Chemical control of liquid phase separation in the cell

Adame Arana, Omar

28 February 2020

Zellen sind in der Lage, gleichzeitig ganz unterschiedliche biochemische Prozesse zu bewältigen. Dies gelingt ihnen durch eine Einteilung ihres Inneren in Kompartiemente, sogennante Organellen, die die jeweils geeignete biochemische Umgebung für die unterschiedlichen Aufgaben schaffen. Bei membranumschlossenen Kompartimenten ist leicht vorstellbar, dass sie eine andere biochemische Zusammensetzung als ihre Umgebung haben können. Jedoch existieren auch Organelle ohne Membran die durch eine flüssig-flüssig Phasenseparation entstehen. Manche dieser Kompartiemente haben die Fähigkeit, RNA zu binden und Proteinkomplexe auszubilden, während andere auf die Veränderungen innerhalb der Zelle, wie z.B. die Veränderung des pH-Werts und der damit Verbunden Änderung ihres Protonierungszustands, reagieren können. Um diese Prozesse theoretisch analysieren zu können, entwickeln wir zunächst ein allgemeingültiges, thermodynamisches Gerüst, um Systeme zu untersuchen, die im chemischen Gleichgewicht flüssig-flüssig hasensepariert vorliegen können. Dies erlaubt, basierend auf den Erhaltungsgrößen, im chemischen Gleichgewicht thermodynamisch konjungierten Variablen zu identifizieren, welche aus den erhaltenen Komponenten und den zugehörigen chemischen Potentialen bestehen. Mithilfe des obig erwähnten Gerüsts können wir den Einfluss des pH-Wertes auf die flüssig-flüssig Phasenseparation in einem minimalen Modell untersuchen. Dies beschreibt die makromolekulare Phasenseparation, kontrolliert durch Protonierungs- und Deprotonierungreaktionen, welche wiederum vom pH-Wert abhängig sind. Unsere Untersuchung der pH-Abhängigkeit der Phasenseparation kommt zu folgenden Ergebnissen: Erstens liegt die größte Region von Phasenseparation im Phasendiagramm typischerweise im Bereich des isoelektrischen Punkts. Zweitens zeigt das Modell eine Fähigkeit der erneuten Mischung auf. Drittens ist die Topologie des Phasendiagrams von der dominantesten Interaktion bestimmt. Unser Modell stimmt mit experimentellen Beobachtungen zur Phasenseparation von intrinsisch ungeordneten, Proteinen, deren Struktur sich pH abhängig verändern, überein. Das Modell ist außerdem konsistent mit Beobachtungen von Phasenseparation von Proteinen im Zytosol von Hefezellen, die entsteht, wenn der intrazellulare pH-Wert in die Nähe des isoelektrischen Punkt dieser Proteine gebracht wird. Des Weiteren geht diese Arbeit auf den physikalischen Mechanismus ein, mit dem flüssigkeitsähnliche Organellen, sog. P granules, im Organismus Caenorhabditis elegans positioniert werden. Um dieses Phänomen zu analysieren, stellen wir zunächst experimentelle Beobachtungen vor, die zeigen, dass PGL-3, eine Hauptkomponente der P granules, flüssigkeitsähnliche Tropfen bildet, deren Zusammensetzung von RNA moduliert werden kann. Darüber hinaus zeigen wir Daten, die großen Unterschiede zwischen der RNA-Bindungsaffinität von Proteinen wie Mex-5, die für die Positionierung der P granules relevant sind, und solchen, die P granules bilden, wie PGL-3, zeigen. Dies deutet darauf hin, dass eine Konkurrenz zwischen den Bestandteilen der P Granula und MEX-5 um die zur Bindung zur Verfügung stehende RNA besteht, die die Kondensation und Auflösung von P Granula räumlich kontrollieren könnte. Auf diesen experimentellen Befunden aufbauend führen wir ein minimalles Modell ein, in dem wir die Phasenseparation von PGL-3 an Bindungsreaktionen der MEX-5 Proteine und RNA koppeln. Um die experimentellen Beobachtungen beschreiben zu können, muss die Neigung des PGL-3 Proteins zur Phasenseparation zunehmen, wenn es Komplexe mit RNA bildet. Dies unterstützt die Idee, dass MEX-5 diese Phasenseparation unterdrückt, indem es die Anzahl an möglichen RNA-Bindungspartner für PGL-3 herabsetzt und damit die weitere Entstehung derartiger Protein-RNA-Komplexe erschwert. Dieser einfache Mechanismus scheint die Hauptursache dafür zu sein, dass P granules auf der posterioren Seite des Caenorhabditis elegans Embryos zu finden sind. / One of the main features of cells is their incredible ability to control biochemical processes in space and time. They do so by organizing their interior in sub-compartments called organelles, each of them with a different biochemical environment that allows them to perform specific tasks in the cell. It is sometimes believed that these compartments need a membrane in order to have a stable biochemical environment and regulat their compositions. However, there are some organelles which lack a membrane and seem to form and organize via liquid-liquid phase separation. Some of the components that form these membraneless organelles have the ability to bind to RNA and form complexes, while some others react to changes in the intracellular environment such as pH variations, which in turn affects their protonation state. In order to study these processes from a theoretical perspective, we develop a generic thermodynamic framework to study systems exhibiting liquid-liquid phase separation at chemical equilibrium. This framework, based on the use of conservation laws in chemical reactions, allow us to identify thermodynamic conjugate variables at chemical equilibrium, which are given by a set of conserved quantities and the corresponding conjugate chemical potentials. Within the aforementioned framework, we introduce a minimal model to study the effect of pH on liquid-liquid phase separation. Our model explains macromolecular phase separation controlled by protonation and deprotonation reactions, which are tuned by the pH of the system. We study the phase behavior of the system as a function of pH. Our main findings are: Firstly, the broadest region of phase separation is typically found at the isoelectric point. Secondly, the system exhibits reentrant behavior. Thirdly, that the dominating interaction in the system determines the topology of the phase diagrams. Our model is in agreement with experimental observations of in vitro protein phase separation of pH-responsive intrinsically disordered proteins, as well as with observations of protein phase separation exhibited by many cytosolic proteins when the intracellular pH in yeast cells is brought close to the isoelectric point of such proteins. Moreover, this work analyses the physical mechanism behind the positioning of liquid-like organelles in the {\it{Caenorhabditis elegans}} organism known as P granules. In order to study this phenomenon, we first present firm experimental evidence showing that PGL-3 protein, a key component of P granules, forms liquid-like drops whose assembly can be modulated by RNA. We then present data showing that the RNA-binding affinity differs significantly between proteins relevant for the positioning of P granules, such as MEX-5 and the proteins forming the P granules, like the aforementioned PGL-3. This points to a possible mechanism of RNA-binding competition between P granule constituents and MEX-5 in order to spatially control the condensation and dissolution of P granules. Based on the experimental evidence, we propose a minimal model in which we couple phase separation of PGL-3 to a set of binding reactions involving the MEX-5 protein and RNA. We find that in order to explain the experimental data, the tendency for phase separation of the PGL-3 protein increases with the formation of complexes of PGL-3 bound to RNA. This therefore supports the idea that MEX-5 inhibits this protein phase separation by depleting the RNA available for PGL-3 to form such complexes. This simple mechanism is at the core of how P granules localize to the posterior side of the Caenorhabditis elegans embryo.

