Benjamin W. Lindsey

Easy and Rapid Differentiation of Embryonic Stem Cells into Functional Motoneurons Using Sonic Hedgehog‐Producing Cells

Directing embryonic stem (ES) cells to differentiate into functional motoneurons has proven to be a strong technique for studying neuronal development as well as being a potential source of tissue for cell replacement therapies involving spinal cord disorders. Unfortunately, one of the mitogenic factors (i.e., sonic hedgehog agonist) used for directed differentiation is not readily available, and thus this technique has not been widely accessible. Here, we present a novel and simple method to derive motoneurons from ES cells using readily attainable reagents. ES cells were derived from a mouse in which enhanced green fluorescent protein (eGFP) was linked to a motoneuron specific promoter. The cells were plated onto a monolayer of 293 EcR‐Shh cells that carry an integrated construct for the expression of sonic hedgehog (Shh) under ecdysone‐inducible control. To initiate motoneuron differentiation, 293 EcR‐Shh:ES cell cocultures were treated with ponasterone A (PA) and retinoic acid for 5 days. PA induces ecdysone, and thus drives Shh expression. To assess differentiation, putative ES cell‐derived motoneurons were studied immunocytochemically and cultured on chick myotubes for functional analysis. We found that ES cells differentiated into eGFP+ cells that expressed transcription factors typical of motoneurons. Furthermore, ES cell‐derived motoneurons were capable of forming functional connections with muscle fibers in vitro. Finally, when transplanted into the developing chick spinal cord, ES cell‐derived motoneurons migrated to the ventral horn and projected axons to appropriate muscle targets. In summary, this simple treatment paradigm produces functional motoneurons that can be used for both developmental and preclinical studies.

The cellular composition of neurogenic periventricular zones in the adult zebrafish forebrain

A central goal of adult neurogenesis research is to characterize the cellular constituents of a neurogenic niche and to understand how these cells regulate the production of new neurons. Because the generation of adult‐born neurons may be tightly coupled to their functional requirement, the organization and output of neurogenic niches may vary across different regions of the brain or between species. We have undertaken a comparative study of six (D, Vd, Vv, Dm, Dl, Ppa) periventricular zones (PVZs) harboring proliferative cells present in the adult forebrain of the zebrafish (Danio rerio), a species known to possess widespread neurogenesis throughout life. Using electron microscopy, we have documented for the first time the detailed cytoarchitecture of these zones, and propose a model of the cellular composition of pallial and subpallial PVZs, as well as a classification scheme for identifying morphologically distinct cell types. Immunolabeling of resin‐embedded tissue confirmed the phenotype of three constitutively proliferating (bromodeoxyuridine [BrdU]+) cell populations, including a radial glial‐like (type IIa) cell immunopositive for both S100β and glutamine synthetase (GS). Our data revealed rostrocaudal differences in the density of distinct proliferative populations, and cumulative labeling studies suggested that the cell cycle kinetics of these populations are not uniform between PVZs. Although the peak numbers of differentiated neurons were generated after ∼2 weeks among most PVZs, niche‐specific decline in the number of newborn neurons in some regions occurred after 4 weeks. Our data suggest that the cytoarchitecture of neurogenic niches and the tempo of neuronal production are regionally distinct in the adult zebrafish forebrain. J. Comp. Neurol. 520:2275–2316, 2012.

From Inflation to Flotation: Contribution of the Swimbladder to Whole-Body Density and Swimming Depth During Development of the Zebrafish (Danio rerio)

Teleost fishes have body tissues that are denser than water, causing them to sink. Many teleosts therefore possess a gas-filled swimbladder that provides lift, allowing fish to attain neutral buoyancy. The importance of the swimbladder as a buoyancy aid during changing body sizes over ontogeny and its role in determining the swimming depth of fish remain unclear. In this study, we have used the zebrafish (Danio rerio) to investigate changes in the size and shape of the swimbladder during development and examine whether these changes affect the hydrostatic contribution of the swimbladder during swimming. Our results showed that swim-up behavior is critical for larvae to first inflate their swimbladder, decrease body density, and attain neutral buoyancy. Following inflation, we found a strong linear correlation between fish volume and swimbladder volume over ontogeny. This trend was supported by measures of the density of zebrafish, which was conserved within a narrow range between 1.00 +/- 0.001 and 0.996 +/- 0.001 g/cm(3) despite an increase in the swimming depth of zebrafish, which occurred upon transition to a double-chambered organ. Finally, we demonstrated that the contribution of the swimbladder keeps the fish within 1.7% of neutral buoyancy throughout larval development.

