Neuron-specific and developmental regulation of the synapsin II gene expression in transgenic mice

Direct Conversion of Equine Adipose-Derived Stem Cells into Induced Neuronal Cells Is Enhanced in Three-Dimensional Culture

The ability to culture neurons from horses may allow further investigation into equine neurological disorders. In this study, we demonstrate the generation of induced neuronal cells from equine adipose-derived stem cells (EADSCs) using a combination of lentiviral vector expression of the neuronal transcription factors Brn2, Ascl1, Myt1l (BAM) and NeuroD1 and a defined chemical induction medium, with βIII-tubulin-positive induced neuronal cells displaying a distinct neuronal morphology of rounded and compact cell bodies, extensive neurite outgrowth, and branching of processes. Furthermore, we investigated the effects of dimensionality on neuronal transdifferentiation, comparing conventional two-dimensional (2D) monolayer culture against three-dimensional (3D) culture on a porous polystyrene scaffold. Neuronal transdifferentiation was enhanced in 3D culture, with evenly distributed cells located on the surface and throughout the scaffold. Transdifferentiation efficiency was increased in 3D culture, with an increase in mean percent conversion of more than 100% compared to 2D culture. Additionally, induced neuronal cells were shown to transit through a Nestin-positive precursor state, with MAP2 and Synapsin 2 expression significantly increased in 3D culture. These findings will help to increase our understanding of equine neuropathogenesis, with prospective roles in disease modeling, drug screening, and cellular replacement for treatment of equine neurological disorders.

Expressive proteomics profile changes of injured human brain cortex due to acute brain trauma

OBJECTIVE

To find the expressive proteomics changes in damaged human brain cortex after traumatic brain injury (TBI).

METHOD

By rapid high-throughput and precise proteomic techniques, the traumatic injured human frontal cortexes were compared with non-trauma controls.

RESULTS

On 2-DE PAGE, 138 protein spots were found significantly different on expressive level of quantitative mature. Most of these proteins expressed in a fluctuant fashion within 18 hours after trauma, with mean levels lower than control. Eighty-two protein spots were identified by MALDI-MS TOF, which were products of 71 proteins and could be grouped into 10 categories based on possible functions: cytoskeleton (n = 10), metabolism (n = 13), electron transport (n = 8), signalling transduction (n = 4), stress response (n = 6), protein synthesis and turnover (n = 8), transporter (n = 5), cell cycle (n = 1), other (n = 8) and unknown (n = 9).

CONCLUSION

After traumatic brain injury, there are significant proteins expressing changes in damaged brain tissue. These proteins may play a critical role in TBI. Although some of these proteins functions are not fully understood, they may become novel biomarkers and novel therapy targets in the future.

Phosphorylation of parkin by Parkinson disease-linked kinase PINK1 activates parkin E3 ligase function and NF-kappaB signaling

Mutations in PTEN-induced putative kinase 1 (PINK1) or parkin cause autosomal recessive forms of Parkinson disease (PD), but how these mutations trigger neurodegeneration is poorly understood and the exact functional relationship between PINK1 and parkin remains unclear. Here, we report that PINK1 regulates the E3 ubiquitin-protein ligase function of parkin through direct phosphorylation. We find that phosphorylation of parkin by PINK1 activates parkin E3 ligase function for catalyzing K63-linked polyubiquitination and enhances parkin-mediated ubiquitin signaling through the IkappaB kinase/nuclear factor kappaB (NF-kappaB) pathway. Furthermore, the ability of PINK1 to promote parkin phosphorylation and activate parkin-mediated ubiquitin signaling is impaired by PD-linked pathogenic PINK1 mutations. Our findings support a direct link between PINK1-mediated phosphorylation and parkin-mediated ubiquitin signaling and implicate the deregulation of the PINK1/parkin/NF-kappaB neuroprotective signaling pathway in the pathogenesis of PD.

Long-lasting effects of elevated neonatal leptin on rat hippocampal function, synaptic proteins and NMDA receptor subunits

The high circulating levels of leptin in neonatal rodents do not seem to be regulating energy balance at this age, but rather may play an important role for brain development. We tested the hypothesis that high neonatal leptin levels modify hippocampal function and production of synaptic proteins with possible long-term consequences on long-term potentiation (LTP) in adulthood. We first showed that in postnatal day (PND) 10 neonates, acute leptin treatment functionally activated leptin receptors (ObR) in the CA1 and DG regions of the hippocampus through the induction of phosphoERK1/2, but not phosphoSTAT3 protein although both phospho-proteins were induced in the arcuate nucleus. We next examined whether chronic leptin administration (3 mg/kg BW, intraperitoneally) during the first 2 weeks of life (postnatal day, PND 2-14) produces a functional signal in the hippocampus that alters the expression of NMDA receptor subunits (NR1, NR2A, NR2B), synaptic proteins and LTP in the short and long-term. In PND 10 as in adults (PND 70) rats, chronic leptin treatment increased NR1 expression in the hippocampus while reducing NR2B protein levels. Elevated hippocampal concentrations of synapsin2A and synaptophysin were detected during leptin treatment on PND 10 suggesting increased neurotransmitter release. In adults, only SNAP-25 expression was increased after neonatal leptin treatment. LTP was reduced dramatically by leptin treatment in preweaning rats although the changes did not persist until adulthood. Elevated exposure to leptin during a critical period of neonatal hippocampal development might serve to enhance NMDA-dependent functions other than LTP and have important effects on synaptogenesis and neurotransmitter release.

