Your search keyword '"Szőke-Pázsi K"' showing total 8 results

1. 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, C., Szőke-Pázsi, K., Makai, S., Gell, G., Fábián, A., Poczkodi, E., Tóth, G., Sági, L., Tamás, L., Juhász, A., Éva, C., Szőke-Pázsi, K., Makai, S., Gell, G., Fábián, A., Poczkodi, E., Tóth, G., Sági, L., Tamás, L., and Juhász, A.

Abstract

High-molecular-weight glutenin subunit (HMW GS) proteins are major components of the gluten matrix, which is the physical basis of bread-making in wheat. Epigenetic and transcriptional regulations of HMW GS genes were studied both in silico and in wet lab to understand their tissue (endosperm) specific expression. Our co-expressional network analysis identified key transcription factor (TF) genes that regulate HMW GS genes. We also show here that HMW GS genes are inhibited in vegetative tissues by histone deacetylation as revealed by strong GUS expression in vascular tissues of transgenic barley seedlings harbouring HMW GS gene promoter::uidA-reporter gene fusions upon treatment with a histone deacetylase inhibitor. A novel method termed in vivo DNA affinity purification (IP) has been developed here for the isolation of histones and transcription factors binding to target DNA regions. The technique is based on the biolistic introduction of biotinylated PCR probes amplified from HMW GS gene promoters into wheat leaves. Twenty-four hours later, the probe is cross-linked with interacting factors and subsequently re-purified from plant nuclear extracts. Many proteins, ribosomal proteins and histones have so far been isolated. No lysine-acetylated histone protein fragments were found which further highlight the inhibiting effect of histone deacetylation on HMW GS gene expression.

Published

2018

2. DArTseq genotyping facilitates identification of Aegilops biuncialis chromatin introgressed into bread wheat Mv9kr1.

Author

Gaál E, Farkas A, Türkösi E, Kruppa K, Szakács É, Szőke-Pázsi K, Kovács P, Kalapos B, Darkó É, Said M, Lampar A, Ivanizs L, Valárik M, Doležel J, and Molnár I

Subjects

Genotype, Genetic Introgression, Genetic Markers, Genotyping Techniques, Plant Breeding methods, Chromosome Mapping, Triticum genetics, Aegilops genetics, Chromatin genetics, Chromatin metabolism, Chromosomes, Plant genetics, Genome, Plant

Abstract

Wild wheat relative Aegilops biuncialis offers valuable traits for crop improvement through interspecific hybridization. However, gene transfer from Aegilops has been hampered by difficulties in detecting introgressed U b - and M b -genome chromatin in the wheat background at high resolution. The present study applied DArTseq technology to genotype two backcrossed populations (BC382, BC642) derived from crosses of wheat line Mv9kr1 with Ae. biuncialis accession, MvGB382 (early flowering and drought-tolerant) and MvGB642 (leaf rust-resistant). A total of 11,952 Aegilops-specific Silico-DArT markers and 8,998 wheat-specific markers were identified. Of these, 7,686 markers were assigned to U b -genome chromosomes and 4,266 to M b -genome chromosomes and were ordered using chromosome scale reference assemblies of hexaploid wheat and Ae. umbellulata. U b -genome chromatin was detected in 5.7% of BC382 and 22.7% of BC642 lines, while 88.5% of BC382 and 84% of BC642 lines contained M b -genome chromatin, predominantly the chromosomes 4M b and 5M b . The presence of alien chromatin was confirmed by microscopic analysis of mitotic metaphase cells using GISH and FISH, which allowed precise determination of the size and position of the introgression events. New Mv9kr1-Ae. biuncialis MvGB382 4M b and 5M b disomic addition lines together with a 5DS.5DL-5M b L recombination were identified. A possible effect of the 5M b L distal region on seed length has also been observed. Moreover, previously developed Mv9kr1-MvGB642 introgression lines were more precisely characterized. The newly developed cytogenetic stocks represent valuable genetic resources for wheat improvement, highlighting the importance of utilizing diverse genetic materials to enhance wheat breeding strategies., (© 2024. The Author(s).)

