Kinga Balassa scite author profile

Kinga Balassa

3Publications

7Citation Statements Received

42Citation Statements Given

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160

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Eötvös Loránd University

Publications

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Expression Pattern of RNA Interference Genes During Drought Stress and MDMV Infection in Maize

Balassa

Janda

et al. 2022

J Plant Growth Regul

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When stress factors trigger transcriptional and metabolic changes, RNA interference (RNAi) is associated with gene expression regulation at the transcriptional and post-transcriptional levels. RDR, DCL and AGO proteins contribute to these gene silencing processes during stress reactions and plant development. An entire revision of the maize RDR, DCL and AGO genes was carried out prior to the experiments. In this study, the transcript changes of a total of 4 ZmRDR, 5 ZmDCL and 17 ZmAGO genes were analysed in maize during either drought stress or MDMV infection, with or without salicylic acid pre-treatment or siRNA pre-treatment, respectively. The gene expression profiles showed the early, middle and late activity of these genes. Drought stress caused major changes in the expression profiles, indicating that there were various steps in stress response regulation. Moreover, insights were gained into the fine-tuning mechanisms of SA regulation. In the case of MDMV infection less diverse trends were observed, which were mainly focused on antiviral defence. However, treatment with exogenous siRNA seems to be an appropriate tool for the targeted influencing of RNAi, especially of AGO genes. These results represent the first contribution to the relationship between RNAi and salicylate signalling and between viral infection and siRNA-triggered defence in maize.

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Physiological and Molecular Background of Maize Cold-Tolerance Enhancement with S-methylmethionine Salicylate

Balassa

Oláh²,

Balassa³

et al. 2022

J Plant Growth Regul

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Low temperature is amongst the most influential abiotic stress factors, having deep impact on plant growth, yield and productivity. Studies on beneficial effects of certain biologically active substances, S-methylmethionine (SMM) and salicylic acid (SA) have provided a lot of valuable information regarding their role to counteract harmful effects of environmental stresses such as chilling. To obtain a more complex and stable defence compound with an extended range of stress-protective effect, the new derivative S-methylmethionine salicylate (MMS) was synthesised from the natural, biologically active substances SMM and SA. Since both original materials have complex stress-protective roles, the new compound was expected to combine the effects of original substances and to stabilise the unstable SMM in the new compound, thus providing an extended stress tolerance. Photosynthetic efficiency and accumulation of stress-related metabolites (polyamines and flavonoids) were measured in chilled and control plants, with and without MMS pretreatment, and expression changes of several genes involved in the cold stress response were analysed by quantitative real-time PCR (RT-qPCR) and a detailed microarray study. Our data show how the MMS combines the effect of SMM and SA on molecular level, causing numerous changes in the gene expression pattern and metabolite content. MMS gives rise to a better physiological condition, thus it could provide an alternative, environmental friendly way to enhance the plants defence mechanisms against stressors. As MMS is more stable than SMM, it promises easier, more long-lasting and more cost-effective usage in agriculture, with a complementing effect of SA.

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Changes in physiology, gene expression and ethylene biosynthesis in MDMV-infected sweet corn primed by small RNA pre-treatment

Balassa

Gondor

et al. 2021

Saudi Journal of Biological Sciences

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The physiological condition of plants is significantly affected by viral infections. Viral proliferation occurs at the expense of the energy and protein stores in infected plant cells. At the same time, plants invest much of their remaining resources in the fight against infection, making them even less capable of normal growth processes. Thus, the slowdown in the development and growth processes of plants leads to a large-scale decrease in plant biomass and yields, which may be a perceptible problem even at the level of the national economy. One form of protection against viral infections is treatment with small interfering RNA (siRNA) molecules, which can directly reduce the amount of virus that multiplies in plant cells by enhancing the process of highly conserved RNA interference in plants. The present work demonstrated how pre-treatment with siRNA may provide protection against MDMV (Maize dwarf mosaic virus) infection in sweet corn ( Zea mays cv. saccharata var. Honey Koern). In addition to monitoring the physiological condition of the maize plants, the accumulation of the virus in young leaves was examined, parallel, with changes in the plant RNA interference system and the ethylene (ET) biosynthetic pathway. The siRNA pre-treatment activated the plant antiviral defence system, thus significantly reducing viral RNA and coat protein levels in the youngest leaves of the plants. The lower initial amount of virus meant a weaker stress load, which allowed the plants to devote more energy to their growth and development. In contrast, small RNA pre-treatment did not initially have a significant effect on the ET biosynthetic pathway, but later a significant decrease was observed both in the level of transcription of genes responsible for ET production and, in the amount of ACC (1-aminocyclopropane-1-carboxylic acid) metabolite. The significantly better physiological condition, enhanced RNAi response and lower quantity of virus particles in siRNA pretreated plants, suggested that siRNA pre-treatment stimulated the antiviral defence mechanisms in MDMV infected plants. In addition, the consistently lower ACC content of the plants pre-treated with siRNA suggest that ET does not significantly contribute to the successful defence in this maize hybrid type against MDMV.

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Kinga Balassa

Expression Pattern of RNA Interference Genes During Drought Stress and MDMV Infection in Maize

Physiological and Molecular Background of Maize Cold-Tolerance Enhancement with S-methylmethionine Salicylate

Changes in physiology, gene expression and ethylene biosynthesis in MDMV-infected sweet corn primed by small RNA pre-treatment

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