Chemical and genetic control of melanocyte development, proliferation and regeneration in zebrafish

Marie, Kerrie Leanne

January 2013

Melanocytes are pigment-producing cells that colour our hair, skin and eyes. Melanocytes are evolutionary conserved in vertebrates, and in addition to contributing to pigmentation and pattern formation, can contribute to background adaptation (zebrafish) and protection against harmful UV irradiation (humans). Many of the processes involved in melanocyte development – such as migration, proliferation and differentiation - are misregulated in melanoma. Here, I use chemical biology in zebrafish to identify targetable pathways in melanocyte development and regeneration, with a view to how these processes may be misregulated in melanoma and other pigmentation syndromes. We first wanted to address the potential for small molecules to regulate multiple stages of melanocyte development and differentiation. In Chapter 3, I describe my work involved in a small molecule screen for clinically active compounds that alter melanocyte biology (Colanesi et al., 2012). In this work we have identified small-molecules that affect melanocyte migration, differentiation, survival, morphology and number. This is important as it highlights new pathways essential for normal melanocyte development and consequently provides further tools in which to study melanocytes. Identifying the target of small molecules in vivo is a challenge in chemical biology. In Chapter 4, I describe my contributions to understanding how 5-nitrofuran compounds act in zebrafish (Zhou et al., 2012). My work has contributed to understanding the activity of 5-nitrofurans is dependent upon its nitrofuran ring structure. I have also helped confirm a conserved interaction between 5-nitrofurans and ALDH2, which may contribute to the off-target effects observed in the clinic. These results are important as they aid further understand of the 5-nitrofuran class of drugs and give evidence to support combination therapy of 5-nitrofurans with ALDH2 inhibitors as a way to overcome clinical side effects. Additionally I show that NFN1 treatment limits ensuing melanocyte regeneration thereby suggesting a role at the Melanocyte Stem Cell (MSC), which provides me with a key tool to study melanocyte regeneration in zebrafish. How tissue specific cell numbers are specified and maintained is a key question in developmental biology. In Chapter 5, I describe the identification of the MITF gene in the maintenance of cell cycle arrest in differentiated melanocytes (Taylor et al., 2011). We show that the human melanoma mutation MITF4TΔ2B promotes melanocyte division, thereby suggesting a role for melanocyte division in the pathogenesis of melanoma. This work is valuable because it highlights Mitf as a molecular rheostat that controls melanocyte proliferation and differentiation in living vertebrates, and helps us to understand the role of MITF in melanoma progression. Little is known about the pathways that control melanocyte stem cells in animals. To identify new melanocyte stem cell pathways, I used NFN1 as the basis for a small molecule screen for enhancers of melanocyte regeneration (Chapter 6). I find that chemical inhibition of Phosphatase of Regenerating Liver-3 (Prl-3) in zebrafish can enhance melanocyte regeneration. Importantly, I have found that there are an increased number of melanocyte progenitor cells in PRL3-inhibitor treated zebrafish. I propose that PRL-3 may control progenitor cell number in melanocyte regeneration. This is significant because it identifies PRL-3 as a novel molecular target controlling melanocyte progenitor cells, and identifies a new chemical tool with which to study melanocyte differentiation from a progenitor population. In the final chapter, I discuss how this work relates to the larger field of melanocyte developmental biology, and the new insight it provides into the fundamental processes of how organisms control cell number and pattern formation. In addition, I discuss how this work may have implications for understanding and treating melanocyte diseases, such as vitiligo (loss of melanocytes) and melanoma (cancer of the melanocyte).

616.99

Analysis of developmental and regenerative spinal motor neuron generation in zebrafish larvae

Yang, Yujie

January 2017

In contrast to mammals, adult zebrafish are able to regenerate motor neurons and regain swimming ability within 6 weeks after a spinal cord injury. During this regenerative process, a range of developmental signals such as dopamine and serotonin are found to be re-deployed. This makes the research of embryonic signals become essential for the promotion of regeneration in the future. In my research, I am interested in identifying genes that are important for motor neuron development and motor axon differentiation. I also aimed to study the ability of zebrafish larvae to regenerate spinal motor neurons, and whether they can be used to study the essential developmental cues and the mechanisms underlying successful functional recovery. Motor axons grow out of the spinal cord in a motor neuron subtype specific manner and innervate different muscle groups to facilitate locomotor movements. To find genes and important pathways involved in motor neuron generation and axon development in zebrafish, we conducted an ENU-induced mutagenesis screen in islet-1:GFP transgenic zebrafish, in which a subset of dorsally projecting motor neurons are labelled. We have discovered 6 mutants displaying delayed or inhibited appearance of secondary motor neurons and/or motor axon deficits among 111 F2 families screened. Through subsequent mutant phenotypical analysis, I focused my study in two mutant lines manifesting a lack of islet-1:GFP motor neurons, and an absence of islet-1:GFP motor axons. I used various molecular markers to characterise the mutant phenotypes and observed several additional anatomical defects. I also initiated the study of causative mutation analysis based on the candidate gene list generated from Next Generation Sequencing (NGS). To gain an insight of the genes’ role in motor neuron development and axonal differentiation, I started functional analyses in order to confirm genes that are responsible for the observed motor neuron/axon phenotypes, and I have achieved some promising preliminary results. Motor neurons are generated from the motor neuron progenitor domain (pMN). This neurogenesis process sharply declines at 48 hours post-fertilisation (hpf), while pMN progenitor cells continue to proliferate to produce oligodendrocytes. By inflicting a mechanical lesion in the spinal cord of zebrafish larvae, we demonstrated that they are capable of regenerate new motor neurons and achieve full functional recovery within 48 hours following the injury, sharing similar mechanisms to that of the adult zebrafish. I further studied oligodendrocyte generation and found that pMN domain is able to switch from oligodendrogenesis to motor neuron generation after a spinal lesion. This demonstrates the high plasticity of the pMN domain. Interestingly, the generation of dorsal Pax2-positive interneurons was not altered after the lesion, suggesting that the regenerative potential differs in different progenitor domains. This study showed that the motor neuron regenerative process in zebrafish larvae is robust and they can be used for studying motor neuron regeneration. Taken together, the discovery of the genes from our screen will provide insights to the developmental cues that are involved in motor neuron generation and axon growth. Furthermore, spinal cord lesion in larval zebrafish larvae is established as a regenerative model that can be utilized to dissect the roles and mechanisms of these signals and pathways in the promotion of motor neuron regeneration.

