Lentivirus-mediated gene expression in corneal endothelium

Parker, Douglas George Anthony, park0290@flinders.edu.au

January 2008

Modulation of corneal transplant rejection using gene therapy shows promise in experimental models but the most appropriate vector for gene transfer is yet to be determined. The overarching aim of the thesis was to evaluate the potential of a lentiviral vector for use in human corneal transplantation. Specific aims were: (i) to assess the ability of an HIV-1-based lentiviral vector to mediate expression of the enhanced yellow fluorescent protein (eYFP), and a model secreted protein interleukin-10 (IL10), in ovine and human corneal endothelium; and (ii) to examine the influence of lentivirus-mediated IL10 expression on the survival of ovine corneal allografts. Four lentiviral vectors expressing eYFP under the control of different promoters, were tested: the simian virus type-40 (SV40) early promoter, the phosphoglycerate kinase (PGK) promoter, the elongation factor-1alpha (EF) promoter, and the cytomegalovirus (CMV) promoter. Two lentiviral vectors expressing IL10 were tested: one containing the SV40 promoter and another containing a steroid-inducible promoter (GRE5). Lentivirus-mediated expression in transduced ovine and human corneal endothelium was assessed by fluorescence microscopy, real-time quantitative RT-PCR and ELISA, following alterations of transduction period duration (2–24 hr) and vector dose, as well as in the presence or absence of polybrene or dexamethasone (GRE5 vector). It was also compared to expression mediated by adenoviral vectors. Orthotopic transplantation of ex vivo transduced donor corneas was performed in outbred sheep. Allografts were reviewed daily for vascularisation and signs of immunological rejection. Lentivirus-mediated eYFP expression was delayed in ovine corneal endothelium compared to human. However, in both species the final transduction rate was greater than 80% and expression was stable for at least 14 d in vitro. Lentivirus-mediated expression in ovine and human corneal endothelium was higher with the viral promoters in comparison to the mammalian promoters. A 24 h transduction of ovine corneal endothelium with the lentiviral vector encoding IL10 resulted in expression levels which were increasing after 15 d of organ culture but logarithmically lower than those achieved by adenovirus. Shortening the lentiviral transduction period to 2 h led to a reduction in expression, but the addition of polybrene (40 micrograms / ml) to the transduction mixture restored expression to levels comparable to those attained after a 24 h transduction period. Lentivirus-mediated IL10 expression was higher and more rapid in human corneal endothelium compared to ovine corneas. Dexamethasone-responsive transgene expression was observed in both ovine and human corneal endothelium using the lentiviral vector containing the GRE5 promoter. Lentivirus-mediated expression in ovine corneal endothelium was stable for 28 d in vivo. A modest prolongation of ovine corneal allograft survival (median of 7 d) was achieved by transduction of donor corneas for 2–3 h with the lentivirus expressing IL10. Attempts to increase the expression of IL10 by the addition of polybrene (40 micrograms / ml) to the transduction mixture, resulted in a toxic effect on corneal allografts which abrogated the beneficial effect of IL10. The lentiviral vector shows potential for the stable expression of therapeutic transgenes in human corneal transplantation. However, the mechanisms underlying the species-specific differences in HIV-1-mediated transgene expression will need to be elucidated and overcome if the ovine preclinical model is to provide justification for a clinical trial.

corneal transplantation

corneal endothelium

lentiviral vector

Etude de l'étape d'entrée des vecteurs lentiviraux dérivés du VIH-1 dans les cellules hématopoïétiques humaines / Study of the entry step of HIV-1-derived lentiviral vectors into human hematopoietic cells

