Proceedings of the Microbiological Society of Korea Conference (한국미생물학회:학술대회논문집)
The Microbiological Society of Korea
- Annual
Domain
- Life Science > Molecular Cell Biology
2005.05a
-
Rhee, Sung-Keun;Kang, Cheol-Hee;Bae, Jin-Woo;Nam, Young-Do;Park, Ja-Ryeong;Zhou, Jizhong;Park, Yong-Ha 21
-
-
Epifluorescence microscopy and direct viable counting methods have shown that only 0.01-0.1% of all the microbial cells from marine environments form colonies on standard agar plates. To culture novel marine microorganisms, high throughput culturing (HTC) techniques were developed to isolate cells in very low nutrient media. This approaches was designed to address microbial metabolic precesses that occur at natural substrate concentrations and cell densities, which are typically about three orders of magnitude less than in common laboratory media. Approximately 5000 cultures of pelagic marine bacteria were examined over the course of 3 years. Up to 14% of cells from coastal seawater were cultured using this method, a number that is 1400 to 140-fold higher than obtained by traditional microbiological culturing techniques. Among the cultured organisms are many unique phylogenetic lineages that have been named as new phyla (7), orders (2, 5, 12), families (3), and genera (1, 4, 6). Over 90% of the cells recovered by this method do not replicate in standard agar plating, the most common method of microbial cell cultivation.
-
-
-
-
Photosynthetic microbes possess a wealth of photoactive proteins including chlorophyll-based pigments, phototropin-related blue light receptors, phytochromes, and cryptochromes. Surprisingly, recent genome sequencing projects discovered additional photoactive proteins, retinal-based rhodopsins, in cyanobacterial and algal genera. Most of these newly found rhodopsin genes and retinal synthase have not been expressed and their functions are unknown. Analysis of the Anabaena and Chlamyrhodopsin with retinal synthase revealed that they have sensory functions, which, based on our work with haloarchaeal rhodopsins, may use a variety of signaling mechanisms. Anabaena rhodopsin is believed to be sensory, shown to interact with a soluble transducer and the putative function is either chromatic adaptation or circadian rhythm. Chlamydomonas rhodopsins are involved in phototaxis and photophobic responses based on electrical measurements by RNAi experiment. In order to analyze the protein, we developed a sensory rhodopsin expression system in E. coli. The opsin in E. coil bound endogenous all-trans retinal to form a pigment and can be observed on the plate. Using this system we could identify retinal synthase in Anabaena PCC 7120. We conclude that Anabaena D475 dioxygenase functions as a retinal synthase to the Anabaena rhodopsin in the cell.
-
-
Heat Shock Transcription Factor (HSF), and the promoter heat Shock Element (HSE), are among the most highly conserved transcriptional regulatory elements in nature. HSF mediates the transcriptional response of eukaryotic cells to heat, infection and inflammation, pharmacological agents, and other stresses. While HSF is essential for cell viability in yeast, oogenesis and early development in Drosophila, extended life-span in C. elegans, and extra-embryonic development and stress resistance in mammals, little is known about its full range of biological target genes. We used whole genome analyses to identify virtually all of the direct transcriptional targets of yeast HSF, representing nearly three percent of the genomic loci. The majority of the identified loci are heat-inducibly bound by yeast HSF, and the target genes encode proteins that have a broad range of biological functions including protein folding and degradation, energy generation, protein secretion, maintenance of cell integrity, small molecule transport, cell signaling, and transcription. Approximately 30% of the HSF direct target genes are also induced by the diauxic shift, in which glucose levels begin to be depleted. We demonstrate that phosphorylation of HSF by Snf1 kinase is responsible for expression of a subset of HSF targets upon glucose starvation.
