The Abl-interactor Abi suppresses the function of the BRAG2 GEF family member Schizo

Guanine nucleotide exchange factors (GEF) of the BRAG subfamily activate small Arf GTPases, which are pivotal regulators of intracellular membrane traffic and actin dynamics. Consequently, BRAG proteins have been implicated to regulate the surface levels of adhesive and signaling receptors. However, not much is known about the mechanism leading to the regulation of these surface proteins. In this study we found that the Drosophila BRAG GEF Schizo interacts physically with the Abl-interactor (Abi). schizo mutants display severe defects in myoblast fusion during syncytial muscle formation and show increased amounts of the cell adhesion protein N-cadherin. We demonstrate that the schizo myoblast fusion phenotype can be rescued by the expression of the Schizo GEF (Sec7) and membrane-binding (pleckstrin homology) domain. Furthermore, the expression of the Sec7-PH domain in a wild-type background decreases the amounts of N-cadherin and impairs myoblast fusion. These findings support the notion that the Sec7-PH domain serves as a constitutive-active form of Schizo. Using a yeast-two hybrid assay, we show that the SH3 domain of Abi interacts with the N-terminal region of Schizo. This region is also able to bind to the cytodomain of the cell adhesion molecule N-cadherin. To shed light on the function of Schizo and Abi in N-cadherin removal, we employed epistasis experiments in different developmental contexts of Drosophila. These studies point towards a new model for the regulation of Schizo. We propose that the binding of Abi to the N-terminal part of Schizo antagonizes Schizo function to inhibit N-cadherin removal.

Fucosylation in Urological Cancers

Fucosylation is an oligosaccharide modification that plays an important role in immune response and malignancy, and specific fucosyltransferases (FUTs) catalyze the three types of fucosylations: core-type, Lewis type, and H type. FUTs regulate cancer proliferation, invasiveness, and resistance to chemotherapy by modifying the glycosylation of signaling receptors. Oligosaccharides on PD-1/PD-L1 proteins are specifically fucosylated, leading to functional modifications. Expression of FUTs is upregulated in renal cell carcinoma, bladder cancer, and prostate cancer. Aberrant fucosylation in prostate-specific antigen (PSA) could be used as a novel biomarker for prostate cancer. Furthermore, elucidation of the biological function of fucosylation could result in the development of novel therapeutic targets. Further studies are needed in the field of fucosylation glycobiology in urological malignancies.

Leptin—A Potential Bridge between Fat Metabolism and the Brain’s Vulnerability to Neuropsychiatric Disorders: A Systematic Review

Background: Obesity and being overweight have been described as potential causes of neurological disorders. Leptin, a peptide expressed in fat tissue, importantly participates in energy homeostasis and storage and has recently been identified for its signaling receptors in neuronal circuits of the brain. Aim: To elucidate whether the endogenous modulation of leptin can be a protection against neuropsychiatric disorders. Method: A systematic review was performed in accordance with the PRISMA-P method, and reports of studies containing data of leptin concentrations in healthy individuals with or without obesity were retrieved from the PubMed database, using the combinations of Mesh terms for “Leptin” and “Metabolism”. Results: Forty-seven randomized and non-randomized controlled trials, dating from 2000 to 2021, were included in the qualitative synthesis. Discussion and conclusions: Leptin secretion displays a stabilizing pattern that is more sensitive to a negative energy intake imbalance. Leptin levels influence body weight and fat mass as a pro-homeostasis factor. However, long-term exposure to elevated leptin levels may lead to mental/behavioral disorders related to the feeding and reward systems.

An Insight into GPCR and G-Proteins as Cancer Drivers

G-protein-coupled receptors (GPCRs) are the largest family of cell surface signaling receptors known to play a crucial role in various physiological functions, including tumor growth and metastasis. Various molecules such as hormones, lipids, peptides, and neurotransmitters activate GPCRs that enable the coupling of these receptors to highly specialized transducer proteins, called G-proteins, and initiate multiple signaling pathways. Integration of these intricate networks of signaling cascades leads to numerous biochemical responses involved in diverse pathophysiological activities, including cancer development. While several studies indicate the role of GPCRs in controlling various aspects of cancer progression such as tumor growth, invasion, migration, survival, and metastasis through its aberrant overexpression, mutations, or increased release of agonists, the explicit mechanisms of the involvement of GPCRs in cancer progression is still puzzling. This review provides an insight into the various responses mediated by GPCRs in the development of cancers, the molecular mechanisms involved and the novel pharmacological approaches currently preferred for the treatment of cancer. Thus, these findings extend the knowledge of GPCRs in cancer cells and help in the identification of therapeutics for cancer patients.

