Global ETD Search

61	Increased expression of therapeutic proteins by identification of 3'-UTRs from high expressing genes in CHO cells Westlund, Alexander January 2019 (has links) Therapeutic proteins, a.k.a. biopharmaceuticals, are most commonly produced in expression systems derived from Chinese Hamstery Ovary (CHO) cells, thanks to great capacity of post-translational modifications like secretation, folding and glycosylation. The engineering of cells for regulation of protein expression has many options including knock-in and knock-out of genes, epigenetic studies or improvement of the expression casette of the protein of interest by e.g. promotor variants or modifications of the 5’ and 3’ untranslated region (UTR). The 3’-UTR is therefore a good optimization candidate for attempting to achieve increased expression of therapeutic proteins. The final aim of this study was to identify and design 3’-UTRs for improved expression of therapeutic proteins in HyClone™ CHO cells from GE Healthcare Bio-Sciences AB (GEHC). The impact goal is to increase the efficiency and lower the costs for pharmaceutical companies when producing biopharmaceuticals in the HyClone™ CHO cell line, leading to increased accessibility of monoclonal antibodies (mAbs) on the pharmaceutical market. The study was initiated with bioinformatic analysis of the CHO cell transcriptome from a set of RNA-seq data of HyClone™ CHO to find high expressing, context independent genes. The 3’-UTRs from the best candidate genes were used for construction of plasmids for expression of a Fc-eGFP fusion protein. Nine selected 3’-UTRs were designed, synthesized and cloned into a parent plasmid (pGE0520) creating nine plasmid variants (pGE0523-531). The constructed plasmids were used for evaluation with site directed integration (SDI) into the HyClone™ CHO cell line and expression analysis were performed by flow cytometry and antibody titer measurements from cells with successfully integrated plasmid sorted by fluorescence-activated cell sorting (FACS). Result show a significant effect on protein expression when using different variants of 3’-UTRs. Two variants, pGE0524 and pGE0526, competing with the parent plasmid in expression levels and integration efficiency from SDI, making them candidates for further investigations against the parent plasmid. Results also show good correlation between flow cytometry data from pre- and post-sorting, which can make research for further 3’-UTRs more efficient by evaluations and prediction of expression levels before cell sorting. Mammalian cell CHO E. coli protein expression plasmid transformation Fc-fusion protein flow cytometry FACS transfection mRNA UTR gene engineering Industrial Biotechnology Industriell bioteknik
62	Rab Proteins and Alzheimer's: A Current Review of Their Involvement in Amyloid Beta Generation with Focus on Rab10 Expression in N2A-695 Cells Arano Rodriguez, Ivan 01 March 2015 (has links) This thesis work describes the role of Rab proteins in amyloid processing and clearance in different cell pathways. It also describes an experimental approach used to analyze the expression effects of Rab10 in amyloid beta production. Since the main theory behind neurodegeneration in Alzheimer's disease claims that high levels of amyloid beta 42 (Aβ42) molecules trigger widespread neuronal death, control of Aβ42 has been a main target in Alzheimer's disease research. In addition, several studies show increased levels of particular Rab proteins in Alzheimer's pathogenesis. However, no review consolidates current findings in neurodegeneration of Alzheimer's with Rab protein dysfunction. The first chapter of this thesis aims to address this need by providing a current review of Rab proteins associated with APP and neurodegeneration. The second chapter constitutes an experimental approach used to characterize the effects of Rab10 and Sar1A GTPases in APP and amyloid processing. We found that Rab10 expression does not affect APP production but significantly changes Aβ generation, particularly the toxic Aβ42 and Aβ42:40 ratio. On the other hand, we found no significant effect of Sar1A expression on either APP or amyloid beta generation. These findings partially confirm the work done by Kauwe et al (2015) and provide preliminary evidence for two potential targets for protective effects in neurodegeneration. Rab proteins GTPases Alzheimer's disease gene genetic variants 3' UTR amyloid beta neurodegeneration endocytosis anterograde transport autophagy amyloid precursor protein transient transfection overexpression knockdown Biology
