Hadas Erez

Formation of microtubule-based traps controls the sorting and concentration of vesicles to restricted sites of regenerating neurons after axotomy

Transformation of a transected axonal tip into a growth cone (GC) is a critical step in the cascade leading to neuronal regeneration. Critical to the regrowth is the supply and concentration of vesicles at restricted sites along the cut axon. The mechanisms underlying these processes are largely unknown. Using online confocal imaging of transected, cultured Aplysia californica neurons, we report that axotomy leads to reorientation of the microtubule (MT) polarities and formation of two distinct MT-based vesicle traps at the cut axonal end. Approximately 100 μm proximal to the cut end, a selective trap for anterogradely transported vesicles is formed, which is the plus end trap. Distally, a minus end trap is formed that exclusively captures retrogradely transported vesicles. The concentration of anterogradely transported vesicles in the former trap optimizes the formation of a GC after axotomy.

Tau-Induced Traffic Jams Reflect Organelles Accumulation at Points of Microtubule Polar Mismatching

It is currently accepted that tau overexpression leads to impaired organelle transport and thus to neuronal degeneration. Nevertheless, the underlying mechanisms that lead to impaired organelle transport are not entirely clear. Using cultured Aplysia neurons and online confocal imaging of human tau, microtubules (MTs), the plus‐end tracking protein – end‐binding protein 3, retrogradely and anterogradely transported organelles, we found that overexpression of tau generates the hallmarks of human tau pathogenesis. Nevertheless, in contrast to earlier reports, we found that the tau‐induced impairment of organelle transport is because of polar reorientation of the MTs along the axon or their displacement to submembrane domains. ‘Traffic jams’ reflect the accumulation of organelles at points of MT polar discontinuations or polar mismatching rather than because of MT depolymerization. Our findings offer a new mechanistic explanation for earlier observations, which established that tau overexpression leads to impaired retrograde and anterograde organelle transport, while the MT skeleton appeared intact.

Local calcium-dependent mechanisms determine whether a cut axonal end assembles a retarded endbulb or competent growth cone

The transformation of a cut axonal end into a growth cone (GC), after axotomy, is a critical event in the cascade leading to regeneration. In an earlier series of studies we analyzed the cellular cascades that transform a cut axonal end into a competent GC. We found that axotomy of cultured Aplysia neurons leads to a transient elevation of the free intracellular Ca2+ concentration ([Ca2+]i), calpain activation and localized proteolysis of submembranal spectrin. These events are associated with the formation of distinct microtubule (MT) based vesicle traps that accumulate anterogradely transported vesicles that fuse with the spectrin free plasma membrane in support of the growth process (Erez, H., Malkinson, G., Prager-Khoutorsky, M., De Zeeuw, C.I., Hoogenraad, C.C., and Spira, M.E. 2007. Formation of microtubule-based traps controls the sorting and concentration of vesicles to restricted sites of regenerating neurons after axotomy. J. Cell Biol. 176: 497-507.; Erez, H., and Spira, M.E. 2008. Local self-assembly mechanisms underlie the differential transformation of the proximal and distal cut axonal ends into functional and aberrant growth cones. J. Comp. Neurol. 507: spc1.). Here we report that under conditions that limit calcium influx into the cut axonal end, axotomy leads to the formation of endbulbs (EBs) rather than to competent GCs. Under these conditions typical MT based vesicle traps are not formed, and Golgi derived vesicles concentrate at the very tip of the cut axon. Since under these conditions the spectrin barrier is not cleaved, vesicle fusion with the plasma membrane and actin polymerization are retarded and growth processes are impaired. We conclude that the immediate assembly of competent GC or an EB after axotomy is the outcome of autonomous local events that are shaped by the magnitudes of the [Ca2+]i gradients at the site of injury.

Changing gears from chemical adhesion of cells to flat substrata toward engulfment of micro-protrusions by active mechanisms.