Ingrao, Dina

29 November 2013

Les vecteurs lentiviraux (LV) sont des outils efficaces de transfert de gène, largement utilisés en thérapie génique, en particulier pour la transduction ex vivo de cellules souches et progénitrices hématopoïétiques (CSPH). Afin d’étudier simultanément la fusion et la transduction dans les CSPH avec les LV, nous avons adapté une méthode basée sur latechnologie du transfert d’énergie entre deux molécules fluorescentes (FRET). Pour mettre en place cette technique, des LV capables d’incorporer spécifiquement une enzyme, la bétalactamase (BLAM-LV) et de coder une forme tronquée du récepteur au facteur de croissance nerveuse (DELTA-NGFR), sont produits. Nos résultats montrent que les LV sont soumis à une restriction post-entrée forte dans les cellules hématopoïétiques, que ce soit dans des lymphocytes T immortalisés ou bien des CSH CD34+. Nous montrons également que cette inhibition post-entrée peut être partiellement saturée après une forte augmentation de la multiplicité d’infection ou en présence d’additifs de culture, comme la Vectofusin-1® ou laRetronectin®. De plus, nous avons montré lors de la transduction de CSPH avec des vecteurs BLAM-LV que la Vectofusin-1® agit sur l’étape d’entrée en augmentant l’adhésion et la fusion entre les membranes virale et cellulaire. Cette technique représente donc un nouvel outil sensible et efficace pour étudier de façon concomitante l’étape de fusion et le niveau de transduction dans les cellules cibles. A terme, ce travail permettra une meilleure compréhension de la biologie des LV mais pourra également conduire à l’élaboration de protocoles de transduction lentivirale plus efficaces. / Lentiviral vectors (LV) are used for various gene transfer applications, notably for hematopoietic gene therapy, but methods are lacking to precisely evaluate parameters that control the efficiency of transduction in relation with the entry of vectors into target cells. We adapted a fluorescence resonance energy transfer (FRET)-based HIV-1 fusion assay to measure the entry of non-replicative recombinant LV in various cell types, including primary human hematopoietic stem and progenitor cells, and to quantify the level of transduction of he same initially-infected cells. The assay utilizes recombinant LV containing betalactamase (BLAM)-Vpr chimeric proteins (BLAM-LV) and encoding a truncated form of thelow affinity nerve growth factor receptor (DELTA-NGFR). This LV-based fusion/transduction assay is a dynamic and versatile tool, revealing for instance the extent of lentiviral post-entry restrictions occuring in cells of hematopoietic origin. The assay also shows that transduction enhancers like Vectofusin®-1 or Retronectin® can partially relieve this post-entry block but their effects differ in the way to promote LV entry. Furthermore, our results show that Vectofusin®-1 acts at the entry step by promoting the adhesion and the fusion between lentiviral and cellular membranes. In conclusion, one such assay should be useful to study hematopoietic post-entry restrictions directed against LV and should allow improvements in various LV-based gene therapy protocols.

Vecteur lentiviral

Lentiviral vector

Hematopoietic cell

Gene therapy

Targeting and repair of adult testicular somatic cells through viral gene therapy

