Advances in Plastid Biology and Its Applications

One of the distinguishing features of plants is the presence of membrane-bound organelles called plastids. Starting from proplastids (undifferentiated plastids) they readily develop into specialised types, which are involved in a range of cellular functions such as photosynthesis, nitrogen assimilat...

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Tipo de recurso:: Book

Fecha de publicación:: 2016

Institución:: Universidad de Bogotá Jorge Tadeo Lozano

Repositorio:: Expeditio: repositorio UTadeo

Idioma:: eng

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dc.title.spa.fl_str_mv	Advances in Plastid Biology and Its Applications
title	Advances in Plastid Biology and Its Applications
spellingShingle	Advances in Plastid Biology and Its Applications Science (General) Botany Plastids Plastid transformation Retrograde signalling Metabolic Engineering Plastid polymerases Plastid replication Biopharming Plastid division Plastid biogenesis Plastid development
title_short	Advances in Plastid Biology and Its Applications
title_full	Advances in Plastid Biology and Its Applications
title_fullStr	Advances in Plastid Biology and Its Applications
title_full_unstemmed	Advances in Plastid Biology and Its Applications
title_sort	Advances in Plastid Biology and Its Applications
dc.subject.spa.fl_str_mv	Science (General) Botany Plastids
topic	Science (General) Botany Plastids Plastid transformation Retrograde signalling Metabolic Engineering Plastid polymerases Plastid replication Biopharming Plastid division Plastid biogenesis Plastid development
dc.subject.lemb.spa.fl_str_mv	Plastid transformation Retrograde signalling Metabolic Engineering Plastid polymerases Plastid replication
dc.subject.keyword.spa.fl_str_mv	Biopharming Plastid division Plastid biogenesis Plastid development
description	One of the distinguishing features of plants is the presence of membrane-bound organelles called plastids. Starting from proplastids (undifferentiated plastids) they readily develop into specialised types, which are involved in a range of cellular functions such as photosynthesis, nitrogen assimilation, biosynthesis of sucrose, starch, chlorophyll, carotenoids, fatty acids, amino acids, and secondary metabolites as well as a number of metabolic reactions. The central role of plastids in many aspects of plant cell biology means an in-depth understanding is key for a holistic view of plant physiology. Despite the vast amount of research, the molecular details of many aspects of plastid biology remains limited. Plastids possess their own high-copy number genome known as the plastome. Manipulation of the plastid genome has been developed as an alternative way to developing transgenic plants for various biotechnological applications. High-copy number of the plastome, site-specific integration of transgenes through homologous recombination, and potential to express proteins at high levels (>70% of total soluble proteins has been reported in some cases) are some of the technologies being developed. Additionally, plastids are inherited maternally, providing a natural gene containment system, and do not follow Mendelian laws of inheritance, allowing each individual member of the progeny of a transplastomic line to uniformly express transgene(s). Both algal and higher plant chloroplast transformation has been demonstrated, and with the ability to be propagated either in bioreactors or in the field, both systems are well suited for scale up of production. The manipulation of chloroplast genes is also essential for many approaches that attempt to increase biomass accumulation or re-routing metabolic pathways for biofortification, food and fuel production. This includes metabolic engineering for lipid production, adapting the light harvesting apparatus to improve solar conversion efficiencies and engineering means of suppressing photorespiration in crop species, which range from the introduction of artificial carbon concentrating mechanisms, or those pre-existing elsewhere in nature, to bypassing ribulose bisphosphate carboxylase/oxygenase entirely. The purpose of this eBook is to provide a compilation of the latest research on various aspects of plastid biology including basic biology, biopharming, metabolic engineering, bio-fortification, stress physiology, and biofuel production.One of the distinguishing features of plants is the presence of membrane-bound organelles called plastids. Starting from proplastids (undifferentiated plastids) they readily develop into specialised types, which are involved in a range of cellular functions such as photosynthesis, nitrogen assimilation, biosynthesis of sucrose, starch, chlorophyll, carotenoids, fatty acids, amino acids, and secondary metabolites as well as a number of metabolic reactions. The central role of plastids in many aspects of plant cell biology means an in-depth understanding is key for a holistic view of plant physiology. Despite the vast amount of research, the molecular details of many aspects of plastid biology remains limited. Plastids possess their own