Envolvimento da neuraminidase-1 na atrofia muscular / The role of neuraminidase-1 in muscle atrophy

Vanessa Rodrigues Rizzato

18 August 2014

Sialidose é uma doença neurossomática causada pela deficiência congênita da neuraminidase-1 (Neu1), enzima envolvida na regulação do catabolismo de sialoglicoconjugados nos lisossomos. Com o acúmulo de sialoglicoconjugados, ocorre comprometimento sistêmico e neurológico. Achados histológicos musculares incluem expansão da matriz extracelular (MEC) devido à proliferação anormal de fibroblastos, invasão das fibras musculares por componentes da MEC, fragmentação do citoplasma, formação vacuolar e atrofia das fibras musculares. Entretanto o mecanismo da atrofia muscular na deficiência de Neu1 não está completamente esclarecido, sendo o objetivo desse estudo. Desnervou-se o músculo gastrocnêmio direito de camundongos com deficiência de Neu1 (Neu1 -/-) e de controles Neu1 +/+. Os animais foram eutanasiados 0, 3, 7, 14 e 21 dias pós desnervação. Os músculos desnervados e contralaterais foram submetidos às seguintes análises: 1) histologia geral e medida da área transversa das fibras; 2) autofagia, através da avaliação da presença de vacúolos autofágicos por estudo ultraestrutural e da análise da expressão da proteína LC3; 3) ativação do sistema lisossomal, por reação de fosfatase ácida e análise da expressão proteica de catepsina L e lamp1; 4) deposição de colágeno e infiltração de tecido conjuntivo no tecido muscular; 5) níveis das proteínas Akt e GSK3b; 6) expressão dos atrogenes MuRF1 e Atrogina-1; 7) níveis da proteína MyoD, relacionada à diferenciação muscular; e 8) expressão dos genes Neu1, Neu2, Neu3 e Neu4. Os animais Neu1-/- apresentaram menor peso corporal e muscular compararando-se com animais Neu1 +/+. Houve redução progressiva da área das fibras dos músculos desnervados em relação aos músculos contralaterais. Os animais Neu1-/- apresentaram atrofia muscular basal, com aumento acentuado dos espaços endomisiais e perimisiais. Ocorreu formação de vacúolos autofágicos a partir de 14 dias de desnervação tanto em animais Neu1+/+ quanto em Neu1-/-. Os níveis de expressão proteica de catepsina L e de lamp1 aumentaram a partir de 14 dias de desnervação, mais notadamente em músculos desnervados de camundongos Neu1-/-. A expressão proteica de colágeno III mostrou-se aumentada em animais Neu1-/-, principalmente após desnervação. A expressão proteica da forma fosforilada do Akt (forma ativada) diminuiu após 21 dias de desnervação principalmente em músculos desnervados de animais Neu1+/+. Os níveis de PGSK3 b, forma inativa de GSK3b, diminuíram após a desnervação, em animais Neu1+/+ e animais Neu1-/-. Houve aumento na expressão gênica de Atrogina-1 e MuRF1 após 3 e 7 dias de desnervação, respectivamente; a expressão gênica de Atrogina-1 nos camundongos Neu1-/- teve um aumento atrasado, mostrando diferença significante após 7 dias de desnervação. Não houve diferença significativa entre níveis proteicos de MyoD. A expressão gênica de Neu1 mostrou-se elevada em músculos desnervados de animais Neu1+/+. Conclui-se, portanto, que a Neu1 parece atuar na regulação da massa