Structural biology has been used for many years. In particular, in 1953, it enabled the determination of the structure of DNA using X-ray diffraction. And more recently, the resolution of the structure of the Spike protein of the SARS-CoV2 virus allowed researchers to better understand the fusion mechanism of the virus and to study the interactions brought into play by neutralizing antibodies during infection or vaccination.<\/span><\/p>\n<\/div>\n<\/div>\n<\/div>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n This constantly evolving field now allows us to solve more and more precise structures, to study larger and larger molecular complexes and to study processes that occur in less than a tenth of a trillionth of a second. Computational models, complementary to structure resolution methods, allow the design of new proteins not found in nature. These new proteins with useful functions may lead to potentially life-saving drugs.<\/p>\n<\/blockquote>\n<\/div>\n<\/div>\n<\/div>\n [\/et_pb_text][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n The information gathered from structural biology finds applications in medicine, biotechnology and agriculture.<\/span><\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ module_id=”introduction” _builder_version=”4.27.4″ _module_preset=”default” background_color=”#EEEFF3″ global_colors_info=”{}”][et_pb_row _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” header_font=”PT Serif|700|||||||” header_text_color=”#4D1749″ header_2_font=”PT Serif|700|||||||” header_2_font_size=”30px” border_color_bottom=”#EEEFF3″ global_colors_info=”{}”]<\/p>\n [\/et_pb_text][et_pb_divider color=”#D2C6D2″ divider_position=”center” _builder_version=”4.16″ _module_preset=”default” custom_margin=”0px||0px||true|false” global_colors_info=”{}”][\/et_pb_divider][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_2,1_2″ _builder_version=”4.16″ _module_preset=”default” custom_margin=”25px||25px||true|false” custom_padding=”||||false|false” global_colors_info=”{}”][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n Structural biology analysis are performed using imaging techniques such as cryo-electron microscopy (cryo-EM), X-ray crystallography, nuclear magnetic resonance (NMR) spectroscopy and small angle X-ray scattering, as well as computer modelling, to determine the 3D structure of biological macromolecules at the atomic level. These techniques allow the observation of isolated molecules but also of larger structures such as molecular complexes (notably the association of proteins and\/or nucleic acids forming a functional unit), viruses and organelles. [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n Progression in structural biology comprises the merging of all imaging techniques, enabling to create a more precise and clearer map of macromolecules\u2019 shape and how they interact with others.<\/span><\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ module_id=”introduction” _builder_version=”4.27.4″ _module_preset=”default” background_color=”#FFFFFF” global_colors_info=”{}”][et_pb_row _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” header_font=”PT Serif|700|||||||” header_text_color=”#4D1749″ header_2_font=”PT Serif|700|||||||” header_2_font_size=”30px” border_color_bottom=”#EEEFF3″ global_colors_info=”{}”]<\/p>\n [\/et_pb_text][et_pb_divider color=”#D2C6D2″ divider_position=”center” _builder_version=”4.16″ _module_preset=”default” custom_margin=”0px||0px||true|false” global_colors_info=”{}”][\/et_pb_divider][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_2,1_2″ _builder_version=”4.16″ _module_preset=”default” custom_margin=”25px||25px||true|false” custom_padding=”||||false|false” global_colors_info=”{}”][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n The global structural biology market is expanding rapidly worldwide<\/strong><\/span> (Figure 1), as structural biology plays a central role in understanding the special arrangement and the complex folding of proteins, nucleic acids, carbohydrates and lipid membranes. The drug discovery segment is expected to capture the maximum market share.