Anna Di Vito

Influence of micro-patterned PLLA membranes on outgrowth and orientation of hippocampal neurites

In neuronal tissue engineering many efforts are focused on creating biomaterials with physical and chemical pathways for controlling cellular proliferation and orientation. Neurons have the ability to respond to topographical features in their microenvironment causing among others, axons to proliferate along surface features such as substrate grooves in micro-and nanoscales. As a consequence these neuronal elements are able to correctly adhere, migrate and orient within their new environment during growth. Here we explored the polarization and orientation of hippocampal neuronal cells on nonpatterned and micro-patterned biodegradable poly(l-lactic acid) (PLLA) membranes with highly selective permeable properties. Dense and porous nonpatterned and micro-patterned membranes were prepared from PLLA by Phase Separation Micromolding. The micro-patterned membranes have a three-dimensional structure consisting of channels and ridges and of bricks of different widths. Nonpatterned and patterned membranes were used for hippocampal neuronal cultures isolated from postnatal days 1-3 hamsters and the neurite length, orientation and specific functions of cells were investigated up to 12 days of culture. Neurite outgrowth, length plus orientation tightly overlapped the pattern of the membrane surface. Cell distribution occurred only in correspondence to membrane grooves characterized by continuous channels whereas on membranes with interconnected channels, cells not only adhered to and elongated their cellular processes in the grooves but also in the breaking points. High orientation degrees of cells were determined particularly on the patterned porous membranes with channel width of 20 mum and ridges of 17 mum whereas on dense nonpatterned membranes as well as on polystyrene culture dish (PSCD) controls, a larger number of primary developed neurites were distributed. Based on these results, PLLA patterned membranes may directly improve the guidance of neurite extension and thereby enhancing their orientation with a consequently highly ordered neuronal cell matrix, which may have strong bearings on the elucidation of regeneration mechanisms.

Distinct alpha subunits of the GABAA receptor are responsible for early hippocampal silent neuron-related activities.

The modulatory actions of GABAA receptor subunits are crucial for morphological and transcriptional neuronal activities. In this study, growth of hamster hippocampal neurons on biohybrid membrane substrates allowed us to show for the first time that the two major GABAA α receptor subunits (α2,5) are capable of early neuronal shaping plus expression differences of some of the main neuronal cytoskeletal factors (GAP‐43, the neurotrophin––BDNF) and of Gluergic subtypes. In a first case the inverse α5 agonist (RY‐080) seemed to account for the reduction of dendritic length at DIV7, very likely via lower BDNF levels. Conversely, the effects of the preferentially specific agonist for hippocampal α2 subunit (flunitrazepam) were, instead, directed at the formation of growth cones at DIV3 in the presence of greatly (P < 0.01) diminished GAP‐43 levels as displayed by strongly reduced axonal sprouting. It is interesting to note that concomitantly to these morphological variations, the transcription of some Gluergic receptor subtypes resulted to be altered. In particular, flunitrazepam was responsible for a distinctly rising expression of axonal NR1 mRNA levels from DIV3 (P < 0.01) until DIV7 (P < 0.001), whereas RY‐080 evoked a very great (P < 0.001) downregulation of dendritic GluR2 at only DIV7. Together, our results demonstrate that GABAA α2,5 receptor‐containing subunits by regulating the precise synchronization of cytoskeletal factors are considered key modulating neuronal elements of hippocampal morphological growth features. Moreover, the notable NR1 and GluR2 transcription differences promoted by these GABAA α subunits tend to favorably corroborate the early role of α2 + α5 on hippocampal neuronal networks in hibernating rodents through the recruitment and activation of silent neurons, and this may provide useful insights regarding molecular neurodegenerative events.

PAN hollow fiber membranes elicit functional hippocampal neuronal network.

This study focuses on the development of an advanced in vitro biohybrid culture model system based on the use of hollow fibre membranes (HFMs) and hippocampal neurons in order to promote the formation of a high density neuronal network. Polyacrylonitrile (PAN) and modified polyetheretherketone (PEEK-WC) membranes were prepared in hollow fibre configuration. The morphological and metabolic behaviour of hippocampal neurons cultured on PAN HF membranes were compared with those cultured on PEEK-WC HF. The differences of cell behaviour between HFMs were evidenced by the morphometric analysis in terms of axon length and also by the investigation of metabolic activity in terms of neurotrophin secretion. These findings suggested that PAN HFMs induced the in vitro reconstruction of very highly functional and complex neuronal networks. Thus, these biomaterials could potentially be used for the in vitro realization of a functional hippocampal tissue analogue for the study of neurobiological functions and/or neurodegenerative diseases.

Flat and tubular membrane systems for the reconstruction of hippocampal neuronal network.