Published

2024

3. DArTseq genotyping facilitates the transfer of "exotic" chromatin from a Secale cereale × S. strictum hybrid into wheat.

Author

Szőke-Pázsi K, Kruppa K, Tulpová Z, Kalapos B, Türkösi E, Gaál E, Darkó É, Said M, Farkas A, Kovács P, Ivanizs L, Doležel J, Rabanus-Wallace MT, Molnár I, and Szakács É

Abstract

Cultivated and wild species of the genus rye ( Secale ) are important but underexploited gene sources for increasing the genetic diversity of bread wheat. Gene transfer is possible via bridge genetic materials derived from intergeneric hybrids. During this process, it is essential to precisely identify the rye chromatin in the wheat genetic background. In the present study, backcross generation BC 2 F 8 from a cross between Triticum aestivum (Mv9kr1) and S. cereanum ('Kriszta,' a cultivar from the artificial hybrid of S. cereale and S. strictum ) was screened using in-situ hybridization (GISH and FISH) and analyzed by DArTseq genotyping in order to select potentially agronomically useful genotypes for prebreeding purposes. Of the 329,267 high-quality short sequence reads generated, 27,822 SilicoDArT and 8,842 SNP markers specific to S. cereanum 1R-7R chromosomes were identified. Heatmaps of the marker densities along the 'Lo7' rye reference pseudomolecules revealed subtle differences between the FISH- and DArTseq-based results. This study demonstrates that the "exotic" rye chromatin of S. cereanum introgressed into wheat can be reliably identified by high-throughput DArTseq genotyping. The Mv9kr1-'Kriszta' addition and translocation lines presented here may serve as valuable prebreeding genetic materials for the development of stress-tolerant or disease-resistant wheat varieties., 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. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Szőke-Pázsi, Kruppa, Tulpová, Kalapos, Türkösi, Gaál, Darkó, Said, Farkas, Kovács, Ivanizs, Doležel, Rabanus-Wallace, Molnár and Szakács.)

Published

2024

4. Chromosome genomics facilitates the marker development and selection of wheat-Aegilops biuncialis addition, substitution and translocation lines.

Author

Farkas A, Gaál E, Ivanizs L, Blavet N, Said M, Holušová K, Szőke-Pázsi K, Spitkó T, Mikó P, Türkösi E, Kruppa K, Kovács P, Darkó É, Szakács É, Bartoš J, Doležel J, and Molnár I

Subjects

In Situ Hybridization, Fluorescence, Chromosomes, Plant genetics, Translocation, Genetic, Genetic Markers, Genomics, Triticum genetics, Aegilops genetics

Abstract

The annual goatgrass, Aegilops biuncialis is a rich source of genes with considerable agronomic value. This genetic potential can be exploited for wheat improvement through interspecific hybridization to increase stress resistance, grain quality and adaptability. However, the low throughput of cytogenetic selection hampers the development of alien introgressions. Using the sequence of flow-sorted chromosomes of diploid progenitors, the present study enabled the development of chromosome-specific markers. In total, 482 PCR markers were validated on wheat (Mv9kr1) and Ae. biuncialis (MvGB642) crossing partners, and 126 on wheat-Aegilops additions. Thirty-two markers specific for U- or M-chromosomes were used in combination with GISH and FISH for the screening of 44 Mv9kr1 × Ae. biuncialis BC 3 F 3 genotypes. The predominance of chromosomes 4M and 5M, as well as the presence of chromosomal aberrations, may indicate that these chromosomes have a gametocidal effect. A new wheat-Ae. biuncialis disomic 4U addition, 4M(4D) and 5M(5D) substitutions, as well as several introgression lines were selected. Spike morphology and fertility indicated that the Aegilops 4M or 5M compensated well for the loss of 4D and 5D, respectively. The new cytogenetic stocks represent valuable genetic resources for the introgression of key genes alleles into wheat., (© 2023. The Author(s).)

