Functional and Mechanistic Insight into the Role of ATG9A in Autophagy

Weerasekara, Vajira Kaushalya

01 January 2017

The bulk degradative process of macroautophagy requires the dynamic growth of autophagosomes, which carry cellular contents to the lysosome for recycling. Atg9A, a multi-pass transmembrane protein, is an apical regulator of autophagosome growth, yet its regulatory mechanism remains unclear. Our work suggests that hypoxia (low glucose and oxygen) triggers a rearrangement of the small adapter protein 14-3-3ζ interactome. Our data suggest that the localization of mammalian Atg9A to autophagosomes requires phosphorylation on the C terminus of Atg9A at S761, which creates a 14-3-3z docking site. Under basal conditions, this phosphorylation is maintained at a low level and is dependent on both ULK1 and AMPK. However, upon induction of hypoxic stress, activated AMPK bypasses the requirement for ULK1 and mediates S761 phosphorylation directly, resulting in an increase in 14-3-3z interactions, recruitment of Atg9A to LC3-positive autophagosomes, and enhanced autophagosome production. These observations suggested to us that long unstructured C-terminus of Atg9A may be a site of protein docking and regulation. We used BioID, along with conventional interactomics, to map the C- and N-terminal proximity-based interactions of Atg9A. We identified a network of Atg9A C-terminal interactions that include members of the ULK1 complex. Using gel filtration, we find that Atg9A co-immunoprecipitates with the ULK1 complex in high molecular weight fractions. Moreover, phosphorylation of the Atg9A C-terminus at S761 occurs within the ULK1 complex under nutrient-replete conditions, while hypoxia triggers a redistribution of phosphorylated Atg9A to low molecular weight fractions. Probing these relationships further, we find that Atg13, a component of the ULK1 complex, directly interacts with Atg9A and is required for Atg9A C-terminal phosphorylation. Furthermore, a non-phosphorylatable mutant of Atg9A (S761A) accumulates with Atg13 in high molecular weight complexes. Together, these data suggest that Atg13 recruits Atg9A to the ULK1 complex at the phagophore assemble site (PAS) and that S761 phosphorylation triggers Atg9A retrieval from the PAS

Autophagy

ATG9A

14-3-3ζ

AMPK

ULK1

Cancer

Chemoresistance

Chemistry

14-3-3ζ Regulation of Metastasis Through Mediation of Liprin-α and Liprin-β

Hynes, Rachel

01 March 2016

Cancer is a set of varied and diverse diseases that share common characteristics, such as active proliferation, increased replicative potential, and tissue invasion or metastasis. One protein, 14-3-3ζ, is shown to be upregulated in a number of different cancers and also correlates with poor patient prognosis, recurrence, and mortality. This protein comes from a family of adapter proteins known for their scaffolding ability, pro- and anti-oncogenic capabilities, and affinity for phosphorylated substrates. It has been shown previously to participate in cancer progression, subversion of apoptosis, and to increase chemoresistance. Herein we will discuss the ability of 14-3-3ζ to promote distant-site metastasis and we propose that it does so through a variety of different mechanisms including the MAPK signaling cascade, HER2/ErbB2 pathway, and by mediation of cell adhesion through regulation of LAR. Liprin-β was identified as a novel 14-3-3ζ interactor in a mass spectrometry-based interactomics analysis. 14-3-3ζ was found to co-immunoprecipitate with both Liprin-α and Liprin-β. We will discuss the identification and mutation of putative 14-3-3ζ binding sites on both Liprins, the effect these have on the binding of both Liprins to 14-3-3ζ and of Liprin-α to LAR, and the possible downstream consequences of these interactions. The results described herein are inconclusive due in part to our inability to obtain a reliable Liprin-β pulldown and in part our inability to identify the 14-3-3ζ-binding sites on Liprin-α and Liprin-β. The concluding chapter contains a discussion of the possible future directions, including the creation of further Liprin mutants as well as fluorescent imaging of LAR localization and focal adhesion turnover.

