Nfia Is Critical for AII Amacrine Cell Production: Selective Bipolar Cell Dependencies and Diminished ERG

The nuclear factor one (NFI) transcription factor genes Nfia, Nfib, and Nfix are all enriched in late-stage retinal progenitor cells, and their loss has been shown to retain these progenitors at the expense of later-generated retinal cell types. Whether they play any role in the specification of those later-generated fates is unknown, but the expression of one of these, Nfia, in a specific amacrine cell type may intimate such a role. Here, Nfia conditional knockout (Nfia-CKO) mice (both sexes) were assessed, finding a massive and largely selective absence of AII amacrine cells. There was, however, a partial reduction in type 2 cone bipolar cells (CBCs), being richly interconnected to AII cells. Counts of dying cells showed a significant increase in Nfia-CKO retinas at postnatal day (P)7, after AII cell numbers were already reduced but in advance of the loss of type 2 CBCs detected by P10. Those results suggest a role for Nfia in the specification of the AII amacrine cell fate and a dependency of the type 2 CBCs on them. Delaying the conditional loss of Nfia to the first postnatal week did not alter AII cell number nor differentiation, further suggesting that its role in AII cells is solely associated with their production. The physiological consequences of their loss were assessed using the ERG, finding the oscillatory potentials to be profoundly diminished. A slight reduction in the b-wave was also detected, attributed to an altered distribution of the terminals of rod bipolar cells, implicating a role of the AII amacrine cells in constraining their stratification. SIGNIFICANCE STATEMENT The transcription factor NFIA is shown to play a critical role in the specification of a single type of retinal amacrine cell, the AII cell. Using an Nfia–conditional knockout mouse to eliminate this population of retinal neurons, we demonstrate two selective bipolar cell dependencies on the AII cells; the terminals of rod bipolar cells become mis-stratified in the inner plexiform layer, and one type of cone bipolar cell undergoes enhanced cell death. The physiological consequence of this loss of the AII cells was also assessed, finding the cells to be a major contributor to the oscillatory potentials in the electroretinogram.

[1]  B. Reese,et al.  Quantitative trait loci on chromosomes 9 and 19 modulate AII amacrine cell number in the mouse retina , 2023, Frontiers in Neuroscience.

[2]  J. L. Madrigal,et al.  Models of microglia depletion and replenishment elicit protective effects to alleviate vascular and neuronal damage in the diabetic murine retina , 2022, Journal of neuroinflammation.

[3]  R. Wong,et al.  Hierarchical partner selection shapes rod-cone pathway specificity in the inner retina , 2022, iScience.

[4]  B. Reese,et al.  Cell numbers, cell ratios, and developmental plasticity in the rod pathway of the mouse retina , 2022, Journal of anatomy.

[5]  J. Sanes,et al.  Mouse Retinal Cell Atlas: Molecular Identification of over Sixty Amacrine Cell Types , 2020, The Journal of Neuroscience.

[6]  R. Wong,et al.  Distinct Developmental Mechanisms Act Independently to Shape Biased Synaptic Divergence from an Inhibitory Neuron , 2020, Current Biology.

[7]  F. Rieke,et al.  LRRTM4: A Novel Regulator of Presynaptic Inhibition and Ribbon Synapse Arrangements of Retinal Bipolar Cells , 2020, Neuron.

[8]  L. Richards,et al.  Variants in nuclear factor I genes influence growth and development , 2019, American journal of medical genetics. Part C, Seminars in medical genetics.

[9]  Stephen J. Eglen,et al.  From random to regular: Variation in the patterning of retinal mosaics* , 2019, The Journal of comparative neurology.

[10]  Karin Dedek,et al.  Rod Bipolar Cells Require Horizontal Cells for Invagination Into the Terminals of Rod Photoreceptors , 2019, Front. Cell. Neurosci..

[11]  Brian S. Clark,et al.  Single-Cell RNA-Seq Analysis of Retinal Development Identifies NFI Factors as Regulating Mitotic Exit and Late-Born Cell Specification , 2019, Neuron.

[12]  Xianjun Zhu,et al.  Tmem30a deficiency leads to retinal rod bipolar cell degeneration , 2019, Journal of neurochemistry.

[13]  Kevin L. Briggman,et al.  Synaptic Transfer between Rod and Cone Pathways Mediated by AII Amacrine Cells in the Mouse Retina , 2018, Current Biology.

[14]  Bret A. Moore,et al.  A Population Study of Common Ocular Abnormalities in C57BL/6N rd8 Mice , 2018, Investigative ophthalmology & visual science.

[15]  B. Reese,et al.  DNER and NFIA are expressed by developing and mature AII amacrine cells in the mouse retina , 2018, The Journal of comparative neurology.

