Global ETD Search

171	Ciblage des chaperons d'histone par une stratégie peptidomimétique / Targeting histone chaperones by a peptidomimetic strategy Bakail, May 18 November 2016 (has links) ASF1 est un chaperon d’histones H3-H4 impliqué dans de nombreux cancers. Comme bon nombre de protéines, ce chaperon exerce ses fonctions dans la cellule à travers des interactions protéine-protéine qu’il établit avec d’autres partenaires protéiques. La présente thèse porte sur le développement d’une stratégie originale de design de peptides inhibiteurs de ce type d’interactions souvent associées à des maladies. Cette stratégie rationnelle et itérative repose sur le couplage d’épitopes de liaison provenant de différents partenaires de l’interaction, et leur stabilisation par l’introduction de résidus « ancre » permettant ainsi d’engager un grand nombre de contacts avec la cible. L’extension de cette approche vers des peptidomimes permet par la suite de surmonter les obstacles liés à l’utilisation des peptides en thérapeutique tels que la biodisponibilité et la demi-vie. Appliquée au ciblage d’ASF1, cette méthode a permis de concevoir un peptide, ip4, présentant une affinité de 3nM pour sa cible, soit 3000 fois supérieure au partenaire naturel H3. Ce même peptide a été mimé avec succès par un composé, if3, de nature oligourée. Efficacement internalisés à l’aide d’une Cell Penetrating Peptide clivable, ces inhibiteurs présentent un effet antiprolifératif provoquant la mort des cellules cancéreuse, vraisemblablement dû au ciblage spécifique d’ASF1. / ASF1 is a histone H3-H4 chaperone implicated in several cancers. Like many proteins, this chaperone mediates its cellular functions through protein-protein interactions involving various protein partners. The present thesis focuses on the development of an original strategy to design inhibitory peptides targeting such disease-associated type of biological interactions. This rational and iterative strategy relies on the tethering of binding epitopes isolated from different partners, and stabilized by “anchor” residues that engage large number of atomic contacts with the target. The further progression of this approach toward a peptidomimetic strategy overcomes obstacles commonly associated to the therapeutic use of peptides such as biodisponibility and half-life. Applied for targeting ASF1, such method allowed the conception of a peptide, ip4, presenting a 3nM affinity for its target, which is 3000 fold higher than that of the natural partner H3. This peptide could be successfully mimicked by an oligourea structure, giving rise to the peptidomimetic if3. When coupled to a cleavable Cell Penetrating Peptide, these inhibitors displayed an on-target effect where they impeded cancerous cells proliferation, ultimately resulting in cells death. Drug design Peptidomimétique Interaction protéine-Protéine Chaperon d'histone Activité cellulaire Cancer Drung design Peptidomimetic Protein-Protein interaction Histone chaperone Cellular activity Cancer
172	Establishment of interaction partners of Plasmodium falciparum heat shock protein 70-x(PfHsp 70-x) Monyai, Florina Semakaleng 18 May 2018 (has links) MSc (Biochemistry) / Department of Biochemistry / Plasmodium falciparum is a unicellular protozoan parasite that causes malaria in humans. The parasite is passed to humans through mosquito bites and migrates to the liver before it infects host erythrocytes. It is at the erythrocytic stage of development that the parasite causes malaria pathology. Malaria is characterized by the modification of host erythrocytes making them cytoadherent. This is as a result of formation of protein complexes (knobs) on the surface of the erythrocyte. The knobs that develop on the surface of the erythrocyte are constituted by proteins of host origin as well as some proteins that the parasite ‘exports’ to the host cell surface. Nearly 550 parasite proteins are thought to be exported to the infected erythrocyte. Amongst the exported proteins is P. falciparum heat shock protein 70-x (PfHsp70-x). Hsp70 proteins are known to maintain protein homeostasis. Thus, the export of PfHsp70-x may be important for maintaining protein homeostasis in the host cell. PfHsp70-x is not essential for parasite survival although is implicated in the development of parasite virulence. This is possibly through its role in facilitating the trafficking of parasite proteins to the erythrocyte as well as supporting the formation