Outgrowth Region Research Articles

Nanoscaffold's stiffness affects primary cortical cell network formation

Networks of neurons cultured on-chip can provide insights into both normal and disease-state brain function. The ability to guide neuronal growth in specific, artificially designed patterns allows us to study how brain function follows form. Primary cortical cells cultured on nanograting scaffolds, in particular astrocytes, showed highly ordered regions of dendritic outgrowth. Usually, materials suitable for nanopatterning have a stiffness far above that of the extracellular matrix. In this paper, the authors studied two materials with large differences in stiffness, polydimethylsiloxane (PDMS) and silicon. Our results show that both nanopatterned silicon and PDMS guide the outgrowth of astrocytes in cortical cell culture, but the growth of the astrocyte is affected by the stiffness of the substrate, as revealed by differences in the cell soma size and the organization of the outgrowth.

Automated tracking of stem cell lineages of Arabidopsis shoot apex using local graph matching

Shoot apical meristems (SAMs) of higher plants harbor stem-cell niches. The cells of the stem-cell niche are organized into spatial domains of distinct function and cell behaviors. A coordinated interplay between cell growth dynamics and changes in gene expression is critical to ensure stem-cell homeostasis and organ differentiation. Exploring the causal relationships between cell growth patterns and gene expression dynamics requires quantitative methods to analyze cell behaviors from time-lapse imagery. Although technical breakthroughs in live-imaging methods have revealed spatio-temporal dynamics of SAM-cell growth patterns, robust computational methods for cell segmentation and automated tracking of cells have not been developed. Here we present a local graph matching-based method for automated-tracking of cells and cell divisions of SAMs of Arabidopsis thaliana. The cells of the SAM are tightly clustered in space which poses a unique challenge in computing spatio-temporal correspondences of cells. The local graph-matching principle efficiently exploits the geometric structure and topology of the relative positions of cells in obtaining spatio-temporal correspondences. The tracker integrates information across multiple slices in which a cell may be properly imaged, thus providing robustness to cell tracking in noisy live-imaging datasets. By relying on the local geometry and topology, the method is able to track cells in areas of high curvature such as regions of primordial outgrowth. The cell tracker not only computes the correspondences of cells across spatio-temporal scale, but it also detects cell division events, and identifies daughter cells upon divisions, thus allowing automated estimation of cell lineages from images captured over a period of 72 h. The method presented here should enable quantitative analysis of cell growth patterns and thus facilitating the development of in silico models for SAM growth.

Effective Isolation and Culture of Endothelial Cells in Embryoid Body Differentiated from Human Embryonic Stem Cells

We describe the isolation of endothelial cells from the center region of the attached embryoid body (EB) by a two-step enzyme treatment. The isolated cells from the center and outgrowth region of the EB were characterized separately. As human embryonic stem (hES) cells differentiated in EB, they lost expression of the undifferentiated marker Oct-4, whereas expression levels of endothelial-specific markers were increased. Using RT-PCR, fluorescence-activated cell sorting (FACS) analysis, and immunofluorescence, we have shown that various endothelial cell markers, including platelet/endothelial cell adhesion molecule (PECAM), von Willebrand factor (vWF), Flk-1, and Tie2, were expressed on the attached EB. Compared with the outgrowth region of EB, the center region had a higher population of cells with these endothelial cell markers. Once isolated by the twostep enzyme treatment, cells from the center region continued to differentiate into endothelial cell lineage while expression level of endothelial cell markers in cells from the outgrowth region decreased in subcultures. This study has demonstrated that the isolation of EB by a two-step enzyme treatment is a useful technique to obtain endothelial cell marker-positive cells with high yield. Furthermore, a similar approach can be taken to identify the location and distribution of specific cell types in EB and thereby allow us to isolate and expand specific cell types.

