Liang-Jwu Chen

A Novel Class of Gibberellin 2-Oxidases Control Semidwarfism, Tillering, and Root Development in Rice

Gibberellin 2-oxidases (GA2oxs) regulate plant growth by inactivating endogenous bioactive gibberellins (GAs). Two classes of GA2oxs inactivate GAs through 2β-hydroxylation: a larger class of C19 GA2oxs and a smaller class of C20 GA2oxs. In this study, we show that members of the rice (Oryza sativa) GA2ox family are differentially regulated and act in concert or individually to control GA levels during flowering, tillering, and seed germination. Using mutant and transgenic analysis, C20 GA2oxs were shown to play pleiotropic roles regulating rice growth and architecture. In particular, rice overexpressing these GA2oxs exhibited early and increased tillering and adventitious root growth. GA negatively regulated expression of two transcription factors, O. sativa homeobox 1 and TEOSINTE BRANCHED1, which control meristem initiation and axillary bud outgrowth, respectively, and that in turn inhibited tillering. One of three conserved motifs unique to the C20 GA2oxs (motif III) was found to be important for activity of these GA2oxs. Moreover, C20 GA2oxs were found to cause less severe GA-defective phenotypes than C19 GA2oxs. Our studies demonstrate that improvements in plant architecture, such as semidwarfism, increased root systems and higher tiller numbers, could be induced by overexpression of wild-type or modified C20 GA2oxs.

Enhanced Methionine and Cysteine Levels in Transgenic Rice Seeds by the Accumulation of Sesame 2S Albumin

A chimeric gene encoding a precursor polypeptide of sesame 2S albumin, a sulfur-rich seed storage protein, was expressed in transgenic rice plants under the control of the glutelin promoter with the aim of improving the nutritive value of rice. Rice grains harvested from the first generation of ten different transformed lines inherited the transgene, and the accumulated sesame 2S albumin was presumably processed correctly as its mature form in sesame seed. This transgene was specifically expressed in maturing rice seeds with its encoded sesame 2S albumin exclusively accumulated in the seeds. The crude protein content in rice grains from five putative homozygous lines was increased by 0.64-3.54%, and the methionine and cysteine contents of these transgenic rice grains were respectively elevated by 29-76% and 31-75% compared with those of wild-type rice grains.

Serotonin accumulation in transgenic rice by over-expressing tryptophan decarboxlyase results in a dark brown phenotype and stunted growth

A mutant M47286 with a stunted growth, low fertility and dark-brown phenotype was identified from a T-DNA-tagged rice mutant library. This mutant contained a copy of the T-DNA tag inserted at the location where the expression of two putative tryptophan decarboxlyase genes, TDC-1 and TDC-3, were activated. Enzymatic assays of both recombinant proteins showed tryptophan decarboxlyase activities that converted tryptophan to tryptamine, which could be converted to serotonin by a constitutively expressed tryptamine 5′ hydroxylase (T5H) in rice plants. Over-expression of TDC-1 and TDC-3 in transgenic rice recapitulated the stunted growth, dark-brown phenotype and resulted in a low fertility similar to M47286. The degree of stunted growth and dark-brown color was proportional to the expression levels of TDC-1 and TDC-3. The levels of tryptamine and serotonin accumulation in these transgenic rice lines were also directly correlated with the expression levels of TDC-1 and TDC-3. A mass spectrometry assay demonstrated that the dark-brown leaves and hulls in the TDC-overexpressing transgenic rice were caused by the accumulation of serotonin dimer and that the stunted growth and low fertility were also caused by the accumulation of serotonin and serotonin dimer, but not tryptamine. These results represent the first evidence that over-expression of TDC results in stunted growth, low fertility and the accumulation of serotonin, which when converted to serotonin dimer, leads to a dark brown plant color.

