School Of Basic And Applied Sciences
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Item Environmental Friendly Technologies for Remediation of Toxic Heavy Metals: Pragmatic Approaches for Environmental Management(Springer International Publishing, 2022-05-06T00:00:00) Sharma, Ritika; Saini, Khem Chand; Rajput, Sneh; Kumar, Mohit; Mehariya, Sanjeet; Karthikeyan, Obulisamy Parthiba; Bast, FelixContamination of different environmental matrices (air, soil, and water) by toxic heavy metals is a widespread problem that disturbs the environment as an outcome of many anthropocentric practices. Heavy metals exceeding the permissible limits exert deleterious impacts on human beings, causing life-threatening health manifestations and detrimental effects on the environment. This has alarmed the dire need to explore various modern remediation techniques that can be utilized to lower excessive concentrations. Owing to their high-cost effectiveness, unsatisfactory output, environmentally unfriendly, complicated procedure, and high operational costs, these technologies failed to find any practical utility in remediation. On the other hand, plants and associated microorganisms are receiving more consideration as a means of remediating or degrading environmental pollutants. This chapter provides us insights into the various environmental friendly techniques that will improve our environment�s quality. Among which, phytoremediation is considered an effective technique which is known for its esthetic benefits and endless applicability. Furthermore, metal-resistant bacteria (plant growth-promoting rhizobacteria) are also reported to play a pivotal role in the phytoremediation and solubilization of minerals. Thus, this chapter critically reviews the phytoremediation technology and the efficient exploitation of microbes to alleviate the environmental burden of toxic heavy metals. � The Author(s), under exclusive license to Springer Nature Switzerland AG 2022.Item Environmental Friendly Technologies for Remediation of Toxic Heavy Metals: Pragmatic Approaches for Environmental Management(Springer International Publishing, 2022-05-06T00:00:00) Sharma, Ritika; Saini, Khem Chand; Rajput, Sneh; Kumar, Mohit; Mehariya, Sanjeet; Karthikeyan, Obulisamy Parthiba; Bast, FelixContamination of different environmental matrices (air, soil, and water) by toxic heavy metals is a widespread problem that disturbs the environment as an outcome of many anthropocentric practices. Heavy metals exceeding the permissible limits exert deleterious impacts on human beings, causing life-threatening health manifestations and detrimental effects on the environment. This has alarmed the dire need to explore various modern remediation techniques that can be utilized to lower excessive concentrations. Owing to their high-cost effectiveness, unsatisfactory output, environmentally unfriendly, complicated procedure, and high operational costs, these technologies failed to find any practical utility in remediation. On the other hand, plants and associated microorganisms are receiving more consideration as a means of remediating or degrading environmental pollutants. This chapter provides us insights into the various environmental friendly techniques that will improve our environment�s quality. Among which, phytoremediation is considered an effective technique which is known for its esthetic benefits and endless applicability. Furthermore, metal-resistant bacteria (plant growth-promoting rhizobacteria) are also reported to play a pivotal role in the phytoremediation and solubilization of minerals. Thus, this chapter critically reviews the phytoremediation technology and the efficient exploitation of microbes to alleviate the environmental burden of toxic heavy metals. � The Author(s), under exclusive license to Springer Nature Switzerland AG 2022.Item Transcriptomic investigations of gene networks in response to arsenic accumulation in Brassica juncea (L.) Czern & Coss(Central University of Punjab, 2019) Thakur, Sapna; Bhardwaj, PankajArsenic (As), a widespread toxic metalloid is class I carcinogen known to cause adverse health effects in human. In the present study, As accumulation potential and differential gene expression in B. juncea is investigated. The amount of arsenic accumulated varied in the range of 15.99 to 1138.70 mg/Kg on dry weight basis in five cultivars. A decrease in chlorophyll content and increase in membrane damage and enzymatic activities of antioxidants was observed with increase in As concentration in the B. juncea cultivars. Using maximum As accumulating cultivar (RLM514), a total of 10,870 significantly differentially expressed transcripts in response to As treatment were identified. Further, the pathway analysis revealed a large scale reprogramming of genes involving carbon metabolism (2.5%), plant hormone signaling (1.4%), and glutathione metabolism (0.6%). Moreover, a comparative account of Cd toxicity revealed a total of 11,294 transcripts to be significantly differentially expressed. The genes related to response to chemical, oxidative stress, transport, and secondary metabolism were upregulated whereas multicellular organismal development, developmental process, photosynthesis were downregulated by Cd treatment. Furthermore, 616 membrane transport proteins were found to be significantly differentially expressed. Cd-related transporters such as metal transporter (Nramp1), metal tolerance protein (MTPC2, MTP11), cadmiumtransporting ATPase, and plant cadmium resistance protein (PCR2, PCR6) were upregulated while cadmium/zinc- transporting ATPase (HMA2, HMA3, HMA4), highaffinity calcium antiporter (CAX1), and iron transport protein (IRT1) were downregulated by Cd treatment. Pathway analysis revealed signaling cascades including plant hormones signaling, MAPK signaling and Ca signaling was modulated suggesting their role in Cd-stress tolerance. The regulation overview using MapMan also revealed gene expression related to plant hormones, calcium regulation and MAP kinases were altered under Cd-stress.Item Insights into the Molecular Mechanism of