Villous Explant Culture: Characterization and Evaluation of a Model to Study Trophoblast Invasion

The mechanisms that control invasion of cytotrophoblast (CTB) cells into the maternal decidua and myometrium with transformation of the maternal spiral arteries are not fully understood, but oxygen is thought to be a key factor. We carried out a semiquantitative evaluation of an explant culture model for use in the study of trophoblast proliferation and invasion. Explants of human villous tissue (6–9 weeks of gestation) cultured on Matrigel in both standard culture conditions (18% O2) and in a low oxygen environment (2% O2) produced regions of outgrowth, of cytotrophoblast cells from villous tips and migration of cells into the Matrigel. The number of sites of outgrowth and migration, area of outgrowth, and extent of migration of cells into the Matrigel tended to increase throughout the culture period (144 h) but varied between explants from the same placenta and those from different placentas. There were no significant differences in the number of sites of outgrowth or migration scores in explants cultured in a low oxygen environment compared to those cultured in standard conditions. This study highlights the importance of careful validation, design and interpretation of experiments using in vitro culture systems, particularly those investigating the regulatory role of oxygen.

Role of phosphatidylinositol 3-kinase in neuronal survival and axonal outgrowth of adult mouse dorsal root ganglia explants.

Adult ganglionic peripheral neurons have lost dependence on target-derived neurotrophin signaling for survival and regeneration after injury. To understand the mechanisms required to sustain such processes at maturity, we are studying neuronal survival and axonal outgrowth of adult mouse dorsal root ganglia (DRG) explants. We have here examined the role of phosphatidylinositol 3-kinase (PI3-K) activity. Both neuronal survival and axonal outgrowth of spontaneously growing preparations were decreased significantly by the PI3-K inhibitor LY294002 as was the increased outgrowth caused by nerve growth factor or glial cell line-derived factor. Inhibition of PI3-K activity promoted neuronal cell death to the same extent in the presence as in the absence of a growth factor, whereas inhibition of mitogen-activated protein kinase, MAPK, lacked effect. Using a compartmentalized system, it could be shown that only axonal outgrowth was decreased when the outgrowth region only was exposed to LY294002. Already-formed growth cones showed morphological changes within 5-10 min after exposure to LY294002. Akt (PKB) is one downstream effector of PI3-K. Immunofluorescence revealed the presence of activated Akt in DRG cell bodies and in axonal growth cones. Immunoreactivity was decreased by PI3-K inhibition. The results suggest that Akt is constitutively active in adult DRG neurons, and that PI3-K mediated processes are involved in neuronal survival of one or more DRG neuronal subpopulations and also in axonal elongation. The possible significance of Akt signaling for these effects is discussed.

Chondroitin and keratan sulfates have opposing effects on attachment and outgrowth of ventral mesencephalic explants in culture.

During rat brain development, striatal proteoglycan (PG) expression shows specific spatio-temporal modifications suggesting a possible role in the guidance of its dopaminergic afferents. The effects of individual glycosaminoglycans (GAGs) on dopaminergic (DA) neuronal adhesion and outgrowth were therefore studied. We tested the behavior of dissociated embryonic rat mesencephalic cells cultivated on substrate-bound GAGs. Neuronal attachment was very limited and quantitative morphometry revealed variations in DA fiber outgrowth depending on the type and the concentration of GAG used. Next, we developed a cryoculture system to examine how neurons react toward GAGs expressed in situ. Rat brain slices from different developmental stages were used as substrates for embryonic mesencephalic explants. Preferential regions of adherence and outgrowth were observed: the striatum was found to be the most permissive, whereas the cortex was inhibitory. Western blotting experiments confirmed quantitative and qualitative changes in chondroitin sulfate (neurocan, phosphacan) and keratan sulfate (KS) containing PGs in these substrates and enzymatic digestion of GAGs before cryoculture revealed a substantial involvement of PGs in DA neuron adhesion and outgrowth. In particular, CSPGs seemed to mediate the permissive effect of the striatum, whereas KS confers an inhibitory effect to the cortex. PGs may thus be important for limiting midbrain projections to the striatum during development and for maintaining topography in the adult.

