Filter paper-based spin column method for cost-efficient DNA or RNA purification.

We describe herein a method of recharging used commercial spin columns or assembling homemade spin columns using filter paper as binding material for cost-effective, low throughput nucleic acid purification. The efficiency of filter paper-based spin columns was evaluated for purification of nucleic acids from various sources. Following protocols of commercial kits, we found filter paper to be a useful binding material for purification of nucleic acids, including plant genomic DNA, plant total RNA, PCR products, and DNA from agarose gels. However, filter paper has a weak binding affinity to plasmid DNA in tested miniprep protocols. Protocols for the use of filter paper recharged spin columns or homemade spin columns for low throughput purification of plant genomic DNA and total RNA with unused commercial kit buffers or less expensive homemade buffers are presented.

A modified GC-specific MAKER gene annotation method reveals improved and novel gene predictions of high and low GC content in Oryza sativa.

BACKGROUND: Accurate structural annotation depends on well-trained gene prediction programs. Training data for gene prediction programs are often chosen randomly from a subset of high-quality genes that ideally represent the variation found within a genome. One aspect of gene variation is GC content, which differs across species and is bimodal in grass genomes. When gene prediction programs are trained on a subset of grass genes with random GC content, they are effectively being trained on two classes of genes at once, and this can be expected to result in poor results when genes are predicted in new genome sequences. RESULTS: We find that gene prediction programs trained on grass genes with random GC content do not completely predict all grass genes with extreme GC content. We show that gene prediction programs that are trained with grass genes with high or low GC content can make both better and unique gene predictions compared to gene prediction programs that are trained on genes with random GC content. By separately training gene prediction programs with genes from multiple GC ranges and using the programs within the MAKER genome annotation pipeline, we were able to improve the annotation of the Oryza sativa genome compared to using the standard MAKER annotation protocol. Gene structure was improved in over 13% of genes, and 651 novel genes were predicted by the GC-specific MAKER protocol. CONCLUSIONS: We present a new GC-specific MAKER annotation protocol to predict new and improved gene models and assess the biological significance of this method in Oryza sativa. We expect that this protocol will also be beneficial for gene prediction in any organism with bimodal or other unusual gene GC content.

A single-step method for RNA isolation from tropical crops in the field.

The RNAzol RT reagent was used to provide pure RNA from human cells. We develop a protocol using RNAzol RT reagent to extract pure RNA from plants tissues and demonstrate that this RNA extraction method works not only at room temperature but also at elevated temperatures and provides the simplest and most effective single-step method to extract pure and undegraded RNA directly from tropical plants in the field. RNA extraction directly in a complex field environment opens up the way for studying gene-environment interactions at transcriptome level to decipher the complex regulatory network involved in multiple-stress responses.

Application of a simple and affordable protocol for isolating plant total nucleic acids for RNA and DNA virus detection.

Standard molecular methods for plant virus diagnosis require the purification of RNA or DNA extracts from a large number of samples, with sufficient concentration and quality for their use in PCR, RT-PCR, or qPCR analysis. Most methods are laborious and use either hazardous and/or costly chemicals. A previously published protocol for RNA isolation from several plant species yields high amounts of good quality RNA-DNA mixture in a simple, safe and inexpensive manner. In the present work, this method was tested to obtain RNA-DNA extracts from leaves of tomato, potato and three species of citrus, and was compared with two commercial kits. The results demonstrated that this protocol offers at least comparable nucleic acid quality, quantity and purity to those provided by commercial phenol-based or spin column systems and that are suitable to be used in PCR, RT-PCR and qPCR for virus and viroid detection. Because of its easy implementation and the use of safe and inexpensive reagents, it can be easily implemented to work in plant virus and viroid detection in different plant species.

A quick, efficient, and cost-effective method for isolating high-quality total RNA from tomato fruits, suitable for molecular biology studies.

Tomato (Solanum lycopersicum L.) is the primary model for the study of fleshy fruits, and research on this species has elucidated many aspects of fruit physiology, development, and metabolism. However, for advancing such studies at molecular biology levels, the RNA isolation from fruit tissues is often essential. The RNA isolation from tomato fruits is complicated because of the presence of high levels of polysaccharides, polyphenolics, pigments, and secondary metabolites and also the varying water content during development. Here, we present an optimized protocol for the isolation of total RNA from the fruit tissues at different developmental stages. In comparison to the previous methods described for the RNA isolation from tomato fruit, this method has the advantages that it does not involve the use of guanidine salts, lyophilizers, and commercial reagents, reduces the time and cost of extraction, overcomes the high water content problem, and promotes RNA quality by inhibiting RNA degradation and minimizing the gDNA, polyphenolic and polysaccharide contaminations. Using this method, high yields of high-purity and intact RNA samples were obtained as confirmed by the spectrophotometric readings and the electrophoresis on denaturing agarose gels. The isolated RNA was employed as a robust template for cDNA synthesis, reverse transcriptase-polymerase chain reaction (RT-PCR), and temporal gene expression analysis. The functionality of the isolated RNA was further demonstrated through cloning full-length cDNAs encoding ß-galactosidase proteins by RT-PCR and sequencing.

