Identification of specific proteins from seed embryos by two-dimensional gel electrophoresis for the discrimination between indica and japonica rice

Summary Proteins extracted from seed embryos of 29 different cultivated rice (Oryza sativa L.) and one wild rice (O. rufipogon Griff.) were compared by two-dimensional gel electrophoresis analysis. Among more than 300 protein spots on the gel we found some interesting variations in ten spots which were individually designated as proteins A-J. Protein E was observed in all indica cultivars but was not found in those of the subspecies japonica. In contrast, protein F was only detected in japonica cultivars. Protein A existed in all japonica cultivars but, with the exception of IR-36, could not be found in other indica cultivars. Therefore, proteins A, E and F can be used as markers for the identification of indica and japonica. Some so-called Javanica cultivars showed the characteristics of japonica subspecies with regard to proteins A and F, while one other cultivar of Javanica expressed a type intermediate between indica and japonica interms of proteins A and E. One feature discriminating between Javanica and japonica cultivars was found in the D, G, and J proteins which were expressed strongly in Javanica cultivars but were scarcely expressed in those of japonica. Expression of subspecies-specific proteins E and F in f₁ hybrids was also investigated.     

Proteomics of the rice cell: systematic identification of the protein populations in subcellular compartments

Despite recent progress in sequencing the complete genome of rice (Oryza sativa), the proteome of this species remains poorly understood. To extend our knowledge of the rice proteome, the subcellular compartments, which include plasma membranes (PM), vacuolar membranes (VM), Golgi membranes (GM), mitochondria (MT), and chloroplasts (CP), were purified from rice seedlings and cultured suspension cells. The proteins of each of these compartments were then systematically analyzed using two-dimensional (2D) electrophoresis, mass spectrometry, and Edman sequencing, followed by database searching. In all, 58 of the 464 spots detected by 2D electrophoresis in PM, 43 of the 141 spots in VM, 46 of the 361 spots in GM, 146 in the 672 spots in MT, and 89 of the 252 spots in CP could be identified by this procedure. The characterized proteins were found to be involved in various processes, such as respiration and the citric acid cycle in MT; photosynthesis and ATP synthesis in CP; and antifungal defense and signal systems in the membranes. Edman degradation revealed that 60–98% of N-terminal sequences were blocked, and the ratios of blocked to unblocked proteins in the proteomes of the various subcellular compartments differed. The data on the proteomes of subcellular compartments in rice will be valuable for resolving questions in functional genomics as well as for genome-wide exploration of plant function.Electronic Supplementary Material Supplementary material is available in the online version of this article at Communicated by G. Jürgens     

Proteome analysis of rice root proteins regulated by gibberellin

To gain an enhanced understanding of the mechanism by which gibberellins （GAs） regulate the growth and development of plants, it is necessary to identify proteins regulated by GA. Proteome analysis techniques have been applied as a direct, effective, and reliable tool in differential protein expressions. In previous studies, sixteen proteins showed differences in accumulation levels as a result of treatment with GA3, uniconazole, or abscisic acid （ABA）, and/or the differences between the GA-deficient semi-dwarf mutant, Tan-ginbozu, and normal cultivars. Among these proteins, aldolase increased in roots treated with GA3, was present at low levels in Tan-ginbozu roots, and decreased in roots treated with uniconazole or ABA. In a root elongation assay, the growth of aldolase-antisense transgenic rice was half of that of vector control transgenic rice. These results indicate that increases in aldolase activity stimulate the glycolytic in the GA-induced growth of roots. In among GA, aldolase, and root growth. pathway and may play an important role this review, we discuss the relationship among GA, aldolase, and root growth.     

Comparative studies of four protein preparation methods for proteomic study of the dinoflagellate Alexandrium sp. using two-dimensional electrophoresis

Alexandrium is a wide-spread genus of dinoflagellate causing harmful algal blooms and paralytic shellfish poisoning around the world. Proteomics has been introduced to the study of Alexandrium, but the protein preparation method is still unsatisfactory with respect to protein spot number, separation and resolution, and this has limited the application of a proteomic approach to the study of dinoflagellates. In this study we compared four protein preparation methods for the two-dimensional electrophoresis (2DE) analysis of A. tamarense: (1) urea/Triton X-100 buffer extraction with trichloroacetic acid (TCA)/acetone precipitation; (2) direct precipitation with TCA/acetone; (3) 40 mM Tris (hydroxymethyl) aminomethane (Tris) buffer extraction; and (4) 50 mM Tris/5% glycerol buffer extraction. The results showed that, among the four protein preparation methods, the method combining the urea/Triton X-100 buffer extraction and TCA/acetone precipitation allowed detection of the highest number and quality of protein spots with a clear background. Although the direct TCA/acetone precipitation method also detected a high number of protein spots with a clear background, the spot number, separation and intensity were not as good as those obtained from the urea/Triton X-100 buffer extraction with TCA/acetone precipitation method. The 40 mM Tris buffer and 50 mM Tris/5% glycerol buffer methods allowed the detection of fewer protein spots and a pH range only from 4 to 7. Subsequently, the urea/Triton X-100 buffer extraction with TCA/acetone precipitation method was successfully applied to profiling protein expression in A. catenella under light stress conditions and the differential expression proteins were identified using MALDI TOF–TOF mass spectrometry. The method developed here appears to be promising for further proteomic studies of this organism and related species.     