of protein complexes that constitute the knobs that develop on the surface of the infected erythrocyte. The main objective of the current study was to investigate protein interaction partners of PfHsp70-x. It is generally believed that PfHsp70-x interacts with various proteins of human and parasite origin. Potential candidate interactors include its protein substrates, Hsp70 co-chaperones such as Hsp40 members, and human Hsp70-Hsp90 organizing protein (hHop). The establishment of the PfHsp70-x interactome would highlight the possible role of PfHsp70-x in the development of malaria pathogenicity. Based on bioinformatics analysis, PfHsp70-x was predicted to interact with some exported P. falciparum Hsp40s, hHop and human Hsp90 (hHsp90). Recombinant forms of PfHsp70-x (full length and a truncated form that lacks the C-terminal EEVN motif implicated in co-chaperone binding) were expressed in E. coli BL21 Star (DE3) cells. Recombinant hHop and hHsp70 were expressed in E. coli JM109 (DE3) cells. The proteins were successfully purified using nickel affinity chromatography. Co-affinity chromatography using recombinant PfHsp70-x and immuno-affinity chromatography using PfHsp70-x specific antibody did not confirm the direct interaction of PfHsp70-x with human Hop. However, the direct interaction of hHop and PfHsp70-x has previously been validated in vitro and the current bioinformatics data support ii the existence of such a complex. PfHsp70-x was not stable in the cell lysate that was prepared and this could explain why its interaction with hHop could not be ascertained. However, taken together the evidence from a previous independent study, and the predicted interaction of PfHsp70-x with human chaperones suggests cooperation of chaperone systems which possibly facilitates the folding and function of parasite proteins that are exported to the infected erythrocyte. / NRF Malaria P. falciparum PfHsp70-x Human chaperones human Hop Chaperone networks Interaction partners Protein-protein interactions 616.9362 Malaria -- Prevention Malaria -- Immunological aspects Plasmodium falciparum Protozoan diseases Fever Malaria
173	Comparative analysis of a chimeric Hsp70 of E. coli and Plasmodium falciparum origin relative to its wild type forms Lebepe, Charity Mekgwa 18 May 2019 (has links) MSc (Biochemistry) / Department of Biochemistry / Sustaining proteostasis is essential for the survival of the cell and altered protein regulation leads to many cellular pathologies. Heat shock proteins (Hsps) are involved in the regulation of the protein quality control. Hsps are a group of molecular chaperones that are upregulated in response to cell stress and some are produced constitutively. The Hsp70 family also known as DnaK in Escherichia coli (E. coli) is the most well-known group of molecular chaperones. Structurally, Hsp70s consist of a nucleotide binding domain (NBD) and a substrate binding domain (SBD) conjugated by a linker sub-domain. ATP binding and hydrolysis is central to the Hsp70 functional cycle. Hsp70s play a role in cytoprotection especially during heat stress in E. coli. Hsp70s from different organisms are thought to exhibit specialized cellular functions. As such E. coli Hsp70 (DnaK) is a molecular chaperone that is central to proteostasis in E. coli. On the other hand, Plasmodium falciparum Hsp70s are structurally amenable to facilitate folding of P. falciparum substrates. The heterologous production of P. falciparum proteins in E. coli towards drug discovery has been a challenge. There is need to develop tools that enhance heterologous expression and proper folding of P. falciparum proteins in an E. coli expression system. To this end, a chimeric Hsp70, KPf consisting of E. coli DnaK NBD and P. falciparum Hsp70-1 (PfHsp70-1) SBD was previously designed. KPf was shown to confer cytoprotection to E. coli DnaK deficient cells that were subjected to heat stress. In this study it was proposed that KPf has an advantage over E. coli DnaK and PfHsp70-1 in its function as a protein folding chaperone. Therefore, the main aim of this study was to characterize the chaperone function of KPf relative to the function of wild type E. coli and P. falciparum Hsp70s. The recombinant forms of KPf, DnaK and PfHsp70-1 proteins were successfully expressed and purified using nickel affinity chromatography. Circular Dichroism (CD) structural study demonstrated that KPf and PfHsp70-1 are predominantly α-helical and are also heat