A surgical window of opportunity trial evaluating the effect of the PCSK9 inhibitor evolocumab on tumoral MHC-I expression and CD8<sup>+</sup> infiltration in glioma.
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2025-10
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Abstract
Many cancers evade immunosurveillance by downregulating surface major histocompatibility class (MHC)-I. Proprotein convertase subtilisin/kexin type 9 (PCSK9) promotes MHC-I degradation and is elevated in glioma. Evolocumab is a clinically approved PCSK9 inhibitor which restores MHC-I expression in pre-clinical cancer models. However, monoclonal antibodies have limited blood brain/tumor barrier penetrance (BBB/BTB). We conducted a window-of-opportunity trial, evaluating evolocumab's BBB/BTB penetrance and biological effect (PesKE; NCT04937413). Patients with newly diagnosed or recurrent glioma undergoing a clinically indicated biopsy or resection were enrolled (n = 32, M: 16, F: 16; control average age: 51.85, evolocumab: 53). Intervention participants (n = 6) received a single subcutaneous evolocumab dose pre-procedure, of which 4 provided research tissue. No significant adverse events were observed. Evolocumab was detected in all analyzed intervention tissue, with an average tumor: blood ratio of 0.0222 (SD ± 0.0190), akin to other monoclonals. Evolocumab quantitation was 4.44× greater in contrast-enhancing (mean 0.0068 fmol/mcg (SD ± 0.001)) vs non-contrast enhancing cases (mean 0.0015 fmol/mcg (SD ± 0.0004)). Proteomic analysis found positive trends between evolocumab and MHC-I subtypes (HLA-A-C, E-G), with a significant positive correlation with HLA-H (R2 = 0.9584, p = 0.021*). Tumor tissue with higher evolocumab titers demonstrated increased surface MHC-I and CD8+ T cell infiltration. Increased CD8+ TNF, FASLG and GZMA transcription was observed in high titer tissue compared to low titer tissue and untreated controls. Pre-resection evolocumab is well tolerated but exhibits BBB/BTB penetrance akin to other monoclonal antibodies. Increased tumoral evolocumab/PCSK9i may enhance tumoral MHC-I/effector CD8+ infiltration. Future work will explore combining evolocumab with BBB/BTB opening therapies like low-intensity focused ultrasound.
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Singh, Kirit, Matthew W Foster, Marlene J Violette, Anna M Corcoran, Kelly M Hotchkiss, Chelsea O Railton, Emily E Blandford, Kathryn E Blethen, et al. (2025). A surgical window of opportunity trial evaluating the effect of the PCSK9 inhibitor evolocumab on tumoral MHC-I expression and CD8<sup>+</sup> infiltration in glioma. Scientific reports, 15(1). p. 37112. 10.1038/s41598-025-21064-9 Retrieved from https://hdl.handle.net/10161/34357.
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Scholars@Duke
Matthew Wolf Foster
David Michael Ashley
My career in cancer research dates more than two decades. I am credentialed in both pediatric and adult neuro-oncology practice and this has been the focus of my efforts in translational research and leadership. As evident from my publication and grant support record, my primary academic focus has been on neurologic tumors, the development of innovative therapies and approaches to care. These efforts have included basic and translational laboratory research. My experience includes moving laboratory findings in brain tumor immunology and epigenetics into early phase clinical trials. I have expertise in immuno-oncology, having developed and clinically tested dendritic cell vaccines and other immuno-therapeutics. My achievements in research have led to change in practice in the care of children and adults with brain tumors, including the introduction of new standards of practice for the delivery of systemic therapy. I am highly regarded for this work, as evidenced by numerous invitations to plenary sessions and symposia of international standing. I have been the principal investigator of a number of important national and international studies, both clinical and pre-clinical. I am recognized as a senior figure and opinion leader in neuro-oncology nationally and internationally. I have held several significant leadership roles, including Director of two major cancer centers, I served as the Chair of Medicine at Deakin University, the Program Director of Cancer Services at University Hospital Barwon Health, and Executive Director of the Western Alliance Academic Health Science Centre (Australia). I began my current position as Director of The Preston Robert Tisch Brain Tumor Center, Head, Preuss Laboratory, in March 2018. In this role, I am responsible for the clinical care, research, and educational program related to Brain Tumor Center. I am also a senior investigational neuro-oncologist within the adult brain tumor program at Duke.
Annick Desjardins
Henry Seth Friedman
Overview: Our laboratory is pursuing a comprehensive analysis of the biology and therapy of adult and childhood central nervous system malignancies, particularly high-grade medulloblastoma, glioma, and ependymoma.