info:eu-repo/classification/ddc/530

ddc:530

Experimentelle Untersuchungen zur Strukturbildung unter stationärer solutaler Marangoni-Instabilität

Schwarzenberger, Karin

23 November 2015

Beim Stoffübergang einer grenzflächenaktiven Substanz in einem flüssigen Zweiphasensystem kann solutale Marangoni-Instabilität einsetzen. Die weitere nichtlineare Entwicklung der Marangoni-Instabilität geht mit einer enormen Vielfalt von Strömungsmustern einher. In der Literatur wird dieser Aspekt häufig unter dem unscharfen Ausdruck „Grenzflächenturbulenz“ zusammengefasst. Diese Arbeit stellt heraus, dass drei grundlegende Strukturformen existieren: Rollzellen, Relaxationsoszillationen und Relaxationsoszillationswellen. Ein großer Teil der Komplexität der Strömungsmuster ist dadurch begründet, dass die Grundstrukturen unterschiedliche Hierarchieebenen aufweisen. Es werden die zugrunde liegenden Bedingungen für das Auftreten der jeweiligen Strukturtypen, ihre transiente Natur und die Bildung der hierarchischen Strömungsmuster untersucht. Des Weiteren betrachtet diese Arbeit die Wechselwirkungen mit Dichteeffekten, die sowohl die Charakteristik der Strukturen als auch ihre zeitliche Entwicklung beeinflussen.