<\/span><\/p>\n<\/div>\n<\/div>\n<\/div>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][\/et_pb_column][\/et_pb_row][et_pb_row _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_divider color=”#D2C6D2″ divider_position=”center” _builder_version=”4.16″ _module_preset=”default” custom_margin=”0px||0px||true|false” global_colors_info=”{}”][\/et_pb_divider][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n Figure 1 \u2013 Evolution of the structural biology market size from 2023 to 2034.<\/strong><\/em><\/span><\/p>\n [\/et_pb_text][et_pb_image src=”http:\/\/synthelis.com\/wp-content\/uploads\/2025\/04\/Biologie-Structurale-Figure1.webp” alt=”Figure 1 \u2013 \u00c9volution de la taille du march\u00e9 de la biologie structurale de 2023 \u00e0 2034 – Synthelis Biotech” title_text=”Biologie Structurale – Figure1″ _builder_version=”4.27.4″ _module_preset=”default” hover_enabled=”0″ global_colors_info=”{}” sticky_enabled=”0″][\/et_pb_image][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_2,1_2″ _builder_version=”4.16″ _module_preset=”default” custom_margin=”25px||25px||true|false” custom_padding=”||||false|false” global_colors_info=”{}”][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n One of the major difficulties in structural biology is protein structure prediction or modelling. Computational approaches, in parallel with experimental structure determination techniques, have been developed to predict the 3D structure of macromolecules, their dynamics and interactions. Two main strategies have been employed to achieve this, namely template-based and neural network (deep learning)-based approaches [1,2]. In order to understand how macromolecules work in a native complex environment and generate an integrated multiscale whole-cell model, an integrative structural biology approach will be required, congregating improvements and expansion of structural training sets for enhanced modelling, and the integration of diverse data from complementary fields like proteomics (Figure 2).<\/span><\/p>\n<\/div>\n<\/div>\n<\/div>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n Another growing trend in structural biology is the study of 4D structures of complex entities<\/strong><\/span> (enzymes and other spatially and temporally heterogeneous structural ensembles) throughout a functional cycle, in which the fourth dimension is time [1,2]. This will require new techniques and methodologies aimed at capturing and analysing the dynamic aspects of biomolecular structures when they respond to different environmental conditions or during biological processes.<\/span><\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_divider color=”#D2C6D2″ divider_position=”center” _builder_version=”4.16″ _module_preset=”default” custom_margin=”0px||0px||true|false” global_colors_info=”{}”][\/et_pb_divider][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n Figure 2 \u2013 Integrated structural biology \u2013 the interplay between various technologies. Reproduced from [2].<\/strong><\/em><\/span><\/p>\n [\/et_pb_text][et_pb_image src=”http:\/\/synthelis.com\/wp-content\/uploads\/2025\/02\/Biologie-Structurale-Figure2-EN.webp” alt=”Figure 2 \u2013 Integrated structural biology \u2013 the interplay between various technologies.” title_text=”Biologie Structurale – Figure2-EN” _builder_version=”4.27.4″ _module_preset=”default” global_colors_info=”{}”][\/et_pb_image][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ module_id=”introduction” _builder_version=”4.27.4″ _module_preset=”default” background_color=”#D2C6D2″ global_colors_info=”{}”][et_pb_row _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” header_font=”PT Serif|700|||||||” header_text_color=”#4D1749″ header_2_font=”PT Serif|700|||||||” header_2_font_size=”30px” border_color_bottom=”#EEEFF3″ global_colors_info=”{}”]<\/p>\n [\/et_pb_text][et_pb_divider color=”#D2C6D2″ divider_position=”center” _builder_version=”4.16″ _module_preset=”default” custom_margin=”0px||0px||true|false” global_colors_info=”{}”][\/et_pb_divider][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_2,1_2″ _builder_version=”4.16″ _module_preset=”default” custom_margin=”25px||25px||true|false” custom_padding=”||||false|false” global_colors_info=”{}”][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n Cell-free protein synthesis (CFPS)<\/strong><\/span> using\u00a0Escherichia coli\u00a0cell extracts has successfully been applied to protein sample preparation for structure determination by X-ray crystallization and NMR spectroscopy. Milligram quantities of proteins can be synthesized by the dialysis mode of the cell-free reaction in several hours, and a great variety of proteins can be produced including mammalian proteins, heteromultimeric protein complexes, and integral membrane proteins, with advantages over the recombinant protein expression methods with bacterial and eukaryotic host cells.<\/span><\/p>\n Cell-free synthesis enables to surpass one of the limitations in structural analysis of proteins, namely the production of high-yield and high-purity target proteins.<\/strong><\/span> A multiscale eukaryotic wheat germ cell-free protein expression pipeline was developed to generate functional proteins of different sizes from multiple host organism and DNA source origins [3]. The system was able to produce highly pure (> 98%) proteins compatible with all three major protein sample formats used for structural biology including single particle analysis with electron microscopy, and both two-dimensional and three-dimensional protein crystallography. Furthermore, by using an eukaryotic ribosome, the cell-free system would enable the synthesis of complex eukaryotic proteins including, for example, protein complexes and membrane proteins [4].<\/span><\/p>\n<\/div>\n<\/div>\n<\/div>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#4D1749″ text_font_size=”1.4em” text_line_height=”1.4em” global_colors_info=”{}”]<\/p>\n In\u001ecell protein crystallization is a technique that has been advantageously employed in structural biology studies since it does not require protein purification and a complicated crystallization process. Nonetheless, only a few protein structures have been determined so far since the crystals are incidentally formed in living cells and are insufficient in size and quality for structure analysis.<\/span><\/p>\n Recently, application of CFPS to in-cell protein crystallization was reported for the synthesis of the polyhedra crystal, one of the most highly studied in-cell protein crystals [5]. The so-called cell\u001efree protein crystallization (CFPC) method involved direct protein crystallization using a cell\u001efree system and was able to perform crystallization and structure determination of nano\u001esized polyhedra crystal at high resolution. The CFPC focused on: <\/span> [\/et_pb_text][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ _builder_version=”4.27.4″ _module_preset=”default” background_color=”#FFFFFF” global_colors_info=”{}”][et_pb_row _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” header_font=”PT Serif|700|||||||” header_text_color=”#4D1749″ header_3_font=”PT Serif|700|||||||” header_3_font_size=”30px” border_color_bottom=”#EEEFF3″ global_colors_info=”{}”]<\/p>\n [\/et_pb_text][et_pb_divider color=”#D2C6D2″ divider_position=”center” _builder_version=”4.16″ _module_preset=”default” custom_margin=”0px||0px||true|false” global_colors_info=”{}”][\/et_pb_divider][\/et_pb_column][\/et_pb_row][et_pb_row make_equal=”on” _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][dnxte_feature_list_parent dnxte_feature_list_item_margin=”||20px||false|false” dnxte_feature_list_item_padding=”||10px||false|false” _builder_version=”4.27.4″ _module_preset=”default” custom_margin=”||||false|false” custom_padding=”||||false|false” border_color_bottom=”#D2C6D2″ global_colors_info=”{}”][dnxte_feature_list_child dnxte_feature_list_title=”Carugo O., Djinovi\u0107-Carugo K. 2023. Structural biology: a golden era. PLoS Biol. 21, e3002187.” dnxte_feature_list_icon=”h||divi||400″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif|700|||||||” module_text_color=”#4D1749″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.1371\/journal.pbio.3002187″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][dnxte_feature_list_child