Amanda J. Boyle

Intracellular routing in breast cancer cells of streptavidin-conjugated trastuzumab Fab fragments linked to biotinylated doxorubicin-functionalized metal chelating polymers.

We describe the synthesis of a heterotelechelic metal-chelating polymer (Bi-MCP-Dox), a polyacrylamide with a number average degree of polymerization DPn = 50 (PDI = 1.2), with biotin (Bi) and doxorubicin (Dox) as functional chain ends and diethylenetriaminepentaacetic acid (DTPA) pendant groups as the binding sites for metal ions. We compared its behavior in cell-uptake experiments with a similar polymer (Bi-MCP) without Dox. These MCPs were complexed with trastuzumab Fab (tmFab) fragments covalently linked to streptavidin (SAv) to form tmFab-SAv-Bi-MCP-Dox and tmFab-SAv-Bi-MCP via the strong affinity between Bi and SAv. tmFab targets human epidermal growth factor receptor-2 (HER2), which is overexpressed on certain human breast cancer cells. Surface plasmon resonance (SPR) experiments with the extracellular domain (ECD) of HER2 showed that incorporation of the MCPs in these complexes had no significant effect on the association or dissociation rate with the HER2 ECD and the dissociation constants. The tmFab-complexed MCPs were subsequently labeled with (111)In (an Auger electron emitting radionuclide). Auger electrons can cause lethal DNA double strand breaks (DSBs) but only if they are emitted intracellularly and especially, in close proximity to the nucleus. To evaluate the cellular and nuclear uptake of tmFab-SAv-Bi-MCP-Dox, we incubated HER2+ SK-BR-3 human breast cancer cells with the complexes saturated with stable In(3+) and visualized their distribution by confocal fluorescence microscopy, monitoring the fluorescence of Dox. In parallel, we carried out cell fractionation studies on tmFab-SAv-Bi-MCP-Dox and on tmFab-SAv-Bi-MCP labeled with (111)In. Both radiolabeled complexes showed cell internalization and nuclear localization. We conclude that metal-chelating polymers with this composition appear to encourage internalization, nuclear uptake, and chromatin (DNA) binding of trastuzumab fragments modified with streptavidin in human breast cancer cells expressing HER2. Further study is needed to understand the impact of polymer charge on cellular uptake and distribution to intracellular compartments.

Biotinylated polyacrylamide-based metal-chelating polymers and their influence on antigen recognition following conjugation to a trastuzumab Fab fragment.

We report the synthesis and characterization of metal-chelating polymers (MCPs) with a terminal biotin and a polyacrylamide backbone harboring multiple diethylenetriaminepentaacetic acid (DTPA) chelating sites. These polymers are conjugated to a streptavidin (SAv)-modified Fab fragment of trastuzumab (tmFab) and subsequently complexed with (111)In through DTPA. Trastuzumab has specific targeting ability toward human epidermal growth factor receptor-2 (HER2), which is overexpressed on some types of breast cancer cells and ovarian cancer cells. (111)In can generate Auger electrons which cause lethal DNA double strand breaks. The radioimmunoconjugates (RICs) were designed to target HER2 overexpressing cancer cells and carry multiple copies of (111)In to these cells. The mole maximum specific activities of these polymers were investigated by loading the polymers with (111)In at an increasing (111)In to polymer ratio. The polymers show 55-fold to 138-fold higher maximum specific activity than DTPA modified tmFab-SAv. Moreover, the HER2 immunoreactivities of these RICs were evaluated by measuring their specific binding ability toward HER2 overexpressing SKOV-3 ovarian cancer cells. The results demonstrate that although in the presence of polymer there is increased nonspecific binding, HER2 targeting ability was retained, ensuring the radionuclide delivery ability of these RICs.

Radioimmunotherapy of cancer with high linear energy transfer (LET) radiation delivered by radionuclides emitting α-particles or Auger electrons.