63	Regulation of RNA Processing in Human Papillomavirus Type 16 Rush, Margaret January 2005 (has links) <p>Human papillomavirus type 16 (HPV-16) is the major cause of cervical cancer. HPV-16 gene expression is tightly linked to the differentiation programme of the infected epithelium. Expression of the late genes, L1 and L2, encoding the capsid proteins, is delayed until the more terminally differentiated cells. Successful inhibition of HPV-16 late gene expression early in the viral life cycle is essential for persistence of infection, the highest risk factor for cervical cancer.</p><p>The goal of this thesis was to identify regulatory RNA elements and cellular factors that influence RNA processing events, such as alternative splicing and polyadenylation, during late gene expression. For this purpose, transfection of plasmids containing almost the full-length HPV-16 genome into HeLa cells, followed by RNA analysis, was employed. An exonic splicing enhancer (ESE) was identified that firmly supported the use of the E4 3’ splice site. A key regulator of HPV-16 gene expression, the E4 ESE was required for early mRNA splicing and polyadenylation, as well as for inhibition of premature late gene expression. The early polyadenylation signal (pAE) is also an important block of premature late gene expression. An upstream polyadenylation element (USE) was identified in the early 3’ untranslated region that enhanced polyadenylation at pAE, and interacted specifically with the cellular factors CstF-64, hnRNP C1/C2, PTB and hFip1. With the help of adenoviral E4orf4, a protein which causes dephosphorylation of SR proteins, we found that overexpression of SRp30c activated HPV-16 late gene expression by an exon skipping mechanism, and that SRp30c may interfere with early mRNA terminal exon definition.</p><p>This work identified a crucial splicing enhancer, as well as a number of cellular proteins binding to an USE in the early region of HPV-16. Furthermore, the cellular splicing factor SRp30c was shown to play a role in the regulation of HPV-16 late gene expression.</p> Molecular biology RNA processing human papillomavirus HPV-16 alternative splicing polyadenylation exonic splicing enhancer 3'UTR upstream polyadenylation element SR proteins Molekylärbiologi Molecular biology Molekylärbiologi
64	Regulation of RNA Processing in Human Papillomavirus Type 16 Rush, Margaret January 2005 (has links) Human papillomavirus type 16 (HPV-16) is the major cause of cervical cancer. HPV-16 gene expression is tightly linked to the differentiation programme of the infected epithelium. Expression of the late genes, L1 and L2, encoding the capsid proteins, is delayed until the more terminally differentiated cells. Successful inhibition of HPV-16 late gene expression early in the viral life cycle is essential for persistence of infection, the highest risk factor for cervical cancer. The goal of this thesis was to identify regulatory RNA elements and cellular factors that influence RNA processing events, such as alternative splicing and polyadenylation, during late gene expression. For this purpose, transfection of plasmids containing almost the full-length HPV-16 genome into HeLa cells, followed by RNA analysis, was employed. An exonic splicing enhancer (ESE) was identified that firmly supported the use of the E4 3’ splice site. A key regulator of HPV-16 gene expression, the E4 ESE was required for early mRNA splicing and polyadenylation, as well as for inhibition of premature late gene expression. The early polyadenylation signal (pAE) is also an important block of premature late gene expression. An upstream polyadenylation element (USE) was identified in the early 3’ untranslated region that enhanced polyadenylation at pAE, and interacted specifically with the cellular factors CstF-64, hnRNP C1/C2, PTB and hFip1. With the help of adenoviral E4orf4, a protein which causes dephosphorylation of SR proteins, we found that overexpression of SRp30c activated HPV-16 late gene expression by an exon skipping mechanism, and that SRp30c may interfere with early mRNA terminal exon definition. This work identified a crucial splicing enhancer, as well as a number of cellular proteins binding to an USE in the early region of HPV-16. Furthermore, the cellular splicing factor SRp30c was shown to play a role in the regulation of HPV-16 late gene expression. Molecular biology RNA processing human papillomavirus HPV-16 alternative splicing polyadenylation exonic splicing enhancer 3'UTR upstream polyadenylation element SR proteins Molekylärbiologi Molecular biology Molekylärbiologi