Darbey, Annalucia Leigh

January 2018

Androgens are essential for the maintenance of male health and wellbeing. A disturbance in androgen signalling has been associated with a number of clinically relevant disorders such as cardiovascular disease, diabetes and metabolic disorders as well as infertility. Primarily produced in the testis in males, the actions of androgens are mediated through binding to androgen receptor (AR), a member of the nuclear receptor superfamily of ligand-activated transcription factors. The somatic cells of the testis are known to have a number of key roles in both testis function and development and the Sertoli, Leydig and Peritubular Myoid cells are known to express AR in adulthood. It is through AR that some testicular functions are mediated; for example, the Sertoli cells support of complete spermatogenesis with Sertoli cell androgen receptor knockout (SCARKO) testis demonstrating a halt of spermatogenesis before meiosis. However, how androgen signalling is impacting testicular function through each of the somatic cell types is not yet fully understood. Currently, treatments for male reproductive disorders such as hypogonadism (low androgens) and infertility are limited to treatment of the symptoms; using androgen replacement therapy and in vitro fertilisation techniques. This has been, up until recently, a result of a lack of understanding of the causes of these conditions and a lack of resources able to treat them, with research suggesting that a genetic component may be responsible in a number of cases. However, due to the limited genetic investigation diagnosis of men with male reproductive disorders, the wider understanding of the genetics underpinning male hypogonadism and infertility is incomplete. Developments in technology for the investigation and editing of the genetic code are triggering a surge in the exploration of genetic disorders and, in parallel, into the fields of gene delivery vectors and editing technologies. These technologies will allow an expansion into the knowledge and understanding of genetic disorders whilst simultaneously affording the opportunity to exploit this understanding for the development of therapeutics. There have been a small handful of previous studies using technologies such as viral vectors to target the testicular somatic cells and deliver exogenous transgenes with the purpose of both gene editing and repair, all with varying degrees of success. Here, techniques to introduce and target the Leydig and Sertoli cells were investigated to determine the most appropriate methodology for gene delivery to and manipulation of the testis. Refinement of injections into the interstitial compartment were carried out before introducing lentiviral vectors and targeting of Leydig cells was validated and optimised. Lentiviral vectors are able to permanently integrate into the host cell. Surprisingly, analysis of testis post lentiviral injection determined that the lentiviral targeted Leydig cells began to undergo apoptosis one week post injection and were subsequently cleared from the testis after ten days. Contrastingly, this was not the case when adenoviral vectors were introduced into the interstitial compartment, with Leydig cells continuing to express the delivered reporter transgene and, importantly, not expressing markers of apoptosis, ten days post injection. This would suggest that using adenoviral vectors to target the Leydig cell population in the adult testis would be more appropriate than using lentiviral vectors. Previous studies have successfully used lentiviral vectors to target the Sertoli cells in the adult testis via the introduction of the particles through the efferent duct. However, this can result in damage to efferent duct, resulting in blockages and subsequently the seminiferous tubules. To circumvent this, introduction of the lentiviral particles through the rete compartment of the testis at a range of lower injection pressures was examined and injecting at a lower pressure through the rete testis was found to reduce the likelihood of introducing negative impacts on testicular histology when targeting the seminiferous tubules. Using these refined methods of introducing lentiviral vectors, targeted Sertoli cells stably expressed the delivered transgene for up to one year post injection. Using viral vector delivered transgenes for both the investigation of testicular genetic disorders and for the development of therapeutics has great potential. To explore this potential, we first generated a mouse model in which AR was ablated from both the Leydig and Sertoli cells using Cre/LoxP technology, termed the SC-LC-ARKO. Alongside providing a potential model to 'repair' with viral vectors, the SC-LC-ARKO model also provided an additional model for comparison with other models exhibiting ablation of AR from both single somatic cell types and double somatic cell types. This further enabled a characterisation of the roles of AR in adult testicular function, with results suggesting that loss of AR from more than one cell type results in an additive phenotype when compared to single cell knock outs. Despite providing further insight into the roles of AR in the testis, further analysis of the Cre line used to generate the SC-LC-ARKO model indicated that a small number of Leydig cells were expressing the Cre recombinase, resulting in only a small population of Leydig cells with ablated AR. Considering this, to explore the potential of rescuing Sertoli cell AR using lentiviral vectors, we then utilised an already well characterised Sertoli Cell AR knockout (SCARKO) model. Lentiviral vectors expressing mouse AR and monomeric GFP (moeGFP) downstream of a CMV promoter were generated and injected into the rete testis of WT and SCARKO adult (day 100) males at low pressure. The contralateral testis was injected with a lentiviral vector expressing moeGFP alone (also downstream of a CMV promoter) using the same technique. Analysis of testis sections revealed a reintroduction of AR to Sertoli cells in 100% of SCARKO testis injected with lentivirus expressing mouse AR. As a result of this re-expression of AR in Sertoli cells, 66% of the testis injected with lentivirus expressing mouse AR had evidence of morphologically mature elongated spermatids, indicative of ongoing spermatogenesis. These results suggest that a rescue of the infertility phenotype reported in previous studies of SCARKO testis. Also demonstrated is the reversal of the SCARKO testicular phenotype in tubules targeted by the mAR expressing lentiviral vector. This suggests that absence Sertoli cell AR throughout development does not have a permanent impact on the Sertoli cells capacity to support spermatogenesis in adulthood following rescue of SC AR expression in adulthood. In summary, the results of these studies have provided a refinement in the methodologies for targeting the Sertoli and Leydig cells of the adult testis with viral vectors as well as demonstrating successful rescue of a previously reported mouse model exhibiting infertility through reintroduction of a functional gene. Alongside this, comparisons of AR knockout models have afforded insight into maintenance of testis function through AR.