Laboratory Studies: Active programs, using human adult and pediatric CNS tumor continuous cell lines, transplantable xenografts growing subcutaneously and intracranially in athymic nude mice and rats, and as well as in the subarachnoid space of the athymic nude rats, and patients tumor specimens, are defining:
1) the chemotherapeutic profile of medulloblastoma, adult and childhood glioma and ependymoma
2) mechanisms of resistance to classical bifunctional alkylators, nitrosoureas and methylators operational in malignant glioma and medulloblastoma, particularly DNA adduct and crosslink repair, O6-alkylguanine-DNA alkyltransferase elevation and DNA mismatch repair deficiency.
3) modulations designed to over come or circumvent specific mechanisms of resistance
4) the activity of signal pathway inhibitors of EGFR, m-tor and other targets
5) the therapeutic advantages of intrathecal and intratumoral drug delivery in the treatment of neoplastic meningitis and intracranial malignancies, respectively.
The results of the therapeutic studies to date have demonstrated the marked activity of alkylating agents, particularly melphalan and cyclophosphamide and the role of glutathione, AGT glutathione-S-transferase, abnormal drug transport and alterations in formation and repair of DNA-DNA crosslinks in modulating cytotoxicity of these agents. Modulations shown to be effective in enhancing alkylator activity/reversing alkylator resistance include BSO-mediated glutathione depletion, inhibition of DNA-DNA crosslink repair and inhibition of 06-alkylguanine-DNA alkyltransferase by 06-benzylguanine. Recent studies have demonstrated profound activity of temozolomide, CPT-11 topotecan, irofulven, and karenitecin as well as the combination of CPT-11 or topotecan plus BCNU or temozolomide. Successful treatment of neoplastic meningitis in nude rats with intrathecal 4-hydroperoxycyclophosphamide, melphalan, temozolomide and busulfan, and intracranial glioma in nude rats with intratumoral temozolomide has also been demonstrated. More recent studies have revealed cyclophosphamide resistance secondary to DNA interstrand crosslink repair. Additional studies have shown that cyclophosphamide crosslinks are formed at the 1,3 N7 position, serving as the basis for construction of a defined crosslink in a plasmid vector to assay for crosslink repair and allowing demonstration of the lack of a role of nucleotide excision repair. Mismatch repair deficiency has been shown as a mechanism mediating acquired methylator (procarbazine and temozolomide) resistance in an adult glioblastoma xenograft.
Clinical Studies: Clinical investigations are designed to translate laboratory programs into successful treatment for adults and children with malignant brain tumors, particularly medulloblastoma. Clinical trials for adults include phase II trials of temozolomide, ZD1839 (Iressa), karenitecin, and temozolomide plus O6-BG as well as phase I trials of topotecan plus BCNU, CPT-11 plus temozolomide, and PTK787 ± temozolomide or CCNU. Studies are in progress in children evaluating the activity CPT-11 plus temozolomide, intrathecal busulfan and cyclophosphamide/melphalan or cyclophosphamide/busulfan plus autologous bone marrow support . Extension of these studies to a larger cohort of patients is being performed nationally under the auspices of the Pediatric Brain Tumor Consortium (Henry S. Friedman -- Head of New Agents Committee).
Future studies will address the role of agents designed to decrease repair of interstrand crosslinks when given in combination with alkylating agents, as well as newer signal pathway inhibitors such as RAD001, PKI166, and DB-67.
Margaret Johnson
I am a neuro-oncologist, neurologist, and palliative care physician at the Preston Robert Tisch Brain Tumor Center. I also provide neuro-oncology expertise for the National Tele-Oncology Program and National Precision Oncology Program at the Veteran's Health Administration. My clinical and research interests encompass supportive care and palliative care with a special interest in older adults with brain tumors. The incidence of malignant brain tumors like glioblastoma and non-malignant tumors like meningioma affect aging populations and it is crucial to be able to provide better care for these patients.
Allan Howard Friedman
At the present time, I am participating in collaborative research in the areas of primary malignant brain tumors, epilepsy and subarachnoid hemorrhage.
Primary malignant brain tumors are increasing in frequency. Patients harboring glioblastoma, the most malignant primary brain tumor, have a life expectancy of less than one year. In collaboration with the Division of Neurology and the Department of Pathology, clinical and laboratory trials have been initiated to identify better treatment for this condition. At present, trials of monoclonal antibodies and novel chemotherapeutic agents are being carried out.
Although physicians have been interested in seizures since the time of Hippocrates, the origin of seizures remains obscure. At Duke University we have treated approximately thirty seizure patients a year by removing abnormal portions of brain. Tissue from these resections is being analyzed for genetics and receptor abnormalities. Positron emission tomography and magnetic resonance imaging are being used to ferret out the origin of the patient's seizures.