muscular principalmente controlando o processo de ativação do sistema lisossomal, porém aparentemente sem afetar a autofagia / Sialidosis, a severe neurosomatic disease, results from congenital neuraminidase-1 (Neu1) deficiency. This enzyme regulates the catabolism of sialoglycoconjugates in the lysosomes. Systemic and neurologic manifestations occur due to the sialoglycoconjugates accumulation. In the mouse model for Neu1 deficiency, the muscle histologic findings include extracellular matrix (ECM) expansion, due to abnormal fibroblast proliferation, muscle fibers invasion by ECM components, cytoplasm fragmentation, vacuolar formation and muscle atrophy. Nevertheless the mechanisms of muscle atrophy in Neu1 deficiency are not completely known. This study was designed to investigate Neu1 involvement in muscle atrophy process. Denervation of gastrocnemius muscle was performed by sectioning sciatic nerve from Neu1 deficient mice (Neu1 -/-) and from normal control Neu1 +/+; the animals were euthanized 0, 3, 7, 14 and 21 days after denervation. Denervated and control muscles were collected and submitted to several analysis: 1) histological; 2) autophagic vacuoles formation, performed by ultrastructural analysis and LC3 protein expression; 3) acid phosphatase reaction, lamp1 and cathepsin L protein expression, to analyze lysosomal activation; 4) collagen deposition and fibrous formation; 5) proteins involved with muscle trophism, Akt and GSK3b; 6) MuRF1 and Atrogin-1 gene expression; 7) MyoD protein expression; 8) Neu1, Neu2, Neu3 and Neu4 genes expression. Neu1 -/- mice presented decreased body and muscle weight comparing to Neu1 +/+ animals. Muscle fiber cross-sectional area was reduced in denervated muscles comparing to contralateral muscles. Neu1 -/- mice muscles presented basal atrophy and increase of endomisial and perimisial spaces, which became more evident after denervation. After 14 days of denervation, autophagosome formation was noticed on Neu1 +/+ and Neu1-/- animals. Cathepsin L protein levels were increased after 14 and 21 days of denervation, especially in denervated muscles from Neu1 -/- mice. Lamp1 protein expression was increased in Neu1-/- animals. Type III collagen protein levels were increased in Neu1-/- animals. There were no significant differences between MyoD protein levels. P-Akt, active form of Akt protein levels, decreased after 21 days of denervation, especially in denervated muscles from control group animals, indicating that protein synthesis is decreased. P-GSK3b, inactive form of GSK3b decreased in denervated muscles from Neu1 -/- and Neu1 +/+ animals, which indicates that this protein remained activated during muscle atrophy process. There were significant differences in Atrogin-1 and MuRF1 gene expression levels after 3 and 7 days of denervation. Neu1 -/- animals muscles presented a delayed Atrogin-1 response. Neu1 gene expression was increased in denervated muscles from Neu1 +/+ mice. These findings suggest that Neu1 seems to act in the regulation of muscle mass mainly by controlling the process of lysosomal system activation, but apparently without affecting autophagy

