The Role of Alternative Epidermal Growth Factor Receptor Trafficking in Driving Cancer Progression

Maisel, Sabrina, Maisel, Sabrina

January 2017

The Epidermal Growth Factor Receptor (EGFR) is associated with a variety of cancers, including brain, lung, cervix, renal and breast. It is part of a family of receptors known as the ErbB receptors (ErbB1/EGFR, ErbB2/HER2, ErbB3/HER3, and ErbB4/HER4), transmembrane proteins found on epithelial cells responsible for a multitude of signaling events. In cancers, EGFR is frequently mutated or improperly expressed, upregulated in more than 50 percent of basal-like cancers. Mutations commonly promote constitutive activation or increase receptor recycling. In basal-like breast cancers such as triple negative breast cancer (TNBC), named for the lack of hormone receptors (estrogen and progesterone) and the HER2 receptor, EGFR is highly upregulated and associated with a variety of oncogenic activity, including increased proliferation and migration, and inhibition of cell death. Changes in these pathways are predicated on altered trafficking and activation of EGFR, events driven by variation in stimuli and interacting partners, such as other ErbB family members or oncogenic adaptor proteins such as MUC1, a member of the mucin family. In TNBC, upon stimulus with epidermal growth factor (EGF), EGFR colocalizes with MUC1 in intracellular vesicles distributed throughout the cytoplasm. These intracellular vesicles are associated with early endosomes, as indicated by the presence of early endosome antigen 1 (EEA1). Association with MUC1 prolongs the presence of EGFR in these vesicles, as EGFR's stay is significantly reduced in cells lacking MUC1. Retention in these vesicles by MUC1 inhibits trafficking of EGFR to the lysosome for degradation and is also associated with an increase in EGF-dependent migratory ability. Introduction of late endosome inhibitors (thereby preventing lysosomal targeting) increases migration in the absence of MUC1, the same effect as in the presence of MUC1. Further, inhibition of retrograde trafficking significantly decreases the rate of migration and changes cellular distribution of filopodia corresponding to migratory ability in MUC1-containing cells. Taken together, these data indicate that MUC1 is responsible for altering EGFR trafficking by retaining EGFR in EEA1-positive vesicles for prolonged periods, allowing for increased signal transduction through retrograde trafficking of EGFR and structural reorganization promoting a migratory phenotype. Loss of the polarity protein Llgl1 is associated with alterations in EGFR trafficking, promoting highly diffuse EGFR distribution throughout the cytoplasm versus along basolateral membranes. These changes in trafficking are also associated with increases in AKT and dual-phosphorylated-ERK signal transduction, both downstream targets of activated EGFR. Altering localization of EGFR to other membranes and intracellular vesicles without inducing polarity loss through a point mutation at amino acid 667 was found to also upregulate the AKT pathway. Mislocalization driven by polarity loss or point mutation in the basolateral targeting domain is sufficient to increase migration speeds of non-cancerous epithelial cell lines in vitro. This increased oncogenic activity is likely attributed to increased nuclear localization of the transcription factor TAZ (transcription co-activator with a PDZ-binding domain), whose nuclear translocation is associated with increased stem-like properties such as migration and survival. Together, these data reveal the oncogenic potential caused by alterations in EGFR trafficking that occur when polarity is lost or EGFR is improperly associated with proteins that promote changes to canonical EGFR localization and degradation, such as MUC1.

epidermal growth factor receptor

llgl1

migration

MUC1

Retrograde Trafficking

The potently neutralizing monoclonal antibody 1B7 : its unique epitope, effects on intracellular trafficking, and elicitation upon infection with pertussis

