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Enzyme
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Query: EC:3.6.1.3 (
ATPase
)
65,361
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Multidrug resistance transporters (MDRs) are excellent candidates for molecular-level biomonitoring - they function in exporting xenobiotic compounds and their expression is inducible. However, currently available MDR sequence information from aquatic invertebrates is partial and mostly biased towards the conserved
ATPase
domain. In the present study, two genes belonging to the MDR/TAP (ABCB) family were cloned and characterized from the bivalve Brachidontes pharaonis, which thrives in rocky environments along the Israeli Mediterranean coast. One of these is a complete sequence of a 'half'ABCB, probably belonging to the
ABCB10
subfamily, while the second is a 'full'ABCB1 transporter. A quantitative RT-PCR protocol for biomonitoring was tested in laboratory experiments. Bivalves exposed to diesel showed significant increase in B1 expression levels, while the expression of B10 was suppressed. These results suggest that B. pharaonis features an MDR1 homologue that is induced by pollution and may serve as a sentinel organism for routine biomonitoring programs. However, our findings also exemplify that not all MDRs are equally suitable for this purpose and sequence information must be expanded beyond the
ATPase
domain for correct classification of cloned genes.
...
PMID:Cloning and expression of MDR transporters from marine bivalves, and their potential use in biomonitoring. 1671 20
ATP-binding cassette (ABC) transporters are implicated in a diverse range of physiological and pathophysiological processes, such as cholesterol and lipid transportation and multidrug resistance. Despite the considerable efforts made in understanding of the cellular function of ABC proteins, the regulation mechanism of this type of protein is still poorly defined. Here we report the identification and functional characterization of a novel
ATPase
protein, protein associated with ABC transporters (PAAT), in humans. PAAT contains a nucleotide-binding domain (NBD)-like domain and a signal for intramitochondrial sorting. We showed that PAAT is localized in both the cytoplasm and the mitochondria and has an intrinsic
ATPase
activity. PAAT physically interacts with the 3 known mitochondrial inner membrane ABC proteins, ABCB7, ABCB8, and
ABCB10
, but not ABCB1, ABCB6, or ABCG2, and functionally regulates the transport of ferric nutrients and heme biosynthesis. Significantly, PAAT deficiency promotes cell death, reduces mitochondrial potential, and sensitizes mitochondria to oxidative stress-induced DNA damages. Our experiments revealed that PAAT is a novel
ATPase
and a trans-regulator of mitochondrial ABC transporters that plays an important role in the maintenance of mitochondrial homeostasis and cell survival.
...
PMID:PAAT, a novel ATPase and trans-regulator of mitochondrial ABC transporters, is critically involved in the maintenance of mitochondrial homeostasis. 2506 48
ABCB10
(ATP binding cassette sub-family B10) is a mitochondrial inner-membrane ABC transporter.
ABCB10
has been shown to protect the heart from the impact of ROS during ischemia-reperfusion and to allow for proper hemoglobin synthesis during erythroid development. ABC transporters are proteins that increase ATP binding and hydrolysis activity in the presence of the transported substrate. However, molecular entities transported by
ABCB10
and its regulatory mechanisms are currently unknown. Here we characterized ATP binding and hydrolysis properties of
ABCB10
by using the 8-azido-ATP photolabeling technique. This technique can identify potential
ABCB10
regulators, transported substrates and amino-acidic residues required for ATP binding and hydrolysis. We confirmed that Gly497 and Lys498 in the Walker A motif, Glu624 in the Walker B motif and Gly602 in the C-Loop motif of
ABCB10
are required for proper ATP binding and hydrolysis activity, as their mutation changed
ABCB10
8-Azido-ATP photo-labeling. In addition, we show that the potential
ABCB10
transported entity and heme precursor delta-aminolevulinic acid (dALA) does not alter 8-azido-ATP photo-labeling. In contrast, oxidized glutathione (GSSG) stimulates ATP hydrolysis without affecting ATP binding, whereas reduced glutathione (GSH) inhibits ATP binding and hydrolysis. Indeed, we detectABCB10 glutathionylation in Cys547 and show that it is one of the exposed cysteine residues within
ABCB10
structure. In all, we characterize essential residues for
ABCB10
ATPase
activity and we provide evidence that supports the exclusion of dALA as a potential substrate directly transported by
ABCB10
. Last, we show the first molecular mechanism by which mitochondrial oxidative status, through GSH/GSSG, can regulate
ABCB10
.
