Nicholas K. Brown

The Therapeutic Effect of Anti-HER2/neu Antibody Depends on Both Innate and Adaptive Immunity

Anti-HER2/neu antibody therapy is reported to mediate tumor regression by interrupting oncogenic signals and/or inducing FcR-mediated cytotoxicity. Here, we demonstrate that the mechanisms of tumor regression by this therapy also require the adaptive immune response. Activation of innate immunity and T cells, initiated by antibody treatment, was necessary. Intriguingly, the addition of chemotherapeutic drugs, although capable of enhancing the reduction of tumor burden, could abrogate antibody-initiated immunity leading to decreased resistance to rechallenge or earlier relapse. Increased influx of both innate and adaptive immune cells into the tumor microenvironment by a selected immunotherapy further enhanced subsequent antibody-induced immunity, leading to increased tumor eradication and resistance to rechallenge. This study proposes a model and strategy for anti-HER2/neu antibody-mediated tumor clearance.

CD160 is essential for NK-mediated IFN-γ Production

Tu et al. generated a novel CD160-deficient mouse and showed impaired NK cell–mediated tumor elimination and IFN-γ production. CD160+ NK cells are functionally distinct in secretion of IFN-γ from their CD160− NK cell counterparts.

Direct and indirect roles of the LTβR pathway in central tolerance induction

Medullary thymic epithelial cells (mTECs) play a critical role in thymic negative selection of autoreactive thymocytes, especially for thymocytes specific for peripheral tissue-restricted self-antigens (TRA). Deficiency in lymphotoxin b receptor (LTbetaR) is associated with peripheral tissue inflammation, but whether this is caused by defective negative selection has been unclear; the significance of the LTbetaR pathway for negative selection is evident in some models but not others. Here, we revisit the data and clarify the role of LTbetaR in mTEC development and function and thymic TRA expression. These processes are discussed as potential mechanisms for LTbetaR-mediated control of negative selection.

EDTA is superior to DTT treatment for overcoming the prozone effect in HLA antibody testing

A limitation of solid‐phase human leukocyte antigen (HLA) antibody assays is the falsely low/negative result of samples with high‐titer antibodies, a phenomenon known as the prozone effect. Here we compared the efficacy of ethylenediaminetetraacetic acid (EDTA) and dithiothreitol (DTT) treatment of serum samples in overcoming the prozone effect. A total of 21 serum samples were treated with either EDTA or DTT before HLA single antigen bead assay. The efficacy of prozone effect reversal, compared with untreated samples, was examined on fourfold, serially diluted samples, from neat to 1:256, using PBS as diluent. EDTA reversed the prozone effect in all tested samples, with an efficiency of greater than 84%, estimated by the ratio of undiluted sample mean fluorescence intensity (MFI) to peak MFI, for any given dilution. In contrast, the efficiency of DTT treatment was as low as 47%. These results show superior prozone effect reversal with EDTA treatment, compared with DTT.

Identification and characterization of novel HLA alleles: Utility of next-generation sequencing methods.

The HLA genes are the most polymorphic of the human genome, and novel HLA alleles are continuously identified, often by clinical Sanger sequencing-based typing (SBT) assays. Introduction of next-generation sequencing (NGS) technologies for clinical HLA typing may significantly improve this process. Here we compare four cases of novel HLA alleles identified and characterized by both SBT and NGS. The tested NGS system sequenced broader regions of the HLA loci, and identified novel polymorphisms undetected by SBT. Subsequent characterization of the novel alleles in isolation of coencoded alleles by SBT required custom-designed primers, while the NGS system was able to sequence both alleles in phase. However, the tested assay was unable to amplify buccal cell DNA for subsequent NGS sequencing, presumably due to the lower quality of these samples. While NGS assays will undoubtedly increase novel allele identification, more stringent DNA sample requirements may be necessary for this new technology.

Reanalysis of the role of pronase treatment of B cells in the flow cytometric crossmatch assay: Fc receptor is not the primary target

Pronase, a mixture of nonspecific bacterial proteases, is used to pretreat human lymphocytes to prevent false-positive B cell results in the flow cytometric crossmatch (FCXM) assay. The target of pronase has been reported to be B cell-expressed Fc receptors, which nonspecifically bind IgG. As pronase use in FCXM can induce other complications, including degradation of HLA leading to inappropriate FCXM results, and false-positive T cell results when testing serum from HIV-positive patients, we tested whether specifically blocking Fc receptor CD32 could replace pronase. Anti-CD32 mAb 6C4 was superior to pronase for blocking binding of aggregated IgG to B cells. However, 6C4 was unable to replace pronase in clinical FCXM, as it did not prevent false-positive B cell FCXM results, or enhance sensitivity of the assay. We conclude that the functional targets of pronase in the FCXM assay are poorly understood, and that B cell-expressed Fc receptor plays an insignificant role.