Ice-Cap: A Method for Growing Arabidopsis and Tomato Plants in 96-well Plates for High-Throughput Genotyping

It is becoming common for plant scientists to develop projects that require the genotyping of large numbers of plants. The first step in any genotyping project is to collect a tissue sample from each individual plant. The traditional approach to this task is to sample plants one-at-a-time. If one wishes to genotype hundreds or thousands of individuals, however, using this strategy results in a significant bottleneck in the genotyping pipeline. The Ice-Cap method that we describe here provides a high-throughput solution to this challenge by allowing one scientist to collect tissue from several thousand seedlings in a single day ^1,2. This level of throughput is made possible by the fact that tissue is harvested from plants 96-at-a-time, rather than one-at-a-time.The Ice-Cap method provides an integrated platform for performing seedling growth, tissue harvest, and DNA extraction. The basis for Ice-Cap is the growth of seedlings in a stacked pair of 96-well plates. The wells of the upper plate contain plugs of agar growth media on which individual seedlings germinate. The roots grow down through the agar media, exit the upper plate through a hole, and pass into a lower plate containing water. To harvest tissue for DNA extraction, the water in the lower plate containing root tissue is rapidly frozen while the seedlings in the upper plate remain at room temperature. The upper plate is then peeled away from the lower plate, yielding one plate with 96 root tissue samples frozen in ice and one plate with 96 viable seedlings. The technique is named "Ice-Cap" because it uses ice to capture the root tissue. The 96-well plate containing the seedlings can then wrapped in foil and transferred to low temperature. This process suspends further growth of the seedlings, but does not affect their viability. Once genotype analysis has been completed, seedlings with the desired genotype can be transferred from the 96-well plate to soil for further propagation. We have demonstrated the utility of the Ice-Cap method using Arabidopsis thaliana, tomato, and rice seedlings. We expect that the method should also be applicable to other species of plants with seeds small enough to fit into the wells of 96-well plates.     

A simple and sensitive high-throughput GFP screening in woody and herbaceous plants

Green fluorescent protein (GFP) has been used widely as a powerful bioluminescent reporter, but its visualization by existing methods in tissues or whole plants and its utilization for high-throughput screening remains challenging in many species. Here, we report a fluorescence image analyzer-based method for GFP detection and its utility for high-throughput screening of transformed plants. Of three detection methods tested, the Typhoon fluorescence scanner was able to detect GFP fluorescence in all Arabidopsis thaliana tissues and apple leaves, while regular fluorescence microscopy detected it only in Arabidopsis flowers and siliques but barely in the leaves of either Arabidopsis or apple. The hand-held UV illumination method failed in all tissues of both species. Additionally, the Typhoon imager was able to detect GFP fluorescence in both green and non-green tissues of Arabidopsis seedlings as well as in imbibed seeds, qualifying it as a high-throughput screening tool, which was further demonstrated by screening the seedlings of primary transformed T₀ seeds. Of the 30,000 germinating Arabidopsis seedlings screened, at least 69 GFP-positive lines were identified, accounting for an approximately 0.23% transformation efficiency. About 14,000 seedlings grown in 16 Petri plates could be screened within an hour, making the screening process significantly more efficient and robust than any other existing high-throughput screening method for transgenic plants.     

An enzymatic fluorescent assay for the quantification of phosphite in a microtiter plate format

A sensitive fluorometric assay for the quantification of phosphite has been developed. The assay uses the enzymatic oxidation of phosphite to phosphate by a recombinant phosphite dehydrogenase with NAD⁺ as cosubstrate to produce the highly fluorescent reaction product resorufin. The optimized assay can be carried out in a 96-well microtiter plate format for high-throughput screening purposes and has a detection limit of 0.25 nmol phosphite. We used the method to quantify phosphite levels in plant tissue extracts and to determine phosphite dehydrogenase activity in transgenic plants. The assay is suitable for other biological or environmental samples. Because phosphite is a widely used fungicide to protect plants from pathogenic oomycetes, the assay provides a cost-effective and easy-to-use method to monitor the fate of phosphite following application.     

