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Showing 26 results for Hadi
Khadijeh Abbaszadeh, Reza Shirzadian-Khorramabad, Mohammad Mahdi Sohani, Zahra Hajiahmadi,
Volume 9, Issue 2 (3-2023)
Abstract
Salinity stress affects morpho-physiological and biochemical traits of plants. The transgenic Bt plants play a significant role in pest control, but their response and ability to cope with environmental stresses still need to be evaluated. Therefore, effect of salinity stress at 0, 50, 100, 150, and 200 mM on morphological, physiological, and molecular traits of T3 transgenic tomato plants containing cry1Ab gene (CH-Falat-Bt) was investigated and compared with that of the non-transgenic control (CH-Falat). Evaluation of the morphological traits (leaf area, root length, fresh and dry weight of roots) at different salinity levels revealed that CH-Falat-Bt transgenic plants are more tolerant to salinity stress compared to CH-Falat non-transgenic plants. The chlorophyll content at 150 and 200 mM salinity levels was 12 and 9% plants, respectively. Moreover, the amount of RWC, carotenoids, proline and soluble sugars increased significantly in transgenic plants as salinity levels increased. The relative expression of SOS1 and SOS2 genes showed a significant increase in all salinity levels in CH-Falat-Bt transgenic plants compared to CH-Falat non-transgenic plants. The amount of electrolyte leakage in the transgenic plants was significantly reduced compared to the non-transgenic plants. The results of morphological, physiological, and molecular investigations of CH-Falat-Bt transgenic plants confirmed that the undesirable effects of salinity stress on transgenic plants is much less than non-transgenic ones. in general CH-Falat-Bt transgenic plants are more tolerant to different applied salinity levels than the wild variety.
Razieh Khadivar, Ahmad Ismaili, Seyed Sajad Sohrabi, Hasan Torabi Podeh,
Volume 9, Issue 2 (3-2023)
Abstract
Drought stress is one of the main environmental factors that affects growth and productivity of crop plants, including lentil. In the course of evolution evolution, crucial genetic regulations mediated by non-coding RNAs (ncRNAs) have emerged in plant in response to drought and other abiotic stresses. In the present study, after identifying lncRNAs within the expression profile of lentil, RNA-seq data and real-time PCR analyses were employed to examine the expression pattern of some of the identified lncRNAs under drought stress. Additionally, psych R package was used to generate the lncRNAs-DEGs co-expression network. A total of 3590 lncRNA sequences were identified in lentils transcriptome. Numerous lncRNAs were co-expressed with genes involved in circadian rhythm regulation, zinc ion response, photosynthetic photoreaction, and ion homeostasis. The LCUL_evgLocus_104392, LCUL_evgLocus_99066 and LCUL_evgLocus_61876 sequences were differentially expressed in response to drought stress. Examining the co-expression of these sequences with differentially expressed genes in response to drought stress, led to the identification of metabolic pathways associated with these sequences. In this study, lncRNA sequences were identified for the first time in lentil, and provided useful insights into the function of lncRNA in plant resistance to drought stress. The lncRNAs-DEGs co-expression network can lead to a better understanding of drought response mechanisms in lentil.
Hossein Abdi, Hadi Alipour, Iraj Bernousi, Jafar Jafarzadeh,
Volume 10, Issue 1 (9-2023)
Abstract
Evaluating the population structure is essential for understanding diversity patterns, choosing proper parents for crossing, accurate identification of genomic regions controlling traits, and evolutionary and kinship relationship studies. In this research, the genetic structure of a wheat population was studied in a panel consisting of 383 Iranian wheat genotypes of hexaploid (cultivars and landraces) and tetraploid species based on distance-based methods (principal component analysis and discriminant analysis of principal component). For this purpose, 16270 single nucleotide polymorphism (SNP) markers obtained by the GBS technique were used. According to the results, almost a quarter of the total variance was belonged to the diversity between populations, and the Fst coefficient between cultivars and landraces was equal to 0.15. In contrast, the above coefficient between tetraploid samples and hexaploid landraces was high and equal to 0.44. Genome D had the lowest value of Fst index and chromosome 4B showed the highest Fst coefficient, and other genetic diversity indices. Although the PCA biplot distinguished hexaploid wheat cultivars from landraces, it was unable to distinctly separate tetraploid genotypes from other genotypes. Accurate evaluation of the population structure with the DAPC method was able to identify and separate the predetermined successfully groups, suggesting that the DAPC approach maximizes the differentiation between groups and minimizes the changes within the group. Partial admixture between cultivars and landraces of hexaploid wheat can be related to gene exchange between these two groups or perhaps their wrong labeling at the time of collection. In general, the results of this study provided valuable information about the genetic differentiation of Iranian tetraploid and hexaploid wheat, which can be used in future wheat breeding programs. Further, protecting these genotypes in gene banks is necessary for different strategies.
