Joon Ki Hong

Genome-wide identification of glucosinolate synthesis genes in Brassica rapa.

Glucosinolates play important roles in plant defense against herbivores and microbes, as well as in human nutrition. Some glucosinolate‐derived isothiocyanate and nitrile compounds have been clinically proven for their anticarcinogenic activity. To better understand glucosinolate biosynthesis in Brassica rapa, we conducted a comparative genomics study with Arabidopsis thaliana and identified total 56 putative biosynthetic and regulator genes. This established a high colinearity in the glucosinolate biosynthesis pathway between Arabidopsis and B. rapa. Glucosinolate genes in B. rapa share 72–94% nucleotide sequence identity with the Arabidopsis orthologs and exist in different copy numbers. The exon/intron split pattern of B. rapa is almost identical to that of Arabidopsis, although inversion, insertion, deletion and intron size variations commonly occur. Four genes appear to be nonfunctional as a result of the presence of a frame shift mutation and retrotransposon insertion. At least 12 paralogs of desulfoglucosinolate sulfotransferase were found in B. rapa, whereas only three were found in Arabidopsis. The expression of those paralogs was not tissue‐specific but varied greatly depending on B. rapa tissue types. Expression was also developmentally regulated in some paralogs but not in other paralogs. Most of the regulator genes are present as triple copies. Accordingly, glucosinolate synthesis and regulation in B. rapa appears to be more complex than that of Arabidopsis. With the isolation and further characterization of the endogenous genes, health‐beneficial vegetables or desirable animal feed crops could be developed by metabolically engineering the glucosinolate pathway.

Regulation of seed germination and seedling growth by an Arabidopsis phytocystatin isoform, AtCYS6

Phytocystatins are cysteine proteinase inhibitors in plants that are implicated in the endogenous regulation of protein turnover and defense mechanisms against insects and pathogens. A cDNA encoding a phytocystatin called AtCYS6 (Arabidopsis thaliana phytocystatin6) has been isolated. We show that AtCYS6 is highly expressed in dry seeds and seedlings and that it also accumulates in flowers. The persistence of AtCYS6 protein expression in seedlings was promoted by abscisic acid (ABA), a seed germination and post-germination inhibitory phytohormone. This finding was made in transgenic plants bearing an AtCYS6 promoter–β-glucuronidase (GUS) reporter construct, where we found that expression from the AtCYS6 promoter persisted after ABA treatment but was reduced under control conditions and by gibberellin4+7 (GA4+7) treatment during the germination and post-germinative periods. In addition, constitutive over-expression of AtCYS6 retarded germination and seedling growth, whereas these were enhanced in an AtCYS6 knock-out mutant (cys6-2). Additionally, cysteine proteinase activities stored in seeds were inhibited by AtCYS6 in transgenic Arabidopsis. From these data, we propose that AtCYS6 expression is enhanced by the germination inhibitory phytohormone ABA and that it participates in the control of germination rate and seedling growth by inhibiting the activity of stored cysteine proteinases.

Distinct expression patterns of two Arabidopsis phytocystatin genes, AtCYS1 and AtCYS2, during development and abiotic stresses

The phytocystatins of plants are members of the cystatin superfamily of proteins, which are potent inhibitors of cysteine proteases. The Arabidopsis genome encodes seven phytocystatin isoforms (AtCYSs) in two distantly related AtCYS gene clusters. We selected AtCYS1 and AtCYS2 as representatives for each cluster and then generated transgenic plants expressing the GUS reporter gene under the control of each gene promoter. These plants were used to examine AtCYS expression at various stages of plant development and in response to abiotic stresses. Histochemical analysis of AtCYS1 promoter- and AtCYS2 promoter-GUS transgenic plants revealed that these genes have similar but distinct spatial and temporal expression patterns during normal development. In particular, AtCYS1 was preferentially expressed in the vascular tissue of all organs, whereas AtCYS2 was expressed in trichomes and guard cells in young leaves, caps of roots, and in connecting regions of the immature anthers and filaments and the style and stigma in flowers. In addition, each AtCYS gene has a unique expression profile during abiotic stresses. High temperature and wounding stress enhanced the expression of both AtCYS1 and AtCYS2, but the temporal and spatial patterns of induction differed. From these data, we propose that these two AtCYS genes play important, but distinct, roles in plant development and stress responses.

