Pomology
Seyed Asghar Mousavi; Akram Vatankhah; Ali Imani
Abstract
IntroductionAlmond (Prunus dulcis L.) is one of the valuable nut trees that is cultivated in many temperate regions and Mediterranean climatic conditions for domestic consumption and export. Almond belongs to the genus Prunus, from the Rosaceae family. Identifying and introducing genotypes and cultivars ...
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IntroductionAlmond (Prunus dulcis L.) is one of the valuable nut trees that is cultivated in many temperate regions and Mediterranean climatic conditions for domestic consumption and export. Almond belongs to the genus Prunus, from the Rosaceae family. Identifying and introducing genotypes and cultivars of late bloom is one of the most important goals of almond breeding programs. The correct choice of almond rootstock causes better management of the garden, compatibility with all types of soil and resistance to nematodes. Peach × almond hybrid has been the most widely used rootstock in both dry and irrigated conditions in the past years. Creating an orchard by selecting grafted genotypes on suitable rootstock for sustainable cultivation of almonds is particularly important. Cultivation of superior genotypes grafted on fruit trees has an effect on pomological characteristics, yield and quality of nuts. The requirement for the introduction and production of superior cultivars is an accurate selection between cultivars, which is possible through the identification of cultivars and their diversity. The purpose of this research is to investigate and evaluate the most important vegetative, phenological, quantitative and qualitative characteristics of nuts and kernels in 36 promising cultivars and genotypes grafted on GN15 rootstock, in order to introduce superior cultivars.Materials and Methods:In this research, 36 promising almond cultivars and genotypes on GN15 rootstock were investigated in garden conditions in terms of various vegetative traits, nut and kernel characteristics in order to obtain suitable commercial cultivars. This research was conducted at the Badam research station in Saman region affiliated to the Center for Research and Education of Agriculture and Natural Resources of Chaharmahal and Bakhtiari province as a randomized complete block design with three replications. Vegetative traits of tree height, canopy length, canopy width, and branch length were measured by meter in the garden, and rootstock diameter, scion diameter, and branch diameter were measured in the garden with calipers. In order to measure the nut and kernels, 100 fruits were harvested from each of the studied cultivars and genotypes at the time of fruit ripening, and their green shell was separated and dried. Measurement of traits such as length, width, diameter of nut and kernel was done by digital caliper and weight of nut and kernel was measured by digital scale with accuracy of 0.01. Coding of some traits was done based on almond descriptor (Gülcan, 1985) with some changes. The data obtained from the experiment were analyzed using SAS software (version 3.1.9). To compare the means, Duncan's multiple range test was used at the 5% probability level.Results and DiscussionAccording to the results of analysis of variance (ANOVA), there was a statistically significant difference at the level of 1% between the attributes of tree height, canopy width, rootstock and scion diameter, branch length and diameter, and the ratio of tree height to canopy length. (P<0.01). The results of variance analysis show that there is a significant difference between the investigated nut and kernel traits in promising cultivars and genotypes grafted on GN (Table 5). These differences show the diversity in the investigated traits and it is possible to choose cultivars for different values of the same trait. Based on the average comparison results of the vegetative traits, the highest height in genotypes GA4, GA3, GA35, The highest canopy width was observed in genotypes GA5, GA17, GA3, and GA20, GA15, GA5, the highest diameter of rootstock and scion, and the highest length and diameter of one-year branches were observed in genotype GA18. The results of the comparison of the average nut and kernel characteristics show that there is a significant difference in the cultivars and genotypes investigated in this research. The results of the comparison of the average nut and kernel characteristics show that there is a significant difference in the cultivars and genotypes investigated in this research. Based on the obtained results, cultivars and genotypes of GA5, GA24, GA12, GA9 and GA1 showed relative superiority in terms of nut and kernel traits. The results of this research showed that the GA35 genotype grafted on the GN15 rootstock had the highest length, width and diameter of the nut, and the highest weight of nut and kernel. The kernel color light, the without shrinking the kernel and the highest percentage of kernel and the highest ratio of kernel weight to nut weight.ConclusionThe results of this research showed that the examination of vegetative traits, nuts and kernels in the studied cultivars and genotypes could show the diversity between cultivars and genotypes. The results showed that the investigated cultivars and genotypes have significant differences in terms of all nut and kernel traits, which indicates the existence of diversity between the investigated cultivars and genotypes. This indicates that these cultivars and genotypes can be considered as a source of good germplasm for breeding programs. Cultivars and genotypes with higher percentage of kernels had thinner shell, more patterns on the skin, and light to medium kernel color. Based on the obtained results, cultivars and genotypes of GA5, GA24, GA12, GA9 and GA1 showed relative superiority in terms of nut and kernel traits. The results of this research showed that the GA35 genotype grafted on the GN15 rootstock had the highest length, width and diameter of the nut, and the highest weight of nut and kernel. The kernel color light, the without shrinking the kernel and the highest percentage of kernel and the highest ratio of kernel weight to nut weight.
