Extracellular matrix allows PC12 neurite elongation in the absence of microtubules

Several groups have shown that PC12 will extend microtubule-containing neurites on extracellular matrix (ECM) with no lag period in the absence of nerve growth factor. This is in contrast to nerve growth factor (NGF)-induced neurite outgrowth that occurs with a lag period of several days. During this lag period, increased synthesis or activation of assembly-promoting microtubule-associated proteins (MAPs) occurs and is apparently required for neurite extension. We investigated the growth and microtubule (MT) content of PC12 neurites grown on ECM in the presence or absence of inhibitors of neurite outgrowth. On ECM, neurites of cells with or without prior exposure to NGF contain a normal density of MTs, but frequently contain unusual loops of MTs in their termini that may indicate increased MT assembly. On ECM, neurites extend from PC12 cells in the presence of 10 microM LiCl at significantly higher frequency than on polylysine. On other substrates, LiCl inhibits neurite outgrowth, apparently by inhibiting phosphorylation of particular MAPs (Burstein, D. E., P. J. Seeley, and L. A. Greene. 1985. J. Cell Biol. 101:862-870). Although 35-45% of 60 Li(+)-neurites examined were found to contain a normal array of MTs, 25-30% were found to have a MT density approximately 15% of normal. The remaining 30% of these neurites were found to be nearly devoid of MTs, containing only occasional, ambiguous, short tubular elements. We also found that neurites would extend on ECM in the presence of the microtubule depolymerizing drug, nocodazole. At 0.1 micrograms/ml nocodazole, cells on ECM produce neurites that contain a normal density of MTs. This is in contrast to the lack of neurite outgrowth and retraction of extant neurites that this dose produces in cells grown on polylysine. At 0.2 microgram/ml nocodazole, neurites again grew out in substantial number and four of five neurites examined ultrastructurally were found to be completely devoid of microtubules. We interpret these results by postulating that growth on ECM relieves the need for MTs to serve as compressive supports for neurite tension (Dennerll, T. J., H. C. Joshi, U. L. Steel, R. E. Buxbaum, and S. R. Heidemann. 1988. J. Cell Biol. 107:665). Because compression destabilizes MTs and favors disassembly, this would tend to increase MT assembly relative to other conditions, as we found. Additionally, if MTs are not needed as compressive supports, neurites could grow out in their absence, as we also observed.     

A Study of the Effects of Flux Density and Frequency of Pulsed Electromagnetic Field on Neurite Outgrowth in PC12 Cells

The aim of this study was to investigate the influence of pulsed electromagnetic fields with various flux densities and frequencies on neurite outgrowth in PC12 rat pheochromocytoma cells. We have studied the percentage of neurite-bearing cells, average length of neurites and directivity of neurite outgrowth in PC12 cells cultured for 96 hours in the presence of nerve growth factor (NGF). PC12 cells were exposed to 50 Hz pulsed electromagnetic fields with a flux density of 1.37 mT, 0.19 mT and 0.016 mT respectively. The field was generated through a Helmholtz coil pair housed in one incubator and the control samples were placed in another identical incubator. It was found that exposure to both a relatively high flux density (1.37 mT) and a medium flux density (0.19 mT) inhibited the percentage of neurite-bearing cells and promoted neurite length significantly. Exposure to high flux density (1.37 mT) also resulted in nearly 20% enhancement of neurite directivity along the field direction. However, exposure to low flux density field (0.016 mT) had no detectable effect on neurite outgrowth. We also studied the effect of frequency at the constant flux density of 1.37 mT. In the range from 1 ∼ 100 Hz, only 50 and 70 Hz pulse frequencies had significant effects on neurite outgrowth. Our study has shown that neurite outgrowth in PC12 cells is sensitive to flux density and frequency of pulsed electromagnetic field.     

