In vitro and in vivo characterization of [⁶⁴Cu][Cu(elesclomol)] as a novel theranostic agent for hypoxic solid tumors

The idea behind theranostics is to use one single agent for both diagnostic and therapeutic purposes. This is particularly relevant in nuclear medicine using diagnostic imaging modalities like positron emission tomography (PET) or single-photon emission computed tomography (SPECT). In PET and SPECT, a radioactive molecule is injected that will accumulate in the region the molecule is engineered to target. By detecting the radioactivity using a scanner, the presence and distribution of the radioactive molecule in the target can be imaged and quantified. For cancer, the target commonly represents the malignancy as a whole or a critical part of the malignancy. By exposing the target with short-range, therapeutic high dose radiation, the malignancy can be eliminated, while the treatment effect can be monitored with PET/computed tomography (CT) or PET/magnetic resonance imaging (MRI). Cancer theranostic is therefore a highly specific and promising diagnostic and therapeutic strategy that can enable personalized cancer treatment [1].

Tumor hypoxia describes the adverse condition within the tumor microenvironment (TME) where the tissue oxygenation is deprived as a result of the imbalance between supply and consumption, usually due to immature and chaotic development of the tumor vasculature [2]. It is well known that tumor hypoxia is associated with poor prognosis, due to resistance to chemo- and/or radiotherapy, disease progression, metastatic development, and higher probability of recurrence [3‐5]. However, the assessment of tumor hypoxia remains challenging. Conventional invasive methods, though being highly sensitive and accurate within the tissue that is sampled, lack general representation of the tumor microenvironment and are limited by accessibility of the tumor [6]. Non-invasive methods, in particular PET, has emerged as a more sensitive and representative method for hypoxia detection. The copper-based hypoxia PET tracer [⁶⁴Cu][Cu-diacetyl-bis(N4-methylthiosemicarbazone)] ([⁶⁴Cu][Cu(ATSM)]) has demonstrated favorable potentials compared to the fluorine-based tracers such as [¹⁸F]fluoromisonidazole ([¹⁸F]F-MISO) or [¹⁸F]fluoroazomycin arabinoside ([¹⁸F]F-FAZA). Although [¹⁸F]F-MISO is shown to detect tissue oxygenation, it suffers from slow uptake and clearance (images usually taken at least 4 h after injection), leading to poor image quality, questionable representations due to the dynamic nature of hypoxia, in addition to lengthy examination time. On the other hand, [¹⁸F]F-FAZA is significantly more hydrophilic and suffers from poor penetration of the blood–brain-barrier as well as high urinary bladder uptake [7‐9]. However, the tracer uptake mechanism remains controversial, having a similar in vivo distribution as ionic copper [7, 10, 11]. Although prior studies have demonstrated promising results from the use of [⁶⁴Cu]CuCl₂ and [⁶⁴Cu][Cu(ATSM)] as theranostic agents, newer copper-based candidates are being investigated in order to optimize both the diagnostic and therapeutic potential for targeting aggressive, hypoxic tumor cells [12‐18].

Elesclomol (ES) is a chemotherapeutic drug that has been evaluated clinically for metastatic melanoma. ES targets the mitochondria of cancer cells with elevated oxidative stress, where it subsequently induces apoptosis [19‐22]. The efficacy of ES is rationalized by chelation with copper outside of the cells and entered as Cu(II)-ES (Cu(ES)), where Cu(II) is reduced to Cu(I) while reactive oxygen species (ROS) are generated [18]. This mechanism presents an opportunity to combine ES with Cu-64 and use [⁶⁴Cu][Cu(ES)] as a theranostic agent for hypoxic tumors, especially for regions with over reduced intracellular state as a result of hypoxia [23]. In addition to being a positron emitter, Cu-64 also emits low energy, high linear energy transfer (LET) Auger electrons, which have demonstrated to induce tumor cell death with high efficiency [24, 25]. With [⁶⁴Cu][Cu(ES)], Cu-64 is delivered into the tumor mitochondria by the help of ES in order to induce the high-LET therapeutic radiation effect, while the chemical concentration of ES remains orders of magnitudes below toxic level.

