Qian-Feng Li

Validation of Candidate Reference Genes for the Accurate Normalization of Real-Time Quantitative RT-PCR Data in Rice During Seed Development

Rice seed, a natural storage organ for starch and protein, is also an ideal bioreactor for the production of valuable proteins. Increasingly, studies focused on rice have tried to determine the functions of its genes and also to improve its yield and quality. Real-time RT-PCR is the best available choice at present for gene expression analysis due to its accuracy, sensitivity, and reproducibility. The right choice of reference genes for normalization, however, is a critical precondition for reliable results. In this study, the expression stabilities of nine commonly used housekeeping genes in rice were carefully assessed using the software geNorm. Our results showed that eIF-4a and ACT1 were the most suitable reference genes among almost all the tested samples from two rice varieties, including different temporal and spatial-specific tissues, especially in seeds at different developmental stages. In contrast, 18S and 25S rRNAs, two common reference genes, were found to have the least stable expression. Moreover, it is necessary to use multiple suitable reference genes together for normalization to get a more reliable result in temporal and spatial expression analysis during rice seed development. The validated reference genes were further relied when used to quantify the expression of several genes of interest during rice seed development.

Characterization of expression of the OsPUL gene encoding a pullulanase-type debranching enzyme during seed development and germination in rice.

Starch-debranching enzymes (DBEs) are key enzymes involved in starch metabolism in cereals, having a dual function, in both starch synthesis and degradation. However, their precise roles in this pathway, particularly their expression profiles, remain unclear. In the present study, we performed a quantitative real-time PCR (Q-PCR) analysis of the expression pattern of the OsPUL gene encoding a pullulanase-type DBE in different tissues as well as in seeds at different developmental stages. The results showed that this gene was expressed only in seeds. In addition, the 1177-bp OsPUL promoter sequence was cloned, and some endosperm-specific motifs such as the GCN4 and AACA motifs were observed to exist in this region. The promoter was then fused with the GUS reporter gene and its expression was carefully investigated in transgenic rice. The data from both histochemical and fluorometric analyses showed that the OsPUL promoter was capable of driving the target gene to have a high level of endosperm-specific expression. The OsPUL gene maintained a relatively high expression level during the entire period of seed development, and peaked in the middle and late stages. This observation was very consistent with that of the endogenous transcription analysis by Q-PCR. Furthermore, the seed germination experiment showed that the OsPUL promoter actively functions in the late stage of seed germination. The expression of the OsPUL gene was maintained at a significant level during the entire grain filling period and in the late stage of seed germination, which coincided with its involvement in starch anabolism and catabolism.

Characterization of Grain Quality and Starch Fine Structure of Two Japonica Rice (Oryza Sativa) Cultivars with Good Sensory Properties at Different Temperatures during the Filling Stage

Temperature during the growing season is a critical factor affecting grain quality. High temperatures at grain filling affect kernel development, resulting in reduced yield, increased chalkiness, reduced amylose content, and poor milling quality. Here, we investigated the grain quality and starch structure of two japonica rice cultivars with good sensory properties grown at different temperatures during the filling stage under natural field conditions. Compared to those grown under normal conditions, rice grains grown under hot conditions showed significantly reduced eating and cooking qualities, including a higher percentage of grains with chalkiness, lower protein and amylose contents, and higher pasting properties. Under hot conditions, rice starch contained reduced long-chain amylose (MW 10(7.1) to 10(7.4)) and significantly fewer short-chain amylopectin (DP 5-12) but more intermediate- (DP 13-34) and long- (DP 45-60) chain amylopectin than under normal conditions, as well as higher crystallinity and gelatinization properties.

Biofortification of rice with the essential amino acid lysine: molecular characterization, nutritional evaluation, and field performance

Highlight Marker-free transgenic rice that over-accumulates the essential amino acid lysine has been generated by combining lines with endosperm-specific and constitutive engineering of lysine, and has been evaluated in the field.

