Lung remodeling in a mouse model of asthma involves a balance between TGF-ß1 and BMP-7.

A key event in chronic allergic asthma is the TGF-ß-induced activation of fibroblasts into α-SMA-positive myofibroblasts which synthesize type-I collagen. In the present study we investigated the effect of the anti-fibrotic molecule BMP-7 in asthma. Balb/c mice were immunized i.p. with ovalbumin in alum and challenged every 2 days with ovalbumin aerosol (two or six challenges for acute and chronic protocols, respectively). The lung was evaluated for: α-SMA and type-I collagen by immunohistochemistry; BMP-7 and TGF- ß1 gene expression by qRT-PCR; type-I collagen and Smads 2 and 3 by immunoblotting; mucus by PSA staining. Type-I collagen around bronchi, α-SMA, mucus secretion, TGF- ß1 and BMP-7 gene expression were all increased in asthma. The TGF- ß1/BMP-7 ratio was higher in the chronic group and correlated with higher levels of collagen. Fibroblasts isolated from asthmatic and healthy lungs produced type-I collagen upon stimulation with TGF- ß1 via phosphorylation of Smad-2, Smad-3. Pre-treatment of the fibroblasts with BMP-7 reduced collagen production and Smads phosphorylation. Intranasal treatment of asthmatic mice with recombinant BMP-7 during the immunization protocol reduced lung inflammation and type I collagen deposition. These results suggest a protective role for BMP-7 in lung allergic inflammation, opposing the pro-fibrotic effects of TGF- ß1.

New insights in osteogenic differentiation revealed by mass spectrometric assessment of phosphorylated substrates in murine skin mesenchymal cells.

BACKGROUND: Bone fractures and loss represent significant costs for the public health system and often affect the patients quality of life, therefore, understanding the molecular basis for bone regeneration is essential. Cytokines, such as IL-6, IL-10 and TNFα, secreted by inflammatory cells at the lesion site, at the very beginning of the repair process, act as chemotactic factors for mesenchymal stem cells, which proliferate and differentiate into osteoblasts through the autocrine and paracrine action of bone morphogenetic proteins (BMPs), mainly BMP-2. Although it is known that BMP-2 binds to ActRI/BMPR and activates the SMAD 1/5/8 downstream effectors, little is known about the intracellular mechanisms participating in osteoblastic differentiation. We assessed differences in the phosphorylation status of different cellular proteins upon BMP-2 osteogenic induction of isolated murine skin mesenchymal stem cells using Triplex Stable Isotope Dimethyl Labeling coupled with LC/MS. RESULTS: From 150 µg of starting material, 2,264 proteins were identified and quantified at five different time points, 235 of which are differentially phosphorylated. Kinase motif analysis showed that several substrates display phosphorylation sites for Casein Kinase, p38, CDK and JNK. Gene ontology analysis showed an increase in biological processes related with signaling and differentiation at early time points after BMP2 induction. Moreover, proteins involved in cytoskeleton rearrangement, Wnt and Ras pathways were found to be differentially phosphorylated during all timepoints studied. CONCLUSIONS: Taken together, these data, allow new insights on the intracellular substrates which are phosphorylated early on during differentiation to BMP2-driven osteoblastic differentiation of skin-derived mesenchymal stem cells.

Fosfoproteômica e proteômica quantitativa de células mesenquimais durante a diferenciação osteoblástica mediada por BMP2, expressão e purificação de diferentes tipos de proteínas morfogenéticas ósseas / Quantitative phosphoproteomics and proteomics of mesenchymal stem cells during BMP2-mediated osteoblastic differentiation, expression and purification of different types of bone morphogenetic proteins

As fraturas e perdas ósseas representam altos riscos para o Sistema público de Saúde (SUS), além de afetar a qualidade de vida do paciente, portanto é necessário o entendimento das bases moleculares que envolvem os mecanismos de reparo ósseo. Citocinas secretadas por células do sistema imune presentes no local da inflamação, como as IL-6, IL-10 e TNFα atuam como fatores quimiotáticos para células mesenquimais, que proliferam e se diferenciam em osteoblastos pela ação autócrina e parácrina de Proteínas Morfogenéticas Ósseas (BMPs), principalmente a BMP2. Embora seja conhecido que a ação de BMP2 ocorra através de sua ligação nos receptores ActRI/BMPR, que ativam proteínas SMADS 1/5/8 efetoras, pouco se sabe sobre os mecanismos intracelulares que participam do processo de diferenciação osteoblástico. Neste estudo propôs-se analisar as diferenças no conteúdo de proteínas totais e de proteínas fosforiladas em células mesenquimais de pele induzidas à osteogênese pelo tratamento com BMP2 por diferentes períodos de tempo, utilizando-se de Isótopos Estáveis de Dimetila acoplado ao LC/MS. A partir de 150µg de material inicial, foi possível identificar 2.264 proteínas, as quais foram quantificadas nos diferentes pontos de indução, sendo que 235 são fosforiladas. Análise de motivos de quinases mostrou que diversos substratos possuem sítios fosforilados correspondentes àqueles dos motivos de fosforilação das quinases Casein Kinase, p38, CDK e JNK. A análise da ontologia gênica mostrou um aumento de processos biológicos relacionados com sinalização e diferenciação após a primeira hora de indução com rhBMP2. Além disso, proteínas envolvidas com o rearranjo do citoesqueleto e com vias de sinalização Wnt e Ras foram encontradas como tendo fosforilação diferencial durante todos os períodos estudados. Os dados revelaram novos substratos intracelulares que são fosforilados nos primeiros momentos do comprometimento com a diferenciação osteoblástica mediada pelo tratamento com rhBMP2 em células mesenquimais derivadas da pele. Além disso, clones celulares que superexpressam as proteínas recombinantes humanas BMP2 e BMP4 foram gerados, e sua atividade verificada in vitro. Paralelamente, a rhBMP7, obtida anteriormente, foi purificada por cromatografia de afinidade utilizando-se uma coluna de Heparina-Sepharose, que foi posteriormente utilizada para ensaios in vitro e in vivo, nos quais se mostrou capaz de gerar osteoblastos e tecido ósseo, respectivamente, o que abre novas possibilidades para o uso destas proteínas como biofármacos no Brasil