Influence of pulsed electromagnetic field with different pulse duty cycles on neurite outgrowth in PC12 rat pheochromocytoma cells

The influence of low frequency (50 Hz repetition rate) pulsed electromagnetic field (EMF) on PC12 cell neurite outgrowth in vitro was investigated in this study. We studied the percentage of neurite bearing cells, average length of neurites, and directivity of neurite outgrowth in PC12 cells cultured for 96 h in the presence of nerve growth factor (NGF). PC12 cells were exposed in one incubator to pulsed EMF at 1.36 mT (peak value) generated by a pair of Helmholtz coils, and the control samples were placed in another identical incubator. We found that the pulse duty cycle had significant effect on neurite outgrowth. Low (10%) pulse on-time significantly inhibited the percentage of neurite bearing cells, but at the same time increased the average length of neurites, while 100% on-time (DC) had exactly the opposite effects. Furthermore, we found that neurites were prone to extend along the direction of pulsed EMF with 10% pulse on-time. Our studies show that neurite outgrowth in PC12 cells is sensitive to the pulse duty and this sensitivity was associated with NGF concentration.     

Cyclic strain increases fibroblast proliferation, matrix accumulation, and elastic modulus of fibroblast-seeded polyurethane constructs

Rapid induction of matrix production and mechanical strengthening is essential to the development of bio-artificial constructs for repair and replacement of load-bearing connective tissues. Toward this end, we describe the development of a mechanical bioreactor and its application to investigate the influence of cyclic strain on fibroblast proliferation, matrix accumulation, and the mechanical properties of fibroblast-seeded polyurethane constructs (FSPC). Human fibroblasts were cultured in 10% serum-containing conditions within three-dimensional, porous elastomeric substrates under static conditions and a model regime of cyclic strain (10% strain, 0.25 Hz, 8 h/day), with and without ascorbic acid supplementation. After one week, the combination of cyclic strain and ascorbic acid resulted in significantly increased construct elastic modulus (>110%) relative to either condition alone. In contrast, cyclic strain alone was sufficient to stimulate significant increases in fibroblast proliferation. Mechanical strengthening of FSPCs was accompanied by increased type I collagen and fibronectin matrix accumulation and distribution, and significantly increased gene expression for type I collagen, TGFbeta-1, and CTGF. These results suggest that strain-induced conditioning in vitro leads to mechanical strengthening of fibroblast/material constructs, most likely resulting from increased collagen matrix deposition, secondary to strain-induced increases in cytokine production.     

Orientation of neurites influences severity of mechanically induced tau pathology

Chronic traumatic encephalopathy is a neurodegenerative disease associated with repeated traumatic brain injury (TBI). Chronic traumatic encephalopathy is a tauopathy, in which cognitive decline is accompanied by the accumulation of neurofibrillary tangles of the protein tau in patients’ brains. We recently found that mechanical force alone can induce tau mislocalization to dendritic spines and loss of synaptic function in in vitro neuronal cultures with random cell organization. However, in the brain, neurons are highly aligned, so here we aimed to determine how neuronal organization influences early-stage tauopathy caused by mechanical injury. Using microfabricated cell culture constructs to control the growth of neurites and an in vitro simulated TBI device to apply controlled mechanical deformation, we found that neuronal orientation with respect to the direction of a uniaxial high-strain-rate stretch injury influences the degree of tau pathology in injured neurons. We found that a mechanical stretch applied parallel to the neurite alignment induces greater mislocalization of tau proteins to dendritic spines than does a stretch with the same strain applied perpendicular to the neurites. Synaptic function, characterized by the amplitude of miniature excitatory postsynaptic currents, was similarly decreased in neurons with neurites aligned parallel to stretch, whereas in neurons aligned perpendicular to stretch, it had little to no functional loss. Experimental injury parameters (strain, strain rate, direction of stretch) were combined with a standard viscoelastic solid model to show that in our in vitro model, neurite work density during stretch correlates with tau mislocalization. These findings suggest that in a TBI, the magnitude of brain deformation is not wholly predictive of neurodegenerative consequences of TBI but that deformation relative to local neuronal architecture and the neurite mechanical energy during injury are better metrics for predicting trauma-induced tauopathy.     

