Site-specific, silicon-induced structural and molecular defence responses against powdery mildew infection in roses

Research output: Contribution to journalJournal articleResearchpeer-review

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Site-specific, silicon-induced structural and molecular defence responses against powdery mildew infection in roses. / Shetty, Radhakrishna; Jensen, Birgit; Shelton, Dale; Jørgensen, Kirsten; Pedas, Pai; Jørgensen, Hans Jørgen Lyngs.

In: Pest Management Science, Vol. 77, No. 10, 2021, p. 4545-4554.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Shetty, R, Jensen, B, Shelton, D, Jørgensen, K, Pedas, P & Jørgensen, HJL 2021, 'Site-specific, silicon-induced structural and molecular defence responses against powdery mildew infection in roses', Pest Management Science, vol. 77, no. 10, pp. 4545-4554. https://doi.org/10.1002/ps.6493

APA

Shetty, R., Jensen, B., Shelton, D., Jørgensen, K., Pedas, P., & Jørgensen, H. J. L. (2021). Site-specific, silicon-induced structural and molecular defence responses against powdery mildew infection in roses. Pest Management Science, 77(10), 4545-4554. https://doi.org/10.1002/ps.6493

Vancouver

Shetty R, Jensen B, Shelton D, Jørgensen K, Pedas P, Jørgensen HJL. Site-specific, silicon-induced structural and molecular defence responses against powdery mildew infection in roses. Pest Management Science. 2021;77(10):4545-4554. https://doi.org/10.1002/ps.6493

Author

Shetty, Radhakrishna ; Jensen, Birgit ; Shelton, Dale ; Jørgensen, Kirsten ; Pedas, Pai ; Jørgensen, Hans Jørgen Lyngs. / Site-specific, silicon-induced structural and molecular defence responses against powdery mildew infection in roses. In: Pest Management Science. 2021 ; Vol. 77, No. 10. pp. 4545-4554.

Bibtex

@article{820abeade4ea4bf8b2b98ac89c744bd2,
title = "Site-specific, silicon-induced structural and molecular defence responses against powdery mildew infection in roses",
abstract = "BACKGROUND: Silicon (Si) application to miniature potted roses can decrease severity of powdery mildew (Podosphaera pannosa) and this is associated with increased accumulation of callose and hydrogen peroxide (H2O2) as well as hypersensitive (HR) cells. We used microscopy, gene expression and specific inhibitors of callose and H2O2 to determine how effective these plant responses are in stopping infection. RESULTS: Pathogen arrest in Si-treated (Si+) plants was accompanied by increased accumulation of callose and H2O2 in papillae and HR cells, respectively. These responses were reduced by application of specific inhibitors (2-deoxy-d-glucose for callose and catalase for H2O2), which increased disease severity in Si+, but not in Si− plants. As markers for HR and callose, expression of the HR-specific gene hsr203J and the wound-related callose synthase GSL5, respectively, was studied. An up-regulation of expression was only seen after isolation of HR cells with laser capture microdissection. The up-regulation was higher in Si+ than in Si− plants and occurred concomitantly with more efficient photosynthesis in Si+ plants at high disease severity as compared to Si− plants. CONCLUSION: Silicon-mediated activation of callose and H2O2 are decisive factors in the defence of rose against P. pannosa and these responses were accompanied with more efficient photosynthesis to strengthen the plant. Only by isolation of HR cells using laser capture microdissection as compared to analysis of whole leaf tissues allowed detection of elevated transcript levels of hsr203J and GSL5 at infection sites as markers for HR.",
keywords = "callose, hypersensitive response, inhibitors, laser capture microdissection, miniature potted rose, silicon",
author = "Radhakrishna Shetty and Birgit Jensen and Dale Shelton and Kirsten J{\o}rgensen and Pai Pedas and J{\o}rgensen, {Hans J{\o}rgen Lyngs}",
year = "2021",
doi = "10.1002/ps.6493",
language = "English",
volume = "77",
pages = "4545--4554",
journal = "Pest Management Science",
issn = "1526-498X",
publisher = "JohnWiley & Sons Ltd",
number = "10",