stable. Tertiary structure studies of PfHsp70-1 and KPf using tryptophan fluorescence revealed that both confirmations of recombinant proteins are perturbed by the presence of ATP more than ADP. Interestingly, the substrate binding capabilities of these proteins were comparable both in the absence or presence of nucleotides ATP/ADP. KPf is an independent chaperone, that exhibit nucleotide binding and hydrolysis. The current study has established unique structure-function features of KPf that distinguishes it from its “parental” forms, DnaK and PfHsp70-1. / NRF Heat shock proteins Chaperone Kpf Dnak PfHsp70-1 PfHsp40 616.9362 Malaria Malariatherapy Malaria -- Immunological aspects Malaria -- Prevention Protozoan diseases Plasmodium falciparum Drugs
174	Specific adaptations in the proteostasis network of the social amoebae Dictyostelium discoideum lead to an unusual resilience to protein aggregation Malinovska, Liliana 29 April 2014 (has links) A key prerequisite for cellular and organismal health is a functional proteome. A variety of human protein misfolding diseases are associated with the occurrence of amyloid protein aggregates, such as amyotrophic lateral sclerosis (ALS) or Huntington’s disease. The proteins involved in disease manifestation all contain aggregation-prone sequences of low compositional complexity. Such sequences are also known as prion-like, because of their sequence similarity to yeast prions. Yeast prion proteins are a specific subset of amyloid forming proteins with distinct physio-chemical and functional features, which give them transmissible properties. The aggregation properties of yeast prions and disease-related prion-like proteins reside in structurally independent, prion-forming domains (PrDs). These domains are highly enriched for uncharged polar amino acids, such as glutamine (Q) and asparagine (N). These compositional features can be used to predict prion-like proteins bioinformatically. To investigate the prevalence of prion-like proteins across different organisms, we analyzed a range of eukaryotic proteomes. Our analysis revealed that the slime mold D. discoideum contains the highest number of prion-like N/Q-rich proteins of all organisms. Based on this finding, we hypothesized that D. discoideum could be a valuable model system to study protein homeostasis (proteostasis) and the molecular basis of protein misfolding diseases. To explore how D. discoideum manages its highly aggregation-prone proteome, we analyzed the behavior of several well-characterized misfolding-prone marker proteins (variants of the disease-causing exon 1 of the huntingtin protein as well as wildtype and variant versions of the Q/N-rich yeast prion Sup35NM). Intriguingly, these proteins did not form cytosolic aggregates in D. discoideum, as they do in other organisms. Aggregates, however, formed as a result of heat stress, which indicates that the tested proteins have the capacity to aggregate, but are kept under tight control under normal conditions. Furthermore, when the stress level was reduced, the stress-induced aggregates dissolved, suggesting that D. discoideum has evolved mechanisms to reverse aggregation after a period of acute stress. Together, these findings reveal an unusual resilience of D. discoideum to aggregation-prone proteins, which very likely results from specific adaptations in its proteostasis network. By studying these specific adaptations, we could get important insight into the strategies that nature employs to control and maintain a highly aggregation-prone proteome. So far, our experimental investigations have revealed evidence for three specific adaptations. First, we identified the disaggregase Hsp101 as a key player in the acute stress response of D. discoideum. A functional analysis of Hsp101 in yeast and D. discoideum revealed that it supports thermotolerance. Second, we found evidence for an important role of the nucleus and nucleolus in proteostasis. We discovered that a small fraction of highly aggregation-prone proteins accumulated in the nucleus or nucleolus of D. discoideum cells. The magnitude of this nuclear accumulation could be increased by proteasome impairment, which suggests that the ubiquitin-proteasome system (UPS) is involved. This finding is consistent with previous studies in other organisms and hints at the possibility that D. discoideum disposes of aggregation-prone proteins by degrading them in the nucleus/nucleolus. Third and