On-target restoration of a split T cell-engaging antibody for precision immunotherapy

T cell-engaging immunotherapies are changing the landscape of current cancer care. However, suitable target antigens are scarce, restricting these strategies to very few tumor types. Here, we report on a T cell-engaging antibody derivative that comes in two complementary halves and addresses antigen combinations instead of single molecules. Each half, now coined hemibody, contains an antigen-specific single-chain variable fragment (scFv) fused to either the variable light (V-L) or variable heavy (V-H) chain domain of an anti-CD3 antibody. When the two hemibodies simultaneously bind their respective antigens on a single cell, they align and reconstitute the original CD3-binding site to engage T cells. Employing preclinical models for aggressive leukemia and breast cancer, we show that by the combinatorial nature of this approach, T lymphocytes exclusively eliminate dual antigen-positive cells while sparing single positive bystanders. This allows for precision targeting of cancers not amenable to current immunotherapies

Komplementierung eines bimolekularen Antikörper-Derivates im Kontext der Immunologischen Synapse

Cancer is a disease of uncontrolled cell proliferation and migration. Downregulation of antigen-presenting major histocompatibility complex (MHC) and co-stimulatory molecules are two of the most commonly used pathways by cancer cells to escape from immune surveillance. Therefore, many approaches have been developed for restoring the immune surveillance in cancer patients. One approach is to redirect the patient’s own T cells for tumor cell destruction. For T cell function it is important to induce a durable and robust cytotoxic response against target cells and to generate memory T cells, after MHC-mediated recognition of foreign intracellular antigens presented on the surface of antigen presenting cells (APC). Because of these cytotoxic properties, T cell mediated immunotherapy has been established as an effective and durable anti-neoplastic treatment. Different T cell mediated therapies for cancer treatment exist. One of them is using bispecific antibody fragments, so called bi-sepcific T cell engagers (BiTEs), for retargeting of T cells against single antigen positive tumor cells. The BiTE antibodies have two antigen binding domains, one against a target on the target cell, the second against CD3 on the T cells, facilitating cell-to-cell interactions. However, suitable single tumor antigens are limited, which restricts this approach to very few tumor types. To overcome this limitation, we have developed T cell-engaging antibody derivatives, termed hemibodies. Hemibodies exist as two complementary polypeptide chains. Each consists of two specific domains. On one end there is a single-chain variable fragment (scFv) against a target protein and on the other end there is either the heavy chain variable domain (VH) or light chain variable domain (VL) of an anti-CD3 binding antibody. Only when both hemibodies bind their respective antigens on the same tumor cell, the complementary anti CD3 VH and VL domains become aligned and reconstitute the functional CD3 binding-domain to engage T cells. For targeting malignant cells of hematopoietic origin, we used hemibodies against CD45 and HLA-A2. They were expressed in CHO cells, then purified via Strep-tag. To get more insight into the hemibody mechanism of T cell mediated target cell killing, we analyzed the biochemical and functional properties of hemibodies in more detail. Our main finding indicates that VLαCD3-scFvαHLA-A2 and VHαCD3-scFvαCD45 hemibodies induce an atypical immunological synapse characterized by a co-localization of HLA-A2 and CD45 out of the target cell -T cell interface. Nevertheless, hemibodies induce a high caspase activity in target cells in a concentration-dependent manner at nanomolar concentrations in vitro. Looking at ZAP70, which is usually recruited from the cytoplasm to the CD3 receptor in the middle of the cell-cell interface, we were able to detect activated ZAP70 outside of the cell-cell interface in the presence of hemibodies. In contrast cells treated with BiTEs show a central recruitment in the cell-cell interface as expected. We looked also at the interaction of hemibodies with soluble recombinant CD3 epsilon/gamma protein in the absence of target cells. The binding could be measured only at