Combined treatment of the experimental human papilloma virus-16-positive cervical and head and neck cancers with cisplatin and radioimmunotherapy targeting viral E6 oncoprotein

Targeted radionuclide therapy for head and neck squamous cell carcinoma: a review

Head and neck squamous cell carcinoma (HNSCC) is a type of head and neck cancer that is aggressive, difficult to treat, and often associated with poor prognosis. HNSCC is the sixth most common cancer worldwide, highlighting the need to develop novel treatments for this disease. The current standard of care for HNSCC usually involves a combination of surgical resection, radiation therapy, and chemotherapy. Chemotherapy is notorious for its detrimental side effects including nausea, fatigue, hair loss, and more. Radiation therapy can be a challenge due to the anatomy of the head and neck area and presence of normal tissues. In addition to the drawbacks of chemotherapy and radiation therapy, high morbidity and mortality rates for HNSCC highlight the urgent need for alternative treatment options. Immunotherapy has recently emerged as a possible treatment option for cancers including HNSCC, in which monoclonal antibodies are used to help the immune system fight disease. Combining monoclonal antibodies approved by the US Food and Drug Administration, such as cetuximab and pembrolizumab, with radiotherapy or platinum-based chemotherapy for patients with locally advanced, recurrent, or metastatic HNSCC is an accepted first-line therapy. Targeted radionuclide therapy can potentially be used in conjunction with the first-line therapy, or as an additional treatment option, to improve patient outcomes and quality of life. Epidermal growth factor receptor is a known molecular target for HNSCC; however, other targets such as human epidermal growth factor receptor 2, human epidermal growth factor receptor 3, programmed cell death protein 1, and programmed death-ligand 1 are emerging molecular targets for the diagnosis and treatment of HNSCC. To develop successful radiopharmaceuticals, it is imperative to first understand the molecular biology of the disease of interest. For cancer, this understanding often means detection and characterization of molecular targets, such as cell surface receptors, that can be used as sensitive targeting agents. The goal of this review article is to explore molecular targets for HNSCC and dissect previously conducted research in nuclear medicine and provide a possible path forward for the development of novel radiopharmaceuticals used in targeted radionuclide therapy for HNSCC, which has been underexplored to date.

Approaches for Head and Neck Cancer Research - Current Status and the Way Forward

Head and neck cancers (HNCs) are seeing an increasing trend in their prevalence among both genders and are the seventh most common cancer type occurring at the global level. Studies addressing both the cancer cell physiology and individual differences in response to a specific treatment modality should be understood for arriving at effective treatment and management of the HNCs. In this article, we discuss the trends in HNC research and their various approaches starting from 2D in vitro models, which are the traditional experimental materials to recently established Cancer-Tissue Originated Spheroids (CTOS) distinctly contributing towards personalized or precision medicine.

Monoclonal Antibodies Against Human Papillomavirus E6 and E7 Oncoproteins Inhibit Tumor Growth in Experimental Cervical Cancer

Nearly all cases of cervical cancer are initiated by persistent infection with high-risk strains of human papillomavirus (hr-HPV). When hr-HPV integrates into the host genome, the constitutive expression of oncogenic HPV proteins E6 and E7 function to disrupt p53 and retinoblastoma regulation of cell cycle, respectively, to favor malignant transformation. HPV E6 and E7 are oncogenes found in over 99% of cervical cancer, they are also expressed in pre-neoplastic stages making these viral oncoproteins attractive therapeutic targets. Monoclonal antibodies (mAbs) represent a novel potential approach against the actions of hr-HPV E6 and E7 oncoproteins. In this report, we describe the utilization of anti-HPV E6 and HPV E7 mAbs in an experimental murine model of human cervical cancer tumors. We used differential dosing strategies of mAbs C1P5 (anti-HPV 16 E6) and TVG701Y (anti-HPV E7) administered via intraperitoneal or intratumoral injections. We compared mAbs to the action of chemotherapeutic agent Cisplatin and demonstrated the capacity of mAbs to significantly inhibit tumor growth. Furthermore, we investigated the contribution of the immune system and found increased complement deposition in both C1P5 and TVG701Y treated tumors compared to irrelevant mAb therapy. Taken together, the results suggest that anti-HPV E6 and E7 mAbs exert inhibition of tumor growth in a viral-specific manner and stimulate an immune response that could be exploited for an additional treatment options for patients.

