Development of a highly efficient gene targeting system induced by transient repression of YKU80 expression in Candida glabrata.
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Candida glabrata: new tools and technologies-expanding the toolkitSystematic phenotyping of a large-scale Candida glabrata deletion collection reveals novel antifungal tolerance genesNew Mechanisms of Flucytosine Resistance in C. glabrata Unveiled by a Chemogenomics Analysis in S. cerevisiaeDeletion of the Pichia pastoris KU70 homologue facilitates platform strain generation for gene expression and synthetic biologyIntestinal resident yeast Candida glabrata requires Cyb2p-mediated lactate assimilation to adapt in mouse intestineGenome-wide survey of transcriptional initiation in the pathogenic fungus, Candida glabrata.Differential oxidant tolerance determined by the key transcription factor Yap1 is controlled by levels of the Yap1-binding protein, Ybp1Improved Gene Targeting through Cell Cycle SynchronizationKRE5 Suppression Induces Cell Wall Stress and Alternative ER Stress Response Required for Maintaining Cell Wall Integrity in Candida glabrataMembrane Proteome-Wide Response to the Antifungal Drug Clotrimazole in Candida glabrata: Role of the Transcription Factor CgPdr1 and the Drug:H+ Antiporters CgTpo1_1 and CgTpo1_2Comparison of sterol import under aerobic and anaerobic conditions in three fungal species, Candida albicans, Candida glabrata, and Saccharomyces cerevisiae.The dual role of candida glabrata drug:H+ antiporter CgAqr1 (ORF CAGL0J09944g) in antifungal drug and acetic acid resistance.Candida glabrata drug:H+ antiporter CgQdr2 confers imidazole drug resistance, being activated by transcription factor CgPdr1.Iron-depletion promotes mitophagy to maintain mitochondrial integrity in pathogenic yeast Candida glabrataMembrane Proteomics Analysis of the Candida glabrata Response to 5-Flucytosine: Unveiling the Role and Regulation of the Drug Efflux Transporters CgFlr1 and CgFlr2.Genetic surgery in fungi: employing site-specific recombinases for genome manipulation.Candida glabrata: a deadly companion?Unexpected effects of azole transporter inhibitors on antifungal susceptibility in Candida glabrata and other pathogenic Candida species.Monitoring of Iron Depletion-Induced Mitophagy in Pathogenic Yeast.The multidrug resistance transporters CgTpo1_1 and CgTpo1_2 play a role in virulence and biofilm formation in the human pathogen Candida glabrata.Roles of vacuolar H+-ATPase in the oxidative stress response of Candida glabrata.Contributions of Aspergillus fumigatus ATP-binding cassette transporter proteins to drug resistance and virulence.Deletion of the DNA Ligase IV Gene in Candida glabrata Significantly Increases Gene-Targeting EfficiencyApplication of the Saccharomyces cerevisiae FLP/FRT recombination system in filamentous fungi for marker recycling and construction of knockout strains devoid of heterologous genes.Efficient gene targeting in a Candida guilliermondii non-homologous end-joining pathway-deficient strain.Candida glabrata drug:H+ antiporter CgTpo3 (ORF CAGL0I10384g): role in azole drug resistance and polyamine homeostasis.A New Determinant of Candida glabrata Virulence: The Acetate Exporter CgDtr1.History of Genome Editing in Yeast.Efficient gene targeting in non-homologous end-joining-deficient Lipomyces starkeyi strains.Advancing metabolic engineering of Yarrowia lipolytica using the CRISPR/Cas system
P2860
Q26800080-B3AAA724-0D16-4ADA-8211-405C537B6E1CQ28539874-2966DF7B-576A-4A9D-A474-96CD15A253FEQ28547198-1C777C9B-93F0-4F15-A520-514E59E3EF4AQ28727694-A4949D30-71C3-4881-B81A-9C6EF9E0F96FQ34024025-822C84B3-5F5A-481E-AB51-9E3E951160F9Q35145957-94C6246E-B88D-4A56-A0E2-1C9DFCA421F3Q35310356-D3D42957-56A4-42B9-80D5-20E5EEB83E77Q35698548-33498066-0C72-482A-BAD4-4BC48380C3C9Q36109051-F6A998E6-D41F-4ADC-BF9B-FE11A4A19A34Q36604088-6091ED4A-246C-454C-A4F0-BCEFFF8A98EDQ36826423-2FF31153-84FC-42BA-998D-6318DBDA7ED4Q36955872-CDE78864-ADC3-4C3C-9307-DCCA113C45ABQ36969871-A701705E-12F5-4BD6-B58D-FECF7969689FQ37141753-8F384947-822C-44F5-8BA4-E9FA9E1CD795Q37521304-2FB2C550-9447-4468-A662-590114680214Q38177172-4059BC0A-F89A-4EE0-9CD0-1B6A81C6AD35Q38214878-3F03C445-F646-43CA-9719-02845A0C9607Q40138001-837CB6BE-8C13-4D27-B5D7-0C7783C5E5B9Q40219218-AEEFEA29-DA11-4B36-8849-6E37835F4977Q40486217-BC0DEF09-5D86-40C1-A4C8-9B4CA07485C0Q40628108-68FBD150-5039-4522-8EE7-E60FF49B8E28Q41867709-DD8B1F27-64D4-44F6-9A73-5897E4DF50DEQ42152478-05816009-930B-4F7F-9B2A-E34F042C3BD7Q42735077-23F42492-C9DA-4871-AF9B-65B698D84881Q43534448-2B66D244-6F59-4F98-8AA3-F47E4B6B39EBQ46926444-D7F71D05-C7EE-4340-AC81-5A119D78D942Q47165005-68DE08B9-0C27-4FD3-91FA-C0133F2EB65AQ48219464-987E435A-A20D-473E-AD84-DC4A3C77114DQ50996682-0DB740D4-583A-4445-A85A-7FA54E26D68FQ57152637-2D447DAA-DF4B-4A19-A98B-E90693DA8E99
P2860
Development of a highly efficient gene targeting system induced by transient repression of YKU80 expression in Candida glabrata.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Development of a highly effici ...... xpression in Candida glabrata.
@ast
Development of a highly effici ...... xpression in Candida glabrata.
@en
type
label
Development of a highly effici ...... xpression in Candida glabrata.
@ast
Development of a highly effici ...... xpression in Candida glabrata.
@en
prefLabel
Development of a highly effici ...... xpression in Candida glabrata.
@ast
Development of a highly effici ...... xpression in Candida glabrata.
@en
P2093
P2860
P356
P1433
P1476
Development of a highly effici ...... expression in Candida glabrata
@en
P2093
Hiroji Chibana
Hironobu Nakayama
Kaname Sasamoto
Yuzuru Mikami
P2860
P304
P356
10.1128/EC.00414-06
P50
P577
2007-05-18T00:00:00Z