�ݺ�ߣshows by User: rainurajeev

�ݺ�ߣshows by User: rainurajeev / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: rainurajeev / Wed, 24 Aug 2016 14:35:53 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: rainurajeev Jsir 59(2) 87 101 /slideshow/jsir-592-87-101/65321881 jsir59287-101-160824143553
Psychrophilic (cold-adapted) microorganisms make a major contribution to Earth’s biomass and perform critical roles in global biogeochemical cycles. The vast extent and environmental diversity of Earth’s cold biosphere has selected for equally diverse microbial assemblages that can include archaea, bacteria, eucarya, and viruses. Underpinning the important ecological roles of psychrophiles are exquisite mechanisms of physiological adaptation. ]]>
Psychrophilic (cold-adapted) microorganisms make a major contribution to Earth’s biomass and perform critical roles in global biogeochemical cycles. The vast extent and environmental diversity of Earth’s cold biosphere has selected for equally diverse microbial assemblages that can include archaea, bacteria, eucarya, and viruses. Underpinning the important ecological roles of psychrophiles are exquisite mechanisms of physiological adaptation. ]]> Wed, 24 Aug 2016 14:35:53 GMT /slideshow/jsir-592-87-101/65321881 rainurajeev@slideshare.net(rainurajeev) Jsir 59(2) 87 101 rainurajeev Psychrophilic (cold-adapted) microorganisms make a major contribution to Earth’s biomass and perform critical roles in global biogeochemical cycles. The vast extent and environmental diversity of Earth’s cold biosphere has selected for equally diverse microbial assemblages that can include archaea, bacteria, eucarya, and viruses. Underpinning the important ecological roles of psychrophiles are exquisite mechanisms of physiological adaptation. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/jsir59287-101-160824143553-thumbnail.jpg?width=120&height=120&fit=bounds" /> Psychrophilic (cold-adapted) microorganisms make a major contribution to Earth’s biomass and perform critical roles in global biogeochemical cycles. The vast extent and environmental diversity of Earth’s cold biosphere has selected for equally diverse microbial assemblages that can include archaea, bacteria, eucarya, and viruses. Underpinning the important ecological roles of psychrophiles are exquisite mechanisms of physiological adaptation.

