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Temporal and spatial expression patterns of the CRX gene and its downstream targets: critical differences during human and mouse eye development

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Temporal and spatial expression patterns of the CRX gene and its downstream targets: critical differences during human and mouse eye development. / Bibb, Lindsay C.; Holt, James K. L.; Tarttelin, Emma E. et al.
In: Human Molecular Genetics, Vol. 10, No. 15, 2001, p. 1571-1579.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Bibb, LC, Holt, JKL, Tarttelin, EE, Hodges, M, Gregory-Evans, K, Rutherford, A, Lucas, RJ, Sowden, JC & Gregory-Evans, CY 2001, 'Temporal and spatial expression patterns of the CRX gene and its downstream targets: critical differences during human and mouse eye development', Human Molecular Genetics, vol. 10, no. 15, pp. 1571-1579. https://doi.org/10.1093/hmg/10.15.1571

APA

Bibb, L. C., Holt, J. K. L., Tarttelin, E. E., Hodges, M., Gregory-Evans, K., Rutherford, A., Lucas, R. J., Sowden, J. C., & Gregory-Evans, C. Y. (2001). Temporal and spatial expression patterns of the CRX gene and its downstream targets: critical differences during human and mouse eye development. Human Molecular Genetics, 10(15), 1571-1579. https://doi.org/10.1093/hmg/10.15.1571

Vancouver

Bibb LC, Holt JKL, Tarttelin EE, Hodges M, Gregory-Evans K, Rutherford A et al. Temporal and spatial expression patterns of the CRX gene and its downstream targets: critical differences during human and mouse eye development. Human Molecular Genetics. 2001;10(15):1571-1579. doi: 10.1093/hmg/10.15.1571

Author

Bibb, Lindsay C. ; Holt, James K. L. ; Tarttelin, Emma E. et al. / Temporal and spatial expression patterns of the CRX gene and its downstream targets : critical differences during human and mouse eye development. In: Human Molecular Genetics. 2001 ; Vol. 10, No. 15. pp. 1571-1579.

Bibtex

@article{18532e38ccdf44d292e8b2a090ecdd46,
title = "Temporal and spatial expression patterns of the CRX gene and its downstream targets: critical differences during human and mouse eye development",
abstract = "Cone–rod homeobox (CRX), a paired-like homeobox transcription factor, plays a major role in photoreceptor development and maintenance of the retina. Fifteen different mutations in the CRX gene have been identified as a cause of blinding retinal dystrophy. As a step towards characterizing the underlying pathophysiology of disease, temporal and spatial gene expression patterns during human and mouse eye development were investigated for CRX and for downstream retinally expressed genes, postulated to be transactivated by CRX. We found that human CRX was expressed at 10.5 weeks post-conception (p.c.). This was significantly later than observed in mouse development. Immunocytochemistry in human retina showed that CRX protein was not detected until >4 weeks later at 15 weeks p.c., implying that it would be unable to transactivate PDEB, IRBP and arrestin, which were all expressed before 15 weeks. These data therefore eliminate CRX as the major transcriptional activator of these three genes from a wide group of retinal genes that can be transactivated by CRX in vitro. Additionally, PDEB was expressed 2 weeks before CRX whereas murine Pdeb was expressed after Crx, highlighting a potential difference for the role of PDEB in human eye development. Previous data had shown CRX expression in the adult human retina to be photoreceptor-specific; however, we demonstrate that this gene is also expressed in the inner nuclear layer (INL) of the human and mouse retina by in situ hybridization and immunocytochemistry. INL localization of murine Crx was confirmed in rd/rd,cl mice, as in this mouse model the photoreceptors are absent. We have found important differences in the temporal expression of this gene in human and mouse retina, although spatial expression of the CRX gene appears to be conserved. In addition, downstream targets of CRX in vitro might not represent in vivo function during development. These data support concerns about the extent to which we can extrapolate from rodent models regarding embryonic development and disease pathophysiology.",
keywords = "crx",
author = "Bibb, {Lindsay C.} and Holt, {James K. L.} and Tarttelin, {Emma E.} and Matt Hodges and Kevin Gregory-Evans and Adam Rutherford and Lucas, {Robert J.} and Sowden, {Jane C.} and Gregory-Evans, {Cheryl Y.}",
year = "2001",
doi = "10.1093/hmg/10.15.1571",
language = "English",
volume = "10",
pages = "1571--1579",
journal = "Human Molecular Genetics",
issn = "1460-2083",
publisher = "Oxford University Press",
number = "15",

}

RIS

TY - JOUR

T1 - Temporal and spatial expression patterns of the CRX gene and its downstream targets

T2 - critical differences during human and mouse eye development

AU - Bibb, Lindsay C.

