Evaluation of anti-LGR5 Antibodies by ImmunoPET for Imaging

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Evaluation of anti-LGR5 Antibodies by ImmunoPET for Imaging Colorectal Tumors and Development of Antibody-Drug Conjugates Ali Azhdarinia, Julie Voss, Sukhen C Ghosh, Jo A. Simien, Servando Hernandez Vargas, Jie Cui, Wangsheng A. Yu, Qingyun Liu, and Kendra S. Carmon Mol. Pharmaceutics, Just Accepted Manuscript • DOI: 10.1021/acs.molpharmaceut.8b00275 • Publication Date (Web): 02 May 2018 Downloaded from http://pubs.acs.org on May 3, 2018

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Molecular Pharmaceutics

Evaluation of anti-LGR5 Antibodies by ImmunoPET for Imaging Colorectal Tumors and Development of Antibody-Drug Conjugates

Authors: Ali Azhdarinia1, Julie Voss1, Sukhen C. Ghosh1, Jo A. Simien1, Servando Hernandez Vargas1, Jie Cui3, Wangsheng A. Yu2, Qingyun Liu2, Kendra. S. Carmon2* Affiliations: 1

Center for Molecular Imaging, The Brown Foundation Institute of Molecular Medicine, The

University of Texas Health Science Center at Houston, Houston, Texas 77030 2

Texas Therapeutics Institute, The Brown Foundation Institute of Molecular Medicine, The

University of Texas Health Science Center at Houston, Houston, Texas 77030 3

Wntrix, Inc., Houston, Texas 77021

*Correspondence to: Kendra S. Carmon, Ph.D. Texas Therapeutics Institute The Brown Foundation Institute of Molecular Medicine 1825 Pressler St., Rm 530H Houston, TX 77030 Phone: 713-500-3390 Fax: 713-500-2447 email: [email protected]

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ABSTRACT Leucine-rich repeat-containing G-protein coupled receptor 5 (LGR5) is highly expressed in colorectal tumors and marks colon cancer stem cells that drive tumor growth and metastasis. Recently, we showed that LGR5 is a promising target for antibody-drug conjugate (ADC) therapy. However, it is important to identify LGR5-positive tumors that would respond ADC treatment. Prior to drug conjugation, we evaluated two different anti-LGR5 monoclonal antibodies (mAbs), 8F2 and 9G5, using

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Zr-immunoPET to select the optimal mAb for ADC

development and tumor imaging. Binding, specificity, and internalization were compared and mAbs were pre-screened as ADC candidates against colon cancer cells using secondary ADCs. Both mAbs demonstrated strong, specific binding in 293T-LGR5 cells, but not 293T-vector cells. In DLD-1 colorectal cancer cells, which express high levels of LGR5, the mAbs rapidly internalized into lysosomes and promoted ADC-induced cytotoxicity, with 8F2 exhibiting slightly higher potency. No binding was detected in DLD-1-shLGR5 (LGR5 knockdown) cells. 89

Zr-DFO-LGR5 mAbs were generated and shown to retain high affinity and LGR5-dependent

uptake in vitro. PET/CT imaging of DLD-1 tumors was performed 5 days post-injection of 89ZrDFO-LGR5 mAbs and findings were consistent with biodistribution data which showed significantly higher tumor uptake (%ID/g) for DFO-9G5 (5.5 ± 1.2) and

89

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Zr-DFO-8F2 (17.9 ± 2.2) compared to

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Zr-

Zr-DFO-IgG (3.8 ± 1.0). No significant uptake was observed in

DLD-1-shLGR5 tumors. This study identifies 8F2 as the optimal candidate for ADC development and provides initial evidence that 89Zr-DFO-LGR5 mAbs may be utilized to stratify tumors which would respond best to LGR5-targeted ADC therapy.

