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NMR Solution Structures of Human γC-Crystallin & the Intrinsically Disordered Viral Genome Linked Protein in the Free & Bound FormDixit, Karuna January 2016 (has links) (PDF)
This thesis describes the tertiary structures and dynamic studies of two protein systems. The first is human γC -crystallin protein, which is present in the nucleus of the human eye lens and the other is the plant viral protein VPg (an intrinsically disordered protein) in its free as well as its protease bound forms. The structural studies described here have been carried out using high-resolution solution NMR spectroscopic methods.
Project I: Determination of solution structure and dynamics of Human γC-crystallin
(HGC) using NMR spectroscopy
The crystallins are the most abundant proteins in the eye lens of vertebrates. These proteins are packed in short-range spatial order to provide the transparency and appropriate refractive index gradient that are required for vision. The crystallins belong to two gene families, which are categorized as the alpha and beta/gamma crystallins respectively. The classification on the basis of molecular size and structure results in the proteins being referred to as alpha, beta and gamma crystallins. Again, each of the crystallins has two or more subtypes. The stoichiometry of the subtypes of α, β and γ crystallins varies with the age of the organism, but the order of abundance remains as β > α > γ irrespective of age. The most abundant crystallins in the nucleus (central region) of eye lens are the γ -crystallins. In the human lens, only three members of the γ− crystallin family are mainly expressed i.e. γS- (HGS), γC - (HGC) and γD - (HGD). HGS is expressed postnatally and thus is present mainly in the cortical region of the lens unlike HGC and HGD crystallins, which are present in the nucleus. It is known that aging and some cataract-associated genetic mutations alter the structure of these proteins. Other point mutations result in minimum structural perturbation but with drastically lowered solubility. Mutation in the human γC -crystallin leads to congenital cataract such as Coppock-like cataract, while structural information is available for HGD & HGS but no structure is available for HGC. However, recently a model structure has been reported for HGC based on a mouse orthologous. Based on this model structure, it was argued that HGC is an insoluble protein and was explained by lower magnitude of dipole moment and fluctuation in N-terminal domain of the model structure. However it is shown that HGC is very soluble protein.
Solution structure of human γC-crystallin has been determined from an analysis of multidimensional triple resonance NMR spectroscopy using distance restraints from unambiguously assigned 1H-1H NOE peaks and dihedral angle restraints from HNHA and HNHB spectra. 15N relaxation average T1 and T2 correspond to 0.729 ± 0.02 and 0.060 ± 0.04 second from 15N backbone relaxation study, which gives average rotational correlation time 10.87 ns that shows human γC-crystallin is monomer in solution of molecular weight 21 kDa (173 residues). The ensemble of 20 lowest energy structures shows a root mean square deviation of 0.60 ± 0.12 Å for the backbone atoms, and 1.03 ± 0.09 Å for all heavy atoms. The comparison between the calculated NMR structure with backbone chain atoms C`, Cα and NH, of the x-ray crystal structure of the mouse γC - crystallin shows that the structure determined here of human γC-crystallin is very similar with an RMSD of 1.3 Å, which is not surprising given the 84.5% amino acid sequence identity between the two proteins.
More importantly, the NMR structure reported here shows the subtle differences in the orientation of specific residues as well as the domain interface between the human and mouse orthologs. The orientation of the calculated dipole moment for this NMR structure differs from earlier reported for model structure. However it is similar to the other known soluble proteins. The determined solution structure of human γC-crystallin also enables us to estimate the effect of cataract-associative mutations on the structure and properties of the protein. Several such mutations are already known, and the work presented here could likely shed light on the molecular basis of these cataracts.
