Na
 +
 coordination at the Na2 site of the Na
 +
 /I
 −
 symporter

Ferrandino, Giuseppe; Nicola, Juan Pablo; Sánchez, Yuly E.; Echeverria, Ignacia; Liu, Yunlong; Amzel, L. Mario; Carrasco, Nancy

doi:10.1073/pnas.1607231113

Cited by 21 publications

(10 citation statements)

References 92 publications

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“…The sodium binding pocket comprises the homologous residues S64 and S67 in TM2; T188, D189 and Q192 in TM6; S347, T349, S351, T352, S354 and S355 in TM9; and, Q261 in TM7 ( Figure 2 B). Notably, while this work was being developed, Ferrandino et al reported computational and biochemical data supporting the role of residues S66, D191, Q194, and Q263 in coordinating sodium in hNIS at the Na2 site, 62 providing independent confirmation of our findings. We propose, therefore, that at least one sodium ion involved in hNIS and hSMCT1 substrate transport is coordinated by a binding pocket conserved between both proteins.…”

Section: Resultssupporting

confidence: 83%

“…The participation of residues S66, D191, Q194, and Q263 in hNIS-mediated iodide uptake has been recently demonstrated by experiments. 62 The hNIS and hSMCT1 models are oriented with the extracellular side toward the top of the page. (C) Sequence logo illustrating conservation of the residues (indicated with arrows) predicted to coordinate the Na + ion.…”

Section: Resultsmentioning

confidence: 99%

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Iodide Binding in Sodium-Coupled Cotransporters

Vergara-Jaque

Fong

Comer

2017

J. Chem. Inf. Model.

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Several apical iodide translocation pathways have been proposed for iodide efflux out of thyroid follicular cells, including a pathway mediated by the sodium-coupled monocarboxylate transporter 1 (SMCT1), which remains controversial. Herein, we evaluate structural and functional similarities between SMCT1 and the well-studied sodium-iodide symporter (NIS) that mediates the first step of iodide entry into the thyroid. Free-energy calculations using a force field with electronic polarizability verify the presence of a conserved iodide-binding pocket between the TM2, TM3, and TM7 segments in hNIS, where iodide is coordinated by Phe67, Gln72, Cys91, and Gln94. We demonstrate the mutation of residue Gly93 of hNIS to a larger amino acid expels the side chain of a critical tryptophan residue (Trp255) into the interior of the binding pocket, partially occluding the iodide binding site and reducing iodide affinity, which is consistent with previous reports associating mutation of this residue with iodide uptake deficiency and hypothyroidism. Furthermore, we find that the position of Trp255 in this hNIS mutant mirrors that of Trp253 in wild-type hSMCT1, where a threonine (Thr91) occupies the position homologous to that occupied by glycine in wild-type hNIS (Gly93). Correspondingly, mutation of Thr91 to glycine in hSMCT1 makes the pocket structure more like that of wild-type hNIS, increasing its iodide affinity. These results suggest that wild-type hSMCT1 in the inward-facing conformation may bind iodide only very weakly, which may have implications for its ability to transport iodide.

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Section: Resultssupporting

confidence: 83%

Section: Resultsmentioning

confidence: 99%

Iodide Binding in Sodium-Coupled Cotransporters

Vergara-Jaque

Fong

Comer

2017

J. Chem. Inf. Model.

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“…Mouse Tlr4 promoter constructs þ52/þ223, À104/þ223, À336/þ223, and À608/þ223 were as reported previously (24). Disruption of the distal Ets-binding site in the mouse Tlr4 promoter was performed by PCR with the oligonucleotide 5 0 -TGGGTTTT-AATCTCTAGCATTGTGAGAAAATATGTAGTTCTAGTCTGAAAC-ATCCA carrying the desire mutation (underlined) using KOD Hot Start DNA polymerase (EMD Millipore) as described previously (25). The artificial ETS reporter 3x Ets d -Luc contains the luciferase gene under the control of a promoter containing three copies in tandem of the flanking region of the distal Ets-binding site (AAAATATGTTCCTCTAGTCTGA) of mouse Tlr4 promoter upstream the adenovirus E1B core promoter.…”

Section: Plasmidsmentioning

confidence: 99%

Functional Toll-like Receptor 4 Overexpression in Papillary Thyroid Cancer by MAPK/ERK–Induced ETS1 Transcriptional Activity

Peyret

Nazar

Martín

et al. 2018

Molecular Cancer Research

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Emerging evidence suggests that unregulated Toll-like receptor (TLR) signaling promotes tumor survival signals, thus favoring tumor progression. Here, the mechanism underlying TLR4 overexpression in papillary thyroid carcinomas (PTC) mainly harboring the BRAF mutation was studied. TLR4 was overexpressed in PTC compared with nonneoplastic thyroid tissue. Moreover, paired clinical specimens of primary PTC and its lymph node metastasis showed a significant upregulation of TLR4 levels in the metastatic tissues. In agreement, conditional BRAF expression in normal rat thyroid cells and mouse thyroid tissue upregulated TLR4 expression levels. Furthermore, functional TLR4 expression was demonstrated in PTC cells by increased NF-κB transcriptional activity in response to the exogenous TLR4-agonist lipopolysaccharide. Of note, The Cancer Genome Atlas data analysis revealed that BRAF-positive tumors with high TLR4 expression were associated with shorter disease-free survival. Transcriptomic data analysis indicated a positive correlation between TLR4 expression levels and MAPK/ERK signaling activation. Consistently, chemical blockade of MAPK/ERK signaling abrogated BRAF-induced TLR4 expression. A detailed study of the promoter revealed a critical MAPK/ERK-sensitive Ets-binding site involved in BRAF responsiveness. Subsequent investigation revealed that the Ets-binding factor ETS1 is critical for BRAF-induced MAPK/ERK signaling-dependent gene expression. Together, these data indicate that functional TLR4 overexpression in PTCs is a consequence of thyroid tumor-oncogenic driver dysregulation of MAPK/ERK/ETS1 signaling. Considering the participation of aberrant NF-κB signaling activation in the promotion of thyroid tumor growth and the association of high TLR4 expression with more aggressive tumors, this study suggests a prooncogenic potential of TLR4 downstream signaling in thyroid tumorigenesis. .

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“…The mechanism by which NIS transports its various monovalent anionic substrates remains poorly understood. NIS does not transport every monovalent anion and it is still unclear what differentiates a substrate from an inhibitor or irrelevant anion [13,[83][84][85][86][87]. Here we compared the anion selectivity and inhibitor sensitivity of NIS proteins from diverse animal species and found, unexpectedly, that they differ not only in their ability to transport the NIS substrates 99m , but also in their susceptibilities to inhibition of iodide transport by a wide range of monovalent anions.…”

Section: Discussionmentioning

confidence: 84%

“…Mapping of the residues in direct contact with the transported ions revealed no significant differences in the sampled models in terms of residue identity and side chain positions between the three species of NIS protein (Fig 8B-8E). Several of these residues have been previously reported as crucial for NIS activity [53,85,86]. Within the hNIS, wNIS, and zNIS subset, the differing residues in the binding areas are at positions 64, 188, and 195, where only the substitution at position 64 (S64C in wNIS and S64A in zNIS) leads to change in the chemical properties of the side chain.…”

Section: Discussionmentioning

confidence: 96%