65	Identification of a new deadenylation negative feedback loop that regulates meiotic progression Belloc Rocasalbas, Eulàlia 15 December 2008 (has links) Els oòcits de vertebrats es troben aturats a la profase I de la primera meiosi (PI). Durant el procés anomenat oogènesi, els oòctits sintetitzen i emmagatzemen grans quantitats d'ARN missatgers(ARNm)que els seran necessaris per la compleció de la meiosi.I,per posteriorment, aturar-se de nou a la metafase de la segona divisió meiòtica (MII) per l'activitat del factor citostàtic(CSF).D'aquestes divisions en destaca el fet que transcorren en absència de transcripció, i per tant depenen totalment en l'activació traduccional dels ARNm anteriorment esmentats que han estat acumulats durant l'oogènesi. L'activació traduccional d'aquests missatgers és principalment induïda per l'elongació de les cues d'adenines(cues de poli(A)), aquest procés és mediat per les seqüències de poliadenilació citoplasmàtiques (CPE)presents a la regió 3' no tradudïda (3'UTR)dels ARNm. El moment i la longitud de la poliadenilació dels ARNm que contenen CPEs estan finament regulats, de manera que en combinació amb la degradació de proteïnes, s'estableixen els patrons específics d'expresió de les proteïnes que condueixen la meiosi (Shmitt et al., 2002; de Moor and Richter, 1997; Ballantyne et al., 1997; Mendez et al., 2002; Charlesworth et al., 2002). Fins a la data, no s'havia descrit que la deadenilació (escurçament de la cua de poli(A)) fos necessària per la progressió meiòtica. En aquesta tesi s'ha descrit, a partir d'un cribatge d'abast genòmic, una ruta de retroalimentació negativa requerida per a la sortida de la primera metafase meiòtica. La nova ruta identificada, a més té la particularitat d'actuar a nivell traduccional regulant l'expressió de proteïnes que participen directament en la progressió meiòtica. L'element central d'aquesta nova ruta és la proteïna C3H-4, que a la vegada és regulada per poliadenilació citoplasmàtica. C3H-4 crea la retroalimentació negativa interaccionant amb elements ARE de les regions 3'UTR, promovent la deadenilació del ARNm al qual s'uneix. D'entre les seves dianes hem identificat Emi1 i Emi2, ambdós reguladors de l'activitat de l'APC/C, crítica per la divisió cel·lular. Xenopus Laevis ruta de retroalimentació poliadenilació poli(A) maduració metafase meiosi ARNm Emi2 Emi1 desenvolupament cyclin E control traduccional CPEB C3H-4 deadenilació 3' UTR 575
66	Étude de la traduction IRES-dépendante du VIH-1 Gendron, Karine 05 1900 (has links) Le virus de l’immunodéficience humaine de type 1 (VIH-1) est responsable de la pandémie du SIDA (syndrome de l’immunodéficience acquise). Des souches virales résistantes aux antirétroviraux actuellement utilisés apparaissent rapidement. Il est donc important d’identifier de nouvelles cibles dans le cycle de réplication du VIH-1 pour développer de nouveaux agents contre ce virus. La traduction des protéines de structure et des enzymes du VIH-1 est une étape essentielle du cycle de réplication virale. Ces protéines sont exprimées à partir de l’ARN messager (ARNm) pleine-longueur (ARNmPL) à la fin du cycle de réplication. L’ARNmPL du VIH-1 peut utiliser un mode d’initiation de la traduction coiffe-dépendant, comme la majorité des ARNm cellulaires, mais peut aussi utiliser un mode d’initiation alternatif, car sa région 5’ non-traduite (5’UTR) contient un site interne d’entrée du ribosome (IRES), ce qui lui permet d’initier la traduction suivant un mode IRES-dépendant. L’initiation IRES-dépendante permet à l’ARNmPL d’être traduit quand l’initiation coiffe-dépendante est inhibée. L’activité de l’IRES de la région 5’UTR de l’ARNmPL du VIH-1 (IRES5’UTR) est faible dans des conditions physiologiques, mais est stimulée lorsque la cellule est arrêtée à la transition G2/M du cycle cellulaire, un arrêt qu’induit l’infection par le VIH-1. Une grande portion