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Browsing by Author "Santos, Juliana Inês"

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  • Antisense oligonucleotide exon-skipping as a therapeutic approach for Mucolipidosis type II a/b: in vitro and in vivo studies
    Publication . Matos, Liliana; Gonçalves, Mariana; Santos, Juliana Inês; Coutinho, Maria Francisca; Prata, Maria João; Pires, Maria João; Oliveira, Paula; Alves, Sandra
    Mucolipidosis type II alpha/beta (ML II alpha/beta) is one of the most severe Lysosomal Storage Disorders and is caused by the deficiency of the enzyme GlcNAc-1-phosphotransferase. This enzyme is responsible for the addition of the mannose 6-phosphate marker to lysosomal enzymes, which allow their targeting to lysosomes. Of the several mutations that occur in ML II alpha/beta, the deletion of 2 nucleotides from GNPTAB exon19 (c.3503_3504del) is the most frequent, making it a good target for a specific mutation therapy as there is no therapy for this disease. In this study, we explored the possibility of an innovative therapeutic strategy based on the use of antisense oligonucleotides (AOs) for ML II alpha/beta. In a previous in vitro study in ML II alpha/beta patient fibroblasts, AOs were used to promote the exon 19 skipping from the GNPTAB pre-mRNA, resulting successfully in the production of an in-frame mRNA1. Currently, our objective is to evaluate the therapeutic potential of this approach, both in vitro in C57BL/6 fibroblasts and in vivo in C57BL/6 mice. For this, 18 animals were used, divided into 6 groups: groups 1 and 4 were injected with saline solution, groups 2 and 5 were injected with AO at 25 mg/kg and groups 3 and 6 were injected with AO at 50 mg/kg. All animals were injected by intraperitoneal route and were sacrificed after 4 days (groups 1, 2, 3) or 7 days (groups 4, 5, 6) post-treatment. At the end of the experiment, the organs were collected and frozen at -80ºC, for later RNA extraction, cDNA synthesis and RT-PCR. After results analysis, the exon 19 skipping was not observed using any of the tested doses or incubation periods. So, we can theorize that the doses administered were not sufficient to achieve a response or the AO might have had a high clearance rate. As for the in vitro experience, the C57BL/6 fibroblasts were seeded in 6-well plates and subsequently transfected with concentrations of AO ranging from 10nM to 600nM. After 24h or 48h of incubation, cells were collected and cDNA analysis revealed a full length transcript but also another one of lower molecular weight compatible with exon-skipping. These are preliminary data, so in the near future more experiments will be done. 1. Matos L, Vilela R, Rocha M, et al. Development of an antisense oligonucleotide-mediated exon skipping therapeutic strategy for Mucolipidosis II: validation at RNA level. Hum Gene Ther, 2020, 31(13-14):775-783.
    2021-09Conference object Open access Show more
  • Antisense oligonucleotide exon-skipping as a therapeutic approach for Mucolipidosis type II a/b: in vitro and in vivo studies
    Publication . Matos, Liliana; Gonçalves, Mariana; Santos, Juliana Inês; Coutinho, Maria Francisca; Prata, Maria João; Pires, Maria João; Oliveira, Paula; Alves, Sandra
    Mucolipidosis type II alpha/beta (ML II) is one of the most severe Lysosomal Storage Disorders and is caused by the deficiency of the enzyme GlcNAc-1-phosphotransferase. This enzyme is responsible for the addition of the mannose 6-phosphate marker to lysosomal enzymes, which allow their targeting to lysosomes. Of the several mutations that occur in ML II, the deletion of 2 nucleotides from GNPTAB exon19 (c.3503_3504del) is the most frequent, making it a good target for a specific mutation therapy as there is no therapy for this disease. In this study, we explored the possibility of an innovative therapeutic strategy based on the use of antisense oligonucleotides (AOs) for ML II. In a previous in vitro study in ML II patient fibroblasts, AOs were used to promote the exon 19 skipping from the GNPTAB pre-mRNA, resulting successfully in the production of an in-frame mRNA. Currently, our objective is to evaluate the therapeutic potential of this approach, both in vitro in C57BL/6 fibroblasts and in vivo in C57BL/6 mice. For this, 18 animals were used, divided into 6 groups: groups 1 and 4 were injected with saline solution, groups 2 and 5 with AO at 25 mg/kg and groups 3 and 6 with AO at 50 mg/kg. All animals were injected by intraperitoneal route and were sacrificed after 4 or 7 days post-treatment. At the end of the experiment, the organs were collected and frozen at -80ºC, for later RNA extraction, cDNA synthesis and RT-PCR. After results analysis, the exon 19 skipping was not observed using any of the tested doses or incubation periods. So, we can theorize that the doses administered were not sufficient to achieve a response or the AO might have had a high clearance rate. As for the in vitro experience, the C57BL/6 fibroblasts were seeded in 6-well plates and subsequently transfected with concentrations of AO ranging from 10nM to 600nM. After 24/48h of incubation, cells were collected and cDNA analysis revealed a full length transcript but also another one of lower molecular weight compatible with exon-skipping. These are preliminary data, so in the near future more experiments will be done.
