Inflammatory metabolic profile of South African patients with prostate cancer

Stefano Cacciatore,Giuseppina M Carbone,Carlo V Catapano,Martha Wium,Massimo Loda,Chanelle Anderson,Towia A Libermann,Azola Samkele Salukazana,Aderonke Ajayi-Smith,Cristina Licari,Marco Carini,Lorenzo Masieri,Luiz F Zerbini,Lisa Kaestner

doi:10.1186/s40170-021-00265-6

Abstract

BackgroundMen with African ancestry are more likely to develop aggressive prostate cancer (PCa) and to die from this disease. The study of PCa in the South African population represents an opportunity for biomedical research due to the high prevalence of aggressive PCa. While inflammation is known to play a significant role in PCa progression, its association with tumor stage in populations of African descent has not been explored in detail. Identification of new metabolic biomarkers of inflammation may improve diagnosis of patients with aggressive PCa.MethodsPlasma samples were profiled from 41 South African men with PCa using nuclear magnetic resonance (NMR) spectroscopy. A total of 41 features, including metabolites, lipid classes, total protein, and the inflammatory NMR markers, GlycA, and GlycB, were quantified from each NMR spectrum. The Bruker’s B.I.-LISA protocols were used to characterize 114 parameters related to the lipoproteins. The unsupervised KODAMA method was used to stratify the patients of our cohort based on their metabolic profile.ResultsWe found that the plasma of patients with very high risk, aggressive PCa and high level of C-reactive protein have a peculiar metabolic phenotype (metabotype) characterized by extremely high levels of GlycA and GlycB. The inflammatory processes linked to the higher level of GlycA and GlycB are characterized by a deep change of the plasma metabolome that may be used to improve the stratification of patients with PCa. We also identified a not previously known relationship between high values of VLDL and low level of GlycB in a different metabotype of patients characterized by lower-risk PCa.ConclusionsFor the first time, a portrait of the metabolic changes in African men with PCa has been delineated indicating a strong association between inflammation and metabolic profiles. Our findings indicate how the metabolic profile could be used to identify those patients with high level of inflammation, characterized by aggressive PCa and short life expectancy. Integrating a metabolomic analysis as a tool for patient stratification could be important for opening the door to the development of new therapies. Further investigations are needed to understand the prevalence of an inflammatory metabotype in patients with aggressive PCa.

Highlights

Men with African ancestry are more likely to develop aggressive prostate cancer (PCa) and to die from this disease
Patients that received androgendeprivation therapy (ADT), i.e., bilateral orchidectomy (BO), were considered as two distinct groups based on the evidence of castration-resistant PCa (CRPC)
Apo-A2 that could help to characterize the differences between GlycA and GlycB. In this first metabolomic study of PCa conducted on an African population for metabolic biomarkers of inflammation, we observed in men with very high aggressive PCa higher levels of the nuclear magnetic resonance (NMR) inflammatory markers GlycA and GlycB, indicating an increased concentration of positive Acute-phase protein (APP) and/or a higher complexity of their glycan structures

Summary

Introduction

Men with African ancestry are more likely to develop aggressive prostate cancer (PCa) and to die from this disease. Inflammation seems to play a key role in PCa development and progression with a significant impact on processes in the tumor microenvironment that facilitate progression to advanced disease [2]. The metabolic changes driven by inflammation are not identified in the majority of studies on cancer. This lack leads to a bias in the understanding of mechanisms involved in the metabolic changes. Nuclear magnetic resonance (NMR) spectroscopy is a powerful technique when applied to the high-throughput analysis of biofluids such as blood [4], which can be collected with minimal impact on the participant. NMR spectroscopy allows the detection in plasma of signals arising from the glycosylation of circulating acute-phase proteins (APPs), such as α1-antichymotrypsin, haptoglobin-1, α1-antitrypsin, transferrin, and α1-acid glycoprotein [6]

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