Sally Meiners

Three-dimensional nanofibrillar surfaces promote self-renewal in mouse embryonic stem cells

The regulation of mouse embryonic stem cell (mESC) fate is controlled by the interplay of signaling networks that either promote self‐renewal or induce differentiation. Leukemia inhibitory factor (LIF) is a cytokine that is required for stem cell renewal in mouse but not in human embryonic stem cells. However, feeder layers of embryonic fibroblasts are capable of inducing stem cell renewal in both cell types, suggesting that the self‐renewal signaling pathways may also be promoted by other triggers, such as alternative cytokines and/or chemical or physical properties of the extracellular matrix (ECM) secreted by feeder fibroblasts. We have recently used a synthetic polyamide matrix (Ultra‐Web) whose three‐dimensional (3D) nanofibrillar organization resembles the ECM/basement membrane. Growth of mESCs on this nanofibrillar surface greatly enhanced proliferation and self‐renewal in comparison with growth on tissue culture surfaces without nanofibers, despite the presence of LIF in both systems. Enhanced proliferation and self‐renewal of the stem cells on nanofibrillar surfaces were correlated with the activation of the small GTPase Rac, the activation of phosphoinositide 3‐kinase (PI3K) pathway, and the enhanced expression of Nanog, a homeoprotein required for maintenance of pluripotency. Inhibitors of PI3K reduced the expression level of Nanog in mESCs cultured on 3D nanofibrillar surfaces. These results provide support for the view that the three‐dimensionality of the culture surface may function as a cue for the activation of Rac and PI3K signaling pathways, resulting in stem cell proliferation and self‐renewal.

Living in three dimensions: 3D nanostructured environments for cell culture and regenerative medicine.

Research focused on deciphering the biochemical mechanisms that regulate cell proliferation and function has largely depended on the use of tissue culture methods in which cells are grown on two-dimensional (2D) plastic or glass surfaces. However, the flat surface of the tissue culture plate represents a poor topological approximation of the more complex three-dimensional (3D) architecture of the extracellular matrix (ECM) and the basement membrane (BM), a structurally compact form of the ECM. Recent work has provided strong evidence that the highly porous nanotopography that results from the 3D associations of ECM and BM nanofibrils is essential for the reproduction of physiological patterns of cell adherence, cytoskeletal organization, migration, signal transduction, morphogenesis, and differentiation in cell culture. In vitro approximations of these nanostructured surfaces are therefore desirable for more physiologically mimetic model systems to study both normal and abnormal functions of cells, tissues, and organs. In addition, the development of 3D culture environments is imperative to achieve more accurate cell-based assays of drug sensitivity, high-throughput drug discovery assays, and in vivo and ex vivo growth of tissues for applications in regenerative medicine.

Mechanisms of astrocyte-directed neurite guidance

Abstract. Astrocytes have recently become better recognized as playing vital roles in regulating the patterning of central nervous system neurites during development and following injury. In general, astrocytes have been shown to be supportive of neurite extension, but alterations in the biochemical properties of astrocytes in particular areas during development and in gliotic tissue may act to confine neurite outgrowth and thus provide guidance cues. In vivo studies indicate that restrictive astrocytes function through their altered expression of specific extracellular matrix molecules, including tenascin, chondroitin, and keratan sulfate proteoglycans. In addition, several in vitro models suggest that other cell surface molecules are utilized by restrictive astrocytes to direct neurite trajectories.

A Distinct Subset of Tenascin/CS-6-PG-Rich Astrocytes Restricts Neuronal Growth in vitro

Astrocytes provide an optimal surface for attachment, migration, and growth of CNS neurons. Nonetheless, not all astrocytes are alike: our previous work demonstrated a heterogeneity in the ability of cultured astrocyte monolayers to support neuronal growth. Areas displaying a fibrous, uneven surface ( “rocky” astrocytes) were shown to be restrictive substrates, whereas surrounding, flat areas were permissive substrates. However, whether these cell types are in fact different cannot be addressed using mixed cultures. Therefore, in the current study we used morphological criteria to isolate the two subpopulations from mixed astrocyte cultures established from the cerebral cortex of neonatal rats. Following isolation, the purified populations only produced progeny with the same phenotype as the parent cells. We then measured production of several extracellular matrix molecules putatively involved in neuronal guidance during development and quantitatively assessed neuronal behavior on the purified populations. Immunocytochemistry and immunoblotting showed that rocky astrocytes were enriched in tenascin and chondroitin-6- sulfate-containing proteoglycans, but not in laminin or fibronectin. In addition, these astrocytes, as well as their isolated matrix, were a less permissive substrate for neuronal growth than flat astrocytes/matrix. Neurite outgrowth was significantly increased on rocky astrocytes following treatment with chondroitinase ABC or AC, but not heparitinase or hyaluronidase. These data support a critical role for matrix-bound chondroitin-6-sulfate-containing proteoglycans. We hypothesize that rocky astrocytes represent a subtype of cells which form barriers to neuronal growth during cortical development.

