The reticuloendothelial system plays a major role in iron metabolism. Despite this, the manner in which macrophages handle iron remains poorly understood. Mammalian cells utilize transferrin-dependent mechanisms to acquire iron via transferrin receptors 1 and 2 (TfR1 and TfR2) by receptor-mediated endocytosis. Here, we show for the first time that the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is localized on human and murine macrophage cell surface. The expression of this surface GAPDH is regulated by the availability of iron in the medium. We further demonstrate that this GAPDH interacts with transferrin and the GAPDHtransferrin complex is subsequently internalized into the early endosomes. Our work sheds new light on the mechanisms involved in regulation of iron, vital for controlling numerous diseases and maintaining normal immune function. Thus, we propose an entirely new avenue for investigation with respect to transferrin uptake and regulation mechanisms in macrophages.Iron is an essential nutrient for all organisms as a constituent of hemoproteins and iron-sulfur proteins. In addition it is also a critical component of functional groups of several proteins involved in vital housekeeping functions. Cells of the immune system require iron for their normal functions such as proliferation, activation, and maturation of lymphocytes (1-5). Iron is also essential for macrophage-mediated cytotoxicity by the production of highly toxic hydroxyl radicals (6, 7). The mononuclear phagocyte system is composed of monocytes, macrophages, and their precursor cells, which play a vital role in iron metabolism by removing effete erythrocytes and recycling iron. These cells also acquire iron via the receptor-mediated uptake of transferrin and the hemoglobin scavenger receptor (8). Practically all extracellular iron circulating in the plasma is bound to transferrin, an abundant protein with high affinity for iron. Two mammalian transferrin receptors TfR1 4 and TfR2 have so far been characterized. Both these receptors are cell surface transmembrane, glycoproteins (9). Unlike TfR1, TfR2 is not regulated by intracellular iron concentrations. This receptor also binds transferrin in manner similar to TfR1, but with a 25-fold lower affinity (10,11,12). Iron uptake from transferrin involves binding to its receptors followed by internalization to the early endosomes. (13, 14). Although TfR-mediated iron uptake is the major pathway for iron acquisition, several studies have indicated that additional mechanisms independent of known TfRs exist; however, these have not been well characterized (15-18). GAPDH was previously considered to be an abundantly present cytosolic protein with a key role in energy metabolism. However, recent evidence has proved that it functions as a moonlighting protein in both prokaryotic and eukaryotic cells, often differentially localized within the cell (19 -21). It is of interest to note that in Staphylococcus aureus, cell wall-associated GAPDH had previously been identified as a trans...
The delivery of nonaggregated cargo proteins to Tetrahymena secretory granules requires receptors of the sortilin/VPS10 family, proteins classically associated with lysosome biogenesis.
Cargo-selective and nonselective autophagy pathways employ a common core autophagy machinery that directs biogenesis of an autophagosome that eventually fuses with the lysosome to mediate turnover of macromolecules. In yeast (Saccharomyces cerevisiae) cells, several selective autophagy pathways fail in cells lacking the dimeric Snx4/Atg24 and Atg20/Snx42 sorting nexins containing a BAR domain (SNX-BARs), which function as coat proteins of endosome-derived retrograde transport carriers. It is unclear whether endosomal sorting by Snx4 proteins contributes to autophagy. Cells lacking Snx4 display a deficiency in starvation induced, nonselective autophagy that is severely exacerbated by ablation of mitochondrial phosphatidylethanolamine synthesis. Under these conditions, phosphatidylserine accumulates in the membranes of the endosome and vacuole, autophagy intermediates accumulate within the cytoplasm, and homotypic vacuole fusion is impaired. The Snx4-Atg20 dimer displays preference for binding and remodeling of phosphatidylserine-containing membrane in vitro, suggesting that Snx4-Atg20-coated carriers export phosphatidylserine-rich membrane from the endosome. Autophagy and vacuole fusion are restored by increasing phosphatidylethanolamine biosynthesis via alternative pathways, indicating that retrograde sorting by the Snx4 family sorting nexins maintains glycerophospholipid homeostasis required for autophagy and fusion competence of the vacuole membrane.
More than one and a half years have elapsed since the commencement of the coronavirus disease 2019 (COVID-19) pandemic, and the world is struggling to contain it. Being caused by a previously unknown virus, in the initial period, there had been an extreme paucity of knowledge about the disease mechanisms, which hampered preventive and therapeutic measures against COVID-19. In an endeavor to understand the pathogenic mechanisms, extensive experimental studies have been conducted across the globe involving cell culture-based experiments, human tissue organoids, and animal models, targeted to various aspects of the disease, viz., viral properties, tissue tropism and organ-specific pathogenesis, involvement of physiological systems, and the human immune response against the infection. The vastly accumulated scientific knowledge on all aspects of COVID-19 has currently changed the scenario from great despair to hope. Even though spectacular progress has been made in all of these aspects, multiple knowledge gaps are remaining that need to be addressed in future studies. Moreover, multiple severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) variants have emerged across the globe since the onset of the first COVID-19 wave, with seemingly greater transmissibility/virulence and immune escape capabilities than the wild-type strain. In this review, we narrate the progress made since the commencement of the pandemic regarding the knowledge on COVID-19 mechanisms in the human body, including virus–host interactions, pulmonary and other systemic manifestations, immunological dysregulations, complications, host-specific vulnerability, and long-term health consequences in the survivors. Additionally, we provide a brief review of the current evidence explaining molecular mechanisms imparting greater transmissibility and virulence and immune escape capabilities to the emerging SARS-CoV-2 variants.
In animal cells, the assembly of dense cores in secretory granules is controlled by proteolytic processing of proproteins. The same phenomenon occurs in the ciliate Tetrahymena thermophila, but the proteases involved appear to be highly unrelated, suggesting that similar regulatory mechanisms have different molecular origins.
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