A residue substitution in the plastid ribosomal protein L12/AL1 produces defective plastid ribosome and causes early seedling lethality in rice.

The plastid ribosome is essential for chloroplast biogenesis as well as seedling formation. As the plastid ribosome closely resembles the prokaryotic 70S ribosome, many plastid ribosomal proteins (PRPs) have been identified in higher plants. However, their assembly in the chloroplast ribosome in rice remains unclear. In the present study, we identified a novel rice mutant, albino lethal 1 (al1), from a chromosome segment substitution line population. The al1 mutant displayed an albino phenotype at the seedling stage and did not survive past the three-leaf stage. No other apparent differences in plant morphology were observed in the al1 mutant. The albino phenotype of the al1 mutant was associated with decreased chlorophyll content and abnormal chloroplast morphology. Using fine mapping, AL1 was shown to encode the PRPL12, a protein localized in the chloroplasts of rice, and a spontaneous single-nucleotide mutation (C/T), resulting in a residue substitution from leucine in AL1 to phenylalanine in al1, was found to be responsible for the early seedling lethality. This point mutation is located at the L10 interface feature of the L12/AL1 protein. Yeast two-hybrid analysis showed that there was no physical interaction between al1 and PRPL10. In addition, the mutation had little effect on the transcript abundance of al1, but had a remarkable effect on the protein abundance of al1 and transcript abundance of chloroplast biogenesis-related and photosynthesis-related genes. These results provide a first glimpse into the molecular details of L12’s function in rice.

Molecular Structure and Physicochemical Properties of Starches from Rice with Different Amylose Contents Resulting from Modification of OsGBSSI Activity

OsGBSSI, encoded by the Waxy (Wx) gene, is the key enzyme in the synthesis of amylose chains. Transgenic rice lines with various GBSSI activities were previously developed via site-directed mutagenesis of the Wx gene in the glutinous cultivar Guanglingxiangnuo (GLXN). In this study, grain morphology, molecular structure, and physicochemical properties were investigated in four transgenic lines with modified OsGBSSI activity and differences in amylose content. A milky opaque appearance was observed in low- and non-amylose rice grains due to air spaces in the starch granules. Gel permeation chromatography (GPC) and high-performance anion-exchange chromatography (HPAEC) analyses showed that although OsGBSSI can synthesize intermediate and extra-long amylopectin chains, it is mainly responsible for the longer amylose chains. Amylose content was positively correlated with trough viscosity, final viscosity, setback viscosity, pasting time, pasting temperature, and gelatinization temperature and negatively with gel consistency, breakdown viscosity, gelatinization enthalpy, and crystallinity. Overall, the findings suggest that OsGBSSI may be also involved in amylopectin biosynthesis, in turn affecting grain appearance, thermal and pasting properties, and the crystalline structure of starches in the rice endosperm.

GS9 acts as a transcriptional activator to regulate rice grain shape and appearance quality

Identification of grain shape determining genes can facilitate breeding of rice cultivars with optimal grain shape and appearance quality. Here, we identify GS9 (Grain Shape Gene on Chromosome 9) gene by map-based cloning. The gs9 null mutant has slender grains, while overexpression GS9 results in round grains. GS9 encodes a protein without known conserved functional domain. It regulates grain shape by altering cell division. The interaction of GS9 and ovate family proteins OsOFP14 and OsOFP8 is modulated by OsGSK2 kinase, a key regulator of the brassinosteroids signaling pathway. Genetic interaction analysis reveals that GS9 functions independently from other previously identified grain size genes. Introducing the gs9 allele into elite rice cultivars significantly improves grain shape and appearance quality. It suggests potential application of gs9, alone or in combination with other grain size determining genes, in breeding of rice varieties with optimized grain shape.Rice grain shape or size is an important trait associated with both yield and appearance quality. Here, the authors identify GS9 as a negative transcription regulator of slender grain and show it can improve grain shape and appearance independently from other previously identified grain size genes.