Comparative mapping, genomic structure, and expression analysis of eight pseudo-response regulator genes in Brassica rapa.

Circadian clocks regulate plant growth and development in response to environmental factors. In this function, clocks influence the adaptation of species to changes in location or climate. Circadian-clock genes have been subject of intense study in models such as Arabidopsis thaliana but the results may not necessarily reflect clock functions in species with polyploid genomes, such as Brassica species, that include multiple copies of clock-related genes. The triplicate genome of Brassicarapa retains high sequence-level co-linearity with Arabidopsis genomes. In B. rapa we had previously identified five orthologs of the five known Arabidopsis pseudo-response regulator (PRR) genes that are key regulators of the circadian clock in this species. Three of these B. rapa genes, BrPRR1, BrPPR5, and BrPPR7, are present in two copies each in the B. rapa genome, for a total of eight B. rapa PRR (BrPRR) orthologs. We have now determined sequences and expression characteristics of the eight BrPRR genes and mapped their positions in the B. rapa genome. Although both members of each paralogous pair exhibited the same expression pattern, some variation in their gene structures was apparent. The BrPRR genes are tightly linked to several flowering genes. The knowledge about genome location, copy number variation and structural diversity of these B. rapa clock genes will improve our understanding of clock-related functions in this important crop. This will facilitate the development of Brassica crops for optimal growth in new environments and under changing conditions.

Overexpression of a Brassica rapa MADS-box gene, BrAGL20, induces early flowering time phenotypes in Brassica napus

BrAGL20 (SOC1) containing MADS box, a floral integrator gene, was introduced into Brassica napus cv. “Youngsan” by Agrobacterium-mediated transformation. Constitutively overexpressed BrAGL20 under the CaMV 35S promoter induced early flowering time compared to the wild-type. These phenotypes were stably inherited through generations T2 and T3, regardless of planting season. The expression of the floral meristem identity genes LFY and AP1 seemed to appear rapidly in the shoot apex region of transgenic plants showing the early flowering time phenotype. These results suggest that overexpression of BrAGL20 can significantly affect the flowering time of B. napus, and regulation of floral integrator gene expression could be applied for adaptation of crops to local environments and climate changes.

Genome-wide analysis of the expansin gene superfamily reveals Brassica rapa -specific evolutionary dynamics upon whole genome triplication

Chinese cabbage (Brassica rapa subsp. pekinensis) is an economically important vegetable that has encountered four rounds of polyploidization. The fourth event, whole genome triplication (WGT), occurred after its divergence from Arabidopsis. Expansins (EXPs) are cell wall loosening proteins that participate in cell wall modification processes. In this study, the impacts of WGT on the B. rapa expansin (BrEXP) superfamily were evaluated. Whole genome screening of B. rapa identified 32 loci coding 53 expansin genes. Fifteen of the loci maintained a single gene copy, 15 maintained two gene copies and 2 maintained three gene copies. Six loci had no synteny to any Arabidopsis thaliana orthologs. Two loci were involved in tandem duplication. Segmental duplication and fragment recombination were dominant in accelerating BrEXP evolution. Three genes (BrEXPA7, BrEXLA1 and BrEXLA2) lost one of their ancestral introns, two genes (BrEXPA18 and BrEXPB6) gained new introns, and a domain tandem repeat (BrEXPA18) and domain recombination (Bra016981; not considered as expansin) were observed in one gene each. Further, domain deletion was observed in an additional five genes (Bra033068, Bra000142, Bra025800, Bra016473 and Bra004891, not considered as expansins) that lost one of their expansin-specific domains evolutionarily. These findings provide a basis for the evolution and modification of the BrEXP superfamily after a WGT event, which will help in determining the functional characteristics of BrEXPs.

