SENSING AND SEPARATING BIOMOLECULES AT BIOINTERFACES

Jung, Hyunsook

2009 May 1900

Ligand-receptor interactions are ubiquitous on cell membranes. Indeed, many important physiological functions primarily involve such interactions. These include cell signaling, pathogen binding, trafficking of lymphocytes, and the immune response.1-4 Therefore, studying ligand-receptor interactions at appropriate model membrane is of importance for both proper understanding of biological functions and applications to biosensors and bioseparations. Supported lipid bilayers are composed of the same lipid molecules found in the plasma cell membranes of living cells and possess the same two-dimensional fluidity as cell membranes, making them capable of mimicking the cell surface. Moreover, supported lipid bilayer-based in vitro assays are appealing because they require only very small sample volumes and they are suitable for multiplexing and high-throughput screening. Recently, our laboratory has combined supported lipid bilayer-coated microfluidic platforms with total internal reflection fluorescence microscopy to obtain equilibrium dissociation constant data for protein-ligand interactions. Using this method, it was found that equilibrium dissociation constants of antibody-ligand interactions at lipid membrane interfaces can be strongly affected by ligand lipophilicity and linker length/structure. These results are described in Chapter III. Monitoring protein-ligand interactions is routinely performed by fluorescently labeling the proteins of interest. Protein labeling can, however, interfere with detection measurements and be highly inconvenient to employ. To solve these problems, a simple and highly sensitive technique for detection of protein-ligand binding at biointerfaces has been developed. The method is based upon modulation of the interfacial pH when the protein binds. This change is detected by pH-sensitive fluorescent dye molecules embedded into the biointerface. The dye fluoresces strongly in the protonated state but becomes inactive upon deprotonation. These results are demonstrated in Chapter IV. Finally, the study of supported lipid bilayer-based electrophoresis is described in Chapter V. Bilayer electrophoresis is an attractive alternative to gel electrophoresis for the separation of membrane components such as lipids and membrane proteins because it is run in native-like environments and avoids exposing the analytes of interest to harsh chemicals. In this study, lipid rafts of varying size were used as separation matrices to separate two similar lipids with different alkyl chains. Lipid rafts of varying size were formed by a process controlled by varying treatment of the solid substrate. Depending on which method was employed, the results showed that lipid raft size could be modulated over five orders of magnitude. Moreover, it was found that the electrophoretic separation of the two lipid components depended on the size of rafts in the bilayer matrix.

Spatio-Temporal Characterization of Ligand-Receptor Interactions in Haematopoietic Stem Cell Rolling during Homing

Al Alwan, Bader

11 1900

Researches on Hematopoietic Stem Cell (HSC) have been expanding that leads to an increase in our understanding of HSC normal behaviors and abnormal alterations. One of the most important issues in the research on HSCs is to understand the mechanism of the homing process of these cells to settle in their niche in the bone marrow and establish the production of various blood cell types after bone marrow transplantation. The cells first must come in contact with the endothelial cells. This contact is known as adhesion and occurs through a multi-step paradigm ending with transmigration to the bone marrow niche. The initial step of the homing, tethering and rolling of HSC, is mediated by P- and E-Selectins present on endothelial cell surface through their interactions with the ligands expressed on the surface of HSC. Thus, understanding the adhesion process and its contribution for efficient HSCs homing will have great impact on HSC therapy. The selectin – ligands interaction has been intensively studied using in vivo and in vitro approaches. However, the molecular mechanism involved by HSCs at single molecule level is poorly understood. Here in this study, a novel experimental method to unravel the molecular mechanisms of the Selectin-ligands interactions in vitro at the single molecule level is developed by combining microfluidics, epi-fluorescence microscopy and live cells. In this work, the new single-molecule imaging technique enabled us to directly visualize the nanoscale spatiotemporal dynamics of the membrane protein-ligand interactions under conditions of shear stress acting on the cells at the molecular level in real time. Using this method, we revealed that selectin ligands on membrane-tethers and slings show unique spatiotemporal dynamics that is distinct from those on the cell body. We demonstrated that the membrane tethers are formed from single microvilli on the cells, which provides a mechanism to spatially localize selectin ligands, PSGL-1 and CD44 on the tethers and slings. We also demonstrated that the selectin ligands show fast diffusional motion along the tethers and slings compared with that on the cell body due to the detachment of cell membranes from actin cytoskeleton during the formation of the tethers. Our results suggest that the spatial confinement of the selectin ligands together with the fast scanning of a large area by the selectin ligands increase the efficiency of selectin-ligands interaction during the rolling, resulting in slow and stable rolling of the cell on selectin. Our findings contribute significantly to molecular level understanding of the initial step of HSCs. This single-molecule imaging technique that we developed in this study will find wide applications in the molecular-level studies on cell-cell interactions including cancer cell metastasis.

