Daniele Bottai

Designer Self-Assembling Peptide Nanofiber Scaffolds for Adult Mouse Neural Stem Cell 3-Dimensional Cultures

Biomedical researchers have become increasingly aware of the limitations of conventional 2-dimensional tissue cell culture systems, including coated Petri dishes, multi-well plates and slides, to fully address many critical issues in cell biology, cancer biology and neurobiology, such as the 3-D microenvironment, 3-D gradient diffusion, 3-D cell migration and 3-D cell-cell contact interactions. In order to fully understand how cells behave in the 3-D body, it is important to develop a well-controlled 3-D cell culture system where every single ingredient is known. Here we report the development of a 3-D cell culture system using a designer peptide nanofiber scaffold with mouse adult neural stem cells. We attached several functional motifs, including cell adhesion, differentiation and bone marrow homing motifs, to a self-assembling peptide RADA16 (Ac-RADARADARADARADA-COHN2). These functionalized peptides undergo self-assembly into a nanofiber structure similar to Matrigel. During cell culture, the cells were fully embedded in the 3-D environment of the scaffold. Two of the peptide scaffolds containing bone marrow homing motifs significantly enhanced the neural cell survival without extra soluble growth and neurotrophic factors to the routine cell culture media. In these designer scaffolds, the cell populations with β-Tubulin+, GFAP+ and Nestin+ markers are similar to those found in cell populations cultured on Matrigel. The gene expression profiling array experiments showed selective gene expression, possibly involved in neural stem cell adhesion and differentiation. Because the synthetic peptides are intrinsically pure and a number of desired function cellular motifs are easy to incorporate, these designer peptide nanofiber scaffolds provide a promising controlled 3-D culture system for diverse tissue cells, and are useful as well for general molecular and cell biology.

Embryonic stem cells promote motor recovery and affect inflammatory cell infiltration in spinal cord injured mice.

The purpose of this study was to determine the fate and the effects of undifferentiated embryonic stem cells (ESCs) in mice after contusive lesion of the spinal cord (SCI). Reproducible traumatic lesion to the cord was performed at T8 level by means of the Infinite Horizon Device, and was followed by intravenous injection of one million of undifferentiated ESCs through the tail vein within 2 h from the lesion. The ESCs-treated animals showed a significant improvement of the recovery of motor function 28 days after lesion, with an average score of 4.61+/-0.13 points of the Basso Mouse Scale (n=14), when compared to the average score of vehicle treated mice, 3.58+/-0.23 (n=10). The number of identified ESCs found at the lesion site was 0.6% of the injected cells at 1 week after transplantation, and further reduced to 0.04% at 1 month. It is, thus, apparent that the promoted hind-limb recovery cannot be correlated to a substitution of the lost tissue performed by the exogenous ESC. The extensive evaluation of production of several neuroprotective and inflammatory cytokines did not reveal any effect by ESC-treatment, but unexpectedly the number of invading macrophages and neutrophils was greatly reduced. This may explain the improved preservation of lesion site ventral myelin, at both 1 week (29+/-11%) and 1 month (106+/-14%) after injury. No teratoma formation was observed, although an inappropriate colonization of the sacral cord by differentiated nestin- and beta-tubulin III-positive ESCs was detected.

Adult neural precursors isolated from post mortem brain yield mostly neurons: An erythropoietin-dependent process

This study was aimed at the isolation of neural precursor cells (NPCs) capable of resisting to a prolonged ischemic insult as this may occur at the site of traumatic and ischemic CNS injuries. Adult mice were anesthetized and then killed by cervical dislocation. The cadavers were maintained at room temperature or at 4°C for different time periods. Post mortem neural precursors (PM-NPCs) were isolated, grown in vitro and their differentiation capability was investigated by evaluating the expression of different neuronal markers. PM-NPCs differentiate mostly in neurons, show activation of hypoxia-inducible factor-1 and MAPK, and express both erythropoietin (EPO) and its receptor (EPO-R). The exposure of PM-NPCs to neutralizing antibodies to EPO or EPO-R dramatically reduced the extent of neuronal differentiation to about 11% of total PM-NPCs. The functionality of mTOR and MAPK is also required for the expression of the neuronal phenotype by PM-NPCs. These results suggest that PM-NPCs can be isolated from animal cadaver even several hours after death and their self-renewable capability is comparable to normal neural precursors. Differently, their ability to achieve a neural phenotype is superior to that of NPCs, and this is mediated by the activation of hypoxia-induced factor 1 and EPO signaling. PM-NPCs may represent good candidates for transplantation studies in animal models of neurodegenerative diseases.