Differentiation of rice varieties by electrophoresis of embryo protein

Summary Variations in the embryo proteins separated by SDS-PAGE have been observed in 43 cultivated varieties of Oryza sativa L. Cluster and discriminant analysis applied to both protein components and morphological characters indicate that knowledge of the differences in embryo proteins can improve our understanding of genetic affinity and make it easier to differentiate between varieties of similar genetic backgrounds.     

Resolution ofFusarium sporotrichioides proteins by two-dimensional polyacrylamide gel electrophoresis and identification by sequence homology comparison in protein data base

Proteins fromFusarium sporotrichioides M-1-1, a T2-toxin-producing strain, were separated by two-dimensional polyacrylamide gel electrophoresis. One thousand two hundred and forty-four protein spots were resolved and 103 protein spots were subjected to N-terminal sequencing. Fifty-eight protein spots were sequenced and 48 proteins were observed to have blocked N termini. Forty out of 58 sequenced proteins were identified by homology search against the PIR protein sequence data base and protein superfamily data base, while the residual 18 sequences were not identified. Twenty-seven of the N-terminal-blocked proteins were subjected to mild anhydrous hydrazine vapor deblocking. Twenty-four spots were not deblocked indicating the presence of acyl groups at the N termini, while 3 proteins were deblocked showing the blocked group to be pyrroglutamyl carboxylic acid residues. The results can provide a more global view of cellular genetic expression than any other technique. The created data may offer a unique opportunity to link information with DNA sequence data.     

Genetic analysis of gliadin components in winter wheat using two-dimensional polyacrylamide gel electrophoresis

Summary Blocks of gliadin components found both in a number of varieties and in single F₂ grains of winter wheat intervarietal hybrids have been studied by two-dimensional electrophoresis combining electrophoresis in acidic aluminium-lactate buffer (pH3.1) and SDS-electrophoresis. Gliadin components (spots) have been shown to be inherited as linked groups (blocks), codominantly and in accordance with a gene dosage in triploid endosperm. Blocks include components differing in their electrophoretic mobility and molecular weight. Some allelic variants of blocks differ only in presence of few additional components or in the electrophoretic mobility of components with similar molecular weights; other variants may contain no similar components. Apparently, in the course of evolution, mutations in individual genes of gliadin-coding loci and processes changing the number of expressing genes and the sizes of their structural part occurred.     

Genetic polymorphism in Norway spruce,Picea abies (L.) Karst,assessed by two-dimensional gel electrophoresis of needle proteins

Summary A comparative analysis of three Norway spruce genotypes by two-dimensional gel electrophoresis is presented. This study has led to the identification of approximately 970 gene products for each genotype. Significant qualitative and quantitative differences have been identified, and qualitative and quantitative divergence indices between genotypes have been computed. Two-dimensional electrophoresis appears to be an efficient tool for studying modifications of gene expression in Norway spruce in response to climatic and pollution stresses.     

Comparison of plastid DNA replication in different cells and tissues of the rice plant

In a previous study, we mapped replication origin regions of the plastid DNA around the 3 end of the 23S rRNA gene in rice suspension-cultured cells. Here, we examined initiation of the plastid DNA replication in different rice cells by two-dimensional agarose gel electrophoresis. We show for the first time, to our knowledge, that the replication origin region of the plastid DNA differs among cultured cells, coleoptiles and mature leaves. In addition, digestion of the replication intermediates from the rice cultured cells with mung bean nuclease, a single-strand-specific nuclease, revealed that both two single strands of the double-stranded parental DNA were simultaneously replicated in the origin region. This was further confirmed by two-dimensional agarose gel analysis with single-stranded RNA probes. Thus, the mode of plastid DNA replication presented here differs from the unidirectional replication started by forming displacement loops (D-loops), in which the two D-loops on the opposite strands expand toward each other and only one parental strand serves as a template.     