Haematopoietic Stem Cell

Bone marrow transplant

HSC homing

Fluorescence microscopy

Ligand-Receptor

Single-Molecule

Studies of Ligand-Receptor Pairs Utilizing Polymerized Planar Supported Lipid Bilayers

Liang, Boying

January 2013

Artificial membranes composed of natural lipids are not stable when exposed to air/vacuum, surfactant, organic solvent, etc. Polymerizable lipids provide an opportunity to broaden the use of lipid membranes to study ligand-receptor pairs under harsh experimental conditions. This dissertation presents the utilization of polymerizable lipids in matrix assisted laser desorption and ionization-mass spectrometry (MALDI-TOF MS) for analysis of ligands bound to membrane receptors. This platform may be applied to rapid drug-screening for membrane receptors including transmembrane proteins. Bacterial toxins and their membrane receptors were used as model ligand-receptor pairs to demonstrate the feasibility of using polymerizable lipids to detect and identify ligands by MALDI-TOF MS. Cholera toxin B (CTB) was successfully detected bound to polymerized lipid membranes with incorporation of its membrane receptor, GM1, while no CTB was detected in non-polymerizable lipid membranes. This affinity capture platform based on poly(lipid) showed a high resistance to interferences. On-plate digestion of bound CTB was performed and 57% amino acid sequence coverage was achieved. Total internal reflection fluorescence microscopy (TIRF-M) was applied to compare CTB-GM1 binding affinity in polymerized and unpolymerized membranes. Under a static flow system, the binding between CTB and GM1 was found to be stronger in polymerized membranes than other membranes. However, the ligand concentration under a static flow system is not in excess and the apparent binding affinity is likely to be significantly different than the true value. The true binding affinity can be approached under a continuous flow system, however equilibration time was found to be too long to address experimentally. Membrane fluidity, which may be required to maintain the membrane receptor activity, is suppressed in poly(lipid) membranes compared to unpolymerized membranes. In order to maintain fluidity, a non-polymerizable lipid was mixed into a polymerized lipid. Fluorescence recovery after photobleaching (FRAP) data showed that fluidity of membrane composed of the mixed lipid was maintained compared to pure poly(lipid). Phase segregation of polymerized lipid and non-polymerizable lipid was detected by atomic force microscopy (AFM). CTB bound to GM1 in mixed lipid membranes was detected by MALDI-MS, indicating the mixed lipid membranes retain stability under MALDI-MS analysis conditions.

AFM

ligand-receptor

lipid

MALDI MS

TIRF

Chemistry

affinity capture platform

Studies of Ligand-Receptor Pairs Utilizing Polymerized Planar Supported Lipid Bilayers

Liang, Boying

January 2013

Artificial membranes composed of natural lipids are not stable when exposed to air/vacuum, surfactant, organic solvent, etc. Polymerizable lipids provide an opportunity to broaden the use of lipid membranes to study ligand-receptor pairs under harsh experimental conditions. This dissertation presents the utilization of polymerizable lipids in matrix assisted laser desorption and ionization-mass spectrometry (MALDI-TOF MS) for analysis of ligands bound to membrane receptors. This platform may be applied to rapid drug-screening for membrane receptors including transmembrane proteins. Bacterial toxins and their membrane receptors were used as model ligand-receptor pairs to demonstrate the feasibility of using polymerizable lipids to detect and identify ligands by MALDI-TOF MS. Cholera toxin B (CTB) was successfully detected bound to polymerized lipid membranes with incorporation of its membrane receptor, GM1, while no CTB was detected in non-polymerizable lipid membranes. This affinity capture platform based on poly(lipid) showed a high resistance to interferences. On-plate digestion of bound CTB was performed and 57% amino acid sequence coverage was achieved. Total internal reflection fluorescence microscopy (TIRF-M) was applied to compare CTB-GM1 binding affinity in polymerized and unpolymerized membranes. Under a static flow system, the binding between CTB and GM1 was found to be stronger in polymerized membranes than other membranes. However, the ligand concentration under a static flow system is not in excess and the apparent binding affinity is likely to be significantly different than the true value. The true binding affinity can be approached under a continuous flow system, however equilibration time was found to be too long to address experimentally. Membrane fluidity, which may be required to maintain the membrane receptor activity, is suppressed in poly(lipid) membranes compared to unpolymerized membranes. In order to maintain fluidity, a non-polymerizable lipid was mixed into a polymerized lipid. Fluorescence recovery after photobleaching (FRAP) data showed that fluidity of membrane composed of the mixed lipid was maintained compared to pure poly(lipid). Phase segregation of polymerized lipid and non-polymerizable lipid was detected by atomic force microscopy (AFM). CTB bound to GM1 in mixed lipid membranes was detected by MALDI-MS, indicating the mixed lipid membranes retain stability under MALDI-MS analysis conditions.

