The role of SWAP-70 in cancer metastasis and tumor immunity

Chang, Chao-Yuan

13 November 2023

Cancer metastasis accounts for approximately 90% of all cancer-related deaths; however, the underlying mechanisms remain largely unknown. It has been known proteins that control F-actin dynamics are crucial for cancer metastasis. In this study, we revealed how an F-actin binding protein, Switch-associated protein 70 (SWAP-70), contributes to breast cancer metastasis. Moreover, immunotherapy is a promising approach to treat metastatic cancer cells by enhancing the function of the host immune system against cancer. Our lab has conducted extensive studies on how SWAP-70 regulates the function of several immune cell types, including dendritic cells (DCs), B cells, and mast cells. These cells have been reported to contribute to tumor immunity. Thus, we hypothesized that SWAP-70 plays a role in tumor immunity. To characterize the function of SWAP-70 in metastasis, we generated 4T1, mouse breast cancer, SWAP-70 knockout (KO) cells using Crispr/Cas9 technology. A syngeneic orthotopic model was used to recapitulate clinical disease progression, and the results showed that SWAP-70 led to significant metastasis to the lungs and bones in immunocompetent mice. Several functional assays have revealed that SWAP-70 promotes anchorage-independent growth, cell migration, invasion, and adhesion in 4T1 cells. Biophysical measurements showed that SWAP-70 contributes to cellular mechanics. To investigate how SWAP-70 in host cells affects tumor immunity, SWAP-70 deficient mice were injected with E0771 mouse breast cancer cells to study tumorigenicity. SWAP-70 deficient mice showed delayed primary tumor growth and less distant metastasis. Isolated SWAP-70−/− DCs were impaired in generating CD8 T cell responses pulsed with soluble OVA protein, but not with OVA peptide, suggesting that the antigen uptake, processing, and presentation process in SWAP-70−/− DCs may be diminished. Taken together, our findings describe the potential mechanisms by which the loss of SWAP-70 hinders cancer metastasis and provide several insights into how targeting SWAP-70 could be a potential therapeutic approach to target cancer.

info:eu-repo/classification/ddc/610

ddc:610

Cytoskeletal reorganization in human blood platelets during spreading

Paknikar, Aishwarya Kishore

19 January 2017

No description available.

570

platelets

cytoskeleton

spreading

real-time F-actin and microtubule

Biologie (PPN619462639)

Nanoscale rearrangements in cortical actin filaments at lytic immunological synapses

Saeed, Mezida Bedru

January 2018

Lytic effector function of Natural Killer (NK) cells and CD8+ T cells occurs through discrete and regulated cell biological steps triggered by recognition of diseased cells. Recent studies of the NK cell synapse support the idea that dynamic nanoscale rearrangements in cortical filamentous (F)-actin are a critical cell biological checkpoint for lytic granule access to NK cell membrane. Loss of function mutations in the LYST gene, a well-characterised cause of Chediak- Hegashi syndrome (CHS), result in the formation of giant lysosomal organelles including lytic granules. Here, we report a mismatch between the extent of cortical F-actin remodelling and enlarged lytic granules that limits the functionality of LYST- deficient NK cells in a human model of CHS. Using super-resolution stimulated emission depletion (STED) microscopy we found that LYST-deficient NK cells had nanoscale rearrangements in the organisation of cortical actin filaments that were indistinguishable from control cells- despite a 2.5-fold increase in the size of polarised granules. Importantly, treatment of LYST-deficient NK cells with actin depolymerising drugs increased the formation of small secretory domains at the synapse and restored their ability to lyse target cells. These data establish that sub-synaptic F-actin is the major factor limiting the release of enlarged lytic granules from CHS NK cells, and reveal a novel target for therapeutic interventions. While the importance of cortical actin filaments in NK cell cytotoxicity have been established, its persistence at the early stages of T cell synapse formation is disputed. We studied the organisation of cortical actin filaments in synapses formed by primary human T cells using STED microscopy and detected intact cortical actin filaments in key T cell effector subsets including memory CD8+ T cells as early as 5-minutes post-activation. Quantitative analysis revealed that activation specific rearrangements in cortical actin filaments at both CD4+ and CD8+ T cell synapses serve to increase the space between filaments. Additionally, comparison of cytolytic T cells with freshly isolated and IL-2 activated primary NK cells revealed that rapid maturation of the cortical actin meshwork is a specific feature of CD8+ T cell lytic synapses. Using chemical inhibition of actin nucleators, we show that increased cortical relaxation is mediated primarily by the activity of actin related proteins (Arp) -2/3. Taken together, these data establish the critical requirement for dynamic rearrangements in cortical actin filaments at lytic synapses but underscore cell-specific differences in its regulation.