-
Jang, Young-Joo;Ji, Jae-Hoon;Chung, Kyung-Sook;Kim, Dong-Uk;Hoe, kwang-Lae;Won, Mi-Sun;Yoo, Hyang-Sook 110
Under the condition of nutritional deprivation, actively growing cells prepare to enter$G_0$ -like stationary phase. Protein modification by phosphorylation/dephosphorylation or ubiqutination contributes to transfer cells from active cell cycle to dormant stage. We show here that Psp1/Sds23, which functions in association with the 20S cyclosome/APC (1) and is essential for cell cycle progression in Schizosaccharomyces pombe (2), is phosphorylated by stress-activated MAP kinase Sty1 and protein kinase A, as well as Cdc2/cyclinB, upon entry into stationary phase. Three serines at the positions 18,333 and 391 are phosphorylated and overexpression of Psp1 mutated on these sites causes cell death in stationary phase. These modifications are required for the binding of Spufd2, a S.pombe homolog of multiubiquitin chain assembly factor E4 in ubiquitin fusion degradation pathway. Deletion of Spufd2 gene led to increase cell viability in stationary phase, indicating that S. pombe Ufd2 functions to inhibit cell growth at this stage to maintain cell viability. Moreover, Psp1 enhances the multiubiquitination function of Ufd2, suggesting that Psp1 phosphorylated by sty1 and PKA kinases is associated with the Ufd2-dependent protein degradation pathway, which is linked to stress tolerance, to maintain cell viability in the$G_0$ -like stationary phase. -
Kim, Tae-Sung;Kim, Mi-Soon;Jung, Mee-Kum;Ahn, Jae-Hyung;Oh, Kyoung-Hee;Lee, Min-Hyo;Ka, Jong-Ok 123
-
The CC chemokine, monocyte chemoattractant protein-1 (MCP-1), plays a crucial role in the initiation of atherosclerosis and has direct effects that promote angiogenesis. To develop a specific inhibitor for MCP-1-induced angiogenesis, we performed in vitro selection employing phage display random peptide libraries. Most of the selected peptides were found to be homologous to the second extracellular loops of CCR2 and CCR3. We synthesized the peptide encoding the homologous sequences of the receptors and tested its effect on the MCP-1 induced angiogenesis. Surface Plasmon Resonance measurements demonstrated specific binding of the peptide to MCP-1 but not to the other homologous protein, MCP-3. Flow cytometry revealed that the peptide inhibited the MCP-1 binding to THP-1 monocytes. Moreover, CAM and rat aortic ring assays showed that the peptide inhibited MCP-1 induced angiogenesis. Our observations indicate that the MCP-1-binding peptide exerts its anti-angiogenic effect by interfering with the interaction between MCP-1 and its receptor.
-
-
The non-pathogenic, non-glycopeptide-producing actinomycete Streptomyces coelicolor carries a cluster of seven genes (vanSRJKHAX) that confers inducible, high-level resistance to vancomycin. The van genes are organised into four transcription units, vanRS, vanJ, vanK and vanHAX, and these transcripts are induced by vancomycin in a vanR-dependent manner. vanHAX are orthologuous to genes found in vancomycin resistant enterococci that encode enzymes predicted to reprogramme peptidoglycan biosynthesis such that cell wall precursors terminate in D-Ala-D-Lac, rather than D-Ala-D-Ala. vanR and vanS encode a two-component signal transduction system that mediates transcriptional induction of the seven van genes. vanJ and vanK are novel genes that have no counterpart in previously characterised vancomycin-resistance clusters from pathogens. VanK is essential for vancomycin resistance in S. coelicolor and it is required for adding Gly branch to stem peptides terminating D-Ala-D-Lac. Because VanK can recognise D-Lac-containing precursors but the constitutively expressed femX enzyme, encoded elsewhere on the chromosome, cannot recognize D-Lac-containing precursors as a substrate, vancomycin-induced expression of VanHAX in a vanK mutant is lethal. Further, femX null mutants are viable in the presence of glycopeptide antibiotics but die in their absence. Bioassay using vanJp-neo fusion reporter system also showed that all identified inducers for van genes expression were glycopeptide antibiotics, but teicoplanin, a membrane-anchored glycopeptide, failed to act as an inducer.
