A simple method to enrich mRNA from total prokaryotic RNA

Isolation of prokaryotic mRNA by the poly(dT) method has been difficult, primarily due to the great instability of the poly(A) sequence in its mRNA. We developed a simple method to remove rRNA from total RNA ofStaphylococcus aureus by cloning a PCR-amplifiedS. aureus rRNA gene fragment into a plasmid, and then synthesizing biotin-labeled antisense rRNA to subtract rRNA. By using this method,S. aureus rRNA is significantly reduced and mRNA is enriched. This method may be used to prepare prokaryotic mRNA for many molecular biology applications.     

Half-lives of messenger RNA species during growth and differentiation of Dictyostelium discoideum

The half-lives of functional messenger RNAs were determined by a method employing the drugs actinomycin D and daunomycin for the inhibition of mRNA synthesis; the activity of extracted mRNAs was determined by an in vitro translation assay. Several controls indicated that this method yielded reliable values for mRNA half-lives; in particular, the declining rate of protein synthesis in the presence of the drugs is due predominantly to the decay of translatable mRNA. This method was used to determine the half-lives of two specific mRNAs—encoding actin and a protein of MW 51,000—as well as that of total cytoplasmic mRNA activity during growth and at several times in differentiation. The half-lives of at least these two mRNAs were shown to be distinctly different from that of the total mRNA population—about 4 hr. However, no significant change in any of these half-lives was observed between growing and developing cells. Therefore wholesale alterations in the degradation rates of total and at least specific messages do not appear to play a role in the regulation of gene expression during Dictyostelium development.     

Changes in the abundance of polyadenylated RNA during slime mould development measured using cloned molecular hybridization probes.

Total Dictyostelium discoideum messenger RNA prepared from cells at the eighth hour of development in suspension culture has been copied into DNA. This DNA was inserted into the plasmid PMB9 and used to transform Escherichia coli. The resulting “clone bank” was screened using an in situ hybridization technique in which replicate copies of a set of clones were hybridized with mRNA isolated from vegetative (non-developing) cells and from cells at the eighth hour of development. The mRNA was labelled in vitro so that the amount of hybridization to a given clone is a measure of the relative abundance of the mRNA complementary to the DNA in that clone. By comparing the amount of hybridization of the mRNA preparations to each clone, it has been possible to identify plasmids containing D. discoideum DNA whose complementary mRNA increases or decreases in abundance during development. These observations are direct proof of a change in mRNA concentration during D. discoideum development for individual high and medium abundance mRNA species. We can estimate from these results the proportion of such mRNA species whose concentration increases significantly during development and we find that only a small fraction show such a change.     

Isolation and translation of plant messenger RNA

A fraction of the RNA species isolated from Lemna gibba G-3 consists of molecules with attached sequences of polyadenylic acid. This polyadenylic acid-containing fraction, separated from total RNA by adsorption onto oligothymidylic acid-cellulose, was shown to be mRNA by its ability to serve as template in a cell-free translation system derived from wheat germ. The products of translation were characterized by electrophoresis. This method permitted the comparison of mRNA from plants grown under different light conditions. Such plants were shown to possess qualitative and quantitative differences in their mRNA complements.     

Fluorophore Binding Aptamers as a Tool for RNA Visualization

Fluorescence correlation spectroscopy (FCS) is suitable for the detection of fluorescent molecules in living cells. For the visualization of mRNA, we genetically fused a fluorophore-specific RNA aptamer to the coding mRNA of the green fluorescent protein, as well as to noncoding sequences. Using these constructs, we showed that the aptamer portion of the mRNA still binds the fluorophore in the nanomolar range as determined via FCS. Furthermore, the binding took place in the context of total RNA extract. A tandem construct of the RNA aptamer even exhibited a lower K_d than the monomer. This FCS-based method establishes a tool for minimal invasive detection of RNA at the single molecule level in individual living cells.     