AFM

ligand-receptor

lipid

MALDI MS

TIRF

Chemistry

affinity capture platform

Nanoscopic Characterization of Selectin-Ligand Interactions During the Initial Step of The Hematopoietic Stem Cell Homing Using Microfluidics-Based 3D Super-Resolution Fluorescence Imaging

Ciocanaru, Ioana Andreea

05 1900

Nanoscopic spatial reorganization of selectin ligands, CD44 and PSGL-1, during the initial step of hematopoietic stem/progenitor cell (HSPC) homing, tethering and rolling of migrating cells over E-selectins, has been recently reported. However, the exact spatial distribution of these ligands and their spatial reorganization during the cell rolling on E-selectins are still an open question. The spatiotemporal characterization at the nanoscale level requires high resolution imaging methods. In this study, I quantitatively characterize nanoscopic spatiotemporal behavior of the selectin ligands on the migrating cells to understanding the molecular mechanism of the cell rolling at the nanoscale level by means of a microfluidics-based 3D super-resolution fluorescence microscopy technique. The obtained results suggest that PSGL-1 on the cell shows significant change in the axial distribution on the cell during the cell rolling on E-selectin whereas the spatial distribution of CD44 along the axial direction is not affected significantly by the cell rolling. These findings indicate that each selectin ligand has a distinct contribution to the initial step of the HSPC homing because of their distinct spatial localizations on the cells that regulate at least partly the accessibility of these ligands to the surface E-selectin.

hematopoietic stem cells

microfluidics

super-resolution microscopy

fluorescence microscopy

STORM

ligand-receptor interactions

Regulation of the innate immune system

McGlasson, Sarah Louise

January 2015

The innate immune system is the first line of defence against pathogen invasion. The range of diseases that are caused by deficiencies in or deregulation of the innate immune system illustrates the importance of maintaining an effective balance between clearance of infectious agents and minimisation of inflammatory mediated tissue damage. This thesis explores the role of two proteins in the regulation of the innate immune system. Primarily, this work investigates the effect of human β-defensin 3 (hBD3) on the response to self-DNA and pathogenic DNA. HBD3 is an antimicrobial peptide (AMP), which has been shown to have a role in regulating the immune response; increased copy number of the region containing the gene for hBD3, DEFB103, is linked to an increased risk of psoriasis. Additionally, a similar cationic AMP, LL37, has been shown to exacerbate the pathogenesis of psoriasis by forming an immunogenic complex with self-DNA. This lead to the hypothesis that hBD3 may also affect the innate immune response to DNA. Therefore this project investigates what effect hBD3 has on the response of the innate immune system to self and pathogenic DNA. Flt-3 dendritic cells were used to show that whilst hBD3 increased cellular uptake of self-DNA, it did not convert self-DNA into an immune stimulus. However, hBD3 significantly exacerbated the response to bacterial DNA in a TLR9-dependent manner, also by increasing cellular uptake into FLDCs. The finding that hBD3 increased cellular uptake of both self- and pathogenic DNA suggests that at sites of infection or increased cell death, where DNA would be found in the extracellular environment, hBD3 may increase uptake into immune cells and could induce an increased immune response. Since increased hBD3 expression is induced by inflammatory stimuli, this process would cause a positive feedback loop of inflammation during bacterial infections. In conclusion, hBD3’s role in regulating the innate immune response to DNA is at the ligand-receptor level rather than affecting signalling pathways. Furthermore, hBD3 promotes the innate immune response to bacterial DNA by increasing the efficiency of cellular uptake possibly by inducing DNA aggregation. These results implicate a possible role for hBD3 in the earliest stages of psoriatic plaque development, which is often initiated or exacerbated by an infection, and this could be investigated further. Secondly, I investigated the innate immune function of an E3 ubiquitin ligase (E3L) not previously associated with human disease. Mutations in E3L have been identified in three microcephalic primordial dwarfism families; these patients also presented with recurrent respiratory illnesses. E3L has been implicated in the regulation of the innate immune system via interactions with signalling pathways downstream of the receptor, though its role is not clear. We hypothesised that E3L had a dual role both in regulating growth and cell division and in regulating the immune system. Primary patient fibroblasts did not demonstrate an altered cytokine response to bacterial or viral ligands, implying that E3L may have a specific function in immune cells. To investigate this further, and to provide a system to study E3L in vivo, two transgenic mouse lines were designed and engineered, firstly a conditional ‘knock-out’ designed to replicate some of the alternative isoforms of E3L seen in RT-PCRs, and secondly a ‘knock-in’ line to recapitulate the human mutation in exon 7 of E3L, R185X. These mouse lines should offer an insight into the developmental role for E3L, and contribute to establishing a potential role for E3L in the innate immune system. This thesis exemplifies the complexity of the innate immune system and the regulatory pathways that interact to maintain a delicate homeostasis preventing pathogenic inflammation. Understanding these regulatory mechanisms may shed light on the pathogenicity of diseases and identification of potential targets for therapeutics.

