Grain yield is controlled by quantitative trait loci (QTLs) derived from natural variations in many crop plants. Here we report the molecular characterization of a major rice grain yield QTL that acts through the determination of panicle architecture. The dominant allele at the DEP1 locus is a gain-of-function mutation causing truncation of a phosphatidylethanolamine-binding protein-like domain protein. The effect of this allele is to enhance meristematic activity, resulting in a reduced length of the inflorescence internode, an increased number of grains per panicle and a consequent increase in grain yield. This allele is common to many Chinese high-yielding rice varieties and likely represents a relatively recent introduction into the cultivated rice gene pool. We also show that a functionally equivalent allele is present in the temperate cereals and seems to have arisen before the divergence of the wheat and barley lineages.
The drive toward more sustainable agriculture has raised the profile of crop plant nutrient-use efficiency. Here we show that a major rice nitrogen-use efficiency quantitative trait locus (qNGR9) is synonymous with the previously identified gene DEP1 (DENSE AND ERECT PANICLES 1). The different DEP1 alleles confer different nitrogen responses, and genetic diversity analysis suggests that DEP1 has been subjected to artificial selection during Oryza sativa spp. japonica rice domestication. The plants carrying the dominant dep1-1 allele exhibit nitrogen-insensitive vegetative growth coupled with increased nitrogen uptake and assimilation, resulting in improved harvest index and grain yield at moderate levels of nitrogen fertilization. The DEP1 protein interacts in vivo with both the Gα (RGA1) and Gβ (RGB1) subunits, and reduced RGA1 or enhanced RGB1 activity inhibits nitrogen responses. We conclude that the plant G protein complex regulates nitrogen signaling and modulation of heterotrimeric G protein activity provides a strategy for environmentally sustainable increases in rice grain yield.
The phosphatidylethanolamine (PE)-binding proteins (PEBPs) are an evolutionarily conserved family of proteins with pivotal biological functions. Here we describe the cloning and functional characterization of a novel family member, human phosphatidylethanolaminebinding protein 4 (hPEBP4). hPEBP4 is expressed in most human tissues and highly expressed in tumor cells. Its expression in tumor cells is further enhanced upon tumor necrosis factor (TNF) ␣ treatment, whereas hPEBP4 normally co-localizes with lysosomes, TNF␣ stimulation triggers its transfer to the cell membrane, where it binds to Raf-1 and MEK1. L929 cells overexpressing hPEBP4 are resistant to both TNF␣-induced ERK1/2, MEK1, and JNK activation and TNF␣-mediated apoptosis. Co-precipitation and in vitro protein binding assay demonstrated that hPEBP4 interacts with Raf-1 and MEK1. A truncated form of hPEBP4, lacking the PE-binding domain, maintains lysosomal co-localization but has no effect on cellular responses to TNF␣. Given that MCF-7 breast cancer cells expressed hPEBP4 at a high level, small interfering RNA was used to silence the expression of hPEBP4. We demonstrated that down-regulation of hPEBP4 expression sensitizes MCF-7 breast cancer cells to TNF␣-induced apoptosis. hPEBP4 appears to promote cellular resistance to TNF-induced apoptosis by inhibiting activation of the Raf-1/MEK/ERK pathway, JNK, and PE externalization, and the conserved region of PE-binding domain appears to play a vital role in this biological activity of hPEBP4.The phosphatidylethanolamine-binding protein (PEBP) 1 family consists of a number of 21-23-kDa basic proteins, first identified in bovine brain, with preferential in vitro affinity for phosphatidylethanolamine, a component of the cell membrane. This family is an evolutionarily conserved group found in species of flowering plants (Antirrhinum (1)), parasites (Plasmodium falciparium (2)), nematodes (Toxocara canis (3)), insects (Drosophila melanogaster (4)), and mammals, including cattle, monkeys, and humans (5). A number of functions have been suggested for the mammalian PEBP proteins, including lipid binding and inhibition of serine proteases (6). These proteins can also act as precursors for a bioactive peptide HCNP (hippocampal cholinergic neurostimulating peptide), important in hippocampus development (5). Plant PEBP homologues are involved in the control of a morphogenic switch between shoot growth and flower structures (7). Yeast two-hybrid screen analysis has shown that human PEBP1 (hPEBP1, also called Raf kinase inhibitory protein or RKIP) acts as a suppressor of Raf-1 kinase activity and mitogen-activated protein kinase signaling in fibroblasts via its ability to sequester and inactivate Raf-1 and MEK1 (8, 9). Both Raf-1 and MEK bind to the highly conserved phosphatidylethanolamine-binding domain of hPEBP; hPEBP induces dissociation of Raf-1⅐MEK complexes and behaves as a competitive inhibitor of MEK phosphorylation. Mapping of the binding domains has shown that MEK and Raf-1 bind to overlapping sites in hPEBP...
