Baculovirus expression and bioactivity of a soluble 140 kDa extracellular cleavage fragment of L1 neural cell adhesion molecule

L1 neural cell adhesion molecule is the founding member of the L1 subfamily of the immunoglobulin superfamily and plays an important role in the overall development of both the central and peripheral nervous systems, making it an attractive candidate for promoting neural regeneration following injury. Currently, L1 used for experimental studies is primarily mammalian-derived; however, the insect cell expression system described here provides an alternative source of recombinant L1 with equivalent bioactivity. A 140 kDa L1 fragment based on a physiological plasmin cleavage site in the extracellular domain was cloned and expressed with a C-terminal 6x histidine tag. Recombinant insect cell-derived L1 was analyzed by Western blot using an antibody to human L1 to confirm immunogenicity and to optimize infection conditions for recombinant L1 production. The recombinant protein was secreted by insect cells, efficiently purified under non-denaturing conditions using dialysis followed by metal affinity chromatography, and analyzed by SDS-PAGE to produce a single band of the expected approximate 140 kDa size. The bioactivity of insect cell-derived L1 was compared to mammalian-derived L1-Fc and poly-L-lysine (PLL) using chick embryonic forebrain neurons. The results show comparable, robust neurite outgrowth at 24h on insect cell-derived L1 and mammalian-derived L1-Fc, with significantly longer neurites than those observed on PLL. Future studies will examine the immobilization of L1 to biomaterial surfaces in physiologically appropriate orientation via the C-terminal 6x histidine tag and will investigate their application in promoting axonal regeneration in the injured nervous system.     

Quality of embryonic bodies and seeding density effects on neural differentiation of mouse embryonic stem cells

Mouse embryonic stem (ES) cells can be differentiated into neural lineage cells, but the differentiation efficiency remains low. This study revealed two important factors that influence the neural differentiation efficiency of mouse ES cells: the first is the quality of embryonic bodies (EBs); good quality of EBs consistently originated from a suspension culture of 1 × 10⁵ ES cells/ml serum-free chemically defined neural inducing medium and they exhibited a smooth round shape, with a dark central region surrounded by a light band. Such EBs are capable of attaining high neural differentiation efficiency. However, poor quality EBs originated from a suspension culture of 1 × 10⁶ ES cells/ml serum-free chemically defined neural inducing medium and exhibited an irregular shape or adhered to the bottom of the dish; they displayed low neural differentiation efficiency. The second factor is the seeding density of EBs: a low seeding density (5 EBs/cm²) induced cells to differentiate into a more caudalized subtypes compared to the cells obtained from high seeding density (20 EBs/cm²). These findings provided fresh insight into the neural induction of mouse ES cells.     

大鼠脑神经干细胞系(RNSC-FMU 1)的建立和鉴定

采用无血清培养液分离和培养新生SD 大鼠脑的神经干细胞,以机械分散的方法传代,成功地建立了大鼠脑神经干细胞系(RSNC-FMU 1)。该细胞系可在体外长期传代,至今已在体外连续生长超过21个月(>100代),保持了神经干细胞的特性和正常的核型,经诱导可分化成为神经元、星形胶质细胞和少突胶质细胞,具有较旺盛的自新能力,倍增时间约为20h,并可冷冻保存,裸鼠体内移植证实其不具有成瘤性。该细胞系为神经干细胞研究提供了一个良好的工具。     

The selectivity of canary HVC neurons for the Bird’s Own Song: Rate coding, temporal coding, or both?

The neuronal selectivity observed in the avian song system for the Bird’s Own Song progressively emerged as an extraordinary fruitful model to investigate the neural code underlying the recognition of complex stimuli and the occurrence of learned behaviors. In adult zebra finch, neurons from the HVC (used as a proper name) show very selective auditory responses, firing more to presentation of the Bird’s Own Song (BOS) than to reverse BOS or other conspecific songs. However, as adult zebra finches always produce the same stereotyped song, the presence of such highly selective neurons in birds with larger repertoire still remains an open question. Data presented here show that neurons selective for the BOS can be found in adult canary, a seasonal breeding bird which display a large repertoire. More precisely, we found that a large proportion of neurons (29/36) exhibits higher responses to presentation of the forward than to the reverse BOS, and that 22% of the cells were identified as selective on the basis of the d′ value. For a cell that was extensively studied, we evaluated to what extent temporal stimulus-related structure predicts the acoustic stimulus using linear or non-linear artificial neural networks (ANN). These analyses indicated that the temporal structure contained in spike trains characterizes more accurately the stimulus than the firing rate. The limitations of applying ANN analyses to electrophysiological data are discussed and potential solutions to increase the confidence in these analysis are proposed.     

