Transmembrane Domain 5 of the LdNT1.1 Nucleoside Transporter Is an Amphipathic Helix That Forms Part of the Nucleoside Translocation Pathway

Valdés, Raquel; Vasudevan, Gayatri; Conklin, David; Landfear, Scott M.

doi:10.1021/bi049873m

Cited by 35 publications

(36 citation statements)

References 55 publications

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“…The magenta rectangle on TM5 denotes the face of TM5 in LdNT1 that was found to be solvent-accessible (27). The roles of these residues in transport function and ligand recognition are described under "Discussion."…”

Section: Discussionmentioning

confidence: 99%

“…7A) is supported by the location of key residues within TMs 1, 2, 4, and 5, all of which map toward the putative aqueous pore in the model, that have been identified by structure-function studies to be critical for ligand selectivity or to be solvent-accessible (4 -6, 8, 27, 28, 36). Specifically these include the following: Met 33 and Leu 92 within hENT1, which have been implicated in the interaction with the vasodilators, dipyridamole and dilazep (Met 33 (5) and LdNT1 (4), respectively, that are important determinants for uridine transport as well as for dilazep interaction in the case of Gly 179 ; Asp 389 and Arg 393 within TM8 of LdNT2, which constitute a conserved signature motif (DXXXR) within the majority of ENTs (10) and are important determinants for transporter function and targeting (11); Cys 337 in LdNT1,which when mutated to a bulkier residue results in a transporter with impaired transport capability (4); residues mapped to the solvent-accessible face of TM5 in LdNT1 (27); and an exofacial Cys 140 in rENT1 (28). Because of the low sequence identity (Ͻ14%) between the MFS and ENTs and the inherent difficulties in modeling unstructured loop domains, this ENT structural prediction will, of course, require extensive computational refinement and experimental validation to evolve.…”

Section: Discussionmentioning

confidence: 99%

“…7A). Furthermore, all the residues on various ENTs that have been identified through biochemical and genetic data to be either solvent-accessible (27,28) or important ligand selectivity determinants (4 -8) were oriented toward the putative ligand-binding pore (Fig. 7A).…”

Section: Isolation Of Suppressor Mutants-previous Data Havementioning

confidence: 99%

See 2 more Smart Citations

Second-site Suppression of a Nonfunctional Mutation within the Leishmania donovani Inosine-Guanosine Transporter

Arastu‐Kapur¹,

Arendt²,

Purnat

et al. 2005

Journal of Biological Chemistry

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LdNT2 is a member of the equilibrative nucleoside transporter family, which possesses several conserved residues located mainly within transmembrane domains. One of these residues, Asp 389 within LdNT2, was shown previously to be critical for transporter function without affecting ligand affinity or plasma membrane targeting. To further delineate the role of Asp 389 in LdNT2 function, second-site suppressors of the ldnt2-D389N null mutation were selected in yeast deficient in purine nucleoside transport and incapable of purine biosynthesis. A library of random mutants within the ldnt2-D389N background was screened in yeast for restoration of growth on inosine. Twelve different clones were obtained, each containing secondary mutations enabling inosine transport. One mutation, N175I, occurred in four clones and conferred augmented inosine transport capability compared with LdNT2 in yeast. N175I was subsequently introduced into an ldnt2-D389N construct tagged with green fluorescent protein and transfected into a ⌬ldnt1/⌬ldnt2 Leishmania donovani knockout. GFP-N175I/D389N significantly suppressed the D389N phenotype and targeted properly to the plasma membrane and flagellum. Most interestingly, N175I increased the inosine K m by 10-fold within the D389N background relative to wild type GFP-LdNT2. Additional substitutions introduced at Asn 175 established that only large, nonpolar amino acids suppressed the D389N phenotype, indicating that suppression by Asn 175 has a specific size and charge requirement. Because multiple suppressor mutations alleviate the constraint imparted by the D389N mutation, these data suggest that Asp 389 is a conformationally sensitive residue. To impart spatial information to the clustering of second-site mutations, a three-dimensional model was constructed based upon members of the major facilitator superfamily using threading analysis. The model indicates that Asn 175 and Asp 389 lie in close proximity and that the second-site suppressor mutations cluster to one region of the transporter.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Second-site Suppression of a Nonfunctional Mutation within the Leishmania donovani Inosine-Guanosine Transporter