Identification and characterization of SHI family genes from Brassica rapa L. ssp. pekinensis

SHI (short internodes) is a negative regulator of gibberellin-induced cell elongation. Extensive searches in the Brassica rapa genome allowed for the prediction of at least six different SHI-related genes on six chromosomes in the genome. Genome structural examination revealed that these genes had one intron each in their corresponding open reading frames. Protein structure comparisons using the CLUSTALW program and based on alignments of all BrSRS (B. rapaSHI-related sequence) proteins revealed broad conservation of the RING finger-like zinc finger and IGGH motifs. According to the phylogenetic relationship based on deduced amino acid sequences, the six BrSRS proteins were most closely related to Arabidopsis SRS (AtSRS) proteins; however, BrSRS proteins were dispersed in the phylogenetic tree. Semi-quantitative RT-PCR analysis indicated that the six BrSRS genes exhibited different expression patterns in various tissues and responded differently to growth phytohormones. The differences among the six BrSRS genes with respect to gene structure and expression pattern suggest that these genes may play diverse physiological roles in the developmental process of B. rapa.

Effect of Feeding Plum and Red Ginseng Marc on Vital Reaction in Broiler Stress

This study was conducted to test the efficacy of plum (Prunus mume) and red ginseng (Panax ginseng C.A Meyer) marc as stress inhibitors under heat stress and lipopolysaccharide (LPS) challenge in broilers by investigating their effects on blood biochemical parameters, immunoglobulin concentration and splenic cytokine mRNA expressions. A total of one hundred ninety-two 1-d-old male broiler chicks (Ross 308) were divided into 2 stress conditions (heat and LPS) experiments. Each experiment was divided into 4 treatment groups with 8 replicates of 3 birds in each group. NC (negative control, no immune substances), PC (positive control, 25 ppm -glucan), PM (1% plum marc) and RGM (3% red ginseng marc) treatments were administered with respective substance through water supplementation. During heat stress, The Ca/Mg ratio in PM and RGM was significantly decreased in comparison with that of NC (P

Ectopic expression of an Arabidopsis dehydration-responsive element-binding factor DREB2C improves salt stress tolerance in crucifers

Key messageDREB2Cacts as a transcriptional activator of the salt tolerance-relatedCOLD-REGULATED 15Agene.AbstractDEHYDRATION-RESPONSIVE ELEMENT BINDING FACTOR 2C (DREB2C) regulates plant responses to heat stress. We report here that DREB2C is induced by NaCl stress in Arabidopsis, based on quantitative RT-PCR analyses of transcript levels and DREB2C promoter-controlled GUS activity assays. Constitutive overexpression of DREB2C from the cauliflower mosaic virus (CaMV) 35S promoter led to enhanced salt tolerance in transgenic Arabidopsis and canola plants that was characterized by higher chlorophyll content, lower tissue Na+ content, reduced rate of water loss, and tighter membrane integrity in plants grown in NaCl-containing medium. Basal expression of the stress-responsive genes COLD-REGULATED 15A (COR15A), RESPONSIVE TO DEHYDRATION (RD) 29A and RD29B, was higher in transgenic DREB2C-overexpressing Arabidopsis plants than in the wild-type. Promoter transactivation assays and electrophoretic mobility-shift assays showed that DREB2C interacts directly with the three DREs in the COR15A promoter, both in vivo and in vitro. Transgenic Arabidopsis constitutively overexpressing COR15A from the CaMV35S promoter exhibited greater NaCl tolerance than the untransformed wild-type. Taken together, the data suggest that DREB2C functions as transcriptional activator that promotes NaCl tolerance, in part through upregulation of the stress-responsive gene COR15A.

Expression of a Chinese cabbage cysteine proteinase inhibitor, BrCYS1, retards seed germination and plant growth in transgenic Tobacco plant

Phytocystatins are plant cysteine proteinase inhibitors that regulate endogenous and heterologous cysteine proteinases of the papain family. A cDNA encoding the phytocystatin BrCYS1 (Brassica rapa cysteine proteinase inhibitor 1 ) has been isolated from Chinese cabbage (B. rapa subsp.pekinensis) flower buds. In order to explore the role of this inhibitory enzyme, tobacco plants (Nicotiana tabacum L. cv. Samson) containing altered amounts of phytocystatin were generated by over-expressingBrCYS1 cDNA in either the sense or the antisense configuration. The resulting plants hadin vitro enzyme inhibitory activities that were over 10% of those detected in wild type plants. The transgenic plants exhibited retarded seed germination and seedling growth and a reduced seed yield, whereas these properties were enhanced in antisense plants. These data suggest that BrCYS1 participates in the control of seed germination, post-germination and plant growth by regulating cysteine peptidase activity.