Comparative proteomic study reveals the involvement of diurnal cycle in cell division, enlargement, and starch accumulation in developing endosperm of Oryza sativa

The development and starch accumulation of cereal endosperms rely on the sugar supply of leaves, which is subject to diurnal cycles, and the endosperm itself also experiences a light/dark switch. However, revealing how the cereal endosperm responds to diurnal input remains a major challenge. We used comparative proteomic approaches to probe diurnally affected processes in rice endosperm (Oryza sativa) 10 days after flowering under 12-h light/12-h dark. Starch granules in rice endosperm showed a growth ring structure under a normal light/dark cycle but not under constant light. Sucrose showed a high level in light and low level in dark. Two-dimensional (2-D) differential in-gel electrophoresis-based proteomic analysis revealed 101 protein spots diurnally changed and 91 identities, which were involved in diverse processes with preferred distribution in stress response, protein synthesis/destination and metabolism. Proteins involved in cell division showed high expression in light and those in cell enlargement and cell wall synthesis high in dark, while starch synthesis proteins were light-downregulated and dark-upregulated. Redox homeostasis-associated proteins showed in-phase peaks under light and dark. These data demonstrate diurnal input-regulated diverse cellular and metabolic processes in rice endosperm, and coordination among these processes is essential for development and starch accumulation with diurnal input.     

Dynamic proteomic analysis reveals diurnal homeostasis of key pathways in rice leaves

Diurnal physiological acclimation regulated by a circadian system is an advantage for plant fitness. The circadian system is composed of a signal input, the clock and output pathways. Understanding the regulation mechanism of the output pathways remains a major challenge. Diurnal proteomic change reflects the state of circadian organization. We found the content of glucose, fructose, sucrose and starch diurnally changed in leaves of rice seedlings grown under a 12-h light/12-h dark condition with constant temperature. Dynamic proteomics analysis revealed 140 protein spots with diurnally changed levels at six times of the light/dark cycle; 132 spots were identified by MS, and 119 spots were of a single protein each with functional annotation. These proteins are involved in regulation of carbohydrate flow, redox, protein folding, nitrogen and protein metabolism, energy conversion, photorespiration and photosynthesis. Of these proteins, 81.5% were upregulated during the light phase, overlappingly, 41.2% showed behavior of circadian anticipation to dawn. Pattern analysis showed that the diurnal regulation involved pathways of allocation of carbohydrates between temporary reserves and consumption, maintenance of redox homeostasis, diurnal protein reassembly and nitrogen assimilation. These pathways reflect biochemical phenotypes of the circadian change linking the oscillator and circadian outputs.     

Genetic, proteomic and metabolic analysis of the regulation of energy storage in rice seedlings in response to drought

We used proteomic analysis to determine the response of rice plant seedlings to drought-induced stress. The expression of 71 protein spots was significantly altered, and 60 spots were successfully identified. The greatest down-regulated protein functional category was translation. Up-regulated proteins were mainly related to protein folding and assembly. Additionally, many proteins involved in metabolism (e.g. carbohydrate metabolism) also showed differences in expression. cDNA microarray and GC-MS analysis showed 4756 differentially expressed mRNAs and 37 differentially expressed metabolites. Once these data were integrated with the proteomic analysis, we were able to elucidate the metabolic pathways affected by drought-induced stress. These results suggest that increased energy consumption from storage substances occurred during drought. In addition, increased expression of the enzymes involved in anabolic pathways corresponded with an increase in the content of six amino acids. We speculated that energy conversion from carbohydrates and/or fatty acids to amino acids was increased. Analysis of basic metabolism networks allowed us to understand how rice plants adjust to drought conditions.     

Proteomic analysis of salt stress-responsive proteins in rice root

Salt stress is one of the major abiotic stresses in agriculture worldwide. We report here a systematic proteomic approach to investigate the salt stress-responsive proteins in rice (Oryza sativa L. cv. Nipponbare). Three-week-old seedlings were treated with 150 mM NaCl for 24, 48 and 72 h. Total proteins of roots were extracted and separated by two-dimensional gel electrophoresis. More than 1100 protein spots were reproducibly detected, including 34 that were up-regulated and 20 down-regulated. Mass spectrometry analysis and database searching helped us to identify 12 spots representing 10 different proteins. Three spots were identified as the same protein, enolase. While four of them were previously confirmed as salt stress-responsive proteins, six are novel ones, i.e. UDP-glucose pyrophosphorylase, cytochrome c oxidase subunit 6b-1, glutamine synthetase root isozyme, putative nascent polypeptide associated complex alpha chain, putative splicing factor-like protein and putative actin-binding protein. These proteins are involved in regulation of carbohydrate, nitrogen and energy metabolism, reactive oxygen species scavenging, mRNA and protein processing, and cytoskeleton stability. This study gives new insights into salt stress response in rice roots and demonstrates the power of the proteomic approach in plant biology studies.     

