Development of techniques for testing the effect of the E1 region on adenovirus integration /

Adenoviral vectors are currently the most widely used gene therapeutic vectors, but their inability to integrate into host chromosomal DNA shortened their transgene expression and limited their use in clinical trials. In this project, we initially planned to develop a technique to test the effect of the early region 1 (E1) on adenovirus integration by comparing the integration efficiencies between an E1-deleted adenoviral vector (SubE1) and an Elcontaining vector (SubE3). However, we did not harvest any SubE3 virus, even if we repeated the transfection and successfully rescued the SubE1 virus (2/4 transfections generated viruses) and positive control virus (6/6). The failure of rescuing SubE3 could be caused by the instability of the genomic plasmid pFG173, as it had frequent intemal deletions when we were purifying It. Therefore, we developed techniques to test the effect of E1 on homologous recombination (HR) since literature suggested that adenovirus integration is initiated by HR. We attempted to silence the E1 in 293 cells by transfecting E1A/B-specific small interfering RNA (siRNA). However, no silenced phenotype was observed, even if we varied the concentrations of E1A/B siRNA (from 30 nM to 270 nM) and checked the silencing effects at different time points (48, 72, 96 h). One possible explanation would be that the E1A/B siRNA sequences are not potent enough to Induce the silenced phenotype. For evaluating HR efficiencies, an HR assay system based on bacterial transfonmatJon was designed. We constmcted two plasmids ( designated as pUC19-dl1 and pUC19-dl2) containing different defective lacZa cassettes (forming white colonies after transformation) that can generate a functional lacZa cassette (forming blue colonies) through HR after transfecting into 293 cells. The HR efficiencies would be expressed as the percentages of the blue colonies among all the colonies. Unfortunately, after transfonnation of plasmid isolated from 293 cells, no colony was found, even at a transformation efficiency of 1.8x10^ colonies/pg pUC19, suggesting the sensitivity of this system was low. To enhance the sensitivity, PCR was used. We designed a set of primers that can only amplify the recombinant plasmid fomied through HR. Therefore, the HR efficiencies among different treatments can be evaluated by the amplification results, and this system could be used to test the effect of E1 region on adenovirus integration. In addition, to our knowledge there was no previous studies using PCR/ Realtime PCR to evaluate HR efficiency, so this system also provides a PCR-based method to carry out the HR assays.

