about
Molecular characterization of the Acremonium chrysogenum cefG gene product: the native deacetylcephalosporin C acetyltransferase is not processed into subunitsThe penicillin gene cluster is amplified in tandem repeats linked by conserved hexanucleotide sequencesThe Cerato-Platanin protein Epl-1 from Trichoderma harzianum is involved in mycoparasitism, plant resistance induction and self cell wall protectionTvDim1 of Trichoderma virens is involved in redox-processes and confers resistance to oxidative stresses.The isopenicillin N acyltransferases of Aspergillus nidulans and Penicillium chrysogenum differ in their ability to maintain the 40-kDa alphabeta heterodimer in an undissociated form.Characterization of the lys2 gene of Penicillium chrysogenum encoding alpha-aminoadipic acid reductase.Characterization and nitrogen-source regulation at the transcriptional level of the gdhA gene of Aspergillus awamori encoding an NADP-dependent glutamate dehydrogenase.Detection of peptaibols and partial cloning of a putative peptaibol synthetase gene from T. harzianum CECT 2413.Generation, annotation and analysis of ESTs from Trichoderma harzianum CECT 2413.The heterologous overexpression of hsp23, a small heat-shock protein gene from Trichoderma virens, confers thermotolerance to T. harzianum.Cloning and characterization of the Thcut1 gene encoding a cutinase of Trichoderma harzianum T34.The ThPG1 endopolygalacturonase is required for the trichoderma harzianum-plant beneficial interaction.Involvement of Trichoderma harzianum Epl-1 Protein in the Regulation of Botrytis Virulence- and Tomato Defense-Related Genes.Resolution of four large chromosomes in penicillin-producing filamentous fungi: the penicillin gene cluster is located on chromosome II (9.6 Mb) in Penicillium notatum and chromosome I (10.4 Mb) in Penicillium chrysogenum.Age-related clinical, serological, and histopathological features of celiac disease.Identification of loci and functional characterization of trichothecene biosynthesis genes in filamentous fungi of the genus Trichoderma.Effects of Trichothecene Production on the Plant Defense Response and Fungal Physiology: Overexpression of the Trichoderma arundinaceum tri4 Gene in T. harzianum.Influence of Rhizoctonia solani and Trichoderma spp. in growth of bean (Phaseolus vulgaris L.) and in the induction of plant defense-related genes.Involvement of Trichoderma trichothecenes in the biocontrol activity and induction of plant defense-related genesInhibitory activity of Beauveria bassiana and Trichoderma spp. on the insect pests Xylotrechus arvicola (Coleoptera: Cerambycidae) and Acanthoscelides obtectus (Coleoptera: Chrisomelidae: Bruchinae).Characterization of the bip gene of Aspergillus awamori encoding a protein with an HDEL retention signal homologous to the mammalian BiP involved in polypeptide secretion.Development of a qPCR Strategy to Select Bean Genes Involved in Plant Defense Response and Regulated by the Trichoderma velutinum - Rhizoctonia solani Interaction.The contribution of Trichoderma to balancing the costs of plant growth and defense.Overexpression of the Trichoderma brevicompactum tri5 gene: effect on the expression of the trichodermin biosynthetic genes and on tomato seedlings.Targeted inactivation of the mecB gene, encoding cystathionine-gamma-lyase, shows that the reverse transsulfuration pathway is required for high-level cephalosporin biosynthesis in Acremonium chrysogenum C10 but not for methionine induction of the cGenes for beta-lactam antibiotic biosynthesis.Nitrogen Metabolism and Growth Enhancement in Tomato Plants Challenged with Trichoderma harzianum Expressing the Aspergillus nidulans Acetamidase amdS Gene.Trichodiene Production in a Trichoderma harzianum erg1-Silenced Strain Provides Evidence of the Importance of the Sterol Biosynthetic Pathway in Inducing Plant Defense-Related Gene Expression.Functional analysis of the Trichoderma harzianum nox1 gene, encoding an NADPH oxidase, relates production of reactive oxygen species to specific biocontrol activity against Pythium ultimumThe importance of chorismate mutase in the biocontrol potential of Trichoderma parareesei.Three genes hrdB, hrdD and hrdT of Streptomyces griseus IMRU 3570, encoding sigma factor-like proteins, are differentially expressed under specific nutritional conditions.Relevance of trichothecenes in fungal physiology: disruption of tri5 in Trichoderma arundinaceum.Transgenic expression of the Trichoderma harzianum hsp70 gene increases Arabidopsis resistance to heat and other abiotic stresses.Overexpression of a Trichoderma HSP70 gene increases fungal resistance to heat and other abiotic stresses.Cloning and characterization of the gene cahB encoding a cephalosporin C acetylhydrolase from Acremonium chrysogenum.Subcellular localization of the homocitrate synthase in Penicillium chrysogenum.The cefT gene of Acremonium chrysogenum C10 encodes a putative multidrug efflux pump protein that significantly increases cephalosporin C production.Expression of a synthetic copy of the bovine chymosin gene in Aspergillus awamori from constitutive and pH-regulated promoters and secretion using two different pre-pro sequences.Co-transformation with autonomous replicating and integrative plasmids in Penicillium chrysogenum is highly efficient and leads in some cases to rescue of the intact integrative plasmid.Involvement of the Transcriptional Coactivator ThMBF1 in the Biocontrol Activity of Trichoderma harzianum.
