertoire, genome organisation, and the unique function of guided modifications in these protozoan parasites.     

Chemical modification resolves the asymmetry of siRNA strand degradation in human blood serum

Small interfering (si)RNAs have recently been used to therapeutically silence genes in vivo after intravenous systemic delivery. Further progress in the development of siRNA therapeutics will in part rely on tailoring site-specific chemical modifications of siRNAs to optimize their pharmacokinetic properties. Advances are particularly needed to improve the nucleolytic stability of these double-stranded RNA drugs in vivo and suppress adverse off-target gene silencing effects. Here we demonstrate that specific chemical 2'-O-methylation, which has already been shown to ameliorate the omnipresent off-target toxicity of siRNAs, selectively protects the particularly vulnerable 5'-end of the guide strand against exonucleolytic degradation in human blood serum. Specific chemical modification thus resolves the asymmetric degradation of the guide and passenger strands, which is inherent to the thermodynamic asymmetry of the siRNA termini as required for proper utilization of the guide strand in RNA interference.     

Why do shrews twitter? Communication or simple echo-based orientation

Shrews are very vocal animals. We tested behaviourally whether the high-pitched laryngeal ‘twittering’ calls of as-yet unclear function serve for communication or echo-based orientation. We used a representative species from each of the two largest phylogenetic groups of shrews. In both species, experimental manipulation of substrate density, but not of the likelihood of conspecific presence, affected the shrews'' call rate when exploring an unknown environment. This adaptation of call rate to the degree of habitat clutter parallels bat echolocation and suggests that shrews may use the echoes and reverberations of their calls for identifying routes through their habitat or for probing habitat type. To assess the acoustic feasibility of shrew echo orientation, we ensonified shrew habitats in the field with an ‘artificial shrew’ (small speaker mounted close to a sensitive microphone). The data showed that shrew-like calls can indeed yield echo scenes useful for habitat assessment at close range, but beyond the range of the shrews'' vibrissae.     

Microarray Analysis of Gene Expression in Soybean Roots Susceptible to the Soybean Cyst Nematode Two Days Post Invasion

Soybean root cells undergo dramatic morphological and biochemical changes during the establishment of a feeding site in a compatible interaction with the soybean cyst nematode (SCN). We constructed a cDNA microarray with approximately 1,300 cDNA inserts targeted to identify differentially expressed genes during the compatible interaction of SCN with soybean roots 2 days after infection. Three independent biological replicates were grown and inoculated with SCN, and 2 days later RNA was extracted for hybridization to microarrays and compared to noninoculated controls. Statistical analysis indicated that approximately 8% of the genes monitored were induced and more than 50% of these were genes of unknown function. Notable genes that were more highly expressed 2 days after inoculation with SCN as compared to noninoculated roots included the repetitive proline-rich glycoprotein, the stress-induced gene SAM22, ß-1,3-endoglucanase, peroxidase, and those involved in carbohydrate metabolism, plant defense, and signaling.     

Polyadenylated RNA sequences which are reduced in concentration following auxin treatment of soybean hypocotyls

Previous work has shown that any effect of exogenous auxin on gene expression in soybean hypocotyl tissue must be restricted to a relatively small fraction of the polyadenylated RNA. However, kinetic hybridization analysis with cDNA probes revealed that a minor abundant class of sequences is markedly reduced in concentrations in the auxin-treated polyadenylated RNA. Recombinant plasmids containing copies of polyadenylated RNA species were constructed using the G-C tailing procedure and clones of auxin-regulated sequences were detected by differential in situ hybridization with cDNA of polyadenylated RNA from auxin-treated or untreated hypocotyls. Although the 12 clones which were selected all contained different size inserts, and were therefore independent, 11 of these apparently hybridized to just two different RNA species. The rate constant of the auxin-sensitive abundant component of the untreated polyadenylated RNA/DNA hybridization was similar to that of the reaction between the two major groups of clones and untreated polyadenylated RNA. This indicates that these cloned sequences are homologous with that cDNA fraction. The twelfth clone is thought to be representative of a group of less abundnt auxin-regulated polyadenylated mRNA species which had been detected in an earlier analysis of the in vitro translation products of soybean hypocotyl RNA. Both the timing and the extent of the influence of auxin on the relative concentration of these cloned sequences are quite consistent with a close relationship between growth regulation by auxin and its effects on gene expression.     