Neuron cell positioning on polystyrene in culture by silver-negative ion implantation and region control of neural outgrowth

A new method to control the position of neuron cell attachment and extension region of neural outgrowth has been developed by using a pattering ion implantation with silver-negative ions into polystyrene dishes. This technique offers a promising method to form an artificially designed neural network in cell culture in vitro. Silver-negative ions were implanted into non-treated polystyrene dishes (NTPS) at conditions of 20 keV and 3×1015ions/cm2 through a pattering mask, which had as many as 67 slits of 60μm in width and 4 mm in length with a spacing of 60μm. For cell culture in vitro, nerve cells of PC-12h (rat adrenal phechromocytoma) were used because they respond to a nerve growth factor (NGF). In the first 2 days in culture without NGF, we observed a selective cell attachment only to the ion-implanted region in patterning Ag− implanted polystyrene sample (p-Ag/NTPS). In another 2 days in culture with NGF, the nerve cells expanded neurites only over the ion-implanted region. For collagen-coated p-Ag/NTPS sample of which collagen was coated after the ion implantation (Collagen/p-Ag/NTPS), most nerve cells were also attached on the ion-implanted region. However, neurites expanded in both ion-implanted and unimplanted regions. The contact angle of NTPS decreased after the ion implantation from 86° to 74°. The region selectivity of neuron attachment and neurite extension is considered to be due to contact angle lowering by the ion implantation as radiation effect on the surface.

Fins, limbs, and tails: outgrowths and axial patterning in vertebrate evolution

Current phylogenies show that paired fins and limbs are unique to jawed vertebrates and their immediate ancestry. Such fins evolved first as a single pair extending from an anterior location, and later stabilized as two pairs at pectoral and pelvic levels. Fin number, identity, and position are therefore key issues in vertebrate developmental evolution. Localization of the AP levels at which developmental signals initiate outgrowth from the body wall may be determined by Hox gene expression patterns along the lateral plate mesoderm. This regionalization appears to be regulated independently of that in the paraxial mesoderm and axial skeleton. When combined with current hypotheses of Hox gene phylogenetic and functional diversity, these data suggest a new model of fin/limb developmental evolution. This coordinates body wall regions of outgrowth with primitive boundaries established in the gut, as well as the fundamental nonequivalence of pectoral and pelvic structures. BioEssays 20:371–381, 1998. © 1998 John Wiley & Sons Inc.

Epithelium is required for maintaining FGFR-2 expression levels in facial mesenchyme of the developing chick embryo.

In the developing chick embryo, fibroblast growth factor-2 (FGFR-2) expression patterns correlate with outgrowth of facial prominences. Frontonasal mass prominences that form the pre-nasal cartilage and upper beak express high levels of FGFR-2 receptor, whereas maxillary prominences that form the flattened corners of the beak and palatal shelves express low FGFR-2 transcript levels. Facial epithelium is an abundant source of FGFs and is required to support outgrowth of mesenchymal tissue, including cartilage rod formation. Because FGFR-2 is highly expressed in regions of facial outgrowth and because epithelium is required for outgrowth of facial prominences, epithelium could be required to maintain FGFR-2 transcripts in facial mesenchyme. To test this hypothesis, we removed epithelium to inhibit outgrowth of regions of the embryonic face, grafted frontonasal mass and maxillary prominences into a host limb bud, and then examined changes in FGFR-2 expression using in situ hybridization. We also hybridized adjacent sections with collagen II probe to identify regions undergoing chondrogenesis. Our results indicate that removal of epithelium from frontonasal mass led to a decrease in FGFR-2 and collagen II expression 24 hr after grafting to host and that neither FGFR-2 nor collagen II expression increased to expected levels at 48 hr. These results suggest that there are signals in the epithelium required for increasing FGFR-2 and collagen II gene transcription, and the expression of these genes are linked to outgrowth of facial prominences.

Alterations in Msx 1 and Msx 2 expression correlate with inhibition of outgrowth of chick facial primordia induced by retinoic acid.