Analysis of the protein expression profiling during rice callus differentiation under different plant hormone conditions

Plant hormones function to coordinate plant growth and development. While the plant hormones, mainly auxin and cytokinin, are exogenously added to various plant tissue cultures, their effects on the organogenesis are apparent, but little is known concerning the molecular mechanisms by which they function in cultured cells. Rice, as a model plant in monocots, is also suitable to tissue culture studies. Here, we used four types of regeneration mediums with different relative concentrations of cytokinin and auxin for rice callus differentiation, the calli at different differentiation stages were collected for proteomic analysis. 2-dimensional electrophoresis revealed that 213 protein spots significantly differentially expressed during callus differentiation under different hormone conditions. By using mass spectrometry, 183 differentially expressed protein spots were identified to match 157 unique proteins. Most of these differential proteins were cellular/metabolic process-related proteins, whose different expression patterns may be correlated with the cytokinin and auxin regulation. Several hormone-related proteins were prominently featured in differentiated calli as compared with the initiated calli, such as alpha-amylase isoforms, mannose-binding rice lectin, putative dehydration stress-induced protein, cysteine endopeptidase and cystatin. All these results provide a novel insight into how the two plant hormones effect the callus differentiation in rice on the proteomic level.     

Rhythms in glutamine synthetase activity, energy charge, and glutamine in sunflower roots

Roots of sunflower plants (Helianthus annuus L. var. Mammoth Russian) subjected to L12:D12, L18:D6, and L12:D12 followed by continuous light all display rhythms of about 12 hours for glutamine synthetase (GS) activity (transferase reaction) with one peak in the `light phase' and one in the `dark phase.' Root energy charge (EC = ATP+½ADP/ATP+ADP+AMP) is directly correlated with GS, but the GS rhythm is better explained as the result of a rhythmic adenine nucleotide ratio (ATP/ADP+AMP) that regulates enzyme activity through allosteric modification. When L12:D12 plants are subjected to free-running conditions in continuous darkness, only diurnal rhythms for GS and EC, with peaks in the dark phase, remain. The 12-hour root rhythms for GS and EC appear to be composed of two alternating rhythms, one a diurnal, light-dependent, incompletely circadian light phase rhythm and the other a light-independent, circadian dark phase rhythm.

Only glutamine, of the root amino acids, displays cyclical changes in concentration, maintaining under all conditions a 12-hour rhythm that is consistently synchronized with, but nearly always inversely correlated with, GS and EC rhythms.

     

Proteomic Analysis of Rice Plasma Membrane-associated Proteins in Response to Chitooligosaccharide Elicitors

Chitooligomers or chitooligosaccharides （COS） are elicitors that bind to the plasma membrane （PM） and elicit various defense responses. However, the PM-bound proteins involved in elicitor-mediated plant defense responses still remain widely unknown. In order to get more information about PM proteins involved in rice defense responses, we conducted PM proteomic analysis of the rice suspension cells elicited by COS. A total of 14 up- or downregulated protein spots were observed on 2-D gels of PM fractions at 12 h and 24 h after COS incubation. Of them, eight protein spots were successfully identified by MS （mass spectrography） and predicted to be associated to the PM and function in plant defense, including a putative PKN/PRK1 protein kinase, a putative pyruvate kinase isozyme G, a putative zinc finger protein, a putative MAR-binding protein MFP1, and a putative calcium-dependent protein kinase. Interestingly, a COS-induced pM5-like protein was identified for the first time in plants, which is a transmembrane nodal modulator in transforming growth factor-β（TGFβ） signaling in vertebrates. We also identified two members of a rice polyprotein family, which were up-regulated by COS. Our study would provide a starting point for functionality of PM proteins in the rice basal defense.     

