Randy Woodson

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Horticultural science: A translational science with a strong past and a bright future

HortScience, 44(7), 2063–2064.

Diversity of Function in the Isocitrate Lyase Enzyme Superfamily:  The Dianthus caryophyllus Petal Death Protein Cleaves α-Keto and α-Hydroxycarboxylic Acids†

Biochemistry, 44(50), 16365–16376.

Diversity of function in the isocitrate lyase enzyme superfamily: The Dianthus caryophyllus petal death protein cleaves alpha-keto and alpha-hydroxycarboxylic acids

Biochemistry, 44(50), 16365–16376.

In search of eternal youth: The delay of postharvest senescence in flowers

ELEGANT SCIENCE IN FLORICULTURE, pp. 305–314.

Changes in ethylene responsiveness of senescence-related genes during carnation flower development

PHYSIOLOGIA PLANTARUM, 116(4), 503–511.

Pollination signals and flower senescence

In S. D. O'Neill & J. A. Roberts (Eds.), Plant reproduction. Sheffield, UK: Sheffield Academic Press.

Protection of intellectual property in plant breeding and biotechnology: A land grant university perspective

Biotechnology, gene flow, and intellectual property rights : ?b an agricultural summit : proceedings of a conference held September 13, 2002, in Indianapolis, Indiana. West Lafayette, IN: Purdue University.

Report of the Altered Ripening Working Group

Proceedings of a Workshop on criteria for field testing of plants with engineered regulatory, metabolic and signaling pathways. Blacksburg, VA.: Information Systems for Biotechnology, Virginia Tech Press.

It's all about learning: An inquiry-based approach to teaching plant physiology

HortTechnology, 10, 277–279.

Learning in an inquiry-driven plant physiology laboratory

Journal of Natural Resources and Life Sciences Education, 29, 31–35.

Accumulation of 1-aminocyclopropane-1-carboxylic acid (ACC) in petunia pollen is associated with expression of a pollen-specific ACC synthase late in development

JOURNAL OF THE AMERICAN SOCIETY FOR HORTICULTURAL SCIENCE, 124(2), 145–151.

Differential expression of three members of the 1-aminocyclopropane-1-carboxylate synthase gene family in carnation

PLANT PHYSIOLOGY, 119(2), 755–764.

Inhibition of catalase by antisense RNA increases susceptibility to oxidative stress and chilling injury in transgenic tomato plants

JOURNAL OF THE AMERICAN SOCIETY FOR HORTICULTURAL SCIENCE, 124(4), 330–336.

Interorgan signaling following pollination in carnations

JOURNAL OF THE AMERICAN SOCIETY FOR HORTICULTURAL SCIENCE, 124(6), 598–604.

Regulation and function of pollination-induced ethylene in carnation and petunia flowers

In C. C. A. K. Kanellis, A. B. B. H. Klee, J. C. Pech, & D. Grierson (Eds.), Biology and biotechnology of the plant hormone ethylene II (pp. 195–201). Kluwer Academic.

Ethylene-responsive gene expression during carnation flower senescence

In W. A. L. R. L. Bieleski & C. J. Clark (Eds.), Postharvest 96 : International Postharvest Science Conference, Taupo, New Zealand, 4th to 9th of August, 1996 (Vol. 464, pp. 135–140).

The physiological and molecular responses of carnation flowers to high temperature

POSTHARVEST BIOLOGY AND TECHNOLOGY, 14(2), 185–192.

Biotechnology and horticulture

HortScience, 32(6), 1021–1023.

Oxidative stress and diurnal variation in chilling sensitivity of tomato seedlings

JOURNAL OF THE AMERICAN SOCIETY FOR HORTICULTURAL SCIENCE, 122(4), 485–490.

Pollination-induced ethylene and flower senescence in carnation

In Australasian Postharvest Horticulture Conference report : globalisation : the challenge to home and export markets. NSW, Australia: University of Western Sydney Hawkesbury Press.

Pollination-induced ethylene in carnation - Role of stylar ethylene in corolla senescence

PLANT PHYSIOLOGY, 115(1), 205–212.

Transcriptional regulation of senescence-related genes in carnation flowers

In C. C. A. K. Kanellis, H. Kende, & D. Grierson (Eds.), Biology and biotechnology of the plant hormone ethylene.