Project II: Solution structural studies of intrinsically disordered protein VPg in free and bound forms from Sesbania mosaic virus
Sesbania mosaic virus (SeMV) is a plant virus, which infects the Sesbania grandiflora tree. SeMV belongs to Sobemovirus genus, which is not defined under any family. The length of this viral genome is ~4kb. This viral genome has four open-reading frames (ORF). ORF1 and ORF2 encode movement and coat proteins, respectively. ORF2 is again split into two ORFs i.e. ORF2a and ORF2b by a -1 shift in the reading frame and encode two polypeptide chains. These polypeptide chains generate several functional proteins upon polyprotein processing. Polyprotein processing is a mechanism employed by animal and plant viruses to produce several functional proteins from a single polypeptide chain. The two polyproteins expressed are catalytically cleaved by a serine protease, thus releasing the four proteins: VPg (viral protein genome linked), RdRP (RNA dependent RNA polymerase), P10, and P8.
VPg (“Viral Protein genome linked”) as its name suggests, is covalently linked to the 5` end of the viral RNA. VPgs are generally known to be intrinsically disordered proteins and have many interacting partners. Intrinsically Disordered Proteins (IDPs) are not explained by the 3D structure–function dogma. However, they are important for biological functions such as molecular recognition, signal transduction and regulation. It is known that SeMV protease becomes inactive in the absence of the VPg domain at its C-terminal. VPgs of animal viruses are well studied as compared to VPgs of plant virues. The size of VPg varies across the Sobemovirus genus. It is important to know the structure of VPg since it is necessary for protease activity. The studies conducted here focus on the structural analysis of the VPg in its free and bound forms with protease (VPg complex) as well as some aspect of full-length ProVPg.
For structural studies, two constructs of VPg as fusion protein with Cytb5 tag, one lacking 23 residues at its C-terminal using the pET21a(+) plasmid vector have been designed. Sub-cloning was also done to add a thrombin recognition site to remove the hexa-His tag from new constructs of full-length ProVPg and protease (PRO). These proteins were highly expressed, isotopically labeled and purified for NMR study. The sample used for structural studies of the ProVPg 23 complex was prepared using selectively protonated Ile, Leu and Val; and isotopically labeled i.e. 2H, 13C, and 15N-VPg 23 protein.
VPg in its free form is an intrinsically disordered protein and this has been confirmed by its dynamic nature observed using solution NMR spectroscopy. VPg binds to its partner protease and adopts a 3D-structure, which has been shown here. The tertiary structure has been determined using distance restraints from 1HN-1HN NOEs and methyl 1HN NOEs, and dihedral angle predicted from analysis of chemical shift values. The tertiary structure of ProVPg 23 complex has one β -sheet composed of three antiparallel β-strands and an α-helix. The ensemble of 20 lowest energy structures shows a root mean square deviation of 0.42 ± 0.09 Å for the backbone atoms, and 1.09 ± 0.11 Å for all heavy atoms for residues 15 to 50 that are primarily involved in structure formation. On the other hand RMSD is 2.34 ± 0.72 Å for the backbone and 2.55 ± 0.60 Å for all heavy atoms for all residues including both termini. That the tertiary fold of VPg both in full-length ProVPg and when complexed with protease domain (PRO) are the same has been shown here. The NMR structure reported here provides a structural basis for the origin of resonances in the up-field region of one–dimensional proton spectrum of full length ProVPg. The binding surface based on the structures of ProVPg 23 complex determined here and X-ray structure of PRO; has been determined using HADDOCK. The structural model here of full length ProVPg 23 shows the presence of aromatic interaction between Trp271 of PRO and Trp46 of VPg, which is consistent with the earlier biochemical studies.
