Preterm birth disrupts cerebellar development by affecting granule cell proliferation program and Bergmann glia

Preterm birth disrupts cerebellar development by affecting granule cell proliferation program and Bergmann glia

Preterm birth is a leading cause of long-term motor and cognitive deficits. Clinical studies suggest that some of these deficits result from disruption of cerebellar development, but the mechanisms that mediate cerebellar abnormalities in preterm infants are largely unknown. Furthermore, it remains...

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Published in:Experimental neurology Vol. 306; pp. 209 - 221
Main Authors: Iskusnykh, Igor Y., Buddington, Randal K., Chizhikov, Victor V.
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-08-2018
Subjects:
Animals
Apoptosis
Atoh1
Cell Count
Cell Proliferation
Cerebellum
Cerebellum - growth & development
Cerebellum - pathology
Cyclins - biosynthesis
Cytoplasmic Granules - pathology
Development
Female
Gene Expression Regulation, Developmental
Granule cell precursors
Interneurons - pathology
Jag1
Jagged-1 Protein - biosynthesis
Jagged-1 Protein - genetics
Neuroglia - pathology
Pregnancy
Premature Birth - pathology
Preterm birth
Proliferation
Purkinje Cells - pathology
Swine
Cerebellum
PCs
Jag1
Preterm birth
CDKIs
C-sect. term
BG
Proliferation
EGL
pH 3
Atoh1
IGL
Granule cell precursors
Nat. born term
LCM
Development
ML
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Summary:Preterm birth is a leading cause of long-term motor and cognitive deficits. Clinical studies suggest that some of these deficits result from disruption of cerebellar development, but the mechanisms that mediate cerebellar abnormalities in preterm infants are largely unknown. Furthermore, it remains unclear whether preterm birth and precocious exposure to the ex-utero environment directly disrupt cerebellar development or indirectly by increasing the probability of cerebellar injury, including that resulting from clinical interventions and protocols associated with the care of preterm infants. In this study, we analyzed the cerebellum of preterm pigs delivered via c-section at 91% term and raised for 10 days, until term-equivalent age. The pigs did not receive any treatments known or suspected to affect cerebellar development and had no evidence of brain damage. Term pigs sacrificed at birth were used as controls. Immunohistochemical analysis revealed that preterm birth did not affect either size or numbers of Purkinje cells or molecular layer interneurons at term-equivalent age. The number of granule cell precursors and Bergmann glial fibers, however, were reduced in preterm pigs. Preterm pigs had reduced proliferation but not differentiation of granule cells. qRT-PCR analysis of laser capture microdissected external granule cell layer showed that preterm pigs had a reduced expression of Ccnd1 (Cyclin D1), Ccnb1 (Cyclin B1), granule cell master regulatory transcription factor Atoh1, and signaling molecule Jag1. In vitro rescue experiments identified Jag1 as a central granule cell gene affected by preterm birth. Thus, preterm birth and precocious exposure to the ex-utero environment disrupt cerebellum by modulating expression of key cerebellar developmental genes, predominantly affecting development of granule precursors and Bergmann glia. •Preterm birth reduces the number of cerebellar granule cells and Bergmann glia.•Preterm birth disrupts proliferation but not differentiation of granule precursors.•In the EGL, preterm birth reduces expression of Cyclins D1/B1, Atoh1 and Jag1.•Jag1 is a central granule cell signaling molecule affected by preterm birth.
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Present address: College of Nursing, University of Tennessee Health Science Center, Memphis, TN 38163, USA
ISSN:0014-4886
1090-2430
1090-2430
DOI:10.1016/j.expneurol.2018.05.015