Development of packaging cell lines for rescuing BAV2 viral vectors

The construction of adenovirus vectors for cloning and foreign gene expression requires packaging cell lines that can complement missing viral functions caused by sequence deletions and/or replacement with foreign DNA sequences. In this study, packaging cell lines were designed to provide in trans the missing bovine adenovirus functions, so that recombinant viruses could be generated. Fetal bovine kidney and lUng cells, acquired at the trimester term from a pregnant cow, were tranfected with both digested wild type BAV2 genomic DNA and pCMV-EI. The plasmid pCMV-EI was specifically constructed to express El of BAV2 under the control of the cytomegalovirus enhancer/promoter (CMV). Selection for "true" transformants by continuous passaging showed no success in isolating immortalised cells, since the cells underwent crisis resulting in complete cell death. Moreover, selection for G418 resistance, using the same cells, also did not result in the isolation of an immortalised cell line and the same culture-collapse event was observed. The lack of success in establishing an immortalised cell line from fetal tissue prompted us to transfect a pre-established cell line. We began by transfecting MDBK (Mardin-Dardy bovine kidney) cells with pCMV-El-neo, which contain the bacterial selectable marker neo gene. A series of MDBK-derived cell lines, that constitutively express bovine adenoviral (BAV) early region 1 (El), were then isolated. Cells selected for resistance to the drug G418 were isolated collectively for full characterisation to assess their suitability as packaging cell lines. Individual colonies were isolated by limiting dilution and further tested for El expression and efficiency of DNA uptake. Two cell lines, L-23 and L-24, out of 48 generated foci tested positive for £1 expression using Northern Blot analysis. DNA uptake studies, using both lipofectamine and calcium phosphate methods, were performed to compare these cells, their parental MDBK cells, 8 and the unrelated human 293 cells as a benchmark. The results revealed that the new MDBKderived clones were no more efficient than MDBK cells in the transient expression of transfected DNA and that they were inferior to 293 cells, when using lacZ as the reporter gene. In view of the inherently poor transfection efficiency of MDBK cells and their derivatives, a number of other bovine cells were investigated for their potential as packaging cells. The cell line CCL40 was chosen for its high efficiency in DNA uptake and subsequently transfected with the plasmid vector pCMV El-neo. By selection with the drug G418, two cell lines were isolated, ProCell 1 and ProCell 2. These cell lines were tested for El expression, permissivity to BAV2 and DNA uptake efficiency, revealing a DNA uptake efficiency of 37 % , comparable to that of CCL40. Attempts to rescue BAV2 mutants carrying the lacZ gene in place of £1 or £3 were carried out by co-transfecting wild type viral DNA with either the plasmid pdlElE-Z (which contains BAV2 sequences from 0% to 40.4% with the lacZ gene in place of the £1 region from 1.1% to 8.25%) or with the plasmid pdlE3-5-Z (which contains BAV2 sequences from 64.8% to 100% with the lacZ gene in place of the E3 region from 75.8% to 81.4%). These cotransfections did not result in the generation of a viral mutant. The lack of mutant generation was thought to be caused by the relative inefficiency ofDNA uptake. Consequently, cosBAV2, a cosmid vector carrying the BAV2 genome, was modified to carry the neo reporter gene in place of the £3 region from 75.8% to 81.4%. The use of a single cosmid vector earring the whole genome would eliminate the need for homologous recombination in order to generate a viral vector. Unfortunately, the transfection of cosBAV2- neo also did not result in the generation of a viral mutant. This may have been caused by the size of the £3 deletion, where excess sequences that are essential to the virus' survival might have been deleted. As an extension to this study, the spontaneous E3 deletion, accidently discovered in our viral stock, could be used as site of foreign gene insertion.

Engineering an improved adenovirus packaging cell line

Recombinant human adenovirus (Ad) vectors are being extensively explored for their use in gene therapy and recombinant vaccines. Ad vectors are attractive for many reasons, including the fact that (1) they are relatively safe, based on their use as live oral vaccines, (2) they can accept large transgene inserts, (3) they can infect dividing and postmitotic cells, and (4) they can be produced to high titers. However, there are also a number of major problems associated with Ad vectors, including transient foreign gene expression due to host cellular immune responses, problems with humoral immunity, and the creation of replication competent adenoviruses (RCA). Most Ad vectors contain deletions in the E1 region that allow for insertion of a transgene. However, the E1 gene products are required for replication and thus must be supplied in trans by a helper ceillille that will allow for the growth and packaging of the defective virus. For this purpose the 293 cell line (Graham et al., 1977) is used most often; however, homologous recombination between the vector and the cell line often results in the generation of RCA. The presence of RCA in batches of adenoviral vectors for clinical use is a safety risk because tlley . may result in the mobilization and spread of the replication-defective vector viruses, and in significant tissue damage and pathogenicity. The present research focused on the alteration of the 293 cell line such that RCA formation can be eliminated. The strategy to modify the 293 cells involved the removal of the first 380 bp of the adenovirus genome through the process of homologous recombination. The first step towards this goal involved identifying and cloning the left-end cellular-viral jUl1ction from 293 cells to assemble sequences required for homologous recombination. Polymerase chain reaction (PCR) was performed to clone the junction, and the clone was verified through sequencing. The plasn1id PAM2 was then constructed, which served as the targeting cassette used to modify the 293 cells. The cassette consisted of (1) the cellular-viral junction as the left-end region of homology, (2) the neo gene to use for positive selection upon tranfection into 293 cells, (3) the adenoviral genome from bp 380 to bp 3438 as the right-end region of homology, and (4) the HSV-tk gene to use for negative selection. The plasmid PAM2 was linearized to produce a double strand break outside the region of homology, and transfected into 293 cells using the calcium-phosphate technique. Cells were first selected for their resistance to the drug G418, and subsequently for their resistance to the drug Gancyclovir (GANC). From 17 transfections, 100 pools of G418f and GANCf cells were picked using cloning lings and expanded for screening. Genomic DNA was isolated from the pools and screened for the presence of the 380 bps using PCR. Ten of the most promising pools were diluted to single cells and expanded in order to isolate homogeneous cell lines. From these, an additional 100 G41Sf and GANef foci were screened. These preliminary screening results appear promising for the detection of the desired cell line. Future work would include further cloning and purification of the promising cell lines that have potentially undergone homologous recombination, in order to isolate a homogeneous cell line of interest.