Keywords: LGR5, immunoPET, colon cancer, zirconium-89, antibody-drug conjugates

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INTRODUCTION Leucine-rich repeat-containing G-protein coupled receptor 5 (LGR5) is a bona fide marker of adult stem cells and is highly expressed in several solid tumors including gastrointestinal cancers of the stomach, liver, and colon with low expression in normal tissue

1-4

. Specifically, LGR5

expression is elevated in approximately 60-70% of colorectal adenocarcinomas

1-2

. LGR5 is

comprised of a large extracellular domain (ECD) with 17-leucine-rich repeats and a seven transmembrane domain 5 and binds R-spondin growth factors (RSPO1-4) to modulate the Wnt/βcatenin signaling pathway 6-8. A series of recent studies demonstrated that LGR5-positive cells in colon cancer function as cancer stem cells to drive tumor growth and metastasis in models of human and mouse colon cancer

9-13

. Therefore, it is important to develop diagnostic approaches

that identify LGR5-positive tumors and generate novel targeted therapies to treat and eliminate them. LGR5 is rapidly and constitutively internalized within cells making it a suitable transit for targeted therapies such as antibody-drug conjugates (ADCs), which are innovative therapeutics that combine the specificity of monoclonal antibodies (mAbs) with the potency of cytotoxic drugs

1, 14-16

. Upon selective entry into cancer cells via internalization, ADCs are trafficked to

lysosomes where drug is released to exert its cell-killing effect

16

. Recently, we reported the

generation of anti-LGR5 ADCs for targeted treatment of colon cancer 1. The ADCs incorporated the highly cytotoxic payload, monomethyl auristatin E (MMAE), and specifically destroyed LGR5-positive colon cancer cells and induced tumor regression without significant adverse effects. Since ADC effectiveness is dependent on target specificity, non-invasive imaging is an attractive approach for examining differences in the in vivo properties of candidate mAbs and

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developing optimization strategies. Moreover, imaging is an effective approach for target assessment and is critical for identifying tumors that would best respond to ADC therapy. One strategy to evaluate ADC target antigen expression and tumor uptake is by performing non-invasive mAb-based positron emission tomography (immunoPET). Zirconium-89 (89Zr) has emerged as the preferred radionuclide for immunoPET since its half-life is compatible with the long circulation time of mAbs and has been utilized in a number of clinical trials 17-18. The ability to perform delayed imaging with

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Zr enables clearance of the tracer from non-target tissues,

resulting in improved tumor visualization compared to other radiometals. As a result of these properties,

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Zr-immunoPET is becoming more widely implemented in the preclinical

19-21

and

clinical 22-23 development of ADCs. We hypothesize that 89Zr-immunoPET can be used to predict which anti-LGR5 mAbs would be most suitable for ADC development and to identify LGR5-positive tumors that would respond to therapy. We cloned and produced two distinct anti-LGR5 mAbs to compare binding, internalization, and effects on colon cancer cell cytotoxicity in the presence of secondary ADCs. ImmunoPET was performed to compare tumor uptake in LGR5-positive and -negative tumors, followed by tissue biodistribution to identify the utility of 89Zr-labeled anti-LGR5 mAbs as diagnostic tools to non-invasively assess LGR5 expression in tumors and to predict ADC efficacy.

EXPERIMENTAL SECTION Expression Vectors, Commercial Antibodies, and Other Reagents. All reagents were analytical grade and used without further purification unless otherwise stated. Chelex-100 resin was purchased from Bio-Rad Laboratories and used with aqueous buffers to ensure metal-free

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conditions. hIgG1 was from Fisher Scientific. Expression vectors encoding Myc-hLGR5, MycmLGR5 were generated previously 1, 6. The Fab Anti-human IgG Fc-Duocarmycin DM antibody with cleavable linker (Fab-αHFc-CL-DMDM) was purchased from Moradec, LLC. Commercial antibodies were used in accordance to manufacturer’s guidelines. For western blot: anti-LGR5 (Abcam, ab75732) and from Cell Signaling, anti-myc-tag (2276) and anti-β-actin (4970). For immunocytochemistry (ICC): anti-Lamp-1 (Cell Signaling, 9091) and secondary antibodies goat anti-rabbit-Alexa-488, goat anti-human-Alexa-555, and goat anti-human-Alexa-488 (Life Technologies). Cloning and Production of Anti-LGR5 mAbs. For the anti-LGR5 mAb rat-human chimera constructs, codon optimized sequences encoding the light (VL)and heavy chain variable (VH) regions of rat 8F2 and 9G5