Cloning of a DNA-binding protein that interacts with the ethylene-responsive enhancer element of the carnation GST1 gene

PLANT MOLECULAR BIOLOGY, 31(4), 751–759.

Temporal and spatial expression of 1-aminocyclopropane-1-carboxylate oxidase mRNA following pollination of immature and mature petunia flowers

PLANT PHYSIOLOGY, 112(2), 503–511.

ETHYLENE-REGULATED EXPRESSION OF A CARNATION CYSTEINE PROTEINASE DURING FLOWER PETAL SENESCENCE

PLANT MOLECULAR BIOLOGY, 28(3), 505–512.

POLLINATION-INDUCED ETHYLENE IN CARNATION

PLANT PHYSIOLOGY, 108(4), 1405–1412.

Transformation of carnation by microprojectile bombardment

SCIENTIA HORTICULTURAE, 64(3), 177–185.

AN ETHYLENE-RESPONSIVE ENHANCER ELEMENT IS INVOLVED IN THE SENESCENCE-RELATED EXPRESSION OF THE CARNATION GLUTATHIONE-S-TRANSFERASE (GSTI) GENE

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 91(19), 8925–8929.

ENHANCEMENT OF ETHYLENE BIOSYNTHESIS AND GERMINATION WITH THIDIAZURON AND SOME SELECTED AUXINS IN STRIGA-ASIATICA SEEDS

PHYSIOLOGIA PLANTARUM, 91(3), 529–536.

Ethylene biosynthesis in Striga seeds and its possible use as a probe for germination stimulants

In J. A. C. V. A. H. Pieterse & S. J. Borg (Eds.), Biology and management of Orobanche : proceedings of the third International Workshop on Orobanche and related Striga research, Amsterdam, The Netherlands, November 8-12, 1993. Royal Tropical Institute.

Molecular biology of flower senescence in carnation

In R. J. Scott & A. D. Stead (Eds.), Molecular and cellular aspects of plant reproduction. Cambridge: Cambridge University Press.

Pistil-specific and ethylene-regulated expression of 1-aminocyclopropane-1-carboxylate oxidase genes in petunia flowers

Plant Cell, 6(9), 1227–1239.

A FLOWER SENESCENCE-RELATED MESSENGER-RNA FROM CARNATION ENCODES A NOVEL PROTEIN RELATED TO ENZYMES INVOLVED IN PHOSPHONATE BIOSYNTHESIS

WANG, H., BRANDT, A. S., & WOODSON, W. R. (1993, July). PLANT MOLECULAR BIOLOGY, Vol. 22, pp. 719–724.

CHARACTERIZATION OF AN ETHYLENE-RESPONSIVE GLUTATHIONE-S-TRANSFERASE GENE-CLUSTER IN CARNATION

PLANT MOLECULAR BIOLOGY, 22(1), 43–58.

ENHANCEMENT OF ETHYLENE BIOSYNTHESIS AND GERMINATION BY CYTOKININS AND 1-AMINOCYCLOPROPANE-1-CARBOXYLIC ACID IN STRIGA-ASIATICA SEEDS

PHYSIOLOGIA PLANTARUM, 89(1), 21–26.

EXPRESSION OF ETHYLENE BIOSYNTHETIC-PATHWAY MESSENGER-RNAS IS SPATIALLY REGULATED WITHIN CARNATION FLOWER PETALS

JOURNAL OF PLANT PHYSIOLOGY, 141(6), 663–667.

Ethylene and interorgan signaling in flowers following pollination

In J. Schultz & I. Raskin (Eds.), Plant signals in interactions with other organisms : proceedings 8th annual Penn State symposium in plant physiology, May 20-22, 1993. Rockville, MD: American Society of Plant Physiologists.

Ethylene biosynthesis and strigol-induced germination of striga-asiatica

Physiologia Plantarum, 88(2), 359–365.

ORGANIZATION AND STRUCTURE OF THE 1-AMINOCYCLOPROPANE-1-CARBOXYLATE OXIDASE GENE FAMILY FROM PETUNIA-HYBRIDA

PLANT MOLECULAR BIOLOGY, 23(6), 1151–1164.