-
Hesketh, Andy;Chater, Keith;Kim, Dae-Wi;Lee, Kye-Joon;Bucca, Giselda;Hotchkiss, Graham;Smith, Colin 149
-
-
-
Hypovirus infection of the chestnut blight fungus Cryphonectria parasitica is a useful model system to study the hypoviral regulation of fungal gene expression. The hypovirus is known to downregulate the fungal laccase1 (lac 1), the modulation of which is tightly governed by the inositol triphosphate (
$IP_3$ ) and calcium second messenger system in a virus-free strain. We cloned the gene cplc1 encoding a phosphatidyl inositol-specific phospholipase C (PLC), in order to better characterize the fungal gene regulation by hypovirus. Sequence analysis of the cplc1 gene indicated that the protein product contained both the X and Y domains, which are the two conserved regions found in all known PLCs, with a 133 amino acid extension between the 2nd${\beta}$ -strand and the${\alpha}$ -helix in the X domain. In addition, the gene organization appeared to be highly similar to that of a${\delta}$ type PLC. Disruption of the cplc1 gene resulted in slow growth and produced colonies characterized by little aerial mycelia and deep orange in color. In addition, down regulation of lac1 expression was observed. However, temperature sensitivity, osmosensitivity, virulence, and other hypovirulence-associated characteristics did not differ from the wild-type strain. Functional complementation of the cplc1-null mutant with the PLC1 gene from Saccharomyces cerevisiae restored lac1 expression, which suggests that the cloned gene encodes PLC activity. The present study indicates that the cplc1 gene is required for appropriate mycelial growth, and that it regulates the lac1 expression, which is also modulated by the hypovirus. Although several PLC genes have been identified in various simple eukaryotic organisms, the deletion analysis of the cplc1 gene in this study appears to be the first report on the functional analysis of PLC in filamentous fungi. -
Potato scab, an important disease that affects developing tubers, causes a major problem in potato cultivation. The major potato cultivation areas in Korea are located in two Northern provinces, Gangwon and Gyeonggi, and two Southern provinces, Jeju island, and South Jeolla. In these areas, potato scab is widely distributed and has caused severe problem in potato cultivation. Therefore, potato-growing areas were surveyed for identification and distribution of potato scab pathogens from 1996 to 1999. Pathogenic Streptomyces strains were isolated from potato scab lesions and six representative Streptomyces species were characterized based on their phenotypic and molecular characteristics including, pathogenicity, physiological and morphological properties, analyses of 16SrRNA genes and 16S-23S ITS region, DNA relatedness, production of thaxtomin A, and the presence of nec1 and ORFtnp gene homologs. Three species were identified as previously described Streptomyces scabies, S. turgidiscabies, and S. acidiscabies, while other three species having distinct phenotypics properties were identified as novel S. luridiscabiei, S. puniciscabiei, and S. niveiscabiei.
-
-
-
-
-
-
-
-
Choi, Ji-Young;Kim, Jong-Gill;Choi, Young-Cheol;Kim, Won-Tae;Sim, Ha-Sik;Je, Yeon-Ho;Hwang, Seok-Jo 181.2
-
Kwon, Hyuk-Yong;Bae, Jin-Woo;Quan, Zhe-Xue;Nam, Young-Do;Park, Ja-Ryeong;Chang, Ho-Won;Rhee, Sung-Keun;Park, Yong-Ha 181.3
-
-
-
-
-
-
-
Lee, Hyang-Burm;Kim, Young-Jun;Jin, Hui Zi;Lee, Jung-Jun;Kim, Chang-Jin;Park, Jae-Young;Park, Chae-Haeng;Jung, Hack-Sung 183.2
