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Structural analysis of induced mutagenesis A’ protein from mycobacterium tuberculosis and of a thermophillic GH9 cellulaseAnye, Valentine January 2014 (has links)
Masters of Science / The three-dimensional structures of proteins are important in understanding their function and interaction with ligands and other proteins. In this work, the structures of two proteins, ImuA’ from mycobacterium tuberculosis and GH9 C1 cellulase from a metagenomic library, were analysed using structural biological and modelling techniques. The gene encoding ImuA’ was amplified by two-step PCR, cloned, and expressed in E. coli. The recombinant ImuA’ produced was found to be largely insoluble. The insoluble protein was successfully solubilized in 8M urea but refolding the protein to its native structure was unsuccessful. By homology modelling, a 3D model of ImuA’ was obtained from a partly homologous protein RecA. In comparison to RecA, ImuA’ appears to lack some loop amino acids critical for DNA binding. Hence ImuA’ is postulated to not bind DNA. The second protein, GH9 C1 cellulase, was produced in E. coli. The protein was purified by chromatographic techniques and crystallized in a precipitant to protein ratio of 1:2 by hanging and sitting drop crystallization methods. The reservoir solution was made up of 15-30% (w/v) PEG 3350, 200 mM salt and 100 mM Tris-HCL pH 7.5-8.5. The protein crystals only diffracted x-rays to 4 å resolution which could not be used to obtain a crystal structure of the protein. The diffraction data, however, showed the crystal to be monoclinic with space group P2. Homology modelling revealed GH9 C1 cellulase to be a two domain protein with a smaller N-terminal Ig-like domain and a larger catalytic domain.The catalytic domain retains two ca2+ binding sites, which potentially stabilize the active site conformation and increase thermostability of the protein. Overall GH9 C1 cellulase is structurally similar to other GH9 cellulases, suggesting that its catalytic mechanism may be conserved.
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Molecular characterization of the binding site of nematode GABA-A receptorsAccardi, Michael 01 August 2010 (has links)
Haemonchus contortus is a parasitic nematode that is controlled in large part by
nematocidal drugs that target receptors of the parasitic nervous system. Hco-UNC-49 is a
nematode GABA receptor that has a relatively low overall sequence homology to
mammalian GABA receptors but is very similar to the UNC-49 receptor found in the free
living nematode Caenorhabditis elegans. However, the nematode receptors do exhibit
different sensitivities to GABA which may be linked to differences in the putative GABA
binding domains. Mutational analysis conducted in this study identified at least one
amino acid, positioned near the GABA binding domain, which may partially account for
differences in nematode GABA sensitivity. In addition, positions reported to be crucial
for GABA sensitivity in mammalian receptors also affect GABA sensitivity in Hco-
UNC-49 suggesting that the GABA binding domains of the mammalian and nematode
GABA receptors share some pharmacological similarities. However, there were some
differences observed. For example, in mammalian GABAA receptors amino acids from
both and subunits appear to be important for GABA sensitivity. For residues
examined in this study, only those on the UNC-49B subunit, and not UNC-49C, appear
important for GABA sensitivity. / UOIT
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Kartierung der Bindungstasche des humanen Bittergeschmacksrezeptors hTAS2R10 / Mapping the binding site of the human bitter taste receptor hTAS2R10Born, Stephan January 2012 (has links)
Die Bittergeschmacksrezeptoren stellen in der Superfamilie der G-Protein-gekoppelten Rezeptoren eine besondere Gruppe dar. Im Menschen können die 25 Rezeptoren eine große Anzahl unterschiedlichster Bittergeschmacksstoffe detektieren. Diese Substanzen können sowohl schädlich, wie etwa Strychnin, als auch der Gesundheit förderliche Arzneistoffe, wie etwa Chloramphenicol sein. Unter den Bittergeschmacksrezeptoren des Menschen gibt es eine Gruppe von drei Rezeptoren, die besonders viele Bitterstoffe detektieren können. Einer von ihnen ist der Rezeptor hTAS2R10.