Changes in the social environment induce neurogenic plasticity predominantly in niches residing in sensory structures of the zebrafish brain independently of cortisol levels

The social environment is known to modulate adult neurogenesis. Studies in mammals and birds have shown a strong correlation between social isolation and decreases in neurogenesis, whereas time spent in an enriched environment has been shown to restore these deficits and enhance neurogenesis. These data suggest that there exists a common adaptive response among neurogenic niches to each extreme of the social environment. We sought to further test this hypothesis in zebrafish, a social species with distinct neurogenic niches within primary sensory structures and telencephalic nuclei of the brain. By examining stages of adult neurogenesis, including the proliferating stem/progenitor population, their surviving cohort, and the resulting newly differentiated neuronal population, we show that niches residing in sensory structures are most sensitive to changes in the social context, and that social isolation or novelty are both capable of decreasing the number of proliferating cells while increasing the number of newborn neurons within a single niche. Contrary to observations in rodents, we demonstrate that social novelty, a form of enrichment, does not consistently rescue deficits in cell proliferation following social isolation, and that cortisol levels do not negatively regulate changes in adult neurogenesis, but are correlated with the social context. We propose that enhancement or suppression of adult neurogenesis in the zebrafish brain under different social contexts depends largely on the type of niche (sensory or telencephalic), experience from the preceding social environment, and occurs independently of changes in cortisol levels.

The contribution of the swimbladder to buoyancy in the adult zebrafish (Danio rerio): a morphometric analysis.

Many teleost fishes use a swimbladder, a gas‐filled organ in the coelomic cavity, to reduce body density toward neutral buoyancy, thus minimizing the locomotory cost of maintaining a constant depth in the water column. However, for most swimbladder‐bearing teleosts, the contribution of this organ to the attainment of neutral buoyancy has not been quantified. Here, we examined the quantitative contribution of the swimbladder to buoyancy and three‐dimensional stability in a small cyprinid, the zebrafish (Danio rerio). In aquaria during daylight hours, adult animals were observed at mean depths from 10.1 ± 6.0 to 14.2 ± 5.6 cm below the surface. Fish mass and whole‐body volume were linearly correlated (r2 = 0.96) over a wide range of body size (0.16–0.73 g); mean whole‐body density was 1.01 ± 0.09 g cm−3. Stereological estimations of swimbladder volume from linear dimensions of lateral X‐ray images and direct measurements of gas volumes recovered by puncture from the same swimbladders showed that results from these two methods were highly correlated (r2 = 0.85). The geometric regularity of the swimbladder thus permitted its volume to be accurately estimated from a single lateral image. Mean body density in the absence of the swimbladder was 1.05 ± 0.04 g cm−3. The swimbladder occupied 5.1 ± 1.4% of total body volume, thus reducing whole‐body density significantly. The location of the centers of mass and buoyancy along rostro‐caudal and dorso‐ventral axes overlapped near the ductus communicans, a constriction between the anterior and posterior swimbladder chambers. Our work demonstrates that the swimbladder of the adult zebrafish contributes significantly to buoyancy and attitude stability. Furthermore, we describe and verify a stereological method for estimating swimbladder volume that will aid future studies of the functions of this organ. J Morphol., 2008.

Sensory‐specific modulation of adult neurogenesis in sensory structures is associated with the type of stem cell present in the neurogenic niche of the zebrafish brain

Teleost fishes retain populations of adult stem/progenitor cells within multiple primary sensory processing structures of the mature brain. Though it has commonly been thought that their ability to give rise to adult‐born neurons is mainly associated with continuous growth throughout life, whether a relationship exists between the processing function of these structures and the addition of new neurons remains unexplored. We investigated the ultrastructural organisation and modality‐specific neurogenic plasticity of niches located in chemosensory (olfactory bulb, vagal lobe) and visual processing (periventricular grey zone, torus longitudinalis) structures of the adult zebrafish (Danio rerio) brain. Transmission electron microscopy showed that the cytoarchitecture of sensory niches includes many of the same cellular morphologies described in forebrain niches. We demonstrate that cells with a radial‐glial phenotype are present in chemosensory niches, while the niche of the caudal tectum contains putative neuroepithelial‐like cells instead. This was supported by immunohistochemical evidence showing an absence of glial markers, including glial fibrillary acidic protein, glutamine synthetase, and S100β in the tectum. By exposing animals to sensory assays we further illustrate that stem/progenitor cells and their neuronal progeny within sensory structures respond to modality‐specific stimulation at distinct stages in the process of adult neurogenesis – chemosensory niches at the level of neuronal survival and visual niches in the size of the stem/progenitor population. Our data suggest that the adult brain has the capacity for sensory‐specific modulation of adult neurogenesis and that this property may be associated with the type of stem cell present in the niche.

Mural lymphatic endothelial cells regulate meningeal angiogenesis in the zebrafish

Mural cells of the vertebrate brain maintain vascular integrity and function, play roles in stroke and are involved in maintenance of neural stem cells. However, the origins, diversity and roles of mural cells remain to be fully understood. Using transgenic zebrafish, we identified a population of isolated mural lymphatic endothelial cells surrounding meningeal blood vessels. These meningeal mural lymphatic endothelial cells (muLECs) express lymphatic endothelial cell markers and form by sprouting from blood vessels. In larvae, muLECs develop from a lymphatic endothelial loop in the midbrain into a dispersed, nonlumenized mural lineage. muLEC development requires normal signaling through the Vegfc–Vegfd–Ccbe1–Vegfr3 pathway. Mature muLECs produce vascular growth factors and accumulate low-density lipoproteins from the bloodstream. We find that muLECs are essential for normal meningeal vascularization. Together, these data identify an unexpected lymphatic lineage and developmental mechanism necessary for establishing normal meningeal blood vasculature.