Evaluation of novel highly specific antibodies to cancer testis antigen Centrin-1 for radioimmunoimaging and radioimmunotherapy of pancreatic cancer

Background

Pancreatic ductal adenocarcinoma (PDAC) accounts for >90% of pancreatic malignancies, and has median survival of <6 months. There is an urgent need for diagnostic and therapeutic options for PDAC. Centrin1 (CETN1) is a novel member of Cancer/Testis Antigens, with a 25‐fold increase of CETN1 gene expression in PDX from PDAC patients. The absence of selective anti‐CETN1 antibodies is hampering CETN1 use for diagnosis and therapy. Here we report the generation of highly specific for CETN1 antibodies and their evaluation for radioimmunoimaging and radioimmunotherapy (RIT) of experimental PDAC.

Methods

The antibodies to CETN1 were generated via mice immunization with immunogenic peptide distinguishing CETN1 from CETN2. Patient tumor microarrays were used to evaluate the binding of the immune serum to PDAC versus normal pancreas. The antibodies were tested for their preferential binding to CETN1 over CETN2 by ELISA. Mice bearing PDAC MiaPaCa2 xenografts were imaged with microSPECT/CT and treated with ²¹³Bi‐ and ¹⁷⁷Lu‐labeled antibodies to CETN1.

Results

Immune serum bind to 50% PDAC cases on patient tumor microarrays with no specific binding to normal pancreas. Antibodies demonstrated preferential binding to CETN1 versus CETN2. Antibody 69‐11 localized to PDAC xenografts in mice in vivo and ex vivo. RIT of PDAC xenografts with ²¹³Bi‐labeled antibodies was effective, safe, and CETN1‐specific.

Conclusions

The results demonstrate the ability of these novel antibodies to detect CETN1 both in vitro and in vivo; as well, the RIT treatment of experimental PDAC when radiolabeled with ²¹³Bi is highly efficient and safe. Further evaluation of these novel reagents for diagnosis and treatment of PDAC is warranted.

Pharmacodynamic study of 131I-labeled CA215 antibody on an animal model of estrogen-resistant OC-3-VGH ovarian cancer

The aim of the present study was to explore the inhibitory effect of ¹³¹I-labeled ovarian cancer antigen 215 (¹³¹I-CA215) antibody on human OC-3-VGH ovarian cancer. A subcutaneous transplanted tumor model of estrogen-resistant human OC-3-VGH ovarian cancer in nude mice was established. The model mice were randomly divided into seven groups, which were the negative control (NC), positive control (PC; 60 mg/kg cyclophosphamide), high-dose CA215 antibody (HA; 10 mg/kg), low-dose CA215 antibody (LA; 2 mg/kg), high-dose ¹³¹I-CA215 antibody (¹³¹I-HA; 10 mg/kg + 125 μCi), medium-dose ¹³¹I-CA215 antibody (¹³¹I-MA; 6 mg/kg + 75 μCi) and low-dose ¹³¹I-CA215 antibody (¹³¹I-LA; 2 mg/kg + 25 μCi) groups. Each group received intraperitoneal administration for 14 consecutive days. At 24 h after the final administration, the tumor was removed and weighed to calculate the tumor inhibition rate (TIR) and the relative tumor increase rate (T/C). Compared with the NC group, the HA group, as well as the ³¹I-HA and ¹³¹I-MA antibody groups, exhibited significantly inhibited tumor growth. The relative T/C values were 54, 30 and 48%, respectively, and the TIRs were 33.59, 64.89 and 45.80%, respectively. All differences were statistically significant. The difference between the HA and ¹³¹I-HA groups also presented statistical significance. CA215 and ¹³¹I-CA215 antibodies can markedly inhibit OC-3-VGH ovarian cancer. The high-dose ¹³¹I-CA215 antibody demonstrated a clear synergetic effect.