7, 24

and the constant region of human κ light chain (CL) and IgG1

heavy chain (CH) were synthesized (Epoch Life Sciences). The VL/CL and VH/CH for each mAb were subcloned into separate pCEP4 (ThermoFisher) expression vectors using In-Fusion HD cloning (Clontech). MAbs were produced and purified as previously described 1. Cell Culture and Western Blot. HEK293T (293T) and DLD-1 cells were purchased from ATCC and routinely tested for mycoplasma. 293T and DLD-1 cells were cultured in DMEM and RPMI medium, respectively, supplemented with 10% fetal bovine serum (FBS) and penicillin/streptomycin at 37°C with 95% humidity and 5% CO2. DLD-1 cells with stable LGR5 knockdown (shLGR5) or vector (shCTL) and stable 293T cell lines overexpressing hLGR5 or mLGR5 and vector cells were established as previously reported

1, 6

. For western blot, protein

extraction was performed using RIPA buffer (Sigma) supplemented with protease/phosphatase inhibitors. Cell lysates were incubated at 37°C for 1 hour in 2x SDS buffer and loaded on SDS-

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PAGE. HRP-labeled secondary antibodies were utilized for detection with standard ECL protocol. Immunocytochemistry and Binding Assays. For immunocytochemistry (ICC), HEK293T or DLD-1 cells were seeded into 8-well chamber slides and incubated overnight. The next day, cells were treated with anti-LGR5 mAbs at 37°C for 1 hr. Cells were PBS washed, 4% formalin fixed, and permeabilized in 0.1% saponin. For lysosome co-localization studies, cells were incubated with anti-Lamp-1 for 45 min followed by anti-rabbit-Alexa-488 and anti-human-Alexa-555 for 1 hr at room temperature. Nuclei were counterstained with TO-PRO®-3. Images were acquired using confocal Leica TCS SP5 microscope with LAS AF Lite software. For whole-cell binding, cells were seeded onto poly-D-lysine coated 96-well plates and incubated overnight. Serial dilutions of anti-LGR5 mAbs were added for 2 hrs at 4°C. Plates were washed in PBS, fixed, incubated with anti-human-Alexa-555 for 1 hr at room temperature, and washed. Fluorescence intensity was quantified using Tecan Infinite M1000 plate reader. Data were analyzed with GraphPad Prism software using the logistic nonlinear regression model. In Vitro Cytotoxicity. DLD-1 cells were plated at 1000 cells/well in 96 half-well plates. Serial dilutions of unconjugated mAbs or isotype-matched hIgG1 control were added to the plate in the presence or absence of 5µg/ml Fab-αHFc-CL-DMDM and allowed to incubate for 4 days at 37°C. Each condition was tested in triplicate in 3 experiments. Luciferase measurements were performed using CellTiter-Glo (Promega) and EnVision mulitlabel (PerkinElmer) plate reader. Data were analyzed with GraphPad Prism software using the logistic nonlinear regression model. DFO Conjugation and

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Zr-labeling. Immunoconjugates were prepared by reacting 1 mg of

mAb with an 8-fold molar excess of p-isothiocyanatobenzyl-desferrioxamine B (DFO-Bz-NCS, Macrocyclics) in 0.1 M sodium carbonate (pH 9). Reactions were conducted at 37 oC for 1 h and

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Molecular Pharmaceutics

transferred to 4oC for continuous end-over-end mixing overnight. The products were purified with Zeba desalting spin columns (Thermo Scientific) and collected in PBS.