Arsenic Phytoremediation(Springer New York LLC, 2019) Thakur S.; Choudhary S.; Majeed A.; Singh A.; Bhardwaj P.Arsenic (As) is a widespread carcinogenic pollutant. Phytoremediation is the most suited technology for alleviating the As contamination of soil. In this review, we have discussed the uptake mechanism and the associated transporters for different As species. Glutathione, phytochelatins, metallothionins, and secondary metabolites play important role in As detoxification and enhancing tolerance. The roles of MAPK signaling and calcium signaling are highlighted in the perception of As stress along with phytohormones signaling in stress tolerance. Furthermore, transcription factors involved in regulation of gene expression under As stress are discussed. High-throughput sequencing has reduced the time duration and enhanced the knowledge regarding understanding the molecular mechanism of phytoremediation. The role of CRISPR/Cas9 and synthetic genes in context to phytoremediation is discussed. We have provided a holistic understanding of the present knowledge about phytoremediation in the context of mechanisms of the As uptake and tolerance. A complete understanding of the phytoremediation process is essential for As-risk mitigation and will help in augmenting its efficiency and true potential.Item Comparative transcriptome profiling reveals the reprogramming of gene networks under arsenic stress in Indian mustard(Canadian Science Publishing, 2019) Thakur S.; Choudhary S.; Dubey P.; Bhardwaj P.Arsenic is a widespread toxic metalloid that is classified as a class I carcinogen known to cause adverse health effects in humans. In the present study, we investigated arsenic accumulation potential and comparative gene expression in Indian mustard. The amount of arsenic accumulated in shoots varied in the range of 15.99–1138.70 mg/kg on a dry weight basis among five cultivars. Comparative expression analysis revealed 10 870 significantly differentially expressed genes mostly belonging to response to stress, metabolic processes, signal transduction, transporter activity, and transcription regulator activity to be up-regulated, while most of the genes involved in photosynthesis, developmental processes, and cell growth were found to be down-regulated in arsenic-treated tissues. Further, pathway analysis using the KEGG Automated Annotation server (KAAS) revealed a large-scale reprogramming of genes involved in genetic and environmental information processing pathways. Top pathways with maximum KEGG orthology hits included carbon metabolism (2.5%), biosynthesis of amino acids (2.1%), plant hormone signal transduction (1.4%), and glutathione metabolism (0.6%). A transcriptomic investigation to understand the arsenic accumulation and detoxification in Indian mustard will not only help to improve its phytoremediation efficiency but also add to the control measures required to check bioaccumulation of arsenic in the food chain.Item Comparative Transcriptome Profiling Under Cadmium Stress Reveals the Uptake and Tolerance Mechanism in Brassica juncea(Springer, 2019) Thakur, Sapna; Choudhary, Shurti; Bhardwaj, PankajCadmium (Cd) is a biologically non-essential and phytotoxic heavy metal pollutant. In this study, we estimated the Cd accumulation potential of Indian mustard and identified factors responsible for Cd uptake, tolerance, and detoxification. Eight transcriptomic libraries were sequenced and ??230 million good quality reads were generated. The alignment rate against B. juncea reference genome V1.5 varied in the range of 85.03-90.06%. Comparative expression analysis using DESeq2 revealed 11,294 genes to be significantly differentially expressed under Cd treatment. The agriGO singular enrichment analysis revealed genes related to response to chemical, oxidative stress, transport, and secondary metabolic process were upregulated, whereas multicellular organismal development, developmental process, and photosynthesis were downregulated by Cd treatment. Furthermore, 616 membrane transport proteins were found to be significantly differentially expressed. Cd-related transporters such as metal transporter (Nramp1), metal tolerance protein (MTPC2, MTP11), cadmium-transporting ATPase, and plant cadmium resistance protein (PCR2, PCR6) were upregulated whereas cadmium/zinc-transporting ATPase (HMA2, HMA3, HMA4), high-affinity calcium antiporter (CAX1), and iron transport protein (IRT1) were downregulated by Cd treatment. A total of 332 different gene-networks affected by Cd stress were identified using KAAS analysis. Various plant hormones signaling cascades were modulated suggesting their role in Cd stress tolerance. The regulation overview using MapMan analysis also revealed gene expression related to plant hormones, calcium regulation, and MAP kinases were altered under Cd stress.Item Comparative metabolic profiling of vetiver (Chrysopogon zizanioides) and maize (Zea mays) under lead stress(Elsevier Ltd, 2018) Pidatala, V.R.; Li, K.; Sarkar, D.; Wusirika, R.; Datta, R.Lead (Pb) contamination of residential soils in United States is attributed to use of Pb based paints prior to 1978 and their deterioration and accumulation in surface soils. Exposure to Pb due to ingestion and inhalation of Pb laden soil and dust causes neurological disorders, renal disorders, developmental and behavioral problems, particularly in children under the age of six. Vetiver grass is one of the leading choices for Pb remediation due to its ability to hyperaccumulate Pb, in addition to high biomass. In order to understand the effect of Pb on vetiver metabolic pathways, we compared the global metabolic changes in vetiver with that of maize, a Pb susceptible plant under Pb stress. Vetiver showed massive increase in levels of key metabolites in response to Pb, including amino acids, organic acids and coenzymes. Maize showed very modest increase in some of the same metabolites, and no change in others. The results provide the first indication of the difference in metabolic response of the hyperaccumulator, vetiver to lead stress as compared to maize. ? 2017 Elsevier Ltd