    2021-11Conference object Open access Show more
  • Antisense oligonucleotide exon-skipping as a therapeutic approach for Mucolipidosis type II α/β: in vitro and in vivo studies
    Publication . Gonçalves, Mariana; Matos, Liliana; Santos, Juliana Inês; Coutinho, Maria Francisca; Prata, Maria João; Pires, Maria João; Oliveira, Paula; Alves, Sandra
    Genetic therapy directed towards the correction of RNA mis-splicing is being investigated at basic research and in late-stage clinical trials. Many mutations that change the normal splicing pattern and lead to aberrant mRNA production have been identified in Lysosomal Storage Disorders (LSDs). Mucopolysaccharidosis IIIC (MPS IIIC) is one of those LSDs caused by mutations in the HGSNAT gene that encodes an enzyme involved in heparan sulphate degradation. Splicing mutations are one of the most frequent (~20%) genetic defects in MPS IIIC. Approximately 55% correspond to 5' splice-site (ss) mutations thus constituting a good target for mutation-specific therapeutic approaches. Recently, we have demonstrated in fibroblast cells that a modified U1 snRNA vector designed to improve the definition of exon 2 5’ss of the HGSNAT can restore splicing impaired by the mutation c.234+1G>A. Currently, our goal is to evaluate in vivo the therapeutic potential of that modified U1 snRNA by testing it in mice expressing the human splicing defect. For this purpose, two full-length constructs were generated by cloning the wild-type (wt) or the mutated HGSNAT splicing-competent cassettes in the pcDNA 3.1 vector. Then, in an in vitro assay, the wt or mutated construct was transfected in Hep3B and COS-7 cells. After molecular analysis it was observed that both minigenes reproduce the healthy control and patient cDNA’s splicing pattern. Therefore, both constructs were used to generate mice of the C57BL/6 strain expressing the human mutation c.234+1G>A in the liver and test its modified U1-mediated rescue in vivo. Wt or mutant minigenes were administrated in mice by hydrodynamic injection following a reported protocol(1). After 48 hours animals were sacrificed, the liver was collected and molecular analysis was performed. Preliminary results showed expression of the HGSNAT cDNA from the mutant construct in the liver of at least one animal. Thus, further tests will be carried out to optimize some limiting points, such as the administration of the minigenes (e.g. increase of injection volume from 7% to 8-9% of mice body weight; inclusion of an in vivo transfection reagent to enhance delivery efficiency) and the use of other mice strain. 1. Balestra D, et al. (2014) J Thromb Haemost 12(2):177–185.
