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Prediction of membrane protein structureSon, Hyeon S. January 1997 (has links)
No description available.
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Marginally hydrophobic transmembrane α-helices shaping membrane protein foldingde Marothy, Tuuli Minttu Virkki January 2014 (has links)
Most membrane proteins are inserted into the membrane co-translationally utilizing the translocon, which allows a sufficiently long and hydrophobic stretch of amino acids to partition into the membrane. However, X-ray structures of membrane proteins have revealed that some transmembrane helices (TMHs) are surprisingly hydrophilic. These marginally hydrophobic transmembrane helices (mTMH) are not recognized as TMHs by the translocon in the absence of local sequence context. We have studied three native mTMHs, which were previously shown to depend on a subsequent TMH for membrane insertion. Their recognition was not due to specific interactions. Instead, the presence of basic amino acids in their cytoplasmic loop allowed membrane insertion of one of them. In the other two, basic residues are not sufficient unless followed by another, hydrophobic TMH. Post-insertional repositioning are another way to bring hydrophilic residues into the membrane. We show how four long TMHs with hydrophilic residues seen in X-ray structures, are initially inserted as much shorter membrane-embedded segments. Tilting is thus induced after membrane-insertion, probably through tertiary packing interactions within the protein. Aquaporin 1 illustrates how a mTMH can shape membrane protein folding and how repositioning can be important in post-insertional folding. It initially adopts a four-helical intermediate, where mTMH2 and TMH4 are not inserted into the membrane. Consequently, TMH3 is inserted in an inverted orientation. The final conformation with six TMHs is formed by TMH2 and 4 entering the membrane and TMH3 rotating 180°. Based on experimental and computational results, we propose a mechanism for the initial step in the folding of AQP1: A shift of TMH3 out from membrane core allows the preceding regions to enter the membrane, which provides flexibility for TMH3 to re-insert in its correct orientation. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 2: Manuscript.</p>
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Molecular Dynamics Simulation Of Transmembrane Helices And Analysis Of Their Packing In Integral Membrane ProteinsIyer, Lakshmanan K 09 1900 (has links) (PDF)
No description available.
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Sequence And Structural Determinants of Helices in Membrane ProteinsShelar, Ashish January 2016 (has links) (PDF)
Membrane proteins roughly constitute 30% of open reading frames in a genome and form 70% of current drug targets. They are classified as integral, peripheral membrane proteins and polypeptide toxins. α-helices and β -strands are the principal secondary structures observed in integral membrane proteins. This thesis presents the results of studies on analysis and correlation of sequence and structure of helices constituting integral helical membrane proteins. The aim of this work is to understand the helix stabilization, distortion as well as packing in terms of amino acid sequences and the correlated structures they adopt. To this end, analyses of datasets of X-ray crystal structures of integral helical membrane proteins and their comparison with a dataset of representative folds of globular proteins was carried out. Initial analysis was carried out using a non-redundant dataset of 75 membrane proteins to understand sequence and structural preferences for stabilization of helix termini. The subsequent analysis of helix distortions in membrane proteins was carried out using an updated dataset of 90 membrane proteins.
Chapter 1 of the thesis reviews experimental as well as theoretical studies that have provided insights into understanding the structure of helical membrane proteins.
Chapter 2 details the methods used during the course of the present investigations. These include the protocol used for creation of the non-redundant database of membrane and globular proteins. Various statistical methods used to test significance of the position-wise representation of amino acids in helical regions and the differences in globular and membrane protein datasets have been listed. Based on the tests of significance, a methodology to identify differences in propensity values that are statistically significant among two datasets has been devised. Programs used for secondary structure identification of membrane proteins namely Structure Identification (STRIDE) and Assignment of Secondary Structure in Proteins (ASSP) as well as those used for characterization of helical geometry (Helanal-Plus) have also been enlisted.