Improving lentiviral vector-mediated gene transfer by understanding cellular barriers

Oakland, Mayumi

01 May 2013

Cystic fibrosis (CF) is an autosomal recessive genetic disorder of which lung disease is the leading cause of morbidity and mortality. One attractive strategy for the treatment of CF lung disease is to directly deliver CF transmembrane conductance regulator gene to airway epithelia. Although promising results have been reported, barriers present in the lung make successful gene transfer to the respiratory tract difficult. In order to improve gene transfer strategies in the intrapulmonary airways, we need to identify the bottlenecks of transduction for the vector system. A previous study reported that feline immunodeficiency virus (FIV)-mediated gene transfer was more efficient in the nasal airways in mice than the intrapulmonary airways (Sinn, P.L. et al. 2008, J. Viol). Our first goal was to identify barriers to lentiviral gene transfer in the murine airways. We demonstrate that host immune response is not the major barrier preventing efficient FIV-mediated transduction in the intrapulmonary airways. We show that the FIV vector transduces murine primary nasal epithelial cell cultures with greater efficiency than murine primary tracheal epithelial cell cultures. In addition, GP64 pseudotyped vesicular stomatitis virus (VSV) transduces better in nasal epithelia compared to intrapulmonary airways in mice. On the other hand, we observed that VSVG glycoprotein-pseudotyped VSV transduces the intrapulmonary airway as well as nasal epithelia in mice with similar efficiency. Our results suggest that differentially expressed cellular factor(s) specific for GP64 or FIV vector may be the major barrier(s) for FIV vector-mediated gene transfer in the murine intrapulmonary airways. The recent development of CF porcine models prompted us to investigate possible barriers for lentiviral vector-mediated gene transfer in porcine cells. Our preliminary results showed that HIV transduction was restricted in porcine but not human lung-derived cell lines. Porcine TRIM5 has sequences similar to restrictive bovine TRIM5 orthologs. Therefore, our second goal was to investigate the possible restriction of lentiviral vectors by porcine TRIM5. We demonstrate that transient overexpression or knockdown of endogenously expressed porcine TRIM5 does not affect HIV or FIV transduction. Lastly, we characterized a mucin domain-deleted EBOV (EBOVΔO) glycoprotein mutant with increased transduction. This EBOVΔO 5-mer mutant was generated based on mutants with an increased transduction as identified by alanine scanning mutagenesis (Brindlay, M.A. et al. 2007. J. Viol). We show that VSV pseudotyped with the 5-mer mutant increased transduction both in vitro and in mice when compared to the wild-type EBOVΔO. Structural analysis demonstrated that 5 mutations were located proximal to the GP1-GP2 interface. Enhanced transduction likely results from a lower energy metastable state of the glycoprotein. FIV pseudotyped with 5-mer also shows increased transduction in multiple cell lines. Identification of barriers in intrapulmonary airways and improvements of vector systems will help the advancement of gene therapy for CF.

Ebola virus

FIV

Gene therapy

lentiviral vector

TRIM5alpha

Microbiology

Optimization of Lentivirus Production for Cancer Therapy

Camacho, Emely

January 2011

Vectors based on lentivirus backbones have revolutionized our ability to transfer genesinto many cell types. Lentiviral vectors integrate into the chromatin of target cells and do not transfer any viral genes causing vector replication. Both of these features arecommonly used in gene therapy and have been used clinically in individuals sufferingfrom cancer, infections and genetic diseases. It has been discovered that T-cells can be genetically modified to be used as effective weapons against cancer: therefore virus mustbe produced to deliver the gene of interest into the T-cells. In this project, lentiviralvectors have been produced to transfer the gene coding for a chimeric antigen receptor(CAR) which is directed to CD19 on B-cells. The vectors will, hence, be used to generateCD19 retargeted T-cells in purpose to kill CD19 cells such as B-cell lymphoma andleukemia. We have evaluated two production protocols to determine a feasible method toculture these vectors. We have also stimulate T-cells with two different antibodies (anti-CD3 and anti-CD28) and transduced T-cells. Our results demonstrate that theconcentration of virus was higher after prolonged incubation in 4˚C, which can not beexplained. The stimulation demonstrated that bound anti-CD3 was the best stimulator,and moreover the FACS-analysis showed that addition of anti-CD28 gave a highertransduction level. In conclusion, the viral vectors may be kept in 4˚C for two days beforeconcentrating the virus, and bound anti-CD3 is a better choice than soluble anti-CD3 forstimulation of T-cells.