In this study, our first aim was to implement a production method of [⁶⁴Cu]CuCl₂ and subsequently label ATSM and ES in high molar activity. ES has not been labeled with [⁶⁴Cu]CuCl₂ before. Secondly, we aimed to investigate the therapeutic effects of [⁶⁴Cu][Cu(ES)] as compared to [⁶⁴Cu]CuCl₂ and [⁶⁴Cu][Cu(ATSM)], both in vitro using cell cultures from prostate cancer and glioblastoma and in vivo in prostate cancer xenografts receiving single- and multiple doses of [⁶⁴Cu][Cu(ES)] in comparison to [⁶⁴Cu][Cu(ATSM)]. Third, the potential of [⁶⁴Cu][Cu(ES)] to detect tumor hypoxia compared to [⁶⁴Cu]CuCl₂ and [⁶⁴Cu][Cu(ATSM)] was evaluated with PET/MR imaging of both prostate and glioblastoma xenografts.

The average molar activity of the buffered [⁶⁴Cu]CuCl₂ solution was 199 ± 148 GBq/µmol end of production (EOP) based on ICP-MS. The yield of [⁶⁴Cu]CuCl₂ at EOP was 1.14 ± 2.7 MBq/(μAh·mg), giving approximately 5–6 GBq [⁶⁴Cu]CuCl₂ in 2 mL of volume. The final pH of the solution was 4.7 ± 0.2. The radiolabeling yielded a product with radiochemical purity ≥ 98% and molar activity 166 ± 81 GBq/µmol end of synthesis (EOS) for [⁶⁴Cu][Cu(ES)], as analyzed with HPLC (Fig. 1). The stability of [⁶⁴Cu][Cu(ES)] was evaluated in both mouse and human serum, confirming that [⁶⁴Cu][Cu(ES)] is stable in serum during 4 h, as shown in Supplementary Figure S1.

Treatment with [⁶⁴Cu][Cu(ES)] resulted in reduced survival in all three cell lines (Fig. 2a–c). With an activity of 128 Bq/cell, [⁶⁴Cu][Cu(ES)] effectively reduced the survival of U-87MG cells to 3.5% ± 1.8% (p = 0.003 compared to the control) in normoxia and 5.1% ± 1.4% (p = 0.001) in hypoxia, while treatment with [⁶⁴Cu][Cu(ATSM)] gave a survival of 54.7% ± 5.5% (p = 0.009) in normoxia and 65.2% ± 3.2% (p = 0.172) in hypoxia. Treatment with [⁶⁴Cu]CuCl₂ gave only around 15% reduced survival in U-87MG cells in both normoxia and hypoxia compared to the untreated control. In the 22Rv1 and PC3 cells, the same trend as with U-87MG were seen, although the percentage of survival reduction was lower. For all three cell lines, the hypoxic cells were more resistant to treatment with [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu][Cu(ES)] than the cells in normoxia, whereas the treatment with [⁶⁴Cu]CuCl₂ was less affected by hypoxia. The induction of hypoxia was confirmed by the expression of HIF-1α in Western blots in both treated and untreated samples (Fig. 2d, e).

Whole cell uptake studies showed that hypoxia increased the uptake of Cu-64 in all three cell lines (22Rv1, PC3, U-87MG) (Fig. 3a). For [⁶⁴Cu]CuCl₂, the increase was low but significant for PC3 and U-87MG (p = 0.008, p < 0.001, respectively), while for [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu][Cu(ES)], the increased uptake in hypoxia was higher and significant for all three cell lines ([⁶⁴Cu][Cu(ATSM)]: p = 0.014, 0.007, 0.022, respectively, and [⁶⁴Cu][Cu(ES)]: p = 0.013, 0.001, 0.006, respectively). Overall, both [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu][Cu(ES)] had higher uptake of Cu-64 compared to [⁶⁴Cu]CuCl₂ for both normoxic and hypoxic cells across all cell lines. The level of uptake was similar in 22Rv1 and PC3 cells, while the U-87MG cells had higher uptake both in normoxic and hypoxic cells.