Published

2023

5. Transfer of the ph1b Deletion Chromosome 5B From Chinese Spring Wheat Into a Winter Wheat Line and Induction of Chromosome Rearrangements in Wheat- Aegilops biuncialis Hybrids.

Author

Türkösi E, Ivanizs L, Farkas A, Gaál E, Kruppa K, Kovács P, Szakács É, Szőke-Pázsi K, Said M, Cápal P, Griffiths S, Doležel J, and Molnár I

Abstract

Effective utilization of genetic diversity in wild relatives to improve wheat requires recombination between wheat and alien chromosomes. However, this is suppressed by the Pairing homoeologous gene, Ph1 , on the long arm of wheat chromosome 5B. A deletion mutant of the Ph1 locus ( ph1b ) has been used widely to induce homoeologous recombination in wheat × alien hybrids. However, the original ph1b mutation, developed in Chinese Spring (CS) background has poor agronomic performance. Hence, alien introgression lines are first backcrossed with adapted wheat genotypes and after this step, alien chromosome segments are introduced into breeding lines. In this work, the ph1b mutation was transferred from two CS ph1b mutants into winter wheat line Mv9kr1. Homozygous genotypes Mv9kr1 ph1b / ph1b exhibited improved plant and spike morphology compared to Chinese Spring. Flow cytometric chromosome analysis confirmed reduced DNA content of the mutant 5B chromosome in both wheat genotype relative to the wild type chromosome. The ph1b mutation in the Mv9kr1 genotype allowed wheat-alien chromosome pairing in meiosis of Mv9kr1 ph1b _K ×  Aegilops biuncialis F 1 hybrids, predominantly with the M b -genome chromosomes of Aegilops relative to those of the U b genome. High frequency of wheat- Aegilops chromosome interactions resulted in rearranged chromosomes identified in the new Mv9kr1 ph1b  ×  Ae. Biuncialis amphiploids, making these lines valuable sources for alien introgressions. The new Mv9kr1 ph1b mutant genotype is a unique resource to support alien introgression breeding of hexaploid wheat., 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 © 2022 Türkösi, Ivanizs, Farkas, Gaál, Kruppa, Kovács, Szakács, Szőke-Pázsi, Said, Cápal, Griffiths, Doležel and Molnár.)

Published

2022

6. Identification of New QTLs for Dietary Fiber Content in Aegilops biuncialis .

Author

Ivanizs L, Marcotuli I, Rakszegi M, Kalapos B, Szőke-Pázsi K, Farkas A, Türkösi E, Gaál E, Kruppa K, Kovács P, Darkó É, Szakács É, Said M, Cápal P, Doležel J, Gadaleta A, and Molnár I

Subjects

Dietary Fiber, Genes, Plant, Plant Breeding, Quantitative Trait Loci, Triticum genetics, Water, Aegilops genetics, beta-Glucans

Abstract

Grain dietary fiber content is an important health-promoting trait of bread wheat. A dominant dietary fiber component of wheat is the cell wall polysaccharide arabinoxylan and the goatgrass Aegilops biuncialis has high β-glucan content, which makes it an attractive gene source to develop wheat lines with modified fiber composition. In order to support introgression breeding, this work examined genetic variability in grain β-glucan, pentosan, and protein content in a collection of Ae. biuncialis . A large variation in grain protein and edible fiber content was revealed, reflecting the origin of Ae. biuncialis accessions from different eco-geographical habitats. Association analysis using DArTseq-derived SNPs identified 34 QTLs associated with β-glucan, pentosan, water-extractable pentosan, and protein content. Mapping the markers to draft chromosome assemblies of diploid progenitors of Ae. biuncialis underlined the role of genes on chromosomes 1M b , 4M b , and 5M b in the formation of grain β-glucan content, while other QTLs on chromosome groups 3, 6, and 1 identified genes responsible for total- and water-extractable pentosan content. Functional annotation of the associated marker sequences identified fourteen genes, nine of which were identified in other monocots. The QTLs and genes identified in the present work are attractive targets for chromosome-mediated gene transfer to improve the health-promoting properties of wheat-derived foods.