Beta emitters rhenium-188 and lutetium-177 are equally effective in radioimmunotherapy of HPV-positive experimental cervical cancer

Cervical cancer caused by the infection with the human papillomavirus (HPV) remains the fourth leading killer of women worldwide. Therefore, more efficacious treatments are needed. We are developing radioimmunotherapy (RIT) of HPV‐positive cervical cancers by targeting E6 and E7 viral oncoproteins expressed by the cancer cells with the radiolabeled monoclonal antibodies (mAbs). To investigate the influence of different radionuclides on the RIT efficacy—we performed RIT of experimental cervical cancer with Rhenium‐188 (¹⁸⁸Re) and Lutetium‐177 (¹⁷⁷Lu)‐labeled mAb C1P5 to E6. The biodistribution of ¹⁸⁸Re‐ and ¹⁷⁷Lu‐labeled C1P5 was performed in nude female mice bearing CasKi cervical cancer xenografts and the radiation dosimetry calculations for the tumors and organs were carried out. For RIT the mice were treated with 7.4 MBq of either ¹⁸⁸Re‐C1P5 or ¹⁷⁷Lu‐C1P5 or left untreated, and observed for their tumor size for 28 days. The levels of ¹⁸⁸Re‐ and ¹⁷⁷Lu‐C1P5 mAbs‐induced double‐strand breaks in CasKi tumors were compared on days 5 and 10 post treatment by staining with anti‐gamma H2AX antibody. The radiation doses to the heart and lungs were similar for both ¹⁷⁷Lu‐C1P5 and ¹⁸⁸Re‐C1P5. The dose to the liver was five times higher for ¹⁷⁷Lu‐C1P5. The doses to the tumor were 259 and 181 cGy for ¹⁷⁷Lu‐C1P5 and ¹⁸⁸Re‐C1P5, respectively. RIT with either ¹⁷⁷Lu‐C1P5 or ¹⁸⁸Re‐C1P5 was equally effective in inhibiting tumor growth when each was compared to the untreated controls (P = 0.001). On day 5 there was a pronounced staining for gamma H2AX foci in ¹⁷⁷Lu‐C1P5 group only and on day 10 it was observed in both ¹⁷⁷Lu‐C1P5 and ¹⁸⁸Re‐C1P5 groups. ¹⁸⁸Re‐ and ¹⁷⁷Lu‐labeled mAbs were equally effective in arresting the growth of CasKi cervical tumors. Thus, both of these radionuclides are candidates for the clinical trials of this approach in patients with advanced, recurrent or metastatic cervical cancer.

Naive and radiolabeled antibodies to E6 and E7 HPV-16 oncoproteins show pronounced antitumor activity in experimental cervical cancer

BACKGROUND

In spite of profound reduction in incidence, cervical cancer claims >275,000 lives annually. Previously we demonstrated efficacy and safety of radioimmunotherapy directed at HPV16 E6 oncoprotein in experimental cervical cancer.

MATERIALS & METHODS

We undertook a direct comparison of targeting E7 and E6 oncoproteins with specific (188)Rhenium-labeled monoclonal antibodies in CasKi subcutaneous xenografts of cervical cancer cells in mice.

RESULTS

The most significant tumor inhibition was seen in radioimmunotherapy-treated mice, followed by the unlabeled monoclonal antibodies to E6 and E7. No hematological toxicity was observed. Immunohistochemistry suggests that the effect of unlabeled antibodies is C3 complement mediated.

CONCLUSION

We have demonstrated for the first time that radioimmunotherapy directed toward E7 oncoprotein inhibits experimental tumors growth, decreases E7 expression and may offer a novel approach to cervical cancer therapy.