Quantitative effects of laminin concentration on neurite outgrowth in vitro

Recent studies indicate that mediation of neurite outgrowth by the glycoprotein laminin may be a significant factor in the outgrowth of neurites to their targets during embryogenesis. To further characterize the possible role of this extracellular matrix molecule during development, we have systematically measured several features of outgrowth by neonatal rat sympathetic neurons on different concentrations of laminin. Individual neurons, obtained by mechanical dissociation of superior cervical ganglia (SCG), were cultured at low density on laminin substrates ranging from 0.01 to 1.0 microgram/cm2. Outgrowth characteristics were subsequently analyzed for noninteracting cells in both fixed and live cultures. Data obtained from neurons fixed after 11 hr of culture showed approximately twofold increases in neurite initiation and outgrowth, and a twofold decrease in branching for a corresponding 100-fold increase in adsorbed laminin concentration. In time-lapse videomicroscopy observations, the root-mean square speed of growth cone movement increased from 60 to 90 microns/hr over the same range in concentration, while the persistence time remained constant at 0.10 hr. In general, neurite outgrowth parameters were relatively insensitive to changes in laminin concentration, supporting the idea that laminin is a permissive rather than an "instructive" substrate during development. Data obtained from fixed cultures were examined in terms of probability models to suggest possible mechanisms contributing to the dose-dependent effects observed.     

Neurite development in PC12 cells cultured on nanopillars and nanopores with sizes comparable with filopodia

We investigated the effect ofnanoscale topography on neurite development in pheochromocytoma (PC12 cells) by culturing the cells on substrates having nanoscale pillars and pores with sizes comparable with filipodia. We found that cells on nanopillars and nanopores developed fewer and shorter neurites than cells on smooth substrates, and that cells on nanopores developed more and longer neurites than cells on nanopillars. These results suggest that PC12 cells were spatially aware of the difference in the nanoscale structures of the underlying substrates and responded differently in their neurite extension. This finding points to the possibility of using nanoscale topographic features to control neurite development in neurons.     

Drag Force as a Tool to Test the Active Mechanical Response of PC12 Neurites

We investigate the mechanical response of PC12 neurites subjected to a drag force imposed by a laminar flow perpendicular to the neurite axis. The curvature of the catenary shape acquired by an initially straight neurite under the action of the drag force provides information on both elongation and tension of the neurite. This method allows us to measure the rest tension and viscoelastic parameters of PC12 neurites and active behavior of neurites. Measurement of oscillations in the strain rate of neurites at constant flow rate provides insight on the response of molecular motors and additional support for the presence of a negative strain-rate sensitivity region in the global mechanical response of PC12 neurites.     

Preferential outgrowth of central nervous system neurites on astrocytes and Schwann cells as compared with nonglial cells in vitro

I have compared central nervous system (CNS) neurite outgrowth on glial and nonglial cells. Monolayers of glial cells (astrocytes and Schwann cells) or nonglial cells (e.g., fibroblasts) were prepared and were shown to be greater than 95% pure as judged by cell type-specific markers. These monolayers were then tested for their ability to support neurite outgrowth from various CNS explants. While CNS neurites grew vigorously on the glial cells, most showed little growth on nonglial cell monolayers. Neurites grew singly or in fine fascicles on the glial cells at rates greater than 0.5 mm/d. The neurite outgrowth on astrocytes was investigated in detail. Scanning and transmission electron microscopy showed that the neurites were closely apposed to the astrocyte surface and that the growth cones were well spread with long filopodia. There was no evidence of significant numbers of explant- derived cells migrating onto the monolayers. Two types of experiments indicated that factors associated with the astrocyte surface were primarily responsible for the vigorous neurite outgrowth seen on these cells: (a) Conditioned media from either astrocytes or fibroblasts had no effect on the pattern of outgrowth on fibroblasts and astrocytes, and conditioned media factors from either cell type did not promote neurite outgrowth when bound to polylysine-coated dishes. (b) When growing CNS neurites encountered a boundary between astrocytes and fibroblasts, they stayed on the astrocytes and did not encroach onto the fibroblasts. These experiments strongly suggest that molecules specific to the surfaces of astrocytes make these cells particularly attractive substrates for CNS neurite outgrowth, and they raise the possibility that similar molecules on embryonic glial cells may play a role in guiding axonal growth during normal CNS development.     