info:eu-repo/classification/ddc/620

ddc:620

Interaction of Actinides with the Predominant Indigenous Bacteria in Äspö Aquifer - Interactions of Selected Actinides U(VI), Cm(III), Np(V) and Pu(VI) with Desulfovibrio äspöensis

Bernhard, Gert, Selenska-Pobell, Sonja, Geipel, Gerhard, Rossberg, Andre, Merroun, Mohamed, Moll, Henry, Stumpf, Thorsten

January 2005

Sulfate-reducing bacteria (SRB) frequently occur in the deep granitic rock aquifers at the Äspö Hard Rock Laboratory (Äspö HRL), Sweden. The new SRB strain Desulfovibrio äspöensis could be iso-lated. The objective of this project was to explore the basic interaction mechanisms of uranium, curium, neptunium and plutonium with cells of D. äspöensis DSM 10631T. The cells of D. äspöensis were successfully cultivated under anaerobic conditions as well in an optimized bicarbonate-buffered mineral medium as on solid medium at 22 °C. To study the interaction of D. äspöensis with the actinides, the cells were grown to the mid-exponential phase (four days). The collected biomass was usually 1.0±0.2 gdry weight/L. The purity of the used bacterial cultures was verified using microscopic techniques and by applying the Amplified Ribosomal DNA Restriction Enzyme Analysis (ARDREA). The interaction experiments with the actinides showed that the cells are able to remove all four actinides from the surrounding solution. The amount of removed actinide and the interaction mechanism varied among the different actinides. The main U(VI) removal occurred after the first 24 h. The contact time, pH and [U(VI)]initial influence the U removal efficiency. The presence of uranium caused a damaging of the cell membranes. TEM revealed an accumulation of U inside the bacterial cell. D. äspöensis are able to form U(IV). A complex interaction mechanism takes place consisting of biosorption, bioreduction and bioaccumulation. Neptunium interacts in a similar way. The experimental findings are indicating a stronger interaction with uranium compared to neptunium. The results obtained with 242Pu indicate the ability of the cells of D. äspöensis to accumulate and to reduce Pu(VI) from a solution containing Pu(VI) and Pu(IV)-polymers. In the case of curium at a much lower metal concentration of 3x10-7 M, a pure biosorption of Cm(III) on the cell envelope forming an inner-sphere surface complex most likely with organic phosphate groups was detected. To summarize, the strength of the interaction of D. äspöensis with the selected actinides at pH 5 and actinide concentrations ≥10 mg/L ([Cm] 0.07 mg/L) follows the pattern: Cm > U > Pu >> Np.

Quantification of Progesterone and 17-β Estradiol in Mouse Serum by Liquid Chromatography-Tandem Mass Spectrometry

Kennard, Benjamin, Cobble, Allison, Gravitte, Amy, Galloway, Kaleigh, Kintner, Jen, Hall, Jennifer, Brown, Stacy C

