Clinical importance of high-mannose, fucosylated, and complex N-glycans in breast cancer metastasis
Klára Ščupáková, … , Ron M.A. Heeren, Kristine Glunde
Klára Ščupáková, … , Ron M.A. Heeren, Kristine Glunde
Published November 9, 2021
Citation Information: JCI Insight. 2021;6(24):e146945. https://doi.org/10.1172/jci.insight.146945.
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Resource and Technical Advance Oncology

Clinical importance of high-mannose, fucosylated, and complex N-glycans in breast cancer metastasis

Abstract

BACKGROUND. Although aberrant glycosylation is recognized as a hallmark of cancer, glycosylation in clinical breast cancer (BC) metastasis has not yet been studied. While preclinical studies show that the glycocalyx coating of cancer cells is involved in adhesion, migration, and metastasis, glycosylation changes from primary tumor (PT) to various metastatic sites remain unknown in patients. METHODS. We investigated N-glycosylation profiles in 17 metastatic BC patients from our rapid autopsy program. Primary breast tumor, lymph node metastases, multiple systemic metastases, and various normal tissue cores from each patient were arranged on unique single-patient tissue microarrays (TMAs). We performed mass spectrometry imaging (MSI) combined with extensive pathology annotation of these TMAs, and this process enabled spatially differentiated cell-based analysis of N-glycosylation patterns in metastatic BC. RESULTS. N-glycan abundance increased during metastatic progression independently of BC subtype and treatment regimen, with high-mannose glycans most frequently elevated in BC metastases, followed by fucosylated and complex glycans. Bone metastasis, however, displayed increased core-fucosylation and decreased high-mannose glycans. Consistently, N-glycosylated proteins and N-glycan biosynthesis genes were differentially expressed during metastatic BC progression, with reduced expression of mannose-trimming enzymes and with elevated EpCAM, N-glycan branching, and sialyation enzymes in BC metastases versus PT. CONCLUSION. We show in patients that N-glycosylation of breast cancer cells undergoing metastasis occurs in a metastatic site–specific manner, supporting the clinical importance of high-mannose, fucosylated, and complex N-glycans as future diagnostic markers and therapeutic targets in metastatic BC. FUNDING. NIH grants R01CA213428, R01CA213492, R01CA264901, T32CA193145, Dutch Province Limburg “LINK”, European Union ERA-NET TRANSCAN2-643638.

Authors

Klára Ščupáková, Oluwatobi T. Adelaja, Benjamin Balluff, Vinay Ayyappan, Caitlin M. Tressler, Nicole M. Jenkinson, Britt S.R. Claes, Andrew P. Bowman, Ashley M. Cimino-Mathews, Marissa J. White, Pedram Argani, Ron M.A. Heeren, Kristine Glunde

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Figure 2

N-glycan abundances grouped by anatomical sites and histological tissue types.

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N-glycan abundances grouped by anatomical sites and histological tissue ...
(A) The heatmap represents an overview of the 28 significantly differentially abundant N-glycans throughout 7 most common organ sites and 6 most common pathology annotations. Each entry represents the average level of a given N-glycan across all 17 TMAs for a specific site and annotation combination. The glycans are grouped based on glycan structure similarities (bottom). MALDI-MSI data are displayed log-scaled. CS, cancer-associated stroma. Bone metastasis consists of pooled bone, spine, vertebra, and rib metastases. (B) Data set GEO GSE26338 analyzed for N-glycosylation genes. Heatmap showing significantly altered genes between PT and metastatic tumors (P < 0.05, FDR < 0.15). (C) Differentially expressed genes shown schematically within the N-glycan biosynthesis pathway. Dashed lines indicate consistent observations in GE and MSI analyses.