System identification of muscle–joint interactions of the cat hind limb during locomotion

Neurophysiological experiments in walking cats have shown that a number of neural control mechanisms are involved in regulating the movements of the hind legs during locomotion. It is experimentally hard to isolate individual mechanisms without disrupting the natural walking pattern and we therefore introduce a different approach where we use a model to identify what control is necessary to maintain stability in the musculo-skeletal system. We developed a computer simulation model of the cat hind legs in which the movements of each leg are produced by eight limb muscles whose activations follow a centrally generated pattern with no proprioceptive feedback. All linear transfer functions, from each muscle activation to each joint angle, were identified using the response of the joint angle to an impulse in the muscle activation at 65 postures of the leg covering the entire step cycle. We analyzed the sensitivity and stability of each muscle action on the joint angles by studying the gain and pole plots of these transfer functions. We found that the actions of most of the hindlimb muscles display inherent stability during stepping, even without the involvement of any proprioceptive feedback mechanisms, and that those musculo-skeletal systems are acting in a critically damped manner, enabling them to react quickly without unnecessary oscillations. We also found that during the late swing, the activity of the posterior biceps/semitendinosus (PB/ST) muscles causes the joints to be unstable. In addition, vastus lateralis (VL), tibialis anterior (TA) and sartorius (SAT) muscle-joint systems were found to be unstable during the late stance phase, and we conclude that those muscles require neuronal feedback to maintain stable stepping, especially during late swing and late stance phases. Moreover, we could see a clear distinction in the pole distribution (along the step cycle) for the systems related to the ankle joint from that of the other two joints, hip or knee. A similar pattern, i.e., a pattern in which the poles were scattered over the s-plane with no clear clustering according to the phase of the leg position, could be seen in the systems related to soleus (SOL) and TA muscles which would indicate that these muscles depend on neural control mechanisms, which may involve supraspinal structures, over the whole step cycle.     

Unexpected activities of Smad7 in Xenopus mesodermal and neural induction

Neural induction is widely believed to be a direct consequence of inhibition of BMP pathways. Because of conflicting results and interpretations, we have re-examined this issue in Xenopus and chick embryos using the powerful and general TGFβ inhibitor, Smad7, which inhibits both Smad1- (BMP) and Smad2- (Nodal/Activin) mediated pathways. We confirm that Smad7 efficiently inhibits phosphorylation of Smad1 and Smad2. Surprisingly, however, over-expression of Smad7 in Xenopus ventral epidermis induces expression of the dorsal mesodermal markers Chordin and Brachyury. Neural markers are induced, but in a non-cell-autonomous manner and only when Chordin and Brachyury are also induced. Simultaneous inhibition of Smad1 and Smad2 by different approaches does not account for all Smad7 effects, indicating that Smad7 has activities other than inhibition of the TGFβ pathway. We provide evidence that these effects are independent of Wnt, FGF, Hedgehog and retinoid signalling. We also show that these effects are due to elements outside of the MH2 domain of Smad7. Together, these results indicate that BMP inhibition is not sufficient for neural induction even when Nodal/Activin is also blocked, and that Smad7 activity is considerably more complex than had previously been assumed. We suggest that experiments relying on Smad7 as an inhibitor of TGFβ-pathways should be interpreted with considerable caution.     

