Medicinal Plants
Khadijeh Ahmadi; Heshmat Omidi; Majid Amini; Elyas Soltani
Abstract
Introduction
Kelussia odoratissima Mozaff is a native species of Iran which is a rare and endangered species. It grows as a wild in cold and mountainous bioclimatic and is used in traditional medicine to treat various diseases such as cardiovascular disease, gastric ulcer, respiratory and intestinal ...
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Introduction
Kelussia odoratissima Mozaff is a native species of Iran which is a rare and endangered species. It grows as a wild in cold and mountainous bioclimatic and is used in traditional medicine to treat various diseases such as cardiovascular disease, gastric ulcer, respiratory and intestinal inflammation. The change of status from dormancy to germination can be eliminated by using some treatments in accordance with the natural conditions of the mother base habitat. However, some physiological needs of dormant seeds can be met by scratching (mechanical and chemical), washing in running water, dry storage, cold and humid conditions, light, smoke, and plant growth regulators. The aim of this study was to investigate different strategies including pretreatment, leaching and constant germination temperature on seed germination characteristics and Kelussia seedling growth.
Materials and Methods
The experiment was conducted in Petri dishes at Seed Technology Laboratory of Agricultural Sciences Faculty of Shahed University. K. odoratissima Mozaff seeds were collected from their natural habitat in Fereydounshahr, Isfahan province in 2019.
This study was performed in the Crop Physiology and Seed Technology Laboratories of Shahed University, Faculty of Agricultural Sciences, from 23.09.2019 to 22.11.2019. The cultivation was in Petridish at constant germination temperatures after priming and leaching. The experiment was performed as a factorial experiment in a completely randomized design with three replications. Each replication included 36 Petridish and 20 Kelussia seeds were planted in each petri dish. Experimental factors include constant germination temperatures (1, 5, 10 and 15°C), duration of rinsing with running water at 15°C (24, 48 and 72 h) and hormone pretreatment with gibberellin (0, 250 and 500 ppm). Before applying the hormonal pretreatment and temperature, the seeds were washed in running water in such a way that seeds were placed in a strainer that was not immersed and water flowed on the seeds for the specified periods of time for this treatment. In this case, germination inhibitors were washed from the seed surface. According to the test period and laboratory conditions, the laboratory temperature could be controlled at 15 °C with a thermometer and cooling devices. Then, for hormonal pretreatment, the seeds were placed in containers containing gibberellin solution with concentrations of 0, 250 and 500 ppm and refrigerated at 4°C for 72 h. After washing the seeds, 20 seeds were placed in Petridish with a diameter of 10 cm and a height of 2 cm on Whatman filter paper No. 1 and at temperatures of 1, 5, 10 and 15°C with 16 h of light and 8 h of darkness passed. Due to the fact that germination in seeds grown at this temperature at 15°C was zero in all treatment compositions, it was excluded from statistical analysis. To analyze the data variance, the SAS 9.1 statistical software was used. The comparison of means of traits was performed using the Duncan test at 5% probability level.
Results and Discussion
Germination traits, growth indices and physiological parameters of seedling photosynthetic pigments under the influence of leaching, temperature, gibberellin and the interactions of leaching in temperature, leaching in gibberellin, temperature in gibberellin and the combination of leaching treatment × temperature × gibberellin showed significant differences. The results showed that the optimum germination temperature was 1°C and about 54% of seeds were able to germinate at this temperature without using any pretreatment. However, pretreatment of seeds at a temperature of 1°C with gibberellin at 250 ppm and washing for 72 h increased the germination rate to 65%. It has also been shown that treatment with gibberellin at 250 ppm seedling length and gibberellin at 500 ppm improves seedling fresh and dry weight in three leaching treatments at 10°C. Chlorophyll and carotenoid content of seedlings was observed in the combination of 24 hours leaching treatment, temperature of 5°C and gibberellin priming of 500 ppm. Due to the wide variety of species of Apiaceae and also the variety of type and depth of sleep, various treatments to break dormancy and stimulate seed germination of plants of this genus have been proposed, the most important of which are wet and gibberellin. It should be noted that the germination ecology and appropriate treatments to break dormancy in different plant species, plants of the same family, same species and different ecotypes of the same species can be completely different.
Conclusion
According to the results of this study, seed treatment with 72 hours of cold water washing, 1°C and gibberellin pretreatment with a concentration of 250 ppm was able to show the highest germination percentage to achieve High germination is recommended. In addition, at 5°C under gibberellin pretreatment and leaching showed a relatively high germination percentage. Accordingly, gibberellin hormonal pretreatment at low temperatures was effective in achieving more germination under priming conditions. Is. On the other hand, a concentration of 500 ppm gibberellin increased seedling weight and photosynthetic pigments. In general, a temperature of 1°C followed by a temperature of 5°C was effective in increasing the germination of celery seeds and was able to record better results. Also, the suitable seedling growth temperature for mountain celery is 10°C and the application of Gibberellin hormonal pretreatment improved the growth characteristics of Kelussia seedlings.
