�ݺ�ߣshows by User: Ananya39

�ݺ�ߣshows by User: Ananya39 / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: Ananya39 / Tue, 31 May 2022 13:32:39 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: Ananya39 CRISP_ana.pptx /slideshow/crispanapptx/251892860 crispana-220531133239-90ba48ad
CRISPR/Cas systems: The link between functional genes and genetic improvement. The discovery and modification of CRISPR/Cas system, a nature-occurred gene editing tool, opens an era for studying gene function and precision crop breeding cutting-edge biotechnological tool for crop improvement Used for pathogen resistance, abiotic tolerance, plant development and morphology and even secondary metabolism and fiber development ]]>
CRISPR/Cas systems: The link between functional genes and genetic improvement. The discovery and modification of CRISPR/Cas system, a nature-occurred gene editing tool, opens an era for studying gene function and precision crop breeding cutting-edge biotechnological tool for crop improvement Used for pathogen resistance, abiotic tolerance, plant development and morphology and even secondary metabolism and fiber development ]]> Tue, 31 May 2022 13:32:39 GMT /slideshow/crispanapptx/251892860 Ananya39@slideshare.net(Ananya39) CRISP_ana.pptx Ananya39 CRISPR/Cas systems: The link between functional genes and genetic improvement. The discovery and modification of CRISPR/Cas system, a nature-occurred gene editing tool, opens an era for studying gene function and precision crop breeding cutting-edge biotechnological tool for crop improvement Used for pathogen resistance, abiotic tolerance, plant development and morphology and even secondary metabolism and fiber development <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/crispana-220531133239-90ba48ad-thumbnail.jpg?width=120&height=120&fit=bounds" /> CRISPR/Cas systems: The link between functional genes and genetic improvement. The discovery and modification of CRISPR/Cas system, a nature-occurred gene editing tool, opens an era for studying gene function and precision crop breeding cutting-edge biotechnological tool for crop improvement Used for pathogen resistance, abiotic tolerance, plant development and morphology and even secondary metabolism and fiber development

CRISP_ana.pptx from Ananya Sinha

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0 1st_Seminar_PHD.pptx /slideshow/1stseminarphdpptx/251892826 1stseminarphd-220531132532-3fcd548f
Multigene cloning approach for crop improvement This technology has been widely adopted by the life science research community especially for applications that require the transfer of thousands of DNA fragments into one type of plasmid. It provides a promising platform for developing gene stacking technologies for crops by which we can integrate many genes of interest simultaneously for crop improvement programs.Site-specific recombinases are the enzymes used for gateway cloning.They fall into one of the two specific families, namely Tyrosine and Serine family. The former includes Cre , FLP and R which bind to identical recombinase binding sites lox, FRT, and RS, respectively. The later includes phiC31 Integrase and phiC31 excisionase (Thorpe and Smith, 1998), which binds to non-identical sites attB/attP and attL/attR, respectively.]]>
Multigene cloning approach for crop improvement This technology has been widely adopted by the life science research community especially for applications that require the transfer of thousands of DNA fragments into one type of plasmid. It provides a promising platform for developing gene stacking technologies for crops by which we can integrate many genes of interest simultaneously for crop improvement programs.Site-specific recombinases are the enzymes used for gateway cloning.They fall into one of the two specific families, namely Tyrosine and Serine family. The former includes Cre , FLP and R which bind to identical recombinase binding sites lox, FRT, and RS, respectively. The later includes phiC31 Integrase and phiC31 excisionase (Thorpe and Smith, 1998), which binds to non-identical sites attB/attP and attL/attR, respectively.]]> Tue, 31 May 2022 13:25:32 GMT /slideshow/1stseminarphdpptx/251892826 Ananya39@slideshare.net(Ananya39) 1st_Seminar_PHD.pptx Ananya39 Multigene cloning approach for crop improvement This technology has been widely adopted by the life science research community especially for applications that require the transfer of thousands of DNA fragments into one type of plasmid. It provides a promising platform for developing gene stacking technologies for crops by which we can integrate many genes of interest simultaneously for crop improvement programs.Site-specific recombinases are the enzymes used for gateway cloning.They fall into one of the two specific families, namely Tyrosine and Serine family. The former includes Cre , FLP and R which bind to identical recombinase binding sites lox, FRT, and RS, respectively. The later includes phiC31 Integrase and phiC31 excisionase (Thorpe and Smith, 1998), which binds to non-identical sites attB/attP and attL/attR, respectively. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/1stseminarphd-220531132532-3fcd548f-thumbnail.jpg?width=120&height=120&fit=bounds" /> Multigene cloning approach for crop improvement This technology has been widely adopted by the life science research community especially for applications that require the transfer of thousands of DNA fragments into one type of plasmid. It provides a promising platform for developing gene stacking technologies for crops by which we can integrate many genes of interest simultaneously for crop improvement programs.Site-specific recombinases are the enzymes used for gateway cloning.They fall into one of the two specific families, namely Tyrosine and Serine family. The former includes Cre , FLP and R which bind to identical recombinase binding sites lox, FRT, and RS, respectively. The later includes phiC31 Integrase and phiC31 excisionase (Thorpe and Smith, 1998), which binds to non-identical sites attB/attP and attL/attR, respectively.

