Ser/Thr Motifs in Transmembrane Proteins: Conservation Patterns and Effects on Local Protein Structure and Dynamics

Val, Coral del; White, Stephen H.; Bondar, Ana‐Nicoleta

doi:10.1007/s00232-012-9452-4

Cited by 31 publications

(17 citation statements)

References 94 publications

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“…Polar residues located in MSDs of transmembrane helices have been shown to be important contributors to protein packing, oligomerization, and TM stabilization (43)(44)(45)(46)(47)(48). To determine whether the hydrogen-bonding capacity of the residues we identified in the ectodomain interface was important for function, we made alanine substitutions to the wild-type protein (HA tagged) in both the presence or absence of the full-length cytoplasmic tail.…”

Section: Resultsmentioning

confidence: 99%

Characterizing the Murine Leukemia Virus Envelope Glycoprotein Membrane-Spanning Domain for Its Roles in Interface Alignment and Fusogenicity

Salamango

Johnson

2015

J Virol

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The membrane-proximal region of murine leukemia virus envelope (Env) is a critical modulator of its functionality. We have previously shown that the insertion of one amino acid (؉1 leucine) within the membrane-spanning domain (MSD) abolished protein functionality in infectivity assays. However, functionality could be restored to this ؉1 leucine mutant by either inserting two additional amino acids (؉3 leucine) or by deleting the cytoplasmic tail domain (CTD) in the ؉1 leucine background. We inferred that the ectodomain and CTD have protein interfaces that have to be in alignment for Env to be functional. Here, we made single residue deletions to the Env mutant with the ؉1 leucine insertion to restore the interface alignment (gain of functionality) and therefore define the boundaries of the two interfaces. We identified the glycine-proline pairs near the N terminus (positions 147 and 148) and the C terminus (positions 159 and 160) of the MSD as being the boundaries of the two interfaces. Deletions between these pairs restored function, but deletions outside of them did not. In addition, the vast majority of the single residue deletions regained function if the CTD was deleted. The exceptions were four hydroxyl-containing amino acid residues (T139, T140, S143, and T144) that reside in the ectodomain interface and the proline at position 148, which were all indispensable for functionality. We hypothesize that the hydroxyl-containing residues at positions T139 and S143 could be a driving force for stabilizing the ectodomain interface through formation of a hydrogen-bonding network. IMPORTANCEThe membrane-proximal external region (MPER) and membrane-spanning domains (MSDs) of viral glycoproteins have been shown to be critical for regulating glycoprotein fusogenicity. However, the roles of these two domains are poorly understood. We report here that point deletions and insertions within the MPER or MSD result in functionally inactive proteins. However, when the C-terminal tail domain (CTD) is deleted, the majority of the proteins remain functional. The only residues that were found to be critical for function regardless of the CTD were four hydroxyl-containing amino acids located at the C terminus of the MPER (T139 and T140) and at the N terminus of the MSD (S143 and T144) and a proline near the beginning of the MSD (P148). We demonstrate that hydrogen-bonding at positions T139 and S143 is critical for protein function. Our findings provide novel insights into the role of the MPER in regulating fusogenic activity of viral glycoproteins. E nveloped viruses require membrane-spanning cell surface glycoproteins to coordinate fusion between viral and host cell membranes. Retroviral envelope (Env) glycoproteins are produced as precursors that undergo trimerization in the endoplasmic reticulum (1-3). Subsequently, the precursor trimer is cleaved into two subdomains: the receptor-binding surface domain (SU) and the fusion-promoting transmembrane domain (TM). This cleavage process is mediated by a host-cell furin, or f...

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Section: Resultsmentioning

confidence: 99%

Characterizing the Murine Leukemia Virus Envelope Glycoprotein Membrane-Spanning Domain for Its Roles in Interface Alignment and Fusogenicity

Salamango

Johnson

2015

J Virol

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“…By competing with backbone amide groups for hydrogen bonding to carbonyls, Ser/Thr groups can weaken the regular amide/carbonyl backbone hydrogen bonding, increasing the local dynamics of the helix [39]. Examples of such hydroxyl/carbonyl intra-helical hydrogen bonding include the network of hydrogen bonds involving S245 and S249 on the extracellular side (Figure S10), the transient hydrogen bond between S212 and the K215 carbonyl (Figure S7), or the intra-helical hydrogen bond between T218 and the L214 carbonyl (Figure S7).…”

Section: Resultsmentioning

confidence: 99%

Electrostatic interactions and hydrogen bond dynamics in chloride pumping by halorhodopsin

Jardón-Valadez

Bondar

Tobias

2014

Biochimica et Biophysica Acta (BBA) - Bioenergetics

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Translocation of negatively charged ions across cell membranes by ion pumps raises the question as to how protein interactions control the location and dynamics of the ion. Here we address this question by performing extensive molecular dynamics simulations of wild type and mutant halorhodopsin, a seven-helical transmembrane protein that translocates chloride ions upon light absorption. We find that inter-helical hydrogen bonds mediated by a key arginine group largely govern the dynamics of the protein and water groups coordinating the chloride ion.

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“…In general, proton coupling involves the protonation and deprotonation of one or more residues, but strictly speaking, it is difficult to discriminate protonation/deprotonation of amino acid residues from binding and translocation of a hydronium ion (130). The transfer of a proton may happen via a series of protein amino acids, involving carboxylates, hydroxyls, amines, and water (131). Such a proton permeation pathway requires that proton translocation is coupled to solute binding and translocation, as the system would otherwise create a proton leak (124,132).…”

Section: Energy-coupling Mechanism and Amino Acid Accumulationmentioning

confidence: 99%

Regulation of Amino Acid Transport in Saccharomyces cerevisiae

Bianchi

Klooster

Ruiz

et al. 2019

Microbiol Mol Biol Rev

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SUMMARY We review the mechanisms responsible for amino acid homeostasis in Saccharomyces cerevisiae and other fungi. Amino acid homeostasis is essential for cell growth and survival. Hence, the de novo synthesis reactions, metabolic conversions, and transport of amino acids are tightly regulated. Regulation varies from nitrogen pool sensing to control by individual amino acids and takes place at the gene (transcription), protein (posttranslational modification and allostery), and vesicle (trafficking and endocytosis) levels. The pools of amino acids are controlled via import, export, and compartmentalization. In yeast, the majority of the amino acid transporters belong to the APC (amino acid-polyamine-organocation) superfamily, and the proteins couple the uphill transport of amino acids to the electrochemical proton gradient. Although high-resolution structures of yeast amino acid transporters are not available, homology models have been successfully exploited to determine and engineer the catalytic and regulatory functions of the proteins. This has led to a further understanding of the underlying mechanisms of amino acid sensing and subsequent downregulation of transport. Advances in optical microscopy have revealed a new level of regulation of yeast amino acid transporters, which involves membrane domain partitioning. The significance and the interrelationships of the latest discoveries on amino acid homeostasis are put in context.

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Ser/Thr Motifs in Transmembrane Proteins: Conservation Patterns and Effects on Local Protein Structure and Dynamics

Cited by 31 publications

References 94 publications

Characterizing the Murine Leukemia Virus Envelope Glycoprotein Membrane-Spanning Domain for Its Roles in Interface Alignment and Fusogenicity

Characterizing the Murine Leukemia Virus Envelope Glycoprotein Membrane-Spanning Domain for Its Roles in Interface Alignment and Fusogenicity

Electrostatic interactions and hydrogen bond dynamics in chloride pumping by halorhodopsin

Regulation of Amino Acid Transport in Saccharomyces cerevisiae

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