AU - Holt, James K. L.

AU - Tarttelin, Emma E.

AU - Hodges, Matt

AU - Gregory-Evans, Kevin

AU - Rutherford, Adam

AU - Lucas, Robert J.

AU - Sowden, Jane C.

AU - Gregory-Evans, Cheryl Y.

PY - 2001

Y1 - 2001

N2 - Cone–rod homeobox (CRX), a paired-like homeobox transcription factor, plays a major role in photoreceptor development and maintenance of the retina. Fifteen different mutations in the CRX gene have been identified as a cause of blinding retinal dystrophy. As a step towards characterizing the underlying pathophysiology of disease, temporal and spatial gene expression patterns during human and mouse eye development were investigated for CRX and for downstream retinally expressed genes, postulated to be transactivated by CRX. We found that human CRX was expressed at 10.5 weeks post-conception (p.c.). This was significantly later than observed in mouse development. Immunocytochemistry in human retina showed that CRX protein was not detected until >4 weeks later at 15 weeks p.c., implying that it would be unable to transactivate PDEB, IRBP and arrestin, which were all expressed before 15 weeks. These data therefore eliminate CRX as the major transcriptional activator of these three genes from a wide group of retinal genes that can be transactivated by CRX in vitro. Additionally, PDEB was expressed 2 weeks before CRX whereas murine Pdeb was expressed after Crx, highlighting a potential difference for the role of PDEB in human eye development. Previous data had shown CRX expression in the adult human retina to be photoreceptor-specific; however, we demonstrate that this gene is also expressed in the inner nuclear layer (INL) of the human and mouse retina by in situ hybridization and immunocytochemistry. INL localization of murine Crx was confirmed in rd/rd,cl mice, as in this mouse model the photoreceptors are absent. We have found important differences in the temporal expression of this gene in human and mouse retina, although spatial expression of the CRX gene appears to be conserved. In addition, downstream targets of CRX in vitro might not represent in vivo function during development. These data support concerns about the extent to which we can extrapolate from rodent models regarding embryonic development and disease pathophysiology.

AB - Cone–rod homeobox (CRX), a paired-like homeobox transcription factor, plays a major role in photoreceptor development and maintenance of the retina. Fifteen different mutations in the CRX gene have been identified as a cause of blinding retinal dystrophy. As a step towards characterizing the underlying pathophysiology of disease, temporal and spatial gene expression patterns during human and mouse eye development were investigated for CRX and for downstream retinally expressed genes, postulated to be transactivated by CRX. We found that human CRX was expressed at 10.5 weeks post-conception (p.c.). This was significantly later than observed in mouse development. Immunocytochemistry in human retina showed that CRX protein was not detected until >4 weeks later at 15 weeks p.c., implying that it would be unable to transactivate PDEB, IRBP and arrestin, which were all expressed before 15 weeks. These data therefore eliminate CRX as the major transcriptional activator of these three genes from a wide group of retinal genes that can be transactivated by CRX in vitro. Additionally, PDEB was expressed 2 weeks before CRX whereas murine Pdeb was expressed after Crx, highlighting a potential difference for the role of PDEB in human eye development. Previous data had shown CRX expression in the adult human retina to be photoreceptor-specific; however, we demonstrate that this gene is also expressed in the inner nuclear layer (INL) of the human and mouse retina by in situ hybridization and immunocytochemistry. INL localization of murine Crx was confirmed in rd/rd,cl mice, as in this mouse model the photoreceptors are absent. We have found important differences in the temporal expression of this gene in human and mouse retina, although spatial expression of the CRX gene appears to be conserved. In addition, downstream targets of CRX in vitro might not represent in vivo function during development. These data support concerns about the extent to which we can extrapolate from rodent models regarding embryonic development and disease pathophysiology.

KW - crx

U2 - 10.1093/hmg/10.15.1571

DO - 10.1093/hmg/10.15.1571

M3 - Journal article

VL - 10

SP - 1571

EP - 1579

JO - Human Molecular Genetics

JF - Human Molecular Genetics

SN - 1460-2083

IS - 15

ER -