Abstract Radioimmunotherapy (RIT) aims to selectively deliver radionuclides emitting &agr;‐particles, &bgr;‐particles or Auger electrons to tumors by conjugation to monoclonal antibodies (mAbs) that recognize tumor‐associated antigens/receptors. The approach has been most successful for treatment of non‐Hodgkins B‐cell lymphoma but challenges have been encountered in extending these promising results to the treatment of solid malignancies. These challenges include the low potency of &bgr;‐particle emitters such as 131I, 177Lu or 90Y which have been commonly conjugated to the mAbs, due to their low linear energy transfer (LET = 0.1–1.0 keV/&mgr;m). Furthermore, since the &bgr;‐particles have a 2–10 mm range, there has been dose‐limiting non‐specific toxicity to hematopoietic stem cells in the bone marrow (BM) due to the cross‐fire effect. Conjugation of mAbs to &agr;‐particle‐emitters (e.g. 225Ac, 213Bi, 212Pb or 211At) or Auger electron‐emitters (e.g. 111In, 67Ga, 123I or 125I) would increase the potency of RIT due to their high LET (50–230 keV/&mgr;m and 4 to 26 keV/&mgr;m, respectively). In addition, &agr;‐particles have a range in tissues of 28–100 &mgr;m and Auger electrons are nanometer in range which greatly reduces or eliminates the cross‐fire effect compared to &bgr;‐particles, potentially reducing their non‐specific toxicity to the BM. In this review, we describe the results of preclinical and clinical studies of RIT of cancer using radioimmunoconjugates emitting &agr;‐particles or Auger electrons, and discuss the potential of these high LET forms of radiation to improve the outcome of cancer patients. Graphical abstract Figure. No caption available.

Trastuzumab Labeled to High Specific Activity with 111In by Site-Specific Conjugation to a Metal-Chelating Polymer Exhibits Amplified Auger Electron-Mediated Cytotoxicity on HER2-Positive Breast Cancer Cells

Our objective was to evaluate the cytotoxicity toward HER2-positive human breast cancer (BC) cells of trastuzumab modified site-specifically with a metal-chelating polymer (MCP) that presents multiple DTPA chelators for complexing (111)In. (111)In emits subcellular range Auger electrons that induce multiple lethal DNA double-strand breaks (DSBs) in cells. MCPs were synthesized with a polyglutamide backbone with 24 or 29 pendant DTPA groups, with or without nuclear translocation sequence (NLS) peptide modification and a terminal hydrazide group for reaction with aldehydes generated by sodium periodate (NaIO4)-oxidation of glycans on the Fc-domain of trastuzumab. Trastuzumab was site-specifically modified with two DTPA and labeled with (111)In for comparison (trastuzumab-NH-Bn-DTPA-(111)In). The maximum specific activity (SA) for labeling trastuzumab-Hy-MCP with (111)In was 90-fold greater than for trastuzumab-NH-Bn-DTPA-(111)In [8.9 MBq/μg (1.5 × 10(6) MBq/μmol) vs 0.1 MBq/μg (1.2 × 10(4) MBq/μmol)]. Trastuzumab-Hy-MCP-(111)In was bound, internalized, and imported into the nucleus of SK-BR-3 cells. NLS peptide modification of MCPs did not increase nuclear importation. A greater density of DNA DSBs was found for BC cells exposed to high SA (5.5 MBq/μg) than low SA (0.37 MBq/μg) radioimmunoconjugates. At 20 nmol/L, high SA trastuzumab-Hy-MCP-(111)In was 6-fold more effective at reducing the clonogenic survival (CS) of HER2 overexpressed and HER2 gene-amplified SK-BR-3 cells (1.3 × 10(6) receptors/cell) than low SA MCP-radioimmunoconjugates (CS = 1.8 ± 1.3 vs 10.9 ± 0.7%; P = 0.001). Low SA trastuzumab-NH-Bn-DTPA-(111)In (20 nmol/L) reduced the CS of SK-BR-3 cells to 15.8 ± 2.1%. The CS of ZR-75-1 cells with intermediate HER2 density (4 × 10(5) receptors/cell) but without HER2 gene amplification was reduced to 20.5 ± 4.3% by high SA trastuzumab-Hy-MCP-(111)In (20 nmol/L). The CS of HER2-overexpressed (5 × 10(5) HER2/cell) but trastuzumab-resistant TrR1 cells was decreased to 17.1 ± 1.6% by high SA trastuzumab-Hy-MCP-(111)In. Unlabeled trastuzumab (20 nmol/L) was 18-fold less potent than high SA trastuzumab-Hy-MCP-(111)In at reducing the CS of SK-BR-3 cells (CS = 37.0 ± 5.3%) and 3-fold less effective against Zr-75-1 cells (CS = 53.1 ± 9.8%). Unlabeled trastuzumab had no effect on the survival of TrR1 cells. We conclude that increasing the SA for labeling with (111)In by site-specific conjugation of MCPs to trastuzumab greatly amplified the cytotoxic potency against HER2-overexpressed and gene-amplified BC cells and extended its cytotoxicity to cells with intermediate HER2 expression but without gene amplification and to cells that are HER2 overexpressed but trastuzumab-resistant.

