The Role of Lipids in Cellular Architecture and Function

Lopes Sampaio, Julio

09 July 2010

All cells are delimited by membranes that protect the cell from the surrounding environment. In eukaryotic cells the same principle applies at subcellular level where membranes delimit functional cell organelles. The membrane structure, properties and function are defined in part by their lipid composition. Lipidomics is the large‐scale study of pathways and networks of cellular lipids in biological systems. It involves the identification and quantitation of cellular lipid molecular species and their interactions with other lipids, proteins, and other metabolites. Lipidomics has been greatly facilitated by recent advances in ionization technology and mass spectrometric capabilities which have simplified the sample processing prior to analysis, giving rise to shotgun lipidomics. Shotgun lipidomics is fast, highly sensitive, and can identify hundreds of lipids missed by other methods. However, Glycosphingolipids are an important lipid family that was out of the scope of shotgun lipidomics due to the lack of suitable analytical tools. The aim of my thesis was two‐fold. The first aim was the establishment of Glycosphingolipid identification and quantification by shotgun approach. This allowed us to perform lipidomic studies with unprecedented comprehensiveness (~300 lipid species from 15 different lipid classes) from low sample amounts and with minimal sample processing. The second was the application of this technology in studies of the role of lipids in several processes like vesicular carrier formation, cell polarization, protein delivery to the plasma membrane and viral budding. This work resulted in several findings. We found that there is sorting of sphingolipids and sterols into plasma membrane targeted vesicular carriers in budding yeast. When kidney cells change from a mesenchymal to an epithelial morphology there is a profound remodeling of their lipidome, with the synthesis of longer, more saturated, more hydroxylated, and more glycosylated sphingolipids. When these sphingolipids and sterols are depleted in epithelial cells, the apical transport in epithelial cells is impaired. These data strongly support the idea that lipid rafts play an important role in sorting and delivery of lipid and protein cargo to the plasma membrane. Finally, we found that the envelopes of vesicular stomatitis virus and Semliki forest virus assert little specificity in the incorporation of lipids from the plasma membrane. This weak specificity seems to be related to a combination of virus lipid bilayer asymmetry and curvature.

info:eu-repo/classification/ddc/570

ddc:570

Mechanismy ustavení a udržení polarity PIN přenašečů v Arabidopsis / Mechanisms of establishment and maintenance of PIN polarity in Arabidopsis

Glanc, Matouš

January 2019

Cell polarity is a key concept in plant biology. The subcellular localization of Pin- formed (PIN) auxin efflux carriers in the root of "#$%&'()*&* is remarkably asymmetrical, making PINs prominent markers to study cell polarity. In spite of its developmental importance and two decades of research, the molecular basis of PIN polarity remains largely unknown. In this thesis, I employed advanced transgenic and fluorescence microscopy approaches to gain insight into several aspects of PIN polarity regulation. I participated in establishing a novel genetically encoded inhibitor of endocytosis, an invaluable tool for the study of the importance of endocytosis for various cellular processes, including PIN polarity. I demonstrated that apical polarity of PIN2 needs to be re-established after cell division and that this process depends on endocytosis, '+!,(-( protein secretion and the action of WAG1 and related protein kinases, but not transcytosis, cell-cell signaling or intact cytoskeleton. Finally, I identified the previously unknown role of MAB4/MEL proteins in PIN polarity, which lies in the ability of MAB4/MELs to reduce PIN lateral diffusion and thus contribute to PIN polarity maintenance. My results, besides broadening current understanding of PIN polarity regulation, identify mechanisms that...

Crumbs Affects Protein Dynamics In Anterior Regions Of The Developing Drosophila Embryo