Regulation and function of flower senescence-related genes

In R. H. Z. R. A. Hammerschlag & L. D. Owens (Eds.), Second International Symposium on In Vitro Culture and Horticultural Breeding: Baltimore, Maryland, U.S.A., June 28-July 2, 1992 (Vol. 336, pp. 41–46).

EXPRESSION OF ETHYLENE BIOSYNTHETIC-PATHWAY TRANSCRIPTS IN SENESCING CARNATION FLOWERS

PLANT PHYSIOLOGY, 99(2), 526–532.

Ethylene regulation and function of flower senescence-related genes

In A. L. J. C. Pech & C. Balague? (Eds.), Cellular and molecular aspects of the plant hormone ethylene : proceedings of the International Symposium on Cellular and Molecular Aspects of Biosynthesis and Action of the Plant Hormone Ethylene, Agen, France, August 31st - September 4th, 1992. Kluwer Academic.

MOLECULAR-CLONING AND NUCLEOTIDE-SEQUENCE OF A CDNA-ENCODING CATALASE FROM TOMATO

DRORY, A., & WOODSON, W. R. (1992, November). PLANT PHYSIOLOGY, Vol. 100, pp. 1605–1606.

MOLECULAR-CLONING OF AN 1-AMINOCYCLOPROPANE-1-CARBOXYLATE SYNTHASE FROM SENESCING CARNATION FLOWER PETALS

PLANT MOLECULAR BIOLOGY, 18(2), 377–386.

NUCLEOTIDE-SEQUENCE OF A CDNA-ENCODING THE ETHYLENE-FORMING ENZYME FROM PETUNIA COROLLAS

PLANT PHYSIOLOGY, 100(1), 535–536.

VARIATION IN FLOWER SENESCENCE AND ETHYLENE BIOSYNTHESIS AMONG CARNATIONS

HORTSCIENCE, 27(10), 1100–1102.

A FLOWER SENESCENCE-RELATED MESSENGER-RNA FROM CARNATION SHARES SEQUENCE SIMILARITY WITH FRUIT RIPENING-RELATED MESSENGER-RNAS INVOLVED IN ETHYLENE BIOSYNTHESIS

WANG, H., & WOODSON, W. R. (1991, July). PLANT PHYSIOLOGY, Vol. 96, pp. 1000–1001.

AN ETHYLENE-RESPONSIVE FLOWER SENESCENCE-RELATED GENE FROM CARNATION ENCODES A PROTEIN HOMOLOGOUS TO GLUTATHIONE S-TRANSFERASES

MEYER, R. C., GOLDSBROUGH, P. B., & WOODSON, W. R. (1991, August). PLANT MOLECULAR BIOLOGY, Vol. 17, pp. 277–281.

BIOTECHNOLOGY OF FLORICULTURAL CROPS

HORTSCIENCE, 26(8), 1029–1033.

CHARACTERIZATION OF AN ETHYLENE-REGULATED FLOWER SENESCENCE-RELATED GENE FROM CARNATION

PLANT MOLECULAR BIOLOGY, 17(1), 61–71.

CLONING AND NUCLEOTIDE-SEQUENCE OF A S-ADENOSYLMETHIONINE SYNTHETASE CDNA FROM CARNATION

LARSEN, P. B., & WOODSON, W. R. (1991, July). PLANT PHYSIOLOGY, Vol. 96, pp. 997–999.

Gene expression and flower senescence

In F. S. J. Harding & J. N. M. Mol (Eds.), Genetics and breeding of ornamental species. Kluwer Academic.

ROLE OF THE GYNOECIUM IN CYTOKININ-INDUCED CARNATION PETAL SENESCENCE

JOURNAL OF THE AMERICAN SOCIETY FOR HORTICULTURAL SCIENCE, 116(4), 676–679.

REGULATION OF SENESCENCE-RELATED GENE-EXPRESSION IN CARNATION FLOWER PETALS BY ETHYLENE

PLANT PHYSIOLOGY, 93(4), 1370–1375.

Regulation of gene expression in senescing carnation petals

In Horticultural biotechnology : proceedings of the Horticultural Biotechnology Symposium, held at the University of California, Davis, California, August 21-23, 1989 (pp. 203–212). New York: Wiley-Liss.