Locating and sequencing of the E3 and neighbouring regions in bovine advenovirus type 2

Adenoviruses are nonenveloped icosahedral shaped particles. The double stranded DNA viral genome is divided into 5 major early transcription units, designated E1 A, E1 B, and E2 to E4, which are expressed in a regulated manner soon after infection. The gene products of the early region 3 (E3), shown to be nonessential for viral replication in vitro, are believed to be involved in counteracting host immunosurveillance. In order to sequence the E3 region of Bovine adenovirus type 2 (BAV2) it was necessary to determine the restriction map for the plasmid pEA48. A physical restriction endonuclease map for BamHl, Clal, Eco RI, Hindlll, Kpnl, Pstt, Sail, and Xbal was constructed. The DNA insert in pEA48 was determined to be viral in origin using Southern hybridization. A human adenovirus type 5 recombinant plasmid, containing partial DNA fragments of the two transcription units L4 and L5 that lie just outside the E3, was used to localize this region. The recombinant plasmid pEA was subcloned to facilitate sequencing. The DNA sequences between 74.8 and 90.5 map units containing the E3, the hexon associated protein (pVIII), and the fibre gene were determined. Homology comparison revealed that the genes for the hexon associated pV11I and the fibre protein are conserved. The last 70 amino acids of the BAV2 pV11I were the most conserved, showing a similarity of 87 percent with Ad2 pV1I1. A comparison between the predicted amino acid sequences of BAV2 and Ad40, Ad41 , Ad2 and AdS, revealed that they have an identical secondary structure consisting of a tail, a shaft and a knob. The shaft is composed of 22, 15 amino acid motifs, with periodic glycines and hydrophobic residues. The E3 region was found to consist of about 2.3 Kbp and to encode four proteins that were greater than 60 amino acids. However, these four open reading frames did not show significant homology to any other known adenovirus DNA or protein sequence.

Manipulation of adenovirus early region 1 rescue plasmids by homologous recombination in Saccharomyces cerevisiae

The manipulation of large (>10 kb) plasmid systems amplifies problems common to traditional cloning strategies. Unique or rare restriction enzyme recognition sequences are uncommon and very rarely located in opportunistic locations. Making site-specific deletions and insertions in larger plasmids consequently leads to multiple step cloning strategies that are often limited by time-consuming, low efficiency linker insertions or blunt-end cloning strategies. Manipulation ofthe adenovirus genome and the genomes ofother viruses as bacterial plasmids are systems that typify such situations. Recombinational cloning techniques based on homologous recombination in Saccharomyces cerevisiae that circumvent many ofthese common problems have been developed. However, these techniques are rarely realistic options for such large plasmid systems due to the above mentioned difficulties associated with the addition ofrequired yeast DNA replication, partitioning and selectable marker sequences. To determine ifrecombinational cloning techniques could be modified to simplify the manipulation of such a large plasmid system, a recombinational cloning system for the creation of human adenovirus EI-deletion rescue plasmids was developed. Here we report for the first time that the 1,456 bp TRP1/ARS fragment ofYRp7 is alone sufficient to foster successful recombinational cloning without additional partitioning sequences, using only slight modifications of existing protocols. In addition, we describe conditions for efficient recombinational cloning involving simultaneous deletion of large segments ofDNA (>4.2 kb) and insertion of donor fragment DNA using only a single non-unique restriction site. The discovery that recombinational cloning can foster large deletions has been used to develop a novel recombiliational cloillng technique, selectable inarker 'kilockouf" recombinational cloning, that uses deletion of a yeast selectable marker coupled with simultaneous negative and positive selection to reduce background transformants to undetectable levels. The modification of existing protocols as described in this report facilitates the use of recombinational cloning strategies that are otherwise difficult or impractical for use with large plasmid systems. Improvement of general recombinational cloning strategies and strategies specific to the manipulation ofthe adenovirus genome are considered in light of data presented herein.