Knust, Elisabeth, Firmino, João, Tinevez, Jean-Yves

18 January 2016

Maintenance of apico-basal polarity is essential for epithelial integrity and requires particular reinforcement during tissue morphogenesis, when cells are reorganised, undergo shape changes and remodel their junctions. It is well established that epithelial integrity during morphogenetic processes depends on the dynamic exchange of adherens junction components, but our knowledge on the dynamics of other proteins and their dynamics during these processes is still limited. The early Drosophila embryo is an ideal system to study membrane dynamics during morphogenesis. Here, morphogenetic activities differ along the anterior-posterior axis, with the extending germband showing a high degree of epithelial remodelling. We developed a Fluorescence Recovery After Photobleaching (FRAP) assay with a higher temporal resolution, which allowed the distinction between a fast and a slow component of recovery of membrane proteins during the germband extension stage. We show for the first time that the recovery kinetics of a general membrane marker, SpiderGFP, differs in the anterior and posterior parts of the embryo, which correlates well with the different morphogenetic activities of the respective embryonic regions. Interestingly, absence of crumbs, a polarity regulator essential for epithelial integrity in the Drosophila embryo, decreases the fast component of SpiderGFP and of the apical marker Stranded at Second-Venus specifically in the anterior region. We suggest that the defects in kinetics observed in crumbs mutant embryos are the first signs of tissue instability in this region, explaining the earlier breakdown of the head epidermis in comparison to that of the trunk, and that diffusion in the plasma membrane is affected by the absence of Crumbs.

Zellmembranen

Embryonen

Membranproteine

Embryos

Cell membranes

Membrane proteins

Drosophila melanogaster

Cell polarity

Curve fitting

Integral membrane proteins

ddc:610

rvk:XA 10000

Phenotypic characterisation of the C. elegans latrophilin homolog, lat-1

Mestek, Lamia

January 2011

G proteins coupled receptors (GPCRs) play essential developmental roles with functions in all of the immune, olfactory sensory systems amongst other systems as well as exhibiting essential roles in the central and peripheral nervous system. GPCRs are also major targets of pharmaceutical drugs currently used to treat a vast number of conditions. Despite their clear importance, the function of many GPCRs is still obscure. Identifying the physiological role of more GPCRs provides a niche for more drugs to be developed and thus more conditions to be treated. The C.elegans lat-1 gene encodes the latrophilin vertebrate homolog; it is a member of the adhesion GPCR family and is structurally related to the flamingo/CELSR, an essential component of planar cell polarity pathway. This study aims to phenotypically characterise lat-1 mutants in C.elegans to provide insights into the physiological role of this important member of adhesion GPCRs. lat-1 mutants exhibit several morphological defects throughout development and during vulva development. Analysing the embryonic development of such mutants also identified an anterior-posterior polarity defect. The results implicate a second evolutionary conserved subfamily of adhesion GPCRs in the control of tissue polarity and morphogenesis.

615.19

Analyse génétique moléculaire du gène de la voie non-canonique Frizzled/Dishevelled PRICKLE1 dans les anomalies du tube neural chez l’humain

Bosoi, Marius Ciprian

08 1900

La voie de la polarité planaire cellulaire (PCP), aussi connue sous le nom de la voie non-canonique du Frizzled/Dishevelled, contrôle le processus morphogénétique de l'extension convergente (CE) qui est essentiel pour la gastrulation et la formation du tube neural pendant l'embryogenèse. La signalisation du PCP a été récemment associée avec des anomalies du tube neural (ATN) dans des modèles animaux et chez l'humain. Prickle1 est une protéine centrale de la voie PCP, exprimée dans la ligne primitive et le mésoderme pendant l'embryogenèse de la souris. La perte ou le gain de fonction de Prickle1 mène à des mouvements de CE fautifs chez le poisson zèbre et la grenouille. PRICKLE1 interagit directement avec deux autres membres de la voie PCP, Dishevelled et Strabismus/Vang. Dans notre étude, nous avons investigué le rôle de PRICKLE1 dans l'étiologie des ATN dans une cohorte de 810 patients par le re-séquençage de son cadre de lecture et des jonctions exon-intron. Le potentiel pathogénique des mutations ainsi identifiées a été évalué par des méthodes bioinformatiques, suivi par une validation fonctionnelle in vivo dans un système poisson zèbre. Nous avons identifié dans notre cohorte un total de 9 nouvelles mutations dont sept: p.Ile69Thr, p.Asn81His, p.Thr275Met, p.Arg682Cys et p.Ser739Phe, p.Val550Met et p.Asp771Asn qui affectent des acides aminés conservés. Ces mutations ont été prédites in silico d’affecter la fonction de la protéine et sont absentes dans une large cohorte de contrôles de même origine ethnique. La co-injection de ces variantes avec le gène prickle1a de type sauvage chez l’embryon de poisson zèbre a démontré qu’une mutation, p.Arg682Cys, modifie dans un sens négatif le phénotype du défaut de la CE produit par pk1 de type sauvage. Notre étude démontre que PK1 peut agir comme facteur prédisposant pour les ATN chez l’humain et élargit encore plus nos connaissances sur le rôle des gènes de la PCP dans la pathogenèse de ces malformations. / The planar cell polarity pathway (PCP) or the non-canonical Frizzled/Dishevelled pathway controls the morphogenetic process of convergent extension (CE) that is essential during embryogenesis for gastrulation and neural tube formation. Recently, PCP signalling was associated with neural tube defects (NTD) in humans and animal models. The core PCP protein, Prickle1, is expressed in the primitive streak and mesoderm during mouse embryogenesis. Both gain and loss of function of Prickle1 cause faulty CE movements in zebrafish and the frog. PRICKLE1 physically interacts with two other core PCP members, Dishevelled and Strabismus/Vang. In the present study we investigated the role of PRICKLE1 in the aetiology of NTDs in a large cohort of 810 patients through resequencing of its open reading frame and exon-intron junctions. The pathogenicity of the identified mutations was assessed through bioinformatics methods followed by a functional validation in a zebrafish system, in vivo. We identified in our cohort a total of nine novel mutations, of which seven affected conserved amino acids: p.Ile69Thr, p.Asn81His, p.Thr275Met, p.Arg682Cys, p.Ser739Phe, p.Val550Met and p.Asp771As. These mutations were predicted to affect the function of the protein in silico and were absent in a large cohort of ethnically-matched controls. Co-injection of these variants with the wild type pk1 in zebrafish oocytes revealed that one mutation, p.Arg682Cys, antagonized the CE phenotype induced by the wild-type zebrafish prickle1a in a dominant fashion. Our study demonstrates that PRICKLE1 can represent a predisposing factor for human NTDs and further expands our knowledge on the role that PCP genes in the pathogenesis of these malformations.

