Construction and function of a root-specific promoter SRSP / 生物工程学报

The responsibility of root is absorbing water and nutrients, it is an important plant tissue, but easily to be affected by biotic and abiotic stresses, affecting crop growth and yield. The design of a synthetic root-specific promoter provides candidate promoters for the functional analysis and efficient expression of stress-related genes in crop roots. In this study, a synthetic root-specific module (pro-SRS) was designed using tandem four-copies of root specific cis-acting elements (OSE1ROOTNODULE, OSE2ROOTNODULE, SP8BFIBSP8AIB, and ROOTMOTIFAPOX1), and fused with minimal promoter from the CaMV 35S promoter to synthesize an artificially synthetic SRSP promoter. The SRSP promoter was cloned in pCAMBIA2300.1 by replacing CaMV 35S promoter so as to drive GUS expression. The constructs with SRSP promoter were transformed in tobacco by Agrobacterium-mediated method. SRSP promoter conferred root-specific expression in transgenic tobacco plants through Real-time PCR (RT-PCR) analysis and GUS histochemical staining analysis. It is indicated that the repeated arrangement of cis-acting elements can realize the expected function of the promoter. This study laid a theoretical foundation for the rational design of tissue-specific promoters.

Genomewide analysis of homeobox gene family in apple (Malus domestica Borkh.) and their response to abiotic stress

Homeobox proteins (HOXs) comprise a large family in eukaryotes and share a highly conserved DNA-binding motif, the homeodomain (HD). HOXs play an important role in the regulation of plant growth, development and stress response. However, systematic analysis and expression profiling of these genes have not been reported in Malus domestica. In this study, a total of 207 HOXs of M. domestica (MdHOXs) were identified and classified into 11 distinct subfamilies, and an unclassified group according to their functional domains. The MdHOXs were localized in all 17 chromosomes with various densities and a majority of them tended to form gene clusters. Analysis of the Ka/Ks ratios suggested that the duplicated genes of MdHOXs mainly underwent purifying selection with restrictive functional divergence after the duplication events. The expression of MdHOXs has organ specific characteristics and were divided into seven different groups. Stress-related cis-acting elements were prevalent in the upstream sequence of MdHOXs by systematic analysis. To explore the response to abiotic stress, eight MdHOXs were randomly selected to investigate their expression using quantitative real-time polymerase chain reaction. Transcription levels of MdHOXs were upregulated in the leaves and roots under cold, osmotic, high salinity or exogenous ABA treatments, which suggested that they may take part in the plant response to abiotic stress. These results provided basic information of HOXs in apple and will further contribute to the functional research of MdHOXs, especially the response to abiotic stress.

Isolation and characterization of a promoter responsive to salt, osmotic and dehydration stresses in soybean

Abstract Drought stress is the main limiting factor of soybean yield. Currently, genetic engineering has been one important tool in the development of drought-tolerant cultivars. A widely used strategy is the fusion of genes that confer tolerance under the control of the CaMV35S constitutive promoter; however, stress-responsive promoters would constitute the best alternative to the generation of drought-tolerant crops. We characterized the promoter of α-galactosidase soybean (GlymaGAL) gene that was previously identified as highly up-regulated by drought stress. The β-glucuronidase (GUS) activity of Arabidopsis transgenic plants bearing 1000- and 2000-bp fragments of the GlymaGAL promoter fused to the uidA gene was evaluated under air-dried, polyethylene glycol (PEG) and salt stress treatments. After 24 h of air-dried and PEG treatments, the pGAL-2kb led to an increase in GUS expression in leaf and root samples when compared to the control samples. These results were corroborated by qPCR expression analysis of the uidA gene. The pGAL-1kb showed no difference in GUS activity between control and treated samples. The pGAL-2kb promoter was evaluated in transgenic soybean roots, leading to an increase in EGFP expression under air-dried treatment. Our data indicates that pGAL-2kb could be a useful tool in developing drought-tolerant cultivars by driving gene expression.

Roles of RUNX1 and PU.1 in CCR3 Transcription

CCR3 is a chemokine receptor that mediates the accumulation of allergic inflammatory cells, including eosinophils and Th2 cells, at inflamed sites. The regulatory sequence of the CCR3 gene, contains two Runt-related transcription factor (RUNX) 1 sites and two PU.1 sites, in addition to a functional GATA site for transactivation of the CCR3 gene. In the present study, we examined the effects of the cis-acting elements of RUNX1 and PU.1 on transcription of the gene in EoL-1 eosinophilic cells and Jurkat T cells, both of which expressed functional surface CCR3 and these two transcription factors. Introduction of RUNX1 siRNA or PU.1 siRNA resulted in a modest decrease in CCR3 reporter activity in both cell types, compared with transfection of GATA-1 siRNA. Cotransfection of the two siRNAs led to inhibition in an additive manner. EMSA analysis showed that RUNX1, in particular, bound to its binding motifs. Mutagenesis analysis revealed that all point mutants lacking RUNX1- and PU.1-binding sites exhibited reduced reporter activities. These results suggest that RUNX1 and PU.1 participate in transcriptional regulation of the CCR3 gene.

