Yunzi Gou scite author profile

Formation of neural and sensory progenitors in the inner ear requires Sox2 in mammals, and in other species is thought to rely on both Sox2 and Sox3. How Sox2 and/or Sox3 promote different fates is poorly understood. Our mutant analysis in zebrafish showed that sox2 is uniquely required for sensory development while sox3 is uniquely required for neurogenesis. Moderate misexpression of sox2 during placodal stages led to development of otic vesicles with expanded sensory and reduced neurogenic domains. However, high-level misexpression of sox2 or sox3 expanded both sensory and neurogenic domains to fill the medial and lateral halves of the otic vesicle, respectively. Disruption of medial factor pax2a eliminated the ability of sox2/3 misexpression to expand sensory but not neurogenic domains. Additionally, mild misexpression of fgf8 during placodal development was sufficient to specifically expand the zone of prosensory competence. Later, cross-repression between atoh1a and neurog1 helps maintain the sensory-neural boundary, but unlike mouse this does not require Notch activity. Together, these data show that sox2 and sox3 exhibit intrinsic differences in promoting sensory vs. neural competence, but at high levels these factors can mimic each other to enhance both states. Regional cofactors like pax2a and fgf8 also modify sox2/3 functions.

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sox2 and sox3 cooperate to regulate otic/epibranchial placode induction in zebrafish

Gou

Guo

Maulding

et al. 2018

Developmental Biology

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Expression of sox3 is one of the earliest markers of Fgf-dependent otic/epibranchial placode induction. We report here that sox2 is also expressed in the early otic/epibranchial placode in zebrafish. To address functions of sox2 and sox3, we generated knockouts and heat shock-inducible transgenes. Mutant analysis, and low-level misexpression, showed that sox2 and sox3 act redundantly to establish a full complement of otic/epibranchial cells. Disruption of pax8, another early regulator, caused similar placodal deficiencies to sox3 mutants or pax8-sox3 double mutants, suggesting that sox3 and pax8 operate in the same pathway. High-level misexpression of sox2 or sox3 during early stages cell-autonomously blocked placode induction, whereas misexpression several hours later could not reverse placodal differentiation. In an assay for ectopic placode-induction, we previously showed that misexpression of fgf8 induces a high level of ectopic sox3, but not pax8. Partial knockdown of sox3 significantly enhanced ectopic induction of pax8, whereas full knockdown of sox3 inhibited this process. Together these findings show that sox2 and sox3 are together required for proper otic induction, but the level of expression must be tightly regulated to avoid suppression of differentiation and maintenance of pluripotency.

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The Warburg Effect and lactate signaling augment Fgf-MAPK to promote sensory-neural development in the otic vesicle

Kantarci

Gou

Riley

2020

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Recent studies indicate that many developing tissues modify glycolysis to favor lactate synthesis (Agathocleous et al., 2012; Bulusu et al., 2017; Gu et al., 2016; Oginuma et al., 2017; Sá et al., 2017; Wang et al., 2014; Zheng et al., 2016), but how this promotes development is unclear. Using forward and reverse genetics in zebrafish, we show that disrupting the glycolytic gene phosphoglycerate kinase-1 (pgk1) impairs Fgf-dependent development of hair cells and neurons in the otic vesicle and other neurons in the CNS/PNS. Fgf-MAPK signaling underperforms in pgk1- / - mutants even when Fgf is transiently overexpressed. Wild-type embryos treated with drugs that block synthesis or secretion of lactate mimic the pgk1- / - phenotype, whereas pgk1- / - mutants are rescued by treatment with exogenous lactate. Lactate treatment of wild-type embryos elevates expression of Etv5b/Erm even when Fgf signaling is blocked. However, lactate’s ability to stimulate neurogenesis is reversed by blocking MAPK. Thus, lactate raises basal levels of MAPK and Etv5b (a critical effector of the Fgf pathway), rendering cells more responsive to dynamic changes in Fgf signaling required by many developing tissues.

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The Cure VCP Scientific Conference 2021: Molecular and clinical insights into neurodegeneration and myopathy linked to multisystem proteinopathy-1 (MSP-1)

Johnson

Klickstein

Khanna

et al. 2022

Neurobiology of Disease

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Sox2 and Sox3 are essential for development and regeneration of the zebrafish lateral line

Undurraga¹,

Gou

Sandoval³

et al. 2019

Preprint

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53The recovery of injured or lost sensory neurons after trauma, disease or aging is a major 54 scientific challenge. Upon hearing loss or balance disorder, regeneration of mechanosensory 55 hair cells has been observed in fish, some amphibians and under special circumstances in 56 birds, but is absent in adult mammals. In aquatic vertebrates, hair cells are not only present in 57 the inner ear but also in neuromasts of the lateral line system. The zebrafish lateral line 58 neuromast has an almost unlimited capacity to regenerate hair cells. This remarkable ability 59is possible due to the presence of neural stem/progenitor cells within neuromasts. In order to 60 further characterize these stem cells, we use the expression of the neural progenitor markers 61Sox2 and Sox3, transgenic reporter lines, and morphological and topological analysis of the 62 different cell types within the neuromast. We reveal new sub-populations of supporting cells, 63 the sustentacular supporting cells and the neuromast stem cells. In addition, using loss-of-64 function and mutants of sox2 and sox3, we find that the combined activity of both genes is 65 essential for lateral line development and regeneration. The capability of sox2/sox3 expressing 66 stem cells to produce new hair cells, hair cell-precursors, and supporting cells after damage 67 was analyzed in detail by time-lapse microscopy and immunofluorescence. We are able to 68 provide evidence that sox2/3 expressing cells are the main contributors to the regenerated 69 neuromast, and that their daughter cells are able to differentiate into most cell types of the 70 neuromast.

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Yunzi Gou

sox2 and sox3 Play unique roles in development of hair cells and neurons in the zebrafish inner ear

sox2 and sox3 cooperate to regulate otic/epibranchial placode induction in zebrafish

The Warburg Effect and lactate signaling augment Fgf-MAPK to promote sensory-neural development in the otic vesicle

The Cure VCP Scientific Conference 2021: Molecular and clinical insights into neurodegeneration and myopathy linked to multisystem proteinopathy-1 (MSP-1)

Sox2 and Sox3 are essential for development and regeneration of the zebrafish lateral line

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