Quantitative measurements of fibroin messenger RNA synthesis in the posterior silk gland of normal and mutant Bombyx mori

The amount of newly synthesized and accumulated fibroin messenger RNA has been measured quantitatively at various stages of posterior silk gland development in Bombyx mori. The two-step method involves fractionation on a Bio-Gel column which excludes the large mRNA, followed by RNAase T₁ digestion, and fractionation of the oligonucleotides on DEAE-Sephadex. Larvae in the feeding stages of the third and fourth instar synthesize and accumulate fibroin mRNA to about 2% of cellular RNA; this corresponds to 0.2 and 2 μg per pair of posterior glands in the third and fourth instars, respectively. More than 70% of this mRNA is degraded in vivo during the third and fourth moulting stages. Fibroin mRNA synthesis resumes again within the first 24 hours of the fifth instar; the mRNA accumulates and predominates over other DNA-like RNAs as the stage proceeds until finally it comprises about 3.5% of cellular RNA in a mature larva (170 μg per pair of posterior glands). These results indicate that more than 99% of the fibroin mRNA detected in the fifth instar is synthesized during this stage.Four spontaneous mutants of B. mori which synthesize very low levels of fibroin have been analyzed for their RNA content in the middle fifth instar. The total cellular RNA of the posterior gland is reduced to 4 to 7% of normal. Fibroin mRNA is more severely reduced to 1% of normal. In three heterozygotes, which have mutant phenotypes with respect to fibroin production, only slight increases of total cellular RNA and fibroin mRNA were observed. Thus, the primary biochemical lesion in these mutants is still unknown.The presumed ancestor to B. mori, the wild silkworm B. mandarina, was also analyzed for its fibroin mRNA. The mRNA isolated from fifth instar larvae of B. mandarina is indistinguishable from that of B. mori with respect to its nucleotide sequence, molecular weight and fraction of total cellular RNA.     

A micromethod for measuring the molar concentration of polyadenylated RNA in the presence of ribosomal RNA

A method has been developed for measuring the molar concentration of RNA and the mole fraction of polyadenylated RNA. Using known mixtures of globin mRNA and rRNA composed of 20 to 85% rRNA, the molar concentration of globin mRNA, a polyadenylated species, was determined in 45 min, with the consumption of less than 100 ng of total RNA. The technique is particularly well suited for determining the molar concentration of poly(A)+ RNA after chromatographic enrichment in columns of oligo(dT)-cellulose or poly(U)-Sepharose. The method makes possible the adoption of a molar standard.     

Monocistronic messenger RNA in yeast

We have determined the rate of polypeptide chain synthesis on different size polysomes in yeast. The completion time for the average polypeptide chain in vivo at 23 °C is two minutes by this technique and is in good agreement with values we have determined by other independent methods.These kinetic experiments indicate that the average size of a nascent polypeptide chain on a polysome is directly related to the size of the polysome. This demonstrates that in the simple eucaryotic organism, Saccharomyces cerevisiae, mRNA is monocistronic in the sense that each mRNA molecule codes for one protein molecule which is released intact from the ribosome upon completion. The pattern of amino acid incorporation into Escherichia coli polysomes is distinctly different. These findings have a number of interesting implications for the genetics of the lower eucaryotes and indicate that the cellular mechanisms of control and co-ordination in yeast may differ from those found in procaryotes and may be similar to cellular mechanisms of control for mammalian cells.     

Euglena gracilis Chloroplast DNA Codes for Polyadenylated RNA

Polyadenylated RNA, isolated from total cellular RNA of photoautotrophically grown Euglena gracilis, comprised 2.1% of the total cellular RNA and contained 6.2% polyadenylic acid. Polyadenylated RNA, labeled in vitro with ¹²⁵I, hybridized at saturating levels to an average 7.7% of the chloroplast DNA. In the presence of excess chloroplast rRNA, hybridization of polyadenylated RNA was reduced, but was still observed at a level corresponding to 2.8% of the chloroplast DNA. Polyadenylic acid was not detected in mRNA prepared from chloroplast polyribosomes, indicating a level of less than 0.1% polyadenylic acid in mature chloroplast mRNA. Of the total RNA isolated from cytoplasmic polyribosomes, 2.0% contained polyadenylic acid. This latter polyadenylated RNA did not hybridize to chloroplast DNA.     