    2021-04Conference object Restricted access Show more
  • Antisense oligonucleotide exon-skipping as a therapeutic approach for Mucolipidosis type II α/β: in vitro and in vivo studies
    Publication . Gonçalves, Mariana; Matos, Liliana; Santos, Juliana Inês; Coutinho, Maria Francisca; Prata, Maria João; Pires, Maria João; Oliveira, Paula; Alves, Sandra
    Mucolipidosis type II α/β (ML II α/β) is one of the most severe Lysosomal Storage Disorders and is caused by the deficiency of the enzyme GlcNAc-1-phosphotransferase. This enzyme is responsible for the addition of the mannose 6-phosphate marker to lysosomal enzymes, which allow their targeting to lysosomes. Of the several mutations that occur in ML II α/β, the deletion of 2 nucleotides from GNPTAB exon19 (c.3503_3504del) is the most frequent, making it a good target for a specific mutation therapy as there is no therapy for this disease. In this study, we explored the possibility of an innovative therapeutic strategy based on the use of antisense oligonucleotides (AOs) for ML II α/β. In a previous in vitro study in ML II α/β patient fibroblasts, AOs were used to promote the exon 19 skipping from the GNPTAB pre-mRNA, resulting successfully in the production of an in-frame mRNA. Currently, our objective is to evaluate the therapeutic potential of this approach, both in vitro in C57BL/6 fibroblasts and in vivo in C57BL/6 mice. For this, 18 animals were used, divided into 6 groups: groups 1 and 4 were injected with saline solution, groups 2 and 5 were injected with AO at 25 mg/kg and groups 3 and 6 were injected with AO at 50 mg/kg. All animals were injected by intraperitoneal route and were sacrificed after 4 days (groups 1, 2, 3) or 7 days (groups 4, 5, 6) post-treatment. At the end of the experiment, the organs were collected and frozen at -80ºC, for later RNA extraction, cDNA synthesis and RT-PCR. After results analysis, the exon 19 skipping was not observed using any of the tested doses or incubation periods. So, we can theorize that the doses administered were not sufficient to achieve a response or the AO might have had a high clearance rate. As for the in vitro experience, the C57BL/6 fibroblasts were seeded in 6-well plates and subsequently transfected with concentrations of AO ranging from 10nM to 600nM. After 24h or 48h of incubation, cells were collected and cDNA analysis revealed a full length transcript but also another one of lower molecular weight compatible with exon-skipping. These are preliminary data, so in the near future more experiments will be done.
    2021-07Conference object Open access Show more
  • Assessing Niemann-Pick Type C (NP-C) through a multi-omics approach genomic and transcriptomic profile of challenging cases
    Publication . Encarnação, Marisa; Coutinho, Maria Francisca; Cho, Soo-Min; Cardoso, Maria Teresa; Chaves, Paulo; Ribeiro, Isaura; Santos, Juliana Inês; Gaspar, Paulo; Quelhas, Dulce; Lacerda, Lúcia; Leão-Teles, Elisa; Futerman, Anthony H.; Vilarinho, Laura; Alves, Sandra
    Niemann-Pick type C (NP-C) is a neurodegenerative Inherited Metabolic Disease with a heterogeneous clinical presentation, due to mutations in either the NPC1 or NPC2 genes. We studied patients with clinical diagnosis of NP-C but presenting inconclusive results regarding biomarkers testing and molecular analysis. Using NGS- targeted DNA sequencing we have identified some novel putative mutations and subsequent cDNA analysis allowed us to stablish the functional effect of a silent mutation (previously reported as a polymorphism) in the NPC1 splicing process. We demonstrated that this mutation leads to exon skipping, frameshift and premature stop codon and identified it in two NP-C patients from two unrelated Portuguese families. This mutation most likelly leads to a very unstable transcript that was overlooked. Also, to better characterize the pathomechanisms related to specific disease-causing mutations in NP-C patients, we analysed gene expression profiles in cultured skin fibroblasts and compared them to control individuals using Massively Parallel RNA Single-Cell Sequencing (MARS-Seq). The most prominent hits from this transcriptomics analysis were validated by qRT-PCR. The MARS-Seq analysis showed that a number of genes were upregulated and a significant number of the highly enriched genes are related to the unfold protein response (UPR) and Endoplasmic Reticulum (ER) stress, in a specific patient, which deserves further studies. ER stress is a hallmark of many neurodegenerative diseases, including LSD and can be due to misfolded/unfolded proteins as result of a specific missense mutation. Our preliminary results suggest that UPR activation is variable among NP-C patients, and this is likely to depend on the mutation type. Several other factors may contribute to this though, which could explain the heterogeneous presentation of this pathology. Additionally, we have investigated the same patients studied in MARS-Seq at the protein and celular levels. Interestingly, and according to recently published work, we observed that, for the analyzed mutations a significant part of the mutated NPC1 protein was retained/ delayed in the ER.