In dieser Arbeit konnte sowohl experimentell als auch durch computergestützte Modellierung gezeigt werden, dass der hTAS2R10 nur eine Bindungstasche besitzt. Das stimmt mit den bisher ausführlich experimentell und in silico untersuchten Rezeptoren hTAS2R1, -R16, -R38 und -R46 überein. Die für die Agonisteninteraktionen nachweislich wichtigen Transmembrandomänen sind in den bisher untersuchten Bittergeschmacksrezeptoren, wie auch im hTAS2R10, die Transmembrandomänen 3, 5, 6 und 7. Die Untersuchungen zeigten, dass die Bindungstasche des hTAS2R10 in der oberen Hälfte des zum extrazellulären Raum gerichteten Bereichs lokalisiert ist. Insbesondere konnte für die untersuchten Agonisten Strychnin, Parthenolid und Denatoniumbenzoat gezeigt werden, dass die Seitenketten der Aminosäuren in Position 3.29 und 5.40 ausgeprägte agonistenselektive Wechselwirkungen eingehen. Weitere Untersuchungen haben ergeben, dass das weitgefächerte Agonistenspektrum des hTAS2R10 zu Lasten der Sensitivität für einzelne Bitterstoffe geht. Der Vergleich wichtiger Positionen im hTAS2R10, hTAS2R46 und mTas2r105 hat deutlich gemacht, dass sich die Bindungsmodi zwischen diesen Rezeptoren unterscheiden. Dies deutet auf eine getrennte evolutionäre Entwicklung der Bindungseigenschaften dieser Rezeptoren hin. Gleichfalls zeigten die Untersuchungen, dass einige Positionen wie z.B. 7.39 die Funktion aller untersuchten Bittergeschmacksrezeptoren prägen, sich jedoch die genaue Bedeutung im jeweiligen Rezeptor unterscheiden kann. Einzelne dieser Positionen konnten auch bei der Agonisteninteraktion des Rhodopsins und des β2-adrenergen Rezeptors beobachtet werden. Die Ergebnisse dieser Arbeit helfen dabei die Wechselwirkungen zwischen Bitterstoffen und den Bittergeschmacksrezeptoren zu verstehen und geben erste Einblicke in die Entwicklung der Rezeptoren in Hinblick auf ihren Funktionsmechanismus. Diese Erkenntnisse können genutzt werden, um Inhibitoren zu entwickeln, die sowohl ein wichtiges Werkzeug in der Rezeptoranalytik wären, als auch dazu genutzt werden könnten, den unerwünschten bitteren Geschmack von Medikamenten oder gesundheitsfördernden sekundären Pflanzenstoffen zu mindern. Damit könnte ein Beitrag zur Gesundheit der Menschen geleistet werden. / In the Superfamily of G protein-coupled receptors the bitter taste receptors form a notable group. The 25 human receptors are able to detect a large group of structurally diverse bitter compounds. These compounds can be toxic – like strychnine – or have beneficial effects on health – like the pharmacological agent chloramphenicol. Three of these bitter taste receptors show a strikingly broad agonist spectrum. One of them is the hTAS2R10.
It was shown empirically and by computational modelling that the hTAS2R10 has only one binding pocket. This agrees with the findings of studies on the bitter taste receptors hTAS2R1, -R16, -R38 and -R46. The domains important for agonist interaction in these receptors, as well as in the hTAS2R10, are the transmembrane domains 3, 5, 6 and 7. The results of this thesis show that the binding pocket of the hTAS210 is located in the upper part of the receptor which points into the direction of the extracellular area. Interestingly, it has been shown for the amino acid side chains in the positions 3.29 and 5.40, that they can interact with the analysed agonists strychnine, parthenolide and denatonium benzoate in an agonist-selective way. Further analyses showed that the broad tuning of the hTAS2R10 goes at the expense of the sensitivity to single agonists. The comparison of crucial positions in the hTAS2R10, hTAS2R46 and the mTas2r105 reveal that these receptors differ in their binding mode. These could be evidence that the binding abilities of these receptors evolved independently. However, the results show that some positions, e.g. 7.39, influence the receptor activity in all analysed receptors, but the function of these positions in the receptors could be different. Some of these positions also have an influence on the agonist-receptor interaction of Rhodopsin and the β2-adrenergic receptor.
The findings in this thesis contribute to the knowledge about interaction between bitter receptors and bitter compounds. The results also provide insight into the evolvement of receptor functions. These outcomes can be of use for the development of inhibitors which could serve as analytical tools in taste research. Furthermore, such inhibitors could be used to reduce the bitter taste of medicine and healthy plant compounds and thus increase palatability. This could contribute to improve human well-being.