A high-throughput method for the quantitative analysis of auxins

Auxin measurements in plants are critical to understanding both auxin signaling and metabolic homeostasis. The most abundant natural auxin is indole-3-acetic acid (IAA). This protocol is for the precise, high-throughput determination of free IAA in plant tissue by isotope dilution analysis using gas chromatography-mass spectrometry (GC-MS). The steps described are as follows: harvesting of plant material; amino and polymethylmethacrylate solid-phase purification followed by derivatization with diazomethane (either manual or robotic); GC-MS analysis; and data analysis. [13C?]IAA is the standard used. The amount of tissue required is relatively small (25 mg of fresh weight) and one can process more than 500 samples per week using an automated system. To extract eight samples, this procedure takes ～3 h, whether performed manually or robotically. For processing more than eight samples, robotic extraction becomes substantially more time efficient, saving at least 0.5 h per additional batch of eight samples.     

A High-Throughput Platform for Screening Milligram Quantities of Plant Biomass for Lignocellulose Digestibility

The development of a viable lignocellulosic ethanol industry requires multiple improvements in the process of converting biomass to ethanol. A key step is the improvement of the plants that are to be used as biomass feedstocks. To facilitate the identification and evaluation of feedstock plants, it would be useful to have a method to screen large numbers of individual plants for enhanced digestibility in response to combinations of specific pretreatments and enzymes. This paper describes a high-throughput digestibility platform (HTDP) for screening collections of germplasm for improved digestibility, which was developed under the auspices of the Department of Energy-Great Lakes Bioenergy Research Center (DOE-GLBRC). A key component of this platform is a custom-designed workstation that can grind and dispense 1–5 mg quantities of more than 250 different plant tissue samples in 16 h. The other steps in the processing (pretreatment, enzyme digestion, and sugar analysis) have also been largely automated and require 36 h. The process is adaptable to diverse acidic and basic, low-temperature pretreatments. Total throughput of the HTDP is 972 independent biomass samples per week. Validation of the platform was performed on brown midrib mutants of maize, which are known to have enhanced digestibility. Additional validation was performed by screening approximately 1,200 Arabidopsis mutant lines with T-DNA insertions in genes known or suspected to be involved in cell wall biosynthesis. Several lines showed highly significant (p?<?0.01) increases in glucose and xylose release (20–40% above the mean). The platform should be useful for screening populations of plants to identify superior germplasm for lignocellulosic ethanol applications and also for screening populations of mutant model plants to identify specific genes affecting digestibility.     

A rapid column-based ancient DNA extraction method for increased sample throughput

Genetic analyses using museum specimens and ancient DNA from fossil samples are becoming increasingly important in phylogenetic and especially population genetic studies. Recent progress in ancient DNA sequencing technologies has substantially increased DNA sequence yields and, in combination with barcoding methods, has enabled large-scale studies using any type of DNA. Moreover, more and more studies now use nuclear DNA sequences in addition to mitochondrial ones. Unfortunately, nuclear DNA is, due to its much lower copy number in living cells compared to mitochondrial DNA, much more difficult to obtain from low-quality samples. Therefore, a DNA extraction method that optimizes DNA yields from low-quality samples and at the same time allows processing many samples within a short time frame is immediately required. In fact, the major bottleneck in the analysis process using samples containing low amounts of degraded DNA now lies in the extraction of samples, as column-based methods using commercial kits are fast but have proven to give very low yields, while more efficient methods are generally very time-consuming. Here, we present a method that combines the high DNA yield of batch-based silica extraction with the time-efficiency of column-based methods. Our results on Pleistocene cave bear samples show that DNA yields are quantitatively comparable, and in fact even slightly better than with silica batch extraction, while at the same time the number of samples that can conveniently be processed in parallel increases and both bench time and costs decrease using this method. Thus, this method is suited for harvesting the power of high-throughput sequencing using the DNA preserved in the millions of paleontological and museums specimens.     

