Guided genetic screen to identify genes essential in the regeneration of hair cells and other tissues

Wuhong Pei,Shuo Lin,Shawn M Burgess,Haigen Huang,Kade Pettie,Jason W Sinclair,Blake Carrington,Marypat Jones,Sunny C Huang,Erin Jimenez,Jennifer Idol,Alberto Rissone,Lisha Xu,Raman Sood,Kevin Bishop,Gaurav K Varshney,Claire Slevin

doi:10.1038/s41536-018-0050-7

Abstract

Regenerative medicine holds great promise for both degenerative diseases and traumatic tissue injury which represent significant challenges to the health care system. Hearing loss, which affects hundreds of millions of people worldwide, is caused primarily by a permanent loss of the mechanosensory receptors of the inner ear known as hair cells. This failure to regenerate hair cells after loss is limited to mammals, while all other non-mammalian vertebrates tested were able to completely regenerate these mechanosensory receptors after injury. To understand the mechanism of hair cell regeneration and its association with regeneration of other tissues, we performed a guided mutagenesis screen using zebrafish lateral line hair cells as a screening platform to identify genes that are essential for hair cell regeneration, and further investigated how genes essential for hair cell regeneration were involved in the regeneration of other tissues. We created genetic mutations either by retroviral insertion or CRISPR/Cas9 approaches, and developed a high-throughput screening pipeline for analyzing hair cell development and regeneration. We screened 254 gene mutations and identified 7 genes specifically affecting hair cell regeneration. These hair cell regeneration genes fell into distinct and somewhat surprising functional categories. By examining the regeneration of caudal fin and liver, we found these hair cell regeneration genes often also affected other types of tissue regeneration. Therefore, our results demonstrate guided screening is an effective approach to discover regeneration candidates, and hair cell regeneration is associated with other tissue regeneration.

Highlights

Regenerative medicine offers promising potential to restore tissues and even whole-organs damaged by injury or disease conditions that afflict the daily life for millions of people worldwide.[1,2] Developing effective regenerative medicine fundamentally relies on an advanced understanding of the biological processes that drive tissue repair and replacement
We performed a genetic screen of 254 gene mutations in zebrafish to systemically identify genes that are essential for hair cell re-screened to confirm the genotype–phenotype linkage, typically by analyzing mutations produced from a different pair of parents and by analyzing additional alleles
We further examined the effect of inhibiting these hair cell regeneration genes on the development and regeneration of the liver, using a liver-specific labeling and ablation transgene system Tg(fabp10:CFP-NTR) as a readout.[43]

Summary

Introduction

Regenerative medicine offers promising potential to restore tissues and even whole-organs damaged by injury or disease conditions that afflict the daily life for millions of people worldwide.[1,2] Developing effective regenerative medicine fundamentally relies on an advanced understanding of the biological processes that drive tissue repair and replacement. Numerous genes and pathways are involved in tissue regeneration,[5,6] there are great gaps in our understanding of which genetic factors are essential for the regeneration of a specific tissue. Regenerative medicine holds a promise to improve the quality of life for millions of people suffering from hearing loss.[7,8] Hearing loss is the most common congenital sensory impairment in newborns and the most common sensory deficit in the elderly. Hearing loss in humans is permanent once it occurs, since humans have very limited potential to regenerate hair cells.[10]

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Conclusion