Jsir 59(2) 87 101 from Rainu Rajeev

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0 Areps siddiqui etal 2013 /slideshow/areps-siddiqui-etal-2013/65321847 arepssiddiquietal2013-160824143458
Psychrophilic (cold-adapted) microorganisms make a major contribution to Earth’s biomass and perform critical roles in global biogeochemical cycles. The vast extent and environmental diversity of Earth’s cold biosphere has selected for equally diverse microbial assemblages that can include archaea, bacteria, eucarya, and viruses. Underpinning the important ecological roles of psychrophiles are exquisite mechanisms of physiological adaptation. Evolution has also selected for cold-active traits at the level of molecular adaptation, and enzymes from psychrophiles are characterized by specific structural, functional, and stability properties. These characteristics of enzymes from psychrophiles not only manifest in efficient low-temperature activity, but also result in a flexible protein structure that enables biocatalysis in nonaqueous solvents. In this review, we examine the ecology of Antarctic psychrophiles, physiological adaptation of psychrophiles, and properties of cold-adapted proteins, and we provide a view of how these characteristics inform studies of astrobiology.]]>
Psychrophilic (cold-adapted) microorganisms make a major contribution to Earth’s biomass and perform critical roles in global biogeochemical cycles. The vast extent and environmental diversity of Earth’s cold biosphere has selected for equally diverse microbial assemblages that can include archaea, bacteria, eucarya, and viruses. Underpinning the important ecological roles of psychrophiles are exquisite mechanisms of physiological adaptation. Evolution has also selected for cold-active traits at the level of molecular adaptation, and enzymes from psychrophiles are characterized by specific structural, functional, and stability properties. These characteristics of enzymes from psychrophiles not only manifest in efficient low-temperature activity, but also result in a flexible protein structure that enables biocatalysis in nonaqueous solvents. In this review, we examine the ecology of Antarctic psychrophiles, physiological adaptation of psychrophiles, and properties of cold-adapted proteins, and we provide a view of how these characteristics inform studies of astrobiology.]]> Wed, 24 Aug 2016 14:34:57 GMT /slideshow/areps-siddiqui-etal-2013/65321847 rainurajeev@slideshare.net(rainurajeev) Areps siddiqui etal 2013 rainurajeev Psychrophilic (cold-adapted) microorganisms make a major contribution to Earth’s biomass and perform critical roles in global biogeochemical cycles. The vast extent and environmental diversity of Earth’s cold biosphere has selected for equally diverse microbial assemblages that can include archaea, bacteria, eucarya, and viruses. Underpinning the important ecological roles of psychrophiles are exquisite mechanisms of physiological adaptation. Evolution has also selected for cold-active traits at the level of molecular adaptation, and enzymes from psychrophiles are characterized by specific structural, functional, and stability properties. These characteristics of enzymes from psychrophiles not only manifest in efficient low-temperature activity, but also result in a flexible protein structure that enables biocatalysis in nonaqueous solvents. In this review, we examine the ecology of Antarctic psychrophiles, physiological adaptation of psychrophiles, and properties of cold-adapted proteins, and we provide a view of how these characteristics inform studies of astrobiology. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/arepssiddiquietal2013-160824143458-thumbnail.jpg?width=120&height=120&fit=bounds" /> Psychrophilic (cold-adapted) microorganisms make a major contribution to Earth’s biomass and perform critical roles in global biogeochemical cycles. The vast extent and environmental diversity of Earth’s cold biosphere has selected for equally diverse microbial assemblages that can include archaea, bacteria, eucarya, and viruses. Underpinning the important ecological roles of psychrophiles are exquisite mechanisms of physiological adaptation. Evolution has also selected for cold-active traits at the level of molecular adaptation, and enzymes from psychrophiles are characterized by specific structural, functional, and stability properties. These characteristics of enzymes from psychrophiles not only manifest in efficient low-temperature activity, but also result in a flexible protein structure that enables biocatalysis in nonaqueous solvents. In this review, we examine the ecology of Antarctic psychrophiles, physiological adaptation of psychrophiles, and properties of cold-adapted proteins, and we provide a view of how these characteristics inform studies of astrobiology.

Areps siddiqui etal 2013 from Rainu Rajeev

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0 Marine microbiology ecology & applications colin munn /slideshow/marine-microbiology-ecology-amp-applications-colin-munn/64583302 marinemicrobiology-ecologyapplicationscolinmunn-160801144219
For Marine Microiology]]>
For Marine Microiology]]> Mon, 01 Aug 2016 14:42:19 GMT /slideshow/marine-microbiology-ecology-amp-applications-colin-munn/64583302 rainurajeev@slideshare.net(rainurajeev) Marine microbiology ecology & applications colin munn rainurajeev For Marine Microiology <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/marinemicrobiology-ecologyapplicationscolinmunn-160801144219-thumbnail.jpg?width=120&height=120&fit=bounds" /> For Marine Microiology

