Your search keyword '"Suda, Srinivas"' showing total 3 results

1. Prion protein promotes kidney iron uptake via its ferrireductase activity.

Author

Haldar S, Tripathi A, Qian J, Beserra A, Suda S, McElwee M, Turner J, Hopfer U, and Singh N

Subjects

Animals, Blotting, Western, Cell Line, Transformed, Cell Membrane metabolism, FMN Reductase genetics, Female, Ion Transport genetics, Iron pharmacokinetics, Iron Radioisotopes, Kidney cytology, Kidney Tubules, Proximal cytology, Kidney Tubules, Proximal metabolism, Male, Mice, Knockout, Mice, Transgenic, Microscopy, Confocal, PrPC Proteins genetics, Transferrin metabolism, Transferrin pharmacokinetics, FMN Reductase metabolism, Iron metabolism, Kidney metabolism, PrPC Proteins metabolism

Abstract

Brain iron-dyshomeostasis is an important cause of neurotoxicity in prion disorders, a group of neurodegenerative conditions associated with the conversion of prion protein (PrP(C)) from its normal conformation to an aggregated, PrP-scrapie (PrP(Sc)) isoform. Alteration of iron homeostasis is believed to result from impaired function of PrP(C) in neuronal iron uptake via its ferrireductase activity. However, unequivocal evidence supporting the ferrireductase activity of PrP(C) is lacking. Kidney provides a relevant model for this evaluation because PrP(C) is expressed in the kidney, and ∼370 μg of iron are reabsorbed daily from the glomerular filtrate by kidney proximal tubule cells (PT), requiring ferrireductase activity. Here, we report that PrP(C) promotes the uptake of transferrin (Tf) and non-Tf-bound iron (NTBI) by the kidney in vivo and mainly NTBI by PT cells in vitro. Thus, uptake of (59)Fe administered by gastric gavage, intravenously, or intraperitoneally was significantly lower in PrP-knock-out (PrP(-/-)) mouse kidney relative to PrP(+/+) controls. Selective in vivo radiolabeling of plasma NTBI with (59)Fe revealed similar results. Expression of exogenous PrP(C) in immortalized PT cells showed localization on the plasma membrane and intracellular vesicles and increased transepithelial transport of (59)Fe-NTBI and to a smaller extent (59)Fe-Tf from the apical to the basolateral domain. Notably, the ferrireductase-deficient mutant of PrP (PrP(Δ51-89)) lacked this activity. Furthermore, excess NTBI and hemin caused aggregation of PrP(C) to a detergent-insoluble form, limiting iron uptake. Together, these observations suggest that PrP(C) promotes retrieval of iron from the glomerular filtrate via its ferrireductase activity and modulates kidney iron metabolism., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

2. Brain iron homeostasis: from molecular mechanisms to clinical significance and therapeutic opportunities.

Author

Singh N, Haldar S, Tripathi AK, Horback K, Wong J, Sharma D, Beserra A, Suda S, Anbalagan C, Dev S, Mukhopadhyay CK, and Singh A

Subjects

Animals, Biological Transport, Blood-Brain Barrier metabolism, Brain pathology, Ferritins metabolism, Humans, Iron Chelating Agents pharmacology, Iron Chelating Agents therapeutic use, Mitochondria metabolism, Neurodegenerative Diseases drug therapy, Yeasts metabolism, Brain metabolism, Homeostasis, Iron metabolism, Neurodegenerative Diseases metabolism

Abstract

Iron has emerged as a significant cause of neurotoxicity in several neurodegenerative conditions, including Alzheimer's disease (AD), Parkinson's disease (PD), sporadic Creutzfeldt-Jakob disease (sCJD), and others. In some cases, the underlying cause of iron mis-metabolism is known, while in others, our understanding is, at best, incomplete. Recent evidence implicating key proteins involved in the pathogenesis of AD, PD, and sCJD in cellular iron metabolism suggests that imbalance of brain iron homeostasis associated with these disorders is a direct consequence of disease pathogenesis. A complete understanding of the molecular events leading to this phenotype is lacking partly because of the complex regulation of iron homeostasis within the brain. Since systemic organs and the brain share several iron regulatory mechanisms and iron-modulating proteins, dysfunction of a specific pathway or selective absence of iron-modulating protein(s) in systemic organs has provided important insights into the maintenance of iron homeostasis within the brain. Here, we review recent information on the regulation of iron uptake and utilization in systemic organs and within the complex environment of the brain, with particular emphasis on the underlying mechanisms leading to brain iron mis-metabolism in specific neurodegenerative conditions. Mouse models that have been instrumental in understanding systemic and brain disorders associated with iron mis-metabolism are also described, followed by current therapeutic strategies which are aimed at restoring brain iron homeostasis in different neurodegenerative conditions. We conclude by highlighting important gaps in our understanding of brain iron metabolism and mis-metabolism, particularly in the context of neurodegenerative disorders.

Published

2014

3. Prion protein functions as a ferrireductase partner for ZIP14 and DMT1.

Author

Tripathi, Ajai K., Haldar, Swati, Qian, Juan, Beserra, Amber, Suda, Srinivas, Singh, Ajay, Hopfer, Ulrich, Chen, Shu G., Garrick, Michael D., Turner, Jerrold R., Knutson, Mitchell D., and Singh, Neena

Subjects

*PRIONS, *TRANSFERRIN, *CELL membranes, *BIOLOGICAL membranes, *METAL transport proteins, *N-terminal residues

Abstract

Excess circulating iron is stored in the liver, and requires reduction of non-Tf-bound iron (NTBI) and transferrin (Tf) iron at the plasma membrane and endosomes, respectively, by ferrireductase (FR) proteins for transport across biological membranes through divalent metal transporters. Here, we report that prion protein (PrP C ), a ubiquitously expressed glycoprotein most abundant on neuronal cells, functions as a FR partner for divalent-metal transporter-1 (DMT1) and ZIP14. Thus, absence of PrP C in PrP-knock-out (PrP –/– ) mice resulted in markedly reduced liver iron stores, a deficiency that was not corrected by chronic or acute administration of iron by the oral or intraperitoneal routes. Likewise, preferential radiolabeling of circulating NTBI with 59 Fe revealed significantly reduced uptake and storage of NTBI by the liver of PrP –/– mice relative to matched PrP +/+ controls. However, uptake, storage, and utilization of ferritin-bound iron that does not require reduction for uptake were increased in PrP –/– mice, indicating a compensatory response to the iron deficiency. Expression of exogenous PrP C in HepG2 cells increased uptake and storage of ferric iron (Fe 3+ ), not ferrous iron (Fe 2+ ), from the medium, supporting the function of PrP C as a plasma membrane FR. Coexpression of PrP C with ZIP14 and DMT1 in HepG2 cells increased uptake of Fe 3+ significantly, and surprisingly, increased the ratio of N-terminally truncated PrP C forms lacking the FR domain relative to full-length PrP C . Together, these observations indicate that PrP C promotes, and possibly regulates, the uptake of NTBI through DMT1 and Zip14 via its FR activity. Implications of these observations for neuronal iron homeostasis under physiological and pathological conditions are discussed. [ABSTRACT FROM AUTHOR]

Published

2015