Glyco-engineered anti-EGFR mAb elicits ADCC by NK cells from colorectal cancer patients irrespective of chemotherapy.

BACKGROUND: The epidermal growth factor receptor (EGFR) is overexpressed in colorectal cancer (CRC), and is correlated with poor prognosis, making it an attractive target for monoclonal antibody (mAb) therapy. A component of the therapeutic efficacy of IgG1 mAbs is their stimulation of antibody-dependent cellular cytotoxicity (ADCC) by natural killer (NK) cells bearing the CD16 receptor. As NK cells are functionally impaired in cancer patients and may be further compromised upon chemotherapy, it is crucial to assess whether immunotherapeutic strategies aimed at further enhancing ADCC are viable. METHODS: CRC patients before, during and after chemotherapy were immunophenotyped by flow cytometry for major white blood cell populations. ADCC-independent NK cell functionality was assessed in cytotoxicity assays against K562 cells. ADCC-dependent killing of EGFR(+) A431 cancer cells by NK cells was measured with a degranulation assay where ADCC was induced by GA201, an anti-EGFR mAb glyco-engineered to enhance ADCC. RESULTS: Here, we confirm the observation that NK cells in cancer patients are dysfunctional. However, GA201 was able to induce robust NK cell-dependent cytotoxicity in CRC patient NK cells, effectively overcoming their impairment. CONCLUSIONS: These findings support the evaluation of the therapeutic potential of GA201 in combination with chemotherapy in CRC patients.

Hepatic stem cells: from inside and outside the liver?

The liver is normally proliferatively quiescent, but hepatocyte loss through partial hepatectomy, uncomplicated by virus infection or inflammation, invokes a rapid regenerative response from all cell types in the liver to perfectly restore liver mass. Moreover, hepatocyte transplants in animals have shown that a certain proportion of hepatocytes in foetal and adult liver can clonally expand, suggesting that hepatoblasts/hepatocytes are themselves the functional stem cells of the liver. More severe liver injury can activate a potential stem cell compartment located within the intrahepatic biliary tree, giving rise to cords of bipotential transit amplifying cells (oval cells), that can ultimately differentiate into hepatocytes and biliary epithelial cells. A third population of stem cells with hepatic potential resides in the bone marrow; these haematopoietic stem cells may contribute to the albeit low renewal rate of hepatocytes, but can make a more significant contribution to regeneration under a very strong positive selection pressure. In such instances, cell fusion rather than transdifferentiation appears to be the underlying mechanism by which the haematopoietic genome becomes reprogrammed.

CD152 ligation by CD80 on T cells is required for the induction of unresponsiveness by costimulation-deficient antigen presentation.

Two apparently contradictory observations have been made concerning peripheral T cell tolerance; costimulation-deficient Ag presentation leads to unresponsiveness, and CTLA4 (CD152) ligation is required for unresponsiveness to be induced. This issue was addressed using a CD80- CD86low B cell line to present Ag to DO.11.10 naive CD4+ T cells. Proliferation was substantially enhanced by anti-CD80 or anti-CD152, but was inhibited by anti-CD86. Furthermore, anti-CD80 partially, and anti-CD152 totally protected cloned DO.11.10 T cells from the induction of unresponsiveness following culture with peptide and Chinese hamster ovary H2-Ad+ CD80- CD86- cells. Fab of anti-CD80 caused similar enhancement, and coimmobilized anti-CD80 failed to costimulate the anti-CD3 response of purified T cells, indicating that direct signaling by anti-CD80 was not responsible for these effects. The possibility that anti-CD80 liberated CD28 molecules that were sequestered by the T cell-expressed CD80, enabling them to coaggregate with TCR:CD3 complexes was excluded by finding that anti-CD80 and anti-CD152 individually caused maximal enhancement, rather than having additive effects. These data suggest that T cell-expressed CD80 has a regulatory function and plays a key role in the induction of unresponsiveness due to costimulation-deficient Ag presentation by the ligation of CD152 on neighboring, or even the same, T cell.