Effects of simulated microgravity on the development of the swimbladder and buoyancy control in larval zebrafish (Danio rerio)

The gas-filled swimbladder of teleost fishes provides hydrodynamic lift which counteracts the high density of other body tissues, and thereby allows the fish to achieve neutral buoyancy with minimal energy expenditure. In this study, we examined whether the absence of a constant direction gravitational vector affects the ontogeny of the swimbladder and buoyancy control in zebrafish (Danio rerio). We exposed fertilized eggs to simulated microgravity (SMG) in a closed rotating wall vessel with control eggs placed in a similar but nonrotating container. All eggs hatched in both groups. At 96 hr of postfertilization (hpf), all larvae were removed from the experimental and control vessels. At this point, 62% of the control larvae, but only 14% of SMG-exposed larvae, were observed to have inflated their swimbladder. In addition, the mean volume of the inflated swimbladders was significantly greater in the control larvae compared with larvae raised in SMG. After transfer to open stationary observation tanks, larvae with uninflated swimbladders in both groups swam to the surface to complete inflation, but this process was significantly delayed in larvae exposed to SMG. Initial differences in swimbladder inflation and volume between groups disappeared by 144 hpf. Furthermore, there were no apparent changes in patterns of development and maturation of swimbladder musculature, vasculature, or innervation resulting from SMG exposure at later stages of ontogeny. These data indicate that, despite a transient delay in swimbladder inflation in zebrafish larvae exposed to SMG, subsequent swimbladder development in these animals proceeded similarly to that in normal larvae.

A library of AuNPs modified by RAFT polymers of different charge and chain length: High throughput synthesis and synchrotron XFM imaging using a zebrafish larvae model

Gold nanoparticles (AuNPs) have been widely investigated in drug delivery and imaging. However, for such biomedical applications, the modification of AuNPs is necessary to improve their aqueous dispersion stability and biocompatibility, especially in a salt environment. Here, we report a simple and highly efficient method to create a library of polymer-modified gold nanoparticles (PAuNPs) and screen their dispersion stability utilizing high-throughput facilities (in total 1000 experiments). Three types of water soluble polymers with different charge and chain length were prepared using Reversible Addition-Fragmentation chain Transfer (RAFT) polymerization technology. The polymers were then converted into thiol-capped polymers by aminolysis and coated on AuNPs via thiol–gold binding to improve aqueous dispersion stability as well as the biocompatibility of AuNPs. Remarkably, we present the first report of imaging zebrafish embryos injected with a PAuNPs sample (selected from our PAuNPs library) using synchrotron X-ray fluorescence microscopy (XFM) beamline. The selected PAuNPs sample, which has been evaluated to be non-cytotoxic to L929 cells and biocompatible to zebrafish larvae in a wide range of concentrations, was injected into zebrafish larvae via the cardinal vein and could be clearly visualized in the whole circulatory system including both peripheral blood vessels and the head region by XFM. The result indicates that zebrafish larvae could be a potential animal model for probing the ability of AuNPs to cross the blood–brain barrier (BBB) and therefore hold promise for investigating AuNPs in biomedical applications such as detecting cancer and Alzheimers disease (AD).

Tectal stem cells display diverse regenerative capacities

How diverse adult stem and progenitor populations regenerate tissue following damage to the CNS remains unknown across most neurogenic domains. To understand the role of quiescent radial-glial (qRG) stem cells during regeneration, we tested the hypothesis that qRG could be induced to proliferate and produce newborn neurons. We designed a stab lesion assay in the midbrain tectum of the adult zebrafish to target an isolated population of qRG, and investigated their proliferative behaviour, differentiation potential, and requirement of Wnt/β-catenin signalling for the regenerative response. EdU-labelling showed that a small proportion of qRG transit to a proliferative state (pRG), but that progeny of pRG are restricted to a radial-glial fate. Lesion promoted upregulation of proliferation and neurogenesis from neuro-epithelial-like amplifying progenitors (NE-Ap) of the tectal marginal zone (TMZ). Homeostatic levels of Wnt/β-catenin signalling persisted under lesioned conditions in the qRG/pRG population, whereby increased β-catenin staining and axin2 expression was present in the NE-Ap progenitor zone. Attenuation of Wnt signalling using Dickkopf-1, demonstrated that proliferative responses post-injury appeared to be Wnt-independent. Our results align with the emerging view that adult stem/progenitor phenotypes are characterized by discrete, rather than mutual, regenerative programs and that different stem cell domains employ different modes of regeneration.