posted on 2021-03-02, 13:05authored byYao Chen, Lina Quan, Chuiming Jia, Yiwei Guo, Xinya Wang, Yu Zhang, Yan Jin, Aichun Liu
Multiple
myeloma (MM) is a common hematological malignancy with
poorly understood recurrence and relapse mechanisms. Notably, bortezomib
resistance leading to relapse makes MM treatment significantly challenging.
To clarify the drug resistance mechanism, we employed a quantitative
proteomics approach to identify differentially expressed protein candidates
implicated in bortezomib-resistant recurrent and relapsed MM (RRMM).
Bone marrow aspirates from five patients newly diagnosed with MM (NDMM)
were compared with those from five patients diagnosed with bortezomib-resistant
RRMM using tandem mass tag-mass spectrometry (TMT-MS). Subcellular
localization and functional classification of the differentially expressed
proteins were determined by gene ontology, Kyoto Encyclopedia of Genes
and Genomes pathway, and hierarchical clustering analyses. The top
candidates identified were validated with parallel reaction monitoring
(PRM) analysis using tissue samples from 11 NDMM and 8 RRMM patients,
followed by comparison with the NCBI Gene Expression Omnibus (GEO)
dataset of 10 MM patients and 10 healthy controls (accession no.:
GSE80608). Thirty-four differentially expressed proteins in RRMM,
including proteinase inhibitor 9 (SERPINB9), were identified by TMT-MS.
Subsequent functional enrichment analyses of the identified protein
candidates indicated their involvement in regulating cellular metabolism,
apoptosis, programmed cell death, lymphocyte-mediated immunity, and
defense response pathways in RRMM. The top protein candidate SERPINB9
was confirmed by PRM analysis and western blotting as well as by comparison
with an NCBI GEO dataset. We elucidated the proteome landscape of
bortezomib-resistant RRMM and identified SERPINB9 as a promising novel
therapeutic target. Our results provide a resource for future studies
on the mechanism of RRMM.