Mimicking αB crystallin phosphorylation at serine 45 and 59 in vivo

Hottinger, Shawna KB

21 May 2009

No description available.

Molecular Biology

CryAB

CryABwildtype

CryABS59D

CryABS45/59D

HSPB2

transgenic

protein

Au delà des frontières du glioblastome : caractérisation de la zone péritumorale des glioblastomes / Beyond the frontiers of glioblastoma : multidisciplinary characterisation of glioblastoma's peritumoral brain zone

Lemée, Jean-Michel

26 February 2015

Le glioblastome (GB) est une tumeur hétérogène, agressive devant laquelle les possibilités thérapeutiques disponibles restent limitées. L’étude de la zone péritumorale macroscopiquement normale (ZMN) des GB est essentielle à la compréhension de ses mécanismes de progression et de récidive. Le premier objectif de ce travail de Thèse a été de comparer les données de transcriptomique et de protéomique issues de l’analyse de la zone tumorale des GB dans le cadre du Projet Gliome Grand Ouest. Le taux de concordance entre les 2 modalités est faible, retrouvant toutefois comme point commun une dysrégulation de la protéine légère des neurofilaments qui pourrait servir de biomarqueur potentiel des GB. Le deuxième objectif de ce travail de Thèse a été la caractérisation de la ZMN des GB. Nous avons mis en évidence que cette zone, dont l’aspect est similaire à première vue à celui du tissu cérébral sain, n’est pas une simple zone de transition entre le GB et le tissu cérébral sain. En effet, la ZMN est une entité spécifique possédant des caractéristiques qui lui sont propres, comme la présence d’un phénotype particulier de cellules tumorales infiltrantes et de cellules stromales et une sur’expression des protéines CRYAB et H3F3A. Ce travail de Thèse a aussi été l’occasion de développer de nouvelles techniques d’imagerie per-opératoire de la ZMN, afin d’évaluer la présence d’un contingent tumoral et ainsi optimiser la qualité de la résection chirurgicale. La caractérisation de cette ZMN nous permet de mieux appréhender son implication dans la tumorogenèse et la présence de caractéristiques spécifiques de cette zone ouvre la porte à la détection de biomarqueurs spécifiques, ainsi qu’au développement de thérapies ciblées. Ce travail de Thèse a été valorisé par 2 publications, 2 articles soumis et un brevet est en cours de dépôt et d’évaluation par un cabinet de brevet. / Glioblastoma (GB) is a heterogeneous andaggressive tumor, before which therapeutic options arelimited. The study of the macroscopically normalperitumoral brain zone (PBZ) of GB is essential tounderstand its mechanisms of progression andrecurrence.The first objective of this thesis work was tocompare the transcriptomic and proteomic data from theGB tumor area obtained through the “Grand Ouest”glioma Project. The concordance rate between the 2modalities is low. However, one of the common featureis the dysregulation of neurofilament light polypeptide,which could serve as a biomarker potential of GB.The second objective of this thesis was thecharacterization of the PBZ. We have shown that thisarea, similar at first glance to that of healthy braintissue, is not a simple transition area between the GBand healthy brain tissue but a specific entity withcharacteristics of its own. For example, the ZMNpresents a particular phenotype of infiltrating GB cellsand stromal cells and a surexpression of CRYAB andH3F3A proteins.This thesis work was also an opportunity todevelop new intraoperative imaging techniques of thePBZ, with the aim to assess the presence of a tumoralinfiltration and optimize the quality of the surgicalresection.The characterization of this PBZ allows us tobetter understand its involvement in tumorigenesis andthe presence of specific characteristics of this areaopens the door for the detection of specific biomarkersand the development of targeted therapies.This thesis work was led to 2 publications, 2articles submitted and a patent being evaluated andredacted by a patent office.