Published

2022

7. 1RS arm of Secale cereanum 'Kriszta' confers resistance to stripe rust, improved yield components and high arabinoxylan content in wheat.

Author

Szakács É, Szőke-Pázsi K, Kalapos B, Schneider A, Ivanizs L, Rakszegi M, Vida G, Molnár I, and Molnár-Láng M

Subjects

Plants, Genetically Modified, Translocation, Genetic, Chromosomes, Plant, Disease Resistance genetics, Plant Diseases genetics, Secale genetics, Triticum genetics

Abstract

Wheat-rye T1BL.1RS translocation is widespread worldwide as the genes on 1RS arm have positive effect on stress resistance, grain yield and adaptation ability of wheat. Nowadays, the T1BL.1RS wheat cultivars have become susceptible to rust diseases because of the monophyletic ('Petkus') origin of 1RS. Here we report and discuss the production and detailed investigation of a new T1BL.1RS translocation line carrying 1RS with widened genetic base originating from Secale cereanum. Line '179' exhibited improved spike morphology traits, resistance against stripe rust and leaf rust, as well as higher tillering capacity, fertility and dietary fiber (arabynoxylan) content than the parental wheat genotype. Comparative analyses based on molecular cytogenetic methods and molecular (SSR and DArTseq) makers indicate that the 1RS arm of line '179' is a recombinant of S. cereale and S. strictum homologues, and approximately 16% of its loci were different from that of 'Petkus' origin. 162 (69.5%) 1RS-specific markers were associated with genes, including 10 markers with putative disease resistance functions and LRR domains found on the subtelomeric or pericentromeric regions of 1RS. Line '179' will facilitate the map-based cloning of the resistance genes, and it can contribute to healthy eating and a more cost-efficient wheat production.

Published

2020

8. Unlocking the Genetic Diversity and Population Structure of a Wild Gene Source of Wheat, Aegilops biuncialis Vis. , and Its Relationship With the Heading Time.

Author

Ivanizs L, Monostori I, Farkas A, Megyeri M, Mikó P, Türkösi E, Gaál E, Lenykó-Thegze A, Szőke-Pázsi K, Szakács É, Darkó É, Kiss T, Kilian A, and Molnár I

Abstract

Understanding the genetic diversity of Aegilops biuncialis , a valuable source of agronomical useful genes, may significantly facilitate the introgression breeding of wheat. The genetic diversity and population structure of 86 Ae. biuncialis genotypes were investigated by 32700 DArT markers with the simultaneous application of three statistical methods- neighbor-joining clustering, Principal Coordinate Analysis, and the Bayesian approach to classification. The collection of Ae. biuncialis accessions was divided into five groups that correlated well with their eco-geographic habitat: A (North Africa), B (mainly from Balkans), C (Kosovo and Near East), D (Turkey, Crimea, and Peloponnese), and E (Azerbaijan and the Levant region). The diversity between the Ae. biuncialis accessions for a phenological trait (heading time), which is of decisive importance in the adaptation of plants to different eco-geographical environments, was studied over 3 years. A comparison of the intraspecific variation in the heading time trait by means of analysis of variance and principal component analysis revealed four phenotypic categories showing association with the genetic structure and geographic distribution, except for minor differences. The detailed exploration of genetic and phenologic divergence provides an insight into the adaptation capacity of Ae. biuncialis , identifying promising genotypes that could be utilized for wheat improvement., (Copyright © 2019 Ivanizs, Monostori, Farkas, Megyeri, Mikó, Türkösi, Gaál, Lenykó-Thegze, Szőke-Pázsi, Szakács, Darkó, Kiss, Kilian and Molnár.)

Published

2019