Dissecting the impact of macrophage migration inhibitory factor (MIF) on host immune response

Park, Myeongseon

16 October 2018

Macrophage migration inhibitory factor (MIF) has been implicated in mediating both innate and adaptive immune responses in inflammatory and infectious diseases. The sequence and structure of MIF is highly conserved across the avian phylogeny, which underlies high sequence homology and functional similarities between turkey and chicken MIFs. Turkey MIF (TkMIF) inhibited cell migration and promoted cell proliferation with production of inflammatory mediators, comparable to the biological properties of chicken MIF (ChMIF), thus indicating the biological cross-reactivity between turkey and chicken MIFs. This study identified the cell surface receptor(s) that could bind ChMIF and the biological roles triggered by such interactions. In addition to CD74, a previously identified receptor, CXCR4 also interacts with ChMIF. Moreover, the formation of receptor complexes was shown between CXCR4 and CD74. MIF signaling through CXCR4 and CD74 led to cell chemotaxis and proliferation activity as well as intracellular calcium influx. Intriguingly, Eimeria MIF (EMIF), a homologue secreted following parasitic infection, also interacted with CD74 leading to comparable biological functions to those of ChMIF. Given such observations, we hypothesized that CXCR4 and CD74 are receptors for ChMIF leading to the functional consequences similarly manifested by EMIF interaction with the corresponding receptors. EMIF, predominantly secreted from the invasive merozoite stage, may help the parasite exploit the host immune response by interacting with common ChMIF receptors. This may lead to functional mimicry thus provoking the question of whether EMIF would modulate the biological functions of ChMIF to manipulate the host defense that allows more efficient invasion of the host. To evaluate this concept, a transgenic E. tenella lacking MIF was generated by in vivo passage of E. tenella transfected with a CRISPR plasmid targeting EMIF. Although not fully disrupted, reduction of EMIF expression was observed in the transgenic E. tenella itself as well as in inoculated cells, which resulted in enhanced survival of host cells. Herein, we achieved a better characterization of the functional roles of both avian and parasite MIFs underlying the interaction with common host receptors, along with the essential role of parasite MIF promoting host cell death during parasitic infection. / PHD / When animals get infected or injured, their immune system senses invading pathogens or damaged tissues as danger signals, which often elicits the production of inflammatory mediators. These are chemical messengers secreted mostly by immune cells that initiate cellular communication and infiltration of immune cells to the infection/damaged site leading to inflammatory responses to eliminate the infectious agents and repair damaged tissues. Among many inflammatory mediators, macrophage migration inhibitory factor (MIF) is involved in inflammatory and immune response by regulating cell migration. Interestingly, MIF is secreted by Eimeria parasites (that cause the costly coccidiosis disease in poultry) as well as by chickens (host animal) after infection with this pathogen. Toward a better understanding of the impacts of both avian and parasite MIFs on the host immune response, three specific studies were completed. First, MIF displayed high degree of gene sequence identity and functional similarity between chicken and turkey, supporting the evolutionarily conservation of MIF across birds. The second study identified the MIF receptors and their complexes, which engage in the biological functions of chicken MIF. Through binding to these cell surface receptors, chicken MIF can regulate cell migration and proliferation with calcium release. Intriguingly, Eimeria MIF secreted after parasitic infection is able to bind the same receptors leading to comparable biological functions to those of chicken MIF. Lastly, the role of Eimeria MIF was further evaluated by disrupting its gene in the parasite. Although not fully disrupted in the transgenic parasites, its expression was decreased resulting in enhanced survival of host cells, thus suggesting a deleterious effect of Eimeria MIF on the host, as well as its potential as a therapeutic target to control coccidiosis in poultry.