Glioblastome

Zone péritumorale

Génomique

Transcriptomique

Protéomique

Cultures cellulaires

Cryab

Microscopie biphotonique

Glioblastoma

Peritumoral brain zone

Genomics

Transcriptomics

Proteomics

Cell cultures

CRYAB

Two-photon microscopy

616.994

A CryAB Interactome Reveals Clientele Specificity and Dysfunction of Mutants Associated with Human Disease

Hoopes, Whitney Katherine

01 November 2016

Small Heat Shock Proteins (sHSP) are critical molecular chaperones that function to maintain protein homeostasis (proteostasis) and prevent the aggregation of other proteins during cellular stress. Any disruption in the process of proteostasis can lead to prevalent diseases ranging from cancer and cataract to cardiovascular and Alzheimer's disease. CryAB (αB-crystallin, HspB5) is one of ten known human sHSP that is abundant in the lens, skeletal, and cardiac muscle. This protein is required for cardiac function and muscle cell integrity. When the cell experiences physiological stress, including heat shock, CryAB moves to the cytoskeleton to act as a chaperone and prevent aggregation of its protein clientele. This research is designed to investigate the molecular role of CryAB in cell proteostasis through the identification of putative protein clientele and chaperone activity analysis. We have identified over twenty CryAB-binding partners through combined yeast two-hybrid (Y2H) and co-purification approaches, including interactions with myofibril proteins. Previously reported disease-associated CryAB missense variants were analyzed in comparison to wild type CryAB through Y2H binding assays. The characterization of the similarities and differences in binding specificities of these variants provide a foundation to better understand the chaperone pathways of CryAB and how these changes in molecular function result in the development of disparate diseases such as cataract, cancer, and various myopathies.

small Heat Shock Proteins (sHSP)

HspB5 (αB-crystallin

CryAB)

molecular chaperones

proteostasis

R120G

HspB2

Microbiology

Characterizing the Role of HspB2 in Cardiac Metabolism and Muscle Structure Using Yeast and Mammalian Systems

Neubert, Jonathan Paul

08 August 2012

HspB2 is a small heat shock protein encoded on human chromosome 11. Less than 1000 base pairs away from HSPB2 and situated in a head-to-head orientation lies the gene encoding another small heat shock protein, CRYAB. Because they are uncommonly close to one another they share regulatory elements. In addition, they share protein homology as sHSPs, suggesting that they perhaps perform aimilar functions. SHSPs such as HspB2 and CryAB are traditionally thought to provide protective effects to cells in response to a variety of stress inducers. In response to stress they form complexes around misfolded proteins or proteins in danger of denaturation. HspB2 has been shown to exhibit protective effects during cellular stress and to localize to the Z-line of skeletal muscle. It has also been implicated in cardiac energetics, specifically in the production of ATP, however little is known about its molecular targets. Here I report the use of yeast two-hybrid screening to uncover the molecular targets of HspB2. I also detail the process by which the screens are performed as well as the verification steps, including co-precipitation experiments in mammalian cells. Through these studies we identify many novelbinding partners of HspB2, including CryAB as well as multiple muscle and mitochondrial proteins. Proteins discovered to bind to HspB2 include such proteins as actin and myosin, enzymes catalyzing various steps of glycolysis and the electron transport chain, as well as redox-, small heat shock protein-, kinase-, and electrolyte-related proteins, among others. Studies of the binding partners of HspB2 in cardiac tissue will provide important information clarifying the involvement of HspB2 in cardiac muscle maintenance and metabolism.

small heat shock proteins

HSPB2

CRYAB

yeast two-hybrid

coimmunoprecipitation

Microbiology

Molecular Regulation of Inflammation and Angiogenesis in the Tumor Microenvironment