Molecular cloning and restriction endonuclease analysis of bovine adenovirus type 3

Bovine adenovirus type 3 (BAV3) is a medium size DNA virus that causes respiratory and gastrointestinal disorders in cattle. The viral genome consists of a 35,000 base pair, linear, double-stranded DNA molecule with inverted terminal repeats and a 55 kilodalton protein covalently linked to each of the 5' ends. In this study, the viral genome was cloned in the form of subgenomic restriction fragments. Five EcoRI internal fragments spanning 3.4 to 89.0 % and two Xb a I internal fragments spanning 35.7 to 82.9 % of the viral genome were cloned into the EcoRI and Xbal sites of the bacterial vector pUC19. To generate overlap between cloned fragments, ten Hi n dIll internal fragments spanning 3.9 to 84.9 and 85.5 to 96% and two BAV3 BamHI internal fragments spanning 59.8 to 84.9% of the viral genome were cloned into the HindllI and BamHI sites of pUC19. The HindlII cloning strategy also resulted in six recombinant plasmids carrying two or more Hi ndII I fragments. These fragments provided valuable information on the linear orientation of the cloned fragments within the viral genome. Cloning of the terminal fragments required the removal of the residual peptides that remain attached to the 5' ends of the genome. This was accomplished by alkaline hydrolysis of the DNA-peptide bond. BamH I restriction fragments of the peptide-free DNA were cloned into pUC19 and resulted in two plasmids carrying the BAV3 Bam HI terminal fragments spanning 0 to 53.9% and 84.9 to 100% of the viral genome.

Molecular cloning restriction enzyme analysis, bovine adenovirus type 2 genome

Adenoviruses are non-enveloped icosahedral-shaped particles which possess a double-stranded DNA genome. Currently, nearly 100 serotypes of adenoviruses have been identified, 48 of which are of human origin. Bovine adenoviruses (BAVs), causing both mild respiratory and/or enteral diseases in cattle, have been reported in many countries all over the world. Currently, nine serotypes of SAVs have been isolated which have been placed into two subgroups based on a number of characteristics which include complement fixation tests as well as the ability to replicate in various cell lines. Bovine adenovirus type 2 (BAV2), belonging to subgroup I, is able to cause pneumonia as well as pneumonic-like symptoms in calves. In this study, the genome of BAV2 (strain No. 19) was subcloned into the plasmid vector pUC19. In total, 16 plasmids were constructed; three carry internal San fragments (spanning 3.1 to 65.2% ), and 10 carry internal Pstl fragments (spanning 4.9 to 97.4%), of the viral genome. Each of these plasmids was analyzed using twelve restriction endonucleases; BamHI, CiaI, EcoRl, HiOOlll, Kpnl, Noll, NS(N, Ps~, Pvul, Saj, Xbal, and Xhol. Terminal end fragments were also cloned and analyzed, sUbsequent to the removal of the 5' terminal protein, in the form of 2 BamHI B fragments, cloned in opposite orientations (spanning 0 to 18.1°k), and one Pstll fragment (spanning 97.4 to 1000/0). These cloned fragments, along with two other plasmids previously constructed carrying internal EcoRI fragments (spanning 20.6 to 90.5%), were then used to construct a detailed physical restriction map using the twelve restriction endonucleases, as well as to estimate the size of the genome for BAV2(32.5 Kbp). The DNA sequences of the early region 1 (E1) and hexon-associated gene (protein IX) have also been determined. The amino acid sequences of four open reading frames (ORFs) have been compared to those of the E1 proteins and protein IX from other Ads.