Bone fractures and loss represent significant costs for the public health system and often affect the patients quality of life, therefore, understanding the molecular basis for bone regeneration is essential. Cytokines, such as IL-6, IL-10 and TNFα, secreted by inflammatory cells at the lesion site, at the very beginning of the repair process, act as chemotactic factors for mesenchymal stem cells, which proliferate and differentiate into osteoblasts through the autocrine and paracrine action of bone morphogenetic proteins (BMPs), mainly BMP-2. Although it is known that BMP-2 binds to ActRI/BMPR and activates the SMAD 1/5/8 downstream effectors, little is known about the intracellular mechanisms participating in osteoblastic differentiation. We assessed differences in the phosphorylation status of different cellular proteins upon BMP-2 osteogenic induction of isolated human skin mesenchymal stem cells using Triplex Stable Isotope Dimethyl Labeling coupled with LC/MS. From 150 µg of starting material, 2,264 proteins containing two or more peptides were identified and quantified at five different time points, 235 of which are differentially phosphorylated. Kinase motif analysis showed that several substrates display phosphorylation sites for Casein Kinase, p38, CDK and JNK. Gene ontology analysis showed an increase in biological processes related with signaling and differentiation at early time points after BMP2 induction. Moreover, proteins involved in cytoskeleton rearrangement, Wnt and Ras pathways were found to be differentially phosphorylated during all timepoints studied. Taken together, these data, allow new insights on the intracellular substrates which are phosphorylated early on during commitment to BMP2-driven osteoblastic differentiation of skin-derived mesenchymal stem cells. Cell clones overexpressing the human BMP 2 and 4 recombinant proteins were also generated, and their biological activity was confirmed in vitro. In parallel, chromatography-affinity purified rhBMP7, obtained using heparin-Sepharose columns, was used for in vivo and in vitro assays to evaluate the ability of this purified protein to generate osteoblasts and bone tissue, respectively, opening new avenues for the use of these proteins as biopharmaceuticals in Brazil

Unveiling novel genes upregulated by both rhBMP2 and rhBMP7 during early osteoblastic transdifferentiation of C2C12 cells.

FINDINGS: We set out to analyse the gene expression profile of pre-osteoblastic C2C12 cells during osteodifferentiation induced by both rhBMP2 and rhBMP7 using DNA microarrays. Induced and repressed genes were intercepted, resulting in 1,318 induced genes and 704 repressed genes by both rhBMP2 and rhBMP7. We selected and validated, by RT-qPCR, 24 genes which were upregulated by rhBMP2 and rhBMP7; of these, 13 are related to transcription (Runx2, Dlx1, Dlx2, Dlx5, Id1, Id2, Id3, Fkhr1, Osx, Hoxc8, Glis1, Glis3 and Cfdp1), four are associated with cell signalling pathways (Lrp6, Dvl1, Ecsit and PKCδ) and seven are associated with the extracellular matrix (Ltbp2, Grn, Postn, Plod1, BMP1, Htra1 and IGFBP-rP10). The novel identified genes include: Hoxc8, Glis1, Glis3, Ecsit, PKCδ, LrP6, Dvl1, Grn, BMP1, Ltbp2, Plod1, Htra1 and IGFBP-rP10. BACKGROUND: BMPs (bone morphogenetic proteins) are members of the TGFß (transforming growth factor-ß) super-family of proteins, which regulate growth and differentiation of different cell types in various tissues, and play a critical role in the differentiation of mesenchymal cells into osteoblasts. In particular, rhBMP2 and rhBMP7 promote osteoinduction in vitro and in vivo, and both proteins are therapeutically applied in orthopaedics and dentistry. CONCLUSION: Using DNA microarrays and RT-qPCR, we identified both previously known and novel genes which are upregulated by rhBMP2 and rhBMP7 during the onset of osteoblastic transdifferentiation of pre-myoblastic C2C12 cells. Subsequent studies of these genes in C2C12 and mesenchymal or pre-osteoblastic cells should reveal more details about their role during this type of cellular differentiation induced by BMP2 or BMP7. These studies are relevant to better understanding the molecular mechanisms underlying osteoblastic differentiation and bone repair.