A Connection between Lysine and Serotonin Metabolism in Rice Endosperm

Serotonin biosynthesis is dramatically elevated, and closely linked with dark-brown color of the endosperm, in high-lysine rice. Cereal endosperms produce a vast array of metabolites, including the essential amino acid lysine (Lys). Enhanced accumulation of Lys has been achieved via metabolic engineering in cereals, but the potential connection between metabolic engineering and Lys fortification is unclear. In mature seeds of engineered High Free Lysine (HFL) rice (Oryza sativa), the endosperm takes on a characteristic dark-brown appearance. In this study, we use an integrated metabolomic and transcriptomic approach combined with functional validation to elucidate the key metabolites responsible for the dark-brown phenotype. Importantly, we found that serotonin biosynthesis was elevated dramatically and closely linked with dark-brown endosperm color in HFL rice. A functional connection between serotonin and endosperm color was confirmed via overexpression of TDC3, a key enzyme of serotonin biosynthesis. Furthermore, we show that both the jasmonate signaling pathway and TDC expression were strongly induced in the late stage of endosperm development of HFL rice, coinciding with serotonin accumulation and dark-brown pigmentation. We propose a model for the metabolic connection between Lys and serotonin metabolism in which elevated 2-aminoadipate from Lys catabolism may play a key role in the connection between the jasmonate signaling pathway, serotonin accumulation, and the brown phenotype in rice endosperm. Our data provide a deeper understanding of amino acid metabolism in rice. In addition, the finding that both Lys and serotonin accumulate in HFL rice grains should promote efforts to create a nutritionally favorable crop.

The brassinosteroid-regulated transcription factors BZR1/BES1 function as a coordinator in multisignal-regulated plant growth

BZR1 and BES1 are key transcription factors of brassinosteroid (BR) signaling and represent the integration node of numerous signaling cascades. Their direct target genes have been identified, and BZR1/BES1-DNA interactions have been experimentally verified. Importantly, BZR1/BES1 also integrate different growth and development events via direct protein-protein interactions. For instance, DELLAs, PIFs, ARF6, and PKL, all directly interact with BZR1/BES1, forming a BZR1/BES1-centered regulatory network to coordinate cell elongation. By dissecting various BZR1/BES1-mediated BR responses, the concept that BZR1/BES1 act as an integration hub in multisignal-regulated plant growth and development was developed. The regulation of BZR1/BES1 is dynamic and multifaceted, including phosphorylation status, activity, and stability. Moreover, certain epigenetic modification mechanisms are involved in BZR1/BES1s regulation of gene expression. Herein, we review recent advances in BZR1/BES1-mediated molecular connections between BR and other pathways, highlighting the central role of the BZR1/BES1 interactome in optimizing plant growth and development.

Light involved regulation of BZR1 stability and phosphorylation status to coordinate plant growth in Arabidopsis

Light and brassinosteroid (BR) are master environmental stimulus and endogenous cue for plant growth and development respectively. Great progress has been made in elucidating the molecular mechanisms on the cross-talk between light and BR. However, little is known about how BZR1, the pivotal integration node, is regulated by light and dark. Here, we demonstrated that an intact BR signaling pathway is essential for dark-induced hypocotyl elongation. Consequent expression assay showed that light–dark switch affected BZR1 phosphorylation and accumulation. Moreover, blocking the 26S proteasome pathway promoted the accumulation of both phosphorylated and dephosphorylated BZR1 proteins. Restriction of new protein biosynthesis had multiple effects on BZR1 phosphorylation status and stability, relying on the availability of light and the 26S proteasome pathways. Furthermore, sugar treatment strikingly enhanced the accumulation of total BZR1 under either light or dark conditions, likely by repressing transcript abundance of MAX2, a gene encoding an E3 ligase for BZR1. Finally, light-regulated phosphorylation change of BZR1 requires the existence of endogenous BR as well as functional BIN2 and protein phosphatase 2A (PP2A). Taken together, our results depicted a light-involved complex regulation network of BZR1 stability and phosphorylation status.