UNDERSTANDING THE RELATIONSHIP BETWEEN ONCOLYTIC AD5 DELETED E1b55KDA LYTIC INFECTION AND P53 IN MAMMALIAN CELLS

Adenoviruses are the most commonly used in the development of oncolytic therapy. Oncolytic adenoviruses are genetically modified to selectivity replicate in and kill tumor cells. The p53 molecule is a tumor suppressor protein that responds to viral infection through the activation of apoptosis, which is inhibited by adenovirus E1B55kDa protein leading to progressive viral lytic cycle. The non-specificity of replication has limited the use of wild type adenovirus in cancer therapy. This issue was resolved by using an E1b deleted Ad that can only replicate in cells with a deficiency in the p53 protein, a common feature of most cancer cells. Although demonstrating a moderate success rate, E1b55kDa deleted Ad has not been approved as a standard therapy for all cancer types. Several studies have revealed that E1b deleted Ad replication was independent of p53 status in the cell, as the virus replicated better in some p53 deficient cancers more than others. However, this mechanism has not been investigated deeply. Therefore, the objective of this study is to understand the relationship between p53 status, levels and functional activity, and oncolytic Ad5dlE1b55kDa replication efficiency. Firstly, five transient p53 expression vectors that contain different regulatory elements were engineered and then evaluated in H1299, HEK293 and HeLa cell lines. Data indicated that vector that contains the MARs and HPRE regulatory elements achieved the highest stability of p53 expression. Secondly, we used these vectors to examine the effect of various p53 expression levels on the replication efficiency of oncolytic Ad5dlE1b55kDa. We found that the level of p53 in the cell had an insignificant effect on the oncolytic viruses’ replication. However, the functional activity of p53 had a significant effect on its replication, as Ad5dlE1b55kDa was shown to have selective activity in H1299 cells (p53-null). In contrast, a decrease in viral replication was found in HeLa cells (p53-positive). Finally, the effect of p53’s functional activity on the replication efficiency of oncolytic Ad5dlE1b55kDa was examined. Viral growth was evaluated in H1299 cells expressing number of p53 mutants. P53-R175H mutant successfully rescued viral growth by allowing the virus to exert its mechanism of selectivity. The mechanism entailed deregulating the expression of specific genes, cell cycle and apoptosis, in the p53 pathway to promote its production leading to efficient oncolytic effect. These results confirmed that oncolytic Ad5dlE1b55kDa sensitivity is mutation-type specific. Therefore, before it is applied clinically as cancer therapy for p53 deficient tumors, the type of p53 mutation must be determined for efficient antitumor effect.

CD40-stimulated B Lymphocytes Pulsed with Tumor Antigens Are Effective Antigen-presenting Cells That Can Generate Specific T Cells

Although they are considered as antigen presenting cells (APC), the role of antigen-unspecific B-lymphocytes in antigen presentation and T lymphocyte stimulation remains controversial. In this paper, we tested the capacity of normal human peripheral activated B cells to stimulate T cells using melanoma antigens or melanoma cell lysates. B lymphocytes activated through CD40 ligation and then pulsed with tumor antigens efficiently processed and presented MHC class II restricted peptides to specific CD4+ T cell clones. This suggests that CD40-activated B cells have the functional and molecular competence to present MHC class II epitopes when pulsed with exogenous antigens, thereby making them a relevant source of APC to generate T cells. To test this hypothesis, CD40-activated B cells were pulsed with a lysate prepared from melanoma cells and used to stimulate peripheral autologous T cells. Interestingly, T cells specific to melanoma antigens were generated. Further analysis of these T cell clones revealed that they recognized MHC class II restricted epitopes from tyrosinase, a known melanoma tumor antigen. The efficient antigen presentation by antigen-unspecific activated B cells was correlated with a down-regulation in the expression of HLA-DO, a B cell specific protein known to interfere with HLA-DM function. Because HLA-DM is important in MHC class II peptide loading, the observed decrease in HLA-DO may partially explain the enhanced antigen presentation following B-cell activation. Results globally suggest that when they are properly activated, antigen-unspecific B-lymphocytes can present exogenous antigens by MHC class II molecules and stimulate peripheral antigen-specific T cells. Antigen presentation by activated B cells could be exploited for immunotherapy by allowing the in vitro generation of T cells specific against antigens expressed by tumors or viruses.