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Beyond the limitMainz, Andi 26 October 2012 (has links)
Strukturelle Untersuchungen mittels Lösungs-NMR Spektroskopie sind für supramolekulare Maschinen mit Molekulargewichten von mehr als 150 kDa nur beschränkt möglich. Die Festkörper-NMR mit Probenrotation im sogenannten magischen Winkel (MAS) stellt dagegen eine molekulargewichtsunabhängige Methode dar. Im Rahmen dieser Arbeit wurde eine neue Methode entwickelt, die die MAS NMR Spektroskopie an supramolekularen Komplexen in Lösung erlaubt. Proteinlösungen bilden demnach durch MAS und dessen Ultrazentrifugationseffekt homogene Proteinsedimente aus, in denen die rotatorische Diffusion großer Proteinkomplexe überwiegend aufgehoben ist. Auf diese Weise können klassische Festkörper-NMR Methoden angewandt werden, ohne dass Präzipitations- oder Kristallisationsverfahren erforderlich sind. In Kombination mit Proteindeuterierung, Protonendetektion sowie paramagnetischer Relaxationsverstärkung ermöglichte diese neuartige Methode die Zuordnung von Rückgrat-Amidresonanzen des 20S Proteasoms mit einem Molekulargewicht von 1,1 MDa. Weiterhin wurde diese Methode zur Untersuchung des kleinen Hitzeschockproteins alpha-B-Crystallin und dessen Cu(II)-Bindungseigenschaften genutzt. Das Chaperon (600 kDa) spielt eine wesentliche Rolle in der zellulären Proteinhomeostase. Verschiedenste NMR Techniken und andere biophysikalische Methoden zeigen, dass die konservierte alpha-Crystallin-Domäne ein Cu(II)-Ion nahe der Monomer-Monomer Interaktionsfläche mit pikomolarer Affinität bindet. Die Cu(II)-induzierte Freilegung von Substrat-Interaktionsflächen und Veränderungen in der dynamischen Quartärstruktur modulieren so die oligomere Architektur und die Chaperonaktivität von alpha-B-Crystallin. Die hier erstmals beschriebene MAS NMR Spektroskopie von sedimentierten Biomolekülen legt einen wichtigen Grundstein für zukünftige Struktur- und Dynamikuntersuchungen an großen molekularen Maschinen. / Structural investigations of large biomolecules by solution-state NMR are challenging in case the molecular weight of the complex exceeds 150 kDa. Magic-angle-spinning (MAS) solid-state NMR is a powerful tool for the characterization of biomolecular systems irrespective of their molecular weight. In this work, an approach was developed, which enables the investigation of supramolecular modules by MAS NMR. Protein solutions can yield fairly homogeneous sediments due to the ultracentrifugal forces during MAS. Since rotational diffusion is impaired, typical solid-state NMR techniques can thus be applied without the need of precipitation or crystallization. This new approach in combination with protein deuteration, proton-detection and paramagnetic relaxation enhancement enabled the observation and the assignment of backbone amide resonances of a 20S proteasome assembly with a molecular weight of 1.1 MDa. Similarly, the approach was used to characterize the small heat-shock protein alpha-B-crystallin with respect to its Cu(II)-dependent chaperone activity. The chaperone (600 kDa) plays an essential role in cellular protein homeostasis. We show that the conserved alpha-crystallin core domain is the elementary Cu(II)-binding unit specifically coordinating one Cu(II) ion near to the dimer interface with picomolar binding affinity. We suggest that Cu(II)-binding unblocks potential client binding sites and alters quaternary dynamics of both the dimeric building block as well as the higher-order assemblies of alpha-B-crystallin. In summary, MAS NMR employed to biomolecules in solution is a very promising tool to explore structural and dynamic properties of large biological machines with no upper size limit.