When investigating the internalization of Cu-64, it was confirmed that most of the Cu-64 was in the cytoplasm, while some also was transferred into the cell nucleus (Fig. 3b). Compared to normoxic cells, the uptake in both the nucleus and cytoplasm increased for hypoxic cells from all three cell lines. This effect was not significant for treatment with [⁶⁴Cu]CuCl₂, while for both [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu][Cu(ES)], the effect was significant for both the nuclear and cytoplasmic uptake, although the effect was most pronounced for [⁶⁴Cu][Cu(ATSM)]. [⁶⁴Cu][Cu(ES)] demonstrated a higher uptake in normoxic cells than both [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu]CuCl₂.

Dynamic PET/MRI of 22Rv1 xenografts showed that administration of both [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu][Cu(ES)] resulted in increasing accumulation of Cu-64 activity in the xenograft compared to normal tissue (muscle) (Fig. 4a). As in other studies with Cu-64, liver is the organ with the highest uptake. The increase did not reach maximum during the 90 min scan time. Hypoxia staining of excised tissue revealed colocalization of PET hotspots with hypoxic areas (Fig. 4b). In a separate experiment, static PET/MRI 3 h after injection of [⁶⁴Cu]CuCl₂, [⁶⁴Cu][Cu(ATSM)], and [⁶⁴Cu][Cu(ES)] identified similar signal intensity and uptake patterns in the 22Rv1 xenografts (Fig. 4d). The imaging experiment was also repeated with U-87MG xenografts, confirming the same effects for [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu][Cu(ES)].

The absorbed doses of relevant organs from two healthy animals injected with [⁶⁴Cu][Cu(ES)] was estimated for the following organs: kidneys (76.3 ± 17.1 mGy/MBq), liver (221.2 ± 42.4 mGy/MBq), spleen (30.5 ± 4.2 mGy/MBq), lung (79.9 ± 9.3 mGy/MBq), and brain (69.7 ± 1.74 mGy/MBq).

An unexpected finding was the discovery of the differences in brain uptake after administration of [⁶⁴Cu]CuCl₂, [⁶⁴Cu][Cu(ATSM)], and [⁶⁴Cu][Cu(ES)]. [⁶⁴Cu]CuCl₂ did not show any significant brain uptake, [⁶⁴Cu][Cu(ATSM)] was taken up in the frontal region of the brain, while [⁶⁴Cu][Cu(ES)] appeared to have crossed the blood brain barrier (BBB), showing a high uptake across the whole brain (Fig. 5).

When evaluating the therapeutic effects, administration of [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu][Cu(ES)] both reduced the tumor growth in 22Rv1 mouse xenografts (Fig. 6). Compared to the untreated animals, a single dose of [⁶⁴Cu][Cu(ATSM)] gave a small tumor growth inhibition. The single dose of [⁶⁴Cu][Cu(ES)] resulted in significantly reduced tumor growth compared to the control animals. The multiple doses of [⁶⁴Cu][Cu(ES)] gave the most significant reduction of tumor growth.

In this study, we implemented a method for improved production of [⁶⁴Cu]CuCl₂ and labeled it, for the first time, to ES to achieve [⁶⁴Cu][Cu(ES)]. The improved production method removed the need of a second synthesis module, as reported previously [27], and reduced the final volume of [⁶⁴Cu]CuCl₂ to 2 mL while maintaining similar yield and quality. In vitro studies in three cell lines from prostate cancer and glioblastoma showed that [⁶⁴Cu][Cu(ES)] reduced cell survival more effectively than both [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu]CuCl₂. In vivo studies in xenografts in mice confirmed the superior therapeutic effects of [⁶⁴Cu][Cu(ES)] and also demonstrated the ability of [⁶⁴Cu][Cu(ES)] to detect tumor hypoxia using PET imaging.