Ramezanali Pourali, Mohammadhadi Pahlevani, Khalil Zeinalnejad,
Volume 10, Issue 2 (2-2024)
Abstract
Increasing grain yield and improving the quality of bread are among the most important goals of wheat breeding programs in Iran. Understanding the genetic control of traits and finding molecular or morphological markers associated with them are also prerequisites for any genetic engineering program. In this study, 100 progenies of a 10 × 10 diallel cross were used to analyse the genetics of grain yield and bakery values using STS markers associated with HMWG subunits. This research was carried out during 2018 and 2019 cropping season at Gorgan University of Agricultural Sciences and Natural Resources experimental fields. In the first year, 10 wheat cultivars, including Gonbad, Morvarid, Kalate, Ehsan, Sirvan, Baharan, Chamran2, Shush, Mehrgan and Brat collected from different geographical regions of Iran were planted and crossed in the field. In the second year, the parents and crosses were planted in the form of a randomized complete block design with three replications. The grain yield, number of spikes per plant, number of seeds per spike, seed weight, days to emergence and plant height were recorded. The results of this study indicated significant genetic differences between the parents. Narrow-sense heritability analysis revealed that the crossing of cultivars is the best breeding method to enhance seed yield, number of spikes per plant and days to emergence. Also, to improve the number of seeds per spike, seed weight and plant height, classical breeding methods may offer higher efficiency. Marvarid and Gonbad were ranked 1st and 2nd, respectively with respect to general combining abilities for grain yield, attributed to their positive and significant general combining ability effects. The highest specific combining ability was observed for Ehsan×Gonbad, Marvarid×Chamran 2 and Shush×Sirvan crosses. The results of molecular markers analysis showed that the STS markers were able to identify the difference in the baking value of cultivars. The quality score of the cultivars ranged 6 and 10 and to this end, Kalate and Brat were the top cultivars. Therefore, due to superiority in terms of both quantity and quality for yield, these cultivars can be used as parents with desirable genes for future breeding programs. Overall, the STS markers employed in this study proved to be valuable markers for enhancing the genetic background of bread wheat, particularly when employing marker-assisted selection for bakery value.
Mohammad Nader Ebrahimi, Hadi Ahmadi, Mostafa Darvishnia, Daryoush Ghoudarzi,
Volume 10, Issue 2 (2-2024)
Abstract
Hexaploid winter wheat (Triticum aestivum L., 2n= 6x= 42, AABBDD) is an important small-grain cereal crop grown for food and feed. In Iran, wheat is the most cultivated cereal crop where winter wheat is ranked 1st in terms of production. Wheat fusarium head blight (FHB) is one of the most important diseases of wheat in humid and hot regions of the world, which causes a decrease in yield and grain quality. Fusarium head blight is caused by Fusarium graminearum. In order to investigate the resistance of some wheat traits against HBF, 27 varieties and lines of bread wheat were sown at the farm of Faculty of Agriculture, Lorestan University. The spikes were infected at the first flowering stage by spray inoculation. The results showed that there was a great diversity among the 27 varieties of bread wheat tested in terms of growth traits, yield components, and grain yield. The results of The Duncan's test for comparing means showed that cultivars Ghods, Shiraz, Morvarid 2, and Pishtaz had a significant superiority in terms of grain yield compared to other cultivars. The results of simple correlation and also stepwise regression analysis showed that the traits of 1000 seed weight, plant height, number of seeds per spike, number of spikes, spike length and plant height are very important traits for grain yield. According to values of broad sense heritability and genetic gain for plant height and high correlation of this trait and seed yield, plant height can be used as a suitable trait for improving seed yield by selection. The overall results showed that Shiraz, Pishtaz, Quds and Morwarid-2 cultivars are suitable for transferring resistance to wheat spike blight disease in breeding programs.
Forough Joudaki, Ahmad Ismaili, Seyed Sajad Sohrabi, Seyedeh Zahra Hosseini, Hadi Ahmadi,
Volume 10, Issue 2 (2-2024)
Abstract
Gall oak (Quercus infectoria) is one of the extraordinary tree species with functional medicinal properties within the oak family. Various studies have confirmed the presence of numerous secondary metabolites with therapeutic properties in this plant. Despite the significance of gall oak, its genetic structure remains elusive. Therefore, unraveling the genetic structure of gall ok may provide valuable insights into its potential applications across diverse industries. MicroRNAs emerge as pivotal genetic elements implicated in the biosynthesis of crucial metabolites across a wide range of different plant species. Despite the significant role of miRNAs in plants, as of yet, no miRNAs have been reported in Q. infectoria.. Therefore, in the present study, after assembling the transcriptome of Q. infectoria, the conserved microRNAs were identified. Leaf and root samples of Q. infectoria were collected from trees in the Shineh region, and 2-year-old seedlings were grown from mature oaks in Khorramabad (Lorestan Province, Iran). Total RNA was extracted from roots and leaves using the Djami-Tchatchou method. After sequencing by the Illumina HiSeq 2500 platform and checking the quality of all the generated reads, the adapter sequences were removed, and the high-quality reads were assembled using Trinity package. To identify miRNAs and their target genes, all plant miRNAs sequences were downloaded from the miRbase database. The BLASTn algorithm was employed to identify the highest similarity between unigenes and mature plant miRNAs. Furthermore, BLASTx was used to search against the non-redundant proteins (NR) database to remove protein-coding unigenes. The investigation of miRNA second-structure prediction involved assessing the similarity between potential unigenes and mature miRNA sequences using the mfold web tool. Identification of miRNA target genes and gene ontology (GO) was performed using the psRNAtarget web-tool and OmicsBox software, respectively. Following a range of strict filtering criteria, four miRNAs belonging to conserved miRNAs families were identified, including qin-miR156, qin-miR399, qin-miR160, and qin-miR172. KEGG pathway analysis showed the target genes were involved in the citrate cycle pathway. Examining miRNA target genes in Q. infectoria and analyzing their interaction network, finally led to the identification of three hub genes. Identified miRNA target genes were associated with the biosynthesis of various enzyme groups, suggesting that most of miRNAs regulating hydrolases, transferases, and oxidoreductases. Given the role of microRNAs in regulating transcription factors and their impact on genes involved in secondary metabolite biosynthesis, future breeding programs in Q. infectoria may benefit from the potential of such regulatory elements as a guide and key.
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