Metal-Chelating Polymers (MCPs) with Zwitterionic Pendant Groups Complexed to Trastuzumab Exhibit Decreased Liver Accumulation Compared to Polyanionic MCP Immunoconjugates.

Metal-chelating polymers (MCPs) can amplify the radioactivity delivered to cancer cells by monoclonal antibodies or their Fab fragments. We focus on trastuzumab (tmAb), which is used to target cancer cells that overexpress human epidermal growth factor receptor 2 (HER2). We report the synthesis and characterization of a biotin (Bi) end-capped MCP, Bi-PAm(DET-DTPA)36, a polyacrylamide with diethylenetriaminepentaacetic acid (DTPA) groups attached as monoamides to the polymer backbone by diethylenetriamine (DET) pendant groups. We compared its behavior in vivo and in vitro to a similar MCP with ethylenediamine (EDA) pendant groups (Bi-PAm(EDA-DTPA)40). These polymers were complexed to a streptavidin-modified Fab fragment of tmAb, then labeled with (111)In to specifically deliver multiple copies of (111)In to HER2+ cancer cells. Upon decay, (111)In emits γ-rays that can be used in single-photon emission computed tomography radioimaging, as well as Auger electrons that cause lethal double strand breakage of DNA. Our previous studies in Balb/c mice showed that radioimmunoconjugates (RICs) containing the Bi-PAm(EDA-DTPA)40 polymer had extremely short blood circulation time and high liver uptake and were, thus, unsuitable for in vivo studies. The polymer Bi-PAm(EDA-DTPA)40 carries negative charges on each pendant group at neutral pH and a net charge of (-1) on each pendant group when saturated with stable In(3+). To test our hypothesis that charge associated with the polymer repeat unit is a key factor affecting its biodistribution profile, we examined the biodistribution of RICs containing Bi-PAm(DET-DTPA)36. While this polymer is also negatively charged at neutral pH, it becomes a zwitterionic MCP upon saturation of the DTPA groups with stable In(3+) ions. In both nontumor bearing Balb/c mice and athymic mice implanted with HER2+ SKOV-3 human ovarian cancer tumors, we show that the zwitterionic MCP has improved biodistribution, higher blood levels of radioactivity, lower levels of normal tissue uptake, and higher tumor uptake. Surface plasmon resonance experiments employing the extracellular domain of HER2 show that the MCP immunoconjugates retain high affinity antigen recognition, with dissociation constants in the low nM range. In vitro studies with SKOV-3 cells for both MCP immunoconjugates show a combination of specific binding that can be completed in the presence of excess tmAb IgG and nonspecific binding (NSB) that persists in the presence of tmAb IgG. We conclude that zwitterionic MCPs represent a much better choice than polymers with charges along the backbone for in vivo delivery of RICs to HER2+ cancer cells.