Spatially-restricted expression domains of Msx 1 and Msx 2 in the developing chick face suggest that they may play a role in epithelial-mesenchymal interactions governing outgrowth of facial primordia. Retinoid application to developing chick faces reproducibly inhibits upper beak outgrowth but the lower beak is unaffected. In the normal face, high levels of Msx gene transcripts in upper and lower beak primordia correlate with regions of outgrowth. Following retinoid treatment, Msx 1 and Msx 2 transcripts are rapidly down-regulated in upper beak primordia where outgrowth is inhibited, but remain largely unchanged in lower beak primordia, where outgrowth is unaffected. Decreases in gene expression precede retinoid-induced morphological changes in the upper beak, suggesting that Msx gene products are involved in mediating the effect of retinoids on facial development.

Astrocytes and regenerating axons at the proximal stump of the severed frog optic nerve.

We have studied the growing tip of the severed frog optic nerve, a central nervous system pathway that successfully regenerates. Since reconnection with the distal stump was prevented, guidance of the growing axons along anterogradely degenerating axons and their debris was precluded. One week after nerve section, there was vigorous mononuclear macrophage activity at the cut end, which quickly subsided. Phagocytosis of the remaining debris of retrograde degeneration in the proximal stump was carried out by astrocytes. Regenerating axons appeared at the tip of the stump 3 weeks after the cut. They were preferentially located near the periphery of the stump, in close proximity to astrocytes of the glia limitans. Eight weeks after the cut, regenerating axons formed a region of outgrowth protruding from the tip of the proximal stump. They were always accompanied by astrocytes, and no myelin-producing oligodendrocytes were seen in the outgrowth.

Phospholipase A2 activity is required for regeneration of sensory axons in cultured adult sciatic nerves.

The adult frog dorsal root ganglia (DRGs) and their sciatic nerves (ScN) survive in organ culture for several days. About 3 days after a local test crush, the sensory axons start to regenerate into the distal nerve stump at a rate of approximately 0.6-0.9 mm/day. The axonal outgrowth is inhibited in a non-toxic way by low concentrations of three different phospholipase A2 (PLA2) inhibitors: 4-bromophenacyl bromide (BPB), aristolochic acid, and oleyl-oxyethyl-phosphoryl-choline (OOPC). In contrast, the outgrowth was slightly stimulated by 0.2 microM melittin, a PLA2 activator. Most experiments refer to the effects of BPB, which was shown to almost completely inhibit outgrowth at a concentration which did not affect either ganglionic protein synthesis or axonal transport. Using a compartmental system it could clearly be shown that BPB exerted its action in the outgrowth region. Other experiments showed that the initial period (about 3 days), which precedes the outgrowth, was unaffected by BPB. Several structures, including axonal ones, showed immunoreactivity for the low molecular form of PLA2 (sPLA2). The results suggest that PLA2 activity plays an important role in nerve regeneration and exerts its action at a local level, where the growth cones move forward.

Calmodulin and in vitro regenerating frog sciatic nerves: release and extracellular effects.

Although calmodulin (CaM) is commonly considered to be an intracellular protein, it has been suggested lately that it is released and exerts functions extracellularly. In the present investigation this was studied in in vitro regenerating adult frog (Rana temporaria) sciatic nerves. Using a multi-compartment incubation chamber, the non-neuronal cells in the outgrowth region of such nerves were radiolabelled with amino acid precursors. Based on immunological criteria, these cells were shown to release CaM. When the nerves were treated with CaM, both the outgrowth of sensory axons and the injury-induced proliferation of non-neuronal cells were partially inhibited. The inhibitory effects occurred even when the incubation medium contained as little as 30 pM CaM. Furthermore, treatment with anti-CaM antibodies resulted in reduced outgrowth, which suggested that during normal conditions extracellular CaM is kept at an optimal concentration. Finally, conditioned medium was found to contain several CaM-binding proteins. The present findings may reflect an earlier unknown function of extracellular CaM in controlling various growth mechanisms in integrated tissues.

