Ruey Hua Lee

A novel alkaline α-galactosidase gene is involved in rice leaf senescence

We previously isolated and identified numerous senescence-associated genes (SAGs) in rice leaves. Here we characterized the structure and function of an SAG-Osh69 encoding alkaline α-galactosidase that belongs to a novel family of glycosyl hydrolases. Osh69 is a single-copy gene composed of 13 exons located on rice chromosome 8. The expression level of Osh69 is not only up-regulated during natural leaf senescence but also induced rapidly by darkness, hormones (methyl jasmonic acid, salicylic acid), and stresses (H2O2 and wounding). The recombinant Osh69 protein over-expressed in Escherichia coli has displayed optimal α-galactosidase activity at pHxa08.0. The enzyme showed good hydrolytic activities towards α-1,6-galactosyl oligosaccharides and galactolipid digalactosyl diacylglycerol. Immunoelectron microscopic analysis demonstrates that Osh69 is specifically localized in the chloroplasts of senescing leaves. These findings strongly suggest an important role for Osh69 in the degradation of chloroplast galactolipids during leaf senescence. The nucleotide sequence data reported will appear in the GenBank Nucleotide Sequence Database under the accession number AF251068.

Molecular characterization of a novel senescence-associated gene SPA15 induced during leaf senescence in sweet potato.

The structure and expression of a novel senescence-associated gene (SPA15) of sweet potato were characterized. The protein coding region of the gene consists of 13 exons encoding 420 amino acids. Apparent homologues of this sweet potato gene are found in a variety of dicot and monocot plants, but not in animals or microorganisms. Examination of the expression patterns of the SPA15gene in sweet potato reveals that the transcripts of SPA15 are specifically induced in the senescing leaves, and the temporal profile of SPA15 protein accumulation is correlated with that of SPA15 transcripts. Studies on the distribution of SPA15 homologue in rice plants also indicate that SPA15 homologue is up-regulated specifically in senescing rice leaves. Treatment of detached sweet potato leaves with phytohormones including ethylene, methyl jasmonate, salicylic acid and abscisic acid resulted in a high-level induction of SPA15. Immunoelectron microscopic analysis demonstrates that SPA15 is specifically associated with the cell wall. The potential role for SPA15 during leaf senescence is discussed.

Early signalling pathways in rice roots under vanadate stress.

Vanadate is beneficial to plant growth at low concentration. However, plant exposure to high concentrations of vanadate has been shown to arrest cell growth and lead to cell death. We are interested in understanding the signalling pathways of rice roots in response to vanadate stress. In this study, we demonstrated that vanadate induced rice root cell death and suppressed root growth. In addition, we found that vanadate induced ROS accumulation, increased lipid peroxidation and elicited a remarkable increase of MAPKs and CDPKs activities in rice roots. In contrast, pre-treatment of rice roots with ROS scavenger (sodium benzoate), serine/threonine protein phosphatase inhibitor (endothall), and CDPK antagonist (W7), reduced the vanadate-induced MAPKs activation. Furthermore, the expression of a MAPK gene (OsMPK3) and four tyrosine phosphatase genes (OsDSP3, OsDSP5, OsDSP6, and OsDSP10) were regulated by vanadate in rice roots. Collectively, these results strongly suggest that ROS, protein phosphatase, and CDPK may function in the vanadate-triggered MAPK signalling pathway cause cell death and retarded growth in rice roots.

Alkaline α‐galactosidase degrades thylakoid membranes in the chloroplast during leaf senescence in rice