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Zr-oxalate was

produced by Washington University School of Medicine (St. Louis, MO) and diluted with an equal volume of 0.5 M HEPES. The pH of the radioactive solution was adjusted to 7.4 with 2 N NaOH, and 37 MBq was added to 100 µg of each immunoconjugate in 1 M HEPES. After heating at 37°C for 1 h, the reaction was quenched with 10 mM EDTA and purified with Zeba desalting spin columns. HPLC analysis was performed on DFO conjugates and radiochemical yield and purity were measured by ITLC using 50 mM EDTA as the mobile phase. In Vitro Uptake Assays. Cell uptake of

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Zr-labeled mAbs was measured in 293T, 293T-

hLGR5, DLD-1, and DLD-1-shLGR5 cells in 96-well plates. Approximately 200,000 cells in 150 µL in RPMI were added to each well and incubated with 60 nM of mAb (37-74 kBq) at 37°C for 1 h. Cells were centrifuged and washed 3 times with PBS and radioactivity was quantified in a Wizard2 automated gamma counter (Perkin Elmer). Measurements were normalized to LGR5-negative 293T cells and expressed as fold-difference. Each experiment was performed in triplicate. PET/CT Imaging and Biodistribution. Animal studies were carried out in strict accordance with the recommendations of the Institutional Animal Care and Use Committee of the University of Texas Health Science Center at Houston. Female 5-7 week old nu/nu mice (Charles River Laboratories) were subcutaneously implanted into the lower right flank with 4 x 106 DLD-1 or DLD-1-shLGR5 cells in 1:1 mixture with matrigel (BD Biosciences). After 2 weeks, when tumor size reached ~ 4-6 mm in diameter, mice were randomized and intravenously injected with 1.9-2.7 MBq of 89Zr-DFO-LGR5 mAbs (8F2 or 9G5) or 89Zr-DFO-hIgG1 (n=5 mice/group) and imaged 5 days post-injection on a Siemens Inveon µPET/CT scanner as previously described 25.

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Region-of-interest analysis was performed with the vendor software package to obtain tumor-tobackground ratios (TBRs). At the conclusion of the imaging studies, mice were euthanized by cervical dislocation and tissues were excised, weighed, and counted for radioactivity using a γ counter. The total injected activity per mouse was determined from a known aliquot of the injected solutions and used to calculate the percentage of the injected dose per gram of tissue (%ID/g). Statistical Analysis. Data are expressed as mean ± SEM. Differences between groups were analyzed by Student’s t test. Multiple comparisons used one-way ANOVA and Tukey post hoc analysis. P < 0.05 was considered statistically significant.

RESULTS Characterization of Anti-LGR5 mAb Binding. We produced and purified anti-LGR5 mAbs, 8F2 and 9G5 7, as rat-human chimeras (Sup. Fig. 1). Based on epitope mapping, 8F2 and 9G5 recognize the N-terminus of the LGR5 ECD 7. We tested species cross-reactivity of each antiLGR5 mAb. HEK293T cells overexpressing myc-tagged human LGR5 (293T-hLGR5) or mouse LGR5 (293T-mLGR5) and vector control (293T-vector) cells were established and LGR5 expression was confirmed by western blot (Fig. 1A). Cells were treated for 1 hour at 37°C with 4 µg/ml anti-LGR5 mAb. ICC and confocal analysis showed that 8F2 is specific for hLGR5, whereas 9G5 binds both hLGR5 and mLGR5 (Fig. 1B). To determine relative affinities we used a whole-cell fluorescence binding assay. We showed that 8F2 and 9G5 bind 293T-hLGR5 cells with high affinity with Kd of 0.27 µg/ml (or 1.8 nM) and 0.45 µg/ml (or 3.0 nM), respectively (Fig. 1C). 9G5 bound 293T-mLGR5 cells with Kd of 1.9 µg/ml (or 12.6 nM) (Fig. 1D). 8F2 exhibited minimal binding to mLGR5 at high concentrations, but Kd could not be determined

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Molecular Pharmaceutics

(Fig. 1D). Anti-LGR5 mAbs did not bind 293T-vector cells (Sup. Fig. 1B) which do not express significant levels of endogenous LGR5 6.