A high-throughput chemical screen for resistance to Pseudomonas syringae in Arabidopsis

The study of plant pathogenesis and the development of effective treatments to protect plants from diseases could be greatly facilitated by a high-throughput pathosystem to evaluate small-molecule libraries for inhibitors of pathogen virulence. The interaction between the Gram-negative bacterium Pseudomonas syringae and Arabidopsis thaliana is a model for plant pathogenesis. However, a robust high-throughput assay to score the outcome of this interaction is currently lacking. We demonstrate that Arabidopsis seedlings incubated with P. syringae in liquid culture display a macroscopically visible 'bleaching' symptom within 5 days of infection. Bleaching is associated with a loss of chlorophyll from cotyledonary tissues, and is correlated with bacterial virulence. Gene-for-gene resistance is absent in the liquid environment, possibly because of the suppression of the hypersensitive response under these conditions. Importantly, bleaching can be prevented by treating seedlings with known inducers of plant defence, such as salicylic acid (SA) or a basal defence-inducing peptide of bacterial flagellin (flg22) prior to inoculation. Based on these observations, we have devised a high-throughput liquid assay using standard 96-well plates to investigate the P. syringae-Arabidopsis interaction. An initial screen of small molecules active on Arabidopsis revealed a family of sulfanilamide compounds that afford protection against the bleaching symptom. The most active compound, sulfamethoxazole, also reduced in planta bacterial growth when applied to mature soil-grown plants. The whole-organism liquid assay provides a novel approach to probe chemical libraries in a high-throughput manner for compounds that reduce bacterial virulence in plants.     

High-throughput S-SAP by fluorescent multiplex PCR and capillary electrophoresis in plants

The inherent replicative mode of transposition endows retrotransposons with considerable advantages as genetic tools in plant genome analysis. Here we present a high-throughput sequence-specific amplification polymorphism (S-SAP) method based on copia-like retrotransposons to fulfill the increasing desire of screening large numbers of samples in plants. Classic approach for digestion, ligation and pre-amplification was combined with optimized fluorescent multiplex PCR for simultaneously selective amplifying S-SAP fragments, and multiple S-SAPs were subsequently detected by capillary electrophoresis using ABI PRISM 3700 capillary instruments. Comparisons of results from multiplex PCR with simplex PCR, and from capillary electrophoresis with slab-gel electrophoresis demonstrated that this method is an efficient, economical, and accurate means for high-throughput and large-scale genotyping retrotransposon variation in plants.     

Isolation and partial characterization of a lead-accumulating Brassica juncea mutant

A new screening method for non-destructive, high-sensitivity, high-throughput isolation of plant mutants capable of accumulating large amounts of heavy metals has been developed. This method is based on incubating seedlings in a solution containing radioisotopes of the metals of interest and visualizing the tissue accumulation of these metals with a phosphorimager. We used this technique to isolate mutants of Brassica juncea (L.) Czern with increased accumulation of Cd and Pb for use in phytoremediation, an emerging technology using plants to remediate polluted soil and water. Approximately 50,000 M2 seedlings were screened and 21 mutants were recovered that retained increased accumulation through the third generation. Mutant 7/15–1 is characterized by enhanced Pb accumulation per unit of root fresh weight, stunted root growth, and decreased root cell size. Data indicate that roots of 7/15–1 contain more cell-wall material on a fresh-weight basis than roots of the wild-type, which may at least partially explain its ability to accumulate more Pb. Received: 22 September 1998 / Accepted:19 December 1998     

Culturable Endophytes of Medicinal Plants and the Genetic Basis for Their Bioactivity