Contribution of bradykinin and nitric oxide to AT2 receptor-mediated differentiation in PC12 W cells

We investigated the effect of angiotensin II on intracellular cyclic GMP content and neurite outgrowth as an indicator of cell differentiation in PC12 W cells. Neurite outgrowth was examined by phase-contrast microscopy. Outgrown neurites were classified as small, medium and large, and were expressed as neurites per 100 cells. Angiotensin II (10-7 m) increased the outgrowth of medium and large neurites by mean +/- SEM 20.2 +/- 2.3 and 6.6 +/- 1.4 compared with 1.66 +/- 0.5 and 0.1 +/- 0.06 neurites per 100 cells in control. Cellular cyclic GMP content increased by 50-250% with angiotensin II at concentrations of 10-6-10-4 m. Both blockade of AT2 receptors and of nitric oxide synthase markedly reduced angiotensin II-induced neurite outgrowth and cyclic GMP production. In contrast, B2 receptor blockade had no effect or even increased these angiotensin II effects. Sodium nitroprusside and 8-bromo-cyclic GMP both mimicked the effects of angiotensin II on cell differentiation. The protein kinase G inhibitor KT-5823 inhibited the neurite outgrowth induced by both angiotensin II and 8-bromo-cyclic GMP. Our results demonstrate that angiotensin II can stimulate cell differentiation in PC12 W cells by nitric oxide-related and cyclic GMP-dependent mechanisms. The effects of angiotensin II on cell differentiation and cyclic GMP production were mediated via the AT2 receptor and further enhanced by bradykinin B2 receptor blockade.     

Effect of an exo-polysaccharide from the culture broth of Hericium erinaceus on enhancement of growth and differentiation of rat adrenal nerve cells

It was found that an exo-biopolymer (M.W. 1,000,000, molar ratio of 1.5:1.7:1.2:0.6:0.9, glucose:galactose:xylose:mannose:fructose, purity 99%) purified from the liquid culture broth of Hericium erinaceus mycelium enhanced the growth of rat adrenal nerve cells. The polymer also improved the extension of the neurites of PC12 cell. Its efficacy was found to be higher than those from known nerve growth factors such as Nerve Growth Factor (NGF) and Brain-Derived Nerve Factor (BDNF). The effect of two standards has not been observed above 0.1 (mg l⁻¹) of supplementation; however, the polymer did show the effect of cell growth and neurite extension at up to 1.0 (mg l⁻¹) of addition. While the polymer improved both cell growth and neurite extension, NGF and BDNF did only outgrowth of the neurites. Maximum cell density and length of the neurites were observed as 1.5×10⁵ (viable cells ml⁻¹) and 230 μm, respectively in adding 0.8 (mg l⁻¹) of the biopolymer for 8 days cultivation. The control growth was observed only as 1.2×10⁵ (viable cell ml⁻¹) of maximum cell density and 140 μm of maximum length, respectively. It was also confirmed that the polymer reacted with the nerve cells within 30 min after adding the sample, compared to 80 min in adding two other growth factors. Number of neurite-bearing cells remained relatively steady in adding the polymer even when the cell growth started to be decreased. It was interesting that the polymer effectively delayed apoptosis of PC12 cells by dramatically reducing the ratio of apoptotic cells to 20% from 50% of the control. This revised version was published online in September 2006 with corrections to the Cover Date.     