dnxte_feature_list_title=”Schwalbe H., Audergon P., Haley N., Amaro C.A., Agirre J., Baldus M., Banci L., Baumeister W., Blackledge M., Carazo J.M., Carugo K.D., Celie P., Felli I., Hart D.J., Hau\u00df T., Lehtio L., Lindorff-Larsen K., M\u00e1rquez J., Matagne A., Pierattelli R., Rosato A., Sobott F., Sreeramulu S., Steyaert J., Sussman J.L., Trantirek L., Weiss M.S., Wilmanns M. 2024. The future of integrated structural biology. Structure 32, 1563-1580.” dnxte_feature_list_icon=”h||divi||400″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif|700|||||||” module_text_color=”#4D1749″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.1016\/j.str.2024.08.014″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][dnxte_feature_list_child dnxte_feature_list_title=”Novikova I.V., Sharma N., Moser T., Sontag R., Liu Y., Collazo M.J., Cascio D., Shokuhfar T., Hellmann H., Knoblauch M., Evans J.E. 2018. Protein structural biology using cell-free platform from wheat germ. Adv. Struct. Chem. Imaging 4, 13.” dnxte_feature_list_icon=”h||divi||400″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif|700|||||||” module_text_color=”#4D1749″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.1186\/s40679-018-0062-9″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][dnxte_feature_list_child dnxte_feature_list_title=”Abe S., Tanaka J., Kojima M., Kanamaru S., Hirata K., Yamashita K., Kobayashi A., Ueno T. 2022. Cell\u2011free protein crystallization for nanocrystal structure determination. Sci. Rep. 12, 16031.” dnxte_feature_list_icon=”h||divi||400″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif|700|||||||” module_text_color=”#4D1749″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.1038\/s41598-022-19681-9″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][\/dnxte_feature_list_parent][\/et_pb_column][\/et_pb_row][et_pb_row _builder_version=”4.27.4″ _module_preset=”default” custom_padding=”||0px||false|false” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.27.4″ _module_preset=”default” header_font=”PT Serif|700|||||||” header_text_color=”#4D1749″ header_3_font=”PT Serif|700|||||||” header_3_font_size=”30px” header_4_font=”PT Serif|700|||||||” header_4_font_size=”22px” border_color_bottom=”#EEEFF3″ global_colors_info=”{}”]<\/p>\n [\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row make_equal=”on” _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][dnxte_feature_list_parent dnxte_feature_list_item_margin=”||20px||false|false” dnxte_feature_list_item_padding=”||10px||false|false” _builder_version=”4.27.4″ _module_preset=”default” custom_margin=”||||false|false” custom_padding=”||||false|false” border_color_bottom=”#D2C6D2″ global_colors_info=”{}”][dnxte_feature_list_child dnxte_feature_list_title=”Carugo O., Djinovi\u0107-Carugo K. 2023. Structural biology: a golden era. PLoS Biol. 21, e3002187.” dnxte_feature_list_use_number=”on” dnxte_feature_list_number=”%911%93″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif||||||||” module_text_color=”#000000″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.1371\/journal.pbio.3002187″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][dnxte_feature_list_child dnxte_feature_list_title=”Schwalbe H., Audergon P., Haley N., Amaro C.A., Agirre J., Baldus M., Banci L., Baumeister W., Blackledge M., Carazo J.M., Carugo K.D., Celie P., Felli I., Hart D.J., Hau\u00df T., Lehtio L., Lindorff-Larsen K., M\u00e1rquez J., Matagne A., Pierattelli R., Rosato A., Sobott F., Sreeramulu S., Steyaert J., Sussman J.L., Trantirek L., Weiss M.S., Wilmanns M. 2024. The future of integrated structural biology. Structure 32, 1563-1580.” dnxte_feature_list_use_number=”on” dnxte_feature_list_number=”%912%93″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif||||||||” module_text_color=”#000000″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.1016\/j.str.2024.08.014″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][dnxte_feature_list_child dnxte_feature_list_title=”Novikova I.V., Sharma N., Moser T., Sontag R., Liu Y., Collazo M.J., Cascio D., Shokuhfar T., Hellmann H., Knoblauch M., Evans J.E. 2018. Protein structural