In an attempt to determine the adaptation strategy to phosphorous (Pi) deficiency in oilseed rape, comparative proteome analyses were conducted to investigate the differences of metabolic changes in two oilseed rape genotypes with different tolerance to low phosphorus (LP). Generally in either roots or leaves, there existed few low phosphorus (LP)-induced proteins shared in the two lines. The LP-tolerant genotype 102 maintained higher Pi concentrations than LP-sensitive genotype 105 when growing hydroponically under the 5-μM phosphorus condition. In 102 we observed the downregulation of the proteins related to gene transcription, protein translation, carbon metabolism, and energy transfer in leaves and roots, and the downregulation of proteins related to leaf growth and root cellular organization. But the proteins related to the formation of lateral root were upregulated, such as the auxin-responsive family proteins in roots and the sucrose-phosphate synthase-like protein in roots and leaves. On the other hand, the LP-sensitive genotype 105 maintained the low level of Pi concentrations and suffered high oxidative pressure under the LP condition, and stress-shocking proteins were pronouncedly upregulated such as the proteins for signal transduction, gene transcription, secondary metabolism, universal stress family proteins, as well as the proteins involved in lipid oxygenation and the disease resistance in both leaves and roots. Although the leaf proteins for growth in 105 were downregulated, the protein expressions in roots related to glycolysis and tricarboxylic acid (TCA) cycle were enhanced to satisfy the requirement of organic acid secretion.
Inflorescence branching is a key agronomic trait determining rice yield. The primary branch of the ancestral wild rice (Oryza rufipogon Griff.) bears few grains, due to minimal secondary branching. By contrast, Oryza sativa cultivars have been selected to produce large panicles with more secondary branches. Here we showed that the CONTROL OF SECONDARY BRANCH 1 (COS1) gene, which is identical to FRIZZY PANICLE (FZP), plays an important role in the key transition from few secondary branches in wild rice to more secondary branches in domesticated rice cultivars. A 4-bp tandem repeat deletion approximately 2.7 kb upstream of FZP may affect the binding activities of auxin response factors to the FZP promoter, decrease the expression level of FZP and significantly enhance the number of secondary branches and grain yield in cultivated rice. Functional analyses showed that NARROW LEAF 1 (NAL1), a trypsin-like serine and cysteine protease, interacted with FZP and promoted its degradation. Consistently, downregulating FZP expression or upregulating NAL1 expression in the commercial cultivar Zhonghua 17 increased the number of secondary branches per panicle, grain number per panicle and grain yield per plant. Our findings not only provide insights into the molecular mechanism of increasing grain number and yield during rice domestication, but also offer favorable genes for improving the grain yield of rice.
The modification of plant architecture is a crucial target in rice domestication and modern genetic improvement. Although several genes regulating rice plant architecture have been characterized, the molecular mechanisms underlying rice plant architecture domestication remain largely unclear. Here we show that the inclined tiller growth in wild rice is controlled by a single dominant gene, TILLER INCLINED GROWTH 1 (TIG1), which is located on chromosome 8 and encodes a TCP transcriptional activator. TIG1 is primarily expressed in the adaxial side of the tiller base, promotes cell elongation, and enlarges the tiller angle in wild rice. Variations in the TIG1 promoter of indica cultivars (tig1 allele) resulted in decreased expression of TIG1 in the adaxial side of tiller base and reduced cell length and tiller angle, leading to the transition from inclined tiller growth in wild rice to erect tiller growth during rice domestication. TIG1 positively regulates the expression of EXPA3, EXPB5, and SAUR39 to promote cell elongation and increase the tiller angle. Selective sweep analysis revealed that the tig1 allele was selected in indica cultivars by human beings. The cloning and characterization of TIG1 supports a new scenario of plant architecture evolution in rice.
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