• 제목/요약/키워드: gene disruption

검색결과 166건 처리시간 0.039초

Deletion of GBG1/AYR1 Alters Cell Wall Biogenesis in Saccharomyces cerevisiae

  • Ahn, Ki-Woong;Kim, Sung-Woo;Kang, Hyung-Gyoo;Kim, Ki-Hyun;Park, Yun-Hee;Choi, Won-Ja;Park, Hee-Moon
    • Mycobiology
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    • 제38권2호
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    • pp.102-107
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    • 2010
  • We identified a gene for $\beta$-1,3-glucan synthesis (GBG1), a nonessential gene whose disruption alters cell wall synthesis enzyme activities and cell wall composition. This gene was cloned by functional complementation of defects in $\beta$-1,3-glucan synthase activity of the the previously isolated Saccharomyces cerevisiae mutant LP0353, which displays a number of cell wall defects at restrictive temperature. Disruption of the GBG1 gene did not affect cell viability or growth rate, but did cause alterations in cell wall synthesis enzyme activities: reduction of $\beta$-1,3-glucan synthase and chitin synthase III activities as well as increased chitin synthase I and II activities. GBG1 disruption also showed altered cell wall composition as well as susceptibility toward cell wall inhibitors such as Zymolyase, Calcofluor white, and Nikkomycin Z. These results indicate that GBG1 plays a role in cell wall biogenesis in S. cerevisiae.

Construction of hsf1 Knockout-mutant of a Thermotolerant Yeast Strain Saccharomyces cerevisiae KNU5377 (고온내성 연료용 알코올 효모균주 Saccharomyces cerevisiae KNU5377에서 HSF1 유전자의 변이주 구축)

  • Kim Il-Sup;Yun Hae-Sun;Choi Hye-Jin;Sohn Ho-Yong;Yu Choon-Bal;Kim Jong-Guk;Jin Ing-Nyol
    • Journal of Life Science
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    • 제16권3호
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    • pp.454-458
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    • 2006
  • HSF1 is the heat shock transcription factor in Saccharomyces cerevisiae. S. cerevisiae KNU5377 can ferment at high temperature such as $40^{\b{o}}C$. We have been the subjects of intense study because Hsf1p mediates gene expression not only to heat shock, but to a variety of cellular and environmental stress challenges. Basing these facts, we firstly tried to construct the hsf1 gene-deleted mutant. PCR-method for fast production of gene disruption cassette was introduced in a thermotolerant yeast S. cerevisiae KNU5377, which allowed the addition of short flanking homology region as short as 45 bp suffice to mediate homologous recombination to kanMX module. Such a cassette is composed of linking genomic DNA of target gene to the selectable marker kanMX4 that confers geneticin (G418) resistance in yeast. That module is extensively used for PCR-based gene replacement of target gene in the laboratory strains. We describe here the generation of hsf1 gene disruption construction using PCR product of selectable marker with primers that provide homology to the hsf1 gene following separation of haploid strain in wild type yeast S. cerevisiae KNU5377. Yeast deletion overview containing replace cassette module, deletion mutant construction and strain confirmation in this study used Saccharomyces Genome Deletion Project (http:://www-sequence.standard.edu/group/yeast_deletion_project). This mutant by genetic manipulation of wild type yeast KNU5377 strain will provide a good system for analyzing the research of the molecular biology underlying their physiology and metabolic process under fermentation and improvement of their fermentative properties.

Characterization of a Chalcosyltransferase (gerGTII) in Dihydrochalcomycin Biosynthesis

  • Pageni, Binod Babu;Oh, Tae-Jin;Thuy, Ta Thi Thu;Sohng, Jae Kyung
    • Molecules and Cells
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    • 제26권3호
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    • pp.278-284
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    • 2008
  • An open reading frame, designated GerGTII and located downstream of the polyketide synthase genes, has been identified as a chalcosyltransferase by sequence analysis in the dihydrochalcomycin biosynthetic gene cluster of Streptomyces sp. KCTC 0041BP. The deduced product of gerGTII is similar to several glycosyltransferases, authentic and putative, and it displays a consensus sequence motif that appears to be characteristic of a sub-group of these enzymes. Specific disruption of gerGTII within the S. sp. KCTC 0041BP genome by insertional in-frame deletion method, resulted complete abolishment of dihydrochalcomycin and got the 20-O-mycinosyl-dihydrochalconolide as intermediate product in dihydrochalcomycin biosynthesis which was confirmed by electron spray ionization-mass spectrometry and liquid chromatography-mass spectrometry. Dihydrochalcomycin also was recovered after complementation of gerGTII.