biology using cell-free platform from wheat germ. Adv. Struct. Chem. Imaging 4, 13.” dnxte_feature_list_use_number=”on” dnxte_feature_list_number=”%913%93″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif||||||||” module_text_color=”#000000″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.1186\/s40679-018-0062-9″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][dnxte_feature_list_child dnxte_feature_list_title=”Fogeron M., Lecoq L., Cole L., Harbers M., B\u00f6ckmann A. 2021. Easy synthesis of complex biomolecular assemblies: wheat germ cell-free protein expression in structural biology. Front. Mol. Biosci. 8:639587.” dnxte_feature_list_use_number=”on” dnxte_feature_list_number=”%914%93″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif||||||||” module_text_color=”#000000″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.3389\/fmolb.2021.639587″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][dnxte_feature_list_child dnxte_feature_list_title=”Abe S., Tanaka J., Kojima M., Kanamaru S., Hirata K., Yamashita K., Kobayashi A., Ueno T. 2022. Cell\u2011free protein crystallization for nanocrystal structure determination. Sci. Rep. 12, 16031.” dnxte_feature_list_use_number=”on” dnxte_feature_list_number=”%915%93″ dnxte_feature_list_icon_color=”#4D1749″ _builder_version=”4.27.4″ _module_preset=”default” module_font=”PT Serif||||||||” module_text_color=”#000000″ module_font_size=”15px” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/doi.org\/10.1038\/s41598-022-19681-9″ link_option_url_new_window=”on” border_width_bottom=”1px” border_color_bottom=”#D2C6D2″ global_colors_info=”{}” module_text_color__hover_enabled=”on|hover” module_text_color__hover=”#72486E”][\/dnxte_feature_list_child][\/dnxte_feature_list_parent][\/et_pb_column][\/et_pb_row][\/et_pb_section][et_pb_section fb_built=”1″ _builder_version=”4.27.4″ _module_preset=”default” background_color=”#EDE8EC” global_colors_info=”{}”][et_pb_row _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”4_4″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_text _builder_version=”4.16″ _module_preset=”default” header_font=”PT Serif|700|||||||” header_text_color=”#4D1749″ header_2_font=”PT Serif|700|||||||” header_2_font_size=”30px” border_color_bottom=”#EEEFF3″ global_colors_info=”{}”]<\/p>\n [\/et_pb_text][et_pb_divider color=”#D2C6D2″ divider_position=”center” _builder_version=”4.16″ _module_preset=”default” custom_margin=”0px||0px||true|false” global_colors_info=”{}”][\/et_pb_divider][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=”1_2,1_2″ make_equal=”on” _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][dnxte_blurb blurb_pre_switch=”on” blurb_pre_heading=”Nature” pre_heading_tag=”p” blurb_heading=”Structures and distribution of SARS-CoV-2 spike proteins on intact virions” heading_tag=”h3″ dnxt_image=”http:\/\/synthelis.com\/wp-content\/uploads\/2022\/03\/Nature-Magazine.jpg” dnxt_content_max_width=”90%” dnxt_pre_margin=”-30px||10px||false|false” dnxt_pre_padding=”20px|25px||25px|false|true” dnxt_header_padding=”|25px|30px|25px|false|true” dnxt_post_margin=”||||false|false” dnxt_post_padding=”||||false|false” dnxt_body_margin=”|||51px|false|false” dnxt_content_margin=”||||false|false” heading_bg_show_hide=”on” heading_bg=”#f4f4f4″ btn_icon=”5||divi||400″ btn_icon_color=”#FFFFFF” blurb_hover_switch=”on” dnxt_hover_effect=”dnxt-hover-wobble-to-bottom-right” _builder_version=”4.16″ _module_preset=”default” dnxt_pre_header_font=”|700|||||||” dnxt_heading_text_color=”#4D1749″ dnxt_heading_font_size=”30px” dnxt_btn_text_font=”PT Serif||||||||” dnxt_btn_text_text_color=”#FFFFFF” background_color=”RGBA(255,255,255,0)” custom_margin=”||||false|false” custom_padding=”||||false|false” link_option_url=”https:\/\/www.nature.com\/articles\/s41586-020-2665-2#Abs1″ link_option_url_new_window=”on” border_width_all_dnxt_button_borders=”0px” box_shadow_style_dnxt_description_boxshadow=”preset3″ box_shadow_style_dnxt_button_boxshadow=”preset3″ global_colors_info=”{}”][\/dnxte_blurb][\/et_pb_column][et_pb_column type=”1_2″ _builder_version=”4.16″ _module_preset=”default” global_colors_info=”{}”][dnxte_blurb blurb_pre_switch=”on” blurb_pre_heading=”Alzheimer’s association – Richard C. 