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Chloroplast Related Antibodies Plant Chloroplast Related Antibodies Photosynthetic Electron Transport Calvin Cycle Antenna Proteins Cytochrome b6 / F complex F-type ATPase Photosystem I Photosystem II Gene Transcription System Molecular Chaperone Protein Synthesis TIC/TOC Other Chloroplast Protein Antibodies PhytoAB Inc. Photosynthetic Electron Transport Chloroplast Electron transport process occurs in the thylakoid membranes of chloroplasts during photosynthesis. Related Antibodies Both Photosystems I and II are utilized to split water to get electrons. Electron transport helps establish a proton gradient that powers ATP production and also stores energy in the reduced coenzyme NADPH. This energy is used to power the Calvin Cycle to produce sugar and other carbohydrates. Chloroplast is a type of organelle known as a plastid, characterized by its high concentration of chlorophyll. Other plastid types, such as the leucoplast and the Product Number Abbreviation Reference Sequence Code Size chromoplast, contain little chlorophyll and do not carry out photosynthesis. PHY0099S PC Antibody AT1G20340 150 ug PHY0355S FD1 Antibody AT1G10960 150 ug All chloroplasts have at least three membrane systems—the outer chloroplast PHY0617S FD1 Antibody AT1G10960 150 ug membrane, the inner chloroplast membrane and the thylakoid system. Chloroplasts PHY0360 FNR2 Antibody AT1G20020 150 ug that are the product of secondary endosymbiosis may have additional membranes PHY0611 FNR2 Antibody AT1G20020 150 ug surrounding these three. Inside the outer and inner chloroplast membranes is the chloroplast stroma, a semi-gel-like fluid that makes up much of a chloroplast's volume, and in which the thylakoid system floats. The main role of chloroplasts is to conduct photosynthesis, where the photosynthetic pigment chlorophyll captures the energy from sunlight and converts it and stores it in the energy-storage molecules ATP and NADPH while freeing oxygen from water. WB FNR2 / PHY0360 They then use the ATP and NADPH to make organic molecules from carbon dioxide in a process known as the Calvin cycle. Chloroplasts carry out a number of other functions, including fatty acid synthesis, much amino acid synthesis, and the immune response in plants. 1 PhytoAB Inc. PhytoAB Inc. Photosynthetic Electron Transport Chloroplast Electron transport process occurs in the thylakoid membranes of chloroplasts during photosynthesis. Related Antibodies Both Photosystems I and II are utilized to split water to get electrons. Electron transport helps establish a proton gradient that powers ATP production and also stores energy in the reduced coenzyme NADPH. This energy is used to power the Calvin Cycle to produce sugar and other carbohydrates. Chloroplast is a type of organelle known as a plastid, characterized by its high concentration of chlorophyll. Other plastid types, such as the leucoplast and the Product Number Abbreviation Reference Sequence Code Size chromoplast, contain little chlorophyll and do not carry out photosynthesis. PHY0099S PC Antibody AT1G20340 150 ug PHY0355S FD1 Antibody AT1G10960 150 ug All chloroplasts have at least three membrane systems—the outer chloroplast PHY0617S FD1 Antibody AT1G10960 150 ug membrane, the inner chloroplast membrane and the thylakoid system. Chloroplasts PHY0360 FNR2 Antibody AT1G20020 150 ug that are the product of secondary endosymbiosis may have additional membranes PHY0611 FNR2 Antibody AT1G20020 150 ug surrounding these three. Inside the outer and inner chloroplast membranes is the chloroplast stroma, a semi-gel-like fluid that makes up much of a chloroplast's volume, and in which the thylakoid system floats. The main role of chloroplasts is to conduct photosynthesis, where the photosynthetic pigment chlorophyll captures the energy from sunlight and converts it and stores it in the energy-storage molecules ATP and NADPH while freeing oxygen from water. WB FNR2 / PHY0360 They then use the ATP and NADPH to make organic molecules from carbon dioxide in a process known as the Calvin cycle. Chloroplasts carry out a number of other functions, including fatty acid synthesis, much amino acid synthesis, and the immune response in plants. 