MIF

chicken

Eimeria

CXCR4

CD74

CRISPR/Cas9

Targeting the MIF-CD74 axis to overcome resistance to tyrosine kinase inhibitors in lung cancer

Lee, Meghan

01 March 2024

Development of tyrosine kinase inhibitors (TKIs) against oncogenic drivers has significantly improved survival of patients with oncogene-mutated non-small cell lung cancer (NSCLC). However, acquired resistance to TKIs emerges over time in essentially all patients who initially respond. Recent evidence suggests that drug-tolerant persister (DTP) cells, which survive and adapt to targeted therapies during an early phase of treatment, play an important role in the emergence of drug resistance. A previous study reported that cluster of differentiation 74 (CD74) expression is upregulated in epidermal growth factor receptor (EGFR)-mutated lung cancer after treatment with EGFR-TKIs and that CD74 can be one of the DTP cell markers. However, both the mechanism underlying CD74 expression and the role of CD74 in DTP cells remain unclear. In the current study, an attempt was made to identify the mechanism using cell culture systems and transgenic mouse models. The results confirmed CD74 upregulation at the messenger RNA (mRNA) level after treatments with TKIs in various oncogene-mutated cell lines, including those with EGFR mutations, ROS1 fusions, and ALK fusions. The class II transactivator (CIITA), upstream of CD74, and tumor necrosis factor (TNF)-α expression were induced by treatments with TKIs in tumor cells, leading to an increase in CD74 expression. In addition, the results showed that treatments with TKIs enhance the autocrine secretion of macrophage migration inhibitory factor (MIF), a ligand of CD74, from tumor cells. This implied that autocrine stimulation of CD74 signaling blocks apoptosis and causes emergence of DTP cells. To examine whether CD74 plays an important role in the emergence of resistance to TKIs in vivo, experiments were completed in which lung-specific EGFR-L858R-T790M transgenic mice were crossed with Cd74 knockout mice. The results showed that complete deletion of CD74 overcomes or delays resistance to TKIs. Taken together, the results of this study suggest that the MIF-CD74 axis can be a novel target to overcome resistance in driver-mutated NSCLC. / 2026-02-28T00:00:00Z

Oncology

CD74

Lung cancer

MIF

Tyrosine kinase inhibitors

Cell migration and antigen uptake are two antagonistic functions that are coupled by Myosin II in dendritic cells / La migration cellulaire et la capture d'antigènes sont des fonctions antagonistes couplées par la Myosine II dans les cellules dendritiques

Chabaud, Mélanie

27 June 2014

Les cellules dendritiques (DCs) patrouillent les tissus périphériques à la recherche de dangers potentiels en se déplaçant à travers les tissus et en incorporant de grande quantité de matériel extracellulaire. Cet événement précoce de la réponse immunitaire adaptative est susceptible de déterminer l'amplitude et la qualité de l'activation des lymphocytes T et B. De ce fait, les DCs pourraient avoir besoin d'orchestrer leur motilité et leur fonction de capture des antigènes afin d'initier un réponse immunitaire efficace et adaptée. Afin d'étudier les mécanismes responsables de l'optimisation de l'échantillonnage des tissus par les DCs, nous avons suivi leur migration et leur capacité à capturer des antigènes dans des chambres micro-fluidiques contenant des canaux étroits qui permettent de reproduire l'espace confiné des tissus périphériques. De manière surprenante, nous avons découvert que la migration des DCs et leur aptitude à accumuler des antigènes sont des fonctions antagonistes et dépendent de l'activité du moteur moléculaire Myosine II. Nous avons observé que les DCs se déplacent en alternant des phases rapides au cours desquelles la Myosine II est distribuée de manière asymétrique à l'arrière des cellules, et des phases plus lentes pendant lesquelles la Myosine II est enrichie à l'avant. Les enrichissements transitoires de Myosine II à l'avant des DCs dépendent de l'association de la Myosine II avec la chaîne invariante associée au CMH-II (Ii). Ces évenements favorisent l'absorption d'antigènes et leur transport dans les compartiments endolysosomaux. Des expériences menées avec une pince optique nous ont permis de montrer que l'activité de la Myosine II à l'avant des cellules génère des forces mécaniques qui induisent le transport des vésicules vers l'intérieur de la cellule, probablement en modulant le flux rétrograde d'actine. Ainsi, au cours de cette thèse, nous avons montré que la Myosine II était nécessaire à la fois pour la migration cellulaire et la capture d'antigènes, établissant un mécanisme moléculaire qui permet de coordonner ces deux processus dans le temps et l'espace. Nous proposons que l'alternance de phases de haute mobilité et de phases d'arrêt associées à la capture d'antigènes confère aux DCs une stratégie de recherche intermittente qui leur permettrait d'optimiser la surveillance des tissus périphériques. / Dendritic cells (DCs) patrol peripheral tissues in search for potential dangers by actively crawling and internalizing extracellular materiel. This initial event of an adaptive immune response is likely to determine the magnitude and quality of T cell and B cell immunity. Therefore, DCs might need to tightly orchestrate their migration and their antigen uptake function in order to mount an efficient and adapted immune response. To investigate the mechanisms responsible for the optimization of tissues sampling by DCs, we monitored their migration and their ability to capture antigens in micro-fluidic chambers containing narrow channels that mimic the confined space of peripheral tissues. Surprisingly, we found that cell migration and antigen accumulation in endolysosomes are antagonistic, both relying on the activity of the motor protein Myosin II. We observed that DCs alternate between phases of fast motility during which Myosin II is asymmetrically distributed at the cell rear, and phases of slow motility during which Myosin is enriched at the cell front. Transient Myosin II enrichments at the leading edge depends on its association with the MHC-II associated Invariant Chain (Ii). These events promote antigen uptake and arrival in endolysosomal compartments. Using optical tweezers, we further showed that Myosin II activity at the leading edge generates mechanical forces that drive vesicles transport toward the cell body probably through the modulation of F-actin retrograde flow. Thus, during my PhD, we have shown that Myosin II is required for both migration and antigen capture, providing a molecular mechanism to couple these two processes and allow their coordination in time and space. We propose that alternation between phases of fast motility and phases of low motility associated with efficient antigen capture imposes an intermittent search behavior on DCs, which might be optimal for environment patrolling.