Contribution of the C-terminal tri-lysine regions of human immunodeficiency virus type 1 integrase for efficient reverse transcription and viral DNA nuclear import

Affiliation: Zhujun Ao, Éric Cohen & Xiaojian Yao : Département de microbiologie et immunologie, Faculté de Médecine, Université de Montréal

Computer "Insecurity" and Viral Attacks : Liability Issues Regarding Unsafe Computer Systems Under Quebec Law

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Mécanismes de défense immunitaire innée impliqués dans l’hépatite aiguë induite par le virus de l’hépatite murine de type 3

Le virus de l’hépatite murine de type 3 (MHV3) est un excellent modèle animal pour l’étude des différents désordres immunologiques lors d’infections virales. L’hépatite aiguë fulminante induite par ce virus chez la souris susceptible C57BL/6 se caractérise par la présence de plusieurs foyers nécrotiques et inflammatoires dans le foie associée à une immunodéficience en lymphocytes B et T, tuant les souris entre 3 et 5 jours post-infection. L’évolution rapide de cette maladie virale suggère un débalancement dans les mécanismes de l’immunité naturelle sous le contrôle des cellules NK et NK-T et un bris de l’équilibre entre la tolérance hépatique et la réponse inflammatoire. Afin d’élucider les rôles respectifs des différents mécanismes de la défense innée impliqués dans le développement de l’hépatite aiguë, des infections in vivo ont été réalisées chez des souris C57BL/6 avec la souche pathogène L2-MHV3 ou avec des variants du virus MHV3. Ces derniers possèdent des tropismes différents pour les cellules endothéliales sinusoïdales hépatiques et les cellules de Kupffer, tels que les virus faiblement atténué 51.6-MHV3, fortement atténué CL12-MHV3 et non pathogène YAC-MHV3. Ces études in vivo ont montré une diminution des cellules NK spléniques et myéloïdes suite à une infection avec le virus MHV3. Cette chute en cellules NK spléniques reflète un recrutement de ces cellules au niveau du foie. Par contre, les cellules NK se sont avérées permissives à la réplication virale entraînant un processus d’apoptose suite à la formation de syncétia induits par le virus. Les niveaux de recrutement et d’apoptose des cellules NK et NK-T dans le foie reflètent la pathogénicité des variants MHV3 durant les trois premiers jours de l’infection virale bien que les cellules NK recrutées au niveau du foie maintiennent leur activité cytotoxique. L’ajout des IL-12 et IL-18, qui sont normalement diminués lors de l’hépatite aiguë, provoque une production synergique d’IFN-g par les cellules NK, résultant d’une interaction entre l’activation de la voie p38 MAPK et la réplication virale. Par ailleurs, le récepteur viral CEACAM1a (carcinoembryonic antigen cell adhesion molecule 1a) serait essentiel à cette synergie, mais exercerait aussi une action inhibitrice dans la production de l’IFN-g. D’autre part, les niveaux de production des cytokines immunosuppressives IL-10, TGF-b et PGE2, impliquées dans la tolérance hépatique et particulièrement produites par les cellules de Kupffer et les cellules endothéliales sinusoïdales, sont en relation inverse avec le degré de pathogénicité des variants du virus MHV3. Finalement, le virus pathogène L2-MHV3 déclenche la production de cytokines inflammatoires par les macrophages, tels que l’IL-6 et le TNF-a. L’induction de ces cytokines par les macrophages serait indépendante de la présence de la molécule CEACAM1a. Cette stimulation est plutôt reliée à la fixation des particules virales sur des récepteurs TLR2, en association avec les régions riches en héparanes sulfates. Tous ces résultats mettent en évidence de nouveaux mécanismes par lesquels le virus MHV3 peut diminuer l’efficacité des mécanismes de l’immunité naturelle sous le contrôle des cellules NK et NK-T intrahépatiques, suite à une stimulation de l’inflammation résultant du bris de la tolérance hépatique.