Here, we studied the functional role of a chloroplast alkaline alpha-galactosidase (OsAkalphaGal) in the breakdown of thylakoid membranes during rice (Oryza sativa) leaf senescence. We assayed the enzyme activity of recombinant OsAkalphaGal with different natural substrates and examined the effect of ectopic OsAkalphaGal expression in rice plants. Recombinant OsAkalphaGal showed at least a two-fold greater substrate-binding affinity and a 10-fold greater turnover rate to galactolipid digalactosyl diacylglycerol than the raffinose family of oligosaccharides (verbascose, stachyose, raffinose) and melibiose. The OsAkalphaGal null mutant (osakalphagal) displayed a delayed leaf senescence phenotype. OsAkalphaGal complementation in osakalphagal recovered OsAkalphaGal expression and showed a senescence phenotype similar to that of wild-type plants. Transgenic plants overexpressing OsAkalphaGal (UbiP-OsAkalphaGal) exhibited retarded plant growth and development, and showed a pale-green phenotype coupled with a reduced chlorophyll content to 42% in newly unfolded leaves. UbiP-OsAkalphaGal leaves also showed a 29-fold increase in alkaline alpha-galactosidase activity compared with wild-type leaves. An ultrastructural study of Ubi-OsAkalphaGal chloroplasts in newly unfolded leaves revealed abnormal grana organization. Our findings strongly suggest that OsAkalphaGal is a thylakoid membrane-degrading enzyme involved in the degradation of digalactosyl diacylglycerol during rice leaf senescence.

Deciphering mycorrhizal fungi in cultivated Phalaenopsis microbiome with next-generation sequencing of multiple barcodes

Identifying the species composition of a microbial ecosystem is often hampered by difficulties in culturing the organisms and in the low sequencing depth of traditional DNA barcoding. Metagenomic analysis, a huge-scale nucleotide-sequence-based tool, can overcome such difficulties. In this study, Sanger sequencing of 500 nrITS clones uncovered 29 taxa of 19 fungal genera, whereas metagenomics with next-generation sequencing identified 512 operational taxonomic units (OTUs) for ITS1/2 and 364 for ITS3/4. Nevertheless, high throughput sequencing of PCR amplicons of ITS1/2, ITS3/4, nrLSU-LR, nrLSU-U, mtLSU, and mtATP6, all with at least 1,300× coverage and about 21 million reads in total, yielded a very diverse fungal composition. The fact that 74xa0% of the OTUs were exclusively uncovered with single barcodes indicated that each marker provided its own insights into the fungal flora. To deal with the high heterogeneity in the data and to integrate the information on species composition across barcodes, a rank-scoring strategy was developed. Accordingly, 205 genera among 64 orders of fungi were identified in healthy Phalaenopsis roots. Of the barcodes utilized, ITS1/2, ITS3/4, and nrLSU-U were the most competent in uncovering the fungal diversity. These barcodes, though detecting different compositions likely due to primer preference, provided complementary and comprehensive power in deciphering the microbial diversity, especially in revealing rare species.

Volatilized myrcene inhibits growth and activates defense responses in rice roots

We aimed to analyze the phytotoxic effect of the allelopathic volatile myrcene on rice seedlings, particularly root growth, reactive oxygen species (ROS) generation, and activity of antioxidant enzymes and defense-related genes. Myrcene inhibited the growth of rice seedlings. The activity of ROS and lipoxygenase (LOX) was significantly increased with increasing myrcene concentration in roots and that of antioxidant enzymes was altered dose-dependently. The activity of superoxide dismutase and peroxidase was changed at 24xa0h after myrcene treatment in rice roots. Furthermore, the mRNA expression of three mitogen-activated protein kinase genes (OsMPK2, 3, and 4), WRKY transcription factor gene (OsWRKY71), LOX gene (OsLOX3), pathogenesis-related protein 1b gene (OsPR1b) and cyclin-dependent protein kinase inhibitor (OsCKI) was upregulated and that of cyclin genes OsCycA1;1, OsCycB1;1 and OsCycD1;1 was downregulated with myrcene treatment in rice roots. These results may provide new insights into the molecular basis of the allelopathic volatile response in plants.