1st_Seminar_PHD.pptx from Ananya Sinha

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0 Fermentative metabolism and development of bioprocessing technology, processing and production of recombinant products /slideshow/fermentative-metabolism-and-development-of-bioprocessing-technology-processing-and-production-of-recombinant-products/249382718 phdpbt-603-210616114936
This ppt includes, fermentation, the metabolism, the bioprocessor, it's technology, and the recombinant products. It connects all these topics together. The outline for plants and animals is nearly same]]>
This ppt includes, fermentation, the metabolism, the bioprocessor, it's technology, and the recombinant products. It connects all these topics together. The outline for plants and animals is nearly same]]> Wed, 16 Jun 2021 11:49:35 GMT /slideshow/fermentative-metabolism-and-development-of-bioprocessing-technology-processing-and-production-of-recombinant-products/249382718 Ananya39@slideshare.net(Ananya39) Fermentative metabolism and development of bioprocessing technology, processing and production of recombinant products Ananya39 This ppt includes, fermentation, the metabolism, the bioprocessor, it's technology, and the recombinant products. It connects all these topics together. The outline for plants and animals is nearly same <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/phdpbt-603-210616114936-thumbnail.jpg?width=120&height=120&fit=bounds" /> This ppt includes, fermentation, the metabolism, the bioprocessor, it's technology, and the recombinant products. It connects all these topics together. The outline for plants and animals is nearly same

Fermentative metabolism and development of bioprocessing technology, processing and production of recombinant products from Ananya Sinha

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0 Suspension Culture and Single Cell Cultures, Culturing methods, maintenance and application /slideshow/ananya-248914882/248914882 ananya-210603045935
Suspension Culture and Single Cell Cultures, Culturing methods, maintenance and application Generally, suspension culture is a one stop technology to produce secondary metabolites on a large scale in-vitro, irrespective of the climatic condition or nutrient availability (as required in field plants). In this presentation, we will see the importance of suspension culture, culturing methods and it's application (mostly with respect to plants) and also focus on what exactly is a single cell culture.]]>
Suspension Culture and Single Cell Cultures, Culturing methods, maintenance and application Generally, suspension culture is a one stop technology to produce secondary metabolites on a large scale in-vitro, irrespective of the climatic condition or nutrient availability (as required in field plants). In this presentation, we will see the importance of suspension culture, culturing methods and it's application (mostly with respect to plants) and also focus on what exactly is a single cell culture.]]> Thu, 03 Jun 2021 04:59:35 GMT /slideshow/ananya-248914882/248914882 Ananya39@slideshare.net(Ananya39) Suspension Culture and Single Cell Cultures, Culturing methods, maintenance and application Ananya39 Suspension Culture and Single Cell Cultures, Culturing methods, maintenance and application Generally, suspension culture is a one stop technology to produce secondary metabolites on a large scale in-vitro, irrespective of the climatic condition or nutrient availability (as required in field plants). In this presentation, we will see the importance of suspension culture, culturing methods and it's application (mostly with respect to plants) and also focus on what exactly is a single cell culture. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/ananya-210603045935-thumbnail.jpg?width=120&height=120&fit=bounds" /> Suspension Culture and Single Cell Cultures, Culturing methods, maintenance and application Generally, suspension culture is a one stop technology to produce secondary metabolites on a large scale in-vitro, irrespective of the climatic condition or nutrient availability (as required in field plants). In this presentation, we will see the importance of suspension culture, culturing methods and it's application (mostly with respect to plants) and also focus on what exactly is a single cell culture.