CD33 BiTE ® Construct Mediated Immunological Synapse Formation and Downstream Signaling in T Cells Is Dependent on Expression of Costimulatory Molecules on Target Cells

BiTE ® (Bispecific T-cell Engager) constructs represent a novel immunotherapeutic strategy that recruits T cells against cancer cells independent of their TCR specificity. Currently, two CD33xCD3 BiTE ® antibody constructs (AMG 330 & AMG 673) are being investigated in phase I dose escalation trials in patients with relapsed/refractory Acute Myeloid Leukemia (AML) with early evidence of acceptable safety and anti-leukemic activity (Ravandi et al., ASH 2020; Subklewe et al., EHA 2020). So far, details of BiTE ® mediated T-cell engagement and information on parameters contributing to their efficacy need more investigation. Therefore, we aimed to characterize the interplay between target and effector cells to deepen our mechanistic understanding of BiTE ® construct mediated T-cell engagement. Previously, we have created a novel in vitro model system with murine Ba/F3 cells expressing human (hu) CD33 ± huCD80 ± huCD86 ± huPD-L1 to study T-cell proliferation and cytotoxicity induced by AMG 330. Using that system, we showed that expression of T-cell co-signaling receptors on target cells modulate AMG 330 induced T-cell activity (Marcinek et al., ASH 2018, EHA 2019). Here, we hypothesize that expression of costimulatory molecules impacts BiTE ® mediated immune synapse formation and consecutive downstream signaling in BiTE ® construct activated T cells. To study whether AMG 330 can induce synapse formation and TCR triggering we used a previously described reconstituted T-cell system, which consists of non-immune (HEK) cells introduced with genes encoding the TCR and other proteins (e.g. CD45) required for the regulation of TCR phosphorylation (James et al., Nature 2012). HEK-T cells were incubated with huCD33 transduced RajiB cells in presence of fluorescently labeled AMG 330 or a control BiTE® (cBiTE) construct to allow cell conjugation. A spinning disc confocal microscope system was used to image cells. To pinpoint the role of T-cell co-signaling receptors in immune synapse formation we incubated differentBa/F3 cell constructs or primary AML (pAML) cells with healthy donor T cells in the presence of AMG 330 and analyzed intensity of LFA-1 expression within the synapse using an Imaging Flow Cytometer. Furthermore, we determined phosphorylation of ZAP70, AKT and ERK in conjugated T cells after various time points by phosphoflow cytometry. We observed that AMG 330, in contrast to cBiTE®, induced TCR triggering reflected by exclusion of CD45 from the RajiB-T-cell-interface. Simultaneously clustering of CD33 occurred in AMG 330 induced cell-cell-interfaces (Fig. 1A/B). The percentage of conjugates formed with huCD33 + Ba/F3 cells was significantly higher in constructs expressing huCD86, compared to those expressing no costimulatory antigens or additional huPD-L1 (Mean % in huCD33 + Ba/F3: 2.8 vs. huCD33 + CD86 +.Ba/F3: 4.2 [p=0.0031] vs. huCD33 + huCD86 + PD-L1 + Ba/F3: 2.8 [p=0.0018]). This was accompanied by LFA-1 accumulation within the T-cell-Ba/F3 cell synapse (Mean