P50
Q24531369-4715816F-DF3A-4F91-87EC-AC690B382AEBQ24563186-07CE98A1-2F13-49E1-9D2E-CC8E1EFF82E9Q27303901-91302991-FEBF-4554-B99F-9C378D640ACBQ30975606-3047D2E5-BF7A-4F49-9B45-71D40900C561Q31140089-75CC4629-0823-43E3-86DC-02A63274624FQ31990945-746BC912-B977-41C4-A666-CEE7B8B088F7Q32048656-96010432-5938-48EB-9B85-B1BDA4C421CCQ33248890-F87D5138-3056-49E2-8107-FC9F1562D9E0Q33252037-BDE8F16D-5DD0-442E-9AB0-59ACCE2A525FQ33288343-B520602F-0F8A-4BEC-AF4F-4CC4A2175105Q33383022-5F5A7C7F-37C7-4203-817C-A39C9F77F603Q33480252-60F462C9-267F-4EBE-A381-1B7C0CF5C3CFQ33734536-654837DA-0448-4117-8076-F01C38FF01B9Q34061053-D8D4F9B4-53A9-4FB0-9B22-BB6C8F352494Q34595510-446CBDFC-FDB5-4F52-BDFF-15443295F54EQ35138948-67144D83-6CD2-4C7C-A679-1E2A751AC403Q35973189-CAC8A90F-B90B-486A-9684-77611200A7BAQ36097472-EE1E3737-CF3F-45B5-89F2-6243275A5A9AQ36155750-7888D58D-1AB9-415D-94AA-4536AC986D0AQ36217048-EB945B4D-22F1-4AAB-ACED-F2D1CB3C597EQ36882228-96482CFC-B25D-4C56-9161-6B073E748C96Q37151874-C77D10A7-14E7-4CB0-A5CA-813F913CE7B7Q38176643-38754546-4373-4216-9145-5F58652992E3Q38843747-3DF65CA9-A369-46A8-8873-DD8B798B0251Q39502840-1017EF46-0090-4CF0-A4F7-E709D1656E1CQ40539806-BE842874-5AB5-4DFC-9254-406A39DCAD8EQ40571641-20681E86-A3B2-492F-A9D1-13E9E5A38496Q40744486-4B1D14FF-0B8E-4D95-BBAF-50C5A20EB47CQ41988250-0ECE2A8C-6C49-4979-A316-C17D7729D3F7Q42006492-F7F380AD-97C3-482A-A77A-AB7E6A6A49A6Q42691358-24538C91-6446-4A38-9352-2F719EE8CB1EQ42712669-898ED40A-BE06-40D4-AD27-F0681693880DQ43192084-A3227BBE-1127-4E70-BBA9-50EB268A3D3AQ43409883-1550CE55-1EC6-420F-B938-5AE05F17AC6DQ43835636-34944706-DA60-44A7-BE70-DCC02E93A27DQ43865860-C97765CF-B3C2-4381-8FAB-1BC20103381BQ44098127-DB967E9E-9E9A-4D91-B09B-7FF5552DA2AFQ44463568-549CE1DF-EDFB-4EFA-BF8B-2BE4F352ECE9Q44600932-8441B482-5B77-47F6-BA02-601EFA1B5B07Q46248852-8C7E3A5E-5048-4A22-9916-9A0275CB5076
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Santiago Gutierrez
@ast
Santiago Gutierrez
@en
Santiago Gutierrez
@es
Santiago Gutierrez
@nl
Santiago Gutierrez
@sl
Сантьяго Гутьеррес
@ru
type
label
Santiago Gutierrez
@ast
Santiago Gutierrez
@en
Santiago Gutierrez
@es
Santiago Gutierrez
@nl
Santiago Gutierrez
@sl
Сантьяго Гутьеррес
@ru
prefLabel
Santiago Gutierrez
@ast
Santiago Gutierrez
@en
Santiago Gutierrez
@es
Santiago Gutierrez
@nl
Santiago Gutierrez
@sl
Сантьяго Гутьеррес
@ru
P1053
H-6456-2015
P106
P1153
7006419774
P21
P2798
P31
P3829
P496
0000-0001-6659-1390