Proteomics reveals new insights into the role of light in cadmium response in Arabidopsis cell suspension cultures

Light plays an important role in plant growth, development, and response to environmental stresses. To investigate the effects of light on the plant responses to cadmium (Cd) stress, we performed a comparative physiological and proteomic analysis of light‐ and dark‐grown Arabidopsis cells after exposure to Cd. Treatment with different concentrations of Cd resulted in stress‐related phenotypes such as cell growth inhibition and decline of cell viability. Notably, light‐grown cells were more sensitive to heavy metal toxicity than dark‐grown cells, and the basis for this appears to be the elevated Cd accumulation, which is twice as much under light than dark growth conditions. Protein profiles analyzed by 2D DIGE revealed a total of 162 protein spots significantly changing in abundance in response to Cd under at least one of these two growing conditions. One hundred and ten of these differentially expressed protein spots were positively identified by MS/MS and they are involved in multiple cellular responses and metabolic pathways. Sulfur metabolism‐related proteins increased in relative abundance both in light‐ and dark‐grown cells after exposure to Cd. Proteins involved in carbohydrate metabolism, redox homeostasis, and anti‐oxidative processes were decreased both in light‐ and dark‐grown cells, with the decrease being lower in the latter case. Remarkably, proteins associated with cell wall biosynthesis, protein folding, and degradation showed a light‐dependent response to Cd stress, with the expression level increased in darkness but suppressed in light. The possible biological importance of these changes is discussed.     

Protein profile of rice (Oryza sativa) seeds

Seeds are the most important plant storage organ and play a central role in the life cycle of plants. Since little is known about the protein composition of rice (Oryza sativa) seeds, in this work we used proteomic methods to obtain a reference map of rice seed proteins and identify important molecules. Overall, 480 reproducible protein spots were detected by two-dimensional electrophoresis on pH 4–7 gels and 302 proteins were identified by MALDI-TOF MS and database searches. Together, these proteins represented 252 gene products and were classified into 12 functional categories, most of which were involved in metabolic pathways. Database searches combined with hydropathy plots and gene ontology analysis showed that most rice seed proteins were hydrophilic and were related to binding, catalytic, cellular or metabolic processes. These results expand our knowledge of the rice proteome and improve our understanding of the cellular biology of rice seeds.     

Proteomic Analysis of Low Nitrogen Stress-Responsive Proteins in Roots of Rice

In recent years, the application of proteomic approaches as a tool for global expression analysis and protein identification has been highly efficient in the field of plant research. A solution culture experiment involving two nitrogen treatments, 0.14 mM NH₄NO₃ (low nitrogen (N)) and 1.07 mM NH₄NO₃ (control), was conducted to investigate the response of rice root to low N stress. Root system architecture changed markedly under low N stress, with more lateral roots occurring on the lower part of adventitious roots and longer lateral roots on the upper part, compared to the control. A proteomic approach was employed to further study the rice responses to low N stress. Proteins extracted from roots were profiled by two-dimensional gel electrophoresis, and differentially expressed proteins were analyzed by mass spectrometry. Twelve protein spots were successfully identified by mass spectrometry, 11 of which had known functions. Of these, four were involved with the tricarboxylic acid cycle, two with adenylate metabolism, two with phenylpropanoid metabolism, and two with protein degradation. These differentially expressed proteins play an important role in the responsive mechanisms of rice root to low N stress, and uncovering how the rice proteins respond to low N stress could contribute to improving the nitrogen use efficiency.     

A proteomic approach to analyze nitrogen- and cytokinin-responsive proteins in rice roots

Nitrogen plays a central role in rice growth and development because it modulates a wide variety of processes, including cytokinin (CK) metabolism. CK-mediated signaling is also related to nitrogen metabolism. The functional relation between nitrogen and CK are extremely complex and unclear. In this study, a comparative proteomic analysis was carried out to analyze proteins regulated by nitrogen and CK in rice roots. Proteins extracted from rice roots are separated by two-dimensional polyacrylamide gel electrophoresis. Thirty-two protein spots that expressed similarly by nitrogen and CK treatments are selected for identification by mass spectrometry. Of these spots, 28 are successfully identified. These proteins were categorized into classes related to energy, metabolism, disease/defense, protein degradation, signal transduction, transposons, and unclear classification. Energy gives the largest functional category, suggesting that the glycolysis (two enzymes detected) and tricarboxylic acid cycle (six enzymes detected) are accurately regulated by nitrogen and CK, thus promoting the synthesis of amino acid. The identification of novel proteins provides new insights into the coordination of nitrogen and CK in rice. The possible role of these proteins is discussed.     

