Your search keyword '"Éva, Csaba"' showing total 21 results

1. Transcriptome, hormonal, and secondary metabolite changes in leaves of DEFENSE NO DEATH 1 (DND1) silenced potato plants

Author

Bánfalvi, Zsófia, Kalapos, Balázs, Hamow, Kamirán Áron, Jose, Jeny, Éva, Csaba, Odgerel, Khongorzul, Karsai-Rektenwald, Flóra, Villányi, Vanda, and Sági, László

Published

2024

2. bZIP transcription factors repress the expression of wheat (Triticum aestivum L.) high molecular weight glutenin subunit genes in vegetative tissues

Author

Éva, Csaba, Moncsek, Blanka, Szőke-Pázsi, Kitti, Kunos, Viola, Mészáros, Klára, Makai, Szabolcs, Sági, László, and Juhász, Angéla

Published

2023

3. Root-based inorganic carbon uptake increases the growth of Arabidopsis thaliana and changes transporter expression and nitrogen and sulfur metabolism.

Author

Reinoso, Liesel Gamarra, Majláth, Imre, Dernovics, Mihály, Fábián, Attila, Jose, Jeny, Jampoh, Emmanuel Asante, Hamow, Kamirán Áron, Soós, Vilmos, Sági, László, and Éva, Csaba

Subjects

CARBON fixation, SULFUR metabolism, CARBONIC anhydrase, ASPARTIC acid, ARABIDOPSIS thaliana

Abstract

Root-based uptake of inorganic carbon has been suggested as an additional carbon source. Our study aimed to characterize and understand the root-based uptake and fixation mechanisms and their impact on plant growth. 13C-labeled bicarbonate fed to Arabidopsis roots was assimilated into aspartic acid but mainly into sucrose, indicating that the added inorganic carbon was transported to the leaves. A hydroponic treatment was also established for A. thaliana using 2 mM NaHCO3 at pH 5.6, which enhanced the photosynthetic and growth parameters. According to transcriptome sequencing data, the observed enhancement in growth may be orchestrated by trehalose-6-phosphate signaling and supported by augmented nitrogen and sulfur assimilation. The analysis also revealed regulatory and transporter activities, including several nitrate (NRT2.1), and sulfate transporter (SULTR1;1 and SULTR1;2) candidates that could participate in bicarbonate uptake. Different transporters and carbon fixation mutants were assessed. Arabidopsis homologs of SLOW-TYPE ANION CHANNEL 1 (slah3) CARBONIC ANHYDRASE (bca4), and SULFATE TRANSPORTER (sultr1;2) mutants were shown to be inferior to the bicarbonate-treated wild types in several growth and root ultrastructural parameters. Besides, aquaporin genes PIP1;3 and PIP2;6 could play a negative role in the carbon uptake by venting carbon dioxide out of the plant. The findings support the hypothesis that the inorganic carbon is taken up by the root anion channels, mostly transported up to the shoots by the xylem, and fixed there by RuBisCo after the conversion to CO2 by carbonic anhydrases. The process boosts photosynthesis and growth by providing an extra carbon supply. [ABSTRACT FROM AUTHOR]

Published

2024

4. Plant Biotechnology: Its Importance, Contribution to Agriculture and Environment, and Its Future Prospects

Author

Jose, Jeny, primary and Éva, Csaba, additional

Published

2023

5. Cold inducible promoter driven Cre-lox system proved to be highly efficient for marker gene excision in transgenic barley

Author

Éva, Csaba, Téglás, Flóra, Zelenyánszki, Helga, Tamás, Cecília, Juhász, Angéla, Mészáros, Klára, and Tamás, László

Published

2018

6. In Vivo DNA Affinity Purification and Histone Deacetylase Inhibitor Treatment Proves the Role of Histone Acetylation in the Expression Regulation of High-Molecular-Weight Glutenin Genes

Author

Éva, Csaba, Szőke-Pázsi, Kitti, Makai, Szabolcs, Gell, Gyöngyvér, Fábián, Attila, Poczkodi, Edina, Tóth, Gábor, Sági, László, Tamás, László, and Juhász, Angéla

Published

2018

7. Global transcriptome and targeted metabolite analyses of roots reveal different defence mechanisms against Ralstonia solanacearum infection in two resistant potato cultivars