The mitochondrial DNA markers for distinguishing Phalaenopsis species and revealing maternal phylogeny

Moth orchids (Phalaenopsis) are among the top-traded blooming potted plants in the world. To explore mitochondrial DNA (mtDNA) markers for species identification, we located simple sequence repeats in the mtDNA of Phalaenopsis aphrodite subsp. formosana and then pre-screened them for polymorphic markers by their comparison with corresponding mtDNA regions of P. equestris. The combination of 13 selected markers located in intergenic spacers could unambiguously distinguish 15 endemic moth orchids. Five most variable markers with polymorphic information content (PIC) ≥ 0.7 could be combined to classify 18 of 19 endemic moth orchids including parental strains most commonly used in breeding programs. The sequences of four selected mtDNA regions were highly variable, and one region (MT2) could be used to completely distinguish 19 endemic moth orchids. Though mitochondrial introns were highly conserved among moth orchids, evolutionary hotspots, such as variable simple sequence repeats and minisatellite repeats, were identified as useful markers. Furthermore, a marker technology was applied to reveal the maternal inheritance mode of mtDNA in the moth orchids. Moreover, phylogenetic analysis indicates that the mtDNA was nonmonophyletic below the Phalaenopsis genus. In summary, we have revealed a set of mtDNA markers that could be used for identification and phylogenetic study of Phalaenopsis orchids.

The blue fluorescent protein from Vibrio vulnificus CKM-1 is a useful reporter for plant research

BackgroundThe mBFP is an improved variant of NADPH-dependent blue fluorescent protein that was originally identified from the non-bioluminescent pathogenic bacteria Vibrio vulnificus CKM-1. To explore the application of mBFP in plants, the mBFP gene expression was driven by one of the three promoters, namely, leaf-specific (RbcS), hypoxia-inducible (Adh) or auxin-inducible (DR5) promoters, in different plant tissues such as leaves, roots and flowers under diverse treatments. In addition, the expressed mBFP protein was targeted to five subcellular compartments such as cytosol, endoplasmic reticulum, apoplast, chloroplast and mitochondria, respectively, in plant cells.ResultsWhen the mBFP was transiently expressed in the tobacco leaves and floral tissues of moth orchid, the cytosol and apoplast exhibited brighter blue fluorescence than other compartments. The recombinant mBFP-mS1C fusion protein exhibited enhanced fluorescence intensity that was correlated with more abundant RNA transcripts (1.8 fold) as compared with a control. In the root tips of horizontally grown transgenic Arabidopsis, mBFP could be induced as a reporter under hypoxia condition. Furthermore, the mBFP was localized to the expected subcellular compartments, except that dual targeting was found when the mBFP was fused with the mitochondria-targeting signal peptide. Additionally, the brightness of mBFP blue fluorescence was correlated with NADPH concentration.ConclusionThe NADPH-dependent blue fluorescent protein could serve as a useful reporter in plants under aerobic or hypoxic condition. However, to avoid masking the mitochondrial targeting signal, fusing mBFP as a fusion tag in the C-terminal will be better when the mBFP is applied in mitochondria trafficking study. Furthermore, mBFP might have the potential to be further adopted as a NADPH biosensor in plant cells. Future codon optimization of mBFP for plants could significantly enhance its brightness and expand its potential applications.

Integrating Early Transcriptomic Responses to Rhizotoxins in Rice (Oryza sativa. L.) Reveals Key Regulators and a Potential Early Biomarker of Cadmium Toxicity

As sessile organisms, plants were constantly challenged with biotic and abiotic stresses. Transcriptional activation of stress-responsive genes is a crucial part of the plant adaptation to environmental changes. Here, early response of rice root to eight rhizotoxic stressors: arsenate, copper, cadmium, mercury, chromate, vanadate, ferulic acid and juglone, was analyzed using published microarray data. There were 539 general stress response (GSR) genes up-regulated under all eight treatments, including genes related to carbohydrate metabolism, phytohormone balance, and cell wall structure. Genes related to transcriptional coactivation showed higher Ka/Ks ratio compared to the other GSR genes. Network analysis discovered complicated interaction within GSR genes and the most connected signaling hubs were WRKY53, WRKY71, and MAPK5. Promoter analysis discovers enriched SCGCGCS cis-element in GSR genes. Moreover, GSR genes tend to be intronless and genes with shorter total intron length were induced in a higher level. Among genes uniquely up-regulated by a single stress, a phosphoenolpyruvate carboxylase kinase (PPCK) was identified as a candidate biomarker for detecting cadmium contamination. Our findings provide insights into the transcriptome dynamics of molecular response of rice to different rhizotoxic stress and also demonstrate potential use of comparative transcriptome analysis in identifying a novel potential early biomarker.