finally, we found that cells containing nuclear accumulations are asymmetrically distributed in the multicellular developmental stage (slug), suggesting that D. discoideum employs cell-sorting mechanisms to dispose of cells with accumulated protein damage. Although our current understanding of proteostasis in D. discoideum is preliminary, we have gained important insight into the molecular mechanisms and cellular pathways that D. discoideum uses to counteract protein aggregation. Findings from this work will inform similar comparative studies in other organisms and will impact our molecular understanding of protein misfolding diseases and aging. / Eine wesentliche Voraussetzung für die Gesundheit von Zellen und Organismen ist ein funktionales Proteom. Eine Reihe von humanen Protein- Missfaltungs-Erkrankungen, wie Chorea Huntington und Amyotrophe Lateralsklerose (ALS) werden mit dem Auftreten von amyloiden Protein- Aggregaten in Verbindung gebracht. Sämtliche Proteine, die in der Pathogenese dieser Krankheiten eine Rolle spielen, enthalten aggregations-anfällige Sequenzen mit geringer Sequenzkomplexität. Solche Sequenzen werden als Prion-ähnlich bezeichnet, da sie in ihrer Zusammensetzung den Prionen aus der Hefe S. cerevisiae gleichen. Die Prion-Proteine der Hefe gehören zu einer Unterart von amyloid-aggregierenden Proteinen, die durch bestimmte physikochemische und funktionelle Eigenschaften einen infektiösen Charakter erhalten. Die Aggregations-Eigenschaften von Hefeprionen und aggregationsanfällige Proteinen, die mit Erkrankungen in Verbindung gebracht werden, basieren auf strukturell unabhängigen, Prion-bildenden Domänen (prion domain, PrD). Diese Domänen sind angereichert mit polaren Aminosäuren wie Glutamin und Asparagin. Diese Zusammensetzung kann dazu verwendet werden prion-ähnliche Proteine bioinformatisch vorherzusagen. Um die Verbreitung von Prion-ähnlichen Proteinen in verschiedenen Organismen zu untersuchen, analysierten wir eine Reihe von eukaryotischen Proteomen. Unsere Analyse zeigte, dass der Schleimpilz D. discoideum die höchste Anzahl von Prion-ähnlichen N/Q-reichen Proteinen aufzeigt. Aufgrund dieser Erkenntnisse erstellten wir die Hypothese, dass D. discoideum ein nützlicher Modellorganismus sein könnte, um Protein Homöostase (Proteostase) sowie die molekulare Basis von Proteins-Missfaltungs-Erkrankungen zu ergründen. Um zu analysieren, wie D. discoideum mit seinem höchst aggregations-anfälligen Proteom umgehen kann, untersuchten wir das Verhalten mehrerer bereits charakterisierter aggregations-anfälliger Marker-Proteine in D. discoideum. Hierbei verwendeten wir Varianten des krankheits-erzeugenden Exon 1 des humanen Huntingtin Protein sowie den wild-typ und Varianten des N/Q-reichen Hefe Prions Sup35. Interessanterweise bildeten diese Proteine, anders als in anderen Organismen, keine zytosolischen Aggregate in D. discoideum aus. Aggregate wurden jedoch unter Hitzestress-Bedingungen gebildet. Dies deutet darauf hin, dass die getesteten Proteine durchaus das Vermögen zu aggregieren besitzen, jedoch unter normalen Wachstumsbedingungen streng kontrolliert werden. Wenn, darüberhinaus das Stress- Level gesenkt wurde, kam es zur Auflösung der stress-induzierten Aggregate. Dies deutet darauf hin, dass D. discoideum Mechanismen entwickelt hat, um Aggregate nach Perioden von akutem Stress wieder aufzulösen. Zusammengenommen enthüllen diese Erkenntnisse eine ungewöhnliche Widerstandsfähigkeit gegenüber aggregations-anfälligen Proteinen. Diese beruht höchstwahrscheinlich auf spezifischen Modifikationen im Proteostase Netzwerk. Durch die Analyse dieser spezifischen Anpassungen könnten wichtige Einblicke in die Strategien gewährt werden, welche die Natur benutzt, um ein höchst aggregations-anfälliges Proteom zu erhalten und zu kontrollieren. Bisher erbrachten unsere Experimente Anhaltspunkte für drei spezifische Anpassungen. Erstens zeigten wir, dass die Disaggregase Hsp101 eine Schlüsselrolle in der akuten Stressantwort in D. discoideum einnimmt. Eine funktionale Analyse von Hsp101 in D. discoideum und Hefe zeigte, dass die Disaggregase Thermotoleranz fördert. Zweitens haben wir Anhaltspunkte, dass der Nukleus und der Nukleolus eine wichtige Rolle in der Proteostase einnehmen. Eine geringe Fraktion der überaus aggregations-anfälligen Proteine akkumuliert im Nukleus oder Nukleolus von D. discoideum. Das Ausmaß der nuklearen Akkumulation konnte erhöht werden, wenn das Proteasom beeinträchtigt