Fowl typhoid (FT) is a septicemic disease caused by Salmonella Gallinarum (S. Gallinarum) and is responsible for severe economic losses in Korea. In this study, 49 aminoglycosides (AMG)-resistant S. Gallinarum were analyzed to determine the phenotypic and genotypic characteristics. Thirty-six (73.5%) out of 49 AMG-resistant S. Gallinarum exhibited resistance to at least one agent in three or more of antimicrobial categories as multidrug-resistant (MDR) isolates. Among the AMG-resistant isolates exhibiting MDR, 21 (58.3%) and 11 (30.6%) of the isolates harbored ant(2")-I, which encodes an aminoglycoside adenylyltransferase, and blaTEM-1, which is a β-lactamase-encoding gene, respectively. The qnrB, cmlA, and sul1 and sul2 genes, which are related to resistance to quinolones, chloramphenicol and sulfonamides, respectively, were detected in 8.3~22.2% of the AMG-resistant isolates that exhibited MDR. Twenty-four (66.6%) of 36 AMG-resistance S. Gallinarum exhibiting MDR carried class 1 integrons with aadA genes cassettes. Several plasmid replicon types, such as B/O, FIIA, FIB, and Frep were considered to play a prominent role in S. Gallinarum, and the presence of these genetic characteristics remain a serious concern to the selection of antimicrobials for the treatment of FT.
Avian Influenza (AI) is an avian disease that break out by AI virus (AIV). As Hemagglutinin (HA) that is a main antigen surface protein of influenza virus that causes these influenza infection changes continuously, HA escapes bond of guided antibody by host"s immunity system. Specification region (HA91-261) of HA molecule that reconize receptor (sialic acid) of host cell is well-preserved without changing relatively, but is gotten buried on inside of trimer structure in natural conditions, is reported that development of effective vaccine or cure for HA protein is difficult because is not exposed to immunity system. Aptamer is relatively small strand DNA or RNA, and has high affinity to specific proteins. In this study, new aptamer DNAs were screened which can specifically bind to the receptor binding region of HA H9 protein.
Targeted gene silencing is an essential component of plant biotechnology. RNA interference is often employed for targeted gene silencing in plants. However, it suffers from off-target effects and unstable gene suppression in many cases. In recent years, engineered nuclease-based tools, such as zinc-finger nucleases (ZFNs) and transcription activator-like effector nucleases (TALENs), have been developed to induce site-specific genome modifications. However, these approaches require much time and labor for extensive screening of mutants.
We have recently reported that the activities of dimeric transcription factors are competently suppressed by genome-encoded small interfering peptides (siPEPs) that competitively form nonfunctional heterodimers in plants. In addition, some splice variants of transcription factors also act in a similar manner to negatively regulate the activities of specific transcription factors. We designated the siPEP-mediated suppression of transcription factors peptide interference (PEPi).
Based on our previous observations, we also developed an artificial siPEP (a-siPEP) approach and evaluated its application for the targeted inactivation of transcription factors in the dicot model, Arabidopsis, and monocot model, Brachypodium. We designed a series of potential a-siPEPs of two representative transcription factors SUPPRESSOR OF OVEREXPRESSOR OF CONSTANS 1 (SOC1) and AGAMOUS (AG) that function in flowering induction and floral organogenesis, respectively. Transgenic plants overproducing a-siPEPs displayed phenotypes comparable to those of gene-deficient mutants. Collectively, our data demonstrate that the siPEP tool is an efficient protein knockout system for inactivating specific transcription factors, and other multimeric enzymes and membrane transporters as well, in plants.
We will discuss about the global application of the siPEP toll to other plant species and potential advantages over other gene manipulation tools.
A new mungbean cultivar Soseon (Vigna radiata (L.) Wilczek) was derived from the cross between KM9003-2B-783 and V2939 at the Jeollanam-do Agricultural Research & Extension Services (JARES) in 2003. “Soseon” has erect growth habit, heart leaf, green hypoc
A new mungbean variety Samgang (Vigna radiata (L.) Wilczek) was improved from the cross between Keumseongnogdu and V2939 at the Jeollanam-do Agricultural Research & Extension Services (JARES) in 2002. Samgang has erect growth habit, lobed leaflet, green h
Through earlier breeding efforts, portions of the genome of the wild species Oryza grandiglumis (2n=48) have been introgressed into the rice cultivar, Hwaseongbyeo (Oryza sativa spp. japonica). Hwaseongbyeo was used as recurrent parent and O. grandiglumis
Resistance genes to the blast pathogen (Pyricularia grisea Sacc.) were mapped using a recombinant inbred population consisting of 231 lines derived from a cross between the japonica parents, ‘Suwon365’ and Chucheongbyeo. Phenotypic analysis showed that Su