Prickle1

Anomalies du tube neural

Polarité planaire cellulaire

Extension convergente

Poisson zèbre

Neural tube defects

Planar cell polarity

Convergent extension

Zebrafish

The developmental polarity and morphogenesis of a single cell / Développement de la morphogenèse et de la polarité d’une cellule unique

Bonazzi, Daria

06 March 2015

Comment les cellules établissent leurs formes et organisations internes est un problème biologique fondamental. Au cours de cette thèse, j’ai étudié le développement de la forme cellulaire et de la polarité chez la cellule de levure fissipare. Ces études sont fondées sur l’exploration de la façon dont les petites spores symétriques de levures se développent et s’organisent pour briser la symétrie pour la définition de leur tout premier axe de polarité. Dans une première partie, j’ai étudié les couplages entre la mécanique de surface de la paroi cellulaire des spores et la stabilité de domaines de polarité de Cdc42 qui contrôlent les aspects spatio-temporelles de la brisure de symétrie de ces spores. Dans une seconde partie, j’ai étudié les mécanismes par lesquels ces domaines de polarité contrôlent leur taille et l'adapte à la géométrie de la cellule, un processus vraisemblablement pertinents pour comprendre comment des domaines fonctionnels corticaux s’adaptent à la taille des cellules. Globalement, ces nouvelles recherches focalisant sur la façon dont les cellules développent dynamiquement leur forme et polarité de novo, permettent de mettre en évidence des couplages complexes dans la morphogenèse qui ne peuvent pas être testés en regardant les cellules à « l’état stationnaire» ou avec des outils génétiques. / How cells establish their proper shapes and organization is a fundamental biological problem. In this thesis, I investigated the dynamic development of cellular form and polarity in the rod-shape fission yeast cell. These studies are based on monitoring how small symmetric fission yeast spores grow and self-organize to break symmetry for the definition of their very first polarity axis. In a first part, I studied interplays between surface mechanics of the spore cell wall and the stability of Cdc42-based polarity domains which control spatio-temporal aspects of spore symmetry breaking. In a second part, I studied mechanisms by which these polarity domains control their width and adapt it to cell surface geometry, a process likely relevant to understand how functional cortical domains scale to cell size. Overall these novel investigations focusing on how cells dynamically develop their form and polarity de novo highlight complex feedbacks in morphogenesis that cannot be evidenced by looking at cells at “steady state” or with genetics.

