Limitations of the rabbit pyrogen test for assessing meningococcal OMV based vaccines.

The rabbit pyrogen test was developed in the early 1900's to detect contaminating pyrogens in parenteral medicines. Since its conception alternative methods with improved sensitivity, relevancy and which are ethically more acceptable have been developed. However, the test is a current Pharmacopeial method and is used to evaluate the pyrogen content of some vaccines. In this article the limitations and pitfalls of using the test to measure pyrogenicity of vaccines containing outer membrane vesicles are described. The method is unsuitable as a safety test for these products due to the high levels of endotoxin present in the vaccine which generate a pyrogenic response in rabbits when delivered intravenously without any dilution. Its use as a consistency test is also ambiguous as the test gives a qualitative rather than quantitative response and the rabbit models are highly variable. In addition there is evidence that measuring the temperature rise of the animals over three hours does not capture the maximum fever response. Finally the article considers the use of alternative methods and the validity of animal models when applying a consistency based approach for assessing the quality of licensed products.

Severity of the TGN1412 trial disaster cytokine storm correlated with IL-2 release.

AIM: To determine if cytokine release with a solid phase assay is predictive of adverse responses for a range of therapeutic mAbs. METHODS: Cytokine ELISAs and a multi-array system were used to compare responses generated by different therapeutic mAbs using a solid phase assay. Flow cytometry was employed to determine the cellular source of those cytokines. RESULTS: Only TGN1412 and muromonab-CD3 stimulated CD4+ T-cell mediated cytokine release characterized by significant (all P < 0.0001) IFNγ, TNFα, IL-2, IL-4, IL-5, IL-10, IL-12, IL-13, IL-17 and IL-22 release, comparable with T-cell mitogen. Significantly greater (P < 0.0001) IL-2 release with TGN1412 (2894-6051 pg ml⁻¹) compared with muromonab-CD3 (62-262 pg ml⁻¹) differentiated otherwise comparable cytokine responses. Likewise, TGN1412 stimulated significantly more (P = 0.0001) IL-2 producing CD4+ T-cells than muromonab-CD3 and induced Th1, Th2, Th17 and Th22 subsets that co-release this cytokine. Significant TNFα release was observed with bevacizumab (P = 0.0001), trastuzumab (P = 0.0031) and alemtuzumab (P = 0.0177), but no significant IL-2 release. TGN1412 and muromonab-CD3 caused pro-inflammatory cytokine release despite significantly (both P < 0.0001) increasing numbers of T-cells with a regulatory phenotype. CONCLUSIONS: The severity of the adverse response to TGN1412 compared with muromonab-CD3 and other therapeutic mAbs correlates with the level of IL-2 release.

Antibody C region influences TGN1412-like functional activity in vitro.

The unexpected outcome of the clinical trial of the superagonistic CD28 mAb TGN1412 (IgG4κ) continues to stimulate interest. We show that TGN1412 binds similarly to human and cynomolgus macaque FcγR, eliminating the possibility that differences in Fc-mediated interactions with FcγR contributed to the failure of preclinical testing in macaques to predict toxicity in humans. The influence of the Fc domain and C region structure on the in vitro functional activity of TGN1412 was investigated using F(ab')(2) and Fab fragments derived from TGN1412 recovered from the trial and recombinant TGN1412 subclass variants and mutants. Superagonistic activity, as measured by cytokine release and proliferation, was assessed by exposing PBMCs to immobilized mAbs/fragments or to aqueous mAbs/fragments in the presence of HUVEC monolayers. Removing the Fc generally curtailed or abolished PBMC activation. However, eliminating detectable FcγR-binding of the IgG4 by mutation (L235E) did not abrogate activity. Stabilizing the "wild-type" IgG4 hinge (S228P) enhanced activity without increasing FcγR binding, which could only partially be explained by inhibition of Fab arm-exchange. Subclass switching the IgG4 mAb to IgG1 decreased activity, whereas switching to IgG2 markedly increased activity. We conclude that the C region strongly influences in vitro CD28-mediated superagonistic signaling. Superagonism requires an intact Fc, as shown by the absence of activity of TGN1412 Fab and F(ab')(2) fragments, but, notably, appears to be relatively independent of FcγR-binding properties. We propose that the Fc, potentially through restricting flexibility, maintains a favorable V region conformation to allow superagonistic activity. These findings have important implications for Ab design strategies.

Comparison of novel methods for predicting the risk of pro-inflammatory clinical infusion reactions during monoclonal antibody therapy.