very high concentration out of the therapeutic window. This work contributes to the mechanistic understanding, which underlies the hemibody technology as a new dual antigen restricted T cell-mediated immunotherapy of cancer.Krebs ist eine Krankheit mit unkontrollierter Zellproliferation und -migration. Die Herunterregulierung des antigen-präsentierenden Haupthistokompatibilitätskomplexes (MHC) und der co-stimulierenden Moleküle sind zwei der am häufigsten verwendeten Wege von Krebszellen, um der Immunüberwachung zu entkommen. Daher wurden viele Ansätze zur Wiederherstellung der Immunüberwachung bei Krebspatienten entwickelt. Ein Ansatz besteht darin, die eigenen T-Zellen des Patienten zur Zerstörung von Tumorzellen anzuleiten. T-Zellen zeichnen sich durch ihre schnelle Expansion nach MHC-vermittelter Erkennung von fremden intrazellulären Antigenen auf der Oberfläche von Antigen-präsentierenden Zellen (APC) aus. Darüber hinaus sind eine dauerhafte und robuste zytotoxische Immunantwort und die Erzeugung von Gedächtnis-T-Zellen wichtige Merkmale von T-Zellen. Aufgrund dieser Eigenschaften hat sich die T-Zell-vermittelte Immuntherapie als wirksame antineoplastische Behandlung in den letzten Jahren etabliert. Es gibt verschiedene Ansätze T-Zellen zur Krebsbehandlung zu nutzen. Ein Ansatz verwendet bispezifische Antikörperfragmente, sogenannte bi-sepezifische T-Zell-Engager (BiTEs), zum Retargeting von T-Zellen gegen Antigen-positive Tumorzellen. Die BiTE-Antikörper besitzen zwei Antigen-Bindungsdomänen. Eine ist gegen ein Antigen auf der Zielzelle gerichtet und die zweite ist gegen CD3 auf T-Zellen gerichtet, was zu einer direkten Rekrutierung der T-Zelle an die Zielzelle führt. Geeignete einzelne Tumorantigene, die nur auf Tumorzellen zu finden sind und nicht auf gesundem Gewebe sind jedoch begrenzt, was diesen Ansatz auf sehr wenige Tumortypen einschränkt. Um diese Einschränkung zu überwinden, haben wir bispezifische T-Zell-rekrutierende Antikörper-Derivate entwickelt, sogenannte Hemibodies. Hemibodies sind „single chain“ Polypeptidketten. Jeder Hemibody besitzt zwei spezifische Antigen bindende Domänen. Eine Domäne besteht aus einem „single chain variable Fragment“ (scFv) und ist gegen ein Zielantigen gerichtet und zweite Effektor-Domäne besteht entweder aus der variablen Domäne der schweren Kette (VH), oder die variable Domäne der leichten Kette (VL) eines Anti-CD3-Antikörpers. Nur wenn zwei komplementierende Hemibodies ihr jeweiliges Antigen auf der Oberfläche derselben Zielzelle binden, können die beiden anti-CD3-VH- und anti-CD3-VL-Domänen komplementieren und erst jetzt die funktionelle anti-CD3-Bindungsdomäne ausbilden um T-Zellen zu binden und zu aktivieren. Zur Therapie von bösartigen Zellen hämatopoetischen Ursprungs haben wir Hemibodies gegen CD45 und HLA-A2 hergestellt. Sie wurden in CHO-Zellen exprimiert und dann über Strep-Tag gereinigt. Um mehr über den Hemibody-Mechanismus der T-Zell-vermittelten Abtötung von Zielzellen zu erfahren, haben wir die biochemischen und funktionellen Eigenschaften von Hemibodies genauer analysiert. Unser Arbeit zeigt, dass VLαCD3-scFvαHLA-A2- und VHαCD3-scFvαCD45-Hemibodies eine atypische immunologische Synapse ausbilden. Diese ist gekennzeichnet durch die gemeinsame Verdrängung von HLA-A2 und CD45 aus dem „interface“ zwischen Zielzelle und T-Zelle. Dennoch können Hemibodies selbst bei Konzentrationen im nanomolaren Bereich in vitro eine Caspase-Aktivität in den Zielzellen induzieren. Betrachtet man ZAP70, dass bei T- Zell Aktivierung normalerweise vom Zytoplasma zum CD3-Rezeptor in der Mitte des Zell-Zell „interface“ rekrutiert wird, zeigt sich bei der Hemibody vermittelten T-Zell Aktivierung aktiviertes ZAP70 außerhalb des Zell-Zell „interface“. Im Gegensatz zu Hemibodies zeigen mit BiTEs aktivierte T-Zellen erwartungsgemäß eine zentrale Rekrutierung von ZAP70 im Zell-Zell „interface“. Wir untersuchten auch die Wechselwirkung von Hemibodies mit löslichem rekombinantem CD3-Epsilon / Gamma-Protein in Abwesenheit von Zielzellen. Eine Bindung konnte nur bei sehr hoher Konzentration außerhalb des therapeutischen Fensters gemessen werden. Diese Arbeit untersucht im Detail den T-Zell vermittelten Mechanismus der Hemibody Technologie. Die Ergebnisse ermöglichen uns den Wirkmechanismus der Hemibodies besser zu verstehen. Dies ist wichtig für die sichere Weiterentwicklung dieser neuen zielgerichteten T-Zell vermittelten Immuntherapie