616.07

Characterization of the antibodies and antibody technologies to improve the pharmaceutical activity / 薬学的活性を改善するための抗体および抗体技術に関する研究

Shinmi, Daisuke

23 January 2018

京都大学 / 0048 / 新制・論文博士 / 博士(工学) / 乙第13145号 / 論工博第4163号 / 新制||工||1687(附属図書館) / (主査)教授 森 泰生, 教授 浜地 格, 教授 梅田 眞郷 / 学位規則第4条第2項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

antibody

antibody-drug conjugate

site-specific conjugation

carcinoembryonic antigen

500

Identification des résidus essentiels à l’interaction du récepteur CXCR7 avec ses ligands SDF-1 et ITAC

Benredjem, Besma

08 1900

Les chimiokines sont des petites protéines secrétées dont la fonction principale est la stimulation de la migration de cellules immunitaires vers différents organes et tissus. Elles sont souvent impliquées lors des maladies inflammatoires, auto-immunes et des cancers. Ainsi, les chimiokines et leurs récepteurs couplés aux protéines G (RCPG) sont la cible pharmacologique de plusieurs molécules, actuellement testées en essais cliniques. Nous avons pris comme modèle, lors de notre étude, le récepteur atypique CXCR7. Ce récepteur est dit atypique, car il ne signalise pas via la voie classique des protéines G, mais plutôt via la voie de la β-arrestine. CXCR7 est impliqué dans de nombreux cancers, favorise la progression métastatique et est un co-récepteur pour le virus de l’immunodéficience humaine (VIH). Cependant, aucune donnée sur son mode de liaison avec ses ligands CXCL11/ITAC et CXCL12/SDF-1 n’existe à date. Nous pensons que cette information est essentielle pour le développement efficace d’agonistes et d’antagonistes, et nous nous sommes intéressés à identifier les résidus essentiels à la liaison des deux ligands de CXCR7 et à son activation par ces derniers. Pour cela, nous avons créé une série de mutants par substitution ou délétion d’acides aminés de la partie N-terminale, des boucles extracellulaires et des domaines transmembranaires du récepteur. Nous avons testé leur marquage en surface cellulaire par cytométrie en flux, leur liaison des deux ligands par expériences de radio-liaison, et leur capacité à recruter la β-arrestine en réponse aux ligands par essais BRET. Les résultats obtenus ont permis d’identifier des résidus importants à l’interaction des systèmes CXCR7/SDF-1 et CXCR7-ITAC et suggèrent des modes de liaison à CXCR7 différents entre ITAC et SDF-1. Tout comme la liaison d’ITAC à son autre récepteur CXCR3, sa liaison à CXCR7 suivrait le mode conventionnel de liaison en deux étapes des récepteurs de chimiokines. Cependant, la liaison de SDF-1 à CXCR7 suivrait un autre mode de liaison, contrairement à sa liaison à son autre récepteur, CXCR4. / Chemokines are small secreted proteins whose major function is to stimulate the migration of immune cells to different organs and tissues. They are often involved in inflammatory and auto-immune diseases as well as cancers. Thus, chemokines and their G proteins Coupled Receptors (GPCR) are the pharmacological target of multiples molecules, currently tested in clinical trials. The model of our study is the atypical receptor CXCR7. This receptor is called atypical because it doesn’t signalize through the classical G protein pathway but rather signalizes through the β-arrestin pathway. CXCR7 is involved in many cancers, promotes metastatic progression and is a co-receptor for human immunodeficiency virus (HIV). However, there are, to date, no data concerning its binding mode to its ligands CXCL11/ITAC and CXCL12/SDF-1. We think that this information is crucial for the efficient development of agonists and antagonists and thus decided to identify the residus that are important for the binding of the two ligands of CXCR7 to the receptor and its subsequent activation. For that, we created a set of mutants by substitution or deletion of amino acids of the N-terminus, extracellular loops and transmembrane domains of the receptor. We then tested their surface expression by antibody staining and flow cytometry, their binding of the two ligands by binding assays and their capability to recruit β-arrestin in response to the ligands by BRET assays. The results obtained allowed us to identify important residues for the interaction of the systems CXCR7/SDF-1 and CXCR7/ITAC. They also suggest different binding modes of the chemokines ITAC and SDF-1 to CXCR7. Just like the binding of ITAC to its other receptor CXCR3, the binding mode of ITAC to CXCR7 follows the conventional two steps binding model of chemokine receptors. However, the binding of SDF-1 to CXCR7 follows another binding mode than the classical two step model, unlike its binding to its other receptor CXCR4.