The Stem Cells as a Potential Treatment for Neurodegeneration

Cell degeneration and death, be it extensive and widespread, such as in metabolic disorders, or focal and selective as in Parkinsons disease (PD), is the underlying feature of many neurological diseases. Thus, the replacement of cells lost by injury or disease has become a central tenet in strategies aiming at the development of novel therapeutic approaches for neurodegenerative disorders. In addition to the in vivo recruitment of endogenous cells, which is now emerging as a promising novel strategy, the transplantation of new, exogenously generated brain cells is probably the most extensively studied methodology for cell replacement in the central nervous system, with the initial experimental clinical studies in PD dating back to the early 1970s (Bjorklund, A. and Stenevi, U., 1984, Intracerebral neural implants: neuronal replacement and reconstruction of damaged circuitries. Annu Rev Neurosci 7, 279-308; Snyder, B. J. and Olanow, C. W., 2005, Stem cell treatment for Parkinsons disease: an update for 2005. Curr Opin Neurol 18, 376-85). The need to generate the cells to be transplanted in large quantities and in a reproducible, steady, and safe fashion has long represented one of the major issues in this field, regardless of whether one was trying to produce specific cell subtypes or uncommitted and highly plastic neural precursors, which would respond to local, instructive cues, upon transplantation into the damaged area. Neural stem cells (NSCs), with their capacity for long-term expansion in vitro and their extensive functional stability and plasticity, allow now for the establishment of cultures of mature neural cells as well as highly undifferentiated precursors and are emerging as one of the most amenable cell sources for neural transplantation (Gage, F. H., 2000, Mammalian neural stem cells. Science 287, 1433-8; McKay, R., 1997, Stem cells in the central nervous system. Science 276, 66-71). This chapter illustrates the basic aspect of the handling and preparation of NSCs for experimental transplantation in two animal models of neurodegenerative disorders, namely, postcontusion spinal cord injury and multiple sclerosis.

Third trimester amniotic fluid cells with the capacity to develop neural phenotypes and with heterogeneity among sub-populations

PURPOSE Our aim was the search for new sources of cells potentially useful for central nervous system regenerative medicine. Extra-embryonic tissues are promising sources of pluripotent stem cells. Among these, human second-trimester amniotic fluid (AF) contains cell populations exhibiting self-renewal capacity, multipotency and the expression of embryonic cell markers. METHODS Here we report the properties of the easily available third-trimester AF cells (AFCs). Different cell types from 6 of 9 AF samples were separated, expanded, and characterized by assessing their morphological, proliferative, and differentiative properties. RESULTS All isolated cultures presented CD105, CD90 and CD73 mesenchymal markers, whereas they differed among themselves in CD117, CD146, CD31, NG2 and CD133 expression. Their doubling time and telomere length were conserved throughout many passages. Importantly, immunofluorescence and Real-time PCR showed that, during their proliferative state and differentiation, several cultures expressed neuronal and glial markers such as nestin, GFAP, β-tubulin III and neurofilament H indicating their potential attitude towards a neural fate. Indeed, these cells showed a rather poor capacity to differentiate in adipogenic and osteogenic lineages. CONCLUSIONS In this work we report that cells with neural differentiation capability can be isolated from third-trimester AF, such properties could be useful for neuro-regenerative purposes.

Third trimester NG2-positive amniotic fluid cells are effective in improving repair in spinal cord injury.

Spinal cord injury presents a significant therapeutic challenge since the treatments available are mostly vain. The use of stem cells to treat this condition represents a promising new therapeutic strategy; therefore, a variety of stem cell treatments have been recently examined in animal models of CNS trauma. In this work, we analyzed the effects of third trimester amniotic fluid cells in a mouse model of spinal cord injury. Among the different cultures used for transplantation, some were able to induce a significant improvement in motor recovery (cultures #3.5, #3.6 and #7.30), evaluated by means of open field free locomotion. All effective cell cultures expressed the surface marker nerve/glial antigen 2, ortholog of the human chondroitin sulfate proteoglycan 4, which is present on several types of immature progenitor cells. The improved motor functional recovery was correlated with higher myelin preservation in the ventral horn white matter and an increased vascularization in the peri-lesion area. Real-Time PCR analysis showed higher expression levels of vascular endothelial growth factor and hypoxia-inducible factor-1α mRNA two days after cells transplantation compared to PBS-treated animals, indicating that an angiogenic pathway might have been activated by these cells, possibly through the production of hepatocyte growth factor. This cytokine appears to be produced mostly in filtering organs, such as the lung, of the transplanted animals and is likely released in the blood suggesting an endocrine role of hepatocyte growth factor in targeting the injury site.