The bioactive compounds of medicinal plants are products of the plant itself or of endophytes living inside the plant. Endophytes isolated from eight different anticancer plants collected in Yunnan, China, were characterized by diverse 16S and 18S rRNA gene phylogenies. A functional gene-based molecular screening strategy was used to target nonribosomal peptide synthetase (NRPS) and type I polyketide synthase (PKS) genes in endophytes. Bioinformatic analysis of these biosynthetic pathways facilitated inference of the potential bioactivity of endophyte natural products, suggesting that the isolated endophytes are capable of producing a plethora of secondary metabolites. All of the endophyte culture broth extracts demonstrated antiproliferative effects in at least one test assay, either cytotoxic, antibacterial or antifungal. From the perspective of natural product discovery, this study confirms the potential for endophytes from medicinal plants to produce anticancer, antibacterial and antifungal compounds. In addition, PKS and NRPS gene screening is a valuable method for screening isolates of biosynthetic potential.     

Expression of human nuclear receptors in plants for the discovery of plant-derived ligands

Plants have the potential to produce a wide array of secondary metabolites that have utility as drugs to treat human diseases. To tap this potential, functional human nuclear receptors have been expressed in plants to create in planta screening assays as a tool to discover natural product ligands. Assays have been designed and validated using 3 nuclear receptors: the estrogen receptor (ER), the androgen receptor (AR), and the heterodimeric retinoid X receptor-alpha plus thyroid hormone receptor-beta (RXRA/THRB). Nuclear receptor-reporter constructs have been expressed in plants to detect the presence of natural ligands that are produced de novo in several plant species during different stages of development, in various tissues, and in response to different stress elicitors. Screening experiments with ER, AR, and RXRA/THRB have been conducted, leading to the identification of plant sources of natural product ligands of human nuclear receptors. This in planta screen has led to the identification of previously unreported ER ligands, providing evidence of the complementary value of this approach to current in vitro high-throughput screening assays.     

A simple, rapid and quantitative method for preparing Arabidopsis protein extracts for immunoblot analysis

Although Arabidopsis has numerous well documented advantages for genetic and molecular analyses, its small size can be a limitation for biochemical and immunochemical assays requiring protein extraction. We have developed a rapid method to extract total protein from small amounts of Arabidopsis tissue that can be used for quantitative immunoblot analysis. The procedure involves direct extraction of tissue into SDS-containing buffer under conditions permitting immediate protein quantification in the extract, using commercially available kits without prior fractionation. This approach provides maximal extraction and quantitative recovery of total cellular protein, together with accurate evaluation of target protein levels as a proportion of the total. We have examined the utility and sensitivity of the procedure using monoclonal antibodies to phytochromes A and C (phyA and phyC), which are high- and low-abundance members, respectively, of the phytochrome family in Arabidopsis. Both phytochromes could be rapidly and readily quantified in the tissues examined, with phyC being detectable in extracts representing as few as five dark-grown seedlings, two light-grown seedlings, or half a single leaf from 3-week-old adult plants. The data indicate that the procedure may have broad utility for the detection and quantitative analysis of many proteins, including those of low abundance, in a variety of applications in Arabidopsis. In one such application, we used transgenic Arabidopsis phyC-overexpressor seedlings to demonstrate that the procedure can be used to detect transgene-encoded protein early at the segregating T2 generation, thereby offering the capacity for accelerated screening and selection of lines engineered to overexpress target proteins.     

Isolation of high-molecular-weight plant DNA for DNA damage quantitation: relative effects of solar 297 nm UVB and 365 nm radiation

Quantitation of UV-induced DNA damages in nanogram quantities of non-radiactive DNA from irradiated plants by gel electrophoresis requires a prompt, efficient, high-yield method of isolating DNA yielding high-molecular-weight, enzymatically digestible DNA. To meet these criteria we devised a high-yield method for isolating from plant tissue, DNA whose single-strand molecular length is greater than about 170 kb. Leaf tissue is embedded in agarose plugs, digested with Proteinase K in the presence of detergent, and treated with phenylmethylsulfonyl fluoride (PMSF). The agarose plugs are then soaked with buffer appropriate to the desired enzyme treatment. Evaluation of the DNA on neutral and alkaline gels indicates its high molecular length and low frequency of single-strand breaks. The DNA can be digested with damage-specific and other endonucleases. The method is especially suitable for DNA damage quantitation, as tissue processing is carried out immediately after harvesting (allowing DNA lesion measurement at precisely known times after irradiation), and many samples can be easily handled at once. It should also be useful for molecular analysis of large numbers of plant samples available only in small quantities. We here use this method to quantitate DNA damage induced by 297 and 365 nm radiation, and calculate the relative damaging effects of these wavebands in today's solar spectrum.     