de l’IRES5’UTR, que nous nommons IRES5’UTRc, est présente dans tous les ARNm viraux et a une activité semblable à celle de l’ IRES5’UTR, ce qui indique que le mode IRES-dépendant peut être utilisé par tous les messagers du VIH-1. Lors de mes études doctorales, j’ai caractérisé le fonctionnement de l’IRES5’UTR du VIH-1. J’ai transfecté des cellules lymphocytaires Jurkat T, dérivées des cibles naturelles du VIH-1, avec un vecteur dual-luciférase contenant les séquences codantes des luciférases de la Renilla (Rluc) et de la luciole (Fluc) séparées par la région 5’UTR de l’ARNmPL du VIH-1. La traduction de la Rluc est coiffe-dépendante alors que celle de la Fluc dépend de l’IRES5’UTR. J’ai d’abord effectué une analyse mutationnelle et j’ai identifié trois régions qui stimulent l’activité de l’IRES5’UTR et une tige-boucle qui réprime l’activité de cet IRES, que j’ai nommée IRENE (IRES negative element). J’ai montré que l’effet répresseur d’IRENE est aboli lorsque les cellules sont soumises à un stress oxydatif, un type de stress induit lors d’une infection par le VIH-1. Nous proposons que IRENE maintiendrait l’IRES5’UTR dans une conformation peu active dans des conditions physiologiques. On sait que les IRES sont activés par divers facteurs cellulaires, appelés ITAF (IRES trans-acting factors). Nous proposons que l’IRES5’UTR adopterait une conformation active suite à la liaison d’un ITAF exprimé ou relocalisé lors d’un stress oxydatif. Ces travaux ont fait l’objet d’une publication (Gendron et al., 2011, Nucleic Acids Research, 39, 902-912). J’ai ensuite étudié l’effet de la protéine virale Tat sur l’activité de l’IRES5’UTR. En plus de son rôle essentiel dans la transactivation de la transcription des ARNm viraux, Tat stimule leur traduction coiffe-dépendante, en empêchant l’inhibition d’un facteur d’initiation canonique, eIF2, induite par la protéine kinase modulée par l’ARN double-brin (PKR) et en déroulant la structure TAR présente à l’extrémité 5’ de tous les ARNm du VIH-1. Elle affecte aussi l’expression de plusieurs gènes cellulaires. J’ai montré que les isoformes Tat86 et Tat72, mais non Tat101, stimulent l’activité de l’IRES5’UTR. Cet effet est indépendant de PKR et de TAR, mais dépendrait de la conformation de Tat. Nous proposons que Tat activerait un facteur de transcription cellulaire qui déclenche l’expression d’un ITAF de l’IRES5’UTR ou encore qu’elle activerait directement un tel ITAF. J’ai de plus montré que PKR stimule l’activité de l’IRES5’UTR, ce qui est surprenant puisque PKR est une protéine antivirale. Cet effet est indépendant de l’inhibition d’eIF2 par PKR et pourrait résulter de l’activation d’un ITAF. Sachant qu’une portion active de l’IRES5’UTR, IRES5’UTRc, est présente dans tous les ARNm viraux, notre hypothèse est que la stimulation de cet IRES par PKR permettait de traduire l’ARNm de Tat au début du cycle de réplication, ce qui permettrait ensuite la traduction coiffe-dépendante des ARNm du VIH-1, qui est stimulée par Tat. Ces travaux font l’objet d’un manuscrit (Gendron et al., soumis à RNA). Mes résultats, couplés aux données de la littérature, me conduisent à la conclusion que, à la fin du cycle de réplication du VIH-1, l’activité de l’IRES5’UTR est stimulée par le stress oxydatif, l’arrêt en G2/M et la présence de quantités élevées de Tat, alors que la traduction coiffe-dépendante est compromise. L’initiation IRES-dépendante serait alors indispensable pour que le VIH-1 traduise l’ARNmPL. L’IRES5’UTR constituerait donc une cible très intéressante pour développer des agents anti-VIH. / The human immunodeficiency virus type 1 (HIV-1) is the causative agent of AIDS (acquired immunodeficiency syndrome). Viral strains that are resistant to antiretroviral agents used for the treatment of HIV-1 infected patients rapidly emerge. It is thus important to study the viral replication cycle in order to discover new targets for the development of novel agents against HIV-1. Translation of structural proteins and viral enzymes is a key step of the viral replication cycle. These proteins are translated from the HIV-1 full-length mRNA during late stages of the replication. This mRNA can be translated by a cap-dependent mode which is used by the majority of cellular mRNAs. However, since its 5’ untranslated region (5’UTR) contains an internal ribosome entry site (IRES) that we call