Biological response of the intervertebral disc to dynamic loading

Disc degeneration is a chronic remodeling process that results in alterations of matrix composition and decreased cellularity. This study tested the hypothesis that dynamic mechanical forces are important regulators in vivo of disc cellularity and matrix synthesis. A murine model of dynamic loading was developed that used an external loading device to cyclically compress a single disc in the tail. Loads alternated at a 50% duty cycle between 0MPa and one of two peak stresses (0.9 or 1.3MPa) at one of two frequencies (0.1 or 0.01Hz) for 6h per day for 7 days. An additional group received static compression at 1.3MPa for 3h/day for 7 days. A control group wore the device with no loading. Sections of treated discs were analyzed for morphology, proteoglycan content, apoptosis, cell areal density, and aggrecan and collagen II gene expression. Dynamic loading induced differential effects that depended on frequency and stress. No significant changes to morphology, proteoglycan content or cell death were found after loading at 0.9MPa, 0.1Hz. Loading at lower frequency and/or higher stress increased proteoglycan content, matrix gene expression and cell death. The results have implications in the prevention of intervertebral disc degeneration, suggesting that loading conditions may be optimized to promote maintenance of normal structure and function.     

Embryonic and regenerating Xenopus retinal fibers are intrinsically different

Growth and guidance behavior of Xenopus embryonic (ER) (optic vesicle stage 25/26) and regenerating retinal fibers (stage 47/50 newly regenerating NR, and actively regenerating RR, respectively) have been studied in vitro on a variety of substrates in serum-free media. RR retinas receive a prior conditioning lesion 12-14 days before explantation while NR retinas are explanted immediately after axotomy. The substrates include plastic (UN), polylysine (PL), polyornithine (PO), laminin (LM), fibronectin (FN), and collagen type I (CO). Two kinds of experimental situations were tested, one in which substrates were derivatized to plastic as a planar surface, while the second involved the addition of a substrate as a soluble supplement to dishes derivatized with PL. A neurite growth index (NGI), based on density of neurite outgrowth and axon lengths, is determined for each fiber type on all substrates. Embryonic and regenerating fibers are phenotypically different fiber types; each displays a specific "substrate preference profile" (SPP), reflecting differential growth on each substrate. ER neurites grow equally well on all planar substrates, including plastic, but do not grow on CO (SPP, LM = FN = PL = PO = UN greater than CO). Both NR and RR neurites show distinct substrate preferences, but RR neurites grow more vigorously (SPP, LM greater than CO greater than PL = PO greater than FN). In media supplemented with LM, FN or CO, the SPPs showed little change but the neurite bundle patterns were qualitatively different. Only regenerating neurites display clockwise growth in laminin (LM) and fibronectin (FN)-supplemented media. Under no conditions do embryonic fibers exhibit this pattern which suggests that embryonic and regenerating retinal fibers also differ in cytoskeletal organization. Evidence of intrinsic growth differences in vitro suggest that embryonic and regenerating retinal fibers may not respond to identical guidance cues during in vivo development and regeneration of retinotectal connections.     

Axonal growth in response to experimentally applied mechanical tension

A machine was constructed, called a Cell Puller, that allows the steady advance or withdrawal of a microelectrode at very slow speeds—up to 170 μm/hr. Specially prepared microelectrodes held in the Cell Puller were placed in cultures of dissociated chick sensory ganglion neurons in such a way that growth cones attached to their tips. Movements of the microelectrodes, at speeds up to about 100 μm/hr, then resulted in the elongation of the neurites for up to 24 hr and for increases in length up to 960 μm; more rapid towing failed to cause extensive neurite elongation. Estimates of neurite diameter before and after “towing” indicated that a net increase in neurite volume had occurred. Furthermore, long neurites could be produced by towing from previously rounded neuronal cell bodies confined to small adhesive “islands” on a nonadhesive substratum. Neurites produced by microelectrode towing had a normal appearance, showed rapid saltatory movements of internal organelles and were capable of resuming growth on the substratum. Electron microscopy of bundles of neurites produced in this way from explanted dorsal root ganglia showed an ultrastructure typical of cultured neurites, with abundant longitudinally aligned microtubules and neurofilaments. These experiments demonstrate that neurites can grow in response to mechanical tension under tissue culture conditions. It is proposed that they do so also in normal development, the tension in this case being supplied initially by the locomotory activity of the growth cones and subsequently by the morphogenetic movements of the surrounding tissues.     

