Mechanisms of recovery from viral infections: destruction of infected cells by neutrophils and complement

Highly enriched populations of bovine neutrophils (PMN) were able to destroy herpesvirus-infected cells when in the presence of C. This mechanism of cytotoxicity was termed C-dependent neutrophil-mediated cytotoxicity (CDNC). To demonstrate CDNC required viable PMN, an active source of C, and a target cell expressing viral antigens. Noninfected cells were not susceptible to lysis. Several approaches were used to exclude the presence of antibody as an explanation for the cytotoxicity observed. In a comparison of the effectiveness of different cell types at mediating CDNC, PMN were more effective than macrophages, and lymphocytes were without activity. The results was discussed in terms of the possible in vivo significance of the neutrophil as a cell type capable of mediating recovery from infection, since if a mechanism similar to CDNC occurs in vivo, this could play a role in defense before the time when protective levels of antibody and immune cells are generated.     

The role of neutrophils in antiviral defense--in vitro studies on the mechanism of antiviral inhibition.

Highly enriched populations of bovine neutrophils were added, in the presence of antiviral antibody, to herpesvirus-infected bovine cell cultures. A cell dose-dependent reduction in virus-induced cytopathology was observed. The mechanism of inhibition was presumed to be mediated by a subcellular neutrophil product and not the result of either direct cytotoxicity or antibody-dependent cell-mediated cytotoxicity (ADCC). Thus, inhibition of comparable magnitude was observed when neutrophils and virus-infected cells were separated by cell impermeable membranes. In addition, plaque reduction occurred when antiviral immunoglobulins or fragments unable to mediate ADCC were used in the assays. Killed neutrophils and sonicates were unable to mediate plaque inhibition. Speculations were made as to the origin of the virus-inhibitory substances and the role that neutrophils might assume in mediating recovery from virus infection.     

The direct antiviral cytotoxicity by bovine lymphocytes is not restricted by genetic incompatibility of lymphocytes and target cells.

Experiments were designed to determine if in the ox a requirement for genetic compatibility between antiviral cytotoxic cells and target cells was needed for cytotoxicity to occur. Unrelated bovine animals were immunized with vaccinia or IBR virus (a herpesvirus), and PBL were collected at various times for measurement of their cytotoxicity against autologous or heterologous uninfected or virus-infected fibroblasts. In all instances, cytotoxicity was expressed against heterologous as well as autologous targets and in most cases there was no evidence of enhanced killing of autologous cells. The cytotoxicity was shown to be direct, presumably T cell mediated, and was not attributable to ADCC. The likelihood of the animals under investigation sharing histocompatibility antigens was considered extremely remote but was not formally excluded.     

Social Cues of Future Sperm Competition Received during Development Affect Learning in Adult Male Fruit Flies,Drosophila melanogaster

Journal of Insect Behavior - The social environment provides males with information about the likelihood of reproductive competition. However, social context can be highly variable, and males must...     

Practical approaches for overcoming challenges in heightened characterization of antibody-drug conjugates with new methodologies and ultrahigh-resolution mass spectrometry

Antibody-drug conjugation strategies are continuously evolving as researchers work to improve the safety and efficacy of the molecules. However, as a part of process and product development, confirmation of the resulting innovative structures requires new, specialized mass spectrometry (MS) approaches and methods, as compared to those already established for antibody-drug conjugates (ADCs) and the heightened characterization practices used for monoclonal antibodies (mAbs), in order to accurately elucidate the resulting conjugate forms, which can sometimes have labile chemical bonds and more extreme chemical properties like hydrophobic patches. Here, we discuss practical approaches for characterization of ADCs using new methodologies and ultrahigh-resolution MS, and provide specific examples of these approaches. Denaturing conditions of typical liquid chromatography (LC)/MS analyses impede the successful detection of intact, 4-chain ADCs generated via cysteine site-directed chemistry approaches where hinge region disulfide bonds are partially reduced. However, this class of ADCs is detected intact reliably under non-denaturing size-exclusion chromatography/MS conditions, also referred to as native MS. For ADCs with acid labile linkers such as one used for conjugation of calicheamicin, careful selection of mobile phase composition is critical to the retention of intact linker-payload during LC/MS analysis. Increasing the pH of the mobile phase prevented cleavage of a labile bond in the linker moiety, and resulted in retention of the intact linker-payload. In-source fragmentation also was observed with typical electrospray ionization (ESI) source parameters during intact ADC mass analysis for a particular surface-accessible linker-payload moiety conjugated to the heavy chain C-terminal tag, LLQGA (via transglutaminase chemistry). Optimization of additional ESI source parameters such as cone voltages, gas pressures and ion transfer parameters led to minimal fragmentation and optimal sensitivity. Ultrahigh-resolution (UHR) MS, combined with reversed phase-ultrahigh performance (RP-UHP)LC and use of the FabRICATOR® enzyme, provides a highly resolving, antibody subunit-domain mapping method that allows rapid confirmation of integrity and the extent of conjugation. For some ADCs, the hydrophobic nature of the linker-payload hinders chromatographic separation of the modified subunit/domains or causes very late elution/poor recovery. As an alternative to the traditionally used C₄ UHPLC column chemistry, a diphenyl column resulted in the complete recovery of modified subunit/domains. For ADCs based on maleimide chemistry, control of pH during proteolytic digestion is critical to minimize ring-opening. The optimum pH to balance digestion efficiency and one that does not cause ring opening needed to be established for successful peptide mapping.