Migration cellulaire

Macropinocytose

Myosine II

Chaine Invariante (CD74)

Trafic endocytique

Capture d'antigènes

Cellules dendritiques

Cell Migration

Macropinocytosis

Myosin II

Invariant Chain (CD74)

Endocytic trafficking

Antigen capture

Dendritic cells

571.964 5

Impact de l’expression de l’isoforme p35 de la chaîne invariante humaine chez des souris déficientes en CD74 endogène

Genève, Laetitia G.

03 1900

La chaîne invariante (Ii ; CD74) est une protéine membranaire de type II qui joue un rôle majeur dans la présentation antigénique. Dans le réticulum endoplasmique (RE), Ii favorise l’assemblage du CMH II et prévient la liaison indésirable de polypeptides. Grâce à son motif di-leucine, la chaîne invariante cible le CMH II dans les endosomes. Une fois dans ces compartiments acides, Ii est dégradé, permettant la liaison de peptides de forte affinité qui seront ensuite présentés aux cellules T CD4+. Chez les souris déficientes en Ii murin (mIi), le CMH II présente une conformation non compacte typique des molécules vides ou liées faiblement à un peptide. Le transport du CMH II est aberrant ce qui conduit à une réduction de son expression en surface ainsi qu’à un défaut de présentation antigénique. De plus, Ii diversifie le répertoire de peptides et assure la sélection thymique des cellules T CD4+. Enfin, il a un rôle dans la maturation des cellules B et les souris déficientes en Ii présentent des nombres réduits de cellules B matures folliculaires (FO). L’isoforme mineure humaine p35 (Iip35) n’existe pas chez la souris et possède une extension cytoplasmique de 16 acides aminés contenant un motif R-x-R de rétention dans le RE. La sortie du RE est conditionnelle à la liaison du CMH II qui permet de masquer le motif de rétention. Iip35 agit comme dominant et impose la rétention aux autres isoformes d’Ii. Cependant, le rôle physiologique du motif R-x-R et, plus globalement, celui d’Iip35, demeurent nébuleux. Pour mieux cerner la fonction d’Iip35, nous avons généré des souris transgéniques (Tg) exprimant l’isoforme humaine Iip35 et avons analysé la conformation et le trafic du CMH II, la sélection thymique et la maturation des cellules B ainsi que la présentation antigénique. Nos résultats ont démontré qu’Iip35 favorise l’assemblage du CMH II dans le RE. Il induit également une conformation compacte du CMH II et augmente l’expression du CMH II en surface. De plus, Iip35 cible le CMH II dans les endosomes où un peptide de forte affinité se lie dans la niche peptidique. Par ailleurs, Iip35 diversifie le répertoire de peptides et rétablit totalement la sélection des cellules T CD4+ ainsi que le niveau d’expression du TCR de ces dernières. Iip35 restaure également la présentation antigénique de l’ovalbumine dont la présentation requiert l’expression d’Ii. Par contre, Iip35 rétablit la présentation des superantigènes mais à un niveau moindre que celui des souris sauvages. Ensuite, Iip35 permet le rétablissement de la sélection des cellules iNKT démontrant qu’il assiste la présentation des lipides par les molécules CD1d. Enfin, les résultats ont démontré qu’Iip35 restaure le développement des cellules B matures folliculaires (FO) mais pas celui des cellules B de la zone marginale. Ceci suggère qu’Iip35 est capable d’induire le développement des cellules