14-3-3ζ

Liprin

metastasis

breast cancer

Biochemistry

Chemistry

14-3-3ζ overexpression improves tolerance to acute and chronic cold exposure in male mice

Diallo, Kadidia

08 1900

La thermogenèse adaptative est un mécanisme de production de chaleur médié par les adipocytes bruns. En réponse au froid, ou à un stimulus adrénergique, les adipocytes blancs peuvent être convertis en adipocytes beiges lors d’un processus que l’on nomme le « beiging ». Contrairement aux adipocytes blancs, les adipocytes beiges et bruns expriment des taux élevés de la protéine de découplage 1 (UCP1) et dissipent l'énergie sous forme de chaleur grâce à l'oxydation des lipides. Il a été démontré chez les rongeurs que l’activation des adipocytes bruns et beiges entraîne une réduction significative du poids corporel et l’activation de ces adipocytes chez l’humain semble être un traitement prometteur contre l’obésité et le diabète. Nous avons précédemment identifié un rôle essentiel de la protéine d’échafaudage 14-3-3ζ dans l'adipogenèse, mais son rôle dans d'autres processus adipocytaires reste incertain. Une des premières fonctions identifiées de la 14-3-3ζ est sa capacité à réguler l'activité enzymatique de la tyrosine hydroxylase, indispensable à la production de norépinephrine pour la thermogenèse. Notre étude vise donc à déterminer si la 14-3-3ζ influence le développement et la fonction des adipocytes beiges et bruns. Nos données montrent que la délétion d’un allèle du gène de la 14-3-3ζ n’affecte pas la tolérance au froid aiguë. Comparées aux souris de type sauvage (WT), les souris transgéniques mâles surexprimant la 14-3-3ζ (TAP) ont une meilleure tolérance au froid aiguë (3 heures, 4 °C) et chronique (3 jours, 4 °C). On observe chez les TAP une augmentation du beiging due à une élévation significative de l'ARNm et de la protéine UCP1 dans le tissu adipeux blanc inguinal (iWAT). Par ailleurs, les souris TAP présentent également une réduction significative de la conductance thermique lors d’exposition au froid leur permettant de mieux conserver la chaleur. Collectivement, nos résultats soulignent le rôle novateur de la 14-3-3ζ dans le beiging et nous permettent de mieux comprendre comment la thermogenèse adaptative est régulée. / Adaptive thermogenesis is a mechanism of heat production primarily mediated by brown fat. In some instances, cold exposure or adrenergic stimuli can convert white adipocytes into brown-like or beige adipocytes during a process termed “beiging”. Both beige and brown adipocytes express higher levels of uncoupling protein 1 (UCP1) and can release energy in the form of heat following lipid oxidation. The activation of these thermogenic adipocytes increases energy expenditure to reduce body weight in rodents, and it has been postulated to be a promising therapy for the treatment of obesity and diabetes. We previously identified an essential role of the molecular scaffold, 14-3-3ζ, in adipogenesis, but its roles in other adipocyte processes is uncertain. An early identified function of 14-3-3 was its ability to regulate the enzymatic activity of tyrosine hydroxylase, which is indispensable in the production of norepinephrine for thermogenesis. Thus, our study aims to investigate whether 14-3-3ζ influences the development and function of beige and brown adipocytes. We report here that one allele deletion of the gene of 14-3-3ζ did not affect acute cold tolerance. On the other hand, transgenic overexpression of 14-3-3ζ in male mice (TAP) improves cold tolerance due to enhanced beiging with a remarkable increase in Ucp1 mRNA and protein in inguinal white adipose tissue (iWAT). Interestingly, beiging is increased in the TAP mice without any changes in sensitivity to beta-adrenergic stimuli, sympathetic innervation, or norepinephrine content being detected between WT and TAP mice. TAP mice also displayed significantly lower thermal conductance decreasing heat loss during the chronic cold challenge. Collectively, our results point to a novel role of 14-3-3ζ in beiging and increases our understanding of how adaptive thermogenesis is regulated.

14-3-3ζ

Beiging

Browning

Protéines 14-3-3

Thermogenèse adaptative

Adipocytes bruns.

Adipocytes beiges

Adaptive thermogenesis

Brown adipocytes

Beige adipocytes

14-3-3 proteins