Generation of Endotoxin-Specific Monoclonal Antibodies by Phage and Yeast Display for Capturing Endotoxin.

Endotoxin, a synonym for lipopolysaccharide (LPS), is anchored in the outer membranes of Gram-negative bacteria. Even minute amounts of LPS entering the circulatory system can have a lethal immunoactivating effect. Since LPS is omnipresent in the environment, it poses a great risk of contaminating any surface or solution, including research products and pharmaceuticals. Therefore, monitoring LPS contamination and taking preventive or decontamination measures to ensure human safety is of the utmost importance. Nevertheless, molecules used for endotoxin detection or inhibition often suffer from interferences, low specificity, and low affinity. For this reason, the selection of new binders that are biocompatible, easy to produce, and that can be used for biopharmaceutical applications, such as endotoxin removal, is of high interest. Powerful techniques for selecting LPS-binding molecules in vitro are display technologies. In this study, we established and compared the selection and production of LPS-specific, monoclonal, human single-chain variable fragments (scFvs) through two display methods: yeast and phage display. After selection, scFvs were fused to a human constant fragment crystallizable (Fc). To evaluate the applicability of the constructs, they were conjugated to polystyrene microbeads. Here, we focused on comparing the functionalized beads and their LPS removal capacity to a polyclonal anti-lipid A bead. Summarized, five different scFvs were selected through phage and yeast display, with binding properties comparable to a commercial polyclonal antibody. Two of the conjugated scFv-Fcs outperformed the polyclonal antibody in terms of the removal of LPS in aqueous solution, resulting in 265 times less residual LPS in solution, demonstrating the potential of display methods to generate LPS-specific binding molecules.

Recovering What Matters: High Protein Recovery after Endotoxin Removal from LPS-Contaminated Formulations Using Novel Anti-Lipid A Antibody Microparticle Conjugates.

Endotoxins or lipopolysaccharides (LPS), found in the outer membrane of Gram-negative bacterial cell walls, can stimulate the human innate immune system, leading to life-threatening symptoms. Therefore, regulatory limits for endotoxin content apply to injectable pharmaceuticals, and excess LPS must be removed before commercialization. The majority of available endotoxin removal systems are based on the non-specific adsorption of LPS to charged and/or hydrophobic surfaces. Albeit effective to remove endotoxins, the lack of specificity can result in the unwanted loss of essential proteins from the pharmaceutical formulation. In this work, we developed microparticles conjugated to anti-Lipid A antibodies for selective endotoxin removal. Anti-Lipid A particles were characterized using flow cytometry and microscopy techniques. These particles exhibited a depletion capacity > 6 ×103 endotoxin units/mg particles from water, as determined with two independent methods (Limulus Amebocyte Lysate test and nanoparticle tracking analysis). Additionally, we compared these particles with a non-specific endotoxin removal system in a series of formulations of increasing complexity: bovine serum albumin in water < insulin in buffer < birch pollen extracts. We demonstrated that the specific anti-Lipid A particles show a higher protein recovery without compromising their endotoxin removal capacity. Consequently, we believe that the specificity layer integrated by the anti-Lipid A antibody could be advantageous to enhance product yield.

Semaphorin 3A alters endothelial cell immunogenicity by regulating Class II transactivator activity circuits.

BACKGROUND: Endothelial cells (ECs) play a pivotal role in the allogeneic immune response upon transplantation. Semaphorin 3A (Sema3A) was implicated in the modulation of EC growth, but its effects on immunogenicity were not previously investigated. STUDY DESIGN AND METHODS: ECs were transduced with a lentiviral vector encoding for the green fluorescence protein (GFP) sequence under the control of a Class II transactivator (CIITA)-dependent promoter. Upon stimulation of nonmodified ECs with recombinant Sema3A protein, mRNA and protein levels of CIITA, HLA-DR, and Sema3A receptors were evaluated. An enzyme-linked immunosorbent assay was developed to quantify Sema3A levels in the sera of kidney-transplanted patients. RESULTS: Sema3A stimulation of lentiviral vector encoding for the GFP sequence ECs caused a significant up regulation of the transgene expression, indicating an increase in CIITA levels. Stimulation of nonmodified ECs with Sema3A resulted in an up regulation of CIITA expression, which was associated with enhanced HLA-DR levels and an increase in alloreactive CD4+ T-cell proliferation. Sema3A receptor expression was enhanced by CIITA, establishing a positive feedback loop. Higher levels of Sema3A were observed in sera of patients presenting with organ rejection. CONCLUSION: This study links Sema3A signaling in ECs with increased CIITA levels and higher HLA-DR expression, resulting in CD4+ T-cell activation, which might have important implications for tissue and organ transplantation.

Granulocyte-colony-stimulatory factor: a strong inhibitor of natural killer cell function.

