Browsing by Author "Lee, Yoonsung"
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Item Open Access Ras controls melanocyte expansion during zebrafish fin stripe regeneration.(Dis Model Mech, 2010-07) Lee, Yoonsung; Nachtrab, Gregory; Klinsawat, Pai W; Hami, Danyal; Poss, Kenneth DRegenerative medicine for complex tissues like limbs will require the provision or activation of precursors for different cell types, in the correct number, and with the appropriate instructions. These strategies can be guided by what is learned from spectacular events of natural limb or fin regeneration in urodele amphibians and teleost fish. Following zebrafish fin amputation, melanocyte stripes faithfully regenerate in tandem with complex fin structures. Distinct populations of melanocyte precursors emerge and differentiate to pigment regenerating fins, yet the regulation of their proliferation and patterning is incompletely understood. Here, we found that transgenic increases in active Ras dose-dependently hyperpigmented regenerating zebrafish fins. Lineage tracing and marker analysis indicated that increases in active Ras stimulated the in situ amplification of undifferentiated melanocyte precursors expressing mitfa and kita. Active Ras also hyperpigmented early fin regenerates of kita mutants, which are normally devoid of primary regeneration melanocytes, suppressing defects in precursor function and survival. By contrast, this protocol had no noticeable impact on pigmentation by secondary regulatory melanocyte precursors in late-stage kita regenerates. Our results provide evidence that Ras activity levels control the repopulation and expansion of adult melanocyte precursors after tissue loss, enabling the recovery of patterned melanocyte stripes during zebrafish appendage regeneration.Item Open Access Regulation of Progenitor Cell Proliferation During Zebrafish Fin Regeneration(2009) Lee, YoonsungVertebrates like urodele and teleost have an enhanced capacity for regeneration, when compared to mammals. Recently, the teleost zebrafish (Danio rerio) has become a popular model for studying regenerative events, due to the ability to regenerate multiple organs such as the fin and the heart, and the diverse genetic approaches available for functional studies. In my thesis studies, I have used the zebrafish caudal fin as a model system to understand molecular and cellular mechanism of appendage regeneration.
Pharmacological and genetic studies have revealed that Fgf signaling is important for appendage regeneration. To dissect the mechanism of Fgfs during zebrafish fin regeneration, lab colleagues and I have generated and utilized transgenic animals in which Fgf signaling can be experimentally increased or decreased. Through these transgenic studies, I found that position-dependent Fgf signaling directs regenerative growth and blastemal proliferation. Proximally-amputated fin regenerates grow at higher rates than the distally-amputated, owing to position-dependent amounts of Fgf activity. Further studies using new transgenics have provided an understanding of mechanisms by which Fgfs influence epidermal regulation of the blastema. Loss- and gain-of-function studies of Fgfs reveal that Fgf signaling both positively and negatively regulated shh expression in the epidermis to maintain blastemal function.
During the fin regeneration process, pigmentation pattern is re-established as along with bone structures and connective tissues. While the lineage of the blastema is not precisely clear, pigment cells in the fin regenerates are thought to be derived from melanocyte stem cells. Therefore, melanocyte regeneration is an informative system to understand the mechanism underlying regulation of adult stem cells during regeneration. As part of my thesis studies, we generated transgenic animals in which ectopic Ras expression can be experimentally induced. Transgenic studies, combined with pharmacological approaches, have revealed that Ras controls self-renewal of melanocyte stem cells during fin pigment regeneration.