La protéine majeure de la capside de l’HSV-1 est ubiquitinée

Le virus de l’Herpès simplex de type 1 (HSV-1) est le pathogène humain responsable des lésions herpétiques labiales, plus communément appelé « feux sauvages ». Annuellement, il est responsable de plusieurs cas d’encéphalites et d’infections de l’appareil visuel qui sont la principale cause de cécité en Amérique du Nord. Bien qu’il existe quelques traitements antiviraux, aucun vaccin ou médicament ne permet de prévenir ou de guérir les infections causées par ce virus. Aujourd’hui, les infections produites par l’HSV-1 sont présentes partout sur la planète. Récemment, une étude en protéomique effectuée sur les virus matures extracellulaires a permis d’identifier la présence d’ubiquitines libres et d’enzymes reliées à la machinerie d’ubiquitination dans le virus. De plus, le virus exploite cette machinerie au cours de l’infection. Il est connu que certaines protéines virales sont ubiquitinées durant une infection et que le virus imite même certaines enzymes d’ubiquitination. Nous avons donc entrepris des recherches afin d’identifier des protéines virales ubiquitinées qui pourraient être présentes dans les virus matures ainsi que leurs rôles potentiels. La protéine majeure de la capside, VP5, un constituant très important du virus, a été identifiée. Nos recherches nous ont permis de caractériser le type d’ubiquitination, une monoubiquitination sur les lysines K810 et/ou K1275 de VP5. Le rôle que pourrait jouer l’ubiquitination de VP5 dans le cycle de réplication virale et dans les virus matures n’est toutefois pas encore connu.

Effet de l'initiation du traitement antirétroviral sur la diversité virale du VIH

L’épidémie du VIH-1 dure maintenant depuis plus de 25 ans. La grande diversité génétique de ce virus est un obstacle majeur en vue de l’éradication de cette pandémie. Au cours des années, le VIH-1 a évolué en plus de cinquante sous-types ou formes recombinantes. Cette diversité génétique est influencée par diverses pressions de sélection, incluant les pressions du système immunitaire de l’hôte et les agents antirétroviraux (ARV). En effet, bien que les ARV aient considérablement réduit les taux de morbidité et de mortalité, en plus d’améliorer la qualité et l’espérance de vie des personnes atteintes du VIH-1, ces traitements sont complexes, dispendieux et amènent leur lot de toxicité pouvant mener à des concentrations plasmatiques sous-optimales pour contrôler la réplication virale. Ceci va permettre l’émergence de variantes virales portant des mutations de résistance aux ARV. Ce phénomène est encore plus complexe lorsque l’on prend en considération l’immense diversité génétique des différents sous-types. De plus, le virus du VIH est capable de persister sous forme latente dans diverses populations cellulaires, rendant ainsi son éradication extrêmement difficile. Des stratégies pouvant restreindre la diversité virale ont donc été préconisées dans le but de favoriser les réponses immunes de l’hôte pour le contrôle de l’infection et d’identifier des variantes virales offrant une meilleure cible pour des stratégies vaccinales ou immunothérapeutiques. Dans cet esprit, nous avons donc étudié, chez des sujets infectés récemment par le VIH-1, l’effet du traitement ARV précoce sur la diversité virale de la région C2V5 du gène enveloppe ainsi que sur la taille des réservoirs. En deuxième lieu, nous avons caractérisé la pression de sélection des ARV sur des souches virales de sous types variés non-B, chez des patients du Mali et du Burkina Faso afin d’évaluer les voies d’échappement viral dans un fond génétique différent du sous-type B largement prévalent en Amérique du Nord. Notre étude a démontré la présence d’une population virale très homogène et peu diversifiée dans les premières semaines suivant l’infection, qui évolue pour atteindre une diversification de +0,23% à la fin de la première année. Cette diversification est plus importante chez les sujets n’ayant pas initié de traitement. De plus, ceci s’accompagne d’un plus grand nombre de particules virales infectieuses dans les réservoirs viraux des cellules mononucléées du sang périphérique (PBMC) chez ces sujets. Ces résultats suggèrent que l’initiation précoce du traitement pourrait avoir un effet bénéfique en retardant l’évolution virale ainsi que la taille des réservoirs, ce qui pourrait supporter une réponse immune mieux ciblée et potentiellement des stratégies immunothérapeutiques permettant d’éradiquer le virus. Nous avons également suivi 801 sujets infectés par des sous-types non-B sur le point de débuter un traitement antirétroviral. Bien que la majorité des sujets ait été à un stade avancé de la maladie, plus de 75% des individus ont obtenu une charge virale indétectable après 6 mois d’ARV, témoignant de l’efficacité comparable des ARV sur les sous-types non-B et B. Toutefois, contrairement aux virus de sous-type B, nous avons observé différentes voies moléculaires de résistance chez les sous type non-B, particulièrement chez les sous-types AGK/AK/K pour lesquels les voies de résistances étaient associées de façon prédominante aux TAM2. De plus, bien que la divergence entre les virus retrouvés chez les patients d’une même région soit faible, nos analyses phylogénétiques ont permis de conclure que ces mutations de résistance se sont produites de novo et non à partir d’un ancêtre commun porteur de résistance. Cependant, notre dernière étude au Mali nous a permis d’évaluer la résistance primaire à près de 10% et des études phylogénétiques seront effectuées afin d’évaluer la circulation de ces souches résistantes dans la population. Ces études suggèrent qu’un contrôle de la réplication virale par les ARV peut freiner la diversité du VIH et ainsi ouvrir la voie à un contrôle immunologique ciblé, utilisant de nouvelles stratégies vaccinales ou immunothérapeutiques. Toutefois, une thérapie antirétrovirale sous-optimale (adhérence, toxicité) peut conduire à l’échappement virologique en favorisant l’émergence et la dissémination de souches résistantes.