A portable integrated automatic apparatus for the real-time monitoring of bioluminescence in plants

Real-time monitoring of gene expression by a bioluminescence reporter gene is a powerful method for large-scale, detailed analysis of gene expression in living cells and large-scale screening of mutants. We have developed a portable, compact, integrated automatic bioluminescence-monitoring apparatus that can continuously monitor 960 individual plant seedlings or micro-organism colonies under uniform light conditions at temperatures up to 50 °C. The apparatus gave reproducible and reliable results for both bioluminescence photon counts and period length of bioluminescence rhythms of Arabidopsis reporter strain. Using the apparatus, we measured bioluminescence rhythms in the thermophilic cyanobacterium Thermosynechococcus at temperature up to 43 °C. We also monitored the expression of the flowering regulator gene CONSTANS in Arabidopsis as bioluminescence in high time resolution under different photoperiodic conditions. The high-throughput bioluminescence-monitoring apparatus developed here is a powerful tool for real-time monitoring of gene expression and gene function.     

Agrosuppression: a bioassay for the hypersensitive response suited to high-throughput screening

We describe a novel method, agrosuppression, that addresses the need for an assay of the hypersensitive response (HR) in intact plants that is rapid and adapted to high-throughput functional screening of plant and pathogen genes. The agrosuppression assay is based on inoculation of intact plants with a mixture of Agrobacterium tumefaciens strains carrying (i) a binary plasmid with one or more candidate HR-inducing genes and (ii) a tumor-inducing (oncogenic) T-DNA. In the absence of HR induction, tumor formation is initiated, resulting in a typical crown gall phenotype. However, upon induction of the HR, tumor formation by the oncogenic T-DNA is suppressed, resulting in a phenotype that can be readily scored. We tested and optimized agrosuppression in Nicotiana benthamiana using the inf1 elicitin gene from the oomycete pathogen Phytophthora infestans, which specifically induces the HR in Nicotiana spp., and the gene-for-gene pair Avr9/Cf-9 from the fungal pathogen Cladosporium fulvum and Lycopersicon pimpinellifolium (currant tomato), respectively. Agrosuppression protocols that can be rapidly performed using simple mechanical wounding of petioles of intact N. benthamiana plants were developed and appeared particularly adapted to intensive high-throughput screening. This assay promises to greatly facilitate the cloning of novel plant R genes and pathogen Avr genes and to accelerate functional analyses and structure-function studies of these genes.     

From phenotype to genotype: whole tissue profiling for plant breeding

Fourier transform infrared spectroscopy (FT-IR) was used to obtain ‘holistic’ metabolic fingerprints from a wide range of plants to differentiate species, population, single plant genotype, and chromosomal constitution differences. Sample preparation simply entailed the maceration of fresh leaves with water, and these samples were then dried and analysed by reflectance FT-IR where spectral acquisition was typically 10 s. All samples gave reproducible, characteristic biological infrared absorption spectra and these were analysed by chemometric methods. FT-IR is not biased to any particular chemical species and thus the whole tissue profiles produced measure the total biochemical makeup of the test sample; that is to say it represents a plant phenotype. We show that by simple cluster analysis these phenotypic measurements can be related to the genotypes of the plants and can reliably differentiate closely related individuals. We believe that this approach provides a valuable new tool for the rapid metabolomic profiling of plants, with applications to plant breeding and the assessment of substantial equivalency for genetically-modified plants.     

High-throughput fluorescent screening of transgenic animals: phenotyping and haplotyping.