BACKGROUND: The human cytokine granulocyte-colony stimulatory factor (G-CSF) has found widespread application in the medical treatment of neutropenia and to mobilize hematopoietic stem cells used for transplantation. So far, the effect of G-CSF on natural killer (NK) cells has not been fully investigated. STUDY DESIGN AND METHODS: The effect of G-CSF on the phenotype, cytokine secretion profile, and cytotoxicity of NK cells was assessed. NK cells incubated in vitro in presence of G-CSF for 48 hours as well as NK cells isolated from peripheral blood of G-CSF-mobilized stem cell donors (in vivo) were used. RESULTS: In vitro, G-CSF caused a strongly altered phenotype in NK cells with 49% down regulation of NKp44 frequency. Furthermore, the expression of the activating receptors NKp46 and NKG2D decreased 40 and 64%, respectively. The expression of KIR2DL1 and KIR2DL2 decreased by 46% each. In cytotoxicity assays, the lytic capacity of G-CSF-exposed NK cells is reduced by up to 68% in vitro and up to 83% in vivo. Accordingly, granzyme B levels of in vivo G-CSF-exposed NK cells were reduced by up to 87% in comparison to nonstimulated NK cells. Cytokine production of in vitro and in vivo incubated NK cells was strongly decreased for interferon-γ, tumor necrosis factor-α, and granulocyte macrophage colony-stimulating factor as well as interleukin (IL)-6 and IL-8. Furthermore, we observed a reduction in proliferation and a positive feedback loop that increased the expression of the G-CSF receptor. CONCLUSION: G-CSF was demonstrated to be a strong inhibitor of NK cells activity and may prevent their graft-versus-leukemia effect after transplantation.

Cognate Nonlytic Interactions between CD8+ T Cells and Breast Cancer Cells Induce Cancer Stem Cell-like Properties.

Targeting of tumor immune escape mechanisms holds enormous therapeutic potential. Still, most patients progress under immune checkpoint blockade and some even become hyperprogressors. To investigate how cancer cells respond to activated but ineffective T cells, we challenged peptide-loaded MCF-7 breast cancer cells with antigen-specific CD8+ T cells in which lytic granules had been destroyed by pretreatment with Concanamycin A. Gene expression analysis after coculture revealed simultaneous induction of PD-L1, IDO1, CEACAM1, and further immunoregulatory checkpoints in breast cancer cells. Strikingly, we further observed gene signatures characteristic for dedifferentiation and acquisition of pluripotency markers including Yamanaka factors. Cognate interaction with nonlytic CD8+ T cells also increased the proportion of stem cell-like cancer cells in a cell-to-cell contact- or (at least) proximity-dependent manner in various cell lines and in primary breast cancer cell cultures; this induction of stem cell-like properties was confirmed by enhanced tumor-forming capacity in immunodeficient mice. Resulting tumors were characterized by enhanced cell density, higher proliferation rates, and increased propensity for lymphoid metastasis. These findings describe a widely underappreciated pathway for immune escape, namely immune-mediated dedifferentiation of breast cancer cells, which is associated with profound changes in gene expression and cellular behavior. As the enhanced malignant potential of cancer cells after nonlytic cognate interactions with CD8+ T cells enables increased tumor growth and metastasis in BALB/cnu/nu mice, the described mechanism may provide a possible explanation for the clinical phenomenon of hyperprogression in response to unsuccessful immunotherapy. SIGNIFICANCE: This study shows that ineffective immune responses not only fail to clear a malignancy, but can also activate pathways in cancer cells that promote stemness and tumor-seeding capacity.

Adenosine-generating ovarian cancer cells attract myeloid cells which differentiate into adenosine-generating tumor associated macrophages - a self-amplifying, CD39- and CD73-dependent mechanism for tumor immune escape.

BACKGROUND: Ovarian cancer (OvCA) tissues show abundant expression of the ectonucleotidases CD39 and CD73 which generate immunomodulatory adenosine, thereby inhibiting cytotoxic lymphocytes. Little, however, is known about the effect of adenosine on myeloid cells. Considering that tumor associated macrophages (TAM) and myeloid-derived suppressor cells (MDSC) constitute up to 20 % of OvCA tissue, we investigated the effect of adenosine on myeloid cells and explored a possible contribution of myeloid cells to adenosine generation in vitro and ex vivo. METHODS: Monocytes were used as human blood-derived myeloid cells. After co-incubation with SK-OV-3 or OAW-42 OvCA cells, monocyte migration was determined in transwell assays. For conversion into M2-polarized "TAM-like" macrophages, monocytes were co-incubated with OAW-42 cells. Ex vivo TAMs were obtained from OvCA ascites. Macrophage phenotypes were investigated by intracellular staining for IL-10 and IL-12. CD39 and CD73 expression were assessed by FACS analysis both on in vitro-induced TAM-like macrophages and on ascites-derived ex situ-TAMs. Myeloid cells in solid tumor tissue were analyzed by immunohistochemistry. Generation of biologically active adenosine by TAM-like macrophages was measured in luciferase-based reporter assays. Functional effects of adenosine were investigated in proliferation-experiments with CD4(+) T cells and specific inhibitors. RESULTS: When CD39 or CD73 activity on OvCA cells were blocked, the migration of monocytes towards OvCA cells was significantly decreased. In vivo, myeloid cells in solid ovarian cancer tissue were found to express CD39 whereas CD73 was mainly detected on stromal fibroblasts. Ex situ-TAMs and in vitro differentiated TAM-like cells, however, upregulated the expression of CD39 and CD73 compared to monocytes or M1 macrophages. Expression of ectonucleotidases also translated into increased levels of biologically active adenosine. Accordingly, co-incubation with these TAMs suppressed CD4(+) T cell proliferation which could be rescued via blockade of CD39 or CD73. CONCLUSION: Adenosine generated by OvCA cells likely contributes to the recruitment of TAMs which further amplify adenosine-dependent immunosuppression via additional ectonucleotidase activity. In solid ovarian cancer tissue, TAMs express CD39 while CD73 is found on stromal fibroblasts. Accordingly, small molecule inhibitors of CD39 or CD73 could improve immune responses in ovarian cancer.