Ethylene-regulated gene expression during carnation petal senescence

Fourth International Symposium on Postharvest Physiology of Ornamental Plants: Herzliya, Israel, 20-25 March, 1988, 261, 137–144.

MOLECULAR-CLONING AND CHARACTERIZATION OF SENESCENCE-RELATED GENES FROM CARNATION FLOWER PETALS

PLANT PHYSIOLOGY, 90(2), 690–696.

Physiology and biochemistry of flower petal senescence

Horticultural Reviews, 11, 15–43.

REVERSIBLE INHIBITION OF ETHYLENE ACTION AND INTERRUPTION OF PETAL SENESCENCE IN CARNATION FLOWERS BY NORBORNADIENE

PLANT PHYSIOLOGY, 89(2), 434–438.

Regulation of gene expression by ethylene during carnation flower scenescence

Plant Physiology, 89(Suppl. 4), 48.

BIOCHEMICAL BASIS OF HIGH-TEMPERATURE INHIBITION OF ETHYLENE BIOSYNTHESIS IN RIPENING TOMATO FRUITS

PHYSIOLOGIA PLANTARUM, 72(3), 572–578.

Dark-induced abscission of hibiscus flower buds

HortScience, 23(3), 592–593.

ETHYLENE-INDUCED GENE-EXPRESSION IN CARNATION PETALS - RELATIONSHIP TO AUTOCATALYTIC ETHYLENE PRODUCTION AND SENESCENCE

PLANT PHYSIOLOGY, 87(2), 498–503.

CHANGES IN PROTEIN AND MESSENGER-RNA POPULATIONS DURING THE SENESCENCE OF CARNATION PETALS

PHYSIOLOGIA PLANTARUM, 71(4), 495–502.

CHANGES IN PROTEIN-PATTERNS AND INVIVO PROTEIN-SYNTHESIS DURING PRESENESCENCE AND SENESCENCE OF HIBISCUS PETALS

JOURNAL OF PLANT PHYSIOLOGY, 128(1-2), 67–75.

INVERTASES OF CARNATION PETALS - PARTIAL-PURIFICATION, CHARACTERIZATION AND CHANGES IN ACTIVITY DURING PETAL GROWTH

PHYSIOLOGIA PLANTARUM, 71(2), 224–228.

NITROGEN RATE AND CULTIVAR EFFECTS ON NITROGEN AND NITRATE CONCENTRATION OF SWEET-POTATO LEAF TISSUE

COMMUNICATIONS IN SOIL SCIENCE AND PLANT ANALYSIS, 18(5), 529–541.

Postharvest handling of bud-cut freesia flowers

HortScience, 22(3), 456–458.

Induction of lateral branching in chinese hibiscus with mefluidide

HortScience, 21(1), 71–73.

The effect of storage and wounding on ethylene production by sweet-potato

HortScience, 21(4), 1018–1019.

ROLE OF ETHYLENE IN THE SENESCENCE OF ISOLATED HIBISCUS PETALS

PLANT PHYSIOLOGY, 79(3), 679–683.

Responses of caladium tubers to low, nonfreezing temperatures

HortScience, 20(5), 929–931.

Relationship between nitrate reductase-activity, nitrogen accumulation, and nitrogen partitioning in chrysanthemum

Journal of the American Society for Horticultural Science, 109(4), 491–494.

Accumulation and partitioning of nitrogen and dry-matter during the growth of chrysanthemum

HortScience, 18(2), 196–197.

PETIOLE NITRATE CONCENTRATION AS AN INDICATOR OF GERANIUM NITROGEN STATUS

COMMUNICATIONS IN SOIL SCIENCE AND PLANT ANALYSIS, 14(5), 363–371.

Effects of nitrogen form and potassium concentration on growth, flowering, and nitrogen-utilization of greenhouse roses

Journal of the American Society for Horticultural Science, 107(2), 275–278.

Influence of potassium on the growth, flowering, and chemical-composition of greenhouse roses grown in recirculating nutrient solutions

HortScience, 17(1), 46–47.

The influence of potassium on the growth, flowering and nitrogen utilization of greenhouse roses