ABSTRACT
Diagnosing Alzheimer's disease (AD) in the early stage is challenging. Informative biomarkers can be of great value for population-based screening. Metabolomics studies have been used to find potential biomarkers, but commonly used tissue sources can be difficult to obtain. The objective of this study was to determine the potential utility of erythrocyte metabolite profiles in screening for AD. Unlike some commonly-used sources such as cerebrospinal fluid and brain tissue, erythrocytes are plentiful and easily accessed. Moreover, erythrocytes are metabolically active, a feature that distinguishes this sample source from other bodily fluids like plasma and urine. In this preliminary pilot study, the erythrocyte metabolomes of 10 histopathologically confirmed AD patients and 10 patients without AD (control (CTRL)) were compared. Whole blood was collected post-mortem and erythrocytes were analyzed using ultra-performance liquid chromatography tandem mass spectrometry. Over 750 metabolites were identified in AD and CTRL erythrocytes. Seven were increased in AD while 24 were decreased (P<0.05). The majority of the metabolites increased in AD were associated with amino acid metabolism and all of the decreased metabolites were associated with lipid metabolism. Prominent among the potential biomarkers were 10 sphingolipid or sphingolipid-related species that were consistently decreased in AD patients. Sphingolipids have been previously implicated in AD and other neurological conditions. Furthermore, previous studies have shown that erythrocyte sphingolipid concentrations vary widely in normal, healthy adults. Together, these observations suggest that certain erythrocyte lipid phenotypes could be markers of risk for development of AD.
ABSTRACT
Diagnosing Alzheimer's disease(AD)in the early stage is challenging.Informative biomarkers can be of great value for population-based screening.Metabolomics studies have been used to find potential biomarkers,but commonly used tissue sources can be difficult to obtain.The objective of this study was to determine the potential utility of erythrocyte metabolite profiles in screening for AD.Unlike some commonly-used sources such as cerebrospinal fluid and brain tissue,erythrocytes are plentiful and easily accessed.Moreover,erythrocytes are metabolically active,a feature that distinguishes this sample source from other bodily fluids like plasma and urine.In this preliminary pilot study,the erythrocyte metab-olomes of 10 histopathologically confirmed AD patients and 10 patients without AD(control(CTRL))were compared.Whole blood was collected post-mortem and erythrocytes were analyzed using ultra-performance liquid chromatography tandem mass spectrometry.Over 750 metabolites were identified in AD and CTRL erythrocytes.Seven were increased in AD while 24 were decreased(P<0.05).The ma-jority of the metabolites increased in AD were associated with amino acid metabolism and all of the decreased metabolites were associated with lipid metabolism.Prominent among the potential bio-markers were 10 sphingolipid or sphingolipid-related species that were consistently decreased in AD patients.Sphingolipids have been previously implicated in AD and other neurological conditions.Furthermore,previous studies have shown that erythrocyte sphingolipid concentrations vary widely in normal,healthy adults.Together,these observations suggest that certain erythrocyte lipid phenotypes could be markers of risk for development of AD.
ABSTRACT
BACKGROUND AND PURPOSE: Differences in ischemic stroke between men and women have been mainly attributed to hormonal effects. However, sex differences in immune response to ischemia may exist. We hypothesized that differential expression of X-chromosome genes in blood immune cells contribute to differences between men and women with ischemic stroke. METHODS: RNA levels of 683 X-chromosome genes were measured on Affymetrix U133 Plus2.0 microarrays. Blood samples from patients with ischemic stroke were obtained at ≤ 3 hours, 5 hours, and 24 hours (n=61; 183 samples) after onset and compared with control subjects without symptomatic vascular diseases (n=109). Sex difference in X-chromosome gene expression was determined using analysis of covariance (false discovery rate ≤ 0.05, fold change ≥ 1.2). RESULTS: At ≤ 3, 5, and 24 hours after stroke, there were 37, 140, and 61 X-chromosome genes, respectively, that changed in women; and 23, 18, and 31 X-chromosome genes that changed in men. Female-specific genes were associated with post-translational modification, small-molecule biochemistry, and cell-cell signaling. Male-specific genes were associated with cellular movement, development, cell-trafficking, and cell death. Altered sex specific X-chromosome gene expression occurred in 2 genes known to be associated with human stroke, including galactosidase A and IDS, mutations of which result in Fabry disease and Hunter syndrome, respectively. CONCLUSIONS: There are differences in X-chromosome gene expression between men and women with ischemic stroke. Future studies are needed to decipher whether these differences are associated with sexually dimorphic immune response, repair or other mechanisms after stroke, or whether some of them represent risk determinants.