Medicinal Plants
Alireza Moshrefi-Araghi; Seyyed Hossein Nemati; Mahmud Shoor; Majid Azizi; Nasrin Moshtaghi
Abstract
Introduction Mentha is one of the most important genera of aromatic plants which belongs to the Lamiaceae family. The genus of Mentha is distributed across Asia, Africa, Australia, Europe, and North America. Mentha longifolia L., also known as wild mint, is a fast-growing aromatic perennial herb. ...
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Introduction Mentha is one of the most important genera of aromatic plants which belongs to the Lamiaceae family. The genus of Mentha is distributed across Asia, Africa, Australia, Europe, and North America. Mentha longifolia L., also known as wild mint, is a fast-growing aromatic perennial herb. It is widely used as herbal medicine and is beneficial for the immune system and fighting with secondary infections. The essential oil of this plant is partly responsible for the decongestant, antispasmodic and antibiotic effects. Currently, much emphasis is being laid on conserving plant germplasm as valuable bio-resources. Selection between and within accessions for a high level of herbage yield and other characters requires an effective tool to be applied by mint breeders. Achieving to cultivars that are more capable of optimum producing is a breeding goal. The objectives of this study were to analyze the diversion of the agronomical traits of Mentha longifolia L. genotypes from different regions of Iran under a similar condition in order to find the superior genotypes and introduce for the domestication of this plant. Material and MethodThis research was performed at the research field of the Ferdowsi University of Mashhad. The field is located at 36˚15' North latitude and 59˚38' East longitude, at an altitude of 985 meters. The information related to temperature and precipitation was obtained from climate station. Soil sampling was done in the depth of 0.3 meter and physical experiments on samples were done before starting the experiment. The field was fertilized by 25 kg/ha animal manure. Seeds of 20 genotypes of M. longifolia L. were prepared from Gene Bank of Research Institute of Forests and Rangelands and a view of the wild mint genotypes distribution was presented on the map. The experiment was performed in a field with 500m2 areas in 2015-2016 growing seasons. The experiment in form of compound analysis arranged in complete randomized design with three replicates of 20 wildmint's genotypes in every replication. In each furrow, fourteen bush was totally studied, in which the distance between the two plants was 20 cm. The plot was considered 1.2 by 3 m and the distance between rows was 0.50 m. The dimension in the plots for every replication area was 3.6 m2 and the distance between blocks were 1.5 and between experimental units were 0.5 meters. Picking up was done after elimination of 0.5 meters from every side of replication. The essential oil was extracted using Clevenger type apparatus and by hydrodistillation. Results and DiscussionAnalysis of variance showed that the effect of the diversity among the genotypes on morphological, agronomical and essential oil yield parameters of wild mint was significant (P≤0.01). The results of this study showed that Mentha longifolia L. herb has a high diversity under the same culture conditions among genotypes collected from 20 regions of Iran. Correlation result shows that vegetative organs have more effect on the essential oil content than the reproductive organs. This may be due to the distribution of essential oil accumulation and storage sites, which requires further research in this regard. The study of vegetative and reproductive characteristics suggests that the genotypes of the dry and semi-arid climates have different conditions, which may causes the separation of their genotypes compared with the other genotypes. The bi-plot, based on PC1 and PC2, reflects the relationships between the studied genotypes. The results of bi-plot of cluster analysis confirmed that genotypes were divided into two main groups based on agronomical and morphological traits. Conclusion Finally, plants of genotype G13 belongs to Hormozgan province and then G16 genotype belongs to Khuzestan province were selected because of more biomass, more aerial part volume and also the most essential oil performance compared to the other genotypes. Desirable traits for the aerial part such as the time of flowering, leaf length, leaf width, plant height, the highest number of leaves in the stem and internode distance are important traits that should be considered. In addition, the cultivation of these genotype in order to the further production can be the great help in the domestication of this species and, given the fact that the diversity is a precursor of breeding, this research can be an introduction for future breeding operations. However, further research is needed to confirm the phytochemical superior genotypes.