Elesclomol was in the late 2000s investigated as a chemotherapeutic drug for treatment of metastatic melanoma, entering clinical trials both as a single agent and in combination with paclitaxel. However, ES failed short in a phase III clinical trial due to efficacy and toxicity concerns when used in combination with paclitaxel [19, 20, 30‐33]. Recently, the interest in ES has regained, both for treating copper metabolism related disorders, and as a cancer treatment [34‐39]. Notably, when used as a theranostic agent with Cu-64, the chemical amount of ES is much lower than when used as traditional chemotherapy. The mechanism of action of ES involves the transportation of copper into the mitochondria of tumor cells, targeting the mitochondrial electron transport chain (ETC), where Cu(II) is reduced to Cu(I), generating excess ROS and elevating oxidative stress, ultimately inducing cellular apoptosis [19‐21, 30]. Recent investigations have suggested that cuproptosis, a newly discovered form of programmed cell death which involves copper binding to lipoylated components of the tricarboxylic acid cycle (TCA), might explain the mechanism of action of ES [39, 40].

One of the most important cellular responses to hypoxia is the activation of HIF-1α [41‐44]. Under experimentally controlled hypoxia where the induction of HIF-1α was confirmed, we showed in our in vitro investigation that [⁶⁴Cu][Cu(ES)] accumulates in tumor cells, and that the uptake of Cu-64 significantly increases compared to normoxic tumor cells treated with [⁶⁴Cu][Cu(ES)] (Figs. 2 and 3). Among a series of adaptive genetic responses, HIF-1 regulates the mitochondrial respiration [45]. In hypoxia, HIF-1 actively downregulates oxygen consumption by inhibiting mitochondrial respiration, inducing the expression of pyruvate dehydrogenase kinase 1 (PDK1), inactivating the TCA cycle and diverting glucose metabolites to glycolysis, resulting in an altered ETC in mitochondria [42, 45‐49]. Based on the mechanism of actions of ES, [⁶⁴Cu][Cu(ES)] targets the mitochondrial metabolism in tumor cells and the increased accumulation in hypoxia is likely attributable to the altered ETC in dysfunctional mitochondria within hypoxic cells. The lack of oxygen as terminal electron acceptors in the mitochondrial respiratory chain produces a reductive intracellular microenvironment with excess nicotinamide adenine dinucleotide (NADH) and flavin adenine dinucleotide (FADH2), in which Cu(II) can be reduced to Cu(I) and retain in the region [19, 20, 30, 47, 50, 51]. This indicates that [⁶⁴Cu][Cu(ES)] targets a dysfunctional, reductive mitochondrial microenvironment as a result of hypoxia.