Figure 1. Characterization of LGR5 mAb binding. (A) Western blot analysis of myc-tagged LGR5 in 293T cells. (B) Confocal images of anti-LGR5 mAbs 8F2 and 9G5 binding specificity to 293T-hLGR5 (human) and 293T-mLGR5 (mouse), but not 293T-vector cells. Whole-cell fluorescence binding of mAbs to the surface of 293T (C) hLGR5, and (D) mLGR5 cells.

Screening Anti-LGR5 mAbs for ADC-Induced Cytotoxicity. Since ADC efficacy is dependent upon target internalization and trafficking to the lysosome for release of cytotoxic drug 16, we examined if each mAb co-localized with the lysosome marker, LAMP1, subsequent to binding endogenous LGR5 in cancer cells. DLD-1 (shCTL) colon cancer cells, which express

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high levels of LGR5, and DLD-1 LGR5 knockdown (shLGR5) cells (Fig. 2A) were treated with 8 µg/ml of mAb and incubated at 37°C for 1 hour. 8F2 and 9G5 co-localized with LAMP1 in DLD-1 shCTL cells (Fig. 2B). No mAb binding was detected in DLD-1-shLGR5 cells (Fig. 2B), indicating mAb specificity for endogenous LGR5.

Figure 2. ADC-induced cytotoxicity and lysosome trafficking in DLD-1 colon cancer cells. (A) Western blot of LGR5 expression in DLD-1 control (shCTL) and LGR5 knockdown (shLGR5) cells. (B) Confocal images showing anti-LGR5 mAbs in complex with LGR5 (red) and colocalization (yellow) with the lysosome marker, LAMP1 (green). No binding was observed in DLD-1-shLGR5 cells. Anti-LGR5 mAb mediated cytotoxicity of DLD-1 cells (C) in the absence and (D) presence of duocarmycin-conjugated secondary ADC.

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Molecular Pharmaceutics

MAbs can be pre-screened in vitro for ADC activity by complexing with a secondary ADC and testing the ability of the complex to destroy cancer cells expressing target antigen. LGR5-dependent cell cytotoxicity was examined by treating DLD-1 cells with increasing concentrations of either 8F2, 9G5 or IgG in the presence of an anti-human antibody conjugated with the cytotoxic drug duocarmycin via a cleavable linker (secondary ADC; Fab-αHFc-CLDMDM). Duocarmycin is a potent DNA-alkylating agent that binds into the minor groove of DNA

26

. As shown in Fig. 2C, the anti-LGR5 mAbs and IgG had no effect on cancer cell

viability or proliferation in the absence of secondary ADC. However, when co-treeated with secondary ADC, both anti-LGR5 mAbs induced cytotoxicity with 8F2 exhibiting slightly higher potency (EC50 = 0.59 µg/ml or 3.9 nM vs. 1.37 µg/ml or 9.1 nM for 9G5) (Fig. 2D). IgG control had no effect. Synthesis and LGR5-Dependent Uptake of

89

Zr-Labeled Anti-LGR5 mAbs. DFO was

conjugated to 8F2, 9G5, and a control IgG mAb and HPLC analysis revealed similar retention times and peak profiles following DFO conjugation (Sup. Fig. 2). Using isotopic dilution, we determined there was an average of 2.1-3.4 DFO molecules per mAb, which resulted in

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Zr

radiolabeling yields >70% and radiochemical purity >99% as determined by radio-TLC (Sup. Fig. 3). The specific activities ranged from 0.22-0.34 MBq/µg. Using whole cell fluorescence binding assay, we showed that conjugation of 8F2 and 9G5 with DFO had no significant effect on mAb binding to 293T-hLGR5 cells (Fig. 3A-B). To validate specificity and internalization of 89

Zr-DFO-LGR5 mAbs, an in vitro uptake study was performed in cell lines expressing different

levels of LGR5 expression (Fig. 3C). As expected,

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Zr-DFO-8F2 and

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greater uptake than 89Zr-DFO-IgG in 293T-hLGR5 and DLD-1 cells, and was higher than

89

Zr-DFO-9G5 showed

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Zr-DFO-8F2 uptake

Zr-DFO-9G5 in 293T-hLGR5 cells (P< 0.001). Tracer uptake was

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significantly lower for

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Zr-DFO-8F2 and

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Zr-DFO-9G5 in DLD-1-shLGR5 cells (P< 0.05).