Okadaic Acid and Cultured Frog Sciatic Nerves: Potent Inhibition of Axonal Regeneration in Spite of Unaffected Schwann Cell Proliferation and Ganglionic Protein Synthesis

Okadaic acid (OA) is a frequently used phosphatase inhibitor that by inhibiting dephosphorylation increases the net phosphorylation level in various systems. In the present study OA was used to assess the role of balanced phosphorylation-dephosphorylation reactions for successful regeneration of peripheral nerves. To achieve this, the effects of OA on phosphorylation levels, neurite outgrowth, injury-induced support cell proliferation, and neurofilament stability, respectively, were investigated in the in vitro regenerating, adult frog sciatic sensory nerve. OA at a moderate concentration (20 nM) increased phosphorylation levels and almost completely inhibited the in vitro regeneration in a reversible way. The effect on regeneration was not due to induced neurofilament instability and was only seen when the drug was applied in the outgrowth region. The latter and the absence of effects on support cell proliferation indicate that OA acts locally at the level of newly formed axons. However, the inhibition of regeneration was not a consequence of reduced delivery of proteins by axonal transport, because this process in fact was increased by OA. Altogether, the study suggests that properly balanced phosphorylating-dephosphorylating reactions are critical for regeneration of peripheral nerves.

Retrograde axonal transport of locally synthesized proteins, e.g., actin and heat shock protein 70, in regenerating adult frog sciatic sensory axons.

The local synthesis and subsequent retrograde axonal transport of [35S]methionine-labelled proteins was studied in the in vitro regenerating adult frog sciatic sensory axons. By the use of a three compartment culture system, proteins in the outgrowth region were selectively labelled. After 2 days in culture a rise in TCA-insoluble radioactivity was detected in the dorsal root ganglia, which could be prevented by the addition of vinblastine or 2,4-dinitrophenol to the nerve proximal to the crush site. Two-dimensional polyacrylamide gel electrophoresis of ganglionic proteins revealed a pattern of 35 labelled polypeptides with apparent molecular masses (Mm) ranging from < 15 to 95 kDa and with isoelectric points (pI) ranging from 4.5 to 6.5. The major ones, representing about 75% of the activity in a gel, were of Mm/pI 47/5.4, 48/6.1,. 57/6.0, 62/5.2, 65/4.9-5.0, 65/5.2, and 81/5.4 respectively. One of these polypeptides (47/5.4) was identified as actin and another (81/5.4) as a member of the heat shock protein 70 family. The spots at 65/4.9-5.0 were tubulin isoforms. There was a striking similarity between transported proteins on one hand, and proteins synthesized in the injured nerve on the other, with respect to the Mm/pI of at least 14 protein species. The results suggest that a selected set of proteins, synthesized by non-neuronal cells, e.g., Schwann cells, is transferred to the ganglionic cell bodies by retrograde axonal transport.

Structural changes induced by glycine on Streptomyces antibioticus.

Germination and vegetative growth of Streptomyces antibioticus in liquid medium with different concentrations of glycine was examined. Both processes proved to be sensitive to the amino acid, being inhibited by 5 and 2.5% glycine, respectively. At concentrations of 5% or more, lysis of the vegetative mycelium occurred. Subinhibitory concentrations of glycine induced structural changes on germinating spores. These included an increase in the number of germ tubes produced by spore, in relation to the control. Moreover, soon after outgrowth the tubes bifurcate, giving rise to germinated spores with a characteristic aspect, and anomalous formation of cross-walls that appear both within the spores and in the newly formed germinative tubes, at or close to the region of outgrowth. The branching effect of glycine was also observed during vegetative growth of S. antibioticus.