Heshmat Omidi; Fatemeh Pirjalili; Khadijeh Ahmadi
Abstract
Introduction: Water deficit is one of the major abiotic stresses, which adversely affects crop growth and yield. Plants use two different strategies, including drought avoidance and drought tolerance to grow under drought stress. Drought avoidance species are able to have a normal growth, which is due ...
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Introduction: Water deficit is one of the major abiotic stresses, which adversely affects crop growth and yield. Plants use two different strategies, including drought avoidance and drought tolerance to grow under drought stress. Drought avoidance species are able to have a normal growth, which is due to: 1) efficient and fast metabolism, 2) high uptake of water and nutrients, and 3) little production of secondary metabolites under deficient water conditions. While drought tolerance species maintain their regular growth, under drought stress, by: 1) adjustment of osmotic potential, 2) changes in cell wall properties, and 3) production of antioxidants and secondary metabolites, these species under prolong drought, and irrespective of plant type, plant produces higher rate of secondary metabolites, as a non-enzymatic mechanism. Such products are able to maintain plant activities, under oxidative stress, and in the presence of high rate of reactive oxygen species. Medicinal plants, including Balangu (Lallemantia royleana Benth.), are cultivated across different parts of the world including Iran for food and biodiesel purposes. Investigating the effects of drought stress on the production of secondary compounds by medicinal plants is an important issue. According to the previous studies drought stress increases the production of secondary compounds affecting the quality of medicinal plants. This must be considered when developing tolerant medicinal plants under stress, especially if the quality of medicinal plants is of higher importance than their quantity. The tolerance of medicinal plants is different under stress. Due to the importance of drought and its effects on the growth and the quality of medicinal plants, in this research the effects of stress intensity and plant species on the growth and physiology (including the medicinal contents) of Balangu plants were investigated. To our knowledge, there are not much data on such effects. The objectives of this study were to investigate the effects of drought stress on: 1) Balangu growth and yield, and 2) Balangu physiology including the activities of morphological traits, yield components and oil yield and the production of antioxidant enzyme affecting plant medicinal content. Materials and Methods: This study was conducted to investigate grain yield, yield components, and superoxide dismutase enzyme in three populations of Balangu (Lallemantia royleana Benth.) under drought stress. This study was conducted as a split plot experiment based on randomized complete block design with three replications at the experimental field of Shahed University during 2013-2014 growing season. The main factor consisted of four levels of drought stress (soil moisture content of -0.5, -3.5, -6.5 and -9 atm) and three Balangu Shirazi populations (Mashhad, Kerman and Taleghan) as sub-factors were considered. The main factor included drought stress levels at four levels (soil moisture content of -0.5, -3.5, -6.5 and -9 atm) and three Balangu Shirazi populations (Mashhad, Kerman and Taleghan) were considered as sub-plots. Measured traits were included root length, plant height, fresh and dry weight per plant, grain yield, grain yield components, mucilage percent and yield. In order to study the morphological traits, seven plants of each plot were selected with consideration of marginal impacts. About four square meters of each plot was harvested at maturity for determination of yield and its components.. The analysis of variance was does through SAS 9.12 statistical program and the means were compared by Duncan's multiple range test in 5% level. Results and Discussion: A set of yield and biochemical properties of three different species of Balangu which were affected by drought levels were determined. According to the analysis of variance the yield and biochemical properties of Balangu were significantly affected by drought, and there were significant differences between three species. The results showed that drought stress had a significant effect on growth components, yield components, grain yield, and oil yield and superoxide dismutase enzyme. With decrease of soil water content, plant height traits (24.73 cm), the number of branches (5.44), fresh (17.36 g) and dry (3.80 g) weight of plant, 1000-grain weight (1.51 g), harvest index (6.41 %), grain yield (157 kg.ha-1) and oil yield (37.77 kg.ha-1) decreased. Root length and superoxide dismutase content increased by 24.02 and 66.63% under severe stress compared to no stress condition, respectively. The highest grain and oil yield was obtained in Mashhad population under drought stress. In relatively severe stress conditions, the grain and oil yield of Taleghan population increased with the mean of 315.75 and 86.5 kg.ha-1, respectively. Under drought stress levels, the lowest reduction was observed in some growth characteristics and grain yield of Kerman population. Conclusion: Overall, the results of this study demonstrated that drought stress at flowering stage increased root length and superoxide dismutase enzyme of the studied populations. Furthermore morphological traits, grain yield components, harvest index, relative water content, grain yield and seed oil of Balangu populations were decreased. The highest seed and oil yield gained under moderate stress which belongs to Taleghan population and Mashhad population revealed the highest seed and oil yield under mild stress. Therefore, given the high stresses, introducing high-yielding populations under relatively severe stresses can lead to water use efficiency and irrigation management. Finally, the production of Taleghan population under relatively severe conditions such as arid and semi-arid cropping systems is recommended.