These results suggest uptake of 89Zr-DFO-LGR5 mAbs is LGR5-mediated.

Figure 3. In vitro assessment of

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Zr-DFO-LGR5 mAbs. Whole-cell fluorescence binding

comparing DFO conjugated and unconjugated anti-LGR5 mAbs (A) 8F2 and (B) 9G5 to 293ThLGR5 cells. (C) Assay measuring uptake of 89Zr-DFO-8F2, 89Zr-DFO-9G5 and 89Zr-DFO-IgG in cell lines with different levels of LGR5 expression. Values represent fold-difference compared

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to 293T negative control cells for each mAb. * P< 0.05, ** P< 0.01, *** P< 0.001, ****P< 0.0001

ImmunoPET of

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Zr-Labled Anti-LGR5 mAb Uptake in Colorectal Tumors. PET/CT

imaging in xenografts with varying expression levels of LGR5 demonstrated clear differences in tumor uptake of the immunoconjugates at 5 days p.i. (Fig. 4A). In DLD-1 tumors which express high levels of LGR5, tumor signal of 89Zr-DFO-8F2 was clearly visualized and higher than 89ZrDFO-9G5. Mice that received the control mAb, 89Zr-DFO-IgG, did not show tracer accumulation in tumors. Tumor-to-muscle ratios for 89Zr-DFO-8F2 (16.2 ± 2.1) were significantly higher than 89

Zr-DFO-9G5 (8.0 ± 1.0) and

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Zr-DFO-IgG (6.4 ± 0.8) (Fig. 4B). Comparison of

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Zr-DFO-

8F2 in mice with DLD-1 and DLD-1-shLGR5 tumors revealed 3-fold higher tumor-to-muscle ratios in DLD-1 mice, suggesting high tracer specificity for LGR5. All tracers were predominantly cleared through the liver with no notable uptake in other organs.

Figure 4. ImmunoPET characterization of

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Zr-DFO-LGR5 mAbs in colorectal tumors. (A)

Maximum intensity projection of PET images acquired 5 days post-injection of

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89

Zr-DFO-IgG,

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Zr-DFO-9G5, and

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Zr-DFO-8F2 in DLD-1 cells, and

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Zr-DFO-8F2 in DLD-1 cells with

LGR5 KD. T, indicates tumor site. (B) T/M Ratios. ** P< 0.01, *** P< 0.001

Biodistribution. Ex vivo biodistribution studies were conducted at the completion of PET imaging and are summarized in Fig. 5. Consistent with PET findings, 89Zr-DFO-8F2 had higher uptake in DLD-1 xenografts (17.1 ± 3.3 %ID/g) compared to and

89

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Zr-DFO-9G5 (5.5 ± 1.2 %ID/g)

Zr-DFO-IgG (3.8 ± 1.0 %ID/g). Prominent accumulation of

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Zr-DFO-8F2 was also seen

in the liver (17.9 ± 2.2 %ID/g) and spleen (11.9 ± 1.2 %ID/g) due to reticuloendothelial clearance of the agent. The minor formation of mAb aggregates following DFO conjugation may also have contributed to increased uptake by large molecule clearance organs (Sup. Fig. 2). Lower uptake was observed in all other organs and resulted in high TBRs including a tumor-tomuscle ratio (T/M) of 37.2 ± 4.8 (Sup. Fig. 4). Comparatively, non-tumor uptake values were lower for

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Zr-DFO-9G5 but did not result in higher contrast ratios due to lower tumor uptake

than 89Zr-DFO-8F2. Similar to the PET images, 89Zr-DFO-8F2 uptake in DLD1-shLGR5 tumors with lower antigen expression was minimal (2.0±0.3 %ID/g) and was primarily in the liver and spleen.