Microelectrode arrays increasingly serve to extracellularly record in parallel electrical activity from many excitable cells without inflicting damage to the cells by insertion of microelectrodes. Nevertheless, apart from rare cases they suffer from a low signal to noise ratio. The limiting factor for effective electrical coupling is the low seal resistance formed between the plasma membrane and the electronic device. Using transmission electron microscope analysis we recently reported that cultured Aplysia neurons engulf protruding micron size gold spines forming tight apposition which significantly improves the electrical coupling in comparison with flat electrodes (Hai et al 2009 Spine-shaped gold protrusions improve the adherence and electrical coupling of neurons with the surface of micro-electronic devices J. R. Soc. Interface 6 1153-65). However, the use of a transmission electron microscope to measure the extracellular cleft formed between the plasma membrane and the gold-spine surface may be inaccurate as chemical fixation may generate structural artifacts. Using live confocal microscope imaging we report here that cultured Aplysia neurons engulf protruding spine-shaped gold structures functionalized by an RGD-based peptide and to a significantly lesser extent by poly-l-lysine. The cytoskeletal elements actin and associated protein cortactin are shown to organize around the stalks of the engulfed gold spines in the form of rings. Neurons grown on the gold-spine matrix display varying growth patterns but maintain normal electrophysiological properties and form functioning synapses. It is concluded that the matrices of functionalized gold spines provide an improved substrate for the assembly of neuro-electronic hybrids.

Local self‐assembly mechanisms underlie the differential transformation of the proximal and distal cut axonal ends into functional and aberrant growth cones

Following axotomy, both the proximal and distal cut axonal ends transform into growth cones (GCs). Whereas the GCs formed by the tip of the proximal segment branch to form neurites, the structure formed by the distal cut end fails to grow. The mechanisms underlying the formation of an aberrant GC by the distal cut end are not understood. Earlier we described the cascade that transforms the tip of the proximal cut axon into a GC. This involves microtubule (MT) polar reorientation, which culminates in the formation of two MT‐based vesicle traps, one for Golgi‐derived vesicles and the other that retains retrogradely transported vesicles. The formation of these traps is the outcome of local interactions between dynamically repolymerizing MTs and molecular motors. The concentration of Golgi‐derived vesicles in the plus‐end trap is essential for the successful generation of a functional GC. By using online confocal imaging of transected cultured Aplysia neurons, we analyzed here the restructuring of the distal cut end after axotomy. We found that initially the proximal and distal cut ends undergo identical alterations. Nevertheless, in contrast to the proximal end, the distal cut axon forms only a minus‐end MT‐based trap that concentrates endocytotic vesicles driven by minus‐end oriented motors. Whereas the MTs forming the trap polymerize pointing their plus‐ends centrifugally to form finger‐like protrusions, the trapped vesicles cannot translocate out to fuse with the plasma membrane. Thus, the structure formed at the distal cut axon is incompetent to support growth processes. J. Comp. Neurol. 507:1019–1030, 2008.

Effective expression of the green fluorescent fusion proteins in cultured Aplysia neurons.

The green fluorescent fusion protein and its isoforms are extensively used to monitor gene expression, protein localisation and their dynamics in relations to fundamental cellular processes. However, it has not yet been effectively applied to Aplysia neurons that serve as a powerful model to study the mechanisms underlying neuroplasticity. We report here the development of a procedure combining in vitro transcription of mRNA encoding fluorescent-tagged proteins and its subsequent injection into the cytoplasm to image, in real-time, protein dynamics in cultured Aplysia neurones. To illustrate the efficiency of the procedure we report here the visualisation of actin, microtubules and vesicle trafficking. The results presented here introduce a reliable and effective method to express green fluorescent protein (GFP) fusion proteins in cultured Aplysia neurons.