    2019-10Conference object Restricted access Show more
  • Assessing the potential of RNA-based therapeutics for a group of Lysosomal Storage Diseases with neurological involvement
    Publication . Santos, Juliana Inês; Gonçalves, Mariana; Matos, Liliana; Gaspar, Paulo; Pires, Maria João; Oliveira, Paula; Prata, Maria João
    During the first two decades of the 21st century, remarkable progresses have been achieved in the field of RNA-based therapeutics. From antisense RNA to RNA modification, the therapeutic potential of RNA-based technologies has nothing but increased. In our lab, we have been addressing the potential of different RNA-based drugs to either correct or ameliorate the sub-cellular phenotype of a number of severe, life-threatening diseases: the so-called Lysosomal Storage Disorders (LSDs). Among them, we are focusing our efforts on those which present with a predominant neurological phenotype, since there are virtually no approved treatments for any of them. Briefly, two major research lines are being pursued: the first relies on the design of mutation-specific approaches to correct abnormal splicing processes in LSD-related genes, whenever they underlie pathology. The second depends upon selective downregulation of genes involved in the biosynthethic cascades that give origin to the substrates that accumulate in each pathology. Here we present an overview on our results with both approaches on Sanfilippo syndrome, a sub-group of severe neurodegenerative LSDs. For the mutation-specific, splicing correction approach, we are using U1snRNA vectors to restore the splicing defect caused by the HGSNAT mutation c.234+1G>A, that leads to Sanfilippo C disease. We started by demonstrating in vitro that a modified U1snRNA vector designed to improve the definition of HGSNAT exon 2 could partially restore its normal splicing process. Now, we are evaluating its therapeutic potential in vivo, in mice expressing the human splicing defect. For the substrate reduction approach, we are using siRNAs. By acting over a specific biosynthethic cascade, siRNAs promote an overall decrease of the accumulating substrate. So far, we have already tested this approach in patients’ fibroblasts and observed a high inhibition of the target mRNAs and a decrease in storage. Overall, there are substantial differences between these two approaches but they also face common challenges and show equally promising results.
    2021-11Conference object Open access Show more
  • Coutinho et al. Less Is More: Substrate Reduction Therapy for Lysosomal Storage Disorders. Int. J. Mol. Sci. 2016, 17, 1065
    Publication . Coutinho, Maria Francisca; Santos, Juliana Inês; Alves, Sandra
    n/a.
    2017-01-17Journal article Open access Show more
  • Development of an antisense oligonucleotide-mediated exon skipping therapeutic strategy for Mucolipidosis II: validation at RNA level
    Publication . Matos, Liliana; Vilela, Regina; Rocha, Melissa; Santos, Juliana Inês; Coutinho, Maria Francisca; Gaspar, Paulo; Prata, Maria João; Alves, Sandra
    Lysosomal Storage Disorders (LSDs) are a group of rare inherited metabolic diseases caused by the malfunction of the lysosomal system, which results in the accumulation of undegraded substrates inside the lysosomes and leads to severe and progressive pathology. Despite there is currently a broad understanding of the molecular defects behind LSDs, curative therapies have been approved for only few of these diseases whereas existing treatments are still mostly symptomatic with several limitations. Mucolipidosis type II alpha/beta (ML II) is one of most severe LSDs, which is caused by the total deficiency of the GlcNAc-1-phosphotransferase, a key enzyme for the formation of specific targeting signals on lysosomal hydrolases to lysosomes. GlcNAc-1-phosphotransferase is a multimeric enzyme complex encoded by two genes: GNPTAB and GNPTG. One of the most frequent ML II causal mutation is a dinucleotide deletion on exon 19 of GNPTAB (c.3503_3504del) that leads to the generation of a truncated protein, loss of GlcNAc-1-phosphotransferase activity, and missorting of multiple lysosomal enzymes. Presently, there is no therapy available for ML II. In this study we explored the possibility of an innovative therapeutic strategy for ML II based on the use of antisense oligonucleotides (AOs) capable to induce the skipping of GNPTAB exon 19 harboring the most common disease-causing mutation, c.3503_3504del. The approach confirmed the ability of specific AOs for RNA splicing modulation, thus paving the way for future studies on the therapeutic potential of this strategy.