high-copy number genome known as the plastome. Manipulation of the plastid genome has been developed as an alternative way to developing transgenic plants for various biotechnological applications. High-copy number of the plastome, site-specific integration of transgenes through homologous recombination, and potential to express proteins at high levels (>70% of total soluble proteins has been reported in some cases) are some of the technologies being developed. Additionally, plastids are inherited maternally, providing a natural gene containment system, and do not follow Mendelian laws of inheritance, allowing each individual member of the progeny of a transplastomic line to uniformly express transgene(s). Both algal and higher plant chloroplast transformation has been demonstrated, and with the ability to be propagated either in bioreactors or in the field, both systems are well suited for scale up of production. The manipulation of chloroplast genes is also essential for many approaches that attempt to increase biomass accumulation or re-routing metabolic pathways for biofortification, food and fuel production. This includes metabolic engineering for lipid production, adapting the light harvesting apparatus to improve solar conversion efficiencies and engineering means of suppressing photorespiration in crop species, which range from the introduction of artificial carbon concentrating mechanisms, or those pre-existing elsewhere in nature, to bypassing ribulose bisphosphate carboxylase/oxygenase entirely. The purpose of this eBook is to provide a compilation of the latest research on various aspects of plastid biology including basic biology, biopharming, metabolic engineering, bio-fortification, stress physiology, and biofuel production.
publishDate	2016
dc.date.created.none.fl_str_mv	2016
dc.date.accessioned.none.fl_str_mv	2020-10-05T18:25:25Z
dc.date.available.none.fl_str_mv	2020-10-05T18:25:25Z
dc.type.local.spa.fl_str_mv	Libro
dc.type.coar.spa.fl_str_mv	http://purl.org/coar/resource_type/c_2f33
format	http://purl.org/coar/resource_type/c_2f33
dc.identifier.isbn.none.fl_str_mv	978-2-88945-048-0
dc.identifier.issn.none.fl_str_mv	16648714
dc.identifier.other.none.fl_str_mv	https://www.frontiersin.org/research-topics/3433/advances-in plastid-biology-and-its-applications#nogo
dc.identifier.uri.none.fl_str_mv	http://hdl.handle.net/20.500.12010/14205
dc.identifier.doi.none.fl_str_mv	10.3389/978-2-88945-048-0
identifier_str_mv	978-2-88945-048-0 16648714 10.3389/978-2-88945-048-0
url	https://www.frontiersin.org/research-topics/3433/advances-in plastid-biology-and-its-applications#nogo http://hdl.handle.net/20.500.12010/14205
dc.language.iso.spa.fl_str_mv	eng
language	eng
dc.relation.references.none.fl_str_mv	Ahmad, N., Burgess, S. J., Nielsen, B. L., eds. (2016). Advances in Plastid Biology and Its Applications. Lausanne: Frontiers Media. doi: 10.3389/978-2-88945-048-0
dc.rights.coar.fl_str_mv	http://purl.org/coar/access_right/c_abf2
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rights_invalid_str_mv	Abierto (Texto Completo) http://purl.org/coar/access_right/c_abf2
dc.format.extent.spa.fl_str_mv	161 Páginas
dc.format.mimetype.spa.fl_str_mv	application/pdf
dc.publisher.spa.fl_str_mv	Frontiers Media SA
institution	Universidad de Bogotá Jorge Tadeo Lozano
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spelling	2020-10-05T18:25:25Z2020-10-05T18:25:25Z2016978-2-88945-048-016648714https://www.frontiersin.org/research-topics/3433/advances-in plastid-biology-and-its-applications#nogohttp://hdl.handle.net/20.500.12010/1420510.3389/978-2-88945-048-0161 Páginasapplication/pdfengFrontiers Media SAScience (General)BotanyPlastidsPlastid transformationRetrograde signallingMetabolic EngineeringPlastid polymerasesPlastid replicationBiopharmingPlastid divisionPlastid biogenesisPlastid developmentAdvances in Plastid Biology and Its ApplicationsLibrohttp://purl.org/coar/resource_type/c_2f33Abierto (Texto Completo)http://purl.org/coar/access_right/c_abf2Ahmad, N., Burgess, S. J., Nielsen, B. L., eds. (2016). Advances in Plastid Biology and Its Applications. Lausanne: Frontiers Media. doi: 10.3389/978-2-88945-048-0One of the distinguishing features of plants is the presence of membrane-bound organelles called plastids. Starting from proplastids (undifferentiated plastids) they readily develop into specialised types, which are involved in a range of cellular functions such as photosynthesis, nitrogen assimilation, biosynthesis of sucrose, starch, chlorophyll, carotenoids, fatty acids, amino acids, and secondary metabolites as well as a number of metabolic reactions. The central role of plastids in many aspects of plant cell biology means an in-depth understanding is key for a holistic view of plant physiology. Despite the vast amount of research, the molecular details of many aspects of plastid biology remains limited. Plastids possess their own high-copy number genome known as the plastome. Manipulation of the plastid genome has been developed as an alternative way to developing transgenic plants for various biotechnological applications. High-copy number