wird. Dies deutet darauf hin, dass das Ubiquitin-Proteasom-System involviert sein könnte. Diese Beobachtung ist im Einklang mit jüngsten Berichten aus anderen Organismen und daraus folgt, dass D. discoideum möglicherweise aggregations-anfällige Proteine durch Abbau im Nukleus entsorgt. Drittens konnten wir feststellen, dass Zellen, die nukleare Akkumulationen enthalten, asymmetrisch in der multizellulären Entwicklungs-Struktur des Pseudoplasmodiums verteilt sind. Dies deutet darauf hin, dass D. discoideum möglicherweise den Zellsortierungsmechanismus während der Entwicklung nutzen kann, um Zellen mit angereicherten Protein-Schäden zu beseitigen. Auch wenn das gegenwärtige Verständnis der Proteostase in D. discoideum nur vorläufig ist, haben wir wichtige Einblicke in die molekularen Mechanismen und zellulären Prozesse erhalten, die D. discoideum verwendet, um Protein-Aggregation zu verhindern. Die Ergebnisse dieser Arbeit werden ähnliche vergleichende Studien in anderen Organismen beeinflussen und Auswirkungen auf unser molekulares Verständnis über Protein-Missfaltungs-Erkrankungen und das Altern haben. info:eu-repo/classification/ddc/570 ddc:570
175	Über die potenziell kardioprotektive Rolle des Hitzeschockproteins A4 / The potential cardioprotective role of HSPA4 Gersch, Svante Sören 06 October 2020 (has links) No description available. 610 hspa4 Protein-Qualitäts-Kontrolle Chaperon kardiale Hypertrophie Herzinsuffizienz Chaperone protein quality control cardiomyocytes hspa4 cardiac hypertrophy heart failure Medizin (PPN619874732)
176	Pharmacothérapie ciblée dans la cholestase intrahépatique familiale progressive de type 2 (PFIC2) / Targeted Pharmacotherapy for Progressive Familial Intrahepatic Cholestasis type 2 (PFIC2) Amzal, Rachida 09 July 2019 (has links) ABCB11/BSEP est le transporteur des acides biliaires, localisé au niveau du pôle canaliculaire des hépatocytes. Les mutations de ce gène sont responsables de la cholestase familiale intrahépatique progressive de type 2.Au cours de ma thèse, j’ai évalué la capacité des aminoglycosides et du PTC124 à induire la translecture de codons stop prématurés, l’adressage et la fonction de mutants non-sens et faux sens de Bsep ainsi que l’effet d’une bithérapie (translecture+chaperone).Dans nos modèles cellulaires, la gentamicine était capable d’induire la translecture du codon-stop prématuré du mutant non-sens BsepR1090X dans les lignées NIH3T3, HEK293 et Can 10. La protéine entière générée était partiellement détectée aux membranes plasmiques des cellules HEK293 et canaliculaires des cellules Can 10 et était partiellement fonctionnelle puisqu’elle était responsable d’une augmentation de l’activité de transport de 3H-taurocholate (3H-TC) dans les clones MDCK. Ces effets étaient potentialisés par l’addition de drogues chaperones telles que le 4-phenylbutyrate (4-PB).J’ai également mis en évidence la capacité de nouveaux composés dérivés du 4-PB (MHMPB, OTNC et HMPB) à corriger l’adressage et à augmenter le transport de 3H-TC du mutant faux sens BsepR1128C à des concentrations plus faibles que le 4-PB. Enfin, j’ai pu montrer que d'autres drogues chaperones (GPB, PA, SAHA et C18), pouvaient corriger l’adressage canaliculaire de BsepR1128C et augmenter son activité de transport de 3H-TC dans les clones MDCK. / ABCB11/BSEP is the main bile acids transporter located at the canalicular pole of hepatocytes. Mutations of ABCB11 are responsible for progressive familial intrahepatic cholestasis type 2.During my phD, I evaluated the ability of aminoglycosides and PTC124 to induce readthrough of premature termination codons, targeting and function of nonsense and missense mutants of Bsep and also the effect of combined therapy (readthrough + chaperone).In our expermental models, gentamicin increased readthrough of p.R1090X mutation NIH3T3, HEK293 and Can 10 lines. The resulting full-length protein was detected at the plasma membrane of HEK293 and at the canalicular membrane of Can 10 cells; and was partially functional since it was responsible for increasing the transport activity of 3H-taurocholate (3H-TC) in MDCK clones. These effects were potentiated by the addition of chaperone drugs such as 4-phenylbutyrate (4-PB).I have also demonstrated the ability of new 4-PB derived compounds (MHMPB, OTNC and HMPB) to correct mistrafficking and to increase 3H-TC transport of BsepR1128C missense mutant at lower concentrations than 4-PB. Finally, I showed that other chaperone drugs (GPB, PA, SAHA, and C18) were able to correct mistrafiking of BsepR1128C and to increase its 3H-TC transport activity in MDCK clones. Drogues chaperones Mutations non sens Transporteur des sels biliaires (BSEP) Mutations faux sens 4-Phénylbutyrate Chaperone drugs 4-Phénylbutyrate Missense mutations Non-Sense mutations