Histotypic mouse parietal cortex cultures: Excitation/inhibition ratio and ultrastructural analysis

Primary cultures of mouse parietal cortex, prepared between postnatal day 3 (P3) and P9, were studied using transmission electron microscopy and HPLC of excitatory (aspartate and glutamate) and inhibitory neurotransmitters (glycine, GABA and taurine) to determine their morphological and functional development. Relations between excitation and inhibition (E/I) were contrasted with ultrastructural features over the time course of in vitro development. After 6 days in vitro, cultured parietal cortex neurons prepared from mice at P3 had immature morphological characteristics, whereas P5 cultures showed a more developed histological structure but still with scarce synapses. The acquirement of histotypic characteristics was seen in P7 cultures, which contained numerous symmetric and asymmetric synaptic contacts. On P9, the cultures showed signs of tissue damage. In terms of neurotransmitter levels and E/I ratios, P7 cultures had relatively low E/I ratio as compared with the rest of the cultures prepared before or after P7. These results demonstrated that the development of inhibitory synaptic transmission, as indicated in the fall of E/I ratio, marked the maturation of cerebral cortical tissue and that the critical period to obtain histotypic cultures of mouse parietal cerebral cortex coincides between P5 and P7. This work provides useful information regarding the balance between excitation and inhibition as an indicative parameter for in vitro nerve cell survival, differentiation and maturation and reinforces the great value of histotypic cultures in the study of central nervous system development.

Prenatal and Postnatal Contents of Amino Acid Neurotransmitters in Mouse Parietal Cortex

This study documents the variation in the amino acid neurotransmitter contents during mouse parietal cortex development, from embryonic day 13 (E13) until young adulthood, between postnatal day 21 (P21) and P30. Taurine, an inhibitory neurotransmitter and neuromodulator, is the most abundant neurotransmitter in the developing neocortex, whereas, at the adult stage, glutamate is the more prominent neurotransmitter playing an excitatory role, and GABA is the major inhibitory neurotransmitter. During the proliferative stage of neurogenesis in the mouse cerebral cortex, between E13 and E17, relatively high levels of glutamate, aspartate, taurine and glycine were detected, consistent with a possible trophic influence of these neurotransmitters during cortical development prior to synaptogenesis. Between E17 and E19, a significant decline in the contents of these neurotransmitters was observed, consistent with earlier reports of cell death in the ventricular and subventricular zones during this stage of development. During the perinatal period, a progressive increment in glutamate level was seen between E21 and P5, and then the values remained constant until the second postnatal week. Glutamate also decreased by about 25% between P11 and P15, on the other hand, aspartate diminished by about 20% between P7 and P9. These results were consistent with previous reports of histogenetic cell death during the first 2 postnatal weeks in mouse neocortex. GABA increased from the embryonic period until young adulthood, in contrast, the glycine content decreased; thus, in the adult parietal cortex, the GABA content was about 2.6-fold higher than that of glycine. During the first postnatal week, the concentrations of glutamate and GABA showed significant increments between P0 and P5, while those of aspartate and glycine remained constant. During this period, amino acids are predominantly excitatory and the cerebral cortex is vulnerable to epileptiform activity; the significant increment in taurine content between P0 and P3 suggests a neuroprotective action of taurine against excitotoxicity. At P15, coinciding with the period of maximum cortical synaptogenesis, significant increments in GABA and glycine contents were observed which could be related to the maturation of inhibitory synaptic transmission. At the young adult stage, there was a rise in the levels of both excitatory neurotransmitters, glutamate and aspartate, and a significant reduction in the contents of all three inhibitory neurotransmitters, GABA, glycine and taurine.

PKA and PKC content in the honey bee central brain differs in genotypic strains with distinct foraging behavior

Selection of honey bees for pollen storage resulted in high and low pollen-hoarding strains differing in foraging behavior traits including resource choice and quality, load size, sucrose responsiveness, age of foraging initiation, and learning performance. To determine how these genotypic differences correlate with changes at the level of proteins involved in neuronal function, we measured the content of protein kinase A, protein kinase C, and synapsin in the brains of high- and low-strain bees. In the central brain protein kinase A and protein kinase C levels were greater in high-strain bees and increased from emergence to 5 days in both strains. By 15 days, high-strain bees retained significantly higher levels of protein kinase C than low-strain bees, but overall protein kinase C content decreased in both strains. Synapsin levels increased from emergence to 5 days but did not differ between the two strains. In contrast to the protein kinase A content in the central brain, the basal protein kinase A activity did not differ between the strains or between the two age groups. This provides first evidence that the two genetic strains of honey bees show characteristic differences in the regulation of protein expression that may contribute to the behavioral differences between them.

Genetic engineering of neural function in transgenic rodents: towards a comprehensive strategy?

As mammalian genome projects move towards completion, the attention of molecular neuroscientists is currently moving away from gene identification towards both cell-specific gene expression patterns (neuronal transcriptions) and protein expression/interactions (neuronal proteomics). In the long term, attention will increasingly be directed towards experimental interventions which are able to question neuronal function in a sophisticated manner that is cognisant of both transcriptomic and proteomic organization. Central to this effort will be the application of a new generation of transgenic approaches which are now evolving towards an appropriate level of molecular, temporal and spatial resolution. In this review, we summarize recent developments in transgenesis, and show how they have been applied in the principal model species for neuroscience, namely rats and mice. Current concepts of transgene design are also considered together with an overview of new genetically-encoded tools including both cellular indicators such as fluorescent activity reporters, and cellular regulators such as dominant negative signalling factors. Application of these tools in a whole animal context can be used to question both basic concepts of brain function, and also current concepts of underlying dysfuction in neurological diseases.