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Zfp312 is required for subcortical axonal projections and dendritic morphology of deep-layer pyramidal neurons of the cerebral cortex - PubMed

️Sat Jan 01 2005

Zfp312 is required for subcortical axonal projections and dendritic morphology of deep-layer pyramidal neurons of the cerebral cortex

Jie-Guang Chen et al. Proc Natl Acad Sci U S A. 2005.

Abstract

Pyramidal neurons of the cerebral cortex display marked layer- and subtype-specific differences in their axonal projections and dendritic morphologies. Here we show that transcription factor Zfp312 is selectively expressed by layer V and VI subcortical projection pyramidal neurons and their progenitor cells. Knocking down Zfp312 with small interfering RNAs dramatically reduced the number of subcortical axonal projections from deep-layer pyramidal neurons and altered their dendritic morphology. In contrast, misexpression of Zfp312 in cortically projecting pyramidal neurons of layers II and III induced the expression of Tbr1, a transcription factor enriched in deep-layer neurons, and the formation of ectopic subcortical axonal projections. Thus, our results indicate that transcription factor Zfp312 plays a critical role in layer- and neuronal subtype-specific patterning of cortical axonal projections and dendritic morphologies.

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Figures

**Fig. 1.**
*Zfp312* expression in early VZ progenitors and deep-layer pyramidal neurons. (A) Quantitative real-time RT-PCR analysis of *Zfp312* expression. (B) Sagittal section of adult brain hybridized with *Zfp312* riboprobe. (C and D) Nissl staining and *Zfp312* ISH and immunohistochemistry in neocortex and CA1 hippocampus. (*Insets*) Nuclear localization of Zfp312 in neocortical layer V (C′) and hippocampal (D′) pyramidal neurons. (E) *Zfp312* ISH in whole-mount embryos and sagittal sections of embryonic neocortical wall and P7 neocortex. *Zfp312* is expressed by early ventricular zone (VZ) progenitors (E10.5 and E12.5). From E14.5, *Zfp312* is down-regulated by VZ progenitors, and *Zfp312*-expressing neurons are localized solely in the subplate (SP), deep-layer cortical plate (DL CP), and layers V and VI and absent in the upper-layer CP (UL CP) and layers II to IV. (Scale bar, 275 μm in C, 140 μm in D, and 200 μm in E.)

**Fig. 2.**
*Zfp312* is exclusively expressed by subcortically projecting neurons. (*Left*) Schematic depictions of stereotaxical injection sites of retrograde tracer BDA-3k and expected projection routes (red). (*Right*) Representative images of neurons in the adult primary motor neocortex retrogradely labeled with BDA-3k (red) and colabeled by *Zfp312* ISH (green). *Zfp312*⁺ neurons project to the striatum, thalamus, and brainstem (arrowheads). (Scale bar, 50 μm.)

**Fig. 3.**
*Zfp312* is required for subcortical projections and axonal fasciculation. (A and B) *Zfp312* siRNAs dramatically decreased the expression and nuclear localization of Zfp312-GFP in N2a cells. N2a cells were transfected with *Zfp312-GFP* in the presence of 10-fold excess of pCRLH (A) or pLVTH (B) expressing either scr siRNAs or *Zfp312* siRNAs. GFP from pLVTH was used as an internal control (B). pLVTH expressing either scr siRNA (C) or *Zfp312* siRNAs (D) was delivered by *in utero* electroporation to cortical VZ progenitors at E12.5 and analyzed at P14. GFP⁺ apical dendrites (blue arrowheads) and axons (red arrowheads) were present in the control cortex. In control brains, numerous GFP⁺ axons were present in the white matter (WM), striatum (st) internal capsule (IC), and thalamus (Th) and formed axonal fascicles (red arrowheads). GFP⁺ subcortical axons were dramatically reduced in brains expressing *Zfp312* siRNAs and do not form fasciculated bundles (open arrowheads). (Scale bar, 300 μm in C and D.)

**Fig. 4.**
*Zfp312* regulates pyramidal morphology, dendritic patterning, and spine number. (A and B) Neurolucida 3D reconstructions of layer V neurons in the primary motor cortex electroporated at E12.5 with pLVTH expressing either control (scr) siRNAs or *Zfp312* siRNAs and analyzed at P14. *Zfp312* siRNAs significantly reduced basal dendritic tree complexity (D; P = 0.001), spine number (arrowheads in A′ and B′, quantification in E; P < 0.001), and soma size (F; P < 0.001) and affected the vertical orientation of apical dendrites (C; P = 0.027).

**Fig. 5.**
*Zfp312* siRNAs do not alter the generation, migration, or development of upper-layer pyramidal neurons in the primary somatosensory cortex electroporated at E12.5 with pLVTH. (A) Quantification of laminar distribution of GFP⁺ neurons at P14 showing no differences between neurons expressing scr siRNA and *Zfp312* siRNA (P > 0.05 for each bin). Error bars indicate SD. (B) *Zfp312* siRNAs alter morphology of layer V (arrows) but not layer III pyramidal neurons (arrowhead) at P14. (C) *Zfp312* siRNAs do not affect the expression of upper-layer marker Pou3f3 (red) at P0 (arrowheads). (Scale bar, 200 μm in B and 400 μm in C.)

**Fig. 6.**
*Zfp312* misexpression in layer II/III callosal neurons induces Tbr1 and ectopic subcortical axonal projections. Neocortical VZ progenitors were electroporation *in utero* at E17 with pCLEG or pCLEG-*Zfp312* and analyzed by GFP immunohistochemistry at P14. (A) Control GFP⁺ neurons in the uppermost layer (green arrowheads) send axons through the white matter and corpus callosum (blue arrowheads). *Zfp312*-misexpressing but not control GFP⁺ neurons have ectopic subcortical axons (A and B; red arrows) and are retrogradely labeled by BDA-3k injected into the pons (C and D; arrowheads). (E and F)A small number of neurons electroporated with control pCLEG expressed Tbr1 (E), whereas the vast majority of neurons misexpressing *Zfp312* coexpressed Tbr1 (F) (arrowheads). (Scale bar, 500 μm in A and B,50 μm in C and D, and 90 μm in E and F.)

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Zfp312 is required for subcortical axonal projections and dendritic morphology of deep-layer pyramidal neurons of the cerebral cortex - PubMed