[16]  Naoko Omi,et al.  Classification of Mouse Retinal Bipolar Cells: Type-Specific Connectivity with Special Reference to Rod-Driven AII Amacrine Pathways , 2017, Front. Neuroanat..

[17]  Z. Yin,et al.  Contribution of GABAa, GABAc and glycine receptors to rat dark-adapted oscillatory potentials in the time and frequency domain , 2017, Oncotarget.

[18]  N. Brecha,et al.  Prox1 Is a Marker for AII Amacrine Cells in the Mouse Retina , 2017, Front. Neuroanat..

[19]  C. McCall,et al.  Myeloid Cell-Specific Knockout of NFI-A Improves Sepsis Survival , 2017, Infection and Immunity.

[20]  Evan Z. Macosko,et al.  Comprehensive Classification of Retinal Bipolar Neurons by Single-Cell Transcriptomics , 2016, Cell.

[21]  Jun Zhu,et al.  Tfap2a and 2b act downstream of Ptf1a to promote amacrine cell differentiation during retinogenesis , 2015, Molecular Brain.

[22]  Evan Z. Macosko,et al.  Highly Parallel Genome-wide Expression Profiling of Individual Cells Using Nanoliter Droplets , 2015, Cell.

[23]  E. L. West,et al.  Müller Glia Activation in Response to Inherited Retinal Degeneration Is Highly Varied and Disease-Specific , 2015, PloS one.

[24]  M. Feller,et al.  Elucidating the Role of AII Amacrine Cells in Glutamatergic Retinal Waves , 2015, The Journal of Neuroscience.

[25]  J. S. Lauritzen,et al.  The AII amacrine cell connectome: a dense network hub , 2014, Front. Neural Circuits.

[26]  L. Gan,et al.  Development of Retinal Amacrine Cells and Their Dendritic Stratification , 2014, Current Ophthalmology Reports.

[27]  C. Somps,et al.  GlyT1 inhibitor reduces oscillatory potentials of the electroretinogram in rats , 2014, Cutaneous and ocular toxicology.

[28]  Robert W. Williams,et al.  Independent genomic control of neuronal number across retinal cell types. , 2014, Developmental cell.

[29]  R. Weiler,et al.  AII amacrine cells discriminate between heterocellular and homocellular locations when assembling connexin36-containing gap junctions , 2014, Journal of Cell Science.

[30]  M. A. Raven,et al.  Development and Plasticity of Outer Retinal Circuitry Following Genetic Removal of Horizontal Cells , 2013, The Journal of Neuroscience.

[31]  E. Hartveit,et al.  Electrical synapses between AII amacrine cells in the retina: Function and modulation , 2012, Brain Research.

[32]  Hui Zhao,et al.  The Rd8 mutation of the Crb1 gene is present in vendor lines of C57BL/6N mice and embryonic stem cells, and confounds ocular induced mutant phenotypes. , 2012, Investigative ophthalmology & visual science.

[33]  R. Gronostajski,et al.  Sox9 and NFIA Coordinate a Transcriptional Regulatory Cascade during the Initiation of Gliogenesis , 2012, Neuron.

[34]  J. N. Kay,et al.  MEGF10 AND 11 MEDIATE HOMOTYPIC INTERACTIONS REQUIRED FOR MOSAIC SPACING OF RETINAL NEURONS , 2012, Nature.

[35]  Jonathan B Demb,et al.  Intrinsic properties and functional circuitry of the AII amacrine cell , 2012, Visual Neuroscience.

[36]  J. N. Kay,et al.  NEUROD6 EXPRESSION DEFINES NOVEL RETINAL AMACRINE CELL SUBTYPES AND REGULATES THEIR FATE , 2011, Nature Neuroscience.

[37]  P. Lukasiewicz,et al.  Multiple pathways of inhibition shape bipolar cell responses in the retina , 2010, Visual Neuroscience.

[38]  L. Richards,et al.  NFIA Controls Telencephalic Progenitor Cell Differentiation through Repression of the Notch Effector Hes1 , 2010, The Journal of Neuroscience.

[39]  Frank S Werblin,et al.  Six different roles for crossover inhibition in the retina: Correcting the nonlinearities of synaptic transmission , 2010, Visual Neuroscience.

[40]  Allan R. Jones,et al.  A robust and high-throughput Cre reporting and characterization system for the whole mouse brain , 2009, Nature Neuroscience.

[41]  J. N. Kay,et al.  Birthdays of retinal amacrine cell subtypes are systematically related to their molecular identity and soma position , 2009, The Journal of comparative neurology.