Author

Jose, Jeny, primary, Éva, Csaba, additional, Bozsó, Zoltán, additional, Hamow, Kamirán Áron, additional, Fekete, Zsófia, additional, Fábián, Attila, additional, Bánfalvi, Zsófia, additional, and Sági, László, additional

Published

2023

8. Improved reactive aldehyde, salt and cadmium tolerance of transgenic barley due to the expression of aldo–keto reductase genes

Author

Éva, Csaba, Solti, Ádám, Oszvald, Mária, Tömösközi-Farkas, Rita, Nagy, Bettina, Horváth, Gábor V., and Tamás, László

Published

2016

9. Multiple elements controlling the expression of wheat high molecular weight glutenin paralogs

Author

Makai, Szabolcs, Éva, Csaba, Tamás, László, and Juhász, Angéla

Published

2015

10. Generating Marker-Free Transgenic Wheat Using Minimal Gene Cassette and Cold-Inducible Cre/Lox System

Author

Mészáros, Klára, Éva, Csaba, Kiss, Tibor, Bányai, Judit, Kiss, Eszter, Téglás, Flóra, Láng, László, Karsai, Ildikó, and Tamás, László

Published

2015

11. Methylglyoxal induces stress signaling and promotes the germination of maize at low temperature

Author

Majláth, Imre, primary, Éva, Csaba, additional, Hamow, Kamirán Áron, additional, Kun, József, additional, Pál, Magda, additional, Rahman, Altafur, additional, Palla, Balázs, additional, Nagy, Zoltán, additional, Gyenesei, Attila, additional, Szalai, Gabriella, additional, and Janda, Tibor, additional

Published

2021

12. Overproduction of an Arabidopsis aldo–keto reductase increases barley tolerance to oxidative and cadmium stress by an in vivo reactive aldehyde detoxification

Author

Éva, Csaba, Tóth, Gábor, Oszvald, Mária, and Tamás, László

Published

2014

13. Exogenous methylglyoxal enhances the reactive aldehyde detoxification capability and frost-hardiness of wheat

Author

Majláth, Imre, primary, Éva, Csaba, additional, Tajti, Judit, additional, Khalil, Radwan, additional, Elsayed, Nesma, additional, Darko, Eva, additional, Szalai, Gabriella, additional, and Janda, Tibor, additional

Published

2020

14. Methylglyoxal induces stress signaling and promotes the germination of maize at low temperature.

Author

Majláth, Imre, Éva, Csaba, Hamow, Kamirán Áron, Kun, József, Pál, Magda, Rahman, Altafur, Palla, Balázs, Nagy, Zoltán, Gyenesei, Attila, Szalai, Gabriella, and Janda, Tibor

Subjects

*GERMINATION, *LOW temperatures, *PYRUVALDEHYDE, *GENE expression profiling, *ABSCISIC acid, *JASMONIC acid, *CARBOHYDRATE metabolism, *CORN

Abstract

Maize is sensitive to cold injury, especially during germination. Since cold causes oxidative stress, compounds that promote the accumulation of free radical forms, such as the reactive aldehyde (RA) methylglyoxal (MG), may be suitable to trigger a systemic defense response. In this study, maize seeds were soaked in MG solution for one night at room temperature, before germination test at 13°C. The exogenous MG enhanced the germination and photosynthetic performance of maize at low temperature. Transcriptome analysis, hormonal, and flavonoid profiling indicated MG-induced changes in photosystem antenna proteins, pigments, late embryogenesis abundant proteins, abscisic acid (ABA) derivatives, chaperons, and certain dihydroflavonols, members of the phenylpropanoid pathway. MG-response of the two maize cultivars (A654 and Cm174) were somewhat different, but we recorded higher endogenous hydrogen peroxide (H2O2) and lower nitric oxide (NO) level in at least one of the treated genotypes. These secondary signal molecules may provoke some of the changes in the hormonal, metabolic and gene expression profile. Decreased auxin transport, but increased ABA degradation and cytokinin and jasmonic acid (JA) synthesis, as well as an altered carbohydrate metabolism and transport (amylases, invertases, and SWEET transporters) could have promoted germination of MG-pretreated seeds. While LEA accumulation could have protected against osmotic stress and catalase expression and production of many antioxidants, like para-hydroxybenzoic acid (p-HBA) and anthocyanins may have balanced the oxidative environment for maize germination. Our results showed that MG-pretreatment could be an effective way to promote cold germination and its effect was more pronounced in the originally cold-sensitive maize genotype. [ABSTRACT FROM AUTHOR]

