New research study reveals the atomic tricks of photosynthesis, providing insights into the complex process of chloroplast RNA polymerase transcription. This advancement holds pledge for improving crop durability and understanding plant development mechanisms. Credit: SciTechDaily.comThe secrets of photosynthesis have been revealed at the atomic level, offering substantial new insights into this plant super-power that changed the Earth into a green landscape over a billion years ago.John Innes Centre researchers used an innovative microscopy method called cryo-EM to explore how the photosynthetic proteins are made.The research study, published in Cell, provides a design and resources to promote additional fundamental discoveries in this field and help longer-term objectives of establishing more resistant crops.Understanding Photosynthetic Protein ProductionDr Michael Webster, group leader and co-author of the paper said: “Transcription of chloroplast genes is a fundamental step in making the photosynthetic proteins that offer plants with the energy they need to grow. We hope that by understanding this process better– at the comprehensive molecular level– we will equip scientists looking to establish plants with more robust photosynthetic activity.”” The most essential outcome of this work is the production of a useful resource. Researchers can download our atomic design of the chloroplast polymerase and use it to produce their own hypotheses of how it might function and experimental strategies that would check them.” Photosynthesis takes location inside chloroplasts, small compartments within plant cells which contain their own genome, showing their past as free-living photosynthetic bacteria before they were swallowed up and co-opted by plants.Seeing the polymerase particle that transcribes photosynthetic genes in the plant chloroplast. Images of specific molecules collected with an electron microscopic lense were sorted and lined up to reveal information of the structural architecture of the protein complex. Credit: Michael Webster & & Ishika PramanickThe Webster group at the John Innes Centre examines how plants make photosynthetic proteins, the molecular makers that make this stylish chemical reaction take place, converting atmospheric co2 and water into simple sugars and producing oxygen as a byproduct.The first phase in protein production is transcription, where a gene reads to produce a messenger RNA. This transcription process is done by an enzyme called RNA polymerase.The Complexity of Chloroplast RNA PolymeraseIt was found 50 years ago that chloroplasts contain their own distinct RNA polymerase. Since then, scientists have actually been surprised by how complex this enzyme is. It has more subunits than its ancestor, the bacterial RNA polymerase, and is even bigger than human RNA polymerases.The Webster group wished to comprehend why chloroplasts have such a sophisticated RNA polymerase. To do this they required to visualise the structural architecture of the chloroplast RNA polymerase.The research study group utilized a technique called cryogenic electron microscopy (cryo-EM) to image samples of chloroplast RNA polymerase purified from white mustard plants.Insights from Atomic-Level AnalysisBy processing these images, they had the ability to build a design that consists of the positions of more than 50,000 atoms in the molecular complex.The RNA polymerase complex makes up 21 subunits encoded in the two genomes, nuclear and chloroplast. Close analysis of this structure, as it carries out transcription, permitted the researchers to start discussing these elements functions.The model allowed them to recognize a protein that interacts with the DNA as it is being transcribed and guides it to the enzymes active site.Another element can communicate with the mRNA that is being produced that most likely safeguards it from proteins that would deteriorate it before it is translated into protein.Dr Webster stated: “We understand that each part of the chloroplast RNA polymerase has an essential function since plants that do not have any one of them can not make photosynthetic proteins and as a result can not turn green. We are studying the atomic designs thoroughly to identify what the function is for each of the 21 components of the assembly.” Joint initially author Dr Ángel Vergara-Cruces stated: “Now that we have a structural model the next step is to validate the role of the chloroplast transcription proteins. By revealing mechanisms of chloroplast transcription, our research study uses insight into its function in plant growth and adaptation and response to ecological conditions.” Joint initially author Dr. Ishika Pramanick said: “There were many surprising moments in this impressive work journey, starting with the very challenging protein filtration to taking stunning cryo-EM pictures of this big complex protein to finally seeing our operate in a printed version.” Dr Webster concluded: “Heat, dry spell, and salinity restrict a plants capability to perform photosynthesis. Plants that can produce photosynthetic proteins dependably in the face of environmental stress might manage chloroplast transcription in a different way. We anticipate seeing our work used in the essential effort to develop more robust crops.” Reference: “Structure of the plant plastid-encoded RNA polymerase” by Ángel Vergara-Cruces, Ishika Pramanick, David Pearce, Vinod K. Vogirala, Matthew J. Byrne, Jason K.K. Low and Michael W. Webster, 29 February 2024, Cell.DOI: 10.1016/ j.cell.2024.01.036.
Credit: SciTechDaily.comThe secrets of photosynthesis have actually been revealed at the atomic level, providing significant new insights into this plant super-power that changed the Earth into a green landscape over a billion years ago.John Innes Centre researchers used an innovative microscopy method called cryo-EM to check out how the photosynthetic proteins are made.The research study, published in Cell, provides a model and resources to stimulate more fundamental discoveries in this field and assist longer-term goals of developing more durable crops.Understanding Photosynthetic Protein ProductionDr Michael Webster, group leader and co-author of the paper said: “Transcription of chloroplast genes is a basic step in making the photosynthetic proteins that supply plants with the energy they require to grow.” Photosynthesis takes place inside chloroplasts, little compartments within plant cells that contain their own genome, showing their past as free-living photosynthetic bacteria before they were engulfed and co-opted by plants.Seeing the polymerase molecule that transcribes photosynthetic genes in the plant chloroplast. To do this they required to visualise the structural architecture of the chloroplast RNA polymerase.The research study group used a method called cryogenic electron microscopy (cryo-EM) to image samples of chloroplast RNA polymerase cleansed from white mustard plants.Insights from Atomic-Level AnalysisBy processing these images, they were able to build a model that consists of the positions of more than 50,000 atoms in the molecular complex.The RNA polymerase complex comprises 21 subunits encoded in the 2 genomes, nuclear and chloroplast. Close analysis of this structure, as it performs transcription, permitted the researchers to begin discussing these elements functions.The design allowed them to determine a protein that communicates with the DNA as it is being transcribed and guides it to the enzymes active site.Another part can engage with the mRNA that is being produced that most likely safeguards it from proteins that would deteriorate it before it is translated into protein.Dr Webster stated: “We know that each component of the chloroplast RNA polymerase has an essential role since plants that do not have any one of them can not make photosynthetic proteins and subsequently can not turn green.