Mécanisme de leucémogénèse par les oncogènes SCL et LMO1

La leucémie lymphoïde représente 30% de tous les cancers chez l’enfant. SCL (« Stem cell leukemia ») et LMO1/2 (« LIM only protein ») sont les oncogènes les plus fréquemment activés dans les leucémies aiguës des cellules T chez l'enfant (T-ALL). L’expression ectopique de ces deux oncoprotéines dans le thymus de souris transgéniques induit un blocage de la différenciation des cellules T suivie d’une leucémie agressive qui reproduit la maladie humaine. Afin de définir les voies génétiques qui collaborent avec ces oncogènes pour induire des leucémies T-ALL, nous avons utilisé plusieurs approches. Par une approche de gène candidat, nous avons premièrement identifié le pTalpha, un gène crucial pour la différenciation des cellules T, comme cible directe des hétérodimères E2AHEB dans les thymocytes immatures. De plus, nous avons montré que pendant la différenciation normale des thymocytes, SCL inhibe la fonction E2A et HEB et qu’un dosage entre les protéines E2A, HEB et SCL détermine l’expression du pTalpha. Deuxièmement, par l’utilisation d’une approche globale et fonctionnelle, nous avons identifié de nouveaux gènes cibles des facteurs de transcription E2A et HEB et montré que SCL et LMO1 affectent la différenciation thymocytaire au stade préleucémique en inhibant globalement l’activité transcriptionnelle des protéines E par un mécanisme dépendant de la liaison à l’ADN. De plus, nous avons découvert que les oncogènes SCL et LMO1 sont soit incapables d’inhiber totalement l’activité suppresseur de tumeur des protéines E ou agissent par une voie d’induction de la leucémie différente de la perte de fonction des protéines E. Troisièmement, nous avons trouvé que Notch1, un gène retrouvé activé dans la majorité des leucémies T-ALL chez l’enfant, opère dans la même voie génétique que le pré-TCR pour collaborer avec les oncogènes SCL et LMO1 lors du processus de leucémogénèse. De plus, cette collaboration entre des facteurs de transcription oncogéniques et des voies de signalisation normales et importantes pour la détermination de la destinée cellulaire pourraient expliquer la transformation spécifique à un type cellulaire. Quatrièmement, nous avons trouvé que les oncogènes SCL et LMO1 sont des inducteurs de sénescence au stade préleucémique. De plus, la délétion du locus INK4A/ARF, un évènement retrouvé dans la majorité des leucémies pédiatriques T-ALL associées avec une activation de SCL, collabore aves les oncogènes SCL et LMO1 dans l’induction de la leucémie. Cette collaboration entre la perte de régulateurs de la sénescence suggère qu’un contournement de la réponse de sénescence pourrait être nécessaire à la transformation. Finalement, nous avons aussi montré que l’interaction directe entre les protéines SCL et LMO1 est critique pour l’induction de la leucémie. Ces études ont donc permis d’identifier des évènements collaborateurs, ainsi que des propriétés cellulaires affectées par les oncogènes associés avec la leucémie et de façon plus générale dans le développement du cancer.