Effect of the weaver (wv) mutation on cerebellar neuron differentiation. II. Quantitation of neuron behavior in culture

Quantitative measurements of neuron behavior from time-lapse microcinematography of dissociated cultures of normal (+/+), heterozygous weaver (+/wv), and homozygous weaver (wv/wv) 7-day-old mouse cerebellum were performed to identify dose-dependent expressions of the mutant allele. Impaired neurite growth by granule cell neurons is a direct result of a dose-dependent increased frequency of neurite retraction and decreased rate of growth cone advancement. The number of retractions per neurite is 0.2, 1.0, and 2.0 for +/+, +/wv, and wv/wv neurites, respectively. Maximal rates of growth cone advancement are 1041, 443, and 250 micron/day for +/+, +/wv, and wv/wv granule cell neurites, respectively. Neurite initiation is actually increased in wv/wv cultures, though the neurites are not well sustained. The frequency of neurite initiation is 1.0, 1.7, and 2.2 for +/+, +/wv, and wv/wv neurons, respectively. Measurements of oscillations of somal position revealed that the cell center moves increasing distances over short times in proportion to the number of mutant genes. Nuclear translocation, the mode of somal migration in vivo and in vitro, occurs at the same frequency and rate in normal and mutant cultures. Weaver gene expression induces a cytopathology affecting various morphogenetic events rather than producing a block at a specific stage in granule cell differentiation. It is hypothesized that the dose-dependent impairments of cell motility reflect weaver gene action at the cell surface or cytoskeleton.     

Cell adhesion molecules in the early developing mouse retina: Retinal neurons show preferential outgrowth in vitro on L1 but not N-CAM

Both L1 and N-CAM are present on optic axons early in the developing mouse retina and optic nerve. In in vitro assays on substrates of purified cell adhesion molecules cells derived from E13 mouse retinae showed vigorous neurite extension on L1 but not on N-CAM. Although retinal neurons on N-CAM showed only limited attachment to the substrate, they were able to form lamellipodia immediately around the cell perimeter. In contrast, similarly derived cortical cells showed extensive neurite outgrowth on both substrates. Under these culture conditions, nearly all of the L1 and N-CAM present in the cell membrane appeared to be sequestered on the lower surface of the growth cones and neurites, indicating that most of these cell adhesion molecules were involved in homophilic interactions. Our results suggest differential roles for L1 and N-CAM in intitiation and establishment of the optic pathway. © 1994 John Wiley & Sons, Inc.     

Long-term culture of tissue engineered cartilage in a perfused chamber with mechanical stimulation

One approach to functional tissue engineering of cartilage is to utilize bioreactors to provide environmental conditions that stimulate chondrogenesis in cells cultured on biomaterial scaffolds. We report the combined use of a three-dimensional in vitro model and a novel bioreactor with perfusion of culture medium and mechanical stimulation in long-term studies of cartilage development and function. To engineer cartilage, scaffolds made of a non-woven mesh of polyglycolic acid (PGA) were seeded with bovine calf articular chondrocytes, cultured for an initial 30-day period under free swelling conditions, and cultured for an additional 37 day period in one of the three groups: (1) free-swelling, (2) static compression (on 24 h/day, strain control, static offset 10%), and (3) dynamic compression (on 1 h/day; off 23 h/day; strain control, static offset 2%, dynamic strain amplitude 5%; frequency 0.3 Hz). Constructs were sampled at timed intervals and assessed with respect to structure, biochemical composition, and mechanical function. Mechanical simulation had little effect on the compositions, morphologies and on mechanical properties of construct interiors discs, but it resulted in distincly different properties of the peripheral rings and face sides. Contructs cultured with mechanical loading maintained their cylindrical shape with flat and parallel top and bottom surfaces, and retained larger amounts of GAG. The modular bioreactor system with medium perfusion and mechanical loading can be utilized to define the conditions of cultivation for functional tissue engineering of cartilage.     

