Carlo Cenciarelli

Critical Role Played by Cyclin D3 in the MyoD-Mediated Arrest of Cell Cycle during Myoblast Differentiation

ABSTRACT During the terminal differentiation of skeletal myoblasts, the activities of myogenic factors regulate not only tissue-specific gene expressions but also the exit from the cell cycle. The induction of cell cycle inhibitors such as p21 and pRb has been shown to play a prominent role in the growth arrest of differentiating myoblasts. Here we report that, at the onset of differentiation, activation by MyoD of the Rb, p21, and cyclin D3 genes occurs in the absence of new protein synthesis and with the requirement of the p300 transcriptional coactivator. In differentiated myocytes, cyclin D3 also becomes stabilized and is found nearly totally complexed with unphosphorylated pRb. The detection of complexes containing cyclin D3, cdk4, p21, and PCNA suggests that cdk4, along with PCNA, may get sequestered into high-order structures held together by pRb and cyclin D3. Cyclin D3 up-regulation and stabilization is inhibited by adenovirus E1A, and this correlates with the ability of E1A to promote pRb phosphorylation; conversely, the overexpression of cyclin D3 in differentiated myotubes counteracts the E1A-mediated reactivation of DNA synthesis. These results indicate that cyclin D3 critically contributes to the irreversible exit of differentiating myoblasts from the cell cycle.

Influence of local environment on the differentiation of neural stem cells engrafted onto the injured spinal cord.

Abstract Objectives: In vitro, neural stem cells (NSCs) proliferate as undifferentiated spheroids and differentiate into neurons, astrocytes and oligodendrocytes. These features make NSCs suitable for spinal cord (SC) reconstruction. However, in vivo experiments have demonstrated that in the injured SC transplanted NSCs either remain undifferentiated or differentiate into the astrocytic phenotype. The microenvironment of the injured SC is believed to play a crucial role in driving the differentiation of the engrafted NSCs. Here, we tested the hypothesis that inflammatory cytokines (ICs) may be involved in the restricted differentiation of NSCs after grafting onto the injured SC. Methods: As the first step, we used immunohistochemistry to analyse the expression of tumor necrosis factor (TNF)-α, interleukin (IL)-1β and interferon (IFN)-γ in the normal SC of mice and following traumatic injury. Then, we investigated whether a combination of TNF-α, IL-1β and IFN-γ may affect the phenotype of murine NSCs in vitro. Results: We found that TNF-α, IL–1β and IFN-γ, which are absent in the normal SC, are all expressed in the injured SC and the expression of these cytokines follows a timely tuned fashion with IFN-γ being detectable as long as 4 weeks after injury. In culture, exposure of proliferating NSCs to a combination of TNF-α, IL–1β and IFN-γ was per se sufficient to induce the astrocytic differentiation of these cells even in the absence of serum. Conclusions: In the traumatically injured SC, differentiation of engrafted NSCs is restricted towards the astrocytic lineage because of the inflammatory environment. ICs are likely to play a major role in differentiation of NSCs in the in vivo conditions.

Human microbiome and its association with health and diseases

Human microbiota are distinct communities of microorganisms that resides at different body niches. Exploration of the human microbiome has become a reality due to the availability of powerful metagenomics and metatranscriptomic analysis technologies. Recent advances in sequencing and bioinformatics over the past decade help provide a deep insight into the nature of the host‐microbial interactions and identification of potential deriver genes and pathways associated with human health, well‐being, and predisposition to different diseases. In the present review, we outline recent studies devoted to elucidate the possible link between the microbiota and various type of diseases. The present review also highlights the potential utilization of microbiota as a potential therapeutic option to treat a wide array of human diseases. J. Cell. Physiol. 231: 1688–1694, 2016.

In vitro analysis of mouse neural stem cells genetically modified to stably express human NGF by a novel multigenic viral expression system

