Abstract

Our group has developed and experimentally validated a strategy to increase antibody penetration in solid tumors through transient inhibition of antibody-antigen binding. In prior work, we demonstrated that 1HE, an anti-trastuzumab single domain antibody that transiently inhibits trastuzumab binding to HER2, increased the penetration of trastuzumab and increased the efficacy of ado-trastuzumab emtansine (T-DM1) in HER2+ xenograft bearing mice. In the present work, 1HE variants were developed using random mutagenesis and phage display to enable optimization of tumor penetration and efficacy of trastuzumab-based therapeutics. To guide the rational selection of a particular 1HE mutant for a specific trastuzumab-therapy, we developed a mechanistic pharmacokinetic (PK) model to predict within-tumor exposure of trastuzumab/T-DM1. A pharmacodynamic (PD) component was added to the model to predict the relationship between intratumor exposure to T-DM1 and the corresponding therapeutic effect in HER2+ xenografts. To demonstrate the utility of the competitive inhibition approach for immunotoxins, PK parameters specific for a recombinant immunotoxin were incorporated into the model structure. Dissociation half-lives for variants ranged from 1.1 h (for variant LG11) to 107.9 h (for variant HE10). Simulations predicted that 1HE co-administration can increase the tumor penetration of T-DM1, with inhibitors with longer trastuzumab binding half-lives relative to 1HE (15.5 h) further increasing T-DM1 penetration at the expense of total tumor uptake of T-DM1. The PK/PD model accurately predicted the response of NCI-N87 xenografts to treatment with T-DM1 or T-DM1 co-administered with 1HE. Model predictions indicate that the 1HE mutant HF9, with a trastuzumab binding half-life of 51.1 h, would be the optimal inhibitor for increasing T-DM1 efficacy with a modest extension in the median survival time relative to T-DM1 with 1HE. Model simulations predict that LG11 co-administration will dramatically increase immunotoxin penetration within all tumor regions. We expect that the mechanistic model structure and the wide range of inhibitors developed in this work will enable optimization of trastuzumab-cytotoxin penetration and efficacy in solid tumors.

Highlights

  • There is substantial interest in the development of strategies to increase monoclonal antibody uptake and distribution in solid tumors (Bordeau and Balthasar, 2021)

  • Jain and Baxter used a spherical model structure to explore the impact of elevated interstitial fluid pressure (IFP) on monoclonal antibody (mAb) tumor distribution (Jain and Baxter, 1988)

  • Significant contributions to the understanding of factors that contribute to the heterogeneous distribution of mAb in solid tumors have been made through a series of publications by the Wittrup group (Graff and Wittrup, 2003; Thurber et al, 2007; Thurber et al, 2008; Thurber and Wittrup, 2008; Schmidt and Wittrup, 2009; Rhoden and Wittrup, 2012; Thurber and Dane Wittrup, 2012)

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Summary

Introduction

There is substantial interest in the development of strategies to increase monoclonal antibody (mAb) uptake and distribution in solid tumors (Bordeau and Balthasar, 2021). Following extravasation, mAb rapidly binds to cellular antigens, concentrating antibodies at sites near blood vessels and decreasing the extent of within-tumor mAb distribution. Due to this barrier, high-affinity antibodies demonstrate heterogenous distribution within tumors, with high concentrations of antibody at sites near tumor capillaries, and with little or no antibody distribution to distant sites (i.e., >20 μm from tumor capillaries). The BSB can substantially limit therapeutic efficacy, for highly-toxic antibody therapies where the maximum tolerated dose is far below levels needed to saturate the tumor antigen

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