J1/tenascin in substrate-bound and soluble form displays contrary effects on neurite outgrowth

The influence of J1/tenascin adsorbed to polyornithine-conditioned plastic (substrate-bound J1/tenascin) and J1/tenascin present in the culture medium (soluble J1/tenascin) on neurite outgrowth was studied with cultured single cells from hippocampus and mesencephalon of embryonic rats. Neurons at low density grew well on J1/tenascin substrates and extended neurites that were approximately 40% longer than on the polyornithine control substrate after 24 h in vitro. The neurite outgrowth promoting effect of substrate bound J1/tenascin was largely abolished in the presence of mAb J1/tn2, but not by mAb J1/tn1. In contrast to the neurite growth-promoting effects of substrate bound J1/tenascin, neurite outgrowth on polyornithine, laminin, fibronectin, or J1/tenascin as substrates was inhibited by addition of soluble J1/tenascin to the cultures. Neither of the two mAbs neutralized the neurite outgrowth-inhibitory properties of soluble J1/tenascin. In contrast to their opposite effects on neurite outgrowth, both substrate-bound and soluble J1/tenascin reduced spreading of the neuronal cell bodies, suggesting that the neurite outgrowth-promoting and antispreading effects are mediated by two different sites on the molecule. This was further supported by the inability of the mAb J1/tn2 to neutralize the antispreading effect. The J1/tn2 epitope localizes to a fibronectin type III homology domain that is presumably distinct from the putative Tn68 cell-binding domain of chicken tenascin for fibroblasts, as shown by electronmicroscopic localization of antibody binding sites. We infer from these experiments that J1/tenascin contains a neurite outgrowth promoting domain that is distinguishable from the cell-binding site and presumably not involved in the inhibition of neurite outgrowth or cell spreading. Our observations support the notion that J1/tenascin is a multifunctional extracellular matrix molecule.     

Design and application of an oscillatory compression device for cell constructs

Mechanical compression has been shown to impact cell activity; however a need for a single device to perform a broader range of parametric studies exists. We have developed an oscillatory displacement controlled device to uniaxially strain cell constructs under both static and dynamic compression and used this device to investigate gene expression in cell constructs. The device has a wide stroke (0.25-4 mm) and frequency range (0.1-3 Hz) and several loading waveforms are possible. Alginate cellular constructs with embedded equine chondrocytes were tested and viability was maintained for the 24 h test period. Off-line mechanical testing is described and a modulus value of 18.2 +/- 1.3 kPa found for alginate disks which indicates the level of stress achieved with this deformation profile. Static (15% strain) and dynamic (15% strain, 1 Hz, triangle waveform) testing of chondrocyte constructs was performed and static compression showed significantly higher collagen II expression than dynamic using quantitative RT-PCR. In contrast, differences in matrix metalloproteinase-3 (MMP-3) expression were statistically insignificant. These studies indicate the utility of our device for studying cell activity in response to compression and suggest further studies regarding how the load and strain spectrum impact chondrocyte activity.     

Developmental decrease in neurite extension in cultured chick embryo retina and spinal cord neurons

Retina and spinal cord neurons from chick embryos attach to culture substrates and extend neurites. There is a statistically significant age-related decrease in the percentage and average length of neurites formed in 24-hr cultures of chick retina and spinal cord neurons between 6 and 16 days of embryonic age. The developmental decrease of neurite extension may be important for synaptogenesis in the developing nervous system.