BACKGROUND: Methods for genotyping transgenic animals currently consist of extracting genomic DNA from blood or tissue followed by PCR or Southern blot analysis. These methods when used to screen large numbers of animals can be time consuming and expensive. Therefore, we developed a novel method that allows high-throughput screening of phenotypic changes on leukocytes, resulting from the transgenic genotype. This technique allows investigators to quickly screen a large number of animals without the need to extract DNA from each one. Moreover, since blood is collected for the initial screening, putative homozygotes can be confirmed by conventional methods using the same blood samples. METHODS: We collected blood from wild-type alphagal positive and alphagal knockout mice and probed for the presence of Galalpha(1-->3)Gal (alphagal) epitopes. Also, alloantigen specific antibodies were used to determine the haplotype of our outbred mouse colony in order to develop an inbred line. RESULTS: alphagal epitopes were detected in wild-type but not alphagal knock-out samples. To validate these results, PCR was used to demonstrate the native alphagal gene in wild-type and the pGKneo construct in alphagal knock-out mice. Furthermore, haplotypes were determined and mice divided for backcrosses. CONCLUSIONS: This screening method is useful for both preliminary screening of transgenic mice and the development of an inbred mouse colony by rapid determination of MHC I haplotype. Here, we demonstrate the use of this technique and show how it can be a valuable tool, saving time and resources in both investigator effort and animal husbandry.     

High-throughput DNA extraction method suitable for PCR

PCR has become one of the most popular techniques in functional genomics. Projects in both forward and reverse genetics routinely require PCR amplification of thousands of samples. Processing samples to extract DNA of sufficient purity for PCR is often a limiting step. We have developed a simple 96-well plate-based high-throughput DNA extraction method that is applicable to many plant species. The method involves a simple incubation of plant tissue samples in a DNA extraction buffer followed by a neutralization step. With the addition of a modified PCR buffer, the extracted DNA enabled the robust amplification of genomic fragments from samples of Arabidopsis, tobacco, sorghum, cotton, moss, and even pine needles. Several thousand DNA samples can be economically processed in a single day by one person without the use of robotics. This procedure will facilitate many technologies including high-throughput genotyping, map-based cloning, and identification of T-DNA or transposon-tagged mutants for known gene sequences.     

Genetically Programmed Chloroplast Dedifferentiation as a Consequence of Plastome-Genome Incompatibility in Oenothera

Comparision of chloroplast from plants with one of four plastome types (I, II, III, IV) in the nuclear background of Oenothera elata strain Johansen addressed the effects of plastome-genome incompatibility with respect to leaf pigmentation, plastid ultrastructure, chlorophyll a/chlorophyll b ratio, and photosynthetic electron transport. Previous observations of plastomes I, II, and IV in this nuclear background have revealed no indications of incompatibility, but the studies reported here demonstrate that chloroplasts of plastome IV have subtle alterations in their photosynthetic abilities, in particular, deficiencies in photosystem II. The well-characterized "hybrid bleaching" of plants with the AA genotype and plastome III involves leaves that become bleached in the center while remaining green at the tips, edges, and veins. Electron transport assays performed on fractionated bleached and green tissue from the same plants show photosynthetic defects in both the green and bleached regions, although defects in the latter are more severe. Ultrastructural studies show that chloroplasts in the bleached areas enlarge, thylakoid membranes become swollen and vesiculated, and production of new thylakoids is blocked, with chloroplasts appearing to undergo a programmed senescence. A time course revealed that the senescence is actually a reversible dedifferentiation. Alterations in the composition of medium to which AA/III seedlings were transferred showed that the presence of auxin can prevent the development of the typical incompatibility response, with leaf tissue remaining green rather than bleaching. It is proposed that differences in concentrations of plant growth regulators may be responsible for the persistence of normal chloroplasts near the vascular tissue and leaf blade edges and that seasonal fluctuations in auxin levels could explain the periodic bleaching that occurs in older plants.