Morphogenèse

Levure fissipare

Spore

Brisure de symétrie

Polarité cellulaire

Mécanique cellulaire

Morphogenesis

Fission yeast

Spore

Symmetry breaking

Cell polarity

Cell mechanics

571.6

The developmental polarity and morphogenesis of a single cell / Développement de la morphogenèse et de la polarité d’une cellule unique

Bonazzi, Daria

06 March 2015

Comment les cellules établissent leurs formes et organisations internes est un problème biologique fondamental. Au cours de cette thèse, j’ai étudié le développement de la forme cellulaire et de la polarité chez la cellule de levure fissipare. Ces études sont fondées sur l’exploration de la façon dont les petites spores symétriques de levures se développent et s’organisent pour briser la symétrie pour la définition de leur tout premier axe de polarité. Dans une première partie, j’ai étudié les couplages entre la mécanique de surface de la paroi cellulaire des spores et la stabilité de domaines de polarité de Cdc42 qui contrôlent les aspects spatio-temporelles de la brisure de symétrie de ces spores. Dans une seconde partie, j’ai étudié les mécanismes par lesquels ces domaines de polarité contrôlent leur taille et l'adapte à la géométrie de la cellule, un processus vraisemblablement pertinents pour comprendre comment des domaines fonctionnels corticaux s’adaptent à la taille des cellules. Globalement, ces nouvelles recherches focalisant sur la façon dont les cellules développent dynamiquement leur forme et polarité de novo, permettent de mettre en évidence des couplages complexes dans la morphogenèse qui ne peuvent pas être testés en regardant les cellules à « l’état stationnaire» ou avec des outils génétiques. / How cells establish their proper shapes and organization is a fundamental biological problem. In this thesis, I investigated the dynamic development of cellular form and polarity in the rod-shape fission yeast cell. These studies are based on monitoring how small symmetric fission yeast spores grow and self-organize to break symmetry for the definition of their very first polarity axis. In a first part, I studied interplays between surface mechanics of the spore cell wall and the stability of Cdc42-based polarity domains which control spatio-temporal aspects of spore symmetry breaking. In a second part, I studied mechanisms by which these polarity domains control their width and adapt it to cell surface geometry, a process likely relevant to understand how functional cortical domains scale to cell size. Overall these novel investigations focusing on how cells dynamically develop their form and polarity de novo highlight complex feedbacks in morphogenesis that cannot be evidenced by looking at cells at “steady state” or with genetics.

Morphogenèse

Levure fissipare

Spore

Brisure de symétrie

Polarité cellulaire

Mécanique cellulaire

Morphogenesis

Fission yeast

Spore

Symmetry breaking

Cell polarity

Cell mechanics

571.6

Études génétiques moléculaires du gène de la polarité planaire SCRIBBLE1 chez les anomalies du tube neural

