An Engineered Human Fc-Mannose-Binding-Lectin Captures Circulating Tumor Cells.

Tumor cells circulating throughout the body have shown great potential for providing new diagnostic or therapeutic strategies for treating cancer patients. However, isolating circulating tumor cells (CTCs) is still challenging due to the lack of broad spectrum reagents that bind specifically to these cells. This study shows that an engineered human blood opsonin that mimics the innate immune mechanism for opsonizing complex mannan carbohydrates, Fc-mannose binding lectin (FcMBL), exhibits a broad spectrum of CTC binding activity. Using FcMBL-coated magnetic beads, this study is able to specifically capture and isolate a broad range of tumor cells spiked into buffer or blood. FcMBL is bound preferentially to human and mouse breast cancer cells relative to normal breast epithelium, and this study demonstrates the capture of seven different types of cancer cells with greater than 90% capture efficiency, whereas two of these same cancer cells bound poorly to anti epithelial cell adhesion molecule antibodies. It is also confirmed that FcMBL-coated magnetic beads can be used to capture CTCs from the blood of mice bearing metastatic tumors. The FcMBL capture technology may therefore provide a new tool for harvesting a broad range of CTCs with high efficiency as it targets tumor cell specific surface markers that are expressed across diverse cell types and retained throughout the metastatic process.

Purified and Recombinant Hemopexin: Protease Activity and Effect on Neutrophil Chemotaxis.

Infusion of the heme-binding protein hemopexin has been proposed as a novel approach to decrease heme-induced inflammation in settings of red blood cell breakdown, but questions have been raised as to possible side effects related to protease activity and inhibition of chemotaxis. We evaluated protease activity and effects on chemotaxis of purified plasma hemopexin obtained from multiple sources as well as a novel recombinant fusion protein Fc-hemopexin. Amidolytic assay was performed to measure the protease activity of several plasma-derived hemopexin and recombinant Fc-hemopexin. Hemopexin was added to the human monocyte culture in the presence of lipopolysaccharides (LPS), and also injected into mice intravenously (i.v.) 30 min before inducing neutrophil migration via intraperitoneal (i.p.) injection of thioglycolate. Control groups received the same amount of albumin. Protease activity varied widely between hemopexins. Recombinant Fc-hemopexin bound heme, inhibited the synergy of heme with LPS on tumor necrosis factor (TNF) production from monocytes, and had minor but detectable protease activity. There was no effect of any hemopexin preparation on chemotaxis, and purified hemopexin did not alter the migration of neutrophils into the peritoneal cavity of mice. Heme and LPS synergistically induced the release of LTB4 from human monocytes, and hemopexin blocked this release, as well as chemotaxis of neutrophils in response to activated monocyte supernatants. These results suggest that hemopexin does not directly affect chemotaxis through protease activity, but may decrease heme-driven chemotaxis and secondary inflammation by attenuating the induction of chemoattractants from monocytes. This property could be beneficial in some settings to control potentially damaging inflammation induced by heme.

Stationary nanoliter droplet array with a substrate of choice for single adherent/nonadherent cell incubation and analysis.

Microfluidic water-in-oil droplets that serve as separate, chemically isolated compartments can be applied for single-cell analysis; however, to investigate encapsulated cells effectively over prolonged time periods, an array of droplets must remain stationary on a versatile substrate for optimal cell compatibility. We present here a platform of unique geometry and substrate versatility that generates a stationary nanodroplet array by using wells branching off a main microfluidic channel. These droplets are confined by multiple sides of a nanowell and are in direct contact with a biocompatible substrate of choice. The device is operated by a unique and reversed loading procedure that eliminates the need for fine pressure control or external tubing. Fluorocarbon oil isolates the droplets and provides soluble oxygen for the cells. By using this approach, the metabolic activity of single adherent cells was monitored continuously over time, and the concentration of viable pathogens in blood-derived samples was determined directly by measuring the number of colony-formed droplets. The method is simple to operate, requires a few microliters of reagent volume, is portable, is reusable, and allows for cell retrieval. This technology may be particularly useful for multiplexed assays for which prolonged and simultaneous visual inspection of many isolated single adherent or nonadherent cells is required.