177	Role of molecular chaperones in G protein B5-Regulator of G protein signaling dimer assembly and G protein By dimer specificity Howlett, Alyson Cerny 02 April 2009 (has links) (PDF) In order for G protein signaling to occur, the G protein heterotrimer must be assembled from its nascent polypeptides. The most difficult step in this process is the formation of the Gβγ dimer from the free subunits since both are unstable in the absence of the other. Recent studies have shown that phosducin-like protein (PhLP1) works as a co-chaperone with the cytosolic chaperonin complex (CCT) to fold Gβ and mediate its interaction with Gγ. However, these studies did not address questions concerning the scope of PhLP1 and CCT-mediated Gβγ assembly, which are important questions given that there are four Gβs that form various dimers with 12 Gγs and a 5th Gβ that dimerizes with the four regulator of G protein signaling (RGS) proteins of the R7 family. The data presented in Chapter 2 shows that PhLP1 plays a vital role in the assembly of Gγ2 with all four Gβ1-4 subunits and in the assembly of Gβ2 with all twelve Gγ subunits, without affecting the specificity of the Gβγ interactions. The results of Chapter 3 show that Gβ5-RGS7 assembly is dependent on CCT and PhLP1, but the apparent mechanism is different from that of Gβγ. PhLP1 seems to stabilize the interaction of Gβ5 with CCT until Gβ5 is folded, after which it is released to allow Gβ5 to interact with RGS7. These findings point to a general role for PhLP1 in the assembly of all Gβγ combinations, and suggest a CCT-dependent mechanism for Gβ5-RGS7 assembly that utilizes the co-chaperone activity of PhLP1 in a unique way. Chapter 4 discusses PhLP2, a recently discovered essential protein, and member of the Pdc family that does not play a role in G protein signaling. Several studies have indicated that PhLP2 acts as a co-chaperone with CCT in the folding of actin, tubulin, and several cell cycle and pro-apoptotic proteins. In a proteomics screen for PhLP2A interacting partners, α-tubulin, 14-3-3, elongation factor 1α, and ribosomal protein L3 were found. Further proteomics studies indicated that PhLP2A is a phosphoprotein that is phosphorylated by CK2 at threonines 47 and 52. Phosducin-like protein 1 PhLP1 chaperone chaperonin CCT Gβ 5 Gβ γ RGS Regulator of G protein signaling G protein assembly Phosducin-like protein 2 PhLP2 Biochemistry Chemistry
178	Structural and Functional Studies of Glycine Riboswitches and Development of Fab Chaperone Assisted RNA Crystallography Sherman, Eileen 01 January 2014 (has links) The glycine riboswitch is a structured RNA found upstream of genes in mRNA transcripts in many bacteria, functioning as a biofeedback gene regulator. Upon binding glycine, a complete RNA transcript including gene sequences is transcribed, effectively turning on gene expression. In an effort to understand the intricacies of its functioning, many mutants of the riboswitch were made and characterized during Ph. D. work, resulting in discovery of a P0 duplex/kink-turn motif involving a few nucleotides upstream of the established glycine riboswitch sequence which changed its ligand binding characteristics (Chapter 1). Previously, the two aptamers of the riboswitch were thought to cooperatively bind glycine, but with the inclusion of this leader sequence which forms a kink turn motif with the linker between the two aptamers, glycine binding in one aptamer no longer requires glycine binding in the other. Furthermore, the Kd from three species tested are now a similar, lower value of about 5 µM, indicating authenticity of this new consensus sequence. Glycine binding and interaptamer interaction both enhanced one another in trans aptamer assays. Another discovery from this was a shortened construct including all of aptamer II but only part of aptamer I in which a few specific nucleotides prevented glycine binding in aptamer II (Chapter 2). This may provide insight into the nature of interaptamer interactions in the full switch; addition of an oligonucleotide complimentary to these nucleotides restored glycine binding ability to aptamer