[42]  N. Tian,et al.  BARHL2 Differentially Regulates the Development of Retinal Amacrine and Ganglion Neurons , 2009, The Journal of Neuroscience.

[43]  L. Richards,et al.  Nuclear factor I gene expression in the developing forebrain , 2008, The Journal of comparative neurology.

[44]  C. Cepko,et al.  Temporal order of bipolar cell genesis in the neural retina , 2008, Neural Development.

[45]  M. Tsai,et al.  Lineage tracing demonstrates the venous origin of the mammalian lymphatic vasculature. , 2007, Genes & development.

[46]  R. Gronostajski,et al.  Nuclear Factor I Coordinates Multiple Phases of Cerebellar Granule Cell Development via Regulation of Cell Adhesion Molecules , 2007, The Journal of Neuroscience.

[47]  David J. Anderson,et al.  The Transcription Factor NFIA Controls the Onset of Gliogenesis in the Developing Spinal Cord , 2006, Neuron.

[48]  L. Gan,et al.  Requirement for Bhlhb5 in the specification of amacrine and cone bipolar subtypes in mouse retina , 2006, Development.

[49]  Takashi Fujikado,et al.  Ptf1a determines horizontal and amacrine cell fates during mouse retinal development , 2006, Development.

[50]  J. Wittbrodt,et al.  Rx‐Cre, a tool for inactivation of gene expression in the developing retina , 2006, Genesis.

[51]  B. Chang,et al.  Study of rod- and cone-driven oscillatory potentials in mice. , 2006, Investigative ophthalmology & visual science.

[52]  Wei Wang,et al.  A Role for Nuclear Factor I in the Intrinsic Control of Cerebellar Granule Neuron Gene Expression* , 2004, Journal of Biological Chemistry.

[53]  S. Wu,et al.  The Transcription Factor Bhlhb4 Is Required for Rod Bipolar Cell Maturation , 2004, Neuron.

[54]  M. Shen,et al.  Foxn4 Controls the Genesis of Amacrine and Horizontal Cells by Retinal Progenitors , 2004, Neuron.

[55]  W. Hare,et al.  Origins of the electroretinogram oscillatory potentials in the rabbit retina , 2004, Visual Neuroscience.

[56]  W. Hare,et al.  Temporal modulation of scotopic visual signals by A17 amacrine cells in mammalian retina in vivo. , 2003, Journal of neurophysiology.

[57]  R. Stacy,et al.  Developmental relationship between cholinergic amacrine cell processes and ganglion cell dendrites of the mouse retina , 2003, The Journal of comparative neurology.

[58]  M. A. Raven,et al.  Development of cholinergic amacrine cell stratification in the ferret retina and the effects of early excitotoxic ablation , 2001, Visual Neuroscience.

[59]  S. Bloomfield,et al.  Rod Vision: Pathways and Processing in the Mammalian Retina , 2001, Progress in Retinal and Eye Research.

[60]  R. Gronostajski,et al.  Disruption of the murine nuclear factor I-A gene (Nfia) results in perinatal lethality, hydrocephalus, and agenesis of the corpus callosum. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[61]  R. Masland,et al.  The Major Cell Populations of the Mouse Retina , 1998, The Journal of Neuroscience.

[62]  M. Lavail,et al.  A naturally occurring mouse model of X-linked congenital stationary night blindness. , 1998, Investigative ophthalmology & visual science.

[63]  L. Wachtmeister,et al.  Oscillatory potentials in the retina: what do they reveal , 1998, Progress in Retinal and Eye Research.

[64]  G. Lyons,et al.  Expression patterns of the four nuclear factor I genes during mouse embryogenesis indicate a potential role in development , 1997, Developmental dynamics : an official publication of the American Association of Anatomists.

[65]  R H Masland,et al.  The number of unidentified amacrine cells in the mammalian retina. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[66]  E. Strettoi,et al.  Synaptic connections of the narrow‐field, bistratified rod amacrine cell (AII) in the rabbit retina , 1992, The Journal of comparative neurology.

[67]  R. W. Young Cell differentiation in the retina of the mouse , 1985, The Anatomical record.

[68]  R. W. Young,et al.  Cell death during differentiation of the retina in the mouse , 1984, The Journal of comparative neurology.

[69]  Helga Kolb,et al.  A bistratified amacrine cell and synaptic circuitry in the inner plexiform layer of the retina , 1975, Brain Research.

[70]  Helga Kolb,et al.  Rod and Cone Pathways in the Inner Plexiform Layer of Cat Retina , 1974, Science.

[71]  E. Pugh,et al.  The Origin of the Major Rod- and Cone-Driven Components of the Rodent Electroretinogram and the Effect of Age and Light-Rearing History on the Magnitude of These Components , 1998 .