of MFI in huCD33 + CD86 +.Ba/F3: 10,933 > huCD33 + huCD86 + PD-L1 + Ba/F3: 7,749 > huCD33 + Ba/F3: 7,028). For downstream signaling in T cells after engagement with Ba/F3 cell constructs in the presence of AMG 330, we observed that kinase phosphorylation was highest after 10 minutes in CD86 co-expressing Ba/F3 cells (Mean % of phosphorylation in T-cell conjugates with huCD33 + vs huCD33 + huCD86 + vs huCD33 + CD86 +.PD-L1 + Ba/F3: pERK 40.9 vs 54.3 [p=0.0064] vs 51.2 %; pAKT: 69.1 vs 81.5 [p=0.0642] vs 75.1 %; pZAP70: 6.9 vs 12.2 [p<0.0001] vs 7.7 % [p<0.0001]) (Fig. 1C). Finally, we evaluated if these finding could also be observed in pAML samples. For that, we determined LFA-1 expression intensity within AMG 330-induced pAML-T-cell synapses. We used CD33 + pAML samples with either high CD86 and no PD-L1 expression or vice versa. Comparing synapse formation between these samples, LFA-1 intensity was 4.6-fold higher in the CD86 + PD-L1 - sample compared to the CD86 - PD-L1 + pAML. Taken together, our data unravel molecular mechanisms of BiTE® construct induced immune synapse formation, highlighting the role of costimulatory molecules in this process. They support the notion that T cell co-signaling receptors like CD86 and PD-L1 modulate T-cell response in an early event manner. Prospective analyses in clinical trials are needed to validate the relevance of checkpoint molecule expression on target cells as a potential predictive biomarker for response. Figure 1 Figure 1. Disclosures Brauchle: Adivo: Current Employment. Lacher: Roche: Research Funding. Kischel: Amgen GmbH Munich: Current Employment. von Bergwelt: Roche: Honoraria, Research Funding, Speakers Bureau; Miltenyi: Honoraria, Research Funding, Speakers Bureau; Mologen: Honoraria, Research Funding, Speakers Bureau; Kite/Gilead: Honoraria, Research Funding, Speakers Bureau; Novartis: Honoraria, Research Funding, Speakers Bureau; Astellas: Honoraria, Research Funding, Speakers Bureau; MSD Sharpe & Dohme: Honoraria, Research Funding, Speakers Bureau; BMS: Honoraria, Research Funding, Speakers Bureau. Theurich: Amgen: Consultancy, Honoraria; BMS/Celgene: Consultancy, Honoraria; GSK: Consultancy, Honoraria; Janssen: Consultancy, Honoraria; Pfizer: Consultancy, Honoraria; Sanofi: Consultancy, Honoraria; Takeda: Consultancy, Honoraria. Buecklein: Novartis: Consultancy, Other: congress and travel support, Research Funding, Speakers Bureau; Pfizer: Consultancy, Honoraria, Speakers Bureau; Miltenyi: Research Funding; Kite/Gilead: Consultancy, Honoraria, Other: Congress and travel support, Research Funding; BMS/Celgene: Consultancy, Research Funding; Amgen: Consultancy, Honoraria. Subklewe: Janssen: Consultancy; Seattle Genetics: Consultancy, Research Funding; Roche: Research Funding; Novartis: Consultancy, Research Funding, Speakers Bureau; Pfizer: Consultancy, Speakers Bureau; Klinikum der Universität München: Current Employment; Takeda: Speakers Bureau; MorphoSys: Research Funding; Miltenyi: Research Funding; Gilead: Consultancy, Research Funding, Speakers Bureau; Amgen: Consultancy, Research Funding, Speakers Bureau; BMS/Celgene: Consultancy, Research Funding, Speakers Bureau.