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Proteomics of the ovine cataractMuir, Matthew Stewart January 2008 (has links)
The lens of the eye needs to be completely transparent in order to allow all light entering the eye to reach the retina. This transparency is maintained by the highly ordered structure of the lens proteins the crystallins. Any disruption to the lens proteins can cause an opacity to develop which is known as cataract. During cortical cataract formation there is increased truncation of the lens crystallins. It is believed that overactivation of calcium-dependent cysteine proteases, the calpains, is responsible for the increased proteolysis of the crystallins seen during cataractogenesis. Within the ovine lens there are three calpains, calpain 1, 2 and the lens specific calpain Lp82. The aim of this thesis was to determine the changes in the lens proteins during ageing and cataractogenesis, and to establish the role of the calpains in these processes. Calpain 1 and 2 were purified from ovine lung and Lp82 was purified from lamb lenses using chromatography. Activity and presence of the calpains was determined by using the BODIPY-FL casein assay, gel electrophoresis, Western blot and casein zymography. Changes in the lens proteins, specifically the crystallins, were visualised using two-dimensional electrophoresis (2DE). Lenses from fetal, 6 month old and 8 year old sheep were collected, as well as stage 0, 1, 3 and 6 cataractous ovine lenses. The proteins from the lenses were separated into the water soluble and urea soluble fractions and analysed by 2DE. Mass spectrometry was used to determine the masses and therefore modifications of the crystallins. Finally, the individual crystallins were separated using gel filtration chromatography and incubated with the purified calpains in the presence of calcium. The extent of the proteolysis was visualised using 2DE and truncation sites determined by mass spectrometry. Purification of the calpains resulted in samples that were specific for each calpain and could be used in further experiments. 2DE analysis showed that there were changes to the crystallins during maturation of the lens. The α-crystallins become increasingly phosphorylated as the lens ages and a small amount becomes truncated. The β-crystallins were also modified during ageing by truncation and deamidation. When crystallins from cataractous lenses were compared using 2DE there were changes to both the α- and β-crystallins. The α-crystallins were found to be extensively truncated at their C-terminal tail. Four of the seven β-crystallins, βB1, βB3, βB2 and βA3, showed increased truncation of their N-terminal extensions during cataract formation. All three calpains truncated αA and αB-crystallin at their C-terminal ends after incubation. Calpain 2 and Lp82 each produced unique αA-crystallin truncations. All three calpains truncated βB1 and βA3 and calpain 2 also truncated βB3. When the truncations from the calpain incubations were compared to those seen during cataract formation, many of the truncations were found to be similar. Both the unique truncations from calpain 2 and Lp82 were found in cataractous lenses, with the Lp82 more obvious in the 2DE. The β-crystallin truncations found after incubation with the calpains were similar to those found during cataractogenesis. In conclusion this study documents the changes to the ovine lens during maturation and cataractogenesis and indicates a role for the calpain family in the increased proteolysis observed in the ovine cataract.
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Molekulare Zellstressmechanismen bei der hereditären Einschlusskörpermyopathie / Molecular cell stress mechanisms in hereditary inclusion body myopathyFischer, Charlotte Viola 05 June 2012 (has links)
No description available.
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Molecular and epidemiological studies on eyes with pseudoexfoliation syndromeBotling Taube, Amelie January 2015 (has links)
Pseudoexfoliation (PEX) syndrome is an age-related condition characterized by the production and accumulation of extracellular fibrillary material in the anterior segment of the eye. PEX predisposes for several pathological conditions, such as glaucoma and complications during and after cataract surgery. The pathogenesis of PEX is not yet fully understood. It is multifactorial with genetics and ageing as contributing factors. We aimed to study the proteome in aqueous humor (AH) in PEX in order to increase the knowledge about its pathophysiology. Therefore, we developed sampling techniques and evaluated separation methods necessary for analyzing small sample volumes. Other objectives were to study the lens capsule in eyes with PEX regarding small molecules, and to investigate the association between PEX and cataract surgery in a population-based 30-year follow-up study. Samples of AH from eyes with PEX and control eyes were collected during cataract surgery. In pooled, and individual samples, various liquid based separation techniques and high resolution mass spectrometry were utilized. For quantitation, various methods for labeling, and label free techniques were applied. Lens capsules were collected from some of the patients, and analysed by imaging mass spectrometry. A cohort of 1,471 elderly individuals underwent a comprehensive ophthalmological examination at baseline. Medical information was obtained by questionnaires, and from medical records. Incident cases of cataract surgery were identified by review of medical records. In the initial study, several techniques were explored for protein detection, and a number of proteins were identified as differentially expressed. In the individually labelled samples, changes in the proteome were observed. Eyes with PEX contained higher levels of proteins involved in inflammation, oxidative stress, and coagulation, suggesting that these mechanisms are involved in the pathogenesis in PEX. The levels of β/γ-crystallins were significantly increased in PEX, which is a novel finding. In the lens capsules from individuals with PEX, changes in the lipid composition was observed with time-of-flight secondary ion mass spectrometry. These changes remain to be elucidated. By multivariate analysis, lens opacities were the first, and PEX the second most important predictor for cataract surgery, the later accounting for a 2.38-fold increased risk for cataract surgery.