CXCR7

RCPG

ACKR

ITAC

SDF-1

Interaction ligand/récepteur

Résidus chargés

Cancer

CXCR3

CXCR4

Charged residues

Interaction ligand/receptor

Control of ligand-receptor interaction by tuning molecular environment

Lo schiavo, Valentina

29 November 2011

L'adhésion cellulaire est un processus biologique fondamental contrôlé par des liaisons moléculaires spécifiques entre ligands et récepteurs attachés à des surfaces. La formation et la rupture de ces liens dépendent de facteurs cinétiques, mécaniques et structurelles. Le but de ce travail était d'observer comment l'interaction ICAM-1 - anti ICAM-1 pouvait être modifié en jouant i) sur la multivalence de molécules impliquées dans la liaison ii) sur la topographie de surface et iii) sur la mobilité des ligands. A cette fin, on a principalement utilisé une chambre à flux laminaire, complété par une détection de molécule unique par fluorescence.L'étude sur les effets de multivalence, utilisant des monomères et dimères d'ICAM-1, a été réalisée en absence et en présence d'une force mécanique, montrant la plus grande stabilité des liaisons divalentes. En outre, un renforcement avec la force et le temps a été trouvé et décrit avec une fonction à deux paramètres, montrant, pour les liaisons divalentes, un comportement intermédiaire entre rupture parallèles et successives des liaisons. La fréquence d'adhésion des liaisons monovalentes et bivalentes présente différentes valeurs causées par la différence de longueur de ces molécules.Les expériences d'adhésions ont été effectuées en variant la topographie du substrat pour les molécules étudiées. Une comparaison des cinétiques de liaisons sur ces surfaces ne montrent pas de différences soit dans la formation ou dans la rupture. Pour interpréter ces résultats, un modèle qui prend en compte la zone de contact réel devrait être construit à partir des images AFM des échantillons.Dans l'écoulement, le temps de contact entre les molécules est contrôlé par la convection de microsphères. Des résultats récents montrent qu'un minimum de temps est requis pour former la liaison (Robert et al. 2011). Pour tester cette prédiction, les ligands sont ancrés à une bicouche lipidique (SLB) pour étudier comment la diffusion peut modifier l'adhésion. Expérimentalement, les fréquences d'adhésion des liaisons ont montré un comportement similaire pour les SLB fixes et fluides. Toutefois, la simulation numérique prédit un effet sur la formation de la liaison, même lorsque la diffusion des ligands est faible. Il semblerait que la diffusion joue un rôle dans la dissociation de la liaison, réduisant fortement la valeur de koff pour une bicouche fluide. Cet effet peut être expliqué par la présence éventuelle de liaisons multiples dues à l'accumulation des ligands sur la surface de contact. / Cell adhesion is a fundamental biological process mediated by specific molecular bonds formed by ligands and receptors attached to surfaces. Formation and rupture of these bonds depend on kinetic, mechanical and structural factors. The goal of this work was to observe how the ICAM-1 – anti ICAM-1 interaction can be modified by playing i) on the multivalency of molecules involved in the bond ii) on the topography of surface and iii) on the mobility of ligands. The main technique used for this purpose was the laminar flow chamber, completed by single-particle tracking in fluorescence.The study on multivalency effects, using monomeric and dimeric ICAM-1, was performed in absence and presence of mechanical force, showing the higher stability of divalent bonds. Also, a force- and time- strengthening dependence was found and described with a two-parameter function, showing, for divalent bonds, an intermediate behaviour between parallel and subsequent rupture of bonds. The adhesion frequency of monovalent and divalent bonds exhibit different values accounted by difference in length of these molecules.Adhesion experiments were performed varying the topography of the substrate for the investigated molecules. A comparison of bond kinetics on these surfaces did not show differences either in attachment or in rupture. To interpret these results, a model which takes into account the real contact area should be built from the AFM images of the samples.In the flow, the contact time between molecules is controlled by convection of microspheres. Recent results show that there is a minimal time required to form the bond (Robert et al. 2011). To test this prediction, ligands were anchored to supported lipid bilayer (SLB) to investigate how the diffusion can modify the adhesion. Experimentally, the adhesion frequencies of the bonds showed similar behaviour for fixed and fluid SLB. While, numerical simulation predicted an effect on bond formation even at low ligand diffusion. The diffusion seemed to play a role in bond dissociation, strongly reducing the value of koff for fluid bilayer. This effect can be explained by the possible presence of multiple bonds due to ligand accumulation on the contact area.

