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Clint Chapple

Showing results (11-20 of 91) with videos related to

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The Arabidopsis Book|February 4, 2012
The phenylpropanoid pathway in ArabidopsisChristopher M Fraser, Clint Chapple
The New Phytologist|July 21, 2010
The origin and evolution of lignin biosynthesisJing-Ke Weng, Clint Chapple
Molecular Plant|December 9, 2009
The ARABIDOPSIS accession Pna-10 is a naturally occurring sng1 deletion mutantXu Li, Joy Bergelson, Clint Chapple
Nature Biotechnology|July 11, 2007
Loosening lignin's grip on biofuel productionClint Chapple, Michael Ladisch, Rick Meilan
BMC Genomics|June 9, 2005
Functional analysis and comparative genomics of expressed sequence tags from the lycophyte Selaginella moellendorffiiJing-Ke Weng, Milos Tanurdzic, Clint Chapple
The Plant Journal : for Cell and Molecular Biology|May 15, 2008
Improvement of biomass through lignin modificationXu Li, Jing-Ke Weng, Clint Chapple
Journal of Experimental Botany|September 11, 2019
Mediator function in plant metabolism revealed by large-scale biologyXiangying Mao, Vikki M Weake, Clint Chapple
The Plant Journal : for Cell and Molecular Biology|December 15, 2010
Over-expression of F5H in COMT-deficient Arabidopsis leads to enrichment of an unusual lignin and disruption of pollen wall formationJing-Ke Weng, Huaping Mo, Clint Chapple
Current Opinion in Biotechnology|January 25, 2019
Linking phenylpropanoid metabolism, lignin deposition, and plant growth inhibitionFabiola Muro-Villanueva, Xiangying Mao, Clint Chapple
The Plant Cell|January 2, 2003
The Arabidopsis ref2 mutant is defective in the gene encoding CYP83A1 and shows both phenylpropanoid and glucosinolate phenotypesMatthew R Hemm, Max O Ruegger, Clint Chapple
Pageof 10

Showing results (11-20 of 91) with videos related to

Sort By:
Pageof 10
The Arabidopsis Book|February 4, 2012
The phenylpropanoid pathway in ArabidopsisChristopher M Fraser, Clint Chapple
The New Phytologist|July 21, 2010
The origin and evolution of lignin biosynthesisJing-Ke Weng, Clint Chapple
Molecular Plant|December 9, 2009
The ARABIDOPSIS accession Pna-10 is a naturally occurring sng1 deletion mutantXu Li, Joy Bergelson, Clint Chapple
Nature Biotechnology|July 11, 2007
Loosening lignin's grip on biofuel productionClint Chapple, Michael Ladisch, Rick Meilan
BMC Genomics|June 9, 2005
Functional analysis and comparative genomics of expressed sequence tags from the lycophyte Selaginella moellendorffiiJing-Ke Weng, Milos Tanurdzic, Clint Chapple
The Plant Journal : for Cell and Molecular Biology|May 15, 2008
Improvement of biomass through lignin modificationXu Li, Jing-Ke Weng, Clint Chapple
Journal of Experimental Botany|September 11, 2019
Mediator function in plant metabolism revealed by large-scale biologyXiangying Mao, Vikki M Weake, Clint Chapple
The Plant Journal : for Cell and Molecular Biology|December 15, 2010
Over-expression of F5H in COMT-deficient Arabidopsis leads to enrichment of an unusual lignin and disruption of pollen wall formationJing-Ke Weng, Huaping Mo, Clint Chapple
Current Opinion in Biotechnology|January 25, 2019
Linking phenylpropanoid metabolism, lignin deposition, and plant growth inhibitionFabiola Muro-Villanueva, Xiangying Mao, Clint Chapple
The Plant Cell|January 2, 2003
The Arabidopsis ref2 mutant is defective in the gene encoding CYP83A1 and shows both phenylpropanoid and glucosinolate phenotypesMatthew R Hemm, Max O Ruegger, Clint Chapple
Pageof 10