    2020-04-13Journal article Restricted access Show more
  • Development of an antisense oligonucleotides-based therapy for mucolipidosis type II α/β: in vivo studies
    Publication . Gonçalves, Mariana; Matos, Liliana; Santos, Juliana Inês; Coutinho, Maria Francisca; Prata, Maria João; Pires, Maria João; Oliveira, Paula; Alves, Sandra
    Introduction: The RNA molecule has become an increasingly promising target for the therapy of various diseases. Mucolipidosis type II α/β (ML II α/β) is one of the most severe Lysosomal Storage Disorders and is caused by the deficiency of the enzyme GlcNAc-1- phosphotransferase. This enzyme is responsible for the addition of the mannose 6-phosphate (M6P) marker to lysosomal enzymes, which allow their targeting to lysosomes. GlcNAc-1- phosphotransferase is encoded by the GNPTAB and GNPTG genes. Of the several mutations that occur in ML II α/β, the deletion of 2 nucleotides from GNPTAB exon19 (c.3503_3504del) is the most frequent, being a good target for a mutation specific therapy as there is no therapy for this disease 1,2. In this study, we explored the possibility of an innovative therapeutic strategy based on the use of antisense oligonucleotides (AOs) for ML II. In a previous in vitro study in ML II patient fibroblasts, AOs were used to promote the exon 19 skipping from the GNPTAB pre-mRNA, resulting successfully in the production of an in-frame mRNA 3. Currently, our objective is to evaluate the therapeutic potential of this approach in vivo in mice (Mus musculus) of the strain C57BL/6. Material & Methods: Eighteen animals with an average body mass of 25 g were used. During the study, individual body weight, food and water intake were recorded. The animals were divided into 6 groups: groups 1 and 4 were injected with saline solution, groups 2 and 5 were injected with AO at 25 mg / kg and groups 3 and 6 were injected with AO at 50 mg / kg. All animals were injected intraperitoneally and sacrificed after 4 days (groups 1, 2 and 3) or after 7 days (groups 4, 5 and 6). At the end of the experiment, the organs were collected, weighted and frozen at -80ºC, for later RNA extraction, cDNA synthesis and PCR. Statistical analysis was performed using the GraphPad Prism® for Windows program. Statistical significance between groups was determined by analysis of variance (ANOVA), followed by a Bonferroni test. All ethical issues were followed by the guidelines of the Portuguese General Directorate of Food and Veterinary. Results: Our results show that mice from groups 5 and 6 have a lower liver mass compared to the other groups, with significant differences (p <0.05). Liver of animals from group 3 has a lower weight compared to the liver of animals from group 2 and group 4, with a statistically significant difference. However, exon 19 skipping was not observed in any organ sample using any of the tested doses or incubation periods. Conclusions: To explain these first in vivo results we can theorize that the doses administered were not sufficient to achieve a response or the AO may have had a high clearance rate or did not recognize the target RNA. Moreover, the collected organs should have been preserved in liquid nitrogen to maintain RNA integrity. Other experiments will be done in the near future to overcome these preliminary data. References: [1] R. V. Velho et al. Human mutation. [2] M. F. Coutinho, et al. Biochemistry research international [3] L. Matos, et al. Human Gene Therapy.
    2021-02Conference object Restricted access Show more
  • Development of Engineered-U1 snRNA Therapies: Current Status
    Publication . Gonçalves, Mariana; Santos, Juliana Inês; Coutinho, Maria Francisca; Matos, Liliana; Alves, Sandra
    Splicing of pre-mRNA is a crucial regulatory stage in the pathway of gene expression. The majority of human genes that encode proteins undergo alternative pre-mRNA splicing and mutations that affect splicing are more prevalent than previously thought. Targeting aberrant RNA(s) may thus provide an opportunity to correct faulty splicing and potentially treat numerous genetic disorders. To that purpose, the use of engineered U1 snRNA (either modified U1 snRNAs or exon-specific U1s-ExSpeU1s) has been applied as a potentially therapeutic strategy to correct splicing mutations, particularly those affecting the 5' splice-site (5'ss). Here we review and summarize a vast panoply of studies that used either modified U1 snRNAs or ExSpeU1s to mediate gene therapeutic correction of splicing defects underlying a considerable number of genetic diseases. We also focus on the pre-clinical validation of these therapeutic approaches both in vitro and in vivo, and summarize the main obstacles that need to be overcome to allow for their successful translation to clinic practice in the future.
    2023-09-27Journal article Open access Show more