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A molecular characterization of agonists that bind to Hco-UNC-49, a GABA-gated chloride channel from Haemonchus contortusKaji, Mark 01 November 2012 (has links)
Haemonchus contortus is a blood feeding parasitic nematode infecting ruminants causing anemia and poor health at great economic cost. The ability to pharmaceutically control infection has been challenged by the rapid development and spread of drug resistance. The discovery of new targets is therefore required for sustainable parasite control. UNC-49 is a nematode ligand-gated ion channel that plays an important role in muscle contraction required for normal locomotion. However, little is known regarding its sensitivity to different agonists and how they interact with the binding site. This thesis describes an investigation into the efficacy of a range of classical GABA receptor agonists on Hco-UNC-49 expressed in Xenopus oocytes. The results of our electrophysiological recordings indicate that there is a size requirement for full agonism of the Hco-UNC-49 binding site. Furthermore, a number of molecules that are known to act on vertebrate GABA receptors have no effect on Hco-UNC-49. This suggests that the binding site of nematode GABA receptors does exhibit some unique properties. These findings could possibly be exploited to develop new drugs that specifically target GABA receptors from parasitic nematodes. / UOIT
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Effects of nucleotide variation on the structure and function of human arylamine n-acetyltransferase 1Akurugu, Wisdom Alemya January 2012 (has links)
>Magister Scientiae - MSc / The human arylamine N-acetyltransferase 1 (NAT1) is critical in determining the duration of action and pharmacokinetics of amine-containing drugs such as para-aminosalicylic acid and para-aminobenzoyl glutamate used in clinical therapy of tuberculosis (TB), as well as influencing the balance between detoxification
and metabolic activation of these drugs. SNPs in this enzyme are continuously being detected and indicate inter-ethnic and inter-individual variation in the enzyme function. The effect of nsSNPs on the structure and function of proteins are routinely analyzed using SIFT and POLYPHEN-2 prediction algorithms. The false-negative rate of these two algorithms results in as much as 25% of nsSNPs. This
study aimed to explore the use of homology modeling including residue interactions, Gibbs free energy change and solvent accessibility as additional evidence for predicting nsSNP effects on enzyme function.This study evaluated the functional effects of 14 nsSNPs identified in a South African mixed ancestry
population of which 3 nsSNPs were previously identified in Caucasians. The SNPs were evaluated using structural analysis that included homology modeling, residue interactions, relative solvent accessibility,Gibbs free energy change and sequence conservation in addition to the routinely used nsSNP function prediction algorithms, SIFT and POLYPHEN-2. The structural analysis implemented in this study showed
a loss of hydrogen bonds for S259R thereby affecting protein function which contradicts predictions obtained from SIFT and POLYPHEN-2 algorithms. The variant N245I was shown to be neutral but contradicted the predictions from SIFT and POLYPHEN-2. Structural analysis predicted that variant R242M would affect protein stability and therefore NAT1 function in agreement with POLYPHEN-2 predictions
but contradicting predictions from SIFT. No structural changes were expected for variant E264K in agreement with predictions obtained from POLYPHEN-2 but contradicting results from SIFT. The functions of the remaining 10 nsSNPs were consistent with those predicted by SIFT and POLYPHEN-2 namely that four variants R117T, E167Q, T193S and T240S do not affect the NAT1 function whereas R166T,
F202V, Q210P, D229H, V231G and V235A could affect the enzyme function.This study provided the first evaluation of the functional effects of 11 newly characterized nsSNPs on the NAT1 tuberculosis drug-metabolizing enzyme. The six functionally important nsSNPs predicted by all three methods and the four SNPs with contradictory results will be tested experimentally by creating a SNP construct that will be cloned into an expression vector. These combined computational and
experimental studies will advance our understanding of NAT1 structure-function relationships and allow us to interpret the NAT1 genetic polymorphisms in individuals who are slow or fast acetylators. The results, albeit a small dataset demonstrate that the routinely used algorithms are not without flaws and
that improvements in functional prediction of nsSNPs can be obtained by close scrutiny of the molecular interactions of wild type and variant amino acids.