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Greig” pre_heading_tag=”p” blurb_heading=”Drug discovery and development: Role of basic biological research” heading_tag=”h3″ dnxt_image=”http:\/\/synthelis.com\/wp-content\/uploads\/2022\/03\/Alzheimer-Association.jpg” dnxt_content_max_width=”90%” dnxt_pre_margin=”-30px||10px||false|false” dnxt_pre_padding=”20px|25px||25px|false|true” dnxt_header_padding=”|25px|30px|25px|false|true” dnxt_post_margin=”||||false|false” dnxt_post_padding=”||||false|false” dnxt_body_margin=”|||51px|false|false” dnxt_content_margin=”||||false|false” heading_bg_show_hide=”on” heading_bg=”#f4f4f4″ btn_icon=”5||divi||400″ btn_icon_color=”#FFFFFF” blurb_hover_switch=”on” dnxt_hover_effect=”dnxt-hover-wobble-to-bottom-right” _builder_version=”4.16″ _module_preset=”default” dnxt_pre_header_font=”|700|||||||” dnxt_heading_text_color=”#4D1749″ dnxt_heading_font_size=”30px” dnxt_btn_text_font=”PT Serif||||||||” dnxt_btn_text_text_color=”#FFFFFF” background_color=”RGBA(255,255,255,0)” custom_margin=”||||false|false” 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text_font_size_last_edited=”on|phone” global_colors_info=”{}”]<\/p>\n Even [\/et_pb_text][et_pb_divider show_divider=”off” _builder_version=”4.16″ _module_preset=”default” width=”100%” height=”50px” global_colors_info=”{}”][\/et_pb_divider][et_pb_text _builder_version=”4.16″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#FFFFFF” text_font_size=”16px” background_layout=”dark” custom_margin=”0px||||false|false” global_colors_info=”{}”]<\/p>\n Cell-Free Systems Applications<\/p>\n [\/et_pb_text][\/et_pb_column][et_pb_column type=”1_3″ _builder_version=”4.16″ _module_preset=”default” background_image=”http:\/\/synthelis.com\/wp-content\/uploads\/2022\/01\/Synthelis-MemeUneProteineABesoindExprimerSonPotentiel-Part2.jpg” global_colors_info=”{}”][et_pb_text _builder_version=”4.16″ _module_preset=”default” text_font=”PT Serif||||||||” text_text_color=”#FFFFFF” text_font_size=”16px” background_layout=”dark” min_height=”50vh” min_height_tablet=”50vh” min_height_phone=”50vh” min_height_last_edited=”on|phone” custom_margin=”0px||||false|false” global_colors_info=”{}”][\/et_pb_text][\/et_pb_column][\/et_pb_row][\/et_pb_section]<\/p>\n","protected":false},"excerpt":{"rendered":" The futurof structuralbiologyis bio.Cell-Free fields of applicationThe functions of macromolecules within the cells are intimately associated and depend on their tridimensional structure (tertiary structure) which, in turn, depends on their basic composition (primary structure). Structural biology relates to the study of the structure of molecules and macromolecules, how they fold, and how structural modifications and […]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_et_pb_use_builder":"on","_et_pb_old_content":"","_et_gb_content_width":"","_surecart_dashboard_logo_width":"180px","_surecart_dashboard_show_logo":true,"_surecart_dashboard_navigation_orders":true,"_surecart_dashboard_navigation_invoices":true,"_surecart_dashboard_navigation_subscriptions":true,"_surecart_dashboard_navigation_downloads":true,"_surecart_dashboard_navigation_billing":true,"_surecart_dashboard_navigation_account":true,"footnotes":""},"folder":[52],"class_list":["post-4531","page","type-page","status-publish","hentry"],"yoast_head":"\n\n
How it works?<\/h2>\n
<\/span><\/p>\n<\/div>\n<\/div>\n<\/div>\nTrends and challenges<\/h2>\n
Syst\u00e8mes acellulaires et biologie structurale<\/h2>\n
. establishing crystallization of proteins<\/strong><\/span> using CFPS with small scale and rapid reactions and<\/span>
. manipulating the crystallization by adding chemical reagents.<\/strong><\/span> The advantage of using CFPC is that various reagents can be added to the reaction mixture without preventing protein synthesis. Thus, CFPC opens up the possibility of crystallizing unstable proteins and rapidly determining their structures.<\/span><\/p>\nPublications<\/h3>\n
References<\/h4>\n
To know more<\/h2>\n
forward to
your questions<\/p>\n
a protein
needs
to express
its potential.<\/p>\n