In Chapter 3, datasets of 865 α-helices in 75 membrane proteins and 2680 α- helices from 626 representative folds in globular proteins defined by the STRIDE program have been analyzed to study the sequence determinants at fifteen positions within and around the α-helix. The amino acid propensities have been studied for positions that are important for the process of helix initiation, propagation, stabilization and termination. Each of the 15 positions has unique sequence characteristics reflecting their role and contribution towards the stability of the α-helix. A comparison of the sequence preferences in membrane and globular proteins revealed common residue preferences in both these datasets confirming the importance of these positions and the strict residue preferences therein. However, short/medium length α-helices that initiated/terminated within the membrane showed distinct amino acid preferences at the N-terminus (Ncap, N1, N2) as well as the C-terminus ( Ccap, Ct) when compared to α-helices belonging to membrane and globular proteins. The sequence preferences in membrane proteins were governed by the helix initiating and terminating property of the amino acids as well as the external environment of the helix. Results from our analysis also conformed well with experimentally tested amino acid preferences in a position-specific amino acid preference library of the rat neurotensin receptor (Schlinkmann et al (2012) Proc Natl Acad Sci USA 109(25):1890-5) as well as crystal structures of GPCR proteins.
In the light of the environment dependent amino acid preferences found at α- helix termini, a survey was carried out to find various helix capping motifs adopted at both termini of α-helices in globular and membrane proteins to stabilize these helix termini. The results from these findings have been reported in Chapter 4. A sequence dependent structural preference is found for capping motifs at helix termini embedded inside and protruding outside the membrane. The N-terminus of α-helices was capped by hydrogen bonds involving free main chain amide groups of the first helical turn as donors and amino acid side chains as acceptors, as against the C-terminus which showed position-dependent characteristic backbone conformations to cap the helix. Overall helix termini inside the membrane did not show a very high number of capping motifs; instead these termini were stabilized by helix- helix interactions contributed by the neighboring helices of the helical bundle.
In Chapter 5, we examine transmembrane helical (TMH) regions to identify as well as characterize the various types of helix perturbations in membrane proteins using ASSP and Helanal-Plus. A survey of literature shows that the term ‘helix kink’ has been used rather loosely when in fact helical regions show significant amounts of variation and transitions in helical parameters. Hence a systematic analysis of TMH regions was undertaken to quantify different types of helix perturbations, based on geometric parameters such as helical twist, rise per residue and local bending angle. Results from this analysis indicated that helices are not only kinked but undergo transitions to form interspersed stretches of 310 helices and π-bulges within the bilayer. These interspersed 310 and π-helices showed unique sequence preferences within and around their helical body, and also assisted in main- taining the helical structure within the bilayer. We found that Proline not only kinked the helical regions in a characteristic manner but also caused a tightening or unwinding in a helical region to form 310 and π-helix fragments respectively. The helix distortions also resulted in backbone hydrogen bonds to be missed which were stabilized by hydrogen bonds from neighboring residues mediated by their side chain atoms. Furthermore, a packing analysis showed that helical regions with distortions were able to establish inter-helical interactions with more number of transmembrane segments in the helical bundle.
The study on helix perturbations presented in the previous chapter, brought to light a previously unreported 19 amino acid π-helix fragment interspersed between α-helices in the functionally important transmembrane helix 2 (TM2) belonging to Mitochondrial cytochrome-c-oxidase (1v55). Chapter 6 describes a case study of the structurally similar but functionally different members within the Heme-Copper- Superoxidases (HCO) superfamily that were considered for a comparative analysis of TM2. An analysis of 7 family members revealed that the π-helix shortens, fragments in two shorter π-helices or was even absent in some family members. The long π-helix significantly decreased the total twist and rise of the entire helical fragment thus accommodating more hydrophobic amino acids within the bilayer to avoid hydrophobic mismatch with the bilayer. The increased radius of the TM2 helical fragment also assisted in helix packing interactions by increasing the number of residues involved in helix-helix interactions and hydrogen bonds.
Chapter 7 documents the conclusions from the different analyses presented in each of the above chapters. Overall, it is found that membrane proteins optimize the biophysical and chemical constraints of the external environment to strategically place select amino acids at helix termini to ‘start’ and ‘stop’ α-helices. The stabilization of these helix termini is a consequence of sequence dependent structural preferences to form helix capping motifs. The studies on helix transitions and distortions highlight that membrane proteins are not only packed as α-helices but also accomodate 310- and π-helical fragments. These transitions and distortions help in harboring more hydrophobic amino acids and aiding inter-helical interactions important for maintaining the fold of the membrane protein.
Appendix A describes a comparison of α-helix assignments in globular and membrane proteins by two algorithms, one based on Cα trace (ASSP) and the other using a combination of hydrogen bond pattern along with backbone torsion angles φ and ψ (STRIDE).