The selection of appropriate biomaterials that promote cellular adhesion and growth is particularly important for the in vitro reconstruction of neuronal network. This study focused on the development of new polymeric membranes in flat and tubular (hollow‐fibre) configurations as novel biomaterials for neuronal outgrowth. Two membrane systems constituted by modified polyetheretherketone (PEEK‐WC) and polyacrylonitrile (PAN) membranes were developed and used for the culture of hamster hippocampal neurons. We demonstrated that all investigated membranes supported the adhesion and growth of hippocampal neurons enhancing neuronal differentiation and neurite alignment. The differences in cell behaviours between cells cultured on flat and hollow‐fibre (HF) membranes were highlighted by the quantitative analysis of neuronal marker fluorescence intensity, morphometric analysis, RT–PCR analysis and also by metabolic activity measurements. In particular, the PAN HF membranes showed ideal growth culture conditions, guaranteeing adequate levels of metabolic features. Primary hippocampal cells cultured on PAN HF membranes were able to recreate in vitro a 3D neural tissue‐like structure that, mimicking the hippocampal tissue, could be used as a tool for the study of natural and pathological neurobiological events. Copyright

Environmental stressors and neurobiological features of marine teleosts: histamine receptors as targets.

The excessive levels of aquatic endocrine disruptors (EDs) and namely heavy metals plus xenoestrogens account for irregular gas exchange processes, reduced reproductive success, as well as abnormal social interactions of marine teleost fish. These effects at the encephalic level appear to derive from the interference of major signaling factors such as histamine (HA) neuroreceptor subtypes (H1–4R). HA is one of the main biogenic amine neuronal system responsible for regulatory homeostatic functions, including sleep-wake rhythms and motor activities. Recently, interests have begun to focus attention on toxic effects of some heavy metals, i.e., cadmium (Cd) and lead (Pb), and how they are capable of eliciting motor dysfunctions via HAergic receptor subtypes. Interestingly, subtype 2 (H2R) proved to be a preferential target of heavy metal–dependent altered locomotor maneuvers, as displayed by its specific antagonist (cimetidine)-inducing non-synchronous swimming activities (, Pharmacol Biochem Behav 75:25–33). Conversely, although the preferential H3R antagonist (thioperamide) did not interfer with normal swimming behaviors, it surprisingly did ameliorate heavy metal–dependent hyperactive states (, Toxicol Appl Pharmacol 227:248–256). In the case of the xenoestrogens atrazine and endosulfan, their actions tend to mostly account for feeding alterations through hypothalamic H3R-dependent mechanisms. The aim of this review is to highlight the type of ED-HAergic neuroreceptor variations that are involved in stressor-dependent neurobehavioral responses of commercially valuable marine teleosts.

A reappraisal of macrophage polarization in glioblastoma: Histopathological and immunohistochemical findings and review of the literature

The survival rate in glioblastoma multiforme patients has scarcely improved in the last decades; however, many new therapeutic strategies have been theorized or developed for these neoplasias. Recently, the inverse correlation observed between patient prognosis and tumor-associated macrophages (TAMs) density in solid tumors has encouraged the development of anti-tumor strategies aiming to target TAMs. As expected, TAMs polarization is influenced by both macrophage localization and tumor microenvironment signals, resulting in a more complex scenario than the simple M1/M2 activation status. Macrophage polarization in glioblastoma has not yet been fully elucidated, and most results have been obtained in experimental non-human settings, with some apparent contradiction. The authors performed a histopathological and immunohistochemical study of 37 cases of glioblastoma in order to characterize the M1 and M2 macrophage populations within TAMs. A high prevalence of CD163+ M2-polarized macrophages was detected in this cohort, whereas iNOS+ macrophages were rarely found. The down-regulation of CD68 expression in microglia/macrophage infiltrating glioblastomas is also reported for the first time. Such a finding is associated with a specific location of TAMs within the lesion, as confirmed by the fact that CD68 staining was lower than CD163, mainly in perivascular areas. The authors discuss the recent literature about the global scenario of macrophage plasticity and polarization in glioblastoma, and suggest some pivotal points for therapeutic applications.

The mysterious pathways of cardiac myxomas: a review of histogenesis, pathogenesis and pathology

Cardiac myxoma is the most common benign cardiac tumour, localized generally in the left atrium. The majority of cardiac myxomas occur sporadically, while a relatively small proportion of cases develop as a part of Carney complex syndrome. Currently, the histogenesis of myxoma is poorly understood; however, the mesenchymal and endothelial properties of myxoma cells suggest that a clearer understanding of tumour origins can be achieved through a detailed investigation of heart development and endocardial histogenesis. Growing evidence appears to indicate the reactivated expression in cardiac myxoma of genes encoding heart precursor markers, although the exact mechanisms have not yet been described. In this paper we review the most recent scientific literature concerning cardiac embryology and relate this to recent advances in our understanding of the histogenesis of cardiac myxoma. Moreover, given that much of the literature regarding myxoma is of single case reports, we review progress in our knowledge of the pathology and pathogenesis of this condition.