Different effects on triacylglycerol packaging to oil bodies in transgenic rice seeds by specifically eliminating one of their two oleosin isoforms

Expression of OLE16 and OLE18, two oleosin isoforms in oil bodies of rice seeds, was suppressed by RNA interference. Electron microscopy revealed a few large, irregular oil clusters in 35S::ole16i transgenic seed cells, whereas accumulated oil bodies in 35S::ole18i transgenic seed cells were comparable to or slightly larger than those in wild-type seed cells. Large and irregular oil clusters were observed in cells of double mutant seeds. These unexpected differences observed in oil bodies of 35S::ole16i and 35S::ole18i transgenic seeds were further analyzed. In comparison to wild-type plants, OLE18 levels were reduced to approximately 40% when OLE16 was completely eliminated in 35S::ole16i transgenic plants. In contrast, OLE16 was reduced to only 80% of wild-type levels when OLE18 was completely eliminated in 35S::ole18i transgenic plants. While the triacylglycerol content of crude seed extracts of 35S::ole16i and 35S::ole18i transgenic seeds was reduced to approximately 60% and 80%, respectively, triacylglycerol in isolated oil bodies was respectively reduced to 45% and 80% in accordance with the reduction of their oleosin contents. Oil bodies isolated from both 35S::ole16i and 35S::ole18i transgenic seeds were found to be of comparable size and stability to those isolated from wild-type rice seeds, although they were merely sheltered by a single oleosin isoform. The drastic difference between the triacylglycerol contents of crude seed extracts and isolated oil bodies from 35S::ole16i transgenic plants could be attributed to the presence of large, unstable oil clusters that were sheltered by insufficient amounts of oleosin and therefore could not be isolated together with stable oil bodies.

Genetic resources offer efficient tools for rice functional genomics research

Rice is an important crop and major model plant for monocot functional genomics studies. With the establishment of various genetic resources for rice genomics, the next challenge is to systematically assign functions to predicted genes in the rice genome. Compared with the robustness of genome sequencing and bioinformatics techniques, progress in understanding the function of rice genes has lagged, hampering the utilization of rice genes for cereal crop improvement. The use of transfer DNA (T-DNA) insertional mutagenesis offers the advantage of uniform distribution throughout the rice genome, but preferentially in gene-rich regions, resulting in direct gene knockout or activation of genes within 20-30 kb up- and downstream of the T-DNA insertion site and high gene tagging efficiency. Here, we summarize the recent progress in functional genomics using the T-DNA-tagged rice mutant population. We also discuss important features of T-DNA activation- and knockout-tagging and promoter-trapping of the rice genome in relation to mutant and candidate gene characterizations and how to more efficiently utilize rice mutant populations and datasets for high-throughput functional genomics and phenomics studies by forward and reverse genetics approaches. These studies may facilitate the translation of rice functional genomics research to improvements of rice and other cereal crops.

Identification of the transcription start site for the spinach chloroplast serine tRNA gene

Deleting part of the 3′ end of the spinach chloroplast serine tRNA coding region, which destroyed the proper folding of its RNA transcript and resulted in the inhibition of tRNA processing, allowed the detection of a serine tRNA primary transcript. The transcription start site for this primary transcript, synthesized from the internal promoter, was mapped to −12 upstream from the mature tRNA coding region. Transcription analysis with various 5′ deletion mutants suggested that the AT‐rich region between −31 and −11, immediately upstream of the serine tRNA transcription start site, affects the transcription efficiency, and possibly the selection of transcription start site. Identification of the transcription start site for the spinach chloroplast serine tRNA gene in this study represents the first example of 5′ end mapping of a tRNA precursor transcribed from chloroplast tRNA genes containing an internal promoter.

Ectopic expression of specific GA2 oxidase mutants promotes yield and stress tolerance in rice

Summary A major challenge of modern agricultural biotechnology is the optimization of plant architecture for enhanced productivity, stress tolerance and water use efficiency (WUE). To optimize plant height and tillering that directly link to grain yield in cereals and are known to be tightly regulated by gibberellins (GAs), we attenuated the endogenous levels of GAs in rice via its degradation. GA 2‐oxidase (GA2ox) is a key enzyme that inactivates endogenous GAs and their precursors. We identified three conserved domains in a unique class of C20 GA2ox, GA2ox6, which is known to regulate the architecture and function of rice plants. We mutated nine specific amino acids in these conserved domains and observed a gradient of effects on plant height. Ectopic expression of some of these GA2ox6 mutants moderately lowered GA levels and reprogrammed transcriptional networks, leading to reduced plant height, more productive tillers, expanded root system, higher WUE and photosynthesis rate, and elevated abiotic and biotic stress tolerance in transgenic rice. Combinations of these beneficial traits conferred not only drought and disease tolerance but also increased grain yield by 10–30% in field trials. Our studies hold the promise of manipulating GA levels to substantially improve plant architecture, stress tolerance and grain yield in rice and possibly in other major crops.