Stem cell transplantation in neurological diseases: improving effectiveness in animal models.

Neurological diseases afflict a growing proportion of the human population. There are two reasons for this: first, the average age of the population (especially in the industrialized world) is increasing, and second, the diagnostic tools to detect these pathologies are now more sophisticated and can be used on a higher percentage of the population. In many cases, neurological disease has a pharmacological treatment which, as in the case of Alzheimers disease, Parkinsons disease, Epilepsy, and Multiple Sclerosis can reduce the symptoms and slow down the course of the disease but cannot reverse its effects or heal the patient. In the last two decades the transplantation approach, by means of stem cells of different origin, has been suggested for the treatment of neurological diseases. The choice of slightly different animal models and the differences in methods of stem cell preparation make it difficult to compare the results of transplantation experiments. Moreover, the translation of these results into clinical trials with human subjects is difficult and has so far met with little success. This review seeks to discuss the reasons for these difficulties by considering the differences between human and animal cells (including isolation, handling and transplantation) and between the human disease model and the animal disease model.

Spinal muscular atrophy: new findings for an old pathology.

Understanding the events that are responsible for a disease is mandatory for setting up a therapeutic strategy. Although spinal muscular atrophy (SMA) is considered a rare neurodegenerative pathology, its impact in our society is really devastating as it strikes young people from birth onward, and it affects their families either emotionally or financially. Moreover, it requires intensive care for the children, and this diverts both parents and relatives from their occupations. Each neuron is very different from one another; therefore, in a neurodegenerative disease, the population of axons, synapses and cell bodies degenerate asynchronously, and subpopulations of neurons have different vulnerabilities. The knowledge of the sequence of events along the lengths of individual neurons is crucial to understand if each synapse degenerates before the corresponding axon, or if each axon degenerates before the corresponding cell body. Early degeneration of one neuronal compartment in disease often reflects molecular defects somewhere else. Up until now, SMA is considered mostly a lower motor neuron disease caused by the loss‐of‐function mutations in the SMN1 gene; here, we inspect other features that can be altered by this defect, such as the cross talk between muscle and motor neuron and the role of physical inactivity.

Acrylate end-capped poly(ester-carbonate) and poly(ether-ester)s for polymer-on-multielectrode array devices: synthesis, photocuring and biocompatibility

Polymeric materials based on epsilon-caprolactone (CL), 1,5-dioxepan-2-one (DXO), and trimethylene carbonate (TMC) were prepared and evaluated as possible candidates for polymer-on-multielectrode (PoM) applications. CL was copolymerized with either DXO or TMC in the presence of the diol initiator 1,4-benzenedimethanol (BDM). The ring-opening polymerization experiments, carried out in bulk and using tin(II) catalysis, yielded the desired low molecular weight random copolymer diols, as evidenced by NMR, IR, MALDI-ToF MS, and DSC techniques. Upon reaction with acryloyl chloride, the corresponding diacrylate end-capped copolymers were obtained. The latter were characterized by NMR and IR spectroscopy, and their photocross-linking (in the presence of a UV initiator) was followed by ATR-FTIR spectroscopy. Transparent and soft thin films of the copoly(ether-ester) and copoly(ester-carbonate) diacrylates were prepared and cured under UV irradiation. The resulting polymeric films showed good biocompatibility properties as far as in vitro neural stem cells proliferation and differentiation to neurons and astrocytes are concerned. Noteworthy are the beneficial effects obtained upon preconditioning the copolymers by means of the cell-culture medium and the excellent properties shown particularly by the CL-TMC copolymer. Moreover, preliminary results show that microchannel formation by photocuring is possible with the synthesized polymers.

Establishment of an induced pluripotent stem cell (iPSC) line from a patient with Clozapine-responder Schizophrenia

Peripheral blood mononuclear cells (PBMCs) were collected from a patient with treatment-refractory Schizophrenia who presented an exceptional clinical response to Clozapine. iPSC lines were established with a non-integrating reprogramming system based on Sendai virus. A footprint-free hiPSC line was characterized to confirm the expression of the main endogenous pluripotency markers and have a regular karyotype. Pluripotency was confirmed by differentiation into cells belonging to the three germ layers. This hiPSC line represents a valuable tool to study the molecular, biochemical and electrophysiological properties of mature neuronal populations belonging to Clozapine responder patients with a severe form of Schizophrenia.