Clinical Trial Details
— Status: Recruiting
Administrative data
| NCT number |
NCT04137523 |
| Other study ID # |
eNAMPT |
| Secondary ID |
|
| Status |
Recruiting |
| Phase |
|
| First received |
|
| Last updated |
|
| Start date |
August 12, 2019 |
| Est. completion date |
September 15, 2022 |
Study information
| Verified date |
August 2021 |
| Source |
University of Turin, Italy |
| Contact |
UNITO UNITO |
| Phone |
0116336107 |
| Email |
clinical.trials[@]unito.it |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Observational
|
Clinical Trial Summary
Based on our previous observations, here the investigator plans to further investigate eNAMPT
in MM biology and to establish its role in disease progression where EMT acquisition
represents an hallmark of cancers. Results deriving from proposal would hopefully identify
novel biological vulnerabilities of such malignancy and an innovative biomarker for disease
progression monitoring as well.
Description:
Background and preliminary data:
Multiple myeloma (MM) is characterized by a clonal expansion of malignant plasma cells in the
bone marrow (BM) with a continuous spread of tumour cells in and out of BM. A continuous
interaction between BM stromal cells (BMSCs) and MM cells supports proliferation, survival,
migration, and drug resistance of tumor cells. Indeed, BMSCs by both cytokines production and
cell-cell interactions, control the ability of MM cells to enter into bloodstream, leading to
homing or extravasation of clonal cells into distant tissues, which in turn results in new BM
niches formation.
The epithelial-to-mesenchymal transition (EMT) is a biological phenomenon by which epithelial
cells can switch into a mesenchymal phenotype through the disruption of cell-cell adhesion
and cellular polarity, remodeling of cytoskeleton and changing cell-matrix adhesion. Overall,
these events lead to improved migratory and invasive properties of affected cells.
Remarkably, EMT occurs physiologically during normal embryonic development and tissue
regeneration but, in cancer cell, it has been associated with tumor aggressiveness features
including invasion, metastasis, stemness and drug-resistance. EMT is commonly observed in
solid tumors but it has been recently described also in MM. In such a context, studies have
shown that BM niches-associated hypoxia produces MM cells egress and dissemination through
acquisition of EMT-like features which in turn, by increasing CXCR4 expression, produces
extra-medullary disease (EMD) development.
Alterations in cell metabolism have emerged as one of the hallmarks of cancer that could be
possibly targeted by novel therapeutic approaches. Among these alterations, biosynthesis of
nicotinamide adenine dinucleotide (NAD+) is emerging as novel therapeutic target in tumours.
Nicotinamide phosphorybosyltransferase (NAMPT), the rate-limiting enzyme for NAD+ production
from nicotinamide (NAM) in mammalian cells, is frequently up-regulated in cancers, including
MM, and its relevance as potential therapeutic target has been widely explored by our group.
However, beside its intracellular activity as key metabolic enzyme, NAMPT is also present in
the extracellular milieu where it exerts cytokine/adipokine-like actions as eNAMPT. Although
mechanisms underlying eNAMPT secretion still remain to be elucidated, it is commonly accepted
that there is positive correlation between eNAMPT secretion and intracellular NAMPT levels.
Recent evidences show that eNAMPT plasma levels are significantly higher in cancer patients
in comparison with healthy donors in several hematologic and solid neoplasms. In this
context, eNAMPT was found to exert pro-tumorigenic effects such as promoting cancer cell
proliferation and colonies formation, conferring resistance to apoptosis and shaping of
tumour microenviroment, by promoting neo-angiogenesis and affecting immune response.
The Investigators recently demonstrated the pivotal role played by eNAMPT in the acquisition
of EMT in human breast cancer cells. In detail, NAMPT overexpression promotes acquisition of
fibroblast-like morphology of cancer cells by reducing E-cadherin expression in association
with N-cadherin, Vimentin and ZEB1 upregulation. Importantly, NAMPT-induced EMT is not
associated with NAMPT enzymatic activity and neither with its product levels nicotinamide
mononucleotide (NMN). On the contrary, EMT seems to be mediated by eNAMPT through its ability
to activate TGFβ signaling pathway via increased TGFβ1 production.
Based on our previous observations, here the investigators plan to further investigate eNAMPT
in MM biology and to establish its role in disease progression where EMT acquisition
represents an hallmark of cancers. Results deriving from proposal would hopefully identify
novel biological vulnerabilities of such malignancy and an innovative biomarker for disease
progression monitoring as well.
The investigators have preliminary measured eNAMPT serum levels in PB samples of Newly
Diagnosed Multiple Myeloma (NDMM) (n= 20) patients and healthy donors (HDs; n=6).
Interestingly, eNAPMT levels were found to be significantly higher in tumors than controls,
pointing to a relevant role of this cytokine in MM biology. These data provide the rationale
for further investigations of eNAMPT role in MM.
Sample collection:
Retrospective samples of MM patients will be derived from two different databases (UNITO and
UNIGE) and combined into a new specific database dedicated to this project to cover the
different stages of disease that will be analyzed.
UNITO will coordinate and perform the selection of the samples that will be included. UNITO
will be able to provide the required number of samples for this study. Ultimately, an
independent, representative set of 100 MM patient samples will be selected from previous
clinical trials that have been conducted over the past 5 years.
In general, the samples will meet the following parameters:
- Male and female patients over 18 years of age;
- PB-derived serum samples collected in different disease phases (MGUS, SMM, NDMM and RRMM
MM patients)
- Sufficient CD138+ cells or RNA from CD138+ cells are available;
- ≥ 2 years median survival data and treatment data is available (progression free and
overall survival);
- Bone marrow sample acquired prior to the initiation of the therapy of interest;
- Patients have consented for use of their sample for research purposes.
A feasibility assessment and power analysis of the available samples and clinical data will
be performed for each of the respective available clinical trials from which the samples will
originate. This assessment is performed in order to decide upon, select, and build, a dataset
that provides scientifically and statistically sound evidence for treatment effectiveness
prediction. The selected treatment regimens (combinations of medication) that will be
analyzed cover the complete spectrum of MM treatment classes, including proteasome
inhibitors, immunomodulatory drugs (IMiDs), alkylating agents, HDAC inhibitors and monoclonal
antibodies. Patient samples will be derived from controlled clinical trials, and will be
selected from different treatment groups, containing patients that received the same
treatment regimens, based on one of the following drugs or combinations: Bortezomib
(proteasome inhibitor), Carfilzomib (proteasome inhibitor), Thalidomide (IMiD), Lenalidomide
(IMiD), Pomalidomide (IMiD), Melphalan (alkylating agent), Panabinostat (HDAC inhibitor), and
Daratumumab (monoclonal antibody).
Sample size estimations are based on previous experiences of being able to significantly
determine survival differences between positive and negative cases for a certain treatment
for a sufficiently large group. Given an effect size of at least 3 and an incidence of the
subtype of 20%, a group size of 100 cases will be sufficient to significantly determine the
predictive value of the subtype. (a smaller effect size and a smaller incidence would likely
not be clinically relevant).