Identifying Mechanisms Associated with Innate Immunity in Cows Genetically Susceptible to Mastitis

Elliott, Alexandra Alida

01 December 2010

Mastitis, or mammary gland inflammation, causes the greatest loss in profit for dairy producers. Mastitis susceptibility differs among cows due to environmental, physiological, and genetic factors. Prior research identified a genetic marker in a chemokine receptor, CXCR1, associated with mastitis susceptibility and decreased neutrophil migration. Current research seeks to identify reasons behind mastitis susceptibility by validating this model through in vivo challenge with Streptococcus uberis and studying specific mechanisms causing impaired neutrophil migration. Holstein cows with GG (n=19), GC (n=28), and CC (n=20) genotypes at CXCR1+777 were challenged intramammarily with S. uberis strain UT888. After challenge 68% of quarters from GG genotype, 74% from CC genotype and only 47% from GC genotype cows had ≥10 colony forming units/ml S. uberis for at least two sampling time points (P<0.05). However, among infected cows, number of S. uberis, somatic cell count, rectal temperature, milk scores and mammary scores were comparable among genotypes throughout infection. These findings suggest that cows with GC genotypes may be more resistant to S. uberis mastitis, but have similar responses if infected. To better understand the mechanisms associated with disease resistance, migration patterns in neutrophils from cows with different CXCR1+777 genotypes were evaluated. Neutrophils from cows with GG (n=11) and CC (n=11) genotypes were isolated and stimulated with zymosan activated sera (ZAS). Cells were fixed and stained for F-actin and evaluated for F-actin content, distribution, and cell morphology. Neutrophils from CC cows had significantly lower average F-actin polymerization than GG cows v (P=0.05). Directed migration of neutrophils from GG (n=10) and CC (n=10) genotypes was imaged and tracking data was analyzed for individual cells. Cells from GG genotype traveled further on an X axis and had higher X/Y movement towards IL8 compared to CC genotype, meaning they moved more directly towards IL8. Our findings suggest lower F-actin polymerization in combination with lower ability to directly move towards IL8 could impair neutrophil response to infection in cows with a CC genotype and may contribute to increased mastitis susceptibility. Finding what makes certain cows more susceptible to mastitis could lead to strategies aimed at improved prevention and treatment of mastitis.

Mastitis

innate immunity

neutrophil

chemotaxis

CXCR1

F-actin

Cell Biology

Dairy Science

Immunology and Infectious Disease

Immunopathology

In vitro studies of protein interactions on substrate supported artificial membranes