Electrically conductive 2D-PAN-containing surfaces as a culturing substrate for neurons

In the present contribution we report on a novel route to synthesize 2D-polyaniline (2DPAN) on sulfonated-poly(styrene) (SPS) templates by allowing first monomer assembly followed by chemical oxidation to achieve polymerization. We show that Aplysia neurons grown on 2D-PAN exhibit an unusual growth pattern and adhesion to this conducting substrate that is manifested by the formation of giant lamellipodia. The lamellipodial domains are characterized by small gap between the plasma membrane and the 2D-PAN substrate (ca. 30 nm) and actin rich skeleton resembling the skeleton of growth cones. This behavior is characteristic to uniform substrates containing only 2DPAN. However, in patterned substrates containing additionally poly(L-lysine) Aplysia neurons prefer to extend new neurites on the poly(L-lysine) domains.

Multisite electrophysiological recordings by self-assembled loose-patch-like junctions between cultured hippocampal neurons and mushroom-shaped microelectrodes

Substrate integrated planar microelectrode arrays is the “gold standard” method for millisecond-resolution, long-term, large-scale, cell-noninvasive electrophysiological recordings from mammalian neuronal networks. Nevertheless, these devices suffer from drawbacks that are solved by spike-detecting, spike-sorting and signal-averaging techniques which rely on estimated parameters that require user supervision to correct errors, merge clusters and remove outliers. Here we show that primary rat hippocampal neurons grown on micrometer sized gold mushroom-shaped microelectrodes (gMμE) functionalized simply by poly-ethylene-imine/laminin undergo self-assembly processes to form loose patch-like hybrid structures. More than 90% of the hybrids formed in this way record monophasic positive action potentials (APs). Of these, 34.5% record APs with amplitudes above 300 μV and up to 5,085 μV. This self-assembled neuron-gMμE configuration improves the recording quality as compared to planar MEA. This study characterizes and analyzes the electrophysiological signaling repertoire generated by the neurons-gMμE configuration, and discusses prospects to further improve the technology.

Nanocrystalline diamond surfaces for adhesion and growth of primary neurons, conflicting results and rational explanation.

Using a variety of proliferating cell types, it was shown that the surface of nanocrystalline diamond (NCD) provides a permissive substrate for cell adhesion and development without the need of complex chemical functionalization prior to cell seeding. In an extensive series of experiments we found that, unlike proliferating cells, post-mitotic primary neurons do not adhere to bare NCD surfaces when cultured in defined medium. These observations raise questions on the potential use of bare NCD as an interfacing layer for neuronal devices. Nevertheless, we also found that classical chemical functionalization methods render the “hostile” bare NCD surfaces with adhesive properties that match those of classically functionalized substrates used extensively in biomedical research and applications. Based on the results, we propose a mechanism that accounts for the conflicting results; which on one hand claim that un-functionalized NCD provides a permissive substrate for cell adhesion and growth, while other reports demonstrate the opposite.

A feasibility study of multi-site,intracellular recordings from mammalian neurons by extracellular gold mushroom-shaped microelectrodes

The development of multi-electrode array platforms for large scale recording of neurons is at the forefront of neuro-engineering research efforts. Recently we demonstrated, at the proof-of-concept level, a breakthrough neuron-microelectrode interface in which cultured Aplysia neurons tightly engulf gold mushroom-shaped microelectrodes (gMμEs). While maintaining their extracellular position, the gMμEs record synaptic- and action-potentials with characteristic features of intracellular recordings. Here we examined the feasibility of using gMμEs for intracellular recordings from mammalian neurons. To that end we experimentally examined the innate size limits of cultured rat hippocampal neurons to engulf gMμEs and measured the width of the “extracellular” cleft formed between the neurons and the gold surface. Using the experimental results we next analyzed the expected range of gMμEs-neuron electrical coupling coefficients. We estimated that sufficient electrical coupling levels to record attenuated synaptic- and action-potentials can be reached using the gMμE-neuron configuration. The definition of the engulfment limits of the gMμEs caps diameter at ≤2–2.5 μm and the estimated electrical coupling coefficients from the simulations pave the way for rational development and application of the gMμE based concept for in-cell recordings from mammalian neurons.