Genetic Engineering for Detection of Endocrine Disruption using I-18 C Gene Expression in Chironomus riparius

  • Kwak Inn-Sil
    • Korean Journal of Environmental Biology
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    • 제23권3호
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    • pp.269-274
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    • 2005
  • The 2D/E gel analysis for polypeptide expression reflecting I-18 C gene (early-ecdysterone inducible gene) has conducted the emerged C. riparius adults from larval phase exposure to tebufenozide acting as an ecdysteroidal molting hormone. Control group, the amount of ORE II of the I-18 C gene was larger than that of ORE I of this gene. After treatments, ORE I of the I-18 C gene was overexpressed as the polypeptide, whereas ORF II of this gene was expressed as the polypeptide and was clearly reduced expression. Accordingly, we consider that tebufenozide exhibited endocrine disruptions related processing of ecdysteroid receptor protein reflecting ORF II of I-18 C gene. Also, earlier emergence day was related overexpressed polypeptide reflecting ORE I of I-18 C gene. In this study result, tebufenozide induced changing of physiological condition, and then polypeptide expression reflecting early-ecdysterone inducible I-18 C gene was different between control group and exposure group.

Biomedical Application of Gene Editing (유전자 교정 기술의 생의학적 응용)

  • Ju-Chan, Park;Hyeon-Ki, Jang
    • Journal of Industrial Technology
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    • 제42권1호
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    • pp.29-36
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    • 2022
  • The CRISPR system has revolutionized gene editing field. Cas9-mediated gene editing such as Indel induction or HDR enable targeted gene disruption or precise correction of mutation. Moreover, CRISPR-based new editing tools have been developed such as base editors. In this review, we focus on gene editing in human pluripotent stem cells, which is principal technique for gene correction therapy and disease modeling. Pluripotent stem cell-specific drug YM155 enabled selection of target gene-edited pluripotent stem cells. Also, we discussed base editing for treatment of congenital retina disease. Adenine base editor delivery as RNP form provide an approach for genetic disease treatment with safe and precise in vivo gene correction.

Site-speci fic Inactivation o meso-Diaminopimelate-dehydrogenase Gene (ddh) in a Lysine-producing Brevibacterium lactofementum. (Brevibacterium lactofermentum 에서 meso-Diaminopimelate-dehydrogenase Gene (ddh)의 Site-specific Inactivation)

  • 김옥미;박선희;이갑랑
    • Microbiology and Biotechnology Letters
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    • 제26권5호
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    • pp.387-392
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    • 1998
  • Brevibacterium lactofermentum, a gram-positive bacteria, has both the diaminopimelate (DAP) pathway and meso-DAP-dehydrogenase (DDH) pathway for L-lysine biosynthesis. To investigate importance of DDH pathway and the related ddh gene in lysine production, we introduced site-specific mutagenesis technique. A 300 bp DNA fragment central to the meso-DAP-dehydrogenase gene (ddh) of B. lactofermentum was used to inactive chromosomal ddh gene via homologous recombination. Southern hybridization analysis confirmed that the chromosomal ddh gene was disrupted by the vector sequence. The B. lactofementum ddh mutant obtained have an inactive DDH pathway. The results reveal that inactivation of the ddh gene in B. lactofermentum leads to dramatic reduction of lysine production as well as decrease of the growth rate, indicating that the DDH pathway is essential for high-level lysine production as well as biosynthesis of meso-DAP.

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Induced Mutant Animal Models for Studying the Genetics of Hypertension and Atherosclerosis

  • Oh, Goo-Taeg
    • Toxicological Research
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    • 제17권
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    • pp.289-292
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    • 2001
  • Gene targeting allows precise, predetermined changes to be made in a chosen gene in the mouse genome. To date, targeting has been used most often for generation of animals completely lacking the product of a gene of interest. Models of essential hypertension have been produced by mutated genes relating renin angiotensin system. The most significant contribution to understanding the genetic etiology of essential hypertension is probably the demonstration that discrete alterations in the expression of a variety of different genes can individually cause changes in the blood pressures of mice, even when the mice have all their compensatory mechanisms intact. These effects are readily detected in animals having moderate decreases in gene function due to heterozygosity for gene disruptions or modest increases due to gene duplication. As a species the mouse is highly resistant to atherosclerosis. However. through induced mutations it has been possible to develop lines oj mice that are deficient in apolipoprotein E, a ligand important in lipoprotein clearance, develop atherosclerotic lesions resembling those observed in humans. The atherosclerotic lesions in apoE-deficient mice have been well characterized, and they resemble human lesions in their sites of predilection and progression to the fibroproliferative stage. Other promising models are mice that are deficient in the low-density lipoprotein receptor. Considerable work still remains to be done in dissecting out in a rigorous manner the effects of alterations in single genes on the induction or progression of atherosclerosis and on the control of blood pressures. Perhaps even more exciting is the opportunity now becoming available to breed animals in which the effects oj precise differences in more than one gene can be studied in combination.

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Identification and Characterization of the wbpO Gene Essential for Lipopolysaccharide Synthesis in Vibrio vulnificus

  • Park Na-Young;Lee Jeong-Hyun;Lee Byung-Cheol;Kim Tae-Sung;Choi Sang-Ho
    • Journal of Microbiology and Biotechnology
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    • 제16권5호
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    • pp.808-816
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    • 2006
  • A wbpO gene encoding a putative UDP-N-acetylo-galactosamine dehydrogenase was identified and cloned from Vibrio vulnificus. LPS production was altered by disruption of the wbpO gene through allelic exchanges. The function of the wbpO gene in virulence assessed in vitro and in mice revealed that WbpO is important in both the pathogenesis of V. vulnificus and the biosynthesis of LPS.