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Abstract

The intricate formation of the palate involves a series of complex events, yet its mechanistic basis remains uncertain. To explore major cell populations in the palate and their roles during development, we constructed a spatiotemporal transcription landscape of palatal cells. Palate samples from C57BL/6 J mice at embryonic days 12.5 (E12.5), 14.5 (E14.5), and 16.5 (E16.5) underwent single-cell RNA sequencing (scRNA-seq) to identify distinct cell subsets. In addition, spatial enhanced resolution omics-sequencing (stereo-seq) was used to characterize the spatial distribution of these subsets. Integrating scRNA-seq and stereo-seq with CellTrek annotated mesenchymal and epithelial cellular components of the palate during development. Furthermore, cellular communication networks between these cell subpopulations were analyzed to discover intercellular signaling during palate development. From the analysis of the middle palate, both mesenchymal and epithelial populations were spatially segregated into 3 domains. The middle palate mesenchymal subpopulations were associated with tooth formation, ossification, and tissue remodeling, with initial state cell populations located proximal to the dental lamina. The nasal epithelium of the palatal shelf exhibited richer humoral immune responses than the oral side. Specific enrichment of Tgfβ3 and Pthlh signals in the midline epithelial seam at E14.5 suggested a role in epithelial–mesenchymal transition. In summary, this study provides high-resolution transcriptomic information, contributing to a deeper mechanistic understanding of palate biology and pathophysiology.

Keywords

palate prenatal development cleft palate single-cell transcriptome analysis spatial transcriptome analysis transcriptome profiles

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References

Barrio

Del Río

Murillo

Maldonado

López-Gordillo

Paradas-Lara

Hernandes

Catón

Martínez-Álvarez

. 2014. Epidermal growth factor impairs palatal shelf adhesion and fusion in the Tgf-β₃ null mutant. Cells Tissues Organs. 199(2–3):201–211.

Brown

Knott

Halligan

Yarram

Mansell

Sandy

. 2003. Microarray analysis of murine palatogenesis: temporal expression of genes during normal palate development. Dev Growth Differ. 45(2):153–165.

Buechler

Pradhan

Krishnamurty

Cox

Calviello

Wang

Yang

Tam

Caothien

Roose-Girma

, et al. 2021. Cross-tissue organization of the fibroblast lineage. Nature. 593(7860):575–579.

Cai

Liu

Zhang

Zhu

Dong

Xue

. 2018. Down-regulation of FN1 inhibits colorectal carcinogenesis by suppressing proliferation, migration, and invasion. J Cell Biochem. 119(6):4717–4728.

Cesario

Landin Malt

Deacon

Sandberg

Vogt

Tang

Zhao

Brown

Rubenstein

Jeong

. 2015. Lhx6 and lhx8 promote palate development through negative regulation of a cell cycle inhibitor gene, p57kip2. Hum Mol Genet. 24(17):5024–5039.

Chen

Liao

Cheng

Lai

Qiu

Yang

Hao

, et al. 2022. Spatiotemporal transcriptomic atlas of mouse organogenesis using DNA nanoball-patterned arrays. Cell. 185(10):1777–1792.e1721.

Cordero

Brugmann

Chu

Bajpai

Jame

Helms

. 2011. Cranial neural crest cells on the move: their roles in craniofacial development. Am J Med Genet A. 155(2):270–279.

Cuervo

Covarrubias

. 2004. Death is the major fate of medial edge epithelial cells and the cause of basal lamina degradation during palatogenesis. Development. 131(1):15–24.

Han

Feng

Guo

Loh

Yuan

Cho

Jing

Janeckova

, et al. 2021. Runx2-twist1 interaction coordinates cranial neural crest guidance of soft palate myogenesis. eLife. 10:e62387.

10.

Xue

Liu

Xie

Bai

. 2018. Parathyroid hormone-like hormone induces epithelial-to-mesenchymal transition of intestinal epithelial cells by activating the runt-related transcription factor 2. Am J Pathol. 188(6):1374–1388.

11.

Liu

Ozturk

Gurumurthy

Romano

Sinha

Nawshad

. 2015. TGFβ3 regulates periderm removal through δNp63 in the developing palate. J Cell Physiol. 230(6):1212–1225.

12.

Jin

Ding

. 2006. Analysis of Meox-2 mutant mice reveals a novel postfusion-based cleft palate. Dev Dyn. 235(2):539–546.

13.

Karsenty

. 2008. Transcriptional control of skeletogenesis. Annu Rev Genomics Hum Genet. 9:183–196.

14.

Jones

Hooper

Williams

. 2019. The molecular anatomy of mammalian upper lip and primary palate fusion at single cell resolution. Development. 146(12):dev174888.

15.

Maarse

Bergé

Pistorius

van Barneveld

Kon

Breugem

Mink van der Molen

. 2010. Diagnostic accuracy of transabdominal ultrasound in detecting prenatal cleft lip and palate: a systematic review. Ultrasound Obstet Gynecol. 35(4):495–502.

16.

Mossey

Little

Munger

Dixon

Shaw

. 2009. Cleft lip and palate. Lancet. 374(9703):1773–1785.

17.

Ohbayashi

Shibayama

Kurotaki

Imanishi

Fujimori

Itoh

Takada

. 2002. FGF18 is required for normal cell proliferation and differentiation during osteogenesis and chondrogenesis. Genes Dev. 16(7):870–879.

18.

Ozekin

O’Rourke

Bates

. 2023. Single cell sequencing of the mouse anterior palate reveals mesenchymal heterogeneity. Dev Dyn. 252(6):713–727.

19.

Pitarresi

Norgard

Chiarella

Suzuki

Bakir

Sahu

Zhao

Marchand

Wengyn

, et al. 2021. PTHrP drives pancreatic cancer growth and metastasis and reveals a new therapeutic vulnerability. Cancer Discov. 11(7):1774–1791.

20.

Potter

. 2015. Molecular anatomy of palate development. PLoS One. 10(7):e0132662.

21.

Richardson

Mitchell

Hammond

Mollo

Kouwenhoven

Wyatt

Donaldson

Zeef

Burgis

Blance

, et al. 2017. P63 exerts spatio-temporal control of palatal epithelial cell fate to prevent cleft palate. PLoS Genet. 13(6):e1006828.

22.

Simões-Costa

Bronner

. 2013. Insights into neural crest development and evolution from genomic analysis. Genome Res. 23(7):1069–1080.

23.

Wang

Yang

Zhang

Huang

Chen

. 2019. Shox2 regulates osteogenic differentiation and pattern formation during hard palate development in mice. J Biol Chem. 294(48):18294–18305.

24.

Yang

Wang

Zhou

Liang

Chen

Zhang

Han

, et al. 2020. Fibronectin 1 activates WNT/β-catenin signaling to induce osteogenic differentiation via integrin β1 interaction. Lab Invest. 100(12):1494–1502.

25.

Zhu

Song

Zhong

Huo

Fang

Zhao

Yang

Dai

Qiu

, et al. 2022. Essential role of msx1 in regulating anterior-posterior patterning of the secondary palate in mice. J Genet Genomics. 49(1):63–73.

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Spatiotemporal Evolution of Developing Palate in Mice

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