Functional genomics analysis of the arabidopsis ABI5 bZIP transcription factor

Hur, Jung-Im

15 May 2009

During embryogenesis, the architecture of the plant and the food reserves for seed germination are established. Abscisic acid (ABA) regulates seed development and dormancy. It controls genes involved in stress responses. ABA-responsive basic leucine zipper (bZIP) transcription factors are identified by interaction with ABA responsive cis-regulatory elements. The transcription factor ABI5 is one of these. It regulates gene expression during embryogenesis and in response to ABA. An ABA-insensitive mutant, abi5-6, exhibits no gross morphological defects other than the effect on seed germination in the presence of ABA. Thus, microarray analysis was employed to search for molecular phenotypes. We used cDNA microarrays to analyze ABA regulated gene expression and the role of ABI5 in seedlings. 310 genes were identified as ABI5/ABA regulated genes. 161 of these genes were regulated by ABI5, and 134 of ABI5-regulated genes were co-regulated by ABA. Only a small number of genes altered expression in both Pro35S:ABI5 and abi5-6 genetic backgrounds indicating the preferential binding of the bZIP protein dimers to specific promoter sequences. To determine the optimal platform for identifying ABI5-regulated genes in seeds, a cDNA microarray, the Agilent Arabidopsis Oligo microarray, and the Affymetrix ATH1 arrays were tested. Cross platform comparisons utilized 4,518 genes present on all three platforms. The best correlation was between the Agilent and the Affymetrix results. Furthermore, the Affymetrix results correlated best with qRT-PCR validation data for selected genes. A small number of genes including AtCOR413 pm-1 showed a consistent expression pattern across the three platforms. A robust ABRE cis-regulatory element was identified in the promoter of AtCOR413 pm-1. Further studies showed binding of ABI5 to the promoter of AtCOR413 pm-1 by Electrophoretic Mobility Shift Assays (EMSA) and validated the expression of ABI5 and AtCOR413 pm-1 in abi5-6 seeds by qRT-PCR and RNA gel blot analysis. Transactivation assays using AtCOR413 pm-1 promoter:GUS fusions in Arabidopsis dry seed and seedlings revealed ABI5 acts as a negative regulator for AtCOR413 pm-1 in dry seeds, while other proteins may play major roles in regulating responses to ABA and low temperature (LT) in seedlings.

ABI5 bZIP transcription factor

Genomics analysis

CHARACTERIZATION OF OUTER MEMBRANE PROTEINS AND OUTER MEMBRANE VESICLES AND COMPARATIVE GENOMICS TO IDENTIFY VACCINE CANDIDATES IN FUSOBACTERIUM NECROPHORUM

Prabha K Bista (14206271)

02 December 2022

<p>  </p> <p><em>Fusobacterium necrophorum</em> is a Gram-negative, anaerobic, opportunistic pathogen that causes necrotic infections in cattle leading to liver abscess, foot rot, and calf diphtheria. Particularly, liver abscess in cattle is reported at 20.7% annually, and leads to liver condemnation and an annual economic burden of about 62 million dollars to the feedlot industry. Antibiotic administration is the mainstay of treating these infections, but antibiotic resistance is unavoidable and demand for antibiotic-free, natural, and organic beef has demanded alternative therapies and preventatives. Vaccination is one of the best alternatives to prophylactic antibiotic administration. In this study, we have explored outer membrane proteins (OMPs) and outer membrane vesicles (OMVs) for potential vaccine candidates. OMPs and OMVs are vaccine targets because of their antigenic properties and host specificity. Additionally, we performed comparative genomic analysis of <em>F. necrophorum</em> species to identify additional virulence genes with vaccine potential, unique to the <em>F. necrophorum</em> and its virulent subspecies <em>necrophorum</em>. </p> <p>Protein- protein interaction investigation through binding assay and pulldown assay identified novel OMPs, namely 17kDa, 22kDa, and 66.3 kDa proteins, which were further characterized as OmpH, OmpA and Cell Surface Protein (CSP), respectively. In this study, these novel OMPs including previously characterized 43kDa OMPs were cloned, and recombinant proteins were expressed and purified. These recombinant proteins were used to generate polyclonal antibodies in rabbits, and their efficacy was studied using <em>in vitro</em> adhesion inhibition assays. The combination of two or more antibodies raised against the recombinant OMPs was significantly effective in reducing/neutralizing bacterial binding to bovine endothelial cells compared to individual antibody treatment. This suggests that a multiple subunit vaccine could be effective and provide sufficient evidence to perform <em>in vivo</em> studies. </p> <p>Similarly, we purified OMVs of <em>F. necrophorum</em> subspecies <em>necrophorum</em> 8L1 and analyzed its content using proteomics and lipidomics. Out of 342 proteins identified by tandem liquid chromatography mass spectrometry (LC-MS), OMPs and toxins were the most abundant. These included OMPs and toxins namely, 43 kDa OMP, OmpH, OmpA, CSP, FadA, leukotoxin family filamentous adhesin, N-terminal domain of hemagglutinin and other OMP transport and assembly factor protein. The presence of a subset of these proteins was further confirmed by western blot analysis. Lipidomics analysis showed that OMVs contained phospholipid, sphingolipid, and acetyl carnitine as the main lipid contents. Cytotoxicity assay on BL-3 cell line showed that these OMVs have a toxic effect on host immune cells and could impart immunomodulatory effect. All these findings suggest the vaccine potential of OMVs and demand dose-based <em>in vivo</em> study.</p> <p>In addition, we identified and characterized 5 clinical isolates of <em>F. necrophorum</em> using comparative genomics, UBCG (Up-to-date Bacterial Core Gene) based analysis enabled phylogenetic characterization of 46 <em>F. necrophorum</em> genomes into subspecies specific clades. The pangenome and recombination analysis showed the extensive disparity in accessory genes resulting in species divergence. Strikingly, we detected antimicrobial resistance gene for macrolides and tetracycline in one strain of <em>F. necrophorum</em>, a harbinger of the start of resistance and necessitating search for an alternative prophylactic method. We also noted common virulence genes, including toxins, outer membrane adhesion proteins, cell envelope, type IV secretion system, ABC (ATP-binding cassette) transporters and transporter proteins in <em>F. necrophorum</em> strains. A focused study on these genes could help identify the main genes of virulence and inform effective vaccination strategies against fusobacterial infections. </p> <p>Overall, the studies suggest adhesins and toxin and/or OMV-based subunit vaccine could be potential targets for vaccine development against fusobacterial infections.  </p>

Veterinary bacteriology

Fusobacterium necrophorum

Outer membrane proteins

outer membrane vesicles

whole genome sequences (WGS)

Comparative Genomics Analysis

vaccine candidate protein

Virulent factors