Understanding Disease Susceptibility through Population Genomics

Genetic epidemiology studies have established that the natural variation of gene expression profiles is heritable and has genetic bases. A number of proximal and remote DNA variations, known as expression quantitative trait loci (eQTLs), that are associated with the expression phenotypes have been identified, first in Epstein-Barr virus-transformed lymphoblastoid cell lines and later expanded to other cell and tissue types. Integration of the eQTL information and the network analysis of transcription modules may lead to a better understanding of gene expression regulation. As these network modules have relevance to biological or disease pathways, these findings may be useful in predicting disease susceptibility.

5' and 3' cis-Acting RNA Elements Required for RNA Replication of Porcine Reproductive and Respiratory Syndrome Virus

Porcine reproductive and respiratory syndrome virus (PRRSV), a member of the genus Arterivirus in the family Arteriviridae, is the most important viral pathogens in swine industry worldwide. Here, we have investigated 5' and 3' cis-acting RNA elements required for PRRSV genome replication. Using the infectious PRRSV cDNA, we have manipulated the genomic RNA to generate mutant genomic RNAs, transfected these mutants into susceptible MARC-145 cells, and examined the competence of RNA replication. We found three genetic factors that were essential for viral replication. First, the cap structure present at the 5'-end of the genome was absolutely required for RNA replication. Secondly, polyadenylation of the genomic RNA at the 3'-end was also essential for RNA replication. Thirdly, approximately 100-nucleotide region just upstream of the N protein-coding region was crucial for genomic RNA replication. Taken together, our findings indicate that replication of PRRSV genomic RNA requires three important cis-acting RNA elements: 5' cap structure, 3' poly(A) motif, and an internal sequence of about 100 nucleotides. Further investigation is needed to elucidate the molecular mechanism(s) of how these elements act on PRRSV genome replication.

Evidence for the Presence of a cis-acting Element in the Coding Region of the Japanese Encephalitis Virus Capsid Protein

Japanese encephalitis virus (JEV) is a member of mosquito-borne flaviviruses. To investigate whether there is a cis-acting genetic element in the coding region of the JEV C protein, which is required for viral replication, we generated four mutants by introducing a various size of deletions in each structural protein-coding region, designated as pJEV/Rep/deltaCC/LUC, pJEV/Rep/deltaC/LUC, pJEV/Rep/deltaprM/LUC, and pJEV/Rep/deltaE/LUC, of these, all replicons except for pJEV/Rep/deltaCC/LUC were competent in replication. Since pJEV/Rep/deltaCC/LUC is the same as pJEV/Rep/ deltaC/LUC except for an additional 5' deletion (nt 132~201) in the coding region of the C protein, this region appeared to be essential for RNA replication. This is consistent with the proposed cyclization sequence motif in the 5' region of the C gene, which has been recently shown to be required for replication in other mosquito-borne flaviviruses such as DV, YFV, KUN, and WNV. Thus, our results suggest that a cis-acting genetic element in the coding region of the JEV C protein may play an important role in RNA replication. This study will facilitate the current understanding of JEV RNA replication.

Site-directed mutagenesis of cis-acting element,CHR,in human NFBD1 promoter region / 第三军医大学学报

Objective To investigate the role of a cis-acting element,cell cycle genes homology region (CHR),in the transcriptional regulation of human NFBD1 gene (a nuclear factor with BRCT domain 1) by conducting a site-directed mutagenesis analysis on the element in human NFBD1 promoter region.Methods Wild type of NFBD1 promoter reporter,NFBD1-PS1-325,was used as template to make CHR mutant by using PCR based site-directed mutagenesis.Dual luciferase reporter assay was used to determine promoter reporter activity.Adiamycin treatment was employed to investigate the role of CHR in the transcriptional downregulation of NFBD1 after DNA damage.Results Site-directed mutagenesis of CHR caused a significant decrease in NFBD1 promoter activity,and also attenuated the transcriptional down-regulation of NFBD1 after DNA damage.Conclusion CHR element might be involved in both basic transcriptional regulation and transcriptional downregulation of NFBD1 after DNA damage.