616.8

Developmental Localization of Noradrenergic Innervation to the Rat Cerebellum Following Neonatal 6-Hydroxydopa and Morphine Treatment

Harston, Craig T., Blair Clark, M., Hardin, Judy C., Kostrzewa, Richard M.

01 January 1982

In order to demonstrate the influence of morphine on the developmental localization of regenerated noradrenergic fibers in rat cerebellum, a glyoxylic histofluorescent method and radiometric assay for norepinephrine (NE) were utilized. An initial reduction of NE in the cerebellum after 6-hydroxydopa [6-OHDOPA; 60 µg/g intraperitoneally (i.p.)] was followed by a return to control levels at 3 days, and an elevation above control levels at 7 days. The initial rates of recovery of NE in the cerebellum of the 6-OHDOPA group of rats and the group receiving morphine (20 µg/g i.p.) in combination with 6-OHDOPA were identical up to 7 days. However, by 14 days NE content was further elevated in the cerebellum of the morphine+6-OHDOPA group. Histofluorescent microscopic observations of the cerebellar cortex correlated with the biochemical findings. A reduction in cerebellar NE content at 3 days was associated with a reduction in the number of visible histofluorescent fibers in the cerebellar cortex. By 7 days the relative number of fibers in the 6-OHDOPA groups was similar to that seen in the control group, but by 9 days the relative number of fluorescent fibers in the cerebellar cortex was increased above control. By 13 days there was a further increase in the relative number of fluorescent fibers in the cerebellar cortex of the morphine+6-OHDOPA group, as compared to the group treated with 6-OHDOPA alone. These findings provide an anatomic correlate for recovery of noradrenergic fibers after 6-OHDOPA, and demonstrate an action of morphine in enhancing regenerative sprouting.

6-hydroxydopa

cerebellum

development regeneration

glyoxylic acid histochemistry

morphine

noradrenergic neurons

norepinephrine

Biomedical Sciences

Development of transgenic Ambystoma mexicanum (axolotl) to study cell fate during development and regeneration

Sobkow, Lidia

03 May 2006

The establishment of transgenesisi in axolotls is crucial for studying development and regeneration, as it would allow for long-term fate tracing as well as gene expression analysis, therefore we were interested in both obtaining animals expresing the transgene with little mosaicism in F0 generation and transgenesis. We demonstrate here that plasmid injection into one cell stage axolotl embryo generates transgenic animals that display germline transmission of a transgene. However, the efficiency of simple plasmid injection is very low, expression of the transgene is mosaic and seems to be promoter dependant. We have tested several methods of transgenesis developed in other systems. First we used Adeno-Associated Viral Terminal Repeats inserted into the injected construct to enhance the expression level of the transgene and reduce mosaicism. However, in the axolotl system we do not observe the enhancement of expression. Moreover, the expression appeared to be transient and disappeared after two months. Further, we tested the effect of the inclusion of ISceI meganuclease in the injections, succesful transgenesis method in the medaka system. It resulted in a higher percentage of F0 animals displaying strong , stable expression throughout the body. This represents the first demonstration in the axolotl of germline transmission of the transgene. Using this technique we have generated a germline transgenic anima expressing GFP ubiquitously in all tissue examined. We have used this anima to study cell fate in the dirsal fin during development. We have discovered a contribution of somite cells to dorsal fin mesenchyme in the axolotl, which was previously assumed to derive solely from neural crest. We have also studied the role of blood during tail regeneration by transplanting the ventral blood-forming region from GFP+ embryos into unlabeled host. During tail regeneration, we do not observe GFP+ cells contributing to muscle or nerve, suggesting that during tail regeneration blood stem cells do not undergo significant plasticity. We are interested in characterization of pluripotency of blastema cells. Previously, it has been shown that neural progenitor cells form the spinal cord can transdifferentiate to muscle and other tissue types in the regenerating tail. To test if blastema cells have the potency of differentiating into a neural tissue , we transplanted GFP+ 4day blastema into an injured spinal cord. Our result shows that blastema cells don't seem to contribute to the regenerating spinal cord.

info:eu-repo/classification/ddc/570

ddc:570

Axolotl, GFP, Regeneration, Transgene