5 research outputs found
Proteomics study of human cord blood reticulocyte-derived exosomes
Reticulocyte-derived exosomes (Rex), extracellular vesicles of
endocytic origin, were initially discovered as a cargo-disposal
mechanism of obsolete proteins in the maturation of
reticulocytes into erythrocytes. In this work, we present the
first mass spectrometry-based proteomics of human Rex (HuRex).
HuRex were isolated from cultures of human reticulocyte-enriched
cord blood using different culture conditions and exosome
isolation methods. The newly described proteome consists of 367
proteins, most of them related to exosomes as revealed by gene
ontology over-representation analysis and include multiple
transporters as well as proteins involved in exosome biogenesis
and erythrocytic disorders. Immunoelectron microscopy validated
the presence of the transferrin receptor. Moreover, functional
assays demonstrated active capture of HuRex by mature dendritic
cells. As only seven proteins have been previously associated
with HuRex, this resource will facilitate studies on the role of
human reticulocyte-derived exosomes in normal and pathological
conditions affecting erythropoiesis
Plasma-Derived Extracellular Vesicles as Potential Biomarkers in Heart Transplant Patient with Chronic Chagas Disease
Chagas disease is emerging in countries to which it is not endemic. Biomarkers for earlier therapeutic response assessment in patients with chronic Chagas disease are needed. We profiled plasma-derived extracellular vesicles from a heart transplant patient with chronic Chagas disease and showed the potential of this approach for discovering such biomarkers
Characterization of Plasmodium vivax Proteins in Plasma-Derived Exosomes From Malaria-Infected Liver-Chimeric Humanized Mice
Exosomes are extracellular vesicles of endocytic origin containing molecular signatures implying the cell of origin; thus, they offer a unique opportunity to discover biomarkers of disease. Plasmodium vivax, responsible for more than half of all malaria cases outside Africa, is a major obstacle in the goal of malaria elimination due to the presence of dormant liver stages (hypnozoites), which after the initial infection may reactivate to cause disease. Hypnozoite infection is asymptomatic and there are currently no diagnostic tools to detect their presence. The human liver-chimeric (FRG huHep) mouse is a robust P. vivax infection model for exo-erythrocytic development of liver stages, including hypnozoites. We studied the proteome of plasma-derived exosomes isolated from P. vivax infected FRG huHep mice with the objective of identifying liver-stage expressed parasite proteins indicative of infection. Proteomic analysis of these exosomes showed the presence of 290 and 234 proteins from mouse and human origin, respectively, including canonical exosomal markers. Human proteins include proteins previously detected in liver-derived exosomes, highlighting the potential of this chimeric mouse model to study plasma exosomes derived unequivocally from human hepatocytes. Noticeably, we identified 17 parasite proteins including enzymes, surface proteins, components of the endocytic pathway and translation machinery, as well as uncharacterized proteins. Western blot analysis validated the presence of human arginase-I and an uncharacterized P. vivax protein in plasma-derived exosomes. This study represents a proof-of-principle that plasma-derived exosomes from P. vivax infected FRG-huHep mice contain human hepatocyte and P. vivax proteins with the potential to unveil biological features of liver infection and identify biomarkers of hypnozoite infection
Proteomics study of human cord blood reticulocyte-derived exosomes
Reticulocyte-derived exosomes (Rex), extracellular vesicles of endocytic origin, were initially discovered as a cargo-disposal mechanism of obsolete proteins in the maturation of reticulocytes into erythrocytes. In this work, we present the first mass spectrometry-based proteomics of human Rex (HuRex). HuRex were isolated from cultures of human reticulocyte-enriched cord blood using different culture conditions and exosome isolation methods. The newly described proteome consists of 367 proteins, most of them related to exosomes as revealed by gene ontology over-representation analysis and include multiple transporters as well as proteins involved in exosome biogenesis and erythrocytic disorders. Immunoelectron microscopy validated the presence of the transferrin receptor. Moreover, functional assays demonstrated active capture of HuRex by mature dendritic cells. As only seven proteins have been previously associated with HuRex, this resource will facilitate studies on the role of human reticulocyte-derived exosomes in normal and pathological conditions affecting erythropoiesis
Proteomics study of human cord blood reticulocyte-derived exosomes
Reticulocyte-derived exosomes (Rex), extracellular vesicles of
endocytic origin, were initially discovered as a cargo-disposal
mechanism of obsolete proteins in the maturation of
reticulocytes into erythrocytes. In this work, we present the
first mass spectrometry-based proteomics of human Rex (HuRex).
HuRex were isolated from cultures of human reticulocyte-enriched
cord blood using different culture conditions and exosome
isolation methods. The newly described proteome consists of 367
proteins, most of them related to exosomes as revealed by gene
ontology over-representation analysis and include multiple
transporters as well as proteins involved in exosome biogenesis
and erythrocytic disorders. Immunoelectron microscopy validated
the presence of the transferrin receptor. Moreover, functional
assays demonstrated active capture of HuRex by mature dendritic
cells. As only seven proteins have been previously associated
with HuRex, this resource will facilitate studies on the role of
human reticulocyte-derived exosomes in normal and pathological
conditions affecting erythropoiesis