Sutherland, Jamie Nicole

07 December 2010

Disease caused by Bordetella pertussis persists with rates increasing over the past decade in industrialized countries. A hindrance to vaccine development has been the lack of a clear serological correlate of protective immunity. Pertussis toxin (PTx), an AB-type toxin, is one of the bacteria’s major virulence factors and among the lead candidates for potential correlates. Of the numerous monoclonal antibodies (mAbs) binding PTx, the murine IgG2a mAb 1B7 is potently neutralizing in all in vitro assays and in vivo murine models of infection. 1B7 binds an epitope on the enzymatic S1-subunit of PTx with some linear elements but previous work was unable to more precisely define the epitope or determine its exact mechanism of protection. We characterize the epitope bound by 1B7 on PTx-S1 in molecular detail and define energetically important interactions between residues at the interface including six residues on PTx-S1 and six residues on 1B7. Using this information, a model of the 1B7-S1 interaction was developed, indicating a predominantly conformational epitope located on the base of S1 near S4. The location of this epitope is consistent with previous data and is shown to be conserved across several naturally occurring strain variants including PTx-S1A, B, D, and E in addition to the catalytically inactive 9K/129G variant. Using immunofluorescent microscopy, it was determined that 1B7’s unique mode of action lies in its ability to bind to the toxin and co-traffic into target cells. Upon endocytosis, 1B7 protects from PTx intoxication by redirecting its intracellular retrograde trafficking. In order to determine whether antibody responses are differently induced by infection or acellular vaccination, we analyzed sera from 30 adults with confirmed exposure to pertussis and 30 recent vaccinees. Natural infection resulted in significantly higher titers of anti-PTx-S1, 1B7-like, and 11E6-like antibodies, while overall anti-PTx titers were similar to vaccinated samples. We also observed a direct correlation between in vitro protection and the presence of 1B7-like and 11E6-like antibodies. Thus, natural infection elicits higher titers of protective antibodies indicating that the use of detoxified PTx in current acellular vaccines although highly immunogenic results in the elicitation of predominantly non-neutralizing antibodies. / text

Pertussis toxin

Bordetella pertussis

Retrograde trafficking

11E6

Vaccination

Acellular vaccine preparation

Liens fonctionnels entre l'EGFR et P14ARF : contribution à la carcinogenèse pulmonaire / Functional links between EGFR and p14ARF : contribution to lung carcinogenesis