Published

2022

15. Current and possible approaches for improving photosynthetic efficiency

Author

Éva, Csaba, primary, Oszvald, Mária, additional, and Tamás, László, additional

Published

2019

16. Deciphering the regulatory logic of Glu-1 gene promoters

Author

Makai, Szabolcs, Éva, Csaba, Tamás, László, and Juhász, Angéla

Abstract

This poster was made for The Danubia Epegenetic Conference. Related to: "Multiple elements controlling the expression of wheat high molecular weight glutenin paralogs" FIGE, 2015

Published

2015

17. Advances in the regulation of HMW glutenin genes of wheat

Author

Éva, Csaba, primary, Pázsi, Kitti, additional, Makai, Szabolcs, additional, Tamás, László, additional, and Juhász, Angéla, additional

Published

2016

18. Generating Marker-Free Transgenic Wheat Using Minimal Gene Cassette and Cold-Inducible Cre/Lox System

Author

Mészáros, Klára, primary, Éva, Csaba, additional, Kiss, Tibor, additional, Bányai, Judit, additional, Kiss, Eszter, additional, Téglás, Flóra, additional, Láng, László, additional, Karsai, Ildikó, additional, and Tamás, László, additional

Published

2014

19. Corrigendum to ‘Transgenic barley expressing the Arabidopsis AKR4C9 aldo-keto reductase enzyme exhibits enhanced freezing tolerance and regenerative capacity’ [South African Journal of Botany 93 (2014) 179–184]

Author

Éva, Csaba, primary, Zelenyánszki, Helga, additional, Tömösközi-Farkas, Rita, additional, and Tamás, László, additional

Published

2014

20. Transgenic barley expressing the Arabidopsis AKR4C9 aldo-keto reductase enzyme exhibits enhanced freezing tolerance and regenerative capacity

Author

Éva, Csaba, primary, Zelenyánszki, Helga, additional, Tömösközi-Farkas, Rita, additional, and Tamás, László, additional

Published

2014

21. Root-based inorganic carbon uptake increases the growth of Arabidopsis thaliana and changes transporter expression and nitrogen and sulfur metabolism.

Author

Gamarra Reinoso L, Majláth I, Dernovics M, Fábián A, Jose J, Jampoh EA, Hamow KÁ, Soós V, Sági L, and Éva C

Abstract

Root-based uptake of inorganic carbon has been suggested as an additional carbon source. Our study aimed to characterize and understand the root-based uptake and fixation mechanisms and their impact on plant growth. 13 C-labeled bicarbonate fed to Arabidopsis roots was assimilated into aspartic acid but mainly into sucrose, indicating that the added inorganic carbon was transported to the leaves. A hydroponic treatment was also established for A. thaliana using 2 mM NaHCO 3 at pH 5.6, which enhanced the photosynthetic and growth parameters. According to transcriptome sequencing data, the observed enhancement in growth may be orchestrated by trehalose-6-phosphate signaling and supported by augmented nitrogen and sulfur assimilation. The analysis also revealed regulatory and transporter activities, including several nitrate ( NRT2.1 ), and sulfate transporter ( SULTR1;1 and SULTR1;2 ) candidates that could participate in bicarbonate uptake. Different transporters and carbon fixation mutants were assessed. Arabidopsis homologs of SLOW-TYPE ANION CHANNEL 1 (slah3) CARBONIC ANHYDRASE (βca4), and SULFATE TRANSPORTER (sultr1;2) mutants were shown to be inferior to the bicarbonate-treated wild types in several growth and root ultrastructural parameters. Besides, aquaporin genes PIP1;3 and PIP2;6 could play a negative role in the carbon uptake by venting carbon dioxide out of the plant. The findings support the hypothesis that the inorganic carbon is taken up by the root anion channels, mostly transported up to the shoots by the xylem, and fixed there by RuBisCo after the conversion to CO 2 by carbonic anhydrases. The process boosts photosynthesis and growth by providing an extra carbon supply., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2024 Gamarra Reinoso, Majláth, Dernovics, Fábián, Jose, Jampoh, Hamow, Soós, Sági and Éva.)

Published

2024