Isolation and Characterization of New Maize B Sequences from a Microdissected Library

Understanding the evolution of the maize B chromosome requires insight into the molecular organization of a large number of B clones, which can be potentially obtained by microdissection of the chromosome. Yet, the microdissection protocols currently available are ineffective for a large-scale isolation. In an attempt to improve its efficiency, a protocol was adopted to screen a microdissected B library with probes prepared from the degenerate oligonucleotide primed-PCR product of genomic DNA. This protocol resulted in 59 new B clones, most of which were highly repetitive sequences located in various B regions but mostly in the heterochromatic blocks of the long arm. They also appeared in A chromosomes. Twenty-four of these were retrotransposons, ten knob, 18 noncoding sequences, and seven unknown sequences. The implication of the new B sequences on the B evolution is discussed.

A proteomic study of rice cultivar TNG67 and its high aroma mutant SA0420.

Fragrance is a very important economic trait for rice cultivars. To identify the aroma genes in rice, we performed a proteomics analysis of aroma-related proteins between Tainung 67 (TNG67) and its high aroma mutant SA0420. Seventeen of the differentially identified proteins were close related with the aroma phenotype of SA0420. Among them, 9 were found in leaves and 8 were found in grains. One protein (L3) was identified as the chloroplastic glyceraldehyde-3-phosphate dehydrogenase B (OsGAPDHB) which was less abundant in SA0420 than TNG67. Sequence analysis demonstrated that this protein in SA0420 carries a P425S mutation in the C-terminal extension domain, which might hinder the formation of holoenzyme, thereby changing the profile of aroma compounds. The protein profile of OsGAPDHB showed only a weak correlation to its transcription profile. This result indicated that the reduction of OsGAPDHB in SA0420 is regulated by post-translational processes and can only be analyzed by proteomics approach. Transgenic lines suppressing OsGAPDHB through RNAi harbored more fragrance than TNG67 but less than SA0420. With betaine-aldehyde dehydrogenase as the only fragrance gene identified in rice to date, OsGAPDHB may serve as the second protein known to contribute to the aroma phenotype.

The promoter and the 5′-untranslated region of rice metallothionein OsMT2b gene are capable of directing high-level gene expression in germinated rice embryos

Key messageCritical regions within the rice metallothioneinOsMT2bgenepromoter are identified and the 5′-untranslated region (5′-UTR) is found essential for the high-level promoter activity in germinated transgenic rice embryos.AbstractMany metallothionein (MT) genes are highly expressed in plant tissues. A rice subfamily p2 (type 2) MT gene, OsMT2b, has been shown previously to exhibit the most abundant gene expression in young rice seedling. In the present study, transient expression assays and a transgenic approach were employed to characterize the expression of the OsMT2b gene in rice. We found that the OsMT2b gene is strongly and differentially expressed in germinated rice embryos during seed germination and seedling development. Histochemical staining analysis of transgenic rice carrying OsMT2b::GUS chimeric gene showed that high-level GUS activity was detected in germinated embryos and at the meristematic part of other tissues during germination. Deletion analysis of the OsMT2b promoter revealed that the 5′-flanking region of the OsMT2b between nucleotides −351 and −121 relative to the transcriptional initiation site is important for promoter activity in rice embryos, and this region contains the consensus sequences of G box and TA box. Our study demonstrates that the 5′-untranslated region (5′-UTR) of OsMT2b gene is not only necessary for the OsMT2b promoter activity, but also sufficient to augment the activity of a minimal promoter in both transformed cell cultures and germinated transgenic embryos in rice. We also found that addition of the maize Ubi intron 1 significantly enhanced the OsMT2b promoter activity in rice embryos. Our studies reveal that OsMT2b351-ubi(In) promoter can be applied in plant transformation and represents potential for driving high-level production of foreign proteins in transgenic rice.