Molecular cloning and nucleotide sequence of cDNA for sporamin,the major soluble protein of sweet potato tuberous roots

Summary Sporamin accounts for more than 80% of the total soluble proteins of tuberous roots of sweet potato, but very little, if any, in other tissues of the same plant. In vitro translation of RNA fractions from the tuberous roots in wheat germ extract and subsequent immunoprecipitation with the antibody to sporamin indicated that this protein is synthesized by membrane-bound polysomes as a precursor 4 000 daltons larger than the mature protein. A cDNA expression library was constructed from the total poly(A)⁺ RNA from the tuberous roots by a vector-primer method, and an essentially full-length cDNA clone for the sporamin mRNA was selected by direct immunological screening of the colonies. Northern blot analysis showed that sporamin mRNA is approximately 950 nucleotides in length and is specifically present in tuberous roots and very little, if any, in leaves, petioles and non-tuberous roots. Nucleotide sequence of the cDNA predicts a 37 amino acid extension in the precursor at the amino-terminus of the mature protein.     

An improved method for the isolation of total RNA from Avicennia germinans leaves

Isolation of high-quality RNA of Avicennia germinans L. tissue is difficult due to high levels of phenols and other substances that interfere when using conventional procedures for the isolation. These substances not only decrease the yield but also the quality of RNA is almost poor. We present here a simple RNA protocol and fast methodology that effectively removes these contaminating substances without affecting the yield. The protocol developed is based on the SDS/phenol method with modifications including beta-mercaptoethanol to prevent oxidation of phenolic complexes, and phenol/chloroform extraction is introduced to remove proteins, genomic DNA, and secondary metabolites, and co-precipitated polysaccharides. Both A260/A230 and A260/A280 absorbance ratios of isolated RNA were around 2 and the yield was about 0.3 mg g(-1) fresh weight. Good-quality total RNA from leaves of Avicennia germinans could be easily isolated within 2 h by this protocol which avoided the limitation of plant materials and could provide total RNA for all kinds of further molecular studies.     

干种子高质量总RNA的快速提取方法

高效快速提取高质量的种子RNA是种子分子生物学研究的基础。现有的提取方法难以高效快速地从种子中得到高质量的总RNA。本试验有机地将改进SDS法和异硫氰酸胍法相结合,采用改进的酸性SDS提取液、不溶性PVPP(聚乙烯聚吡咯烷酮)阻止酚类氧化、KAc去除多糖、异丙醇沉淀RNA,可以高效地从0.01～0.1g水稻、大豆、蚕豆、芸豆、花生等干种子中提取到高质量总RNA。此法提取的总RNA,能够满足分子生物学研究的要求,可以进行反转录和RT-PCR反应,用于基因表达研究,并为从具相似成分的其他物种干种子提取总RNA提供参考方法。     

Isolation of Functional RNA from Periderm Tissue of Potato Tubers and Sweet Potato Storage Roots

A reliable and efficient protocol is given for the isolation of mRNA from the periderm of potato tubers and sweet potato storage roots. The method relies on a urea-based lysis buffer and lithium chloride to concentrate total RNA away from most of the cytoplasmic components and to prevent oxidation of phenolic complexes. To enhance the physical separation of the RNA from other macromolecular components, the RNA fraction was incubated in the presence of the cationic surfactant Catrimox-14. Poly(A)⁺ mRNA was separated from total RNA and other contaminants by using Promega's MagneSphere technology. The mRNA was suitable for cDNA library construction and RNA fingerprinting.     