1 PhytoAB Inc. PhytoAB Inc. Chloroplast Related Antibodies Calvin Cycle Antenna Proteins The chlorophyll-binding subunits of photosystems I and II are The Calvin Cycle takes place in the stroma of chloroplasts and uses the energy stored by the light- dependent reactions to form glucose and other carbohydrate molecules using a series of enzymes. internal antenna light-harvesting proteins of oxygenic photosynthesis. The antenna proteins that exist in phycobilisomes in cyanobacteria and light-harvesting chlorophyll protein Product Number Abbreviation Reference Sequence Code Size complexes in green plants act as peripheral antenna systems, enabling more efficient absorption of light energy. PHY0400S RCA Antibody AT2G39730 150 ug WB Lhcb2 / PHY0086S PHY0401S RMT Antibody AT1G14030 150 ug Product Number Abbreviation Reference Sequence Code Size PHY0402S RPI3 Antibody AT3G04790 150 ug PHY0403S FBP Antibody AT3G54050 150 ug PHY0042S LHCA Antibody 150 ug PHY0404S RPE Antibody AT5G61410 150 ug PHY0043S Lhca1 Antibody AT3G54890 150 ug PHY0405S PGK1 Antibody AT3G12780 150 ug PHY0043A Lhca1 Antibody AT3G54890 150 ug PHY0406S FBA1 / 2 Antibody AT4G38970 / AT2G21330 150 ug PHY0044A Lhcb4 Antibody AT5G01530 150 ug PHY0407S TKL-1 Antibody AT3G60750 150 ug PHY0082S Lhca2 Antibody AT3G61470 150 ug PHY0408S GAPA1 Antibody AT3G26650 150 ug PHY0083S Lhca3 Antibody AT1G61520 150 ug PHY0409S TPI Antibody AT2G21170 150 ug PHY0084S Lhca4 Antibody AT3G47470 150 ug PHY0410S SBPase Antibody AT3G55800 150 ug PHY0085S Major Lhcb / Lhcb1;2;3 Antibody AT1G29910/AT2G05100/AT5G54270 150 ug PHY0086S Lhcb2 Antibody AT2G05100 150 ug PHY0087S Lhcb3 Antibody AT5G54270 150 ug PHY0088S Lhcb5 Antibody AT4G10340 150 ug PHY0089S Lhcb6 Antibody AT1G15820 150 ug PHY0116S Lhca5 Antibody AT1G45474 150 ug PHY0487S Lhcb1 Antibody AT1G29910 150 ug PHY0666S Lhca4 Antibody AT3G47470 150 ug PHY0667S Lhcb5 Antibody AT4G10340 150 ug WB RPI3 / PHY0402S WB PGK1 / PHY0405S WB SBPase / PHY0410S PHY0671S Lhcb6 Antibody AT1G15820 150 ug PHY0471S Lhcb7 Antibody AT1G76570 150 ug PHY0670S Lhca6 Antibody AT1G19150 150 ug 2 3 PhytoAB Inc. PhytoAB Inc. Chloroplast Related Antibodies Calvin Cycle Antenna Proteins The chlorophyll-binding subunits of photosystems I and II are The Calvin Cycle takes place in the stroma of chloroplasts and uses the energy stored by the light- dependent reactions to form glucose and other carbohydrate molecules using a series of enzymes. internal antenna light-harvesting proteins of oxygenic photosynthesis. The antenna proteins that exist in phycobilisomes in cyanobacteria and light-harvesting chlorophyll protein Product Number Abbreviation Reference Sequence Code Size complexes in green plants act as peripheral antenna systems, enabling more efficient absorption of light energy. PHY0400S RCA Antibody AT2G39730 150 ug WB Lhcb2 / PHY0086S PHY0401S RMT Antibody AT1G14030 150 ug Product Number Abbreviation Reference Sequence Code Size PHY0402S RPI3 Antibody AT3G04790 150 ug PHY0403S FBP Antibody AT3G54050 150 ug PHY0042S LHCA Antibody 150 ug PHY0404S RPE Antibody AT5G61410 150 ug PHY0043S Lhca1 Antibody AT3G54890 150 ug PHY0405S PGK1 Antibody AT3G12780 150 ug PHY0043A Lhca1 Antibody AT3G54890 150 ug PHY0406S FBA1 / 2 Antibody AT4G38970 / AT2G21330 150 ug PHY0044A Lhcb4 Antibody AT5G01530 150 ug PHY0407S TKL-1 Antibody AT3G60750 150 ug PHY0082S Lhca2 Antibody AT3G61470 150 ug PHY0408S GAPA1 Antibody AT3G26650 150 ug PHY0083S Lhca3 Antibody AT1G61520 150 ug PHY0409S TPI Antibody AT2G21170 150 ug PHY0084S Lhca4 Antibody AT3G47470 150 ug PHY0410S SBPase Antibody AT3G55800 150 ug PHY0085S Major Lhcb / Lhcb1;2;3 Antibody AT1G29910/AT2G05100/AT5G54270 150 ug PHY0086S Lhcb2 Antibody AT2G05100 150 ug PHY0087S Lhcb3 Antibody AT5G54270 150 ug PHY0088S Lhcb5 Antibody AT4G10340 150 ug PHY0089S Lhcb6 Antibody AT1G15820 150 ug PHY0116S Lhca5 Antibody AT1G45474 150 ug PHY0487S Lhcb1 Antibody AT1G29910 150 ug PHY0666S Lhca4 Antibody AT3G47470 150 ug PHY0667S Lhcb5 Antibody AT4G10340 150 ug WB RPI3 / PHY0402S WB PGK1 / PHY0405S WB SBPase / PHY0410S PHY0671S Lhcb6 Antibody AT1G15820 150 ug PHY0471S Lhcb7 Antibody AT1G76570 150 ug PHY0670S Lhca6 Antibody AT1G19150 150 ug 2 3 PhytoAB Inc. PhytoAB Inc. Chloroplast Related Antibodies Cytochrome b6 / F complex F-type ATPase The cytochrome b6f complex is an enzyme found in the thylakoid F-type ATPase, also known as ATP synthase, is the universal membrane in chloroplasts of plants, cyanobacteria, and green enzyme that synthesizes ATP from ADP and phosphate using algae, that catalyze the transfer of electrons from plastoquinol to the energy stored in a transmembrane ion gradient. F-type ATPases have two components, CF1- the catalytic core and plastocyanin. CF0 - the membrane proton channel. The cytochrome b6f complex is a dimer, with each monomer composed of eight subunits. Recently, our company has developed the following ATP synthase antibodies: WB AtpC / PHY0161 In photosynthesis, the cytochrome b6f complex functions to mediate the transfer of electrons between the two photosynthetic reaction center complexes, from Photosystem II to Photosystem I, Product Number Abbreviation Reference Sequence Code Size while transferring protons from the chloroplast stroma across the thylakoid membrane into the lumen. WB PetA / PHY0023 PHY0315 AtpE Antibody ATCG00470 150ug PHY0316 AtpF Antibody ATCG00130 150ug PHY0357 AtpI Antibody ATCG00150 150ug Product Number
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