-
-
-
-
Baik, Keun-Sik;Kim, Eun-Mi;Kieuquynh, Hoa;Park, Seong-Chan;Kim, Mi-Sun;Moon, Se-Il;Seong, Chi-Nam 184.2
-
-
-
-
-
-
Park, Hyung-Jun;Cho, Bong-Gum;Kwon, Soon-Wo;Kim, Byung-Yong;Kim, Mi-Soon;Kim, Wan-Gyu;Weon, Hang-Yeon 185.4
-
-
-
-
-
-
Cha, In-Bae;Weon, Hang-Yeon;Kim, Byung-Yong;Kim, Jong-Shik;Lee, Seon-Young;Go, Seung-Joo;Hong, Seung-Beom;Im, Wan-Taek;Kwon, Soon-Wo 187.2
-
-
-
-
-
-
Kim, Min-Cheol;Kim, Mi-Soon;Ahn, Jae-Hyung;Jung, Mee-Kum;Joo, Dong-Hun;Shin, Hye-Chul;Kim, Tae-Sung 188.4
-
-
-
Lee, Ji-Young;Kim, Kyung-Shik;Choo, Yeng-Fung;Kang, Gi-Su;Park, Ho-Il;Jong, Bor-Chyang;Chang, In-Seop;Kim, Byung-Hong 189.3
-
-
-
Nam, Young-Do;Bae, Jin-Woo;Quan, Zhe-Xue;Rhee, Sung-Keun;Kim, Jeong-Chan;Nahm, Wook-Hyun;Kim, Ju-Young;Yang, Dong-Yoon;Park, Yong-Ha 190.2
-
-
-
-
-
-
-
Shin, Dong-Sung;Park, Myong-Soo;Jung, Se-Ra;Do, Jin-Ok;Lee, Myong-Sook;Lee, Kang-Hyun;Kim, Seung-Bum;Bae, Kyung-Sook 192.1
-
-
-
T. Lugtu, Rovimar;Oh, Young-Sook;Park, Se-Keun;Kim, Yeong-Kwang;Myeong, Chun-Ye;Park, Sung-Gu;Choi, Sung-Chan 192.4
-
-
Park, Ja-Ryeong;Bae, Jin-Woo;Rhee, Sung-Keun;Nam, Young-Do;Kwon, Hyuk-Yong;Oh, Ho-Won;Park, Yong-Ha 193.2
-
-
-
-
-
-
-
-
Jeong, Jeong-Hwa;Kim, Dong-Hyun;Kong, Sung-Ho;Lim, Eun-Jin;Lee, Jong-Yeol;Bae, Young-Su;Lee, Sang-Seob 195.2
-
Lee, Se-Eun;Choi, Jung-Hye;Kim, Byung-Hyuk;Song, Mi-Young;Chon, Tae-Soo;Kang, Sun-Cheol;Koh, Sung-Cheol 195.3
-
-
-
-
-
-
-
-
-
Lee, Dong-Heon;Byun, Hoo-Dhon;Kim, Joo-Il;Bae, Jung-Hoon;Sohn, Jung-Hoon;Choi, Eui-Sung;Oh, Duck-Chul 198.1
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
Jung, Eun-Young;Park, Hong-Ki;Jung, Mi-Eung;Lee, You-Jung;Jung, Jong-Mun;Ji, Gi-Won;Shin, Pan-Se 202.1
-
Lee, Sun-Hee;Chung, Chung-Wook;Kim, Yoon-Seok;Shin, Kyoung-Sook;Hur, Hyoung-Woo;Rhee, Young-Ha 202.2
-
-
-
-
-
-
Kim, Jun-Tae;Seo, Hae-Jeom;Woo, Jung-Hee;Kang, Sung-Gyun;Jeong, Byeong-Chul;Lee, Jung-Hyun;Kim, Sang-Jin 203.4
-
-
-
-
-
-
Kim, Byoung-Guk;Jeong, Hye-Sung;Baek, Sun-Young;Shin, Jin-Ho;Kim, Jae-Ok;Min, Kyung-Il;Ryu, Seung-Rel;Min, Bok-Soon;Kim, Do-Keun;Jeong, Yong-Seok;Park, Sue-Nie 205.4
-
-
-
-
-
-
-
-
-
-
-
Kang, Do-Hyun;Chung, Gyung-Tae;Shin, Na-Ri;Yoon, So-Yeon;Shin, Ji-Hun;Seong, Won-Keun;Rhie, Gi-Eun;Oh, Hee-Bok 208.3
-
-
-
-
-
Kim, Myung-Won;Park, U-Ryung;Ju, Hyun-Mok;Park, Na-Young;Jeong, Hye-Sook;Rhee, Jee-Eun;Lee, Jeong-Hyun;Choi, Sang-Ho 209.4
-
-
-
-
-
-
-
-
Song, Moon-Seok;Yun, Ji-Hee;Cho, Joo-Yong;Kim, Dong-Hyun;Park, Kun-Sup;Chung, Myung-Jun;Kim, Soo-Dong;Baek, Dae-Heoun;Choi, Sung-Sook;Ha, Nam-Joo 211.4
-
Jung, Kyoung-Hwa;Seo, Gwi-Moon;Song, Young-Mi;Oh, Kwang-Keun;Kim, Seung-Joo;Chai, Young-Gyu 212.1
-
-
-
-
-
Park, Dong-Kyu;Song, Jee-Yeon;Kwon, Min-Suk;Yoon, Jin-Young;Choi, Dong-Wook;Park, Chan-Kyu 213.2
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
Park, Ji-Kook;Lee, Dong-Hyun;Lee, Sun-Hi;Park, Min-A;Jeon, Hye-Rin;Choi, Hyoung-Tae;Kim, Kyung-Hoon 220.2
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
Shim, Hye-Eun;Bae, Jin-Hee;Shim, Eun-Sook;Kim, Kyung-Jong;Kim, Sung-Hoon;Choo, Eun-Jin;Chung, Seong-Mi;Lee, Han-Soo;Jeong, Doo-Il 225.1
-
Kim, Hyeon-Guk;Kim, Bae-Hoon;Kim, Jin-Seok;Jang, Jung-Im;Lee, Yong-Hyon;Choi, Won-Cheol;Park, Yoo-Chang;Park, Yong-Keun 225.2
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
Park, Jun-Sun;Kim, Jeong-Min;Yun, Sang-Im;Choi, Yu-Jeong;Song, Byung-Hak;Jeong, Ah-Yong;Yeon, Sun-Mi;Lee, Young-Min 230.4
-
-
-
-
Han, Chang-Ho;Jin, Young-Hee;Choi, Sue-Jung;Lee, Sung-Deuk;Hwang, Kwang-Ho;Kim, Kyung-Sik;Park, Noh-Woon;Choi, Byung-Hyun 231.4
-
-