Abstract Objectives: The purpose of this study was to characterize mouse neural stem cells (NSC) transduced by a multigenic lentiviral vector (LV) and stably express recombinant human nerve growth factor (rhNGF). We obtained NSC-derived cell lines which express human NGF in relevant amount to exploit their ability for therapeutic applications. Methods: We constructed advanced multigenic LV vectors which contain a tricistronic cassette to express simultaneously up to three independent genes: (1) rhNGF (β subunit); (2) EGFP (enhanced green fluorescent protein) and (3) NeoR (neomycin antibiotic resistance gene). Lentiviruses were obtained by transfecting LV constructs plus helper plasmids in human embryonic kidney (HEK)-293T packaging cells. Lentiviral virions were released in culture media and subsequent used to infect mouse NSC. Genetycin 418-resistant NSC were obtained after 1 month of selection in the presence of antibiotic (G418). Levels of human NGF secreted by rhNGF-NSC were determined by ELISA (enzyme-linked immunosorbent assay). Features of multipotentiality of engineered NSC-derived cell lines versus naive cells (control-NSC) were assessed by immunocytochemical analysis in differentiation conditions. Self-renewal of NSC was tested by neurospheres assay (NSA). Results: Levels of secreted human NGF, from conditioned media obtained by rhNGF-NSC cultures, were found to be elevated in either proliferation or differentiation conditions as compared with control cells. Moreover, released hNGF demonstrated biologic activity on PC12 cells by a functional test of neurite outgrowth. Immunocytochemical analysis revealed that engineered NSC showed to be all positives for EGFP. After thirty passages in vitro in the presence of G418, engineered cells versus naive NSC cultures maintained their multipotentiality to differentiate into neurons, astrocytes and oligodendrocytes. Furthermore, it was found that rhNGF-NSC-derived neurons expressed choline acetyltransferase (ChAT) and displayed an enhanced axonal growth. NSA showed an altered sphere forming frequency either in rhNGF-NSC or both group of control NSC. Discussion: Lentivirus-mediated rhNGF gene transfer into NSC was achieved using a new version of LV vectors. We obtained rhNGF-NSC-derived cell lines which released hNGF to high levels in the culture medium. The expression of neural differentiation markers, like microtubule associated protein 2 (MAP2) (a/b), glial fibrillary acidic protein (GFAP) and chondroitin sulphate proteoglycan (NG2), was not enhanced in rhNGF-NSC compared with control cells. Secreted hNGF increased axonal sprouting by rhNGF-NSC-derived neurons which was associated with ChAT expression. rhNGF-NSC may prospectively be good candidates for the treatment of either neurodegenerative diseases such as Alzheimer disease or central nervous system injuries.

PDGF receptor alpha inhibition induces apoptosis in glioblastoma cancer stem cells refractory to anti-Notch and anti-EGFR treatment

BackgroundCancer stem cells (CSC) represent a rare fraction of cancer cells characterized by resistance to chemotherapy and radiation, therefore nowadays there is great need to develop new targeted therapies for brain tumors and our study aim to target pivotal transmembrane receptors such as Notch, EGFR and PDGFR, which are already under investigation in clinical trials setting for the treatment of Glioblastoma Multiforme (GBM).MethodsMTS assay was performed to evaluate cells response to pharmacological treatments. Quantitative RT-PCR and Western blots were performed to state the expression of Notch1, EGFR and PDGFRα/β and the biological effects exerted by either single or combined targeted therapy in GBM CSC. GBM CSC invasive ability was tested in vitro in absence or presence of Notch and/or EGFR signaling inhibitors.ResultsIn this study, we investigated gene expression and function of Notch1, EGFR and PDGFR to determine their role among GBM tumor core- (c-CSC) vs. peritumor tissue-derived cancer stem cells (p-CSC) of six cases of GBM. Notch inhibition significantly impaired cell growth of c-CSC compared to p-CSC pools, with no effects observed in cell cycle distribution, apoptosis and cell invasion assays. Instead, anti-EGFR therapy induced cell cycle arrest, sometimes associated with apoptosis and reduction of cell invasiveness in GBM CSC. In two cases, c-CSC pools were more sensitive to simultaneous anti-Notch and anti-EGFR treatment than either therapy alone compared to p-CSC, which were mostly resistant to treatment. We reported the overexpression of PDGFRα and its up-regulation following anti-EGFR therapy in GBM p-CSC compared to c-CSC. RNA interference of PDGFRα significantly reduced cell proliferation rate of p-CSC, while its pharmacological inhibition with Crenolanib impaired survival of both CSC pools, whose effects in combination with EGFR inhibition were maximized.ConclusionsWe have used different drugs combination to identify the more effective therapeutic targets for GBM CSC, particularly against GBM peritumor tissue-derived CSC, which are mostly resistant to treatments. Overall, our results provide the rationale for simultaneous targeting of EGFR and PDGFR, which would be beneficial in the treatment of GBM.

Brahma is required for cell cycle arrest and late muscle gene expression during skeletal myogenesis

Although the two catalytic subunits of the SWI/SNF chromatin‐remodeling complex—Brahma (Brm) and Brg1—are almost invariably co‐expressed, their mutually exclusive incorporation into distinct SWI/SNF complexes predicts that Brg1‐ and Brm‐based SWI/SNF complexes execute specific functions. Here, we show that Brg1 and Brm have distinct functions at discrete stages of muscle differentiation. While Brg1 is required for the activation of muscle gene transcription at early stages of differentiation, Brm is required for Ccnd1 repression and cell cycle arrest prior to the activation of muscle genes. Ccnd1 knockdown rescues the ability to exit the cell cycle in Brm‐deficient myoblasts, but does not recover terminal differentiation, revealing a previously unrecognized role of Brm in the activation of late muscle gene expression independent from the control of cell cycle. Consistently, Brm null mice displayed impaired muscle regeneration after injury, with aberrant proliferation of satellite cells and delayed formation of new myofibers. These data reveal stage‐specific roles of Brm during skeletal myogenesis, via formation of repressive and activatory SWI/SNF complexes.