Morick, Daniela

23 January 2013

Da eine Vielzahl von Proteininteraktionen innerhalb zellulärer Organismen an der Grenzfläche zu Membranen stattfindet, ist die Untersuchung dieser Prozesse von gro-ßem wissenschaftlichem Interesse. Ziel dieser Arbeit war es Modellsysteme basierend auf artifiziellen Membranen zu entwickeln, mit deren Hilfe die Untersuchung ausge-wählter Proteininteraktionen ermöglicht werden konnte. Im ersten Abschnitt dieser Arbeit (Kapitel 4-6) wurde ein Biosensorassay basierend auf festköperunterstützten Membranen entwickelt, der die Quantifizierung der Interaktion von C-Polycystin-2 (cPC2) mit seinen Interaktionspartnern C-Polycystin-1 (cPC1) und PIGEA14 mittels der Quarzmikrowaagetechnik ermöglichte. Aufgrund der Tatsache, dass die Affinität von cPC2 zu cPC1 in Anwesenheit von Ca2+ dreifach höher war, wurde eine Ca2+ abhängige Trimerisierung von cPC2 postuliert. Die Unterschiede der ermittelten kinetischen Koeffizienten führten zur Entwicklung eines Bindunsgmodells, welches die dreistufige Adsorption von cPC2 an cPC1 in Abwesenheit bzw. einstufige Adsorption in Anwesenheit von Ca2+ implizierte. Im Falle der Interaktion von cPC2 mit PIGEA14 wurde die Abhänigkeit der cPC2 Bindung von der Pseudophosphorylie-rung des Proteins an Ser812 untersucht. Es wurde festgestellt, dass die Affinität der pseudophosphorylierten Mutante cPC2S812D zu PIGEA14 zweifach niedriger war, als die von cPC2wt. Im zweiten Abschnitt der Arbeit (Kapitel 7 und 8) wurde die spezifische Wechselwir-kung von filamentösem Aktin (F-Aktin) mit festkörperunterstützten und porenüber-spannenden Membranen untersucht. Die kontrollierte Anbindung von F-Aktin in und auf porösen Aluminiumoxidfilmen konnte mit Hilfe verschiedener Funktionalisie-rungsstrategien erzielt werden. Der Einfluss eines F-Aktin Netzwerks auf die Span-nung und viskoelastischen Eigenschaften porenüberspannender Membranen wurde mittels kraftmikroskopischer Studien untersucht. Es wurde nachgewiesen, dass der Einfluss von gebundenem F-Aktin auf die Membranspannung gering war, aber erst durch die F-Aktin Adhäsion viskoelastische Membraneigenschaften induziert wurden.

540

protein-protein interactions

artificial membranes

Polycystin-2

F-actin

Chemie  (PPN62138352X)

Etude in silico du complexe impliquant le domaine central de la Dystrophine, le domaine PDZ de la nNOS, l'Actine filamenteuse et les Phospholipides membranaires. / In silico study of the complexe involving the dystrophin central domain, the PDZ domain of the nNOS, the Filamentous actin and Phospholipides.