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Structure-Based Virtual Screening of Selected Malaria Box Compounds Against a Multi-Staged Protein (Falstatin) in Plasmodium falciparumOladunjoye, Bolu Bimbola January 2021 (has links)
Magister Pharmaceuticae - MPharm / Malaria disease poses substantial health risks to many nations, especially in Africa, where it primarily affects pregnant women, children, and immunocompromised patients. However, current antimalarial drugs have limitations such as low safety profile and particularly widespread treatment failure due to the increasing resistance of Plasmodium falciparum, the major causative organism to artemisinin-based therapy (ACT) and other chemotherapeutics. In the light of this, there is a pressing need for new antimalarial drugs with novel mechanisms of action and satisfactory pharmacokinetic properties, which has led to the current study. Furthermore, current antimalarial drugs target specific stages of the Plasmodium life cycle. For instance, chloroquine targets the erythrocytic stage while primaquine targets the liver stage. However, these therapies cannot achieve complete elimination of the parasite once the life cycle has been established in the body. Hence, the goal of this study is to combat resistance by finding novel compounds that can bind to a multiple-staged protein in Plasmodium falciparum. Based on this consideration, falstatin was chosen as the protein target for this study because it was observed to play a crucial role in the degradation of haemoglobin, rupture of erythrocytes by mature schizonts, and subsequent invasion of erythrocytes by free merozoites. Hence, the protein, falstatin can be targeted to inhibit cell growth and cause plasmodial cell death in merozoites as well as schizonts of Plasmodium falciparum. Therefore, it is intended that compounds that bind to falstatin could serve as novel antimalarials that target multiple stages of the Plasmodium life cycle. Consequently, this study explored the structure-based virtual screening approach to identify compounds that could bind to the protein target, falstatin in Plasmodium falciparum. An extensive literature review identified falstatin as the multi-staged drug target for this study, while homology modelling was used to generate the three-dimensional structure of falstatin. Molecular docking was conducted to predict the binding energy of compiled antiplasmodial compounds to falstatin while druglikeness analysis was used to prioritize compounds according to their ADMET (absorption, distribution, metabolism, excretion and toxicity) properties. The top-ranked compound, based on a novel ligand scoring function, was then subjected to molecular dynamics (MD). Following this step, rescoring analysis was performed on the top 5 compounds using the Molecular Mechanics-Generalized Born Surface Area (MM-GBSA) scoring function to gain insight into their component binding energies. Thereafter, a pharmacophore hypothesis was developed based on the 5 top-ranking compounds in order to screen other compound libraries in the future. From the results, TCMDC 131646, TCMDC-124274, TCMDC-138266, TCMDC 123844 and TCMDC 131234 possessed good binding energies and satisfactory ADMET properties showing high ligand scores of 77.1, 75.4, 75.4, 75.4 and 73.1 respectively (on a total scale of 100). Also, the study revealed that the top-ranked compound, TCMDC 131646 had a binding energy of -6.15 KJ/mol, contained no toxicophore and conformed to Lipinski, Egan and Muegge rules of druglikeness. Findings from the MD simulation demonstrated that TCMDC 131646 strongly interacted with the protein, falstatin. Morealso, the study revealed that TCMDC 131646 is structurally diverse from chloroquine, artemisinin, artemether and lumefantrine, indicating that it may possess a distinct mechanism of action. The rescoring analysis of TCMDC-131646, TCMDC 124274, TCMDC-138266, TCMDC 123844 and TCMDC 131234 predicted negative binding energies ≤ -4.662 KJ/mol for the top compounds, further indicating that these compounds are likely to bind strongly with falstatin. Additionally, the developed pharmacophore hypothesis contained -H-N-C=O and N-H moieties which strongly suggested that the presence of electron-withdrawing groups could be vital for the inhibition of falstatin at the active site. Overall, TCMDC 131646 was predicted to be a drug-like and safe compound that could inhibit falstatin in Plasmodium falciparum. Chemical-disease co-occurrence analysis in literature revealed that this compound showed in-vitro antiplasmodial activity at an IC50 of 0.226μM and has also shown in vitro activity for neuralgia, hyperalgesia and arthritis. The research recommends TCMDC 131646 as a potential antimalarial hit compound that could yield novel analogues by hit expansion. However, confirmatory in-vitro and in-vivo studies are required to substantiate these predictions
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Role of N-terminal residues of CCL19 and CCL21 in binding and activation of CCR7Alotaibi, Mashael A.F.J. January 2021 (has links)
Chemokines are chemotactic cytokines, which mediate cell trafficking and play a key
role in mobilisation of leukocytes. More recently, chemokines and their cognate
receptors have been described as key players in different aspects of cancer biology
contributing to proliferation, angiogenesis and metastasis. In particular, chemokines
CCL19 and CCL21 acting on their associated receptor CCR7 are postulated to be key
drivers of lymph node metastasis in a number of malignancies including breast, colon,
gastric, & thyroid cancers. It has been reported that the cleavage of the pre-cysteine