Atrofia muscular

Autofagia

Camundongos Knockout

Colágeno tipo III

Complexos ubiquitina-proteína ligase

Denervação muscular

Neuraminidase sialidose

Quinase da glicogênio sintase

Tecido conjuntivo/patologia

Collagen type

Connective tissue/pathology

Glycogen synthase kinase

Knockout mice, Autophagy

Muscle denervation

Muscular atrophy

Neuraminidase

Sialidosis

Ubiquitinprotein ligase complexes

Efeitos de diferentes glicocorticoides sobre as vias moleculares de regulação do trofismo muscular em ratos e o efeito do EPA/DHA na atrofia muscular induzida pela dexametasona / Effects of different glucocorticoids on molecular pathways regulating muscle trophism in rats and the effect of EPA / DHA on muscle atrophy induced by dexamethasone

Alan Fappi

04 June 2018

Várias condições podem estar relacionadas com a atrofia muscular, tais como inatividade, envelhecimento, septicemia, diabetes, câncer e uso de glicocorticoides. Em tentativa prévia de prevenir tal condição catabólica secundário ao uso de glicocorticoide, através da suplementação de ômega-3 (N-3), observamos um agravamento da atrofia muscular, afetando mais tipos de fibras musculares, usualmente poupadas pelo glicocorticoide, fibras tipo 1 por exemplo. Entretanto, não foi possível determinar quais as propriedades dessa interação. Portanto, o objetivo deste estudo foi de avaliar a ação do Ômega-3 associada a dexametasona e de diferentes glicocorticoides em dose equipotente sobre o peso corporal; área de secção transversa muscular; perfil de ácidos graxos; expressão gênica de fatores de transcrição musculares e atrogenes (Atrogina 1 e MuRF-1); expressão proteica de componentes das vias do IGF-1/Akt/mTOR, Ras/Raf/MEK/ERK e Miostatina/Smad2/3; e expressão de receptores de glicocorticoides na musculatura esquelética de ratos. Metodologia: Ratos Wistar suplementados ou não com ômega-3 (100mg/kg/dia de EPA) por 40 dias receberam dexametasona (DX) subcutânea (2,5 e 1,25mg/kg/dia) nos últimos 10 dias de suplementação. Para estudo dos demais glicocorticoides, ratos sem suplementação receberam deflazacorte (DC), metilprednisolona (MP) em dose/volume equipotente ao de dexametasona (DC 10 e 20mg/kg/dia e MP6,7 e 13,3mg/kg/dia) por 10 dias. Constituindo 10 grupos: CT, N-3, DX1,25, DX2,5, DX1,25+N-3, DX2,5+N-3, MP6, MP13, DC10 e DC20. Através de estudo histológico, imuno-histoquímico, PCR em tempo real e Western blotting, foram avaliados a área transversa dos diferentes tipos de fibras musculares; a expressão de receptor de glicocorticoide na fibra muscular; a expressão gênica dos atrogenes e fatores de transcrição; expressão de proteínas das vias IGF-1, Miostatina e MEK/ERK. Resultados: A administração de N-3 influenciou a atrofia por DX causando maior atrofia em fibras do tipo 1 e 2A, aumento na expressão proteica de FoxO3a total, P-Smad3, LC3-II e gênica (mRNA) de REDD-1, Atrogina-1/MAFbx. De forma isolada o ômega-3 reduziu a expressão de P-FoxO3a, PGC1alfa, a quantidade de ácido araquidônico e a expressão de mRNA do IRS-1 com aumento na expressão de LC3-II. A comparação entre glicocorticoides mostrou que a MP (13mg/kg/dia) acarretou maior impacto no peso corporal e muscular; o DC (10mg/kg/dia) causou menor atrofia em fibras 2B em relação aos demais glicocorticoides. A DX causou maior impacto sobre o Akt total em comparação com os demais glicocorticoides, em P-Akt o grupo DX1,25 teve menor expressão em relação a outros glicocorticoides em dose equipotente. Todos os glicocorticoides afetaram a expressão de P-FOXO3a. Na expressão de ERK1/2 e P-ERK1/2, MP6 foi o grupo com maior prejuízo à fosforilação em relação aos demais em dose equipotente. Já na avaliação da via Miostatina/Smad2/3 os grupos MP 6, MP13 e DC20 mostraram maior expressão de Smad2/3 total e P-Smad3. A expressão gênica de REDD-1 e MYOD foi aumentada nos grupos MP6 e MP13 em relação aos demais grupos; REDD2 no grupo DC20 foi menor em relação ao grupo DX2,5. A expressão de Miostatina foi menor nos grupos DX2,5 e DC20, sendo o DC a droga com menor impacto sobre os atrogenes MuRF-1 e Atrogina-1. DX1,25 e DX2,5 causaram menor expressão de IRS-1 entre os grupos de glicocorticoides. Conclusões: Ômega-3 pode aumentar a atrofia muscular causada por DX em fibras 1 e 2A, possivelmente relacionado com aumento da expressão de FoxO3a, REDD-1 e Atrogina-1, diminuição na expressão de PGC1alfa e P-FoxO3a, nas quantidades de ácido araquidônico com aumento da atividade lisossomal. Comparando diferentes glicocorticoides, a MP tende a produzir maior impacto nos pesos corporal e muscular, o