An analysis of astrocytic cell lines with different abilities to promote axon growth

The adult mammalian central nervous system (CNS) lacks the capacity to support axonal regeneration. There is increasing evidence to suggest that astrocytes, the major glial population in the CNS, may possess both axon-growth promoting and axon-growth inhibitory properties and the latter may contribute to the poor regenerative capacity of the CNS. In order to examine the molecular differences between axon-growth permissive and axon-growth inhibitory astrocytes, a panel of astrocyte cell lines exhibiting a range of axon-growth promoting properties was generated and analysed. No clear correlation was found between the axon-growth promoting properties of these astrocyte cell lines with: (i) the expression of known neurite-outgrowth promoting molecules such as laminin, fibronectin and N-cadherin; (ii) the expression of known inhibitory molecules such tenascin and chondroitin sulphate proteoglycan; (iii) plasminogen activator and plasminogen activator inhibitor activity; and (iv) growth cone collapsing activity. EM studies on aggregates formed from astrocyte cell lines, however, revealed the presence of an abundance of extracellular matrix material associated with the more inhibitory astrocyte cell lines. When matrix deposited by astrocyte cell lines was assessed for axon-growth promoting activity, matrix from permissive lines was found to be a good substrate, whereas matrix from the inhibitory astrocyte lines was a poor substrate for neuritic growth. Our findings, taken together, suggest that the functional differences between the permissive and the inhibitory astrocyte cell lines reside largely with the ECM.

Neurite outgrowth by the alternatively spliced region of human tenascin-C is mediated by neuronal alpha7beta1 integrin.

The region of tenascin-C containing only alternately spliced fibronectin type-III repeat D (fnD) increases neurite outgrowth by itself and also as part of tenascin-C. We previously localized the active site within fnD to an eight amino acid sequence unique to tenascin-C, VFDNFVLK, and showed that the amino acids FD and FV are required for activity. The purpose of this study was to identify the neuronal receptor that interacts with VFDNFVLK and to investigate the hypothesis that FD and FV are important for receptor binding. Function-blocking antibodies against both α7 and β1 integrin subunits were found to abolish VFDNFVLK-mediated process extension from cerebellar granule neurons. VFDNFVLK but not its mutant, VSPNGSLK, induced clustering of neuronal β1 integrin immunoreactivity. This strongly implicates FD and FV as important structural elements for receptor activation. Moreover, biochemical experiments revealed an association of the α7β1 integrin with tenascin-C peptides containing the VFDNFVLK sequence but not with peptides with alterations in FD and/or FV. These findings are the first to provide evidence that the α7β1 integrin mediates a response to tenascin-C and the first to demonstrate a functional role for the α7β1 integrin receptor in CNS neurons.

Cytokine-induced changes in the ability of astrocytes to support migration of oligodendrocyte precursors and axon growth.

Repair of demyelination in the CNS requires that oligodendrocyte precursors (OPs) migrate, divide and then myelinate. Repair of axon damage requires axonal regeneration. Limited remyelination and axon regeneration occurs soon after injury, but usually ceases in a few days. In vivo and in vitro experiments have shown that astrocytic environments are not very permissive for migration of OPs or for axonal re‐growth. Yet remyelination and axon sprouting early after injury occurs in association with astrocytes, while later astrocytes can exclude remyelination and prevent axon regeneration. A large and changing cast of cytokines are released following CNS injury, so we investigated whether some of these alone or in combination can affect the ability of astrocytes to support migration of OPs and neuritic outgrowth. Interleukin (IL) 1α, tumour necrosis factor α, transforming growth factor (TGF) β, basic fibroblast growth factor (bFGF), platelet‐derived growth factor and epidermal growth factor alone exerted little or no effect on migration of OPs on astrocytes, whereas interferon (IFN) γ was inhibitory. The combination of IL‐1α + bFGF was found to be pro‐migratory, and this effect could be neutralized by TGFβ. We also examined neuritic outgrowth from dorsal root ganglion explants in three‐dimensional astrocyte cultures treated with cytokines and found that IL‐1α + bFGF greatly increased axon outgrowth and that this effect could be blocked by TGFβ and IFNγ. All these effects were absent or much smaller when OP migration or axon growth was tested on laminin, so the main effect of the cytokines was via astrocytes. The cytokine effects did not correlate with expression on astrocytes of laminin, fibronectin, tenascin, chondroitin sulphate proteoglycan, N‐cadherin, polysialyated NCAM (PSA‐NCAM), tissue plasminogen activator (tPA) or urokinase (uPA).