A rapid and economical method for low molecular weight RNA isolation from a wide variety of plant species.

We have developed a time- and cost-effective method for isolating low molecular weight (LMW) RNA from plants. In our protocol, the isolation procedure can be completed within 3 h. Polyethylene glycol (PEG) and absolute ethanol are used to isolate LMW RNA, and the LMW RNA yields were >80 µg/g of fresh-weight tissues for several of the plant species tested.

Isolation of high-quality total RNA from leaves of Myrciaria dubia "CAMU CAMU".

Myrciaria dubia is a main source of vitamin C for people in the Amazon region. Molecular studies of M. dubia require high-quality total RNA from different tissues. So far, no protocols have been reported for total RNA isolation from leaves of this species. The objective of this research was to develop protocols for extracting high-quality total RNA from leaves of M. dubia. Total RNA was purified following two modified protocols developed for leaves of other species (by Zeng and Yang, and by Reid et al.) and one modified protocol developed for fruits of the studied species (by Silva). Quantity and quality of purified total RNA were assessed by spectrophotometric and electrophoretic analysis. Additionally, quality of total RNA was evaluated with reverse-transcription polymerase chain reaction (RT-PCR). With these three modified protocols we were able to isolate high-quality RNA (A260nm/A280nm >1.9 and A260nm/A230nm >2.0). Highest yield was produced with the Zeng and Yang modified protocol (384±46µg ARN/g fresh weight). Furthermore, electrophoretic analysis showed the integrity of isolated RNA and the absence of DNA. Another proof of the high quality of our purified RNA was the successful cDNA synthesis and amplification of a segment of the M. dubia actin 1 gene. We report three modified protocols for isolation total RNA from leaves of M. dubia. The modified protocols are easy, rapid, low in cost, and effective for high-quality and quantity total RNA isolation suitable for cDNA synthesis and polymerase chain reaction.

Simple, rapid and cost-effective method for high quality nucleic acids extraction from different strains of Botryococcus braunii.

This study deals with an effective nucleic acids extraction method from various strains of Botryococcus braunii which possesses an extensive extracellular matrix. A method combining freeze/thaw and bead-beating with heterogeneous diameter of silica/zirconia beads was optimized to isolate DNA and RNA from microalgae, especially from B. braunii. Eukaryotic Microalgal Nucleic Acids Extraction (EMNE) method developed in this study showed at least 300 times higher DNA yield in all strains of B. braunii with high integrity and 50 times reduced working volume compared to commercially available DNA extraction kits. High quality RNA was also extracted using this method and more than two times the yield compared to existing methods. Real-time experiments confirmed the quality and quantity of the input DNA and RNA extracted using EMNE method. The method was also applied to other eukaryotic microalgae, such as diatoms, Chlamydomonas sp., Chlorella sp., and Scenedesmus sp. resulting in higher efficiencies. Cost-effectiveness analysis of DNA extraction by various methods revealed that EMNE method was superior to commercial kits and other reported methods by >15%. This method would immensely contribute to area of microalgal genomics.

A Rapid and effective method for RNA extraction from different tissues of grapevine and other woody plants.

INTRODUCTION: RNA quality and integrity are critical for many studies in plant molecular biology. High-quality RNA extraction from grapevine and other woody plants is problematic due to the presence of polysaccharides, polyphenolics and other compounds that bind or co-precipitate with the RNA. OBJECTIVE: To develop an optimised cetyltrimethylammonium bromide (CTAB)-based protocol, to reduce the time and cost of extraction without reducing quality and yield of RNA extracted from polysaccharide-rich tissues of several plants. METHODOLOGY: Several changes were introduced to the original CTAB protocol. All centrifugation steps were carried out at 4 degrees C, the sample weight was decreased and the concentrations of PVP-40 and LiCl were increased reducing incubation time prior to RNA precipitation. This rapid CTAB protocol was compared with six different RNA extraction methods from three grapevine tissues, namely, in vitro plantlets, and leaves and mature canes from actively growing field vines. RESULTS: The rapid CTAB method gave high-quality RNA in only 3 h at low cost with efficiency equal to or higher than that obtained with other time-consuming and expensive protocols. The procedure was applied to RNA extraction from other grapevine tissues and other woody species including olive, lemon, poplar, chestnut, apple, pear, peach, cherry, apricot, plum and kiwi fruit. RNA of high quality could be isolated from all tissues and from all species. CONCLUSION: The study has shown that the improvement of a CTAB-based protocol allows the rapid isolation of high-quality RNA from grapevine and many woody species.

Preparation and quality assessment of RNA from cell-specific samples obtained by laser microdissection.

Laser microdissection is a powerful tool to obtain cell-specific isolates from complex tissue samples. This chapter outlines how to prepare plant material for microdissection and methods to extract and measure high-quality RNA suitable for a variety of different downstream applications.