Identification and early characterization of genetically modified NGF-producing neural stem cells grafted into the injured adult rat brain

Abstract Objective: To investigate whether genetically modified mouse neural stem cells (NSC) expressing recombinant human nerve growth factor (rhNGF) and transplanted in chemically injured rat brain, can survive and eventually acquire phenotypic characteristics of early nerve cells. Methods: Stably high expression of rhNGF in NSC was obtained by a new lentivirus-mediated expression system. To test the effectiveness of hNGF secreted by rhNGF-NSC, hereby we performed either a bioassay for neurite outgrowth in PC12 rat cells or immunoblot analysis for TrkA, the high-affinity NGF receptor, from engineered NSC. rhNGF and mock-NSC were grafted into adult injured rats striatum and 3 days later, animals were killed, and brains were removed and examined by immunohistochemical analysis. Results: The results showed that rhNGF-producing NSC cultured for extended period of time release bioactive hNGF in the culture media which promotes PC12 neuronal differentiation and correlates with the up-regulation of TrkA. rhNGF-NSC transplanted into the injured brain can survive, produce hNGF and induce the expression of NGF receptors, p75NTR and TrkA. Discussion: In vitro and in vivo experiments confirmed the ability of rhNGF-NSC to secrete bioactive hNGF. Our data provide by means of genetically modified rhNGF-producing NSC, a useful experimental tool to test the potential clinical effectiveness of trophic factors relevant to central nervous system (CNS).

Common and Rare Genetic Variants Associated With Alzheimer's Disease

Alzheimers disease (AD) is one of the most devastating disorders. Despite the continuing increase of its incidence among aging populations, no effective cure has been developed mainly due to difficulties in early diagnosis of the disease before damaging of the brain, and the failure to explore its complex underlying molecular mechanisms. Recent technological advances in genome‐wide association studies (GWAS) and high throughput next generation whole genome, and exome sequencing had deciphered many of AD‐related loci, and discovered single nucleotide polymorphisms (SNPs) that are associated with altered AD molecular pathways. Highlighting altered molecular pathways linked to AD pathogenesis is crucial to identify novel diagnostic and therapeutic AD targets. J. Cell. Physiol. 231: 1432–1437, 2016.

Common and Rare Variants Associated with Alzheimer's Disease

Alzheimers disease (AD) is one of the most devastating disorders. Despite the continuing increase of its incidence among aging populations, no effective cure has been developed mainly due to difficulties in early diagnosis of the disease before damaging of the brain, and the failure to explore its complex underlying molecular mechanisms. Recent technological advances in genome‐wide association studies (GWAS) and high throughput next generation whole genome, and exome sequencing had deciphered many of AD‐related loci, and discovered single nucleotide polymorphisms (SNPs) that are associated with altered AD molecular pathways. Highlighting altered molecular pathways linked to AD pathogenesis is crucial to identify novel diagnostic and therapeutic AD targets. J. Cell. Physiol. 231: 1432–1437, 2016.

Cholinergic and dopaminergic neuronal differentiation of human adipose tissue derived mesenchymal stem cells

Mesenchymal stem cells (MSCs) are multipotent cells that can differentiate into various cell types such as cartilage, bone, and fat cells. Recent studies have shown that induction of MSCs in vitro by growth factors including epidermal growth factor (EGF) and fibroblast growth factor (FGF2) causes them to differentiate into neural like cells. These cultures also express ChAT, a cholinergic marker; and TH, a dopaminergic marker for neural cells. To establish a protocol with maximum differentiation potential, we examined MSCs under three experimental culture conditions using neural induction media containing FGF2, EGF, BMP‐9, retinoic acid, and heparin. Adipose‐derived MSCs were extracted and expanded in vitro for 3 passages after reaching >80% confluency, for a total duration of 9 days. Cells were then characterized by flow cytometry for CD markers as CD44 positive and CD45 negative. MSCs were then treated with neural induction media and were characterized by morphological changes and Q‐PCR. Differentiated MSCs expressed markers for immature and mature neurons; β Tubulin III (TUBB3) and MAP2, respectively, showing the neural potential of these cells to differentiate into functional neurons. Improved protocols for MSCs induction will facilitate and ensure the reproducibility and standard production of MSCs for therapeutic applications in neurodegenerative diseases.