05 May 2020

Quantification of progesterone and 17-β estradiol in mouse serum by liquid chromatography-tandem mass spectrometry Authors: Benjamin Kennard, Allison Cobble, Amy Gravitte, Keleigh Galloway, Jen Kintner, Jennifer Hall, Stacy Brown Introduction: In the United States, Chlamydia trachomatis is a commonly appearing sexually transmitted infection1. It affects the U.S. healthcare system to a tune of about $500 million dollars annually2. In women, it generally appears asymptomatic and can lead to severe secondary complications such as pelvic inflammatory diseases or infertility1. Female sex hormones, estrogen and progesterone, are being identified to have a role in chlamydial infection. Specifically, this study aims to create quantification methods to detect levels of estrogen and progesterone in mice, infected with Chlamydia muridarum, plasma samples. Methods: Progesterone samples were prepared using solid-liquid extraction (SLE+) cartridges with ethyl acetate as the elution solvent. Estradiol samples were prepared using liquid-liquid extraction (LLE) with methyl tert-butyl ether and subsequent derivatization with DMIS. Following sample preparation, hormones were quantified in samples using LC-MS/MS with a gradient elution of 1 mM ammonium fluoride in water and acetonitrile. The separation was achieved using a UCT C18 column (100 x 21.mm, 1.8 μm particle size) maintained at 50oC. The mass spectrometer was set up to isolate molecular ions for progesterone (m/z 315.0910) and derivatized estradiol (m/z 431.1835). Quantification was facilitated by the use of deuterium-labeled internal standards and their corresponding molecular ions in the mass spectrometer (d9-progesterone; m/z 324.1230 and d5-estradiol; m/z 436.2922). Results: Several aspects of the assay presented have been optimized for maximum analyte recovery and analytical sensitivity, including column choice, mobile phase, derivatizing agents for estradiol, and extraction protocols for progesterone. The LC-MS/MS method was investigated for precision and accuracy over three separate days. The dynamic range of the progesterone assay was 5 – 100 ng/mL, with a limit of detection of 1 ng/mL. Likewise, the estradiol assay was linear in the range of 5 – 100 ng/mL, with a limit of detection of 0.5 ng/mL. The average precision, represented by % RSD was 0.74 – 8.5% and 6.3 – 13.4% for progesterone and estradiol, respectively. The accuracy of the method, represented by % error was 1.6 – 14.4% and 4.0 – 10.5% for progesterone and estradiol, respectively. Successful validation was defined as < 15% RSD and error (< 20% at the limit of quantification), per current FDA Guidelines. Conclusions: The developed LC-MS/MS method is specific for progesterone and estradiol, and the extraction is suitable for preparation of mouse serum samples. This assay could be successfully applied to hormone quantification in mouse samples to support the investigation of the link between chlamydia infection and hormone levels in female animals. References 1. Chlamydia - 2017 Sexually Transmitted Diseases Surveillance. https://www.cdc.gov/std/stats17/chlamydia.htm. Accessed October 23, 2018. 2. Owusu-Edusei K, Chesson HW, Gift TL, et al. The Estimated Direct Medical Cost of Selected Sexually Transmitted Infections in the United States, 2008. Sex Transm Dis. 2013;40(3):197-201. doi:10.1097/OLQ.0b013e318285c6d2

STI

Chlamydia

Mass Spectrometry

Solid-Liquid Extraction

Liquid-Liquid Extraction

Urogenital System

Bacterial Infections

Female Genital Disorders

Infectious Diseases

Sexually Transmitted Diseases

Venereal Diseases

Womens Health

Design of a solvent recovery system in a pharmaceutical manufacturing plant / Utformning av en lösningsmedelsåtervinningssystem i en läkemedelsfabrik

BHANDARI, SHASHANK

January 2016

Solvents play a crucial role in the Active Pharmaceutical Ingredient (API) manufacturing and are used in large quantities. Most of the industries incinerate the waste solvents or send it to waste management companies for destruction to avoid waste handling and cross-contamination. It is not a cost effective method and also hazardous to the environment. This study has been performed at AstraZeneca’s API manufacturing plant at Sodertalje, Sweden. In order to find a solution, a solvent recovery system is modeled and simulated using ASPEN plus and ASPEN batch modeler. The waste streams were selected based on the quantity and cost of the solvents present in them. The solvent mixture in the first waste stream was toluene-methanol in which toluene was the key-solvent whereas in the second waste stream, isooctane-ethyl acetate was the solvent mixture in which isooctane was the key-solvent. The solvents in the waste stream were making an azeotrope and hence it was difficult to separate them using conventional distillation techniques. Liquid-Liquid Extraction with water as a solvent followed by batch distillation was used for the first waste stream and Pressure Swing Distillation was used for the second waste stream. The design was optimized based on cost analysis and was successful to deliver 96.1% toluene recovery with 99.5% purity and 83.6% isooctane recovery with 99% purity. The purity of the solvents was decided based on the quality conventions used at AstraZeneca so that it can be recovered and recycled in the same system. The results were favorable with a benefit of €335,000 per year and preventing nearly one ton per year carbon dioxide emissions to the environment. A theoretical study for the recovery system of toluene-methanol mixture was performed. The proposed design was an integration of pervaporation to the batch distillation. A blend of polyurethane / poly(dimethylsiloxane) (PU / PDMS) membrane was selected for the separation of methanol and toluene mixture. The results of preliminary calculations show 91.4% toluene recovery and 72% methanol recovery with desired purity.

