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Query: UMLS:C0022716 (
Menkes
)
1,057
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Despite the importance of metal ions in several catalytic functions, there has been, until recently, little molecular information available on the mechanisms whereby metal ions are actively taken up by mammalian cells. The classical concept for iron uptake into mammalian cells has been the endocytosis of
transferrin
-bound Fe3+ by the transferrin receptor. Studies with hypotransferrinaemic mice revealed that in the intestine mucosal
transferrin
is derived from the plasma and that its presence is not required in the intestinal lumen for dietary iron absorption. This suggests that, at least in the intestine, other non-receptor-mediated uptake systems exist. The molecular identification of metal ion transporters is of great importance, in particular since an increasing number of human diseases are thought to be related to disturbances in metal ion homeostasis, including metal ion overload and deficiency disorders (i.e. anaemia, haemochromatosis,
Menkes disease
, Wilson's disease), and neurodegenerative diseases (i.e. Alzheimer's, Friedreich's ataxia and Parkinson's diseases). Furthermore, susceptibilities to mycobacterial infections are caused by metal ion transporter defects. The pathological implications of disturbed metal ion homeostasis confirm the vital roles these metal ions play in the catalytic function of many enzymes, in gene regulation (zinc-finger proteins), and in free radical homeostasis. Recent insights have significantly advanced our knowledge of how metal ions are taken up or released by mammalian cells. The purpose of this review is to summarize these advances and to give an overview on the growing number of mammalian metal ion transporters.
...
PMID:Metal ion transporters in mammals: structure, function and pathological implications. 1037 84
Menkes disease
is an X-linked recessive copper deficiency disorder caused by mutations in the ATP7A (
MNK
) gene which encodes a copper transporting P-type ATPase (
MNK
).
MNK
is normally localized pre- dominantly in the trans -Golgi network (TGN); however, when cells are exposed to excessive copper it is rapidly relocalized to the plasma membrane where it functions in copper efflux. In this study, the c-myc epitope was introduced within the loop connecting the first and second transmembrane regions of
MNK
. This myc epitope allowed detection of the protein at the surface of living cells and provided the first experimental evidence supporting the common topological model. In cells stably expressing the tagged
MNK
protein (
MNK
-tag), extracellular antibodies were internalized to the perinuclear region, indicating that
MNK
-tag at the TGN constitutively cycles via the plasma membrane in basal copper conditions. Under elevated copper conditions,
MNK
-tag was recruited to the plasma membrane; however, internalization of
MNK
-tag was not inhibited and the protein continued to recycle through cyto- plasmic membrane compartments. These findings suggest that copper stimulates exocytic movement of
MNK
to the plasma membrane rather than reducing
MNK
retrieval and indicate that
MNK
may remove copper from the cytoplasm by transporting copper into the vesicles through which it cycles. Newly internalized
MNK
-tag and
transferrin
were found to co-localize, suggesting that
MNK
-tag follows a clathrin-coated pit/endosomal pathway into cells. Mutation of the di-leucine, L1487 L1488, prevented uptake of anti-myc antibodies in both basal and elevated copper conditions, thereby identifying this sequence as an endocytic signal for
MNK
. Analysis of the effects of the di-leucine mutation in elevated copper provided further support for copper-stimulated exocytic movement of
MNK
from the TGN to the plasma membrane.
...
PMID:The Menkes protein (ATP7A; MNK) cycles via the plasma membrane both in basal and elevated extracellular copper using a C-terminal di-leucine endocytic signal. 1048 81
The etiology of many neurodegenerative diseases has been only partly attributed to acquired traits, suggesting environmental factors may also contribute. Metal dyshomeostasis causes or has been implicated in many neurodegenerative diseases. Metal flux across the blood-brain barrier (the primary route of brain metal uptake) and the choroid plexuses as well as sensory nerve metal uptake from the nasal cavity are reviewed. Transporters that have been described at the blood-brain barrier are listed to illustrate the extensive possibilities for moving substances into and out of the brain. The controversial role of aluminum in Alzheimer's disease, evidence suggesting brain aluminum uptake by
transferrin
-receptor mediated endocytosis and of aluminum citrate by system Xc;{-} and an organic anion transporter, and results suggesting transporter-mediated aluminum brain efflux are reviewed. The ability of manganese to produce a parkinsonism-like syndrome, evidence suggesting manganese uptake by
transferrin
- and non-
transferrin
-dependent mechanisms which may include store-operated calcium channels, and the lack of transporter-mediated manganese brain efflux, are discussed. The evidence for
transferrin
-dependent and independent mechanisms of brain iron uptake is presented. The copper transporters, ATP7A and ATP7B, and their roles in
Menkes
and Wilson's diseases, are summarized. Brain zinc uptake is facilitated by L- and D-histidine, but a transporter, if involved, has not been identified. Brain lead uptake may involve a non-energy-dependent process, store-operated calcium channels, and/or an ATP-dependent calcium pump. Methyl mercury can form a complex with L-cysteine that mimics methionine, enabling its transport by the L system. The putative roles of zinc transporters, ZnT and Zip, in regulating brain zinc are discussed. Although brain uptake mechanisms for some metals have been identified, metal efflux from the brain has received little attention, preventing integration of all processes that contribute to brain metal concentrations.
...
PMID:Blood-brain barrier flux of aluminum, manganese, iron and other metals suspected to contribute to metal-induced neurodegeneration. 1711 90