Kharfallah, Fares

05 1900

Les anomalies du tube neural (ATN), incluant l'anencéphalie et le spina-bifida, représentent un groupe de malformations congénitales très fréquentes chez l'homme. Ces anomalies sont causées par un défaut partiel ou complet de la fermeture du tube neurale au cours de l'embryogenèse. Les ATN ont une étiologie complexe et multifactorielle impliquant des facteurs environnementaux et génétiques. La voie de signalisation non-canonique du Frizzled (Fz)/Dishevelled (Dvl) contrôle la polarité cellulaire planaire (PCP) et le processus morphogénétique appelé l’extension convergente qui est essentiel pour la gastrulation et la fermeture du tube neural. Très important, des mutations des gènes de cette voie étaient fortement associées aux ATN chez la souris et l’humain. Scribble est un gène de la voie PCP qui cause une sévère ATN chez la souris Circletail. Notre étude vise à analyser le rôle de SCRIBBLE1 dans les ATN humains par des analyses de séquence de son cadre de lecture et ses jonctions exon-introns. Notre étude comporte 396 patients recrutés au Centre Spina Bifida de l’hôpital Gaslini en Gènes, Italie et 83 patients recrutés au Centre Spina Bifida de l’hôpital Sainte Justine. Les patients sont affectés par plusieurs formes d’ATN. Nous avons identifié neuf mutations rares et non synonymes chez 10 patients, p.Asp93Ala (c. 435G>A), p.Gly145Arg (c. 278A>C), p.Gly263Ser (c. 786C>A), p.Gly469Ser (c. 1405G>A), p.Pro649His (c. 1946C>A), p.Gln808His (c. 2424G>T), p.Val1066Met (c. 3196G>A), p.Arg1150Gln (c. 3480G>A) et p.Thr1422Met (c. 4266C>T). Cinque mutations, p.Gly263Ser, p.Pro649His, p.Gln808His, p.Arg1150Gln, p.Thr1422Met, étaient absentes dans les contrôles analysés et prédites d’être pathogéniques in silico. Cette étude montre que des mutations rares dans SCRIB1 pourraient augmenter le risque des ATN dans une fraction des patients. L’identification des gènes prédisposant aux ATN nous aidera à mieux comprendre les mécanismes pathogéniques impliqués dans ces maladies. / Neural tube defects (NTDs), including anencephaly and spina bifida, represent a group of very common birth defects in humans. These anomalies are caused by a partial or complete failure of neural tube closure during embryogenesis. NTDs have a multifactorial etiology involving environmental and genetic factors. The non-canonical signaling pathway Frizzled (Fz) / Dishevelled (Dvl) controls the planar cell polarity (PCP) and the morphogenetic process called convergent extension (CE) which is essential for gastrulation and neural tube closure. Importantly, mutations in genes of this pathway were strongly associated with NTDs in mice and humans. Scribble is a PCP gene that causes a severe NTD mouse Circletail. Scribble binds to another PCP protein, Stbm / Vang, and they cooperate together for the stability of the PCP pathway. Our study aims at investigating the role of SCRIBBLE1 in human NTDs by sequence analyses of its open reading frame and exon-intron junctions. The cohort included in this study consisted of 396 patients recruited at the Spina Bifida Centre of Gaslini Hospital in Genoa, Italy, and 83 patients recruited at the Spina Bifida Center of the Sainte Justine Hospital, Montreal, Canada. Patients were affected by several forms of NTDs. We identified nine non-synonymous and rare mutations in 10 patients: p.Asp93Ala (c. 435G>A), p.Gly145Arg (c. 278A>C), p.Gly263Ser (c. 786C>A), p.Gly469Ser (c. 1405G>A), p.Pro649His (c. 1946C>A), p.Gln808His (c. 2424G>T), p.Val1066Met (c. 3196G>A), p.Arg1150Gln (c. 3480G>A) and p.Thr1422Met (c. 4266C>T). Five of those mutations, p.Gly263Ser, p.Pro649His, p.Gln808His, p.Arg1150Gln, p.Thr1422Met, were absent in all controls analyzed and were predicted to be pathogenic using bioinformatics. Our study demonstrates that rare mutations in SCRIB1 could predispose to NTDs in a fraction of patients. The identification of genes that predispose to ATN will help us better understand the pathogenic mechanisms involved in these diseases.

SCRIBBLE1

Anomalies du tube neural

Polarité planaire cellulaire

Extension Convergente

Neural tube defects

Planar cell polarity

Convergent Extension

Rôle du cytosquelette d'Actine bactérien MreB dans la motilité cellulaire chez Myxococcus xanthus

Mouhamar, Fabrice

02 November 2011

Myxococcus Xanthus possède un cycle developpemental multicellulaire entièrement sous la dépendance de la capacité des cellules à se déplacer sur des surfaces solides. M. xanthus possède deux systèmes de motilité génétiquement séparé, une motilité Sociale dépendant des pili de Type IV et une motilité Aventurière dont le mécanisme est encore peu compris. Notre hypothèse de travail est que la motilité Aventurière est qu’en des points régulièrement répartis le long du corps cellulaire soient couplés adhésion et traction de ce corps par une interaction entre des moteurs moléculaire et le cytosquelette d’Actine bactérienne MreB. Mon projet est de caractériser la relation qu’il pourrait y avoir entre le cytosquelette et les points d’adhésion durant la motilité. Pour étudier l’implication du cytosquelette MreB durant le mouvement, nous avons utilisé une approche pharmaceutique utilisant l’A22, une drogue permettant la dépolymérisation rapide et spécifique du cytosquelette sans affecter la viabilité des cellules à court terme. De plus j’ai aussi étudier les interactions possible entre MreB et différentes protéines de motilité comme la petite GTPase MglA, qui est connue pour est essentielle au recrutement des machineries de motilité. / Myxococcus xanthus has a multicellular developmental cycle which is dependent on the capacity of the cells to move accross solid surfaces. M. xanthus uses two motility systems: Social motility system is dependent on Type-IV pili, and the Adventurous motility system, the mechanism of which is poorly understood. Our working hypothesis is that Adventurous motility is performed by adhesion points localized along the cell body where a molecular machinery pulls the cell body by interacting with the MreB cytoskeleton. My project aims to characterize the relationship between the adhesion points and the cytoskeleton during movement. To study the involvement of MreB during motility we use A22, a drug known to rapidly and specifically depolymerise in live microscopy assays. Furthermore, I have study also the interactions between MreB and differents proteins like MglA a small GTPase, which we belive is essential for the recruitment of the machineries.