}

RIS

TY - JOUR

T1 - Site-specific, silicon-induced structural and molecular defence responses against powdery mildew infection in roses

AU - Shetty, Radhakrishna

AU - Jensen, Birgit

AU - Shelton, Dale

AU - Jørgensen, Kirsten

AU - Pedas, Pai

AU - Jørgensen, Hans Jørgen Lyngs

PY - 2021

Y1 - 2021

N2 - BACKGROUND: Silicon (Si) application to miniature potted roses can decrease severity of powdery mildew (Podosphaera pannosa) and this is associated with increased accumulation of callose and hydrogen peroxide (H2O2) as well as hypersensitive (HR) cells. We used microscopy, gene expression and specific inhibitors of callose and H2O2 to determine how effective these plant responses are in stopping infection. RESULTS: Pathogen arrest in Si-treated (Si+) plants was accompanied by increased accumulation of callose and H2O2 in papillae and HR cells, respectively. These responses were reduced by application of specific inhibitors (2-deoxy-d-glucose for callose and catalase for H2O2), which increased disease severity in Si+, but not in Si− plants. As markers for HR and callose, expression of the HR-specific gene hsr203J and the wound-related callose synthase GSL5, respectively, was studied. An up-regulation of expression was only seen after isolation of HR cells with laser capture microdissection. The up-regulation was higher in Si+ than in Si− plants and occurred concomitantly with more efficient photosynthesis in Si+ plants at high disease severity as compared to Si− plants. CONCLUSION: Silicon-mediated activation of callose and H2O2 are decisive factors in the defence of rose against P. pannosa and these responses were accompanied with more efficient photosynthesis to strengthen the plant. Only by isolation of HR cells using laser capture microdissection as compared to analysis of whole leaf tissues allowed detection of elevated transcript levels of hsr203J and GSL5 at infection sites as markers for HR.

AB - BACKGROUND: Silicon (Si) application to miniature potted roses can decrease severity of powdery mildew (Podosphaera pannosa) and this is associated with increased accumulation of callose and hydrogen peroxide (H2O2) as well as hypersensitive (HR) cells. We used microscopy, gene expression and specific inhibitors of callose and H2O2 to determine how effective these plant responses are in stopping infection. RESULTS: Pathogen arrest in Si-treated (Si+) plants was accompanied by increased accumulation of callose and H2O2 in papillae and HR cells, respectively. These responses were reduced by application of specific inhibitors (2-deoxy-d-glucose for callose and catalase for H2O2), which increased disease severity in Si+, but not in Si− plants. As markers for HR and callose, expression of the HR-specific gene hsr203J and the wound-related callose synthase GSL5, respectively, was studied. An up-regulation of expression was only seen after isolation of HR cells with laser capture microdissection. The up-regulation was higher in Si+ than in Si− plants and occurred concomitantly with more efficient photosynthesis in Si+ plants at high disease severity as compared to Si− plants. CONCLUSION: Silicon-mediated activation of callose and H2O2 are decisive factors in the defence of rose against P. pannosa and these responses were accompanied with more efficient photosynthesis to strengthen the plant. Only by isolation of HR cells using laser capture microdissection as compared to analysis of whole leaf tissues allowed detection of elevated transcript levels of hsr203J and GSL5 at infection sites as markers for HR.

KW - callose

KW - hypersensitive response

KW - inhibitors

KW - laser capture microdissection

KW - miniature potted rose

KW - silicon

U2 - 10.1002/ps.6493

DO - 10.1002/ps.6493

M3 - Journal article

C2 - 34075680

AN - SCOPUS:85108364712

VL - 77

SP - 4545

EP - 4554

JO - Pest Management Science

JF - Pest Management Science

SN - 1526-498X

IS - 10

ER -

ID: 273579485