The potential for cancer combination therapy with multi-targeted, single-protein pharmaceuticals.

Many diseases and disorders are best treated by a combination of drugs. Unlike small molecules, engineered proteins can be designed to incorporate multiple independent drug activities. Compared with a combination of two or more proteins, the potential benefits of a single biologic that inhibits multiple targets may include lower cost, simplified clinical testing and greater patient convenience. The evolution of HIV combination therapy is a useful point of comparison, as it occurred in an unusual regulatory environment that allowed the testing of combinations when the clinical benefit of component drugs was unproven. The epidermal growth factor receptor family of cancer targets illustrates how a particular single-molecule combination therapy might be used for cancer therapy, so some attempts to construct single-protein agents with multiple activities that include anti-EGFR moieties are reviewed. Protein engineers have created an armory of multiply-targeted antibody derivatives, but such engineered molecules often have a shorter serum half-life than IgG antibodies. New protein engineering approaches may be needed to address this problem. Nonetheless, multiply-targeted single-protein agents may be an economical solution to the problem of antibody combination therapy for cancer.

Antidisialoganglioside/granulocyte macrophage-colony-stimulating factor fusion protein facilitates neutrophil antibody-dependent cellular cytotoxicity and depends on FcgammaRII (CD32) and Mac-1 (CD11b/CD18) for enhanced effector cell adhesion and azurophil granule exocytosis.

Polymorphonuclear leukocytes (PMNs) mediate antibody-dependent cellular cytotoxicity (ADCC), which is increased by the addition of granulocyte-macrophage colony-stimulating factor (GM-CSF). We sought to determine whether PMN ADCC also would be increased by the addition of an antibody/GM-CSF fusion protein and whether this would be associated with the up-regulation and activation of Mac-1 (CD11b/CD18) and with azurophil granule exocytosis. ADCC against LA-N-1 human neuroblastoma cells was evaluated with 4-hour calcein acetoxymethyl ester (calcein-AM) microcytotoxicity assay, electron microscopy, and multi-parameter flow cytometry. With the calcein-AM assay, LA-N-1 cell survival was 10%, 55%, and 75% when PMN ADCC was mediated by the antidisialoganglioside (anti-GD2) immunocytokine hu14.18/GM-CSF, by monoclonal antibody (mAb) hu14.18 mixed with GM-CSF, and by hu14.18 alone. Function-blocking mAbs demonstrated that FcgammaRII and FcgammaRIII were required for ADCC with hu14.18 alone or mixed with GM-CSF, but that only FcgammaRII was required for ADCC with hu14.18/GM-CSF. ADCC mediated by hu14.18 and hu14.18/GM-CSF was Mac-1 dependent. Electron microscopy demonstrated the greatest PMN adhesion, spreading, and lysis of targets with hu14.18/GM-CSF. Monoclonal antibodies blocking Mac-1 function allowed the tethering of PMN to targets with hu14.18/GM-CSF but prevented adhesion, spreading, and cytolysis. Flow cytometry showed that hu14.18 with or without GM-CSF and hu14.18/GM-CSF all mediated Mac-1-dependent PMN-target cell conjugate formation but that GM-CSF was required for the highest expression and activation of Mac-1, as evidenced by the mAb24-defined beta(2)-integrin activation epitope. Hu14.18/GM-CSF induced the highest sustained azurophil granule exocytosis, almost exclusively in PMNs with activated Mac-1. Thus, hu14.18/GM-CSF facilitates PMN ADCC against neuroblastoma cells associated with FcgammaRII and Mac-1-dependent enhanced adhesion and degranulation.