Current Applications of Liquid Biopsy in Gastrointestinal Cancer Disease—From Early Cancer Detection to Individualized Cancer Treatment

Worldwide, gastrointestinal (GI) cancers account for a significant amount of cancer-related mortality. Tests that allow an early diagnosis could lead to an improvement in patient survival. Liquid biopsies (LBs) due to their non-invasive nature as well as low risk are the current focus of cancer research and could be a promising tool for early cancer detection. LB involves the sampling of any biological fluid (e.g., blood, urine, saliva) to enrich and analyze the tumor’s biological material. LBs can detect tumor-associated components such as circulating tumor DNA (ctDNA), extracellular vesicles (EVs), and circulating tumor cells (CTCs). These components can reflect the status of the disease and can facilitate clinical decisions. LBs offer a unique and new way to assess cancers at all stages of treatment, from cancer screenings to prognosis to management of multidisciplinary therapies. In this review, we will provide insights into the current status of the various types of LBs enabling early detection and monitoring of GI cancers and their use in in vitro diagnostics

Variant signaling topology at the cancer cell–T-cell interface induced by a two-component T-cell engager

No abstract available

Circulating Monocytes Serve as Novel Prognostic Biomarker in Pancreatic Ductal Adenocarcinoma Patients

Pancreatic ductal adenocarcinoma (PDAC) ranks among the most fatal cancer diseases, widely accepted to have the most dismal prognoses. Although immunotherapy has broadly revolutionized cancer treatment, its value in PDAC appears to be relatively low. Exhibiting protumoral effects, monocytes have recently been proposed as potential targets of such immunotherapeutic regimens. However, to date, the body of evidence on monocytes’ role in PDAC is scarce. Therefore, we analyzed monocytes in the peripheral blood of 58 PDAC patients prior to surgery and compared them to healthy individuals. PDAC patients showed increased levels of monocytes when compared to healthy controls In addition, patients with perineural infiltration demonstrated a higher percentage of monocytes compared to non-infiltrating tumors and PDAC G3 was associated with higher monocyte levels than PDAC G2. Patients with monocyte levels > 5% were found to have an 8.9-fold increased risk for a G3 and perineural infiltrated PDAC resulting in poorer survival compared to patients with <5% monocyte levels. Furthermore, PDAC patients showed increased expressions of CD86 and CD11c and decreased expressions of PD-L1 on monocytes compared to healthy individuals. Finally, levels of monocytes correlated positively with concentrations of IL-6 and TNF-α in plasma of PDAC patients. Based on our findings, we propose monocytes as a novel prognostic biomarker. Large-scale studies are needed to further decipher the role of monocytes in PDAC and investigate their potential as therapeutic targets

Tumor Infiltration with CD20+CD73+ B Cells Correlates with Better Outcome in Colorectal Cancer

Immunotherapy has become increasingly important in the treatment of colorectal cancer (CRC). Currently, CD73, also known as ecto-5&prime;-nucleotidase (NT5E), has gained considerable interest as a potential therapeutic target. CD73 is one of the key enzymes catalyzing the conversion of extracellular ATP into adenosine, which in turn exerts potent immune suppressive effects. However, the role of CD73 expression on various cell types within the CRC tumor microenvironment remains unresolved. The expression of CD73 on various cell types has been described recently, but the role of CD73 on B-cells in CRC remains unclear. Therefore, we analyzed CD73 on B-cells, especially on tumor-infiltrating B-cells, in paired tumor and adjacent normal tissue samples from 62 eligible CRC patients. The highest expression of CD73 on tumor-infiltrating B-cells was identified on class-switched memory B-cells, followed by naive B-cells, whereas no CD73 expression was observed on plasmablasts. Clinicopathological correlation analysis revealed that higher CD73+ B-cells infiltration in the CRC tumors was associated with better overall survival. Moreover, metastasized patients showed a significantly decreased number of tumor-infiltrating CD73+ B-cells. Finally, neoadjuvant therapy correlated with reduced CD73+ B-cell numbers and CD73 expression on B-cells in the CRC tumors. As promising new immune therapies are being developed, the role of CD73+ B-cells and their subsets in the development of colorectal cancer should be further explored to find new therapeutic options