Batch distillation

liquid-liquid extraction

pressure swing distillation

pharmaceutical manufacturing

sustainable development

Chemical Process Engineering

Kemiska processer

Pharmaceutical Chemistry

Farmaceutisk synteskemi

Characterizing Liquid-Fluid Interfaces Using Surface Light Scattering Spectroscopy

Thapa, Nabin K.

26 July 2019

No description available.

Physics

Surface Light Scattering Spectroscopy

surface tension

binary mixtures

Langmuir monolayers

thermal capillary waves

surface response function

liquid-vapor interfaces

liquid-liquid-vapor interfaces

<i>Cauliflower mosaic virus</i> Inclusion Body Formation: The Where, The How and The Why

Alers-Velazquez, Roberto M.

January 2020

No description available.

Molecular Biology

Virology

LifeAct

Latrunculin B

GFP250

Liquid-liquid phase separation

Nonmembranous organelles

Pararetrovirus

Particle tracking

qPCR

DAS-ELISA

CaMV

P6

inclusion bodies

Talin

symptom formation

temperature

Molecular mechanisms of the asymmetric pit-closing in clathrin-mediated endocytosis / クラスリン媒介エンドサイトーシスにおける非対称ピット閉鎖の分子機構

Yu, Yiming

24 November 2023

京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24983号 / 生博第512号 / 新制||生||68(附属図書館) / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授 荒木 崇, 教授 鈴木 淳, 教授 谷口 雄一 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

Cdc42-interacting protein 4

F-BAR domain-containing protein

clathrin-mediated endocytosis

high-speed atomic force microscopy

superresolution microscopy

liquid-liquid phase separation

actin

460

Un nouveau mécanisme moléculaire de régulation du système ubiquitine-protéasome par séparation de phase liquide-liquide