Interaction ligand-recepteur

Molecule unique

Fluorescence

Chambre a flux

Divalence

Difusion

Rugosité

Ligand-receptor interaction

Single-molecule

Fluorescence

Flow chamber

Divalency

Diffusion

Roughness

Engineering ligand-receptor pairs for small molecule control of transcription

Schwimmer, Lauren J.

19 July 2005

Creating receptors for control of transcription with arbitrary small molecules has widespread applications including gene therapy, biosensors, and enzyme engineering. Using the combination of high throughput docking, codon randomization, and chemical complementation, we have created new receptors to control transcription with small molecules. Chemical complementation, a new method of protein engineering, was used to discover retinoid X receptors (RXR) variants that are activated by compounds that do not activate wild-type RXR. A first library of 32,768 RXR variants was designed for the synthetic retinoid-like compound LG335. The library produced ligand-receptor pairs with LG335 that have a variety of EC50s and efficacies. One engineered variant has essentially the reverse ligand specificity of wild-type RXR and is transcriptionally active at 10 and #64979;fold lower LG335 concentration than wild-type RXR with 9cRA in yeast. The activity of this variant in mammalian cells correlates with its activity in yeast. A second library of 262,144 RXR variants was designed for two purposes: (i) to develop a high-throughput chemical complementation method to select variants that have high efficacies and low EC50s; and (ii) to find variants which are activated by small molecules not known to bind RXR variants. Selection conditions were manipulated to find only variants with high efficacies and low EC50s. This library was also selected for variants that activate transcription specifically in response to gamma-oxo-1-pyrenebutyric acid (OPBA), which is different from any known RXR ligand. OPBA was chosen as a potential ligand using high-throughput docking with the software program FlexX. Two variants are activated by OPBA with an EC50 of 5 mM. This is only ten-fold greater than the EC50 of wild type RXR with its ligand 9cRA (500 nM) in yeast. An improved method synthesizing LG335 and a method for quantifying intracellular ligand concentrations were developed. Although the LG335 synthetic method has an additional step, the overall yield was improved to 8% from 4% in the original publication. Liquid chromatography and mass spectrometry was used to quantify the intracellular concentration of LG335, which was found to be within four fold of the LG335 concentration in the media.

Chemical complementation

Ligand-receptor pair

Protein engineering

Retinoid X receptor

Nuclear receptor

Codon randomized libraries

Transcription factors

Genetic engineering

Nuclear receptors (Biochemistry)

Protein engineering