bridge N-terminal residues of CCL21 (SDGGAQD) and of CCL19 (GTNDAED) renders
both peptides incapable of fully activating CCR7. However, little is known about the
nature of the interactions that occur between the N-terminal residues of CCL19 or
CCL21 and the CCR7 receptor, or the role they have in activation of CCR7. The aim
of this study is to investigate the role of the residues in the N-terminus of CCL19 and
in particular CCL21 in the context of CCR7 activation and to use this information in the
discovery of novel CCR7 antagonists or agonists. To achieve this, we synthesised a
number of short (three to seven amino acids) peptides and peptidomimetics inspired
by the seven N-terminal amino acid residues of CCL19 and CCL21 and
pharmacologically characterised their ability to activate CCR7 or block the activation
of CCR7 using a number of in vitro assays such as calcium flux, trans-well (Boyden
chamber), and Western blotting. We also carried out computational studies to better
understand and predict the activity of these peptides. Our results demonstrate that
some of these peptides are indeed capable of acting as agonists or antagonists of
CCR7. / Kuwait Health Ministry and Kuwait Civil Services Commission
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Structural and Functional Studies of ATP7B, the Copper(I)-transporting P-type ATPase Implicated in Wilson DiseaseFatemi, Negah 06 January 2012 (has links)
Copper is an integral component of key metabolic enzymes. Numerous physiological processes depend on a fine balance between the biosynthetic incorporation of copper into proteins and the export of excess copper from the cell. The homeostatic control of copper requires the activity of the copper transporting ATPases (Cu-ATPases). In Wilson disease the disruption in the function of the Cu-ATPase ATP7B results in the accumulation of excess copper and a marked deficiency of copper-dependent enzymes. In this work, the structure of ATP7B has been modeled by homology using the Ca-ATPase X-ray structure, enabling a mechanism of copper transport by ATP7B to be proposed. The fourth transmembrane helix (TM4) of Ca-ATPase contains conserved residues critical to cation binding and is predicted to correspond to TM6 of the ATP7B homology model, containing the highly conserved CXXCPC motif. The interaction with Cu(I) and the importance of the 3 cysteines in TM6 of ATP7B has been shown using model peptides. ATP7B has a large cytoplasmic N-terminus comprised of six copper-binding domains (WCBD1-6), each capable of binding one Cu(I). Protein-protein interactions between WCBDs and the copper chaperone Atox1 has been shown, contrary to previous reports, to occur even in the absence of copper. 15N relaxation measurements on the apo and Cu(I)-bound WCBD4-6 show that there is minimal change in the dynamic properties and the relative orientation of the domains in the two states. The domain 4-5 linker remains flexible, and domain 5-6 is not a rigid dimer, with flexibility between the domains. Copper transfer to and between WCBD1-6 likely occurs via protein interactions facilitated by the flexibility of the domains with respect to each other. The flexible linkers connecting the domains are important in giving the domains motional freedom to interact with Atox1, to transfer copper to other domains, and finally to transfer copper to the transmembrane site for transport across the membrane.
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Structural and Functional Studies of ATP7B, the Copper(I)-transporting P-type ATPase Implicated in Wilson DiseaseFatemi, Negah 06 January 2012 (has links)
Copper is an integral component of key metabolic enzymes. Numerous physiological processes depend on a fine balance between the biosynthetic incorporation of copper into proteins and the export of excess copper from the cell. The homeostatic control of copper requires the activity of the copper transporting ATPases (Cu-ATPases). In Wilson disease the disruption in the function of the Cu-ATPase ATP7B results in the accumulation of excess copper and a marked deficiency of copper-dependent enzymes. In this work, the structure of ATP7B has been modeled by homology using the Ca-ATPase X-ray structure, enabling a mechanism of copper transport by ATP7B to be proposed. The fourth transmembrane helix (TM4) of Ca-ATPase contains conserved residues critical to cation binding and is predicted to correspond to TM6 of the ATP7B homology model, containing the highly conserved CXXCPC motif. The interaction with Cu(I) and the importance of the 3 cysteines in TM6 of ATP7B has been shown using model peptides. ATP7B has a large cytoplasmic N-terminus comprised of six copper-binding domains (WCBD1-6), each capable of binding one Cu(I). Protein-protein interactions between WCBDs and the copper chaperone Atox1 has been shown, contrary to previous reports, to occur even in the absence of copper. 15N relaxation measurements on the apo and Cu(I)-bound WCBD4-6 show that there is minimal change in the dynamic properties and the relative orientation of the domains in the two states. The domain 4-5 linker remains flexible, and domain 5-6 is not a rigid dimer, with flexibility between the domains. Copper transfer to and between WCBD1-6 likely occurs via protein interactions facilitated by the flexibility of the domains with respect to each other. The flexible linkers connecting the domains are important in giving the domains motional freedom to interact with Atox1, to transfer copper to other domains, and finally to transfer copper to the transmembrane site for transport across the membrane.