DC é menos prejudicial as fibras do tipo 2B, entretanto, afeta predominantemente fibras do tipo 1, da mesma forma que a DX na dosagem de 1,25mg/kg/dia. A DX tende a afetar mais a expressão de Akt total e fosforilado que os demais glicocorticoides. A MP afeta mais a via Ras/Raf/MEK/ERK e expressão de REDD-1 em relação aos demais glicocorticoides, e o DC e MP mostram maior expressão de Smad2/3 total e fosforilada em relação ao DX após 10 dias de administração / Several conditions may be related to muscle atrophy, such as inactivity, aging, septicemia, diabetes, cancer and use of glucocorticoids. In a previous attempt to prevent such glucocorticoid catabolic condition, through the supplementation of omega-3 (N-3), we observed a worsening of muscular atrophy, affecting more types of muscle fibers, usually spared by glucocorticoid, type 1 fibers for example. However, it was not possible to determine the properties of this interaction. Therefore, the objective of this study was to evaluate the action of omega-3 associated with dexamethasone and different glucocorticoids in equipotent dose on body weight; muscle cross-sectional area; fatty acid profile; gene expression of muscle transcription factors and atrogenes (Atrogin-1 and MuRF-1); protein expression of IGF-1/Akt/mTOR, Ras/Raf/MEK/ERK and Myostatin/Smad2/3 pathways components; and expression of glucocorticoid receptors in the skeletal musculature of rats. Methods: Wistar rats given orally or not with omega-3 (100mg/kg/day of EPA) for 40 days received subcutaneous dexamethasone (DX) (2.5 or 1.25mg/kg/day) during the last 10 days of supplementation. For the other glucocorticoids, rats without supplementation received deflazacorte (DC) or methylprednisolone (MP) in dose/volume equivalent to that of dexamethasone (DC 10 or 20mg/kg/day and MP6.7 or 13.3mg/kg/day) for 10 days. Comprising 10 groups: CT, N-3, DX1.25, DX2.5, DX1.25 + N-3, DX2.5 + N-3, MP6, MP13, DC10 and DC20. Through histological, immunohistochemical, real-time PCR and Western blotting, we evaluated the transverse area of the different muscle fibers; the expression of glucocorticoid receptor; the gene expression of atrogenes and transcription factors; protein expression of the IGF-1, Myostatin and MEK/ERK pathways. Results: N-3 administration influenced DEXA atrophy causing increased atrophy in type 1 and 2A fibers, increased protein expression of total FoxO3a, P-Smad3, LC3-II, and REDD-1 gene (mRNA), Atrogin-1/MAFbx isolated omega-3 reduced the expression of P-FoxO3a, PGC1alpha, the amount of arachidonic acid and the expression of IRS-1 mRNA with increased expression of LC3-II. The comparison between glucocorticoids showed that MP13 had a greater impact on body and muscle weight; the DC10 caused less atrophy in 2B fibers in relation to the other glucocorticoids. DX, caused greater impact on total Akt compared to the other glucocorticoids, in P-Akt the DX1,25 group had lower expression to other equipotent dose glucocorticoids. All glucocorticoids affect the expression of P-FOXO3a. In the of ERK1/2 and P-ERK1/2 protein expression, the MP6 was the group with the greatest damage to the phosphorylation in relation to the others in equipotent dose. In the evaluation of the Myostatin/Smad2/3 pathway MP 6, MP13 and DC20 showed higher expression of total Smad2/3 and P-Smad3. The gene expression of REDD-1 and MYOD was increased in the MP6 and MP13 groups compared to the other groups, REDD2 in the DC20 group was lower in relation to the DX2.5 group. Myostatin expression was lower in the DX2.5 and DC20 groups, with DC being the drug with less impact on atrogenes MuRF-1 and Atrogin-1. DX1.25 and DX2.5 caused lower IRS-1 expression among the glucocorticoid groups. Conclusions: Omega-3 may increase muscle atrophy caused by DX in fibers 1 and 2A, possibly related to increased expression of FoxO3a, REDD-1 and Atrogin-1, decreased expression of PGC1alpha and P-FoxO3a, in the amounts of acid arachidonic with increased lysosomal activity. Comparing different glucocorticoids, MP tends to produce a greater impact on body and muscular weights, DC is less harmful to type 2B fibers, however, it predominantly affects type 1 fibers, in the same way as DX in the dosage of 1.25mg/kg/day. DX tends to affect total and phosphorylated Akt expression more than other glucocorticoids. MP affects more the Ras/Raf/MEK/ERK pathway and REDD-1 expression in relation to the other glucocorticoids, and DC and MP show a higher expression of total and phosphorylated Smad2/3 compared to DX after 10 days of administration