Suspension Culture and Single Cell Cultures, Culturing methods, maintenance and application from Ananya Sinha

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0 Gpcr in plants /slideshow/gpcr-in-plants/248546355 gpcrinplants-210526042132
Do plants contain typical GPCRs?” How is G-protein signaling operating in plants. G-proteins are universal signal transducers mediating many cellular responses. In animal systems the G-protein signaling cycle is activated by seven transmembrane-spanning G-protein coupled receptors (or GPCRs, popularly known as “serpentine receptors”). Whether typical G protein-coupled receptors (GPCRs) exist in plants or not is a fundamental question. In contrast to the animal system, the existence of these types of receptors in plants still remains controversial. While in animals ligand binding causes a change in receptor conformation that activate a particular G Protein, in plants, such mechanism is unknown. In fact, it is considered that the plants G-Proteins are self-activating. The G Proteins have their respective GPCRs in animal system. A lot of information is already accumulated in animal system and hence the animal GPCRs are considered “canonical.” Thus, from the very beginning, plant G-proteins have been compared with the animal counterparts and studied as an extrapolation of the animal model. This presentation provides an insight into the molecular mechanisms of G Protein activation in plants as well as whether “canonical” GPCRs are present in any plant species or not. ]]>
Do plants contain typical GPCRs?” How is G-protein signaling operating in plants. G-proteins are universal signal transducers mediating many cellular responses. In animal systems the G-protein signaling cycle is activated by seven transmembrane-spanning G-protein coupled receptors (or GPCRs, popularly known as “serpentine receptors”). Whether typical G protein-coupled receptors (GPCRs) exist in plants or not is a fundamental question. In contrast to the animal system, the existence of these types of receptors in plants still remains controversial. While in animals ligand binding causes a change in receptor conformation that activate a particular G Protein, in plants, such mechanism is unknown. In fact, it is considered that the plants G-Proteins are self-activating. The G Proteins have their respective GPCRs in animal system. A lot of information is already accumulated in animal system and hence the animal GPCRs are considered “canonical.” Thus, from the very beginning, plant G-proteins have been compared with the animal counterparts and studied as an extrapolation of the animal model. This presentation provides an insight into the molecular mechanisms of G Protein activation in plants as well as whether “canonical” GPCRs are present in any plant species or not. ]]> Wed, 26 May 2021 04:21:32 GMT /slideshow/gpcr-in-plants/248546355 Ananya39@slideshare.net(Ananya39) Gpcr in plants Ananya39 Do plants contain typical GPCRs?” How is G-protein signaling operating in plants. G-proteins are universal signal transducers mediating many cellular responses. In animal systems the G-protein signaling cycle is activated by seven transmembrane-spanning G-protein coupled receptors (or GPCRs, popularly known as “serpentine receptors”). Whether typical G protein-coupled receptors (GPCRs) exist in plants or not is a fundamental question. In contrast to the animal system, the existence of these types of receptors in plants still remains controversial. While in animals ligand binding causes a change in receptor conformation that activate a particular G Protein, in plants, such mechanism is unknown. In fact, it is considered that the plants G-Proteins are self-activating. The G Proteins have their respective GPCRs in animal system. A lot of information is already accumulated in animal system and hence the animal GPCRs are considered “canonical.” Thus, from the very beginning, plant G-proteins have been compared with the animal counterparts and studied as an extrapolation of the animal model. This presentation provides an insight into the molecular mechanisms of G Protein activation in plants as well as whether “canonical” GPCRs are present in any plant species or not. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/gpcrinplants-210526042132-thumbnail.jpg?width=120&height=120&fit=bounds" /> Do plants contain typical GPCRs?” How is G-protein signaling operating in plants. G-proteins are universal signal transducers mediating many cellular responses. In animal systems the G-protein signaling cycle is activated by seven transmembrane-spanning G-protein coupled receptors (or GPCRs, popularly known as “serpentine receptors”). Whether typical G protein-coupled receptors (GPCRs) exist in plants or not is a fundamental question. In contrast to the animal system, the existence of these types of receptors in plants still remains controversial. While in animals ligand binding causes a change in receptor conformation that activate a particular G Protein, in plants, such mechanism is unknown. In fact, it is considered that the plants G-Proteins are self-activating. The G Proteins have their respective GPCRs in animal system. A lot of information is already accumulated in animal system and hence the animal GPCRs are considered “canonical.” Thus, from the very beginning, plant G-proteins have been compared with the animal counterparts and studied as an extrapolation of the animal model. This presentation provides an insight into the molecular mechanisms of G Protein activation in plants as well as whether “canonical” GPCRs are present in any plant species or not.