Previously, [⁶⁴Cu][Cu(ATSM)] was considered a promising theranostic candidate for hypoxic tumors [12‐14, 52‐54]. However, challenges and controversies regarding the retention mechanism of [⁶⁴Cu][Cu(ATSM)] has limited its use, especially as similar results have been obtained for ionic Cu-64 substances, such as [⁶⁴Cu]CuCl₂ and ⁶⁴Cu-acetate [10, 11, 55]. Our in vitro and in vivo studies demonstrated that [⁶⁴Cu][Cu(ES)] reduced tumor cell survival and tumor growth significantly more effective than both [⁶⁴Cu]CuCl₂ and [⁶⁴Cu][Cu(ATSM)] (Figs. 2 and 6). The lower therapeutic effects of [⁶⁴Cu]CuCl₂ is explained by that the ionic Cu(II) lacks passive penetration through the cellular membrane and relies solely on active copper transporter 1 (CTR-1) transportation, resulting in less cellular uptake and internalization. On the contrary, [⁶⁴Cu][Cu(ATSM)], which has similar uptake and internalization in hypoxia as [⁶⁴Cu][Cu(ES)], shows intriguing results. The reported hypoxic retention mechanism of [⁶⁴Cu][Cu(ATSM)] involves the reduction of Cu(II) to Cu(I) through disturbed electron flow by NADH/NADPH in the dysfunctional mitochondria under hypoxia. This serves as an indicator of an overreduced intracellular state and mitochondrial disorder, which, to a certain extent, is comparable to the retention mechanism of [⁶⁴Cu][Cu(ES)] [23, 56]. Other studies have challenged the proposed retention mechanism of [⁶⁴Cu][Cu(ATSM)], highlighting the similarity in uptake and in vivo biodistribution between [⁶⁴Cu][Cu(ATSM)] and the ionic compounds ⁶⁴Cu-acetate or [⁶⁴Cu]CuCl₂, suggesting the instability of [⁶⁴Cu][Cu(ATSM)] in blood and the potential role of copper itself in the retention mechanism [10, 11, 55]. Despite the controversies, our data suggests that [⁶⁴Cu][Cu(ES)], [⁶⁴Cu][Cu(ATSM)], and [⁶⁴Cu]CuCl₂ have different in vivo uptake in mice. This is seen in the tumor uptake (Fig. 4), but more prominently by the differences in brain uptake, where [⁶⁴Cu]CuCl₂ does not show any uptake, [⁶⁴Cu][Cu(ATSM)] shows a unique hotspot uptake in the frontal region of the brain, and [⁶⁴Cu][Cu(ES)] shows an overall uptake covering the entire brain (Fig. 5). This is an unexpected, yet very exciting finding that warrants further investigations and that might represent an avenue for developing a new treatment option for brain tumors. This result contradicts the hypothesis that [⁶⁴Cu][Cu(ATSM)] disintegrates immediately upon contact with blood and that the uptake is solely through the copper metabolism pathways, but rather highlights the functional aspect of the complexing ligands. Considering the structural differences between [⁶⁴Cu][Cu(ES)] and [⁶⁴Cu][Cu(ATSM)], the discrepancy in biodistribution and cytotoxicity, despite the similarity of uptake mechanisms, may attribute to the difference in lipophilicity (logP = 2.45 for [⁶⁴Cu][Cu(ES)] vs logP = 1.48 for [⁶⁴Cu][Cu(ATSM)]), which might contribute to better tissue penetration through passive diffusion. The reduction potential (E° =  − 333 mV for [⁶⁴Cu][Cu(ES)] vs E° =  − 590 mV for [⁶⁴Cu][Cu(ATSM)]) of the copper complexes, which determines the point of reduction, is higher (less negative) for [⁶⁴Cu][Cu(ES)] than [⁶⁴Cu][Cu(ATSM)]), thus requires the TME to be more reductive [15, 20, 57, 58]. Meanwhile, Auger electron emission is the main cause of cytotoxicity of Cu-64, and the important aspect for Auger electrons to be effective is the close proximity to the target [49]. For Cu-64, the Auger electrons have an average energy of 2 keV and an average range of 126 nm with an estimated LET of 7 keV/μm [24, 25, 59]. The average size of a mammalian cell is approximately 10–100 μum in diameter, and a typical mitochondrion has a diameter of 0.5–1 μm [60, 61]. It may be hypothesized that [⁶⁴Cu][Cu(ES)] is able to deliver Cu-64 into regions that are closer to nuclear and/or mitochondrial DNA, where the TME is more reductive, and even with a small decrease in distance, it might induce considerably more DNA double strand breaks (DSB) than [⁶⁴Cu][Cu(ATSM)]. In addition, the effect of radiation from Cu-64 complements and amplifies the mechanism of action of ES, in that ES acts both as a vehicle to deliver Cu-64 into the sensitive region and by itself an active ROS generator. The possible synergetic effects of Cu-64, as a positron and Auger electron emitter, and ES, which targets the hypoxic dysfunctional mitochondrial metabolism, suggest that [⁶⁴Cu][Cu(ES)] may be an ideal candidate for a hypoxia theranostic agent. Furthermore, by targeting the hypoxic mitochondria metabolism, [⁶⁴Cu][Cu(ES)] may be effective against cancer stem cells (CSCs), in which mitochondria play an essential role. CSCs are proposed to selectively accumulate in regions where the TME is highly reductive while activation of HIF-1 promotes the epithelial-to-mesenchymal transition, although further investigations are needed to provide sufficient evidence [16‐18, 62‐67].