Uriarte, Maxime

12 1900

L'homéostasie cellulaire implique une régulation fine de la production ainsi que de l'élimination des protéines. La dérégulation de cette homéostasie entraîne des effets néfastes touchant de nombreuses voies de signalisation et de métabolisme et pouvant conduire à diverses maladies telles que le cancer ou la neurodégénérescence. De ce fait, la dégradation des protéines est un processus hautement contrôlé effectué par le système ubiquitine-protéasome (UPS) qui permet le ciblage, l’étiquetage et la dégradation des protéines mal repliées, endommagées ou en fin de vie. Le protéasome est un complexe multiprotéique vital présent dans toutes les cellules eucaryotes dont la biogenèse, la fonction de dégradation et la régulation dans le cytoplasme sont bien connues. Cependant, la fonction du protéasome dans le noyau, notamment en réponse au stress, est encore peu comprise. Les cellules ont développé de nombreux mécanismes adaptatifs en réponse à la variation de l'apport en nutriments comme l’augmentation de la dégradation et le recyclage des protéines. Chez l’humain, le protéasome est dégradé dans le cytoplasme par autophagie lors d’une privation de nutriments mais les mécanismes de régulation du protéasome nucléaire en réponse au stress métabolique restent peu connus. Nous avons trouvé que le protéasome 26S et la sous-unité régulatrice PSME3 forment des foyers nucléaires dans différents types cellulaires de mammifère en réponse à une privation en nutriments. Les foyers, nommés SIPAN pour Starvation-Induced Proteasome Assemblies in the Nucleus, ne sont colocalisés avec aucune structure ou corps nucléaires connus. La formation des SIPAN est réversible lors d’une réintégration des nutriments, suggérant une réponse spécifique liée à un stress métabolique. La manipulation de la quantité d’acides aminés intracellulaire a révélé que les acides aminés non-essentiels jouent un rôle important dans la formation et la résolution des SIPAN. Une analyse métabolomique a permis de trouver des voies reliées au métabolisme des nucléotides et des acides aminés qui pourraient fournir des facteurs clés pour la dissipation des foyers du protéasome. Le fort dynamisme des SIPAN, la présence d’événements de fusion et leur instabilité vis-à-vis des conditions cellulaires suggèrent que les SIPAN résultent d’une séparation de phase liquide-liquide (LLPS). De plus, nous avons trouvé que l’ubiquitine conjuguée est présente dans les SIPAN et que l’ubiquitination et la déubiquitination semblent être impliquées dans la formation et la résolution, respectivement. Nous avons ensuite découvert que la perte du récepteur à l’ubiquitine RAD23B empêche la formation des SIPAN. En effet, les domaines de liaison au protéasome UBL et de liaison à l’ubiquitine UBA1/UBA2 sont nécessaires pour la formation des SIPAN. De manière intéressante, la perte de RAD23B ou du complexe régulateur PSME3 retarde l’induction de l’apoptose et promeut la survie cellulaire. Enfin, en utilisant un inducteur de l’apoptose, nous avons observé l’apparition de ces foyers du protéasome dans le noyau des cellules dont certaines caractéristiques sont similaires aux SIPAN. Notre étude aborde une question très importante dans la compréhension des rôles et du dynamisme du protéasome nucléaire, en particulier dans l'adaptation au stress, qui peut réguler le niveau des protéines nucléaires. De façon générale, cela nous aidera à mieux comprendre le rôle du protéasome dans l’homéostasie nucléaire et son implication dans les maladies humaines. / Cellular homeostasis involves specific regulation of the production as well as the elimination of proteins. The deregulation of this equilibrium leads to harmful effects affecting many signaling and metabolic pathways and can lead to various diseases, such as cancer or neurodegeneration. Hence, protein degradation is a highly controlled process performed by the ubiquitin-proteasome system (UPS) that allows targeting, labeling and degradation of misfolded, damaged, or end-of-life proteins. The proteasome is a vital multiprotein complex found in all eukaryotic cells whose biogenesis, degradative function, and regulation in the cytoplasm are well known. However, the function of the proteasome in the nucleus, particularly in response to stress, is still poorly understood. Cells have evolved many adaptive mechanisms in response to varying nutrient supply such as increased protein degradation and recycling. In humans, the proteasome is degraded in the cytoplasm by autophagy during nutrient deprivation, but the regulatory mechanisms of the nuclear proteasome in response to metabolic stress remain poorly understood. We have found that the 26S proteasome and regulatory subunit PSME3 form nuclear foci in different mammalian cell types in response to nutrient deprivation. These foci, called SIPAN for Starvation-Induced Proteasome Assemblies in the Nucleus, do not colocalize with any known nuclear structures or bodies. The formation of SIPAN is reversible upon nutrient replenishment, suggesting a specific response to metabolic stress. Manipulation of the intracellular amino acid pool revealed that non-essential amino acids play important roles in the formation and resolution of SIPAN. A metabolomics study has identified pathways related to nucleotide and amino acid metabolism that may provide key factors for the dissipation of the proteasome foci. The strong dynamism of SIPAN, the presence of fusion events and their instability towards cellular conditions suggest that SIPAN result from liquid-liquid phase separation (LLPS). Additionally, we have found that conjugated ubiquitin is present in SIPAN and that ubiquitination and deubiquitination appear to be involved in their formation and resolution, respectively. We then discovered that the depletion of the ubiquitin receptor RAD23B prevents the formation of SIPAN. Indeed, the UBL proteasome binding domain and UBA1/UBA2 ubiquitin binding domains are required for SIPAN formation. Interestingly, the depletion of RAD23B or the proteasome regulatory particle PSME3 delays the induction of apoptosis and promotes cell survival. Finally, we found that an apoptosis-inducing agent promotes proteasome foci formation in the nucleus of cells, and these organelles share similarities with SIPAN. Our study addresses a very important question in understanding the roles and dynamism of the proteasome in the nucleus, specifically during stress adaptation, which can regulate the level of nuclear proteins. In general, this will help us to better understand the role of the proteasome in nuclear homeostasis and its involvement in human diseases.

protéasome

ubiquitine

séparation de phase liquide liquide

UPS

apoptose

privation de nutriments

liquid liquid phase separation

apoptosis

RAD23B

nutrients starvation

acides aminés non essentiels

non essential amino acids

Biochemistry / Biochimie (UMI : 0487)

An LC-MS/MS APPROACH FOR GANGLIOSIDES PROFILING IN BRAIN AND RETINAL TISSUE OF MICE: APPLICATION TO GLAUCOMA MICE AGE STUDIES

Gobburi, Ashta Lakshmi Prasad

January 2017

No description available.

Biochemistry

Biology

Chemistry

Analytical Chemistry

Gangliosides

glaucoma

retinal tissue

DBA2J

C57BL6J

liquid-liquid extraction

solid-phase extraction

liquid-chromatography-mass spectrometer

phenyl-hexyl HPLC column

HILIC