Proteome analysis of rice uppermost internodes at the milky stage

Uppermost internodes, which connect the part between the ear and lower stem, form an important pathway transporting mineral nutrition from roots and photosynthates from leaves (especially the flag leaf) to the ear. The milky stage is the first stage of seed ripening. The uppermost internodes of rice at the milky stage are critical for seed quality and yield. Total soluble proteins of the uppermost internodes of rice (Oryza sativa L. ssp. indica) at the milky stage were analyzed using proteomic methods. Using 2-DE, 762 reproducible protein spots were detected. Among them, 132 abundant proteins were analyzed using MALDI-TOF-MS. Searching in the National Center for Biotechnology Information database, we could identify 98 proteins, which represent 80 gene products. These proteins belong to 11 functional groups with energy production-associated proteins in the first place. The large accumulation of proteins involved in metabolism, signaling, and stress resistance indicated that the uppermost internodes of rice have a high physiological and stress-resistant activity. In addition, our results will also enrich the database of the rice proteome.     

Analysis of rice (Oryza sativa L.) genome using pulsed-field gel electrophoresis and rare-cutting restriction endonucleases

TheOryza sativa (rice) genome is small (600 to 900 megabase pairs) when compared to that of other monocotyledonous plants. Rice was the first of the major cereals to be successfully transformed and regenerated. An RFLP map with approximately 300 markers is readily available, and the DNA content per map unit is only two to three times that ofArabidopsis thaliana. Rice is also the main staple food for the majority of peoples in the world. We developed techniques for the preparation of intact genomic DNA from Indica and Japonica subspecies of rice, used statistical methods to determine which restriction endonucleases are rare-cutting, and used pulsed-field gel electrophoresis (PFE) to separate large fragments of rice DNA. Southern hybridization to blotted rice PFE gels was used to show that the digests were complete. The long-term goal of our work is to generate an integrated genetic/physical map for the rice genome, as well as helping to establish rice as a model for map-based gene cloning and genome analysis.     

Identification of tissue proteins by amino acid analysis after purification by two-dimensional electrophoresis

Mouse brain proteins were separated by two-dimensional electrophoresis (2-DE). The proteins of a section of the 2-DE pattern were blotted onto hydrophobic membranes and 43 of them were excised and hydrolyzed by liquid-phase hydrolysis. The amino acid composition of these proteins was determined by orthophthaldialdehyde precolumn derivatization and compared with the compositions of known proteins stored in the NBRF sequence database. An identification program named ASA was developed for this purpose. The ASA program includes correction and weighting factors, data reduction by molecular weight windows, and exclusion or inclusion of certain organisms as desired. As a control, eight test proteins and five well-known proteins from mouse brain, all separated by 2-DE, were correctly identified by the program. Out of the 43 brain proteins selected, 19 were identified with high confidence.     

Characterization of rice transformed via an Agrobacterium-mediated inflorescence approach

Rice inflorescences were inoculated with Agrobacterium tumefaciens strain LBA4404 carrying plasmid pJD4 with application of vacuum infiltration. After co-cultivation, callus was initiated and subjected to hygromycin selection, and plants were regenerated from resistant callus lines. Based on the total number of co-cultivated inflorescences bearing flowers 1 to 3 mm in length, the average frequency for recovering independent transgenic rice plants was at least 30%. Seeds from selfed R0 plants were harvested within 6 months after initiation of the experiments. Genomic DNA blot analysis showed that genes in the T-DNA of the binary plasmid were stably integrated into the rice genome, typically at low copy number. In most, but not all, cases the transgene was transmitted to R1 progeny at a frequency characteristic for Mendelian inheritance of a single dominant trait. For selfed progeny of one two-locus insertion line, reactivation of GUS expression was observed for a single copy locus that segregated from a silenced multicopy locus. For this line and some additional plants, fluorescence in situ hybridization was used to visualize the chromosomal location of the transgene insert.     

Polyethylene glycol fractionation improved detection of low-abundant proteins by two-dimensional electrophoresis analysis of plant proteome

