Clinical Drug Experience Knowledgebase

Proteome-based Personalized Immunotherapy of Malignant Brain Tumors

The trial will include 60 cases of unresectable recurrent glioblastoma multiforme (GBM) after two lines of standard chemotherapy and complete course of radiotherapy.

The first line therapy of GBM involves allogeneic haploidentical hematopoietic stem cells (HSCs), dendritic vaccine (DV) and cytotoxic lymphocytes (CTLs).

HSCs are used to stimulate individualized adoptive immune response, to affect tumor cells (TCs) toxically and to regulate tumor stem cells (TSCs) targeted in order to suppress their reproductive and proliferative potential. To obtain HSC the donor receives 8 subcutaneous administrations of granulocyte colony-stimulating factor (G-CSF) with 8-10 hours interval for 4 days. The first three days a single dose is 2.5 mcg per 1 kg weight, the last day the dose is doubled. The stem cells are harvested at day 5. Red blood cells are withdrawn by centrifuging. The content of cell markers is evaluated by flow cytometry. The result is assessed after cytoconcentrate enrichment and removal of mature cells and plasma from it. The preparation is stored in tubes per 4 ml with cryoprotector and 10% polyglucin solution. Stem cell proportion is no less than 0.5x106 CD34+, and lymphocytes proportion is no less than 0.5x109 per one administration.

The sample of brain tumor is obtained through stereotaxic/ endoscopic/ open biopsy from all patients included into the trial. The TCs and TSCs are immunochemically isolated from GBM biopsy sample. One part of tumor sample is used for standard histological, cytological and immunochemical testing, while tumor cells (TCs) and tumor stem cells (TSCs) (CD133+) are isolated from the other part.

Dendritic cells are isolated from peripheral blood mononuclear cells and cultured. Tumor sample provides tumor specific antigens to prepare DV.

Preparation of CTLs aims to enhance cytotoxic effect on tumor due to great number of circulating CTLs. CTLs are isolated from about 100 ml of peripheral blood after 3 DV administrations, and of them dendritic cells (DCs) are grown. Then, peripheral blood is repeatedly taken, and lymphocytes are isolated. The CTLs are co-cultured with DCs loaded with tumor antigens (first line therapy) or recombinant proteins identical to key oncospecific proteins (second-line therapy) for several times to expand their number (108-109). Their immunophenotype is detected and CTLs are cryopreserved. The first stimulation of CTLs with DCs lasts 6-8 days, the second lasts 2-4 days, next 2 days the lymphocytes are stimulated for the third and fourth time. And then the received lymphocytes are stimulated by IL-2 for 2 days.

Six months after the first line therapy completion the efficiency is evaluated and the cohort demonstrating efficiency continues the therapy, while cohort demonstrating no efficiency will continue the trial with the second line therapy.

The second line therapy arm (active comparator arm) uses DV with recombinant proteins identical to key oncospecific proteins, autologous CTLs and autologous HSCs with modified proteome.

Autologous HSCs are received from the trial participant as described previously. Cell preparation of HSC for active comparator arm is obtained of the cytoconcentrate of autologous mononuclear cells of peripheral blood after mobilization as specified for experimental arm. Tumor specific antigens for active comparator group are provided by tumor tissue of the patient.

TCs and TSCs as well as HSCs of the patient undergo complete transcriptome mapping and gene expression profiling (CTMGEP) and proteome mapping and protein profiling (PMPP). Key (3 or 4 proteins with maximal normalized intensity) oncospecific proteins (OSP) are determined according to proteome testing of TCs, while proteome profiling of TSCs and use of databases of protein-protein relations permit detection of intracellular signal transduction pathways (ISTP) unaffected by carcinogenesis and capable of regulation. Also, receptor membrane targets to affect these signal pathways (acceptor membrane proteins) are detected, as well as proteins that are able to activate them (protein ligands). CTMGEP of TSCs confirms diagnosed functional ISTP. Mathematical modeling of CTMGEP and comparison with Affymetrix GeneChip Human genome U133A Array data reveals perturbagens able to chemically induce HSCs and to modify their proteome profile in order to provide secretion of requisite protein ligands. The database analysis permits understanding of how changes in gene expression induced by a low-molecular agent or micro RNA corresponds with the changes observed in the examined profile. If correspondence is significant, it is supposed, that the agent or similar agents can initiate the effect. If anticorrelation is significant, the agent is supposed to initiate an opposite effect in gene expression modification. The transcriptome of HSCs is modified by co-culturing mononuclear cells with perturbagens. Their biological efficiency is evaluated in vitro in Homunculus bioreactor. Then preparation is stored as described previously.

Individual DV is prepared from the leukoconcentrate of peripheral blood of the patient. The lymphocytes are isolated, cultured with G-CSF and interleukin-2, conditioned by tumor-specific antigens, TNF-α and PGE2 for 48 hours and loaded with recombinant proteins identical to key tumor-specific antigens detected at proteomic testing of TCs. Basic mechanism of individual DV immune effect is elaboration of tumor toxic lymphocytes by the organism of the patient.

CTLs are obtained as described previously. The intervention is described in the appropriate section.

Toxicity will be evaluated according to CTC-NCI criteria. Efficiency is assessed according to the following criteria:

Complete effect - -full disappearance of all tumor foci
Partial effect - -reduction of tumor size and/or metastatic foci by no less than 50% and no signs of new neoplasms
Stabilization - reduction of tumor foci size by less than 50% and no signs of new neoplasms
Progress - growth of tumor foci during the therapy. In case of mosaic effect, when part of foci progresses and part is stable or reducing, the therapy is continued but the cases are analyzed outside the context "Response to the therapy"