Molza, Anne-Elisabeth

24 September 2015

La dystrophine est une très grande protéine codée le gène DMD et située sous la membrane plasmique des fibres musculaires. Elle joue un rôle essentiel dans le maintien de l’intégrité de la cellule musculaire lors des cycles de contraction/relaxation. Cette protéine filamenteuse est composée de quatre domaines structuraux dont le domaine central composé de 24 répétitions homologues à la spectrine. Chaque répétition est organisée en faisceau de trois α-hélices appelé « coiled-coil ». Des mutations du gène DMD sont à l’origine des myopathies de Duchenne (DMD) et de Becker (BMD) qui s’accompagnent d’un déficit total ou d’une dystrophine mutée et induisent de ruptures fréquentes de la membrane des cellules musculaires. La connaissance de la structure de la dystrophine est nécessaire au développement de thérapies à ce jour inexistantes pour les myopathies. Au laboratoire, des données structurales du domaine central de la dystrophine ont été acquises par diffusion des rayons X aux petits angles (SAXS, Small Angles X-ray Scattering). Cette thèse présente le développement d’une approche multi-échelle combinant des données expérimentales SAXS et des données in silico pour la reconstruction de modèles haute-résolution des fragments du domaine central de la dystrophine et d’un fragment muté observé dans une mutation BMD fréquente. Nous avons également cartographié l’interaction de ce domaine central avec deux de ses partenaires fonctionnels importants, l’actine filamenteuse et avec la nitroxyde synthase neuronale (nNOS) et proposé les premiers modèles atomiques des complexes macromoléculaires correspondants. L’ensemble de ces résultats permettra à terme l’optimisation de thérapies pour le traitement des dystrophies musculaires. / Dystrophin is a large protein encoded by DMD gene and located under the plasma membrane of muscle fibers. It plays an essential role in maintaining the integrity of muscle cells during contraction/relaxation cycles. This filamentous protein is composed of four structural domains including the central domain consisting of 24 spectrin-like repeats and four hinges. Each repetition is folded in three α-helices in a ‘coiled-coil’ assembly. Mutations in the DMD gene leads to Duchenne muscular dystrophy (DMD) and Becker (MDBs), which are accompanied by frequent plasma membrane ruptures, due to the loss or modification of dystrophin protein. There are very few structural data available concerning the central domain of dystrophin, which is subject to many mutations involved in DMD and BMD diseases. However, the description and the understanding to an atomic level of dystrophin structure and its interaction is essential for optimization of therapies. Given the impossibility to solve its structure by X-ray crystallography or NMR, structural data of the dystrophin central domain were acquired by small angles X-rays scattering (SAXS, Small Angles X-ray Scattering). This thesis presents the development of an innovative multi-scale approach combining experimental SAXS and in silico derived data, allowing the reconstruction of high-resolution models of dystrophin central domain fragments. Structural data were also obtained on a mutated dystrophin frequently observed in BMDs. Furthermore, we also mapped the interactions of the central domain with two of its majors functional partners, Filamentous actin and neuronal nitroxyde synthase (nNOS) and proposed models of the related macromolecular complexes. At long-term, all of these results will allow optimization of therapies for the treatment of muscular dystrophies.

Dystrophine

Saxs

Modélisation moléculaire

Nnos

Actine-F

Bmd.

Dystrophin

Saxs

Molecular modeling

Nnos

F-Actin

Bmd.

Microstructure of sheared entangled solutions of semiflexible polymers

Lämmel, Marc, Jaschinski, Evelin, Merkel, Rudolf, Kroy, Klaus

27 October 2016

We study the influence of finite shear deformations on the microstructure and rheology of solutions of entangled semiflexible polymers theoretically and by numerical simulations and experiments with filamentous actin. Based on the tube model of semiflexible polymers, we predict that large finite shear deformations strongly affect the average tube width and curvature, thereby exciting considerable restoring stresses. In contrast, the associated shear alignment is moderate, with little impact on the average tube parameters, and thus expected to be long-lived and detectable after cessation of shear. Similarly, topologically preserved hairpin configurations are predicted to leave a long-lived fingerprint in the shape of the distributions of tube widths and curvatures. Our numerical and experimental data support the theory.

Scherausrichtung, Aktin, Modell

shear alignment, F-actin, tube model

info:eu-repo/classification/ddc/530

ddc:530

The Effects of SOCS1, SOCS3 and HSV-1 Infection on Morphology, Cell Viability and Rab7 Expression in Polarized M1 and M2 Raw 264.7 Murine Macrophages

Hey, Jessica Renee

01 June 2018

No description available.

Biology

Biomedical Research

Immunology

Microbiology

Rab7

HSV-1

Herpes Simplex 1

Rab7

F-actin

SOCS1

SOCS3

Cadherin mediated F-actin assembly and the regulation of morphogenetic movements during Xenopus laevis development

Nandadasa, Sumeda A.

05 August 2010

No description available.

Cellular Biology

Cadherin

F-actin

Cytoskeleton

Xenopus

p120

G protein-coupled receptors

Molecular Interactions of Arabinogalactan-Proteins (AGPs) in Tobacco Bright Yellow-2 Cultured Cells and Functional Identification of Four Classical AGPs in Arabidopsis

Sardar, Harjinder Singh

28 September 2007

No description available.

Arabinogalactan-protein

microtubules

F-actin

glycosylphosphatidyl-inositol

lipid rafts

T-DNA mutants

root development