Inflammatory Cytokines Interact to Modulate Extracellular Matrix and Astrocytic Support of Neurite Outgrowth

Following injury to the central nervous system, an astroglial scar forms that is thought to impede neuronal regeneration and recovery of function. It is our hypothesis that inflammatory cytokines act upon astrocytes to alter their biochemical and physical properties, which may in turn be responsible for failed neuronal regeneration. We have therefore examined the interactions of two cytokines with prominent actions following injury, interferon-gamma (IFN-gamma) and basic fibroblast growth factor (FGF2), in modulating the extracellular matrix and proliferation of astrocytes in culture. We also evaluated the effects of these cytokines on the ability of astrocytes to support the growth of neurites. IFN-gamma significantly inhibited the proliferation of rat cortical astrocytes both in serum-free and serum-containing media as measured by [3H]thymidine incorporation. Furthermore, IFN-gamma also antagonized FGF2-induced proliferation. In parallel, IFN-gamma reduced the levels of the ECM molecules tenascin, laminin, and fibronectin as evaluated by Western blot analysis and immunocytochemistry. Similarly, IFN-gamma also antagonized FGF2-induced tenascin formation. While IFN-gamma-pretreated astrocyte monolayers did not differ from control in their ability to support neurite outgrowth of cortical neurons, it antagonized the enhancement of neurite outgrowth on FGF2-treated monolayers. We demonstrate that IFN-gamma did not alter signal transduction through the FGF2 receptor down to the phosphorylation of mitogen-activated protein kinase, suggesting that the interaction is at the level of transcriptional regulation or that an alternate pathway is involved. These results support the hypothesis that inflammatory cytokines interact to modulate several facets of the gliotic response and such interactions may be important in creating the biochemical and physical properties of the glial scar.

Functional peptide sequences derived from extracellular matrix glycoproteins and their receptors: strategies to improve neuronal regeneration.

Peptides derived from extracellular matrix proteins have the potential to function as potent therapeutic reagents to increase neuronal regeneration following central nervous system (CNS) injury, yet their efficacy as pharmaceutical reagents is dependent upon the expression of cognate receptors in the target tissue. This type of codependency is clearly observed in successful models of axonal regeneration in the peripheral nervous system, but not in the normally nonregenerating adult CNS. Successful regeneration is most closely correlated with the induction of integrins on the surface of peripheral neurons. This suggests that in order to achieve optimal neurite regrowth in the injured adult CNS, therapeutic strategies must include approaches that increase the number of integrins and other key receptors in damaged central neurons, as well as provide the appropriate growth-promoting peptides in a “regeneration cocktail.” In this review, we describe the ability of peptides derived from tenascin-C, fibronectin, and laminin-1 to influence neuronal growth. In addition, we also discuss the implications of peptide/receptor interactions for strategies to improve neuronal regeneration.

Morphology, cytoskeletal organization, and myosin dynamics of mouse embryonic fibroblasts cultured on nanofibrillar surfaces

Growth of cells in tissue culture is generally performed on two-dimensional (2D) surfaces composed of polystyrene or glass. Recent work, however, has shown that such 2D cultures are incomplete and do not adequately represent the physical characteristics of native extracellular matrix (ECM)/basement membrane (BM), namely dimensionality, compliance, fibrillarity, and porosity. In the current study, a three-dimensional (3D) nanofibrillar surface composed of electrospun polyamide nanofibers was utilized to mimic the topology and physical structure of ECM/BM. Additional chemical cues were incorporated into the nanofibrillar matrix by coating the surfaces with fibronectin, collagen I, or laminin-1. Results from the current study show an enhanced response of primary mouse embryonic fibroblasts (MEFs) to culture on nanofibrillar surfaces with more dramatic changes in cell spreading and reorganization of the cytoskeleton than previously observed for established cell lines. In addition, the cells cultured on nanofibrillar and 2D surfaces exhibited differential responses to the specific ECM/BM coatings. The localization and activity of myosin II-B for MEFs cultured on nanofibers was also compared. A dynamic redistribution of myosin II-B was observed within membrane protrusions. This was previously described for cells associated with nanofibers composed of collagen I but not for cells attached to 2D surfaces coated with monomeric collagen. These results provide further evidence that nanofibrillar surfaces offer a significantly different environment for cells than 2D substrates.