An Efficient Method for the Extraction of High-Quality Fungal Total RNA to Study the <Emphasis Type="Italic">Mycosphaerella fijiensis</Emphasis>–<Emphasis Type="Italic">Musa</Emphasis> spp. Interaction

Efficient RNA isolation is a prerequisite for gene expression studies and it has an increasingly important role in the study of plant–fungal pathogen interactions. However, RNA isolation is difficult in filamentous fungi. These organisms are notorious for their rigid cell walls and the presence of high levels of carbohydrates, excreted from the fungal cells during submerged growth, which interferes with the extraction procedures. Although many commercial kits are already available for RNA isolation, they do not provide, in most cases, enough amount of pure RNA to be used in upstream applications. In the present work, we propose an easy and efficient protocol for isolating total RNA from the filamentous fungus Mycosphaerella fijiensis, the most important foliar pathogen of Musa spp. varieties worldwide. In addition, we applied the proposed protocol to the isolation of total RNA from banana leaves infected with the pathogen. Our methodology was developed based on the SDS method with modifications including a carbohydrate precipitation step. The protocol resulted in high-quality total RNA, from fungal mycelium grown in PDB medium and infected banana leaves, suitable for further molecular studies. The proposed methodology is also applicable to the ascomycete fungus Passalora fulva (syn. Cladosporum fulvum). Aminael Sánchez-Rodríguez and Orelvis Portal contributed equally to the article.     

A Modified Protocol for RNA Extraction from Different Peach Tissues Suitable for Gene Isolation and Real-Time PCR Analysis

RNA extraction is the first step in the study of gene isolation and expression. However, it is difficult to extract high quantity and quality RNA from tissues containing large quantities of polysaccharides and polyphenols. Peach (Prunus persica), in addition to containing high levels of polysaccharides and polyphenols, is a challenging starting material for RNA isolation using a single method because of different amounts of those substances in diverse tissues. Based on three reported methods, we developed a modified RNA isolation protocol to solve this problem, leading to high quality and quantity of total RNA from peach mesocarp tissues of fruits which were sampled from all developmental stages and different storage periods, as well as from other tissues including flowers, leaves, stems, and roots. With our modified method, 28–650 μg of total RNA was routinely obtained from per gram of fresh material, gave at least a 1.16-fold improvement by compared with those isolated by other seven methods. The RNA extracts were successfully used in downstream applications such as RT-PCR, RACE, and real-time PCR.     

Development of an Efficient Protocol of RNA Isolation from Recalcitrant Tree Tissues

Isolation of RNA from recalcitrant tree tissues has been problematic due to large amounts of secondary metabolites and interfering compounds in their cells. We have developed an efficient RNA extraction method, which yielded high-quality RNA preparations from tissues of the lychee tree. The method reported here utilized EDTA, LSS, and CTAB to successfully inhibit RNase activities. It was found that a high ionic strength brought about by 2 M NaCl was necessary. In addition, secondary metabolites and other interfering compounds were effectively removed using sodium borate and PVPP under a deoxidized condition. The quality of purified RNA was tested by both RACE and Northern blotting analysis, ensuring that the RNA could be used for subsequent gene expression analysis. This method has been successfully applied to purify RNA from 15 other plant species. In conclusion, the protocol reported here is expected to have excellent applications for RNA isolation from recalcitrant plant tissues.     

Isolation of high-quality RNA from white spruce tissue using a three-stage purification method and subsequent cloning of a transcript from the PR-10 gene family

Isolation of PinmIII cDNA homologues from white spruce tissues required a rigorous RNA extraction protocol developed following assessment of three previously reported conifer RNA extraction protocols. Total RNA was extracted via several purification steps designed to minimize binding of phenolics to nucleic acids and was then subjected to caesium chloride ultra-centrifugation. This procedure produced consistently high-quality, intact RNA from both needles and roots with spectrophotometric ratios of approximately 2.0 for both 260/280 nm and 260/230 nm. Total RNA was obtained from the roots of cold-hardened white spruce seedlings for cDNA library construction. More than 2 million recombinant phage particles were generated from 5 microg of a poly(A)+RNA fraction, and ca. 1.3 million cDNA particles were amplified for storage. Approximately 500,000 primary recombinant clones were screened with an heterologous PinmIII cDNA sequence yielding a unique clone, picgl, that was very similar to members of the PR10 gene family.     