Marine microbiology ecology & applications colin munn from Rainu Rajeev

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0 Agricultural biotechnology /slideshow/agricultural-biotechnology-64518551/64518551 agriculturalbiotechnology-160729160354
All living organisms have the ability to improve themselves through natural means in order to adapt to changing environmental conditions. However, it takes hundreds of years before any detectable improvement is obtained. Man then learned how to domesticate and breed plants in order to develop crops to his own liking and needs using various means including biotechnology. Biotechnology is defined as a set of tools that uses living organisms (or parts of organisms) to make or modify a product, improve plants, trees or animals, or develop microorganisms for specific uses. Agricultural biotechnology is the term used in crop and livestock improvement through biotechnology tools. This monograph will focus only on agricultural crop biotechnology. Biotechnology encompasses a number of tools and elements of conventional breeding techniques, bioinformatics, microbiology, molecular genetics, biochemistry, plant physiology, and molecular biology. The biotechnology tools that are important for agricultural biotechnology include: - Conventional plant breeding - Tissue culture and micropropagation - Molecular breeding or marker assisted selection - Genetic engineering and GM crops - Molecular Diagnostic Tools ]]>
All living organisms have the ability to improve themselves through natural means in order to adapt to changing environmental conditions. However, it takes hundreds of years before any detectable improvement is obtained. Man then learned how to domesticate and breed plants in order to develop crops to his own liking and needs using various means including biotechnology. Biotechnology is defined as a set of tools that uses living organisms (or parts of organisms) to make or modify a product, improve plants, trees or animals, or develop microorganisms for specific uses. Agricultural biotechnology is the term used in crop and livestock improvement through biotechnology tools. This monograph will focus only on agricultural crop biotechnology. Biotechnology encompasses a number of tools and elements of conventional breeding techniques, bioinformatics, microbiology, molecular genetics, biochemistry, plant physiology, and molecular biology. The biotechnology tools that are important for agricultural biotechnology include: - Conventional plant breeding - Tissue culture and micropropagation - Molecular breeding or marker assisted selection - Genetic engineering and GM crops - Molecular Diagnostic Tools ]]> Fri, 29 Jul 2016 16:03:54 GMT /slideshow/agricultural-biotechnology-64518551/64518551 rainurajeev@slideshare.net(rainurajeev) Agricultural biotechnology rainurajeev All living organisms have the ability to improve themselves through natural means in order to adapt to changing environmental conditions. However, it takes hundreds of years before any detectable improvement is obtained. Man then learned how to domesticate and breed plants in order to develop crops to his own liking and needs using various means including biotechnology. Biotechnology is defined as a set of tools that uses living organisms (or parts of organisms) to make or modify a product, improve plants, trees or animals, or develop microorganisms for specific uses. Agricultural biotechnology is the term used in crop and livestock improvement through biotechnology tools. This monograph will focus only on agricultural crop biotechnology. Biotechnology encompasses a number of tools and elements of conventional breeding techniques, bioinformatics, microbiology, molecular genetics, biochemistry, plant physiology, and molecular biology. The biotechnology tools that are important for agricultural biotechnology include: - Conventional plant breeding - Tissue culture and micropropagation - Molecular breeding or marker assisted selection - Genetic engineering and GM crops - Molecular Diagnostic Tools <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/agriculturalbiotechnology-160729160354-thumbnail.jpg?width=120&height=120&fit=bounds" /> All living organisms have the ability to improve themselves through natural means in order to adapt to changing environmental conditions. However, it takes hundreds of years before any detectable improvement is obtained. Man then learned how to domesticate and breed plants in order to develop crops to his own liking and needs using various means including biotechnology. Biotechnology is defined as a set of tools that uses living organisms (or parts of organisms) to make or modify a product, improve plants, trees or animals, or develop microorganisms for specific uses. Agricultural biotechnology is the term used in crop and livestock improvement through biotechnology tools. This monograph will focus only on agricultural crop biotechnology. Biotechnology encompasses a number of tools and elements of conventional breeding techniques, bioinformatics, microbiology, molecular genetics, biochemistry, plant physiology, and molecular biology. The biotechnology tools that are important for agricultural biotechnology include: - Conventional plant breeding - Tissue culture and micropropagation - Molecular breeding or marker assisted selection - Genetic engineering and GM crops - Molecular Diagnostic Tools