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Veränderungen im Proteom von Maus und Mensch durch Huntington's ChoreaZabel, Claus 24 January 2003 (has links)
Die Erkrankung Huntington s Chorea ist eine autosomal dominant vererbte Erkrankung, die gewöhnlich im mittleren Lebensabschnitt beginnt und unausweichlich zum Tode führt. In unserem Bestreben, Proteine zu identifizieren, welche an Prozessen "Upstream" oder "Downstream" des krankheitsverursachenden Proteins Huntingtin beteiligt sind, wurde das Proteom eines sehr gut etablierten Mausmodells mit Hilfe der Großgel 2D-Elektrophorese untersucht. Es konnte zum ersten Mal auf Proteinebene nachweisen werden, dass die Expression von zwei Serinproteasehemmern, alpha1-Antitrypsin und Contraspin und darüber hinaus eines Chaperons, alphaB-Kristallin, im Verlauf der Erkrankung abnimmt. Reduzierte Expression von alpha1-Antitrypsin und Contraspin konnte in Gehirn, Leber, Herz und Testes nahe dem Endstadium der Erkrankung nachgewiesen werden. Hier ist es wichtig festzustellen, dass die Expressionsabnahme von alpha1-Antitrypsin im Gehirn der Abnahme in der Leber im Herzen und in den Testes vorangeht. Eine verminderte Expression des Chaperons alphaB-Kristallin wurde nur im Gehirn gefunden. Für ein weiteres Protein, das Major Urinary Protein, wurde eine verminderte Expression in der Leber und im Urin von betroffenen Mäusen festgestellt. Damit konnte demonstriert werden, dass die Erkrankung auf Proteinebene auch ein Protein, das im Gehirn von transgenen Mäusen nicht vorkommt, beeinflusst. Bei Untersuchungen am Menschen wurde in drei Gehirnregionen von Postmortem-Gehirnen von Huntington s Chorea Patienten eine veränderte Expression von alpha1-Antitrypsin festgestellt. Wenn gewährleistet werden kann, dass die Konzentration von alpha1-Antitrypsin und alphaB-Kristallin während Huntington s Chorea im Gewebe nicht absinkt, könnte dies vielleicht neuronalen Zelltod verhindern und somit bei der Verzögerung des Krankheitsverlaufs nutzbringend eingesetzt werden. / Huntington disease is an autosomal dominantly inherited disease that usually starts in midlife and inevitably leads to death. In an effort to identify proteins involved in processes upstream or downstream of the disease causing huntingtin, the proteome of a well-established mouse model was studied by large-gel 2D electrophoresis. It could be demonstrated for the first time at the protein level that two serin protease inhibitors, alpha1-antitrypsin and contraspin and the chaperone alphaB-crystallin decrease in expression over the course of disease. Importantly, the alpha1-antitrypsin decrease in the brain precedes that in liver, heart and testes in mice. Reduced expression of alpha1-antitrypsin and contraspin could be detected in the brain, liver heart and testes close to terminal disease. Decreased expression of the chaperone alphaB-crystallin was found exclusively in the brain. Reduced expression of the liver specific major urinary proteins not found in the brain, was seen in affected mice, demonstrating that the disease exerts its influence on a protein not present in the brain of transgenic mice at the protein level. When investigating three human brain regions obtained post-mortem from Huntington s disease patients, alpha1-antitrypsin expression was also altered. Maintaining alpha1-antitrypsin and alphaB-crystallin availability during the course of Huntington s disease might prevent neuronal cell death and therefore could be useful in delaying the disease progression.
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