IRES5’UTR, it can also be translated by an IRES-dependent mode. The IRES-dependent mode enables the full-length mRNA to be translated when the cap-dependent mode is impaired. The activity of the IRES5’UTR is weak in physiological conditions, but it is stimulated when the cell cycle is arrested at the G2/M transition, an arrest induced by HIV-1 infection. A large portion of this IRES, which we name IRES5’UTRc, is present in all HIV-1 mRNAs and its activity is similar to the activity of the complete IRES, which indicates that the IRES-dependent mode can be used by all HIV-1 mRNAs. During my doctoral studies, I investigated how the HIV-1 IRES5’UTR functions. I transfected Jurkat T cells, a lymphocytic cell line derived from the natural target cells of HIV-1, with a dual-luciferase reporter containing the coding sequences of the Renilla luciferase (Rluc) and the firefly luciferase (Fluc) separated by the complete 5’UTR of the HIV-1 full-length mRNA. Translation of Rluc is cap-dependent while translation of Fluc depends on HIV-1 IRES5’UTR. First, I performed a mutational analysis and I discovered three regions that stimulate the activity of IRES5’UTR and a stem-loop that represses its activity, which we named IRENE (IRES negative element). I showed that the repression induced by IRENE is relieved when cells are exposed to oxidative stress, a type of stress caused by HIV-1 infection. We propose that IRENE maintains the IRES5’UTR in a weakly active conformation in physiological conditions. It is known that IRESes are activated by cellular factors, called ITAFs (IRES trans-acting factors). We propose that the IRES5’UTR adopts an active conformation triggered by the binding of an ITAF that is expressed or relocalized during oxidative stress. These results generated a publication (Gendron et al. Nucleic Acids Research, 2011, 39, 902-912). I then decided to study the effect of the viral protein Tat on the IRES5’UTR activity. In addition to its essential role in the transcription of HIV-1 mRNAs, Tat stimulates the cap-dependent translation of HIV-1 mRNAs by interfering with the inhibition of a canonical initiation factor, eIF2, induced by the protein kinase modulated by double-stranded RNA (PKR) and by unwinding the TAR structure present at the 5’end of all HIV-1 mRNAs. Tat also affects the expression of several cellular genes. I showed that the Tat86 and Tat72 isoforms, but not Tat101, stimulate the activity of the IRES5’UTR. This effect is independent of PKR and TAR, but appears to be dependent upon the conformation of Tat. We suggest that Tat could activate a transcription factor that controls the expression of an ITAF of the IRES5’UTR or else that Tat could directly activate such an ITAF. I also showed that PKR stimulates the IRES5’UTR activity, which is surprising since PKR is an antiviral protein. This effect is independent of the inhibition of eIF2 by PKR and could result from the activation of an ITAF. Knowing that IRES5’UTRc, an active portion of IRES5’UTR is present in all HIV-1 RNAs, our hypothesis is that the stimulation of the IRES activity by PKR would allow Tat mRNA to be translated in the beginning of the replication cycle. This would subsequently allow the cap-dependent translation of HIV-1 mRNAs to proceed, which is stimulated by Tat. These results generated a manuscript that is submitted for publication to RNA. Altogether, my results, coupled to data from literature, lead me to conclude that, in the late phases of the replication cycle, the activity of the HIV-1 IRES5’UTR is stimulated by oxidative stress, by the cell cycle arrest in G2/M and by the presence of high amounts of Tat, while cap-dependent translation is impaired. The IRES5’UTR would thus be critical to translate the HIV-1 full-length mRNA. Consequently, the IRES5’UTR would constitute a very interesting target for the development of novel anti-HIV agents. VIH-1 initiation de la traduction Tat stress oxydatif HIV-1 IRES 5'UTR translation initiation oxidative stress PKR
67	An experimental and genomic approach to the regulation of alternative pre-mRNA splicing in Drosophila rnp-4f Fetherson, Rebecca A. January 2005 (has links) Thesis (M.S.)--Miami University, Dept. of Zoology, 2005. / Title from first page of PDF document. Document formatted into pages; contains [1], ix, 75 p. : ill. Includes bibliographical references (p. 69-75).
