This study attempted to utilize various groundcover plants in phytoremediation, using shade plants, which often have a high shade tolerance for shade urban space. Liriope platyphylla was grown in soil containing three of heavy metals, Zn, Cd, and Pb under four different concentrations (0, 100, 250 and 500 mg/kg) to determine the heavy metal accumulation characteristics and removing from soil. Total amounts of accumulated Zn in L. platyphylla were increased in accordance with increasing elevated Zn concentrations in soil, but the difference was not significant between Zn250 and Zn500. Cd accumulation, sharply increased in Cd100 and Cd250, but was reduced in Cd500. Increased Pb concentration in soil resulted a continuous increase in the total amounts of Pb accumulated in L. platyphylla. The total content of Zn in soil decreased by almost 50% in Zn100, almost 33% in Zn250 and 20% in Zn500 through growth of L. platyphylla over a period of 7 months. In the case of Cd, the concentration in soil, was decreased with 10% in Cd100, 10% in Cd250 and 33% in Cd500 through growth of L. platyphylla over a period of 7 months. This results indicate that more Cd was removed by planting L. platyphylla, compared to Zn or Pb.

Glycoalkaloids are a family of toxic secondary metabolites present in the plants of solanaceae family, which serve for plant defense. Two major glycoalkaloids present in plants are a-solanine and a-chaconine. The upper safe limit of glycoalkaloids for human consumption is 20mg/KG FW and its excess may cause severe health disorders. Light is the major factor known to increase the glycoalkaloid content in post harvest potato tuber. Glycoalkaloid pathway is not completely understood. Hence, identification and characterization of SGA biosynthetic genes and the genetic factors that control their expression levels assumes significance. Present investigation was focused on the study of expression pattern of key genes in steroidal glycoalkaloidal pathway under various light qualities in potato (Solanum tuberosum L). Two potato cultivars Atlantic and Haryeong which accumulates low and high glycoalkaloids respectively were used to check the levels of gene expression under various light qualities viz., red, blue, white, green, yellow, purple, UV light and in dark at different time intervals. Expression of three genes viz., SGT1, SGT2 and SGT3 which are directly involved and four other genes, HMG1, SQS1, SMT1 and SMT2 in the pathway envisaged to be indirectly involved in the glycoalkaloid formation was quantified by RT PCR. Varietal variation in the expression among the genes was observed in different light qualities. White, red and green light compared to other light qualities majorly contributed for the increased expression of genes for glycoalkaloid accumulation at different time intervals. Importantly, there is no significant transcript accumulation of these genes in dark condition. However, more efforts would be extended for further understanding of glycoalkaloid accumulation under light.

Alfalfa (Medicago sativa L.) is one of the most important forage crops in the world and it’s has been known as the best feed materials for dairy cows and other high valued animals. The new uses of alfalfa are being explored as bio-energy, food, medical and biochemical uses. R2R3-type MYB transcription factors play important roles in transcriptional regulation of anthocyanin biosynthesis. The R2R3-type IbMYB1 is known to be a key regulator of anthocyanin biosynthesis in the storage roots of sweetpotato. We previously showed that the expression of IbMYB1a led to anthocyanin pigmentation in tobacco and Arabidopsis. In this study, we generated transgenic alfalfa plants expressing the IbMYB1a gene under the control of CaMV 35S promoter. Overexpression of IbMYBa in transgenic alfalfa produced strong anthocyanin pigmentation in seedlings and generated a deep purple color in leaves, stems, roots, and even in seeds. High performance liquid chromatography (HPLC) analysis revealed that IbMYB1a expression led to the production of cyanidin as a major core molecule of anthocyanidins in alfalfa, as occurs in the purple leaves of sweetpotato (cv.Sinzami). We also examined expression of several structural genes in the anthocyanin biosynthetic pathway in alfalfa by RT-PCR analysis. In this presentation, we will further present molecular and biochemical characterization in IbMYB1a-overexpression lines. This result shows that the IbMYB1a transcription factor is sufficient to induce anthocyanin accumulation in the forage legume alfalfa plants.

High temperature impediment in developing stages of crops has been occurred due to the impact of global warming. Rice production is notable to be sensitive to increasing environmental temperature and grain filling temperatures are already approaching threatening levels in many countries with rice cultivation. Recent proteomic analyses exposed impulsive changes of metabolisms during rice grain development. Interestingly, proteins involved in glycolysis, citric acid cycle, lipid metabolism, and proteolysis were accumulated at higher levels in mature grain than those of developing stages. High temperature (HT) stress in rice ripening period enhances damaged (chalky) grains which have loosely compacted shape starch granules. We carried out two-dimensional gel electrophoresis to analyze protein profiles during grain filling and different developmental stages of rice seed maturation. Proteins were separated from the fertilized seeds (seeds from 7 days and 21 days after fertilization) and seed maturation stage using IEF in the first-dimension and SDS-PAGE in the second dimension along with MALDI-TOF mass spectrometry. More than 1,000 protein spots were detected on a two-dimensional gel electrophoresis. A total of 120 different protein spots out of 140 protein spots were identified by MALDI-TOF and nano LCQ-TOF mass spectrometer. The identified proteins were categorized into six (6) different groups according to their expression patterns during grain filling and seed maturation. Some proteins were confirmed during seed development stages such as cytoplasmic malate dehydrogenase, whereas others were appeared at a specific stage like putative subtilisin-like protease, germin-like, seed allergenic proteins. Furthermore, the chalking mechanism of rice grain under the HT stress could be discussed in terms of grain starch glycome, transcriptome, and proteome.

Drought and salinity are the major abiotic stresses which are being continued to hamper the ecosystem and agriculture of the affected region. Plant species have adaptations to enhance their ability to tolerate stresses through physiological adjustment. Therefore, substantial amount of research are ongoing to provide insights about those mechanisms which enlighten the stress tolerance in plant. In this study, several rice cultivars were collected from the different parts of the world and ion accumulation experiments were conducted to select the best stress tolerant cultivar in drought and salt stress environment. For stress treatment, five rice cultivars were subjected to salt (200 mM NaCl) and drought (200 mM Mannitol) for 72h. Later Na+, Ca++, K+ concentrations in shoot and root samples were examined at different time interval. In both drought and salt stress, rice cultivar C201 (collected for uzbekistan) showed the lowest levels of Na+ ion and Na+: K+ ratio compared to other cultivars. It was significant parallel observation with pokkali (known salt tolerant cultivar). In this preliminary study, it was observed the C201 had more stress tolerant in terms of ion accumulation; however detail physiological studies are required to strengthen the idea regarding the best stress tolerant physiotype.

Several tests and experimental work have been done for identifying the best growth conditions and accumulated amount of lipid moiety in B. braunii, a microalga(UTEX 572) in terms of media composition. The specific growth rate was found to be the highest at 0.15 g/L-day when the phosphorus concentration was doubled with the other ingredients at the normal level. Experiments for varied media compositions revealed that the accumulation of lipid was the highest at 48% (dry cell weight based) in the nitrogen deficient medium and its corresponding specific growth rate was comparative to that in the normal BG 11 medium. In the bubble column experiments, carbon dioxide containing air produced four times more cell mass than air only. Light and glucose addition also enhanced cell mass with maximum, 1.8 g/L and accordingly 42% of lipid composition, which turned out to be a better strategy for higher lipid-producing microalgal culture.