Vacuolar ATPase and Drug Resistance of High Grade Gliomas

NCT ID: NCT05328089

Last Updated: 2024-01-03

Basic Information

• Recruitment Status: RECRUITING
• Total Enrollment: 20 participants
• Study Classification: OBSERVATIONAL
• Study Start Date: 2020-01-30
• Study Completion Date: 2024-04-30

Brief Summary

GBMs are still considered tumors with few available treatment options that are able only to achieve a temporary local control of the disease. In case of a GBM, tumor recurrence is generally expected within 12 months and it is due to the presence of marginal tumoral cells with pro-oncogenic molecular phenotypes that are resistant to actual chemotherapies and to radiation therapy. Nowadays, surgery still represent the first treatment option in case of suspected GBM and it aims to remove the contrast enhancing lesion seen at the pre-operative brain MRI. In particular, the peripheral layer of the tumor is made of low replicating cellsglioblastoma-associated stromal cell (GASC) that can show different carcinogenic properties and that are probably responsible for tumor recurrence. Metabolism of GBMs is mainly anaerobialglicolisis that leads to the transformation of glucose in ATP and lactates. The production of high lactate levels determines a decrease of intracellular pH that is counterbalanced by V-ATPase activity through H+ ions extrusion from the intracellular to the extracellular environment. Increased V-ATPase activity affects different pro-tumoral activities and plays a crucial role in chemoresistance. In fact, a low extracellular pH can reduce the efficacy of antineoplastic agents since a low pH might affect the structural integrity of drugs and their ability to pass through the plasmatic membrane. Finally, V-ATPase can act as an active pump able to excrete antineoplastic agents. GBMs with high V-ATPAse expression are able to transmit malignant features and to activate proliferation of GASC in vitro through a network of microvescicles (MV) like exosomes and large oncosomes (LO) that transport cell to cell copy DNA (cDNA) and micro-RNAs (miRNA).In this view, our work is intended to study: 1) the effects of proton pump inhibitors (PPI) on CSC and GASCs cultures as in vitro add-on treatments; 2) the MVs load (in terms of miRNAs and cDNAs) during the neuro-oncological follow-up in order to understand how it changes after surgery and adjuvant treatments; 3) the possible roles of V-ATPase as a clinical marker to be used to check tumor response to adjuvant treatments.

Detailed Description

GBMs are still considered tumors with few available treatment options that are able only to achieve a temporary local control of the disease. In case of a GBM, tumor recurrence is generally expected within 12 months and it is due to the presence of marginal tumoral cells with pro-oncogenic molecular phenotypes that are resistant to actual chemotherapies and to radiation therapy. In particular, in case of GBM it is possible to distinguish three neoplastic layers within the tumor that show different molecular patterns: the central core; the intermediate layer and the peripheral layer. Nowadays, surgery still represent the first treatment option in case of suspected GBM and it aims to remove the contrast enhancing lesion seen at the pre-operative brain MRI. In particular, the peripheral layer is made of low replicating cells and it can be considered normal when tissue sampling is made far from the tumor cavity. In fact, Clavreul et al. in 2015 demonstrated that peripheral GBM layer contains glioblastoma-associated stromal cell (GASC) that can show different carcinogenic properties and that are probably responsible for tumor recurrence. These findings can be considered in line with previous studies that showed some invasive tumor cells, various types of reactive cells, and angiogenesis with different immunophenotypes in peritumoral brain edema.

Nevertheless, some research teams are trying to understand if surgical removal of peritumoral FLAIR hyperintensity is able to reduce the tumor recurrence rate prolonging the OS.

Metabolism of GBMs is mainly anaerobial and it is sustained by glycolysis. Anaerobial glycolysis is a simple metabolic reaction that leads to the transformation of glucose in ATP and lactates. Glucose is delivered to the tumor through neoangiogenetic processes. Production of a significant amount of lactates determines a decrease of intracellular pH that is counterbalanced by V-ATPase activity through the extrusion of H+ ions from the intracellular to the extracellular environment. In vitro inhibition of V-ATPAse has proved to increase CSC apoptosis due to decrease of intracellular pH.

Moreover, increased V-ATPase activity determines an extrusion of H+ ions in the extracellular environment that can positively affect different pro-tumoral activities. In fact, a decrease of extracellular pH leads to activation of proteases able to destroy the extracellular matrix. Such activity enhances tumor spreading. Moreover, a low extracellular pH can reduce the efficacy of antineoplastic agents since a low pH might affect the structural integrity of drugs and their ability to pass through the plasmatic membrane. Finally, V-ATPase can act as an active pump able to excrete antineoplastic agents.

For this reason, PPIs are considered new anti-cancer drugs able to increase tumoral cell death, reduce tumor invasion and increase chemotherapy efficacy.

Moreover, GBMs with high V-ATPAse expression has proved to be able to transmit highly malignant features through a network of MVs and to activate proliferation of GASC in vitro through the transmission of G1 subunit of V-ATPAse.

In this view, our work is intended to study: 1) the effects of PPIs on CSC and GASCs cultures as in vitro add-on treatments; 2) the MVs load in terms of miRNAs and DNA (ssDNA, exoDNA) during the neuro-oncological follow-up in order to understand how it changes after surgery and adjuvant treatments; 3) the possible roles of V-ATPase as a clinical marker to be used to check tumor response to adjuvant treatments.

Conditions

Glioblastoma Multiforme

Study Design

• Observational Model Type: COHORT
• Study Time Perspective: PROSPECTIVE

Eligibility Criteria

Inclusion Criteria

• Patients => 18 years old;
• Patients with an intra-axial brain tumor suspect for glioma;
• Patients able to sign a consent form for research purpose;
• Patients with planned craniotomy for brain tumor resection.

Exclusion Criteria

• Patients < 18 years old;
• Patients with known brain tumors different than gliomas;
• Patients unable to sign a consent form for research purpose;
• Patients undergoing brain tumor biopsy;
• Patients with poor intra-operative or small surgical sample for histopathological diagnosis;
• Histology diagnostic for tumors different than gliomas.

• Minimum Eligible Age: 18 Years
• Maximum Eligible Age: 90 Years
• Eligible Sex: ALL
• Accepts Healthy Volunteers: No

Sponsors

University of Milano Bicocca

OTHER

Sponsor Role: lead

Responsible Party

Carlo Giorgio Giussani

Associate Professor

Responsibility Role: PRINCIPAL_INVESTIGATOR

Locations

Azienda Socio Sanitaria Territoriale Monza - Ospedale San Gerardo

Monza, , Italy

Site Status: RECRUITING

Countries

Italy

Central Contacts

Carlo G. Giussani, Prof.

Role: CONTACT

carlo.giussani@unimib.it

0392336033 ext. +39

Andrea Di Cristofori, MD

Role: CONTACT

andrea.dicristofori@gmail.com

0392336033 ext. +39

Facility Contacts

Carlo G. Giussani, Prof.

Role: primary

carlo.giussani@unimib.it

0392336033 ext. +39

Andrea Di Cristofori, MD

Role: backup

andrea.dicristofori@gmail.com

3336566719 ext. +39

Provided Documents

Document Type: Study Protocol

View Document

Other Identifiers

0031436

Identifier Type: -

Identifier Source: org_study_id