A22

Complexes d'adhésion

Polarité cellulaire

Complexe de motilité

Localisation de protéines

MreB

Cytosquelette bactérien

A22

Adhesion complexes

Cell polarity

Motility clusters

Protein localization

Bacterial cytoskeleton

Identification d’une nouvelle isoforme du gène suppresseur de tumeur LKB1 ayant des propriétés oncogéniques / Identification of A novel isoform of the tumor suppressor gene LKB1 Having oncogenic properties

Dahmani, Rajae

08 October 2014

LKB1 est un gène suppresseur de tumeur qui code une kinase « maitre » dont l’activité contrôle la polarité et la prolifération cellulaire en les coordonnant avec l’état métabolique de la cellule. Ce travail a abouti à l’identification d’une nouvelle isoforme LKB1 appelée ∆N-LKB1 qui est générée par transcription alternative et initiation interne de la traduction de l'ARNm LKB1. La protéine ∆N-LKB1 est délétée de sa partie N-terminale incluant une partie de son domaine kinase. Bien que la protéine N-LKB1 soit catalytiquement inactive, elle potentialise l'effet activateur de la protéine LKB1 sur sa cible principale l’APMK, senseur énergétique de la cellule, via une interaction directe avec le domaine d'auto-inhibition de l’AMPK. En revanche, ∆N-LKB1 interfère négativement avec la capacité de LKB1 à induire la polarité cellulaire. Enfin, en utilisant des approches in vitro et in vivo, nous avons montré que N-LKB1 possède une propriété oncogénique intrinsèque. N-LKB1 est exprimée seule dans la lignée NCI-H460 issue du cancer du poumon. L’inhibition de l’expression de N-LKB1 dans les cellules NCI-H460 induit une diminution de la survie de ces cellules et inhibe leur pouvoir oncogénique quand elles sont greffées dans la souris nude. Nous avons donc identifié une nouvelle isoforme LKB1 qui stimule l’adaptation métabolique LKB1-dépendante, mais qui inhibe la polarité cellulaire contrôlée par LKB1. Le suppresseur de tumeur LKB1 ainsi que l’oncogène N-LKB1 sont codé par le même gène, ce qui peut expliquer certains des effets paradoxaux de LKB1 durant la tumorigenèse. / The LKB1 tumor suppressor gene encodes a master kinase that coordinates the regulation of energetic metabolism, cell growth and cell polarity. We now report the identification of a novel isoform of LKB1 named N-LKB1 that is generated through alternative transcription and internal initiation of translation of the LKB1 mRNA. The N-LKB1 protein lacks the N-terminal region and a portion of the kinase domain. Although N-LKB1 is catalytically inactive, it potentiates the stimulating effect of LKB1 on the AMP-activated protein kinase (AMPK) metabolic sensor through a direct interaction with the regulatory auto-inhibitory domain of AMPK. Contrasting, N-LKB1 negatively interferes with the LKB1 polarizing activity. Finally, combining in vitro and in vivo approaches, we showedthat N-LKB1 has an intrinsic oncogenic property. N-LKB1 is expressed solely in the lung cancer cell line, NCI-H460. Silencing of N-LKB1 decreased survival of NCI-H460 cells and inhibited their tumorigenicity when engrafted in nude mice. In conclusion, we have identified a novel LKB1 isoform that enhances the LKB1-controlled AMPK metabolic activity but inhibits LKB1-induced polarizing activity. Both, the LKB1 tumor suppressor and the oncogene, N-LKB1, are expressed from the same locus and this may account for some of the paradoxical effects of LKB1 during tumorigenesis.

LKB1

AMPK

Énergie cellulaire

Croissance cellulaire

Polarité cellulaire

Muscle squelettique et cardiaque

LKB1

AMPK

Cellular energy

Cell growth

Cell polarity

Skeletal and heart muscles