Hippocampal Asymmetry of Regional Development and Structural Covariance in Preterm Neonates

Premature birth is associated with high prevalence of neurodevelopmental impairments in surviving infants. The hippocampus is known to be critical for learning and memory, the putative role of hippocampus dysfunction remains poorly understood in preterm neonates. Particularly, hemispherical asymmetry of the hippocampus has been well-noted, either structurally or functionally. How the preterm birth impairs the hippocampal development, and to what extent the hippocampus was impaired by preterm birth asymmetrical has not been well studied. In this study, we compared regional and local hippocampal development in term born neonates (n=361) and prematurely born infants at term-born equivalent age on MRI studies (n = 53) using T2 MRI images collected from the Developing Human Connectome Project (dHCP); We compared 1) volumetric growth; 2) shape development in the hippocampal hemispheres using Laplace–Beltrami eigen-projection and boundary deformation between the two groups; and 3) structural covariance between hippocampal vertices and the cortical thickness in cerebral cortex regions. We demonstrated that premature infants have smaller volume for the right hippocampi, while no difference was observed for the left hippocampi. Lower thickness was observed in the hippocampal head in both hemispheres for preterm neonates compared to full-term peers, while an accelerated hippocampal thickness growth rate was found in left hippocampus only. Structural covariance analysis demonstrated that in premature infants, the structural covariance between hippocampi and limbic lobe were severely impaired compared to healthy term neonates only in left hemisphere. These data suggest that the development of the hippocampus during the third trimester may be altered following early extrauterine exposure, with high degree of asymmetry. These findings suggested that the hippocampus shows high degree of vulnerability, particularly asymmetrical vulnerability or plasticity, in preterm neonates at the term-born equivalent age compared to full-term healthy controls.

CRL5-dependent regulation of the small GTPases ARL4C and ARF6 controls hippocampal morphogenesis

The small GTPase ARL4C participates in the regulation of cell migration, cytoskeletal rearrangements, and vesicular trafficking in epithelial cells. The ARL4C signaling cascade starts by the recruitment of the ARF–GEF cytohesins to the plasma membrane, which, in turn, bind and activate the small GTPase ARF6. However, the role of ARL4C–cytohesin–ARF6 signaling during hippocampal development remains elusive. Here, we report that the E3 ubiquitin ligase Cullin 5/RBX2 (CRL5) controls the stability of ARL4C and its signaling effectors to regulate hippocampal morphogenesis. Both RBX2 knockout and Cullin 5 knockdown cause hippocampal pyramidal neuron mislocalization and development of multiple apical dendrites. We used quantitative mass spectrometry to show that ARL4C, Cytohesin-1/3, and ARF6 accumulate in the RBX2 mutant telencephalon. Furthermore, we show that depletion of ARL4C rescues the phenotypes caused by Cullin 5 knockdown, whereas depletion of CYTH1 or ARF6 exacerbates overmigration. Finally, we show that ARL4C, CYTH1, and ARF6 are necessary for the dendritic outgrowth of pyramidal neurons to the superficial strata of the hippocampus. Overall, we identified CRL5 as a key regulator of hippocampal development and uncovered ARL4C, CYTH1, and ARF6 as CRL5-regulated signaling effectors that control pyramidal neuron migration and dendritogenesis.

An evolutionarily conserved Lhx2-Ldb1 interaction regulates the acquisition of hippocampal cell fate and regional identity

Protein cofactor Ldb1 regulates cell fate specification by interacting with LIM-homeodomain (LIM-HD) proteins in a tetrameric complex consisting of an LDB:LDB dimer that bridges two LIM-HD molecules, a mechanism first demonstrated in the Drosophila wing disc. Here, we demonstrate conservation of this interaction in the regulation of mammalian hippocampal development, which is profoundly defective upon loss of either Lhx2 or Ldb1. Electroporation of a chimeric construct that encodes the Lhx2-HD and Ldb1-DD (dimerization domain) in a single transcript cell-autonomously rescues a comprehensive range of hippocampal deficits in the mouse Ldb1 mutant, including the acquisition of field-specific molecular identity and the regulation of the neuron-glia cell fate switch. This demonstrates that the LHX:LDB complex is an evolutionarily conserved molecular regulatory device that controls complex aspects of regional cell identity in the developing brain.Summary statementSimilar to an Apterous-Chip mechanism that patterns the Drosophila wing blade, interaction between mammalian orthologs Lhx2 and Ldb1 regulates multiple aspects of hippocampal development in the mouse.

The C terminus of p73 is essential for hippocampal development

The p53 family member p73 has a complex gene structure, including alternative promoters and alternative splicing of the 3′ UTR. This results in a complex range of isoforms whose biological relevance largely remains to be determined. By deleting exon 13 (which encodes a sterile α motif) from the Trp73 gene, we selectively engineered mice to replace the most abundantly expressed C-terminal isoform, p73α, with a shorter product of alternative splicing, p73β. These mice (Trp73Δ13/Δ13) display severe neurodevelopmental defects with significant functional and morphological abnormalities. Replacement of p73α with p73β results in the depletion of Cajal–Retzius (CR) cells in embryonic stages, thus depriving the developing hippocampus of the pool of neurons necessary for correct hippocampal architecture. Consequently,Trp73Δ13/Δ13mice display severe hippocampal dysgenesis, reduced synaptic functionality and impaired learning and memory capabilities. Our data shed light on the relevance of p73 alternative splicing and show that the full-length C terminus of p73 is essential for hippocampal development.