Dayde, Delphine

11 December 2014

L'EGFR est un récepteur transmembranaire à activité tyrosine kinase (TK) qui transduit des signaux de prolifération et de survie cellulaire. Dans les cancers du poumon, son activité est fréquemment dérégulée par surexpression et/ou par mutation au niveau de son domaine TK. Ces mutations sont principalement de deux types (EGFR-L858R et EGFR-Del19) et sont dites activatrices car elles induisent une activation constitutive des signalisations oncogéniques de l'EGFR. Elles sont aussi un facteur prédictif de réponse aux EGFR-TKIs qui inhibent spécifiquement ce récepteur. P14ARF est un suppresseur de tumeur qui restreint la prolifération cellulaire et maintient la stabilité génomique. Nous avons décrit son inactivation dans les cancers du poumon et démontré que son expression freine leur développement. Nos résultats récents montrent que l'expression de p14ARF est inhibée dans une très grande majorité d'adénocarcinomes pulmonaires présentant une mutation activatrice de l'EGFR. Sur la base de ces résultats nous avons émis l'hypothèse que l'inhibition de l'expression de p14ARF contribuerait à l'expansion clonale des tumeurs porteuses d'un EGFR muté. P14ARF pourrait ainsi être un frein à l'activité oncogénique de l'EGFR.Dans différents modèles d'adénocarcinomes pulmonaires exprimant un mutant EGFR-L858R nous montrons que l'expression transitoire de p14ARF active une signalisation pro-apoptotique dépendante de STAT3 et de Bcl2. En retour, l'EGFR inhibe l'expression de p14ARF et bloque ses fonctions pro-apoptotiques. Nous montrons aussi que l'activation de l'EGFR (sauvage ou muté) inhibe l'expression de p14ARF à un niveau transcriptionnel. Ceci implique une translocation nucléaire de l'EGFR contrôlée par les PI3Ks de classe III (Vps34) et la fixation de l'EGFR sur le promoteur de ARF. L'ensemble de ces travaux identifie pour la première fois un lien fonctionnel entre les voies de signalisation de l'EGFR et de p14ARF. Ils mettent en évidence un nouveau mécanisme de progression tumorale par lequel une signalisation nucléaire de l'EGFR inactive le suppresseur de tumeur p14ARF afin de permettre la croissance tumorale. / EGFR is a transmembrane tyrosine kinase (TK) receptor which activates proliferative and survival signals. In lung cancer, its activity is frequently deregulated by overexpression and/or mutation in its TK domain. These mutations are mainly of two types (L858R and Del19) and are called « driver mutations » because they induce constitutive activation of EGFR oncogenic signaling. They also represent a predictive responsive factor to EGFR TKIs that specifically inhibit this receptor. P14ARF is a tumor suppressor that restricts cellular proliferation and maintains genomic stability. We described its inactivation in lung cancer and demonstrated that its expression inhibits their development. Our recent results show that the expression of p14ARF is inhibited in a majority of lung adenocarcinomas expressing an activating EGFR mutation. Based on these results we hypothesized that inhibition of p14ARF expression contributes to clonal expansion of mutated EGFR-bearing tumor. P14ARF could be a break to EGFR oncogenic activity.In different models of lung adenocarcinoma expressing a L858R EGFR mutant we show that transient expression of p14ARF activates a pro-apoptotic STAT3/Bcl-2-dependent signaling pathway. In turn, EGFR inhibits the expression of p14ARF and blocks its pro-apoptotic function. We also show that EGFR (wild type or mutated) activation inhibits the expression of p14ARF at the transcriptional level. This implies a nuclear translocation of EGFR controlled by Class III PI3K (Vps34) and its fixation to the ARF promoter. This work identifies for the first time a functional link between EGFR and p14ARF signaling pathways. They highlight a new mechanism of tumor progression by which a nuclear EGFR signaling inactivates the tumor suppressor p14ARF to allow tumor growth.

EGFR

P14ARF

CBNPC

Tumorigenèse

Transport rétrograde

EGFR

P14ARF

NSCLC

Tumorigenesis

Retrograde trafficking

610

Engineering of the RTB Lectin as a Carrier Platform for Proteins and Antigens

Reidy, Michael James

13 March 2007

The major obstacle many promising drugs struggle to overcome is the barrier imposed by the outer cell membrane. In addition to technologies such as liposomes and cell-penetrating peptides, more attention is being given to the class of proteins known as lectins to deliver therapeutic and antigenic proteins to the interiors of cells. Lectins bind to but do not modify sugars, and provide an efficient route to endocytosis. The galactose/N-acetyl-galactosamine specific lectin ricin B-chain (RTB) is especially attractive in possibly fulfilling a carrier role due to its well-characterized endocytotic trafficking and its efficacy over a wide range of cell types. By producing RTB recombinantly in plants it is possible to create a fully active, non-toxic carrier that does not rely on the processing of large amounts of toxic material (e.g. castor bean). Payload molecules such as small molecules and proteins can be attached to RTB via chemical conjugation at primary amine groups, without the loss of lectin or uptake activities. The biotin/streptavidin interaction and direct genetic fusion of polypeptides also provide efficient mechanisms for the attachment of payload proteins to RTB. An immunoglobulin domain-based scaffolding mechanism bridges modified RTB and payload proteins when co-expressed in Agrobacterium-infiltrated plant leaves. Carrier and payload proteins expressed in plants and E. coli, respectively, and purified independently are not able to assemble into an efficient carrier/payload arrangement. These findings show that plant cells are able to correctly produce the two components of the carrier/payload system and assemble them into an efficient and flexible capture and carry technology. / Ph. D.

adjuvant

lectin-mediated uptake

Immunoglobulin scaffolding

Type II RIP processing

lectin

drug carrier

N. benthamiana

ricin B-chain

capture/carry platform

Ricin

retrograde trafficking

RTB

plant-based bioproduction

antigen carrier