In our in vivo therapy study, we demonstrate the effect of [⁶⁴Cu][Cu(ES)] through inhibited tumor growth in the 22Rv1 prostate cancer xenograft, in comparison with [⁶⁴Cu][Cu(ATSM)] and untreated tumors (Fig. 6). Therapeutic effects of [⁶⁴Cu]CuCl₂ and [⁶⁴Cu][Cu(ATSM)] have been previously demonstrated by Ferrari et al. and Yoshii et al. [13, 14]. The administration of a single dose of [⁶⁴Cu][Cu(ES)] resulted in a larger growth inhibition and longer survival than a single dose of [⁶⁴Cu][Cu(ATSM)]. Furthermore, multiple-dose treatment with [⁶⁴Cu][Cu(ES)] gave a further and significant inhibition of tumor growth, although the survival was slightly less than for the mice receiving single-dose [⁶⁴Cu][Cu(ES)], which can be explained by larger initial tumor volumes at the start of treatment (longest diameter of ~ 8 mm for [⁶⁴Cu][Cu(ES)] multiple dose group vs ~ 5 mm for the other groups). This was caused by logistics that prevented production of [⁶⁴Cu][Cu(ES)] when tumors had diameters of ~ 5 mm in both groups. Nevertheless, the in vivo tumor growth curve is consistent with the in vitro clonogenic (Fig. 2), demonstrating the that [⁶⁴Cu][Cu(ES)] is a candidate therapeutic agent.

Although Cu-64 radiopharmaceuticals represent a promising potential as a theranostic agent, it is not without limitations. For instance, while the gamma emission benefits the imaging aspect, it also carries the risk of giving a gamma emission burden when a therapeutic dose is given. Therefore, continued investigations must be carried out to evaluate the benefits of using Cu-64 compared to other radionuclides, such as Cu-67. Although the brain uptake is an intriguing finding, this might limit the use of [⁶⁴Cu][Cu(ES)] as a therapeutic agent in certain tumors. As almost all other radiocopper-based radiopharmaceuticals, Cu-64 is eventually accumulated in the liver, and thus results in a high liver dose. The implication, however, remains not well studied and would be of interest for further investigations.

Following implementation of an improved production method of [⁶⁴Cu]CuCl₂, this is, to the best of our knowledge, the first time that ES is radiolabeled with [⁶⁴Cu]CuCl₂ to [⁶⁴Cu][Cu(ES)]. In vitro and in vivo studies demonstrated that [⁶⁴Cu][Cu(ES)] reduced cell survival and inhibited tumor growth more effectively than both [⁶⁴Cu][Cu(ATSM)] and [⁶⁴Cu]CuCl₂. In addition, we demonstrated that PET imaging of tumor hypoxia with [⁶⁴Cu][Cu(ES)] was feasible. Together, this shows the potential of [⁶⁴Cu][Cu(ES)] as a promising theranostic agent for hypoxic solid tumors. The unexpected finding of brain uptake from [⁶⁴Cu][Cu(ES)] is interesting and warrants further investigations.