Lentiviral vector

gene therapy

293T cell

transfection

chimeric antigen

Étude de l'implication potentielle des marqueurs du striatum dans la maladie de Huntington / Study of potential involvement of striatal markers in Huntington's disease

Galvan, Laurie

15 June 2011

La maladie de Huntington (MH) est une maladie neurodégénérative héréditaire, incurable.Elle est due à une mutation dans le gène HD codant l'huntingtine (htt). Cette mutation setraduit dans la protéine par une augmentation de l'expansion polyglutamine (polyGln) qui larend toxique. Bien que la htt soit ubiquitaire dans le système nerveux central, ladégénérescence touche préférentiellement le striatum. Un patron d'expression de gènesspécifiques du striatum pourrait expliquer cette vulnérabilité préférentielle. Nous avons étudiéles effets "modificateurs" de 5 gènes préférentiellement exprimés dans le striatum vis-à-visde la toxicité de la htt mutée par une approche lentivirale chez la souris. Nous avonscaractérisé les effets de ces marqueurs striataux sur la toxicité induite par la htt mutée pardifférentes approches histologiques. Les "modificateurs" de la MH ont été étudiés plus endétail. Nous avons examiné leur localisation et les mécanismes sous-jacents à leurs effetsneuroprotecteurs. Outre une meilleure compréhension du striatum, cette étude a permis ladécouverte de candidat neuroprotecteur qui pourrait permettre de développer de nouvellesthérapies. / Huntington's disease (HD) is an incurable inherited neurodegenerative disease. HD iscaused by a mutation in the HD gene coding huntingtin (htt). This mutation leads to anexpanded polyglutamine tract (polyQ) in the protein which is toxic to neurons. Although thehtt is ubiquitously expressed in the central nervous system, the first area which degeneratesis the striatum. A pattern of genes selectively expressed into the striatum may confer itsvulnerability to mutated htt. We have studied the modifying effects of five newly identifiedstriatal markers against the toxicity induced by mutated htt using lentiviral strategy in miceand histological approaches. For one of these markers, Double Cortin Kinase Like 3(DCLK3), we have further determined their cellular localization and the potential mechanismsunderlying their neuroprotector effects. The present work led to a better understanding of thefunction of the newly identified markers in the striatum and their potential roles in thepreferential vulnerability of the striatum in HD.

Maladie de Huntington

Striatum

Neuroprotection

Vecteur lentiviral

Huntington's disease

Striatum

Neuroprotection

Lentiviral vector

Enhancement of lentiviral vector production through alteration of virus-cell interactions

Gelinas, Jean-Francois

January 2016

Gene therapy is the introduction or alteration of genetic material with the intention to treat disease. To support this aim, viruses have been modified, with elements linked to viral pathogenicity removed from their genome and replaced by the genetic material to be delivered. Gene therapy vectors based on lentiviruses have many advantages, such as the ability to transduce non-dividing cells and to target specific cell types via pseudotyping. They have been successfully used in ex vivo clinical trials for several haematopoietic stem cell disorders. Lentiviral vectors, however, suffer from substantially lower titres than the more popular adeno-associated virus (AAV)-based vectors and therefore have limited applicability for in vivo gene therapy which requires much greater quantities of virus. The main aim of this thesis was to investigate strategies to improve lentiviral vector productivity during manufacture, in order to increase the likelihood of lentiviruses being adopted for disease treatment. Initial experiments were based on the lentiviral vector manufacturing process currently being developed by the United Kingdom Cystic Fibrosis Gene Therapy Consortium for the generation of highly concentrated, purified lentivirus for clinical use. Supplementation of FreeStyle 293 Expression Medium used during upstream processing was attempted, but none of the assessed supplements led to significant increases in lentiviral vector production. Investigation into intrinsic immunity to viral infection indicated that over-expression of the protein kinase RNA-activated (PKR) led to lower production titres, but over-expression of its inhibitors was not successful at increasing titres. The focus then shifted to reducing, or 'knocking-down', inhibitory factors present in the host cells, which could adversely affect viral titres. Investigation of the published HIV-1 literature revealed a possible 152 candidate inhibitory factors described as having a negative impact on HIV-1 replication in the late stages of the life cycle of the virus. A novel siRNA screen was developed to assess the effect of ‘knock-down' of inhibitory factors on lentiviral vector titre. Application of the screen to 89 candidate inhibitory factors identified nine genes which, when knocked-down, resulted in increased lentiviral vector production by more than 40%. Further work will be necessary to understand the role of the inhibitory factors in lentiviral vector production, but novel cell lines in which genes encoding these factors have been permanently deleted from producer cells could lead to higher titres, reducing costs in the manufacture of lentiviral vectors and making in vivo gene therapy more feasible from a health economics perspective.