Approximately 28,000 patients each year suffer a ruptured intracranial aneurysm. Approximately ten percent of these patients have a genetic predisposition to forming intracranial aneurysms. In conjunction with the Division of Neurology, we are screening candidate genes searching for the cause of intracranial aneurysms.
Stephen Thomas Keir
Brain Tumors, Preclinical Testing, Translational Research
Roger Edwin McLendon
Brain tumors are diagnosed in more than 20,000 Americans annually. The most malignant neoplasm, glioblastoma, is also the most common. Similarly, brain tumors constitute the most common solid neoplasm in children and include astrocytomas of the cerebellum, brain stem and cerebrum as well as medulloblastomas of the cerebellum. My colleagues and I have endeavored to translate the bench discoveries of genetic mutations and aberrant protein expressions found in brain tumors to better understand the processes involved in the etiology, pathogenesis, and treatment of brain tumors. Using the resources of the Preston Robert Brain Tumor Biorepository at Duke, our team, consisting of Henry Friedman, Allan Friedman, and Hai Yan and lead by Darell Bigner, have helped to identify mutations in Isocitrate Dehydrogenase (IDH1 and IDH2) as a marker of good prognosis in gliomas of adults. This test is now offered at Duke as a clinical test. Working with the Molecular Pathology Laboratory at Duke, we have also brought testing for TERT promoter region mutations as another major test for classifying gliomas in adults. Our collaboration with the Toronto Sick Kids Hospital has resulted in prognostic testing for childhood medulloblastomas, primitive neuroectodermal tumors, and ependymomas at Duke.
John Howard Sampson
Current research activities involve the immunotherapeutic targeting of a tumor-specific mutation in the epidermal growth factor receptor. Approaches used to target this tumor-specific epitope include unarmed and radiolabeled antibody therapy and cell mediated approaches using peptide vaccines and dendritic cells. Another area of interest involves drug delivery to brain tumors. Translational and clinical work is carried out in this area to formulate the relationship between various direct intratumoral infusion parameters and drug distribution within brain tumors and normal brain.
The Duke Brain Tumor Immunotherapy Program (BTIP) has an emphasis on translational research in Neuro-Oncology. There are two main areas of study. The first is novel mechanisms of delivery of large molecular weight molecules, such as monoclonal antibodies, throughout brain intersitial space using novel intracerebral infusion techniques developed by this laboratory. Studies exploring this technology are undertaken in both small and large laboratory animals and patients with brain tumors.
The other focus of the BTIP is translational immunotherapy. In this line of work, dendritic cell vaccination strategies and adoptive T-cell strategies have been developed to target novel and well-characterized tumor-specific antigens in patients with brain tumors. The BTIP integrates well with and works closely with the Preston Robert Tisch Brain Tumor Center at Duke. The BTIP is well funded and currently holds seven NIH grants, including a SPORE in Brain Cancer grant. There are a large number of investigators at various levels so that students will get exposure to various levels of research and mentorship.
Evan Calabrese
As a physician scientist focused on artificial intelligence (AI) applications for neurologic disease, my ongoing career goal is to combine clinical excellence in neuroradiology with cutting-edge AI research. My primary research interest lies in the use of innovative AI techniques to help extract clinically useful information from multimodal health data with a focus on neuroimaging. Modern neuroimaging studies, most notably multi-sequence MRI, are amongst the largest and most complex types of health data that are routinely acquired for patients with neurologic disorders. I believe that modern AI tools have enormous potential to help extract new, clinically useful information from complex neuroimaging studies, and through integration with other types of health data, will ultimately improve diagnosis, management, and treatment monitoring for patients with neurologic disease.
Giselle Yvette López
I am a physician scientist with a clinical focus on neuropathology, and a research interest in brain tumors. Originally from Maryland, I completed my undergraduate training at the University of Maryland, completing degrees in Physiology and Neurobiology as well as Spanish Language and Literature. I subsequently came to Duke for my MD and PhD, and discovered a passion for brain tumor research, and quickly realized that this was my life's calling. Clinically, I specialize in neuropathology. While I have active projects and collaborations on many kinds of brain tumors, my lab's primary focus is oligodendroglioma, a kind of infiltrative brain tumor that impacts adults. Our goal is to identify new ways to treat these tumors and improve the lives of patients with oligodendrogliomas and other kinds of brain tumors. By blending together computational approaches with wet lab approaches, we use the strengths inherent in different research modalities to excel in identifying unexplored pathways and thinking outside the box to identify new ways to target this brain tumor. We do this through research in an inclusive, multidisciplinary lab environment that strives for excellence in research while creating well-rounded, thriving scientists ready for the next step in their careers.