Branched amphiphilic peptide capsules: cellular uptake and retention of encapsulated solutes

Branched amphiphilic peptide capsules (BAPCs) are peptide nano-spheres comprised of equimolar proportions of two branched peptide sequences bis(FLIVI)-K-KKKK and bis(FLIVIGSII)-K-KKKK that self-assemble to form bilayer delimited capsules. In two recent publications we described the lipid analogous characteristics of our BAPCs, examined their initial assembly, mode of fusion, solute encapsulation, and resizing and delineated their capability to be maintained at a specific size by storing them at 4°C. In this report we describe the stability, size limitations of encapsulation, cellular localization, retention and, bio-distribution of the BAPCs in vivo. The ability of our constructs to retain alpha particle emitting radionuclides without any apparent leakage and their persistence in the peri-nuclear region of the cell for extended periods of time, coupled with their ease of preparation and potential tune-ability, makes them attractive as biocompatible carriers for targeted cancer therapy using particle emitting radioisotopes. This article is part of a Special Issue entitled: Interfacially Active Peptides and Proteins. Guest Editors: William C. Wimley and Kalina Hristova.

Rational development of radiopharmaceuticals for HIV-1

The global battle against HIV-1 would benefit from a sensitive and specific radiopharmaceutical to localize HIV-infected cells. Ideally, this probe would be able to identify latently infected host cells containing replication competent HIV sequences. Clinical and research applications would include assessment of reservoirs, informing clinical management by facilitating assessment of burden of infection in different compartments, monitoring disease progression and monitoring response to therapy. A "rational" development approach could facilitate efficient identification of an appropriate targeted radiopharmaceutical. Rational development starts with understanding characteristics of the disease that can be effectively targeted and then engineering radiopharmaceuticals to hone in on an appropriate target, which in the case of HIV-1 (HIV) might be an HIV-specific product on or in the host cell, a differentially expressed gene product, an integrated DNA sequence specific enzymatic activity, part of the inflammatory response, or a combination of these. This is different from the current approach that starts with a radiopharmaceutical for a target associated with a disease, mostly from autopsy studies, without a strong rationale for the potential to impact patient care. At present, no targeted therapies are available for HIV latency, although a number of approaches are under study. Here we discuss requirements for a radiopharmaceutical useful in strategies targeting persistently infected cells. The radiopharmaceutical for HIV should be developed based on HIV biology, studied in an animal model and then in humans, and ultimately used in clinical and research settings.

Effect of naive and radiolabeled rhTRAIL on the cervical cancer xenografts in mice

BACKGROUND

There is a need for novel treatments of advanced cervical cancer. We investigated the utility of recombinant human TNF-related apoptosis-inducing ligand (rhTRAIL), a molecule capable of inducing apoptosis in cancer cells, for the therapy of CasKi cervical cancer xenografts in nude mice.

RESULTS

CasKi cells proved to be sensitive in vitro to rhTRAIL with an IC50 of 120 ng/ml. (125)I-tagged rhTRAIL specifically accumulated in CasKi tumors in mice with the highest uptake of 9.4% ID/g at 2 h post-injection. Both naive and 200 µCi (188)Re-tagged rhTRAIL administered in the amount of 0.35 mg/kg body weight significantly retarded CasKi tumor growth to the same extent in mice without the side effects of cisplatin chemotherapeutic control.

CONCLUSION

rhTRAIL is a promising novel agent for treatment of advanced cervical cancer.

Uptake, internalization and nuclear translocation of radioimmunotherapeutic agents

Radioimmunotherapy (RIT) agents that incorporate short-range particle-emitting radionuclides exploit the high linear energy transfer of α-particles and Auger electrons. Both are densely ionizing, generate complex DNA double-strand breaks and so are profoundly cytotoxic. Internalizing RIT agents enter tumor cells through receptor-mediated endocytosis and by incorporation of cell-penetrating peptides. Once internalized, some RIT agents mediate escape from endosomes and/or translocate to the nucleus. In the classical nuclear import pathway, α/β-importins recognize nuclear localization sequences in RIT agents. Translocation through nuclear pores enables RIT agents to bind to nuclear targets induced by, for example, cellular stress, growth factors or anticancer therapy, such as γH2AX or p27(KIP-1). This review discusses RIT agents designed to exploit the mechanisms underlying these complex processes and compares them with noninternalizing RIT agents.