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Structural and functional characterisation of a novel signalling molecule in Arabidopsis thalianaMulaudzi, Takalani January 2011 (has links)
Philosophiae Doctor - PhD / Nitric Oxide (NO) influences a wide range of physiological processes in plants including growth and development, responses to abiotic and biotic stress and pathogen responses. NO binds to the heme group of the mammalian soluble guanylyl cyclase, which activates the enzyme to convert guanosine 5’ triphosphate (GTP) to a second messenger guanosine 3’, 5’ cyclic monophosphate (cGMP). Cyclic GMP further activates other signalling cascades including the regulation of protein kinases, ion gated channels and phosphodiesterases. In plants, a few GCs have been identified and these include AtGC1, AtBRI1, AtWAKL10, and AtPSKR1, however, a GC that contains a heme binding motif that senses NO has yet to be
identified. In order to identify such molecules, a search motif based on conserved HNOX domains and the conserved and functionally assigned amino acid residues in the catalytic centres of annotated GCs was designed and used to search the Arabidopsis thaliana proteome. Several candidate molecules were identified including a flavin-containing monooxygenase (FMO)-like protein and the At5g57690 which is currently annotated as a diacylglycerol kinase. FMOs found in bacteria, yeast, and animals are the most important monooxygenases since they are involved in xenobiotic metabolism and variability in drug response. FMOs in plants are implicated in catalysing specific steps in auxin biosynthesis,metabolism of glucosinolates and pathogen defense mechanisms. The human diacylglycerol
kinase acts as a lipid kinase that mediates a wide range of biological processes which include cell proliferation, differentiation and turmogenesis. In prokaryotes, the structure of Escherichia coli lipid kinase has been solved however, its function has not yet been demonstrated. So far, the occurrence of the diacylglycerol kinases in plants has not yet been reported, and their structure and function also remain elusive. The domain architecture of the 2 molecules (AtNOGC1 and At5g57690) identified by the HNOX-based search strategy revealed that these molecules contain a GC and a heme-binding motif that is conserved among all known heme-binding proteins.In this study, the role of AtNOGC1, a novel NO binding protein in higher plants was investigated and the results showed that this molecule contains an NO-dependant active GC domain. The sequence was first analysed and the location of the HNOX and the GC motifs highlighted. The protein was then recombinatly expressed as a His-SUMO fusion protein and the purification optimised by a second step of ion exchange chromatography. Electrochemical
techniques such as cyclic voltammetry and square wave voltammetry were used to
demonstrate the binding of NO and O2 to the AtNOGC1. Electrochemical data revealed that AtNOGC1 has a lower affinity for O2 and a higher affinity for NO, an important signalling molecule in plants.The presence of the GC activity in AtNOGC1 was investigated by conducting GC activity assays in vitro in the presence or absence of NO. The GC activity assays demonstrated that AtNOGC1 can synthesize cGMP from GTP in vitro. It was also noted that NO was required for the maximum activation of AtNOGC1 catalytic activity. NO-activated catalysis resulted in a >2 fold excess of cGMP production compared to an NO-independent GC activity assay.
The effect of calcium in regulating the GC activity was also investigated and an increase in cGMP levels was observed however, this was just a preliminary finding that requires further experimentation.3 Homology models for both the FMO-like (AtNOGC1) and the diacylglycerol kinase(At5g57690) were built using Modeller program, and important amino acid residues underlying the heme-binding and GC motifs were identified. Residues corresponding to the motifs, which give signature to AtNOGC1 as an FMO, were also noted. In addition,computational functional prediction also suggested the role of AtNOGC1 in a number of processes which include ion binding and functioning as an FMO.Taken together, these findings suggest that AtNOGC1 is a novel Arabidopsis thaliana hemebinding protein that senses NO with higher affinity than for O2. Though AtNOGC1 is currently annotated as a FMO-like protein, it contains a NO-sensitive GC activity and shares limited sequence similarities with mammalian sGC and the recently identified HNOX
domains. Homology modelling strongly suggests that AtNOGC1 and At5g57690 belong to the families of FMOs and diacylglycerol kinases respectively. The domain organisation of AtNOGC1 suggests that more of its functions still remain to be identified. The cloning and characterisation of the At5g57690 gene will provide possible means for further experimentation as well as affording more insights into the exact functions of lipid kinases in plants.
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