6 research outputs found
Классификация экзонов генов человека с использованием алгоритмов автоматического выбора атрибутов экзонов
Volkov AV, Yatskov NN, Grinev VV Classification of exons of human genes
using algorithms for automatic selection of exon attributesСекция 2.
МЕТОДЫ И ТЕХНОЛОГИИ МАТЕМАТИЧЕСКОГО
И ИМИТАЦИОННОГО МОДЕЛИРОВАНИЯ СИСТЕ
Dual modulation of inward rectifier potassium currents in olfactory neuronal cells by promiscuous G protein coupling of the oxytocin receptor
Oxytocin receptor is a seven transmembrane receptor widely expressed in the CNS that triggers G(i) or G(q) protein-mediated signaling cascades leading to the regulation of a variety of neuroendocrine and cognitive functions. We decided to investigate whether and how the promiscuous receptor/G protein coupling affects neuronal excitability. As an experimental model, we used the immortalized gonadotropin-releasing hormone-positive GN11 cell line displaying the features of immature, migrating olfactory neurons. Using RT-PCR analysis, we detected the presence of oxytocin receptors whose stimulation by oxytocin led to the accumulation of inositol phosphates and to the inhibition of cell proliferation, and the expression of several inward rectifier (IR) K+ channel subtypes. Moreover, electrophysiological and pharmacological inspections using whole-cell patch-clamp recordings evidenced that in GN11 cells, IR channel subtypes are responsive to oxytocin. In particular, we found that: (i) peptide activation of receptor either inhibited or stimulated IR conductances, and (ii) IR current inhibition was mediated by a pertussis toxin-resistant G protein presumably of the G(q/11) subtype, and by phospholipase C, whereas IR current activation was achieved via receptor coupling to a pertussis toxin-sensitive G(i/o) protein. The findings suggest that neuronal excitability might be tuned by a single peptide receptor that mediates opposing effects on distinct K+ channels through the promiscuous coupling to different G proteins
Mesenchymal stem cells enhance GABAergic transmission in co-cultured hippocampal neurons
Bone marrow-derived mesenchymal stem cells (MSCs) are multipotent stem cells endowed with neurotrophic
potential combined with immunological properties, making them a promising therapeutic tool for
neurodegenerative disorders. However, the mechanisms through which MSCs promote the neurological recovery
following injury or inflammation are still largely unknown, although cell replacement and paracrine
mechanisms have been hypothesized. In order to find out what are the mechanisms of the trophic action
of MSCs, as compared to glial cells, on CNS neurons, we set up a co-culture system where rat MSCs (or cortical
astrocytes) were used as a feeding layer for hippocampal neurons without any direct contact between the
two cell types. The analysis of hippocampal synaptogenesis, synaptic vesicle recycling and electrical activity
show that MSCs were capable to support morphological and functional neuronal differentiation. The proliferation
of hippocampal glial cells induced by the release of bioactive substance(s) from MSCs was necessary for
neuronal survival. Furthermore, MSCs selectively increased hippocampal GABAergic pre-synapses. This effect
was paralleled with a higher expression of the potassium/chloride KCC2 co-transporter and increased
frequency and amplitude of mIPSCs and sIPSCs. The enhancement of GABA synapses was impaired by the
treatment with K252a, a Trk/neurotrophin receptor blocker, and by TrkB receptor bodies hence suggesting
the involvement of BDNF as a mediator of such effects.
The results obtained here indicate that MSC-secreted factors induce glial-dependent neuronal survival and
trigger an augmented GABAergic transmission in hippocampal cultures, highlighting a new effect by which
MSCs could promote CNS repair. Our results suggest that MSCs may be useful in those neurological disorders
characterized by an impairment of excitation versus inhibition balance
Retinoic acid- and phorbol ester-induced neuronal differentiation down-regulates caveolin expression in GnRH neurons
GN11 and GT1-7 are immortalized gonadotropin-releasing hormone-positive murine cell lines exhibiting the features of immature olfactory neurons and differentiated hypothalamic neurons, respectively. Using electron microscopy and biochemical assays (RT-PCR and immunoblotting) we determined the presence of numerous caveolae invaginations and of caveolin-1 and -2 mRNAs and proteins in GN11 cells, and their absence in GT1-7 cells. The lack of caveolins in GT1-7 cells might be due to the silencing of gene transcription caused by estrogen receptor alpha whose inhibitory activity in GN11 cells could be counter-balanced by co-expression of caveolin-permissive estrogen receptor beta. To test whether the unique expression of caveolins in GN11 cells is related to their immature state, we treated GN11 cells for 24-72 h with retinoic acid or phorbol ester. Both treatments led to neuronal differentiation of GN11 cells, as shown by emission of long neuritic processes, increased expression of growth cone-associated protein-43 and appearance of voltage-gated K+ and C2+ channel currents. Concurrently, caveolins 1 and 2, and estrogen receptor beta were down-regulated in differentiated GN11, whereas estrogen receptor alpha was unaffected by differentiation. We conclude that caveolin expression in GN11 neurons is down-regulated upon differentiation and up-regulated by estrogen receptor beta