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Figure 5. Biodistribution. (A) Comparison of 89Zr-DFO-IgG, 89Zr-DFO-8F2, and 89Zr-DFO-9G5 in mice with DLD-1 tumors and (B)

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Zr-DFO-8F2 in mice with DLD-1 and DLD-1-shLGR5

tumors. *** P< 0.001 for 89Zr-DFO-8F2 uptake compared to other mAbs and tumors.

DISCUSSION Colorectal cancer is the third most common cancer and third leading cause of cancer-related deaths in the United States 27. Over the past decade, the mortality rate of colon cancer has rapidly declined due to advances in imaging, surgical techniques, and therapies.

18

F-fluorodeoxyglucose

(FDG)-PET is a current standard for colorectal cancer staging and evaluating therapeutic response 28. However, this approach can often result in false-positives due to FDG uptake at sites

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of inflammation in response to radiation therapy, surgery, or inflammatory diseases of the colon. Therefore, a more tumor-specific PET agent may significantly improve the detection and treatment of colorectal cancer. Key characteristics of LGR5, such as high tumor- and CSCspecificity 1-2, 9-10 and rapid internalization

14

make it an attractive candidate for both diagnostic

and ADC development to image and eradicate tumors and CSCs. Developing an LGR5 imaging agent could be advantageous in multiple regards. First, LGR5 imaging could enable patient selection by identifying primary and metastatic tumors that may respond to LGR5-targeted therapy. Second, LGR5 imaging agents could assess tumor status before, during, and after targeted treatment or chemotherapy. Third, newly developed anti-LGR5 mAbs could be compared to determine differences in sensitivity, specificity, and ability to generate high TBRs. This is the first study, to our knowledge, to report the use of

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Zr-DFO-LGR5 mAbs to non-

invasively assess LGR5 expression and uptake in colorectal tumors. Our data show that both 8F2 and 9G5 unconjugated mAbs bind LGR5 with high affinity and rapidly internalize with no effect on cell viability (Fig. 1, Sup. Fig. 1B). In vitro cytotoxicity studies identified 8F2 as the more potent anti-LGR5 mAb in the presence of a secondary ADC (Fig. 2C), suggesting a combination of higher binding to endogenous LGR5 and increased internalization to the lysosome compared to 9G5. These findings were in agreement with radioactive cell uptake studies which showed higher uptake of

89

Zr-DFO-8F2 in 293T-hLGR5

and DLD1-cells (Fig. 3C). In vivo characterization by immunoPET in DLD-1 xenografts, which express high levels of LGR5, revealed increased tumor uptake of both 89Zr-DFO-8F2 and 89

DFO-9G5 compared to uptake compared to

Zr-DFO-IgG (Fig. 4A-B).

89

89

Zr-

Zr-DFO-8F2 exhibited enhanced tumor

89

Zr-DFO-9G5, which may be due in part to differences in epitope

accessibility or mAb internalization in vivo. DLD-1-shLGR5 xenografts did not show significant