FO sans stimulation préalable par le MIF (macrophage migration inhibitory factor). Ainsi, l’ensemble de ces résultats démontre qu’Iip35 est fonctionnel et assure la majorité des fonctions d’Ii. Cependant, Iip35 ne remplace pas mIi endogène concernant la maturation des cellules B MZ suggérant qu’il pourrait avoir un rôle de régulateur. / The invariant chain (Ii; CD74) is a type II membrane protein which plays a key role in antigen presentation as well as acting as a receptor for the cytokine MIF (macrophage migration inhibitory factor). In the endoplasmic reticulum (ER), Ii assists the folding of MHC II and prevents the loading of nascent polypeptides in the peptide-binding groove. Di-leucine-like motifs contained in the Ii cytoplasmic tail target the MHC II-Ii complexes in the endocytic pathway. Once in low pH-endosomes, Ii is degraded allowing the binding of a high affinity peptide which is then presented on cell surface to CD4+ T cells. In Ii deficient mice, MHC II displays a “floppy” conformation typical of empty molecules or is loosely bound with peptides. The transport is aberrant leading to decreased surface expression of MHC II and defective antigenic presentation. Also, the lack of Ii restricts the peptide repertoire and impairs thymic selection of CD4+ T cells. Moreover, Ii regulates B cells maturation and Ii deficient mice display reduced numbers of mature follicular B cells (FO). The human minor p35 isoform (Iip35) does not exist in mice and displays a 16 amino acids N-terminal cytoplasmic extension containing a di-arginine (R-x-R) motif causing ER retention and acting as dominant in heterotrimeric complexes with Iip33. Upon binding to MHC II, the retention motif is masked, which allows the complexes to egress from the ER. The physiological role of the R-x-R motif is poorly understood. To shed light on Iip35 function, we generated transgenic mice expressing Iip35 and analyzed the conformation and traffic of MHC II, the thymic selection and the development of B cells as well as the antigenic presentation. Our results showed that Iip35 generates an MHC II in the right conformation and increases MHC II surface expression. Also, Iip35 targets MHC II into endosomes where high affinity peptides bind to the groove. We also showed that Iip35 diversifies the peptide repertoire and fully restores thymic selection of CD4+ T cells as well as the TCR levels on these cells. Then, Iip35 ensures presentation of the Ii-dependent antigen ovalbumin but does not totally rescue the presentation of superantigens. Interestingly, thymic selection of the iNKT cells is fully restored showing that Iip35 assists with lipids presentation by CD1d. Finally, Iip35 allows B cells to develope into FO B cells but does not support marginal zone (MZ) B cells maturation. This result suggests that MIF stimulation is not a prerequisite for FO B cells development. Altogether, these results showed that Iip35 is functional and has most of the CD74 functions. However, it cannot replace the endogenous Ii regarding the MZ B cells maturation suggesting that Iip35 could have regulatory functions by modulating the development of some cells.

Iip35

CD74

Chaîne invariante

Présentation antigénique

CMH II

Souris transgéniques

Motif R-x-R

MHC II

Antigenic presentation

Invariant chain