Agricultural biotechnology from Rainu Rajeev

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0 Marine board pp17_microcean /slideshow/marine-board-pp17microcean/64518361 marineboardpp17microcean-160729155810
The Marine Board provides a pan-European platform for its member organisations to develop common priorities, to advance marine research, and to bridge the gap between science and policy in order to meet future marine science challenges and opportunities. The Marine Board was established in 1995 to facilitate enhanced cooperation between European marine science organisations (both research institutes and research funding agencies) towards the development of a common vision on the research priorities and strategies for marine science in Europe. In 2012, the Marine Board represents 34 Member Organisations from 20 countries. The marine Board provides the essential components for transferring knowledge for leadership in marine research in Europe. Adopting a strategic role, the Marine Board serves its member organisations by providing a forum within which marine research policy advice to national agencies and to the European Commission is developed, with the objective of promoting the establishment of the European Marine Research Area.]]>
The Marine Board provides a pan-European platform for its member organisations to develop common priorities, to advance marine research, and to bridge the gap between science and policy in order to meet future marine science challenges and opportunities. The Marine Board was established in 1995 to facilitate enhanced cooperation between European marine science organisations (both research institutes and research funding agencies) towards the development of a common vision on the research priorities and strategies for marine science in Europe. In 2012, the Marine Board represents 34 Member Organisations from 20 countries. The marine Board provides the essential components for transferring knowledge for leadership in marine research in Europe. Adopting a strategic role, the Marine Board serves its member organisations by providing a forum within which marine research policy advice to national agencies and to the European Commission is developed, with the objective of promoting the establishment of the European Marine Research Area.]]> Fri, 29 Jul 2016 15:58:10 GMT /slideshow/marine-board-pp17microcean/64518361 rainurajeev@slideshare.net(rainurajeev) Marine board pp17_microcean rainurajeev The Marine Board provides a pan-European platform for its member organisations to develop common priorities, to advance marine research, and to bridge the gap between science and policy in order to meet future marine science challenges and opportunities. The Marine Board was established in 1995 to facilitate enhanced cooperation between European marine science organisations (both research institutes and research funding agencies) towards the development of a common vision on the research priorities and strategies for marine science in Europe. In 2012, the Marine Board represents 34 Member Organisations from 20 countries. The marine Board provides the essential components for transferring knowledge for leadership in marine research in Europe. Adopting a strategic role, the Marine Board serves its member organisations by providing a forum within which marine research policy advice to national agencies and to the European Commission is developed, with the objective of promoting the establishment of the European Marine Research Area. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/marineboardpp17microcean-160729155810-thumbnail.jpg?width=120&height=120&fit=bounds" /> The Marine Board provides a pan-European platform for its member organisations to develop common priorities, to advance marine research, and to bridge the gap between science and policy in order to meet future marine science challenges and opportunities. The Marine Board was established in 1995 to facilitate enhanced cooperation between European marine science organisations (both research institutes and research funding agencies) towards the development of a common vision on the research priorities and strategies for marine science in Europe. In 2012, the Marine Board represents 34 Member Organisations from 20 countries. The marine Board provides the essential components for transferring knowledge for leadership in marine research in Europe. Adopting a strategic role, the Marine Board serves its member organisations by providing a forum within which marine research policy advice to national agencies and to the European Commission is developed, with the objective of promoting the establishment of the European Marine Research Area.

Marine board pp17_microcean from Rainu Rajeev

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0 Bioinformatics final /slideshow/bioinformatics-final/64518037 bioinformaticsfinal-160729154710
BIOIFORMATICS]]>
BIOIFORMATICS]]> Fri, 29 Jul 2016 15:47:10 GMT /slideshow/bioinformatics-final/64518037 rainurajeev@slideshare.net(rainurajeev) Bioinformatics final rainurajeev BIOIFORMATICS <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/bioinformaticsfinal-160729154710-thumbnail.jpg?width=120&height=120&fit=bounds" /> BIOIFORMATICS

Bioinformatics final from Rainu Rajeev

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0 Protein structure 2 /slideshow/protein-structure-2/64517974 proteinstructure2-160729154503
BIOIFORMATICS ]]>
BIOIFORMATICS ]]> Fri, 29 Jul 2016 15:45:03 GMT /slideshow/protein-structure-2/64517974 rainurajeev@slideshare.net(rainurajeev) Protein structure 2 rainurajeev BIOIFORMATICS <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/proteinstructure2-160729154503-thumbnail.jpg?width=120&height=120&fit=bounds" /> BIOIFORMATICS

Protein structure 2 from Rainu Rajeev

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0 https://cdn.slidesharecdn.com/profile-photo-rainurajeev-48x48.jpg?cb=1523413313 rainurajeev6@gmail.com https://cdn.slidesharecdn.com/ss_thumbnails/jsir59287-101-160824143553-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/jsir-592-87-101/65321881 Jsir 59(2) 87 101 https://cdn.slidesharecdn.com/ss_thumbnails/arepssiddiquietal2013-160824143458-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/areps-siddiqui-etal-2013/65321847 Areps siddiqui etal 2013 https://cdn.slidesharecdn.com/ss_thumbnails/marinemicrobiology-ecologyapplicationscolinmunn-160801144219-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/marine-microbiology-ecology-amp-applications-colin-munn/64583302 Marine microbiology e...