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Structural and Biophysical Characterisation of Denatured States and Reversible Unfolding of Sensory Rhodopsin IITan, Yi Lei January 2019 (has links)
Our understanding of the folding of membrane proteins lags behind that of soluble proteins due to the challenges posed by the exposure of hydrophobic regions during in vitro chemical denaturation and refolding experiments. While different folding models are accepted for soluble proteins, only the two-stage model and the long-range interactions model have been proposed so far for helical membrane proteins. To address our knowledge gap on how different membrane proteins traverse their folding landscapes, Chapter 2 investigates the structural features of SDS-denatured states and the kinetics for reversible unfolding of sensory rhodopsin II (pSRII), a retinal-binding photophobic receptor from Natronomonas pharaonis. pSRII is difficult to denature, and only SDS can dislodge the retinal chromophore without rapid aggregation. Even in 30% SDS (0.998 $\mathit{\Chi}_{SDS}$), pSRII retains the equivalent of six out of seven transmembrane helices, while the retinal binding pocket is disrupted, with transmembrane residues becoming more solvent-exposed. Folding of pSRII from an SDS-denatured state harbouring a covalently-bound retinal chromophore shows deviations from an apparent two-state behaviour. SDS denaturation to form the sensory opsin apo-protein is reversible. This chapter establishes pSRII as a new model protein which is suitable for membrane protein folding studies and has a unique folding mechanism that differs from those of bacteriorhodopsin and bovine rhodopsin. In Chapter 3, SDS-denatured pSRII, acid-denatured pSRII and sensory opsin obtained by hydroxylamine-mediated bleaching of pSRII were characterised by solution state NMR. 1D $^1$H and $^{19}$F NMR were first used to characterise global changes in backbone amide protons and tryptophan side-chains. Residue-specific changes in backbone amide chemical shifts and peak intensities in 2D [$^1$H,$^{15}$N]-correlation spectra were analysed. While only small changes in the chemical environment of backbone amides were detected, changes in backbone amide dynamics were identified as an important feature of SDS- and acid-denatured pSRII and sensory opsin. $^{15}$N relaxation experiments were performed to study the backbone amide dynamics of SDS-denatured pSRII, reflecting motions on different timescales, including fast fluctuations of NH bond vectors on the ps-ns timescale and the lack of exchange contributions on the µs timescale. These studies shed insight on differences in the unfolding pathways under different denaturing conditions and the crucial role of the retinal chromophore in governing the structural integrity and dynamics of the pSRII helical bundle. Hydrogen bonds play fundamental roles in stabilising protein secondary and tertiary structure, and regulating protein function. Successful detection of hydrogen bonds in denatured states and during protein folding would contribute towards our understanding on the unfolding and folding pathways of the protein. Previous studies have demonstrated residue-specific detection of stable and transient hydrogen bonds in small globular proteins by measuring $^1{\it J}_{NH}$ scalar coupling constants using NMR. In Chapter 4, different methods for measuring $^1{\it J}_{NH}$ scalar coupling were explored using RalA, a small GTPase with a mixed alpha/beta fold, as proof-of-concept. Detection of hydrogen bonds was then attempted with OmpX, a beta-barrel membrane protein, both in its folded state in DPC micelles and in the urea-denatured state. While $^1{\it J}_{NH}$ measurement holds promise for studying hydrogen bond formation, further optimisation of NMR experiments and utilisation of perdeuterated samples are required to improve the precision of such measurements in large detergent-membrane protein complexes. Naturally occurring split inteins can mediate spontaneous trans-splicing both in vivo and in vitro. Previous studies have demonstrated successful assembly of proteorhodopsin from two separate fragments consisting of helices A-B and helices C-G via a splicing site in the BC loop. To complement the in vitro unfolding/folding studies, pSRII assembly in vivo was attempted by introducing a splicing site in the loop region of the beta-hairpin constituting the BC loop of pSRII. The expression conditions for the N- and C-terminal pSRII-intein segments were optimised, and the two segments co-expressed. However, the native chromophore was not observed. Further optimisation is required for successful in vivo trans-splicing of pSRII and application of this approach towards understanding the roles of helices and loops in the folding of pSRII.
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