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uptake of

89

Zr-DFO-8F2, thus verifying LGR5 target specificity. ImmunoPET findings were

consistent with ex vivo quantification of tumor uptake (Fig. 5A-B). Interestingly, biodistribution analyses showed 9G5, which cross-reacts with both mLGR5 and hLGR5, did not exhibit higher uptake in normal mouse tissues which express LGR5 (e.g. intestine) compared to 8F2, which only binds hLGR5 (Fig. 5A). This observation is likely due to the LGR5 receptor density of normal cells being much lower than that of tumor cells. Correspondingly, transcriptome profiling of LGR5-positive cells demonstrated that total LGR5 expression levels are much lower in normal verses cancer cells 29. Tracer levels for 89Zr-DFO-8F2 were higher in blood, which may indicate slower clearance and thereby increase availability of the mAb and improve accumulation in tumors (Fig. 5A). To further enhance tumor targeting and contrast ratios of 89ZrDFO-LGR5 mAbs and ADCs, future work may involve predosing with non-radioactive mAbs to saturate antigen sinks 30. Alternatively, mAb Fc regions may be engineered or deglycosylated to block Fc receptor-mediated sequestration in non-target tissues 31-33. ADC therapy is an emerging and innovative approach to cancer treatment but relies heavily upon in vitro characterization of mAbs, which is not necessarily correlative with their behavior in vivo. Accordingly, an important aspect of the present study was the use of 89Zr-immunoPET as a tool to select the most suitable mAb for ADC development. ImmunoPET is increasingly being used to provide a more accurate assessment of targeted delivery and uptake into tumors, pharmacokinetics, and normal tissue biodistribution of individual mAbs to predict the efficacy of ADCs

20-21

. Using standard in vitro assays for ADC characterization, we showed that 8F2 and

9G5 both bind LGR5 with similar affinity, internalize to lysosomes, and induce cancer cell cytotoxicity in the presence of secondary ADC. Through the use of 89Zr-immunoPET, however, we were able to further analyze differences in mAb properties in vivo and quantitatively

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determine that 8F2 uptake was 2-fold greater than 9G5, suggesting that an 8F2-based ADC would be more effective for toxin delivery to LGR5-positive tumors. This observation supports the therapeutic utility of 8F2 shown in our recent report where monomethyl auristatin E (MMAE)-conjugated 8F2 destroyed LGR5-positive gastrointestinal cancer cells in vitro and eradicated colon tumors in vivo 1. An independent study using a different LGR5 mAb conjugated with MMAE also showed tumor regression 2, further validating the utility of LGR5 as a target for ADC therapy. Since the conjugation of linkers and payloads can affect the hydrophobicity of mAbs, and hence their biodistribution, similar imaging methods could be applied to identify differences in the in vivo properties of ADCs and their corresponding unconjugated mAbs.

CONCLUSIONS We have developed novel 89Zr-labeled anti-LGR5 mAbs for evaluating the imaging potential of the cancer stem cell marker, LGR5, in colorectal tumors. Our data shows that 89Zr-labeled antiLGR5 mAbs can identify tumors with high LGR5 expression and that immunoPET may be used as a tool to improve mAb selection for development of LGR5-targeted ADCs. Furthermore, LGR5 imaging may be useful for stratifying patients which would respond best to an LGR5targeted ADC therapy and for monitoring treatment response. ASSOCIATED CONTENT Supporting Information Additional figures, including coomassie gel of purified mAbs, 293T-vector cell binding assay, HPLC of unconjugated and DFO-conjugated mAb, radio-ITLC showing radiochemical purity of 89

Zr-DFO-LGR5 mAb, and T/M ratios for biodistribution studies (PDF).

AUTHOR INFORMATION

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Corresponding Author *Email: [email protected]; Phone: 713-500-3390; Fax: 713-500-2447 Notes The authors declare no competing financial interest. ACKNOWLEDGEMENTS The authors thank the imaging core at The University of Texas Health Science Center at Houston for their support. This work was supported by a grant from the Cancer Prevention Research Institute of Texas, RP150640 (K.S. Carmon), Welch Foundation Endowment Fund (K.S Carmon), and John S. Dunn Research Scholar Fund (A. Azhdarinia).

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Evaluation of anti-LGR5 Antibodies by ImmunoPET for Imaging Colorectal Tumors and Development of Antibody-Drug Conjugates

Ali Azhdarinia1, Julie Voss1, Sukhen C. Ghosh1, Jo A. Simien1, Servando Hernandez Vargas1, Jie Cui3, Wangsheng A. Yu2, Qingyun Liu2, Kendra. S. Carmon2*

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