Saccade-related remapping of target representations between topographic maps: a neural network study

The goal of this study was to explore how a neural network could solve the updating task associated with the double-saccade paradigm, where two targets are flashed in succession and the subject must make saccades to the remembered locations of both targets. Because of the eye rotation of the saccade to the first target, the remembered retinal position of the second target must be updated if an accurate saccade to that target is to be made. We trained a three-layer, feed-forward neural network to solve this updating task using back-propagation. The network's inputs were the initial retinal position of the second target represented by a hill of activation in a 2D topographic array of units, as well as the initial eye orientation and the motor error of the saccade to the first target, each represented as 3D vectors in brainstem coordinates. The output of the network was the updated retinal position of the second target, also represented in a 2D topographic array of units. The network was trained to perform this updating using the full 3D geometry of eye rotations, and was able to produce the updated second-target position to within a 1 degrees RMS accuracy for a set of test points that included saccades of up to 70 degrees . Emergent properties in the network's hidden layer included sigmoidal receptive fields whose orientations formed distinct clusters, and predictive remapping similar to that seen in brain areas associated with saccade generation. Networks with the larger numbers of hidden-layer units developed two distinct types of units with different transformation properties: units that preferentially performed the linear remapping of vector subtraction, and units that performed the nonlinear elements of remapping that arise from initial eye orientation.     

On the stationary state of a network of inhibitory spiking neurons

The background activity of a cortical neural network is modeled by a homogeneous integrate-and-fire network with unreliable inhibitory synapses. For the case of fast synapses, numerical and analytical calculations show that the network relaxes into a stationary state of high attention. The majority of the neurons has a membrane potential just below the threshold; as a consequence the network can react immediately – on the time scale of synaptic transmission- on external pulses. The neurons fire with a low rate and with a broad distribution of interspike intervals. Firing events of the total network are correlated over short time periods. The firing rate increases linearly with external stimuli. In the limit of infinitely large networks, the synaptic noise decreases to zero. Nevertheless, the distribution of interspike intervals remains broad. Action Editor: Misha Tsodyks     

Experimental Study on Trace Marking and Oncogenicity of Neural Stem Cells Derived from Bone Marrow

It has been well accredited that the neural stem cells (NSCs) derived from bone marrow stroma cells (BMSCs) can be used as the therapeutic application. However, their efficacy and safety in therapeutic application are uncertain. In this experiment, the trace marking and oncogenicity of NSCs derived from BMSCs (BMSCs-D-NSCs) were studied. The BMSCs were harvested by gradient centrifugation and cultured in "NSCs medium" in vitro. The verified CD133/Nestin-positive BMSCs-D-NSCs were then transplanted into nude mice to detect the oncogenicity, into the right lateral cerebral ventricle or right caudae putamen and substantia nigra to examine, whether the symptoms were improved in Parkinson's Disease (PD) models after transplantation, by both SPECT image assay of dopamine transporter (DAT) in corpus striatum and its average standard uptake value (SUVave) in corpus striatum and thalamus. Tissue samples and surviving model animals were studied at 1, 3, and 6 months post-transplantation. Before transplantation, the cells were labeled with BrdU or rAAV-GFP for the pathological sections, and with Feridex for the in vivo trace by MRI assay. The concanavalin A (ConA) agglutination test, stop-dependence test with soft agar, karyotype analysis of chromosome G zone in BMSCs-D-NSCs, and the nude mouse neoplasia test were also performed. The BrdU, rAAV-GFP or Feridex can be used as trace markers of BMSCs-D-NSCs during transplantation. The transplanted BMSCs-D-NSCs displayed neither toxicity nor neoplasia up to 6 months in vivo, but could play an important role in improving the symptoms of the animals with degenerative diseases like PD.     

The neural stem cell niche

The neural stem cell niche defines a zone in which stem cells are retained after embryonic development for the production of new cells of the nervous system. This continual supply of new neurons and glia then provides the postnatal and adult brain with an added capacity for cellular plasticity, albeit one that is restricted to a few specific zones within the brain. Critical to the maintenance of the stem cell niche are microenvironmental cues and cell-cell interactions that act to balance stem cell quiescence with proliferation and to direct neurogenesis versus gliogenesis lineage decisions. Ultimately, based on the location of the niche, stem cells of the adult brain support regeneration in the dentate gyrus of the hippocampus and the olfactory bulb through neuron replacement. Here, we provide a summary of the current understanding of the organization and control mechanisms of the neural stem cell niche.