Arastu‐Kapur¹,

Arendt²,

Purnat

et al. 2005

Journal of Biological Chemistry

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“…The tag was cloned into the BglII site of the Leishmania pX63NEORI expression vector (22). Subsequently, the open reading frame of LmxGT1 was amplified and cloned into the BamHI and EcoRI sites to generate the LmxGT1::HBH gene fusion.…”

Section: Methodsmentioning

confidence: 99%

KHARON1 Mediates Flagellar Targeting of a Glucose Transporter in Leishmania mexicana and Is Critical for Viability of Infectious Intracellular Amastigotes

Tran

Rodriguez‐Contreras

Vieira

et al. 2013

Journal of Biological Chemistry

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Background:The mechanism for selectively targeting membrane proteins to the flagellum of kinetoplastid parasites is unknown. Results: We have identified a novel protein, KHARON1, which is important for the flagellar targeting of a glucose transporter. Conclusion: KHARON1 is the first protein identified in Kinetoplastida that targets a membrane protein to the flagellum. Significance: KHARON1 may be part of a new flagellar targeting pathway.

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“…This generally requires that most or all naturally occurring cysteine residues in the protein be replaced with other amino acids without altering the structure of the protein, as assessed by comparing function to its wild-type counterpart. Mutation of cysteine residues to alanine or serine in many cases results in a cysteine-less protein retaining wild-type affinity for ligand (see [9][10][11]); however, in other proteins such substitutions result in a non-functional protein [12][13][14]. Identification of substitutions that are functional may not be straightforward in such cases, requiring a significant number of molecular biological and biochemical manipulations to construct and evaluate mutants that one thinks might be functional.…”

Section: Nih Public Accessmentioning

confidence: 99%

Genetic selection for a highly functional cysteine-less membrane protein using site saturation mutagenesis

Arendt

Yates

et al. 2007

Analytical Biochemistry

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We describe an efficient method for generating highly functional membrane proteins with variant amino acids at defined positions that couples a modified site-saturation strategy with functional genetic selection. We applied this method to the production of a cysteine-less variant of the Crithidia fasciculata inosine-guanosine permease CfNT2, in order to facilitate biochemical studies using thiolspecific modifying reagents. Of ten endogenous cysteine residues in CfNT2, two cannot be replaced with serine or alanine without loss of function. High-quality single-and double-mutant libraries were produced by combining a previously reported site-saturation mutagenesis scheme based on the Quikchange method with a novel gel purification step that effectively eliminated template DNA from the products. Following selection for functional complementation in S. cerevisiae cells auxotrophic for purines, several highly functional non-cysteine substitutions were efficiently identified at each desired position, allowing the construction of cysteine-less variants of CfNT2 that retained wild-type affinity for inosine. This combination of an improved site-saturation mutagenesis technique and positive genetic selection provides a simple and efficient means to identify functional and perhaps unexpected amino acid variants at a desired position. Keywordscysteine-less; substituted cysteine accessibility method; membrane protein; site-saturation mutagenesis; genetic selection; Quikchange mutagenesis; equilibrative nucleoside transporter A detailed understanding of how a protein functions must include structural information at some level of resolution. While x-ray crystal structures of thousands of soluble proteins have been determined to date, crystals of membrane proteins that diffract to high resolution are notoriously difficult to obtain [1]. In the absence of any high-resolution structural information for many membrane protein families, biochemical methods provide a valuable means to intuit structure. Several of these methods make use of strategically placed cysteine residues because of their unique chemistry among the natural amino acids. For example, cysteines engineered into two transmembrane helices that can be cross-linked with bifunctional thiol-reactive reagents of varying lengths provide information about the distance between the two helices in the folded structure of the protein [2]. Also, the steric and chemical environment of a cysteine residue engineered at a position of interest can be probed by the substituted cysteine Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. [3][...

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Transmembrane Domain 5 of the LdNT1.1 Nucleoside Transporter Is an Amphipathic Helix That Forms Part of the Nucleoside Translocation Pathway

Cited by 35 publications

References 55 publications

Second-site Suppression of a Nonfunctional Mutation within the Leishmania donovani Inosine-Guanosine Transporter

Second-site Suppression of a Nonfunctional Mutation within the Leishmania donovani Inosine-Guanosine Transporter

KHARON1 Mediates Flagellar Targeting of a Glucose Transporter in Leishmania mexicana and Is Critical for Viability of Infectious Intracellular Amastigotes

Genetic selection for a highly functional cysteine-less membrane protein using site saturation mutagenesis

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