RNA interference can be used to disrupt gene function in tardigrades

How morphological diversity arises is a key question in evolutionary developmental biology. As a long-term approach to address this question, we are developing the water bear Hypsibius dujardini (Phylum Tardigrada) as a model system. We expect that using a close relative of two well-studied models, Drosophila (Phylum Arthropoda) and Caenorhabditis elegans (Phylum Nematoda), will facilitate identifying genetic pathways relevant to understanding the evolution of development. Tardigrades are also valuable research subjects for investigating how organisms and biological materials can survive extreme conditions. Methods to disrupt gene activity are essential to each of these efforts, but no such method yet exists for the Phylum Tardigrada. We developed a protocol to disrupt tardigrade gene functions by double-stranded RNA-mediated RNA interference (RNAi). We showed that targeting tardigrade homologs of essential developmental genes by RNAi produced embryonic lethality, whereas targeting green fluorescent protein did not. Disruption of gene functions appears to be relatively specific by two criteria: targeting distinct genes resulted in distinct phenotypes that were consistent with predicted gene functions and by RT-PCR, RNAi reduced the level of a target mRNA and not a control mRNA. These studies represent the first evidence that gene functions can be disrupted by RNAi in the phylum Tardigrada. Our results form a platform for dissecting tardigrade gene functions for understanding the evolution of developmental mechanisms and survival in extreme environments.     

Screening differentially expressed cDNA clones obtained by differential display using amplified RNA.

The major obstacle of differential display is not the technique itself but rather the post-differential display issueof discriminating between false positives and the truly differentially expressed mRNAs. This process is arduous and requires large amounts of RNA. We present and validate a method which allows one to screen putative positives from differential display analysis using only micrograms of total RNA. More importantly, we demonstrate that cDNA probes generated from amplified RNA are representative of the starting mRNA population and can be used for differential screening of mRNA species at a detectable limit of sensitivity of>/=1/40 000.     

Complexity and characterization of polyadenylated RNA in the mouse brain

The complexity of nuclear RNA, poly(A)hnRNA, poly(A)mRNA, and total poly(A)RNA from mouse brain has been measured by saturation hybridization with nonrepeated DNA. These DNA populations were complementary, respectively, to 21, 13.5, 3.8, and 13.3% of the DNA. From the RNA Cot required to achieve half-sturation, it was estimated that about 2.5–3% of the mass of total nuclear RNA constituted most of the complexity. Similarly, complexity driver molecules constituted 6–7% of the mass of the poly(A)hnRNA. 75–80% of the poly(A)mRNA diversity is contained in an estimated 4–5% of the mass of this mRNA. Poly(A)hnRNA constituted about 20% of the mass of nuclear RNA and was comprised of molecules which sedimented in DMSO-sucrose gradients largely between 16S and 60S. The number average size of poly(A)hnRNA determined by sedimentation, electron microscopy, or poly(A) content was 4200–4800 nucleotides. Poly(A)mRNA constituted about 2% of the total polysomal RNA, and the number average size was 1100–1400 nucleotides. The complexity of whole cell poly(A)RNA, which contains both poly(A)hnRNA and poly(A)mRNA populations, was the same as poly(A)hnRNA. This implies that cytoplasmic polyadenylation does not occur to any apparent qualitative extent and that poly(A)mRNA is a subset of the poly(A)hnRNA population. The complexity of poly(A)hnRNA and poly(A)mRNA in kilobases was 5 × 10⁵ and 1.4 × 10⁵, respectively. DNA which hybridized with poly(A)mRNA renatures in the presence of excess total DNA at the same rate as nonrepetitive tracer DNA. Hence saturation values are due to hybridization with nonrepeated DNA and are therefore a direct measure of the sequence complexity of poly(A)mRNA. These results indicate that the nonrepeated sequence complexity of the poly(A)mRNA population is equal to about one fourth that observed for poly(A)hnRNA.