of the plastome, site-specific integration of transgenes through homologous recombination, and potential to express proteins at high levels (>70% of total soluble proteins has been reported in some cases) are some of the technologies being developed. Additionally, plastids are inherited maternally, providing a natural gene containment system, and do not follow Mendelian laws of inheritance, allowing each individual member of the progeny of a transplastomic line to uniformly express transgene(s). Both algal and higher plant chloroplast transformation has been demonstrated, and with the ability to be propagated either in bioreactors or in the field, both systems are well suited for scale up of production. The manipulation of chloroplast genes is also essential for many approaches that attempt to increase biomass accumulation or re-routing metabolic pathways for biofortification, food and fuel production. This includes metabolic engineering for lipid production, adapting the light harvesting apparatus to improve solar conversion efficiencies and engineering means of suppressing photorespiration in crop species, which range from the introduction of artificial carbon concentrating mechanisms, or those pre-existing elsewhere in nature, to bypassing ribulose bisphosphate carboxylase/oxygenase entirely. The purpose of this eBook is to provide a compilation of the latest research on various aspects of plastid biology including basic biology, biopharming, metabolic engineering, bio-fortification, stress physiology, and biofuel production.One of the distinguishing features of plants is the presence of membrane-bound organelles called plastids. Starting from proplastids (undifferentiated plastids) they readily develop into specialised types, which are involved in a range of cellular functions such as photosynthesis, nitrogen assimilation, biosynthesis of sucrose, starch, chlorophyll, carotenoids, fatty acids, amino acids, and secondary metabolites as well as a number of metabolic reactions. The central role of plastids in many aspects of plant cell biology means an in-depth understanding is key for a holistic view of plant physiology. Despite the vast amount of research, the molecular details of many aspects of plastid biology remains limited. Plastids possess their own high-copy number genome known as the plastome. Manipulation of the plastid genome has been developed as an alternative way to developing transgenic plants for various biotechnological applications. High-copy number of the plastome, site-specific integration of transgenes through homologous recombination, and potential to express proteins at high levels (>70% of total soluble proteins has been reported in some cases) are some of the technologies being developed. Additionally, plastids are inherited maternally, providing a natural gene containment system, and do not follow Mendelian laws of inheritance, allowing each individual member of the progeny of a transplastomic line to uniformly express transgene(s). Both algal and higher plant chloroplast transformation has been demonstrated, and with the ability to be propagated either in bioreactors or in the field, both systems are well suited for scale up of production. The manipulation of chloroplast genes is also essential for many approaches that attempt to increase biomass accumulation or re-routing metabolic pathways for biofortification, food and fuel production. This includes metabolic engineering for lipid production, adapting the light harvesting apparatus to improve solar conversion efficiencies and engineering means of suppressing photorespiration in crop species, which range from the introduction of artificial carbon concentrating mechanisms, or those pre-existing elsewhere in nature, to bypassing ribulose bisphosphate carboxylase/oxygenase entirely. The purpose of this eBook is to provide a compilation of the latest research on various aspects of plastid biology including basic biology, biopharming, metabolic engineering, bio-fortification, stress physiology, and biofuel production.Ahmad, NiazBurgess, Steven J.Nielsen, Brent L.ORIGINALADVANCES IN PLASTID BIOLOGY.PDFADVANCES IN PLASTID BIOLOGY.PDFVer documentoapplication/pdf48828842https://expeditiorepositorio.utadeo.edu.co/bitstream/20.500.12010/14205/1/ADVANCES%20IN%20PLASTID%20BIOLOGY.PDF3591eb7540dab9023252948d72bfbc02MD51open accessLICENSElicense.txtlicense.txttext/plain; charset=utf-82938https://expeditiorepositorio.utadeo.edu.co/bitstream/20.500.12010/14205/2/license.txtabceeb1c943c50d3343516f9dbfc110fMD52open accessTHUMBNAILADVANCES IN PLASTID BIOLOGY.PDF.jpgADVANCES IN PLASTID BIOLOGY.PDF.jpgIM Thumbnailimage/jpeg26219https://expeditiorepositorio.utadeo.edu.co/bitstream/20.500.12010/14205/3/ADVANCES%20IN%20PLASTID%20BIOLOGY.PDF.jpg9e80b32e5ab652e65a6115554d54acfaMD53open access20.500.12010/14205oai:expeditiorepositorio.utadeo.edu.co:20.500.12010/142052020-10-05 13:40:36.429open accessRepositorio Institucional - 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Advances in Plastid Biology and Its Applications

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