Ácidos graxos ômega-3

Atrofia muscular

Autofagia

Deflazacorte

Dexametasona

Fator de crescimento insulin-like

Glucocorticoides

Metilprednisolona

Miostatina

Autophagy

Deflazacort

Dexamethasone

Fatty acid omega-3

Glucocorticoids

Insulin-like growth factor I

Methylprednisolone

Mitogen-activated protein kinase kinases

Muscular atrophy

Myostatin

C. elegans, un outil de criblage pour la recherche de traitements contre les maladies rares / Caenorhabditis elegans as chemical screening tool to find compounds and targets against neuromuscular diseases

Giacomotto, Jean

08 March 2010

Les techniques de criblage actuelles (in vitro et in silico) sont dépendantes des efforts menés en biologie médicinale pour identifier des cibles biologiques pertinentes ; cibles difficiles à définir pour les maladies génétiques dites "perte de fonction". De plus, les composés issus de ces cribles s'avèrent souvent inefficaces et/ou toxiques une fois confrontés à la complexité physiologique d'un organisme entier. Pour contourner ce problème, nous proposons d'utiliser le nématode C. elegans, notamment pour des maladies répondant aux critères suivants : i) physiopathologie complexe et/ou mal comprise excluant le développement à court terme de médicaments sur une base rationnelle, ii) peu d’espoir de thérapie génique/cellulaire à court terme, iii) conservation chez C. elegans du gène relié à la maladie humaine et induisant un phénotype exploitable une fois inactivé. Nous démontrons ici que ce petit nématode permet de tester, à moindre coût, un grand nombre de composés chimiques tout en conservant la complexité physiologique d'un animal entier. De plus, la souplesse génétique de cet animal permet d'apporter rapidement des informations sur le mode d'action des composés identifiés. Ainsi, en plus du but initial visant à identifier des molécules bioactives à intérêt thérapeutique, cette approche peut permettre de dégager de nouvelles cibles moléculaires utiles pour l'industrie chimique, et cruciales pour la recherche de traitements contre les maladies perte de fonction. Finalement, nous présentons comment mettre en place une telle stratégie, notamment pour la myopathie de Duchenne, l'amyotrophie spinale et le syndrome de Schwartz-Jampel. Enfin, nous présentons les résultats obtenus lors des différentes campagnes de criblage, les validations des molécules les plus prometteuses et les travaux effectués pour tenter de comprendre leur mode d'action chez le nématode. / Current high-throughput screening methods for drug discovery rely on the existence of targets. Moreover, most of the hits generated during screenings turn out to be invalid after further testing in animal models. To by-pass these limitations, efforts are now being made to screen chemical libraries on whole animals. One of the most commonly used animal model in biology is the murine model Mus musculus. However, its cost limits its use in large-scale therapeutic screening. In contrast, the nematode Caenorhabditis elegans is gaining momentum as screening chemical tool. This tiny worm combines genetic amenability, low cost, and culture conditions that are compatible with large-scale screens. Its main advantage is to allow high-throughput screening in a whole-animal context. Moreover, its use is not dependent on the prior identification of a target and permits the selection of compounds with an improved safety profile. Here, we introduce this approach with the Duchenne Muscular Dystrophy, the Spinal Muscular Dystrophy and the Schwartz-Jampel syndrome. We present the methodology used with each model to screen up to 7,000 compounds and the results of these screening campaigns. We further present the validation of our best hits and try to understand their mechanism of action.

Caenorhabditis elegans

Criblage pharmaceutique

Duchenne Muscular Dystrophy (DMD)

Spinal Muscular Atrophy (SMA)

Syndrome de Schwartz-Jampel

HSPG-2

Perlecan

Anhydrase Carbonique

Sérotonine

Métabolomique

Souris mdx

Dystrophine

Caenorhabditis elegans

Chemical screen

Duchenne Muscular Dystrophy (DMD)

Spinal Muscular Astrophy (SMA)

Schwartz- Jampel syndrome

HSPG-2

Perlecan

Carbonic Anhydrase

Serotonin

Metabolomic

Mdx mice

Dystrophin

576

Development and Validation of Quantitative PCR Assays for DNA-Based Newborn Screening of 22q11.2 Deletion Syndrome, Spinal Muscular Atrophy, Severe Combined Immunodeficiency and Congenital Cytomegalovirus Infection

Theriault, Mylene A.

January 2013

The development of new high throughput technologies able to multiplex disease biomarkers as well as advances in medical treatments has lead to the recent expansion of the newborn screening panel to include DNA-based targets. Four rare disorders; deletion 22q11.2 syndrome and Spinal Muscular Atrophy (SMA), Severe Combined Immunodeficiency (SCID) and Congenital Cytomegalovirus (CMV), are potential candidates for inclusion to the newborn screening panel within the next few years. The major focus of this study was to determine whether 5’-hydrolysis assays developed for the four distinct disorders with specific detection needs and analytical ranges could be combined on the OpenArray system and in multiplexed qPCR reactions. SNP detection of homozygous SMN1 deletions in SMA, CNV detection in the 22q11.2 critical region, and quantification of the SCID biomarker, T-cell receptor excision circles (TRECs) and CMV were all required for disease confirmation. SMA and 22q11.2 gene deletions were accurately detected using the OpenArray system, a first for the technology. The medium density deletion 22q11.2 multiplex successfully identified deletion carriers having either the larger 3 Mb deletion or the smaller 1.5 Mb deletions. Both TREC and CMV targets were detected but with a decrease in sensitivity when compared to their singleplex counterparts. Lastly, copy number detection of the TBX1 was performed when multiplexed with the TREC assay, without a decrease in detection limit of either assay. Here, we provide proof of principal that qPCR multiplexing technologies are amenable to implementation with a newborn screening laboratory.

22q11.2 deletion syndrome

spinal muscular atrophy

severe combined immunodeficiency

congenital cytomegalovirus

qPCR

TaqMan

relative quantification

copy number variation

T-cell receptor excision circle

newborn screening

OpenArray

multiplex

TBX1

CRKL

UFD1L

COMT

HIRA

UL54

UL55

US17

dried blood spot

contiguous gene deletion

SMN1

SMN2