Comparison of Biological,Molecular, and Morphological Methods of Species Identification in a Set of Cultured Panagrolaimus Isolates

We have developed a molecular barcode system that uses the small subunit ribosomal RNA (SSU) sequence to define molecular operational taxonomic units (MOTU) of soil nematodes. Here we attempt to differentiate five cultured isolates of a taxonomically difficult genus, Panagrolaimus, using morphological, molecular, and biological (breeding) criteria. The results indicated that the five culture populations belonged to two reproductively isolated species. The available morphological criteria, including scanning electron microscopy (SEM), were insufficient to differentiate among them, and all five could be classified as one morphospecies. Within-culture variation of the morphometrical data did not discern between the two biological species. Sequence data clearly separated the populations into two groups that supported the breeding results. Given this study represented only five populations of one genus, we suggest a congruence of MOTU analysis with the biological species concept. This multifaceted approach is promising for future identification of nematodes as it is simple, comparable, and transferable.     

Microarray RNA quantification assay for large-scale nanosamples analysis.

We have developed a convenient and sensitive method for the quantification of RNA in samples from microbiopsies. This procedure is especially suitable for quantitating very small amounts of RNA in large-scale biological samples. This method, using a microarray-spotting facility for the study of multigenic expression, entails the hybridization of a DNA probe with RNA spotted at high density on nylon membrane. Furthermore, with this procedure, the reproducibility, sensitivity, and accuracy of the assay are notably improved as compared to current methods.     

Identification and characterization of canine growth differentiation factor-9 and its splicing variant

Growth differentiation factor-9 (GDF-9), a member of the transforming growth factor-β (TGF-β) superfamily, is expressed exclusively in the oocyte within the ovary and plays essential roles in the ovarian function in mammals. However, a possible involvement of GDF-9 in canine ovarian physiology that has a unique ovulation process among mammals has not been studied. Interestingly, we have isolated two types of cDNA clones generated by an alternative splicing from a canine ovarian total RNA. The predominant long form cDNA shares a common precursor structure with GDF-9s in other species whereas the minor short form cDNA has a 172 amino acid truncation in the proregion. Using a transient expression system, we found that the long form cDNA has a defect in mature protein production whereas the short form cDNA readily produces mature protein. However, mutations at one or two N-glycosylation sites in the mature domain of the short form GDF-9 caused a loss in mature protein production. These results suggest that the prodomain and N-linked glycosylation of the mature domain regulate proper processing and secretion of canine GDF-9. Based on the biological functions of GDF-9, these characteristics of canine GDF-9 could be causatively linked to the unique ovulation process in the Canidae.     

A bias-reducing strategy in profiling small RNAs using Solexa

Small RNAs (smRNAs) encompass several different classes of short noncoding RNAs. Progress in smRNA research and applications has coincided with the advance of techniques to detect them. Next-generation sequencing technologies are becoming the preferred smRNA profiling method because of their high-throughput capacity and digitized results. In our small RNA profiling study using Solexa, we observed serious biases introduced by the 5' adaptors in small RNA species coverage and abundance; therefore, the results cannot reveal the accurate composition of the small RNAome. We found that the profiling results can be significantly optimized by using an index pool of 64 customized 5' adaptors. This pool of 64 adaptors can be further reduced to four smaller index pools, each containing 16 adaptors, to minimize profiling bias and facilitate multiplexing. It is plausible that this type of bias exists in other deep-sequencing technologies, and adaptor pooling could be an easy work-around solution to reveal the "true" small RNAome.