Research Opportunities
We currently have opportunities in the laboratory for one-year projects (ideal for post-bac fellows or third year med student research experiences). These projects are centered on identifying and testing novel therapeutic approaches for oligodendroglioma using in vitro and in vivo model systems. Please reach out if you are interested and would like to hear more about my mentoring philosophy, lab culture, and opportunities to be at the cutting edge of science.
Gerald Arthur Grant
Anoop Patel
Simon Gray Gregory
Dr. Gregory is the Margaret Harris and David Silverman Distinguished Professor and Director of the Brain Tumor Omics Program in the Duke Department of Neurosurgery, the Vice Chair of Research in the Department of Neurology, and Director of the Molecular Genomics Core at the Duke Molecular Physiology Institute.
As a neurogenomicist, Dr. Gregory applies the experience gained from leading the sequencing of chromosome 1 for the Human Genome Project to elucidating the mechanisms underlying multi-factorial diseases using genetic, genomic, and epigenetic approaches. Dr. Gregory’s primary areas of research involve understanding the molecular processes associated with disease development and progression in brain tumors and Alzheimer’s disease, drug induced white matter injury repair in multiple sclerosis, and the characterization of lesion microenvironmental changes in MS.
He is broadly regarded across Duke as a leader in the development of novel single cell and spatial molecular technologies towards understanding the pathogenic mechanisms of disease development. Dr. Gregory is also the Section Chair of Genomics and Epigenetics at the DMPI and Director of the Duke Center of Autoimmunity and MS in the Department of Neurology.
Chuan-Yuan Li
Dr. Li is the Vice Chair for Research in the Dept. of Dermatology. Some of the areas that his laboratory conducts research on include:
•Tumor response to therapy, with special emphasis on skin cancer such as melanoma and squamous cell carcinoma where current treatment outcomes are dismal;
•Stem cell and regenerative medicine, we will conduct research to investigate novel mechanisms of stem cell biology so that knowledge gained can be translated into regenerative medicine;
•Mechanisms of carcinogenesis, with emphasis on skin cancers, so that better strategies could be devised to prevent and treat these cancers.
Within these broad areas we have different ongoing research projects. Examples of some of the research projects include:
Unconventional roles of caspases in tumor response to chemotherapy or radiotherapy. A recent area of our laboratory has been the relationship of cell death and repopulation in tumors undergoing radiation and chemotherapy. In our studies, we discovered that cell death is a key trigger for tumor cell repopulation in radiation and chemotherapy. Unexpectedly, caspase 3, which is an executioner in cell death, positively regulate paracrine signaling from dying cells to stimulate proliferation of surviving tumor cells. Furthermore, we found that higher levels of pretreat caspase 3 activation is correlated with worse outcome in head and neck and breast cancers. This is again quite unexpected and contrary to established paradigm. We are currently actively studying the relevance of this mechanism in other malignancies including melanoma. We believe such studies will not only yield promising novel treatments for cancer but also new biomarkers of diagnostic or prognostic values.
Positive roles of apoptosis in wound healing and tissue regeneration. Another area of our research is the relationship between apoptosis and wound healing/tissue regeneration. In our recent research we discovered that cellular apoptosis, in particular, apoptotic caspases 3&7, play key roles in promoting skin wound healing and tissue regeneration. We named this pathway the “Phoenix Rising” pathway for wound healing and tissue regeneration. We are actively studying this mechanism with the hope that knowledge gained could be used for regenerative medicine.
Molecular factors involved in stem cell biology regulation and trans-differentiation. Recently our lab started to investigate molecular mechanisms involved in the maintenance and self-renewal of stem cells. Our efforts led to the discovery that caspases 8&3 play critical roles in the induction of pluripotent stem cells from human fibroblasts. We are in the process of dissecting additional roles of caspases in embryonic stem cells.
Direct reprogramming of one differentiated cell type into another differentiated cell type. Recently, we have been able to directly reprogram human fibroblast cells into dopaminergic neurons, which have great potential in Parkinson's Disease. We are actively pursuing similar studies to reprogram skin fibroblasts into various cells of interest, including other skin cells, through direct reprogramming.
Mustafa Khasraw
I am a physician-scientist with a background in medical oncology and neuro-oncology, with affiliations to multiple departments, research, and training programs at Duke.
I lead a Tumor Immunology Lab where we use various wet and dry lab techniques to understand the interactions between tumors and the immune system. Our goal is to identify vulnerabilities that can be targeted for novel therapies.
I serve as the Deputy Director of the Center for Cancer Immunotherapy at the Duke Cancer Institute where we are tasked to facilitate clinical research and translate promising discoveries made by scientists across various departments and cancer types at Duke, particularly in the field of immune and T cell-based therapies.
My team and our laboratory operate in an environment that enables the transition from bench-side basic scientific discoveries to clinical trials, and back to the bench ensuring the evaluation of new treatments for cancer patients.
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