68	Rôle de la structure du génome viral sur la réplication du virus de l’hépatite C Rance, Elodie 02 1900 (has links) No description available. VHC UTR Génome Structures ARN Circularisation Réplication Thalidomide NF-kB Fibrose HCV Genome Structure RNA Circularization Replication Fibrosis
69	Le rôle de la région variable du 3’ UTR dans la réplication du virus de l’hépatite C Jaatoul, Sally 04 1900 (has links) Mémoire en recherche subventionné par le Conseil de recherche en sciences naturelles et en génie du Canada (CRSNG) / Le génome du virus de l’hépatite C (VHC), membre des Flaviviridae, est constitué d’un ARN monocaténaire linéaire de polarité positive, et contient un seul cadre de lecture ouvert flanqué par deux régions non traduites désignées 5’UTR et 3’UTR. Ces régions contiennent des éléments structurés qui sont importants pour la régulation des processus de traduction et de réplication virale. Mon projet de recherche vise le 3’UTR. Celui-ci a une structure tripartite composée d’une région variable (VR), une région poly (U/UC) et une région X. Notre laboratoire a identifié une séquence VR qui forme une structure duplexe avec une séquence distale située dans le NS5B. Considérant que le gène NS5B code pour la polymérase virale, et que la 3’UTR est impliquée dans la réplication virale, nous postulons que ce duplex pourrait contrôler le niveau de synthèse de l'ARN du VHC. Afin de tester cette hypothèse, nous avons construit des mutants individuels des séquences VR et NS5B du VHC 1b afin d’empêcher la formation du duplex, ainsi qu’un mutant complémentaire aux deux sites permettant la reconstitution du duplex. L’ARN provenant de ces constructions a été synthétisé in vitro et transfecté dans les cellules Huh7.5. Au 9e jour de culture, l’ARN a été extrait des cultures, et la technique RT-qPCR a été ensuite utilisée afin de quantifier et comparer les niveaux d’ARN viral provenant des cultures transfectées avec les mutants versus celles transfectées avec le virus parental. Les résultats obtenus montrent une augmentation de 5.3X et 3.4X, respectivement, entre les niveaux d’ARN viral produits de cultures transfectées avec le virus muté dans les régions 3’UTR-VR et NS5B, comparé au virus parental. Cependant, l’ARN viral obtenu suite à la reconstitution des deux sites complémentaires montre une augmentation de 2.6X. Malgré que la différence entre les niveaux d’ARN des virus mutants ne soit pas statistiquement significative lorsqu’on les compare avec le niveau d’ARN généré par le virus parental, la tendance suggère que la fonction des séquences appariées serait de moduler à la baisse la synthèse de l’ARN viral. Il sera nécessaire de poursuivre davantage ce travail afin de mieux comprendre le rôle de la structure duplexe VR-NS5B sur la réplication du VHC. / The hepatitis C virus (HCV), a member of the Flaviviridae, contains a single (+) strand linear RNA genome which incorporates one long open reading frame flanked by two untranslated regions known as the 5’UTR and 3’UTR. These regions contain structures known to function in the regulation of HCV translation and replication. The 3’UTR is the focus of this research project. Its tripartite structure consists of a variable region (VR), a poly (U/UC) region and the X-tail. Our laboratory recently identified a VR sequence forming a duplex structure with a distal sequence located in the NS5B gene. Because NS5B encodes the viral polymerase, and seeing that the 3’UTR is involved in viral replication, we postulated that this duplex may function in controlling the level of HCV RNA replication. To test this hypothesis, we constructed HCV 1b mutants in the respective VR and NS5B annealing sequences to disrupt complementarity and prevent duplex formation. We also created a mutant with complementary mutations at both sites to reconstitute the duplex. RNA from these constructs was synthesized in vitro and transfected into Huh7.5 cells. Following a 9-day incubation period, RNA from all transfected cultures was harvested and HCV RNA was quantified by RT-qPCR. The data indicate an increase of 5.3X and 3.4X for HCV viral RNA harvested from cultures with disrupted 3’UTR-VR and NS5B, respectively, relative to wild-type HCV 1b, whereas the reconstituted HCV construct yielded a 2.6X increase in viral RNA. While these figures do not reach statistical significance, they suggest that the duplex structure modulates HCV replication downward. Further pursuit of this work is necessary to better elucidate the role of the VR-NS5B duplex structure on HCV replication. VHC Flaviviridae 3’UTR VR NS5B Réplication Interactions distales HCV Distal interactions Replication RNA structures
70	Structure of Retroviral 5′-Untranslated Regions and Interactions with Host and Viral Proteins Comandur, Roopa January 2016 (has links) No description available. Biochemistry Cellular Biology Virology HIV-1 PFV reverse transcription tRNA UTR hLysRS TLE fluorescence anisotropy SAXS NMR, SHAPE anticodon binding domain

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