Geração de animais transgênicos por inoculação de vetor viral em meio de cultura de óvulos

Ravache, Thaís Terpins, Simões, Renata, Goissis, Marcelo Demarchi

January 2014

Orientador: Prof. Dr. Marcelo Augusto Christoffolete / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Biotecnociência, 2014. / Desde o século XV, animais fazem parte da rotina na área da pesquisa, principalmente para estudos de doenças, e hoje em dia o modelo animal mais utilizado para estes estudos é o camundongo, tendo uma participação em mais de 90% das pesquisas em todo o mundo, sendo considerado como uma primeira via para definir funções de genes em mamíferos. Os camundongos são considerados os principais modelos nas técnicas de transgenia animal, porém estas técnicas ainda estão em desenvolvimento, uma vez que as metodologias hoje utilizadas para a geração de animais transgênicos ainda se encontram com uma taxa de sucesso considerada baixa e são dispendiosas, necessitando de muitas etapas. Uma das dificuldades é o contato com a membrana do óvulo devido a zona pelúcida, que é considerada uma barreira física. Vetores virais estão em evidência nas técnicas de transgenia animal, sendo o lentivírus o mais utilizado. Portanto, o objetivo deste projeto é estabelecer um protocolo para a integração de DNA exógeno em óvulos por infecção lentiviral, anteriormente a fertilização in vitro juntamente com a técnica de dissecção parcial da zona pelúcida. Como vetor foi utilizado um lentivírus com GFP em sua construção. Para ocorrer a fertilização in vitro, foram feitas coletas de óvulos em camundongos fêmeas da linhagem C57BL/6, tratadas com injeções hormonais, e coletas de espermatozoides em machos desta mesma linhagem. Os óvulos obtidos foram divididos em grupos controle e com dissecção parcial da zona pelúcida, e estes foram subdivididos em grupos com e sem infecção lentiviral. Entre os grupos houve variação de 20% a 56,25% de embriões em estágio de duas células, e em alguns grupos foi possível alcançar o estágio de blastocisto eclodido. Porém não foi possível visualizar a emissão de fluorescência para confirmar a infecção lentiviral. Em conclusão as metodologias utilizadas tanto para a fertilização in vitro como para a dissecção parcial da zona pelúcida foram de sucesso. Porém a integração do DNA exógeno mostrou resultados não conclusivos, necessitando de estudos futuros. / Since the XV century, animals are used routinely in research, mainly for diseases studies, and nowadays the most used animal model is the mouse, which one has more than 90% of participation in researches around the world and it is considered the first track to define gene function in mammals. Mouse is the main model in transgenic techniques, however the methods available to generate transgenic animals still have a considerable low rate, and also it is expensive, requiring many degrees. An ordinary issue is the contact with the membrane of oocyte due zona pellucida that is considered a physical barrier. In transgenic animals technique, it is in evidence the utilization of viral vectors, and the most used are the lentiviruses. Therefore, the objective of this project is to establish a protocol for the integration of exogenous DNA by lentiviral infection into oocytes, before the in vitro fertilization, using the technique of partial dissection of the zona pellucida. It was used as a vector a lentivirus with GFP in your construction. For in vitro fertilization, were collected oocytes from C57Bl/6 mice, treated with hormones, and sperm from males of the same strain. The obtained oocytes were divided in control group and partial dissection of the zona pellucida group, and then subdivided in groups with and without lentiviral infection. Between the groups, was achieved 20% to 56,25% of two cells stage embryo, and hatched blastocysts stage were obtained at some groups. Therefore it was not possible to visualize florescence emission to confirm the lentiviral infection. In conclusion we have a practicable protocol for in vitro fertilization and partial dissection of the zona pellucida, reaching blastocysts stages in two groups. However the integration of exogenous DNA results were inconclusive, requiring further studies.

CAMUNDONGO

TRANSGENIA ANIMAL

VETOR LENTIVIRAL

MOUSE

TRANSGENIC ANIMAL

LENTIVIRAL VECTOR

Immunité et protection induites par un lentivecteur ADN innovant chez les modèles animaux de vaccination VIH-1. / Immune responses and protection induced by a novel DNA lentivector vaccine in animal models of HIV-1 vaccine.