H ferritin silencing induces protein misfolding in K562 cells: A Raman analysis

The redox state of the cell is involved in the regulation of many physiological functions as well as in the pathogenesis of several diseases, and is strictly dependent on the amount of iron in its catalytically active state. Alterations of iron homeostasis determine increased steady-state concentrations of Reactive Oxygen Species (ROS) that cause lipid peroxidation, DNA damage and altered protein folding. Ferritin keeps the intracellular iron in a non-toxic and readily available form and consequently plays a central role in iron and redox homeostasis. The protein is composed by 24 subunits of the H- and L-type, coded by two different genes, with structural and functional differences. The aim of this study was to shed light on the role of the single H ferritin subunit (FHC) in keeping the native correct protein three-dimensional structure. To this, we performed Raman spectroscopy on protein extracts from K562 cells subjected to FHC silencing. The results show a significant increase in the percentage of disordered structures content at a level comparable to that induced by H2O2 treatment in control cells. ROS inhibitor and iron chelator were able to revert protein misfolding. This integrated approach, involving Raman spectroscopy and targeted-gene silencing, indicates that an imbalance of the heavy-to-light chain ratio in the ferritin composition is able to induce severe but still reversible modifications in protein folding and uncovers new potential pathogenetic mechanisms associated to intracellular iron perturbation.

Lungfish aestivating activities are locked in distinct encephalic γ-aminobutyric acid type A receptor α subunits.

Ammonia in dipnoans plays a crucial role on neuronal homeostasis, especially for those brain areas that maintain torpor and awakening states in equilibrium. In the present study, specific α subunits of the major neuroreceptor inhibitory complex (GABAAR), which predominated during some phases of aestivation of the lungfish Protopterus annectens, turned out to be key adaptive factors of this species. From the isolation, for the first time, of the encoding sequence for GABAAR α1, α4, and α5 subunits in Protopterus annectens, qPCR and in situ hybridization levels of α4 transcript in thalamic (P < 0.001) and mesencephalic (P < 0.01) areas proved to be significantly higher during long aestivating maintenance states. Very evident α5 mRNA levels were detected in diencephalon during short inductive aestivating states, whereas an α4/α1 turnover characterized the arousal state. Contextually, the recovery of physiological activities appeared to be tightly related to an evident up‐regulation of α1 transcripts in telencephalic and cerebellar sites. Surprisingly, TUNEL and amino cupric silver methods corroborated apoptotic and neurodegenerative cellular events, respectively, above all in telencephalon and cerebellum of lungfish exposed to long maintenance aestivating conditions. Overall, these results tend to underlie a novel GABAergic‐related ON/OFF molecular switch operating during aestivation of the lungfish, which might have a bearing on sleeping disorders.

Distinct α subunit variations of the hypothalamic GABAA receptor triplets (αβγ) are linked to hibernating state in hamsters

BackgroundThe structural arrangement of the γ-aminobutyric acid type A receptor (GABAAR) is known to be crucial for the maintenance of cerebral-dependent homeostatic mechanisms during the promotion of highly adaptive neurophysiological events of the permissive hibernating rodent, i.e the Syrian golden hamster. In this study, in vitro quantitative autoradiography and in situ hybridization were assessed in major hypothalamic nuclei. Reverse Transcription Reaction-Polymerase chain reaction (RT-PCR) tests were performed for specific GABAAR receptor subunit gene primers synthases of non-hibernating (NHIB) and hibernating (HIB) hamsters. Attempts were made to identify the type of αβγ subunit combinations operating during the switching ON/OFF of neuronal activities in some hypothalamic nuclei of hibernators.ResultsBoth autoradiography and molecular analysis supplied distinct expression patterns of all α subunits considered as shown by a strong (p < 0.01) prevalence of α1 ratio (over total α subunits considered in the present study) in the medial preoptic area (MPOA) and arcuate nucleus (Arc) of NHIBs with respect to HIBs. At the same time α2 subunit levels proved to be typical of periventricular nucleus (Pe) and Arc of HIB, while strong α4 expression levels were detected during awakening state in the key circadian hypothalamic station, i.e. the suprachiasmatic nucleus (Sch; 60%). Regarding the other two subunits (β and γ), elevated β3 and γ3 mRNAs levels mostly characterized MPOA of HIBs, while prevalently elevated expression concentrations of the same subunits were also typical of Sch, even though this time during the awakening state. In the case of Arc, notably elevated levels were obtained for β3 and γ2 during hibernating conditions.ConclusionWe conclude that different αβγ subunits are operating as major elements either at the onset of torpor or during induction of the arousal state in the Syrian golden hamster. The identification of a brain regional distribution pattern of distinct GABAAR subunit combinations may prove to be very useful for highlighting GABAergic mechanisms functioning at least during the different physiological states of hibernators and this may have interesting therapeutic bearings on neurological sleeping disorders.