Differential spore production by Botrytis cinerea on agar medium and plant tissue under near-ultraviolet light-absorbing polyethylene film

Plastic films containing additives that alter their transmission of the light spectrum may be useful tools for the control of aerial plant pathogens of greenhouse crops. Several samples of polyethylene films containing additives that absorb near ultraviolet (nUV) light in the range 280 to 380 nm wer...

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Bibliographic Details
Published inPlant disease Vol. 80; no. 5
Main Authors Nicot, P.C. (INRA, Avignon, France.), Mermier, M, Vaissiere, B.E, Lagier, J
Format Journal Article
LanguageEnglish
Published 1996
Subjects
ABSORBANCE
ABSORBANCIA
ABSORCION
ABSORPTION
BOTRYTIS CINEREA
CONTROL CULTURAL
CONTROL DE ENFERMEDADES
CONTROLE DE MALADIES
COTILEDONES
COTYLEDON
CRECIMIENTO
CROISSANCE
CUCUMIS MELO
CUCUMIS SATIVUS
CULTIVOS DE INVERNADERO
ENFERMEDADES FUNGOSAS
ESPORAS
ESPORULACION
FILM PLASTIQUE
FLEUR
FLORES
GERMINACION
GERMINATION
LUTTE CULTURALE
LYCOPERSICON ESCULENTUM
MALADIE FONGIQUE
MEDIO DE CULTIVO
MICELIO
MILIEU DE CULTURE
MYCELIUM
PELICULA PLASTICA
PLANTE DE SERRE
POLIETILENO
POLYETHYLENE
PROPIEDADES OPTICAS
PROPRIETE OPTIQUE
RADIACION ULTRAVIOLETA
RAYONNEMENT ULTRAVIOLET
SPORE
SPORULATION
TALLO
TEJIDOS VEGETALES
TIGE
TISSU VEGETAL
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Summary:Plastic films containing additives that alter their transmission of the light spectrum may be useful tools for the control of aerial plant pathogens of greenhouse crops. Several samples of polyethylene films containing additives that absorb near ultraviolet (nUV) light in the range 280 to 380 nm were compared for their ability to affect spore germination, mycelial growth, and sporulation of Botrytis cinerea on agar medium. One film was selected and further evaluated. The kinetics of spore production by the pathogen was similar on agar medium and on tomato stem tissue, and whether incubation took place under the nUV-absorbing film or under a control film. However, spore production on both types of substrates under the nUV film remained at less than 0.05% that of the control for several weeks after inoculation, demonstrating that the nUV film inhibited rather than delayed sporulation. A sharp reduction of spore production was also observed on other plant tissues. However, the efficiency of the nUV film appeared different for different plants, and it was lower on flowers and cotyledons than on stem tissue. Two of the five strains of B. cinerea tested on tomato stem tissue were less sensitive to sporulation inhibition by the nUV film. To clarify the potential of nUV films for the control of gray mold on greenhouse crops, the epidemiological significance of these results needs to be further examined in light of the abundance of such strains in the environment
Bibliography:9619418
F60
H20
ISSN:0191-2917
1943-7692
DOI:10.1094/PD-80-0555