...
PMID:ATP Binding and Hydrolysis Properties of ABCB10 and Their Regulation by Glutathione. 2605 25
Membrane proteins play important roles in health and disease. Despite their importance, the study of membrane proteins has been significantly limited by the difficulties inherent to their successful expression, purification, and stabilization once they have been extracted from the cell membrane. In addition, expression of human membrane proteins commonly requires the use of expensive and/or time-consuming eukaryotic systems, hence their successful expression in bacteria will be obviously beneficial for experimental research. Furthermore, since lipids can have critical effects on the activity of membrane proteins and given the composition similarities between the inner mitochondrial membrane and the bacterial plasma membrane, production of mitochondrial membrane proteins in E. coli represents a logical choice. Here, we present a novel protocol to produce a human mitochondrial ATP-Binding Cassette (ABC) transporter in E. coli. The function of the three known human mitochondrial ABC transporters is not fully understood, but X-ray crystallography models of
ABCB10
produced in insect cells are available. We have successfully expressed and purified
ABCB10
from E. coli. The yield is close to that of another bacterial ABC transporter routinely produced in our laboratory under similar conditions. In addition, we can efficiently reconstitute detergent purified
ABCB10
into lipid nanodiscs. Measurements of
ATPase
activity of
ABCB10
produced in E. coli show an ATP hydrolysis rate similar to other human ABC transporters. This novel protocol facilitates the production of this human mitochondrial transporter for biochemical, structural, and functional analysis, and can likely be adjusted for production of other mitochondrial transporters.
...
PMID:Production of a human mitochondrial ABC transporter in E. coli. 3306 25
Heme biosynthesis occurs through a series of reactions that take place within the cytoplasm and mitochondria, so intermediates need to move across these cellular compartments. However, the specific membrane transport mechanisms involved in the process are not yet identified. The ATP-binding cassette protein
ABCB10
is essential for normal heme production, as knocking down this transporter in mice is embryonically lethal and accompanied by severe anemia plus oxidative damage. The role of
ABCB10
is unknown, but given its location in the inner mitochondrial membrane, it has been proposed as a candidate to export either an early heme precursor or heme. Alternatively,
ABCB10
might transport a molecule important for protection against oxidative damage. To help discern between these possibilities, we decided to study the effect of heme analogs, precursors, and antioxidant peptides on purified human
ABCB10
. Since substrate binding increases the ATP hydrolysis rate of ABC transporters, we have determined the ability of these molecules to activate purified
ABCB10
reconstituted in lipid nanodiscs using
ATPase
measurements. Under our experimental conditions, we found that the only heme analog increasing
ABCB10
ATPase
activity was Zinc-mesoporphyrin. This activation of almost seventy percent was specific for
ABCB10
, as the
ATPase
activity of a negative control bacterial ABC transporter was not affected. The activation was also observed in cysteine-less
ABCB10
, suggesting that Zinc-mesoporphyrin's effect did not require binding to typical heme regulatory motifs. Furthermore, our data indicate that
ABCB10
was not directly activated by neither the early heme precursor delta-aminolevulinic acid nor glutathione, downsizing their relevance as putative substrates for this transporter. Although additional studies are needed to determine the physiological substrate of
ABCB10
, our findings reveal Zinc-mesoporphyrin as the first tool compound to directly modulate
ABCB10
activity and raise the possibility that some actions of Zinc-mesoporphyrin in cellular and animal studies could be mediated by
ABCB10
.
...
PMID:Stimulation of the human mitochondrial transporter ABCB10 by zinc-mesoporphrin. 3325 25
