Login
Registrieren
Passwort zurücksetzen
Veröffentlichen & Verteilen
Verlagslösungen
Vertriebslösungen
Themen
Allgemein
Altertumswissenschaften
Architektur und Design
Bibliotheks- und Informationswissenschaft, Buchwissenschaft
Biologie
Chemie
Geowissenschaften
Geschichte
Industrielle Chemie
Informatik
Jüdische Studien
Kulturwissenschaften
Kunst
Linguistik und Semiotik
Literaturwissenschaft
Materialwissenschaft
Mathematik
Medizin
Musik
Pharmazie
Philosophie
Physik
Rechtswissenschaften
Sozialwissenschaften
Sport und Freizeit
Technik
Theologie und Religion
Wirtschaftswissenschaften
Veröffentlichungen
Zeitschriften
Bücher
Konferenzberichte
Verlage
Blog
Kontakt
Suche
EUR
USD
GBP
Deutsch
English
Deutsch
Polski
Español
Français
Italiano
Warenkorb
Home
Zeitschriften
The EuroBiotech Journal
Band 4 (2020): Heft 1 (January 2020)
Uneingeschränkter Zugang
Effects of zinc and molybdenum on European Bluestar (
Amsonia orientalis
): An
in vitro
study
Arda Acemi
Arda Acemi
,
Yonca Avcı Duman
Yonca Avcı Duman
,
Yonca Yüzügüllü Karakuş
Yonca Yüzügüllü Karakuş
und
Fazıl Özen
Fazıl Özen
| 18. Jan. 2020
The EuroBiotech Journal
Band 4 (2020): Heft 1 (January 2020)
Über diesen Artikel
Vorheriger Artikel
Nächster Artikel
Zusammenfassung
Artikel
Figuren und Tabellen
Referenzen
Autoren
Artikel in dieser Ausgabe
Vorschau
PDF
Zitieren
Teilen
Article Category:
Research Article
Online veröffentlicht:
18. Jan. 2020
Seitenbereich:
32 - 41
DOI:
https://doi.org/10.2478/ebtj-2020-0005
Schlüsselwörter
Molybdenum
,
oxidative stress
,
tissue culture
,
zinc
© 2020 Arda Acemi, Yonca Avcı Duman, Yonca Yüzügüllü Karakuş and Fazıl Özen, published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.
Figure 1
Effects of in vitro Zn and Mo exposure on shoot and root numbers, and lengths of Amsonia orientalis. Mean shoot and root numbers after Zn exposure (a); Mean shoot and root numbers after Mo exposure (b); Mean shoot and root lengths after Zn exposure (c); Mean shoot and root lengths after Mo exposure (d). Values are represented as means ± SD; different letters denote significant differences at p < 0.05.
Figure 2
Changes in the soluble protein and prolin contents of Amsonia orientalis as a result of in vitro treatment with Zn and Mo. Soluble protein content after Zn exposure (a); Soluble protein content after Mo exposure (b); Proline content after Zn exposure (c); Proline content after Mo exposure (d). Values are represented as means ± SD; different letters denote significant differences at p < 0.05.
Figure 3
Changes in malondialdehyde (MDA) and hydrogen peroxide (H2O2) contents in Amsonia orientalis as a result of in vitro treatment with Zn and Mo. MDA content after Zn exposure (a); MDA content after Mo exposure (b); H2O2 content after Zn exposure (c); H2O2 content after Mo exposure (d). Values are represented as means ± SD; different letters denote significant differences at p < 0.05.
Figure 4
Changes in superoxide dismutase (SOD) activity in Amsonia orientalis as a result of in vitro treatment with Zn and Mo. SOD activity after Zn exposure (a); SOD activity after Mo exposure (b). Values are represented as means ± SD; different letters denote significant differences at p < 0.05.
Figure 5
Changes in peroxidase (POD) activity in Amsonia orientalis as a result of in vitro treatment with Zn and Mo. POD activity after Zn exposure (a); POD activity after Mo exposure (b). Values are represented as means ± SD; different letters denote significant differences at p < 0.05.
Figure 6
Changes in catalase (CAT) activity in Amsonia orientalis as a result of in vitro treatment with Zn and Mo. CAT activity after Zn exposure (a); CAT activity after Mo exposure (b). Values are represented as means ± SD; different letters denote significant differences at p < 0.05.
Vorschau