II. With future development, this could also be a useful molecular biology tool, using two signals, glycine and an oligonucleotide, to allow gene expression. To precisely understand how any macromolecule functions, a 3D structure, obtainable by x-ray crystallography, is vital. A new technique to accomplish that for RNA, precedented in the protein world, is Fab chaperoned crystallography, which has advantages compared to RNA alone. A phage displayed library of Fabs with reduced codon diversity designed for RNA was created, the YSGR Min library (Chapter 3). Its Fabs had specificities and affinities equal to or greater than previous libraries which were originally created for phage displayed selection against proteins. Fab chaperoned RNA crystallography is currently in progress for the glycine riboswitch; the best resolution thus far is 5.3 … (Chapter 4). In addition to providing molecular insight into its gene regulation mechanism, a structure of the glycine riboswitch could be applied for use in structure based drug design of novel antibiotics targeting the riboswitch to disrupt important downstream carbon cycle genes in pathogenic bacteria. Glycine riboswitch allosteric genetic control circuit rna targeting Chemistry
179	Intracellular Processing of Cobalamins in Mammalian Cells Hannibal, Luciana 20 July 2009 (has links) No description available. Biochemistry Biology Cellular Biology Chemistry Pathology Cobalamin vitamin B12 methylcobalamin adenosylcobalamin nitrosylcobalamin transcobalamin alkylcobalamin synchrotron diffraction processing MMACHC cblC chaperone crystal structure inborn error deficiency proteomics pathway analysis
180	Host recognition strategies and evolution in phages infecting the marine bacterium Alteromonas sp. Gonzalez-Serrano, Rafael 22 March 2021 (has links) Viruses constitute the vast majority of all biological entities in the biosphere and represent one of the biggest reservoirs of undetected genetic diversity on Earth. Of all the viral particles inhabiting the ocean, phages are the most abundant and can affect the overall microbial composition of marine ecosystems and the dynamics of global biogeochemical cycles. The interaction between prokaryotic cells and their phages is among the oldest and most intertwined host-parasite relationships on the planet. It has been extensively studied by culture, molecular biology, and experimental evolution. However, due to the difficulties of culture with environmental samples, only a few studies have analyzed the mechanisms of phage-host interaction in the marine environment. Here, we have studied the genes involved in viral host recognition and their evolutionary dynamics by focusing on two species of the marine copiotrophic bacterium Alteromonas and several phages infecting them. We described the genomic and morphological characterization of the first Alteromonas phage belonging to the Myoviridae family (Alteromonas myovirus V22) that was isolated in coastal waters of the Mediterranean Sea, and we identified its receptor-binding protein (RBP) used for host recognition by combining fluorescence microscopy and spectrometry. In addition, using size-exclusion chromatography, we showed how this protein required co-expression with a downstream protein to be functional, which later was identified as a new type of intermolecular chaperone crucial for RBP maturation. We also identified a conserved host recognition module in V22 and other unrelated alterophages belonging to different viral families and with completely different morphologies, suggesting horizontal gene transfer between the ancestors of these phages. Furthermore, we described the first coevolution study of a host-parasite system performed with Alteromonas using a metagenomics-like approach. Finally, we analyzed the micro- and macrodiversity of an alterophage population that was able to survive over a long period of time and showed remarkable genomic stability, indicating stable interactions over time between phage-host recognition structures. Overall, this study has contributed to extend the knowledge of known phage-host recognition mechanisms present in the marine ecosystem and has provided a first glimpse of the evolutionary dynamics in phages infecting Alteromonas. Bacteriophage Alteromonas Receptor-binding protein Host recognition Tail fiber Chaperone Experimental evolution Point mutation Allele fixation Microbiología

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