Dieterich, Lothar

January 2011

Tumor growth and progression not only depend on properties of the malignant cells but are strongly influenced by the tumor microenvironment. The tumor stroma consists of various cell types such as inflammatory cells, endothelial cells and fibroblasts, which can either inhibit or promote tumor growth. Consequently, therapeutic targeting of the tumor stroma is increasingly recognized as an important tool to fight cancer. Two particularly important processes that contribute to the pathology of most types of tumors are angiogenesis and inflammation. In order to target these processes specifically and efficiently, it is fundamental to identify and understand the factors and signaling pathways involved. This thesis initially describes the multiple functions of the small heat shock protein αB-crystallin in the tumor microenvironment. αB-crystallin was first identified in a screen of proteins specifically up-regulated in endothelial cells forming vessel-like structures. We found that αB-crystallin is expressed in a subset of tumor vessels and promotes angiogenesis by inhibiting endothelial apoptosis, suggesting that targeting of αB-crystallin might inhibit angiogenesis and thereby decrease tumor growth. However, we also discovered an important role of αB-crystallin in regulation of inflammatory processes. We show that αB-crystallin increases the surface levels of E-selectin, an important leukocyte-endothelial adhesion molecule. Thereby, αB-crystallin may alter leukocyte recruitment to inflamed tissues such as the tumor stroma. In addition, we found that αB-crystallin is expressed in immature myeloid cells that accumulate in the periphery and at the tumor site during tumor development. Importantly, lack of αB-crystallin resulted in increased accumulation of immature myeloid cells, which might increase tumor associated inflammation. Finally, through combining laser microdissection of vessels from human tissue and microarray analysis, we identified a gene expression signature specifically associated with vessels in high grade glioma. Blood vessels in malignant glioma are highly abnormal and contribute to the pathology of the disease. Thus, knowledge about the molecular set-up of these vessels might contribute to the development of future vascular normalizing treatments.

stroma

glioma

alphaB-crystallin

HSPB5

cryab

myeloid cells

Morphology, cell biology, pathology

Morfologi, cellbiologi, patologi

Cell and molecular biology

Cell- och molekylärbiologi

Identification of the Binding Partners for HspB2 and CryAB Reveals Myofibril and Mitochondrial Protein Interactions and Non-Redundant Roles for Small Heat Shock Proteins

Langston, Kelsey Murphey

12 December 2013

Small Heat Shock Proteins (sHSP) are molecular chaperones that play protective roles in cell survival and have been shown to possess chaperone activity. As such, mutations in this family of proteins result in a wide variety of diseases from cancers to cardiomyopathies. The sHSPs Beta-2 (HspB2) and alpha-beta crystalline (CryAB) are two of the ten human sHSPs and are both expressed in cardiac and skeletal muscle cells. A heart that cannot properly recover or defend against stressors such as extreme heat or cold, oxidative/reductive stress, and heavy metal-induced stress will constantly struggle to maintain efficient function. Accordingly, CryAB is required for myofibril recovery from ischemia/reperfusion (I/R) and HspB2 is required I/R recovery as well as efficient cardiac ATP production. Despite these critical roles, little is known about the molecular function of these chaperones. We have identified over two hundred HspB2-binding partners through both yeast two-hybrid and copurification approaches, including interactions with myofibril and mitochondrial proteins. There is remarkable overlap between the two approaches (80%) suggesting a high confidence level in our findings. The sHSP, CryAB, only binds a subset of the HspB2 interactome, showing that the HspB2 interactome is specific to HspB2 and supporting non-redundant roles for sHSPs. We have confirmed a subset of these binding partners as HspB2 clients via in vitro chaperone activity assays. In addition, comparing the binding patterns and activity of sHSP variants in comparison to wild type can help to elucidate how variants participate in causing disease. Accordingly, we have used Y2H and in vitro chaperone activity assays to compare the disease-associated human variants R120GCryAB and A177PHspB2 to wild type and have identified differences in binding and chaperone function. These results not only provide the first molecular evidence for non-redundancy of the sHSPs, but provides a useful resource for the study of sHSPs in mitochondrial and myofibril function.

small heat shock proteins (sHSP)

HspB2 (MKBP)

HspB5 (CryAB)

R120G

A177P

molecular chaperones

myocardial maintenance strategies

mitochondria

proteostasis

Microbiology