Using MERSCOPE to Generate a Cell Atlas of the Mouse Brain that Includes Lowly Expressed Genes

The structure and organization of cells within organs is essential to their function, but nowhere in the body is this more spectacular than the brain. There, sprawling, snowflake-like neurons have grown into a precise arrangement, reaching out to neighboring cells to form neural circuits. Communication within neural circuits, made possible by spatial positioning, forms the basis of our physiology. Recently, a high-resolution cell atlas generated by MERFISH (multiplex error-robust fluorescence in situ hybridization) technology has mapped this spectacular organ with unmatched resolution, depth, and scale. The atlas catalogs cells as they exist in the intact biological system and will allow us to learn more about rare cell types and sparsely expressed cell signaling receptors fundamental to health and disease.

Phosphatidylserine binding directly regulates TIM-3 function

Co-signaling receptors for the T cell receptor (TCR) are important therapeutic targets, with blockade of co-inhibitory receptors such as PD-1 now central in immuno-oncology. Advancing additional therapeutic immune modulation approaches requires understanding ligand regulation of other co-signaling receptors. One poorly understood potential therapeutic target is TIM-3 (T cell immunoglobulin and mucin domain containing-3). Which of TIM-3's several proposed regulatory ligands is/are relevant for signaling is unclear, and different studies have reported TIM-3 as a co-inhibitory or co-stimulatory receptor in T cells. Here, we show that TIM-3 promotes NF-κB signaling and IL-2 secretion following TCR stimulation in Jurkat cells, and that this activity is regulated by binding to phosphatidylserine (PS). TIM-3 signaling is stimulated by PS exposed constitutively in cultured Jurkat cells, and can be blocked by mutating the PS-binding site or by occluding this site with an antibody. We also find that TIM-3 signaling alters CD28 phosphorylation. Our findings clarify the importance of PS as a functional TIM-3 ligand, and may inform the future exploitation of TIM-3 as a therapeutic target.

Signaling receptor localization maximizes cellular information acquisition in spatially-structured, natural environments

Cells in natural environments like tissue or soil sense and respond to extracellular ligands with intricately structured and non-monotonic spatial distributions that are sculpted by processes such as fluid flow and substrate adhesion. Nevertheless, traditional approaches to studying cell sensing assume signals are either uniform or monotonic, neglecting spatial structures of natural environments. In this work, we show that spatial sensing and navigation can be optimized by adapting the spatial organization of signaling pathways to the spatial structure of the environment. By viewing cell surface receptors as a sensor network, we develop an information theoretic framework for computing the optimal spatial organization of a sensing system for a given spatial signaling environment. Applying the framework to simulated environments, we find that spatial receptor localization maximizes information acquisition in many natural contexts, including tissue and soil. Receptor localization extends naturally to produce a dynamic protocol for redistributing signaling receptors during cell navigation and can be implemented in a cell using a feedback scheme. In a simulated tissue environment, dynamic receptor localization boosts navigation efficiency by 30-fold. Broadly, our framework readily adapts to studying how the spatial organization of signaling components other than receptors can be modulated to improve cellular information processing.

The structural basis of intraflagellar transport at a glance

ABSTRACT The intraflagellar transport (IFT) system is a remarkable molecular machine used by cells to assemble and maintain the cilium, a long organelle extending from eukaryotic cells that gives rise to motility, sensing and signaling. IFT plays a critical role in building the cilium by shuttling structural components and signaling receptors between the ciliary base and tip. To provide effective transport, IFT-A and IFT-B adaptor protein complexes assemble into highly repetitive polymers, called IFT trains, that are powered by the motors kinesin-2 and IFT-dynein to move bidirectionally along the microtubules. This dynamic system must be precisely regulated to shuttle different cargo proteins between the ciliary tip and base. In this Cell Science at a Glance article and the accompanying poster, we discuss the current structural and mechanistic understanding of IFT trains and how they function as macromolecular machines to assemble the structure of the cilium.

Molecular-scale spatio-chemical control of the activating-inhibitory signal integration in NK cells

The role of juxtaposition of activating and inhibitory receptors in signal inhibition of cytotoxic lymphocytes remains strongly debated. The challenge lies in the lack of tools that allow simultaneous spatial manipulation of signaling molecules. To circumvent this, we produced a nanoengineered multifunctional platform with molecular-scale spatial control of ligands, which was applied to elucidate KIR2DL1-mediated inhibition of NKG2D signaling—receptors of natural killer cells. This platform was conceived by bimetallic nanodot patterning with molecular-scale registry, followed by a ternary functionalization with distinct moieties. We found that a 40-nm gap between activating and inhibitory ligands provided optimal inhibitory conditions. Supported by theoretical modeling, we interpret these findings as a consequence of the size mismatch and conformational flexibility of ligands in their spatial interaction. This highly versatile approach provides an important insight into the spatial mechanism of inhibitory immune checkpoints, which is essential for the rational design of future immunotherapies.