Two methods for predicting the risk of pro-inflammatory clinical infusion reactions during monoclonal antibody therapy were evaluated. In the first, the antibody of interest is immobilised by air-drying onto 96-well plates prior to the addition of human peripheral blood mononuclear cells (PBMCs). In the second, the antibody is added in aqueous phase to a co-culture of human PBMCs and human endothelium-derived cells. In both methods the cells are incubated with the antibody to allow the accumulation of pro-inflammatory cytokines, quantified by enzyme-linked immunosorbent assay (ELISA). The antibodies associated with clinical infusion reactions, Herceptin, Campath-1H and TGN1412, gave the largest responses taking into account the data for all readouts (tumour necrosis factor-α, TNF, interleukin-6, IL-6, IL-8, IL-2 and cell proliferation) for both methods. Overall, the antibodies tested could be ranked as follows: Tysabri

Endothelial cells co-stimulate peripheral blood mononuclear cell responses to monoclonal antibody TGN1412 in culture.

The failure of preclinical testing to predict the severity of the cytokine storm experienced by the recipients of the superagonistic anti-CD28 monoclonal antibody (mAb) TGN1412 during its Phase 1 clinical trial prompted the development of new in vitro experimental approaches for mimicking in vivo cytokine release and lymphoproliferation. Peripheral blood mononuclear cells (PBMC) presented to TGN1412 immobilised on plastic has previously been shown to stimulate a pro-inflammatory cytokine response. The aim of the present study was to investigate a 'co-culture' model for the detection of TGN1412-like immunomodulatory activity in which TGN1412 was presented to PBMC in the presence of monolayers of endothelium-derived cells and other cell types, followed by measurement of cytokine levels in the culture supernatants and proliferation of PBMC. Culturing PBMC with TGN1412 over primary human umbilical vein endothelial cells (HUVEC) and HUVEC-derived cell lines retaining classic endothelial markers, but not cell lines of non-endothelial origin, mediated the specific release of IL-6, IL-8 and TNFα, and proliferation of PBMC. Low levels of IL-2 and IFNγ were also detected in supernatants with most donors of PBMC. An anti-CD28 mAb agonist, i.e., not a superagonist like TGN1412, did not stimulate cytokine release or proliferation of PBMC in co-cultures. In conclusion, co-culture experiments for TGN1412-specific cytokine release required cells of endothelial origin. However, the profile of released cytokines in co-cultures did not mirror that in the clinical trial participants or the responses from PBMC exposed to TGN1412 immobilised on plastic, suggesting that TGN1412 stimulation of PBMC can occur through more than one mechanism.

Improved in vitro methods to predict the in vivo toxicity in man of therapeutic monoclonal antibodies including TGN1412.

TGN1412 is a "superagonistic" CD28 monoclonal antibody (IgG4) that caused serious adverse events at its first time in human clinical trial. In the present study, different in vitro methods for detecting and quantifying unwanted pro-inflammatory activity of therapeutic monoclonal antibodies (mAbs) such as TGN1412 are described. The antibody of interest is immobilised by wet-coating or air-drying onto polypropylene or polystyrene 96-well plates prior to the addition of human peripheral blood mononuclear cells (PBMCs). The cells are incubated for 16-24h with the immobilised antibody which allows the accumulation of pro-inflammatory cytokines, quantified by enzyme-linked immunoabsorbent assay (ELISA), in response to the antibody. Cytokine responses stimulated by TGN1412 immobilised by air-drying onto polypropylene and polystyrene plates were much larger than responses to TGN1412 wet-coated onto polypropylene and polystyrene plates, respectively. In additional experiments with other mAbs associated with clinical reactions, air-dried mAbs stimulated larger tumour necrosis factor-alpha (TNF) responses than antibodies added in aqueous phase. Also, TGN1412 air-dried onto plastic plates stimulated large proliferative responses of 3-day cultures of lymphocytes. It was concluded that immobilising mAbs by air-drying offers a useful in vitro method for detecting and quantifying pro-inflammatory activities of therapeutic mAbs.

"Cytokine storm" in the phase I trial of monoclonal antibody TGN1412: better understanding the causes to improve preclinical testing of immunotherapeutics.

The CD28-specific mAb TGN1412 rapidly caused a life-threatening "cytokine storm" in all six healthy volunteers in the Phase I clinical trial of this superagonist, signaling a failure of preclinical safety testing. We report novel in vitro procedures in which TGN1412, immobilized in various ways, is presented to human white blood cells in a manner that stimulates the striking release of cytokines and profound lymphocyte proliferation that occurred in vivo in humans. The novel procedures would have predicted the toxicity of this superagonist and are now being applied to emerging immunotherapeutics and to other therapeutics that have the potential to act upon the immune system. Data from these novel procedures, along with data from in vitro and in vivo studies in nonhuman primates, suggest that the dose of TGN1412 given to human volunteers was close to the maximum immunostimulatory dose and that TGN1412 is not a superagonist in nonhuman primates.