| 1. |
- Unnerståle, Sofia
(författare)
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NMR Investigations of Peptide-Membrane Interactions, Modulation of Peptide-Lipid Interaction as a Switch in Signaling across the Lipid Bilayer
- 2010
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Licentiatavhandling (övrigt vetenskapligt/konstnärligt)abstract
- The complexity of multi cellular organisms demands systems that facilitate communicationbetween cells. The neurons in our brains for instance are specialized in this cell-cellcommunication. The flow of ions, through their different ion channels, across the membrane, isresponsible for almost all of the communication between neurons in the brain by changing theneurons membrane potentials. Voltage-gated ion channels open when a certain thresholdpotential is reached. This change in membrane potential is detected by voltage-sensors in the ionchannels. In this licentiate thesis the Homo sapiens voltage- and calcium-gated BK potassiumchannel (HsapBK) has been studied. The NMR solution structure of the voltage-sensor ofHsapBK was solved to shed light upon the voltage-gating in these channels. Structures of othervoltage-gated potassium channels (Kv) have been determined by other groups, enablingcomparison among different types of Kv channels. Interestingly, the peptide-lipid interactions ofthe voltage-sensor in HsapBK are crucial for its mechanism of action.Uni cellular organisms need to sense their environment too, to be able to move towardsmore favorable areas and from less favorable ones, and to adapt their gene profiles to currentcircumstances. This is accomplished by the two-component system, comprising a sensor proteinand a response regulator. The sensor protein transfers signals across the membrane to thecytoplasm. Many sensor proteins contain a HAMP domain close to the membrane that isinvolved in transmitting the signal. The mechanism of this transfer is not yet revealed. Ourstudies show that HAMP domains can be divided into two groups based on the membraneinteraction of their AS1 segments. Further, these two groups are suggested to work by differentmechanisms; one membrane-dependent and one membrane-independent mechanism.Both the voltage-gating mechanism and the signal transduction carried out by HAMPdomains in the membrane-dependent group, demand peptide-lipid interactions that can be readilymodulated. This modulation enables movement of peptides within membranes or within thelipid-water interface. These conditions make these peptides especially suitable for NMR studies.
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| 2. |
- Chatterjee, Subhrangsu, 1978-
(författare)
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Physicochemical and Structural Aspects of Nucleic Acids
- 2007
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- This thesis consists of seven research publications concerning (i) pKa studies of nucleobases in model nucleotides to understand why RNA duplexes are more stable than DNA duplexes (Paper I), (ii) the role of Me(T)-π interactions in the relative stability of DNA-RNA heteroduplexes (Paper II), (iii) pKa measurements in nucleotides with different 2′-substituents (paper III), (iv) a conformation study of constrained sugars and a pKa study of 1-thyminyl to reveal effect of sugar constraints on the pKa of the nucleobase (paper IV), (v) NMR and MD studies of 1′, 2′-oxetane constrained thymidine incorporated Dickerson Drew dodecamer (paper V), (vi) the sequence dependent pKa perturbation of 9-guaninyl moeity in single stranded (ss) DNA and RNA (paper VI), (vii) the non identical chemical nature of internucleotidic phosphates in (ss) RNA using 31P NMR (paper VI), and an alkaline hydrolysis study of phosphodiesters in ssRNAs (paper VII). The architecture of DNA and RNA molecules is determined by (a) hydrogen bonding (b) base stacking (c) a variety of additional non-covalent interactions. In paper (I) we showed that A-U and G-C base pairings in RNA are more stable than A-T and G-C base pairings in DNA by 4.3 and 1 kJ mol-1 respectively. Me(T)-π interaction plays a dominant role in the relative stability of DNA-RNA duplexes (paper II). In paper III and IV, we have shown that 1′ , 2′- oxetane and azetidine rings have strong inductive effect on pyrimidine bases, and that the H2′-sugar proton can be the marker to understand the pseudoaromaticity of pyrimidine bases, as well as increasing constraints in sugar reducing the basicity of nucleobases. A 1′, 2′-oxetane locked thymidine (T) moiety deforms the local structure of Dickerson-Drew dodecamer, d(CGCGAATTCGCG)2- investigated by High resolution NMR and MD study, as is discussed in the paper V. In papers VI and VII, we showed sequence context dependent pKa (N1) of 9-guaninyl perturbation in (ss) DNAs and RNAs and the non identical chemical nature of inter-nucleotidic phosphate groups in single stranded RNAs.
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| 3. |
- Lundborg, Magnus, 1980-
(författare)
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Computer-Assisted Carbohydrate Structural Studies and Drug Discovery
- 2011
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Carbohydrates are abundant in nature and have functions ranging from energy storage to acting as structural components. Analysis of carbohydrate structures is important and can be used for, for instance, clinical diagnosis of diseases as well as in bacterial studies. The complexity of glycans makes it difficult to determine their structures. NMR spectroscopy is an advanced method that can be used to examine carbohydrates at the atomic level, but full assignments of the signals require much work. Reliable automation of this process would be of great help. Herein studies of Escherichia coli O-antigen polysaccharides are presented, both a structure determination by NMR and also research on glycosyltransferases which assemble the polysaccharides. The computer program CASPER has been improved to assist in carbohydrate studies and in the long run make it possible to automatically determine structures based only on NMR data. Detailed computer studies of glycans can shed light on their interactions with proteins and help find inhibitors to prevent unwanted binding. The WaaG glycosyltransferase is important for the formation of E. coli lipopolysaccharides. Molecular docking analyses of structures confirmed to bind this enzyme have provided information on how inhibitors could be composed. Noroviruses cause gastroenteritis, such as the winter vomiting disease, after binding human histo-blood group antigens. In one of the projects, fragment-based docking, followed by molecular dynamics simulations and binding free energy calculations, was used to find competitive binders to the P domain of the capsid of the norovirus VA387. These novel structures have high affinity and are a very good starting point for developing drugs against noroviruses. The protein targets in these two projects are carbohydrate binding, but the techniques are general and can be applied to other research projects.
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