RNA isolation from loquat and other recalcitrant woody plants with high quality and yield

RNA isolation is difficult in plants that contain large amounts of polysaccharides and polyphenol compounds. To date, no commercial kit has been developed for the isolation of high-quality RNA from tissues with these characteristics, especially for fruit. The common protocols for RNA isolation are tedious and usually result in poor yields when applied to recalcitrant plant tissues. Here an efficient RNA isolation protocol based on cetyltrimethylammonium bromide (CTAB) and two successive precipitations with 10 M lithium chloride (LiCl) was developed specifically for loquat fruits, but it was proved to work efficiently in other tissues of loquat and woody plants. The RNA isolated by this improved protocol was not only of high purity and integrity (A₂₆₀/A₂₈₀ ratios ranged from 1.90 to 2.04 and A₂₆₀/A₂₃₀ ratios were > 2.0) but also of high yield (up to 720 μg on average [coefficient of variation = 21%] total RNA per gram fresh tissue). The protocol was tested on loquat fruit (different stages of development, postharvest, ripening, and bruising), leaf, root, flower, stem, and bud; quince fruit and root; grapevine cells in liquid culture; and rose petals. The RNA obtained with this method is amenable to enzymatic treatments and can be efficiently applied for research on gene characterization, expression, and function.     

An optimized preparation method to obtain high-quality RNA from dry sunflower seeds

In an attempt to isolate high-quality, intact total RNA from sunflower (Helianthus annuus) seeds for investigation of the molecular mechanisms of mutations, we tested various procedures, using kits, including RNAiso Plus, RNAiso Plus+RNAiso-mate for Plant Tissue, Trizol, and the Qi method, but no high-quality total RNA of high integrity was obtained with any of these methods, probably due to the high content of polyphenols, polysaccharides, and secondary metabolites in mature sunflower seeds. Modifications were made to the Qi method. To avoid polyphenol oxidation, frozen dry seeds free of the seedcase were ground in a mortar with an equal amount of PVP30, and the fine ground powder was transferred to an extraction buffer with 2% PVP30 (w/v), 5% β-mercaptoethanol (v/v) and LiCl (8 M). A sample homogenate was extracted with chloroform prior to acidic phenol-chloroform extraction. The total RNA was precipitated with 1/4 volume of NaAc and 2 volumes of absolute ethanol to prevent contamination by polysaccharides. The yield of total RNA was 29.95 μg/100 mg husked dry seeds; the ratios of A260/A230 and A260/A280 were 2.44 and 2.09, respectively. Electrophoretic analysis clearly showed 28S and 18S ribosomal RNA bands. Using the extracted RNA, a fragment of the actin gene was successfully expressed by RT-PCR. This modified protocol is suitable for isolating high-quality total RNA from sunflower seeds for molecular research.     

A convenient and efficient protocol for isolating high-quality RNA from latex of Hevea brasiliensis (para rubber tree)

Isolating high-quality RNA from latex of H. brasiliensis is a prerequisite to elucidating the molecular mechanisms of rubber biosynthesis and its regulation. Here, an improved protocol was developed for latex collection, transportation, storage, and RNA isolation. Compared with existing ones, our protocol eliminated liquid nitrogen for latex collection and subsequent low-temperature (-70 degrees C) condition for latex storage, making it more convenient and feasible when latex was collected in remote sampling sites, and latex storage and RNA isolation were conducted in poorly-equipped laboratories. Different methods (UV absorbance scans, denaturing gel electrophoresis, autoradiograph monitoring of cDNA synthesis) were used to confirm the high quality of the RNA prepared with this protocol, whose usefulness was further verified by several practical applications, including construction of one high-quality cDNA library, cloning of the full-length cDNAs of 3 novel Hevea sucrose transporter genes, and semi-quantitative RT-PCR analysis of two rubber-biosynthesis essential genes and one sucrose transporter gene.