Structural changes induced by glycine on Streptomyces antibioticus

Germination and vegetative growth of Streptomyces antibioticus in liquid medium with different concentrations of glycine was examined. Both processes proved to be sensitive to the amino acid, being inhibited by 5 and 2.5% glycine, respectively. At concentrations of 5% or more, lysis of the vegetative mycelium occurred. Subinhibitory concentrations of glycine induced structural changes on germinating spores. These included an increase in the number of germ tubes produced by spore, in relation to the control. Moreover, soon after outgrowth the tubes bifurcate, giving rise to germinated spores with a characteristic aspect, and anomalous formation of cross-walls that appear both within the spores and in the newly formed germinative tubes, at or close to the region of outgrowth. The branching effect of glycine was also observed during vegetative growth of S. antibioticus.

Regenerating Peripheral Axons Transport and Release Low‐Molecular‐Mass Materials In Vitro

The release of radiolabeled material from regenerating frog sciatic nerves was studied using a multicompartment chamber, in which the ganglia and the outgrowth region, respectively, were separated from the rest of the nerve. The nerves were incubated with radioactive amino acids in the ganglionic compartment, and the material transported to and released at the outgrowth region was collected and analyzed. Approximately 10% of the transported radioactivity was released over a 24-h incubation period. Of the released materials, 84% had a molecular mass of < 1,000 daltons [the low-molecular-mass (LM) fraction] as determined by exclusion chromatography. The presence of LM material could not be explained by leakage, nor was it due to intracellular or extracellular degradation of radiolabeled, transported proteins. It was reduced by cold and was shown by the use of vinblastine to be dependent on axonal transport. According to TLC, both the original precursor and metabolites thereof could be detected among the released LM material. The present results demonstrate the existence of a transport system for LM material in peripheral axons. The preferential release of LM over high-molecular-mass material at the outgrowth region suggests that it could serve specific functions during regeneration.

Insulin and IGF-II, but not IGF-I, stimulate the in vitro regeneration of adult frog sciatic sensory axons

We used the in vitro regenerating frog sciatic nerve to look for effects of insulin and insulin-like growth factors I and II (IGF-I, IGF-II) on regeneration of sensory axons and on injury induced support cell proliferation in the outgrowth region. In nerves cultured for 11 days, a physiological dose ( 10ng/ml, ≈ 2 nM) of insulin or IGF-II increased ganglionic protein synthesis (by 20% and 50%, respectively) as well as the level of newly formed, radiolabelled axonal material distal to a crush injury (both by 80%), compared to untreated, paired controls. In addition, insulin increased the outgrowth distance of the furthest regenerating sensory axons by 10%. The preparation was particularly sensitive to insulin during the first 5 days of culturing. Furthermore, both insulin and IGF-II were found to inhibit proliferation of support cells in the outgrowth region in a manner suggesting effects via their individual receptors. The inhibition, about 30%, was observable after 4 but not 11 days in culture. It is not clear if this reflects a stimulated differentiation of some cells. By contrast, IGF-I lacked effects on both regeneration and proliferation. In conclusion, the results suggest that insulin and IGF-II are involved in the regulation of peripheral nerve regeneration.

Effects of protein kinase inhibitors on regeneration in vitro of adult frog sciatic sensory axons.

The effects of protein kinase inhibitors on regeneration in vitro of adult frog sciatic sensory axons were tested. Regeneration of crush-injured nerves for 8 days in serum-free medium was inhibited by staurosporine (100 nM) and H-7 (100 microM), which are both known to inhibit protein kinase C. With the use of a compartmented culture system it could be shown that H-7 exerted both local (outgrowth region) and central (ganglia) effects, the latter being more pronounced. The local effects could be due to reduction of Schwann cell proliferation by H-7. Immunohistochemistry demonstrated the presence of protein kinase C in neuronal cell bodies but not in axonal processes. Proliferation of Schwann cells was accompanied by increased protein kinase C immunoreactivity at the site of injury. H-7 caused a selective inhibition in the incorporation of radioactive phosphate into one 74 kDa protein of both ganglia and nerve but also a more general decrease in protein labelling. The results show that protein phosphorylations, possibly mediated by protein kinase C, are involved in regeneration-related mechanisms operating at both local and central levels in the adult frog sciatic sensory axons.