Moussa, Maha

30 October 2015

Nous avons récemment développé un prototype lentivecteur ADN non intégratif vaccinal contre VIH-1/SIDA que nous avons testé chez des modèles animaux. L'immunisation avec une dose unique de ce vaccin (CAL-SHIV-IN-) a permis la mise en place rapide de réponses immunes spécifiques contre tous les antigènes exprimés par le vaccin chez tous les animaux vaccinés. Les analyses longitudinales ont démontré la mise en place de réponses cellulaires et humorales spécifiques et persistantes sur une durée de plus de 74 semaines en absence de réintroduction d'antigènes chez tous les macaques vaccinés. La caractérisation de ces réponses a révélé la présence de cellules T CD4+ et CD8+ polyfonctionnelles composées de fractions de cellules effectrices mémoires à fonction immédiate (EM), de cellules centrales mémoires (CM) et de cellules précurseurs mémoires ayant une haute capacité de prolifération (PHPC). Ces réponses corrèlent, chez tous les macaques vaccinés (6/6), avec un contrôle du virus d'épreuve hautement hétérologue et pathogénique (SIVmac251) inoculé à petites doses répétées par la voie mucosale rectale. Cette protection est maintenue durant toute la période d'un an de suivi après l'infection avec une différence statistiquement significative de la charge virale plasmatique des groupes contrôles et vaccinés au moins jusqu'à 18 semaines post-infection. Par ailleurs, le contrôle du virus d'épreuve est maintenu plus de 10 mois (correspondant au temps d'arrêt de l'étude) après l'infection. Parmi les corrélats immunologiques de protection nous avons identifié la présence de cellules de type PHPC spécifiques des antigènes du vaccin et qui sont dotées d'une capacité importante de prolifération ex vivo en présence des signaux antigéniques et homéostatiques. Nous avons démontré que ces PHPC contiennent une fraction de cellules T souches mémoires « TSCM » spécifiques du vaccin. Ces TSCM récemment identifiées constitueraient un atout majeur en faveur de notre vecteur et notre stratégie vaccinale du fait de leur haute capacité d'auto-régénération/maintien en absence d'antigène et leur capacité à se différencier en d'autres cellules mémoires TCM et TEM. / We recently developed an innovative prototype non-integrative lentivector DNA vaccine against HIV-1 /AIDS that we tested in pilot studies using animal models of HIV vaccine. We found that a single immunization with our prototype vaccine (CAL-SHIV-IN-) allowed the implementation of potent humoral and cellular responses in all immunized macaques. In addition, both types of responses persisted over a period of 74 weeks post-immunization in absence of antigenic boost. The characterization of the above revealed that vaccine specific T cell responses included polyfunctional CD4+ and CD8+ T cells against all antigens expressed by the vaccine. Detailed phenotypic and functional examinations of these cells showed that they were composed of effector (EM) and central memory (CM) T cells. More importantly they also contained a fraction of precursor memory T cells with high proliferative capacity (PHPC). Immune responses primed by our vaccine regiment correlated with protection in all vaccinated macaques (6/6). As expected our vaccine-induced immune responses did not prevent from infection acquisition but controlled the replication of the highly pathogenic and heterologous SIVmac251 challenge given as repeated low dose by the intrarectal mucosal route. All vaccinated animals (6/6) controlled their viremia to undetectable level using conventional PCR during at least 10 months post infection (end of the experiment). We further focused on PHPC responses associated with viral control and found that these cells vigorously proliferate upon ex vivo stimulation with specific antigens in presence of the homeostatic IL-7 and IL-15 cytokines. Proliferating antigen specific cells contained a type of stem cell-like memory T cells (TSCM). These latter (TSCM) might be a major asset in favor of our lentivector and vaccination strategy due to their high capacity for self-regeneration/maintenance in absence of antigen source.

Vih-1

Vaccin

Caev

Non-Intégratif

Non-Réplicatif

Vecteur ADN lentiviral

Hiv-1

Vaccine

Caev

Non-Integratrive

Non-Replicative

DNA lentiviral vector

610

Evaluations of Temporal Donor-cell Delivery into Brain of a Lysosomal Storage Disease MPS I after Bone Marrow Transplantation with Different Conditioning Regimens and Viral Vector Designs for Efficient Dual-Cassette Expression in Hematopoietic Cells

Boateng-Antwi, Michael

January 2021

No description available.

Surgery

MPS I - Hurler syndrome

Hematopoietic stem cell-gene therapy

CNS

Lentiviral vector design

Dual-cassette expression

mini-CMV enhancer