Identification of NaCl stress-responsive apoplastic proteins in rice shoot stems by 2D-DIGE

Plants have evolved sophisticated systems to cope with adverse environmental conditions such as cold, drought, and salinity. Although a number of stress response networks have been proposed, the role of plant apoplast in plant stress response has been ignored. To investigate the role of apoplastic proteins in the salt stress response, 10-day old rice plants were treated with 200mM NaCl for 1, 6 or 12h, and the soluble apoplast proteins of rice shoot stems were extracted for differential analysis, compared with untreated controls, by 2-D DIGE saturation labeling techniques. One hundred twenty-two significantly changed spots were identified by LC-MS/MS, and 117 spots representing 69 proteins have been identified. Of these proteins, 37 are apoplastic proteins according to the bioinformatic analysis. These proteins are mainly involved in the processes of carbohydrate metabolism, oxido-reduction, and protein processing and degradation. According to their functional categories and cluster analysis, a stress response model of apoplastic proteins has been proposed. These data indicate that the apoplast is important in plant stress signal reception and response.     

Circadian proteomics of the mouse retina

The circadian clock in the retina regulates a variety of physiological phenomena such as disc shedding and melatonin release. Although these events are critical for retinal functions, it is almost unknown how the circadian clock controls the physiological rhythmicity. To gain insight into the processes, we performed a proteomic analysis using 2-DE to find proteins whose levels show circadian changes. Among 415 retinal protein spots, 11 protein spots showed circadian rhythmicity in their intensities. We performed MALDI-TOF MS and NanoLC-MS/MS analyses and identified proteins contained in the 11 spots. The proteins were related to vesicular transport, calcium-binding, protein degradation, metabolism, RNA-binding, and protein foldings, suggesting the clock-regulation of neurotransmitter release, transportation of the membrane proteins, calcium-binding capability, and so on. We also found a rhythmic phosphorylation of N-ethylmaleimide-sensitive fusion protein and identified one of the amino acid residues modified by phosphorylation. These findings provide a new perspective on the relationship between the physiological functions of the retina and the circadian clock system.     

Proteomic analysis of jasmonic acid-regulated proteins in rice leaf blades

Jasmonates play a critical role in plant defense against pathogens through regulation of the expression of defense-related genes. To study the role of jasmonic acid (JA) in the rice self-defense mechanism, a proteomic approach was applied. When 3-week-old rice cv. Java 14 was treated with 100 microM JA for 3 days, numerous necrotic brown spots were observed on the leaf blade. Three-week-old rice was treated with JA and proteins from cytosolic and membrane fractions of leaf blade were separated by two-dimensional polyacrylamide gel electrophoresis. A total of 305 proteins were detected in both cytosolic and membrane fractions. When rice plant was treated with 100 microM JA for 2 days, 12 proteins were up-regulated and 2 proteins were down-regulated. Out of them, 8 proteins were changed in dose dependence manner, while 4 proteins were changed in a time course manner. Among them, pathogenesis-related protein 5 (PR5) and probenazole inducible protein 1 (PBZ1) were significantly induced by 100 microM JA for 2 days. These results suggest that PR5 and PBZ1 are important proteins expressed down-stream of JA signals in rice cv. Java 14.     

Shotgun proteomic analysis for detecting differentially expressed proteins in the reduced culm number rice

To survey protein expression patterns in the reduced culm number (RCN) rice, a comparative shotgun proteomic analysis was conducted. For large-scale protein identification, multidimensional protein identification technology (MudPIT) coupled with pre-fractionation of plant shoot proteins led to the identification of 3004 non-redundant rice proteins. By statistically comparing relative amounts of 1353 reproducibly identified proteins between the RCN rice and the wild-type rice, 44 differentially expressed proteins were detected, where 42 proteins were increased and 2 proteins were decreased in the RCN rice. These proteins appear to have roles in glycolysis, trichloroacetic acid cycle, secondary metabolism, nutrient recycling, and nucleotide metabolism and repair. Consequently, we hypothesized that the RCN rice might fail to maintain sugar nutrient homeostasis. This was confirmed with the observation that the sucrose concentration was increased significantly in the RCN rice compared with the wild-type rice. Also, the RCN rice showed a hypersensitive response to exogenous sucrose treatment.