Gpcr in plants from Ananya Sinha

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0 Genetic Transformation of Maize: Conventional Methods and Precision Genome Modification /slideshow/pbt-604-ananya/248546135 pbt-604ananya-210526040748
Genetic Transformation of Maize: Conventional Methods and Precision Genome Modification This is a summary of the above chapter mentioned in "Biotechnology of Major Cereals". The precision genome modification is defined majorly focused on comparing the conventional genome modification methods with the modern ones.]]>
Genetic Transformation of Maize: Conventional Methods and Precision Genome Modification This is a summary of the above chapter mentioned in "Biotechnology of Major Cereals". The precision genome modification is defined majorly focused on comparing the conventional genome modification methods with the modern ones.]]> Wed, 26 May 2021 04:07:48 GMT /slideshow/pbt-604-ananya/248546135 Ananya39@slideshare.net(Ananya39) Genetic Transformation of Maize: Conventional Methods and Precision Genome Modification Ananya39 Genetic Transformation of Maize: Conventional Methods and Precision Genome Modification This is a summary of the above chapter mentioned in "Biotechnology of Major Cereals". The precision genome modification is defined majorly focused on comparing the conventional genome modification methods with the modern ones. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/pbt-604ananya-210526040748-thumbnail.jpg?width=120&height=120&fit=bounds" /> Genetic Transformation of Maize: Conventional Methods and Precision Genome Modification This is a summary of the above chapter mentioned in "Biotechnology of Major Cereals". The precision genome modification is defined majorly focused on comparing the conventional genome modification methods with the modern ones.

Genetic Transformation of Maize: Conventional Methods and Precision Genome Modification from Ananya Sinha

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0 https://cdn.slidesharecdn.com/profile-photo-Ananya39-48x48.jpg?cb=1722596810 https://cdn.slidesharecdn.com/ss_thumbnails/crispana-220531133239-90ba48ad-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/crispanapptx/251892860 CRISP_ana.pptx https://cdn.slidesharecdn.com/ss_thumbnails/1stseminarphd-220531132532-3fcd548f-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/1stseminarphdpptx/251892826 1st_Seminar_PHD.pptx https://cdn.slidesharecdn.com/ss_thumbnails/phdpbt-603-210616114936-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/fermentative-metabolism-and-development-of-bioprocessing-technology-processing-and-production-of-recombinant-products/249382718 Fermentative metabolis...