Poor detection of low-abundant proteins is a common problem in two-dimensional electrophoresis (2-DE) for separation of proteins in a proteome analysis. This is attributed partially, at least, to the existence of high-abundant proteins, e.g. ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) in plants. They engage a large proportion of the whole-cell proteins and thus prevent low-abundant proteins from being up-taken by immobilized pH gradient (IPG) strip, consequently making the latter poorly detectable by 2-DE. In this work, we report a straightforward protocol for preparation of whole-cell proteins through differential polyethylene glycol (PEG) precipitation aiming at elimination of Rubisco from plant protein samples. In comparison with 2-DE analysis of protein samples prepared using a conventional TCA/acetone method, a relatively high reproducibility of proteins was achieved using a PEG fractionation protocol in terms of protein yield and protein species. As expected, the large subunit of Rubisco was precipitated predominantly in the 16% PEG fraction. This allowed proteins of the Rubisco-containing fraction to be analyzed separately from those of other PEG fractions. After taking into account the overlapping protein spots among 2-DE gels of all fractions through image and statistical analyses, we detected with this protocol a total 5077 protein spots, among which ca. 80% are proteins undetectable with the TCA/acetone method, while the rest of proteins exhibited a significant increase in their abundance. This protocol was developed using Arabidopsis as a source of protein and thus may also be applicable to protein preparations of other plants.     

Identification of gibberellins in the rice plant and quantitative changes of gibberellin A19 throughout its life cycle

The major endogenous gibberellin (GA) in shoots, roots and ears of the rice plant, Oryza sativa L. japonica cv. Nihonbare, was identified as GA₁₉ by combined gas liquid chromatography-mass spectrometry (GC-MS) and GC-selected ion current monitoring (GC-SICM). Another GA present in these tissues in small quantity was tentatively identified as GA₁ by GC-SICM, and GA₄ may be present in the seeds (kernels) of 3rd-leaf-stage seedlings. Using GC-SICM, the GA₁₉ content was quantified throughout the life cycle of rice plants. It was found to reach high levels (ca. 10–15 g/kg fresh weight) in 3rd-leaf seedlings, at panicle initiation (shoots), and during heading and anthesis (ears). The levels of GA₁₉ in Oryza sativa indica cv. T-136 underwent changes closely similar to those found in Nihonbare. The growth-promoting activity in rice of exogenous GA₁₉ is generally considerably less than that of GA₁. It therefore seems possible that GA₁₉ functions as a pool GA. The level of active GAs such as GA₁ may be regulated by the rate of biosynthesis of GA₁₉ or its metabolic conversions.Abbreviations GA(s) gibberellin(s) - GA_n gibberellin A_n - GA_n-MeTMS trimethylsilyl ether of GA_n methyl ester - GC-MS combined gas liquid chromatography-mass spectrometry - GC-SICM combined gas liquid chromatography-selected ion current monitoring - TLC thin-layer chromatography     

Molecular evolution and phylogeny of theDrosophila virilis species group as inferred by two-dimensional electrophoresis

Summary Systematic relationship among the 12 species of theDrosophila virilis species group, andDrosophila robusta, were investigated by the use of two-dimensional electrophoresis (2-DE). A total of 389 protein characters (about 200 loci) were scored and analyzed both phylogenetically and phenetically. The resulting phylogeny was found to be largely concordant with the current views of evolution among these species based on other independent morphological, chromosomal, electrophoretic, and immunological data sets, although some notable differences were observed. The 2-DE data also appeared to be useful for constructing a molecular clock to date the absolute times of divergence among the species. It appears from this analysis that the evolution of the major clades within the species group occurred about 20 million years ago. Previous suggestions that the rate of molecular evolution was different between the virilis and montana phylads was not confirmed. The technique of 2-DE seems to be an excellent tool for reconstructing phylogenies and should be particularly valuable for examining relatively closely related species.     

Modelling zinc uptake by rice crop using a Barber-Cushman approach

The Barber-Cushman mechanistic nutrient uptake model which has been utilized extensively to describe and predict nutrient uptake by crop plants at different stages of crop growth was evaluated for its ability to predict the Zn uptake by rice seedlings. Uptake of the nutrient is, therefore, determined by the rate of nutrient supply to the root surface by mass flow and diffusion. Inter root competition and time dependent root density are accounted for by soil volume that delivers nutrients. The radii of these cylinders decline with increasing density. Since mass flow and diffusion each supply zinc to the root, the process can be described mathematically using the model of Barber-Cushman (1984). The 11 parameters of the model for the uptake by rice cultivars were measured by established experimental techniques. Zinc uptake at different growth stages predicted by the model was compared to measured zinc uptake by rice cultivars grown on sandy loam soil in a green house. Predicted zinc uptake was significantly correlated with observed uptake r ²=0.99^**. Sensitivity analysis was also used to investigate the impact of changes in soil nutrient supply, root morphological and root uptake kinetic parameters on simulated nutrient uptake. Overall results of sensitivity analysis indicate that the half distance between root axes, rate of root growth and water flux affect the uptake of zinc particularly at their higher values rather than at lower values and DaZn is the most sensitive parameter for zinc uptake at its lower values.