Project description:This SuperSeries is composed of the following subset Series: GSE25774: Genome-wide analysis of Tdrd7 knockdown in lens epithelial-derived cell line 21EM15 GSE25775: Genome-wide analysis of 4-day old (P4) Tdrd7 null mouse lens GSE25776: Genome-wide analysis of 1 month old (P30) Tdrd7 null mouse lens Refer to individual Series

Project description:Genome-wide analysis of 4-day old (P4) Tdrd7 null mouse lens

Project description:Analysis of Tdrd7 deficiency in mouse lens epithelial-derived cell line at gene expression level. The hypothesis tested was that Tdrd7 is involved in post-transcriptional control of gene expression in the lens. Results provide evidence for differential regulation of genes involved in lens homeostasis and cataract formation in the absence of Tdrd7. In eukaryotic cells, cytoplasmic RNA granules (RGs) function in the post-transcriptional control of gene expression. However, the involvement of RGs and their component proteins in vertebrate organogenesis is unknown. We report two independent cases of pediatric cataract with loss-of-function mutations in TDRD7, which encodes a Tudor domain RNA binding protein. TDRD7 deficiency in chick lens produces cataracts, and Tdrd7 null mouse mutants develop cataracts, as well as features of glaucoma and male sterility due to azoospermia. In lens fiber cells, TDRD7 is necessary for the RG-mediated post-transcriptional control of critical lens mRNAs, while in the testis it functions as a component of a specialized RG, the chromatoid body. These findings define a new role for RGs in vertebrate organogenesis, and a novel mechanism for cataractogenesis. Total RNA obtained from P30 Lens from Tdrd7 null mice compared to that of Tdrd7 heterozygous mice.

Project description:Analysis of Tdrd7 deficiency in mouse lens epithelial-derived cell line at gene expression level. The hypothesis tested was that Tdrd7 is involved in post-transcriptional control of gene expression in the lens. Results provide evidence for differential regulation of genes involved in lens homeostasis and cataract formation in the absence of Tdrd7. In eukaryotic cells, cytoplasmic RNA granules (RGs) function in the post-transcriptional control of gene expression. However, the involvement of RGs and their component proteins in vertebrate organogenesis is unknown. We report two independent cases of pediatric cataract with loss-of-function mutations in TDRD7, which encodes a Tudor domain RNA binding protein. TDRD7 deficiency in chick lens produces cataracts, and Tdrd7 null mouse mutants develop cataracts, as well as features of glaucoma and male sterility due to azoospermia. In lens fiber cells, TDRD7 is necessary for the RG-mediated post-transcriptional control of critical lens mRNAs, while in the testis it functions as a component of a specialized RG, the chromatoid body. These findings define a new role for RGs in vertebrate organogenesis, and a novel mechanism for cataractogenesis. Total RNA obtained from P4 Lens from Tdrd7 null mice compared to that of Tdrd7 heterozygous mice.

Project description:Analysis of Tdrd7 deficiency in mouse lens epithelial-derived cell line at gene expression level. The hypothesis tested was that Tdrd7 is involved in post-transcriptional control of gene expression in the lens. Results provide evidence for differential regulation of genes involved in lens homeostasis and cataract formation in the absence of Tdrd7. In eukaryotic cells, cytoplasmic RNA granules (RGs) function in the post-transcriptional control of gene expression. However, the involvement of RGs and their component proteins in vertebrate organogenesis is unknown. We report two independent cases of pediatric cataract with loss-of-function mutations in TDRD7, which encodes a Tudor domain RNA binding protein. TDRD7 deficiency in chick lens produces cataracts, and Tdrd7 null mouse mutants develop cataracts, as well as features of glaucoma and male sterility due to azoospermia. In lens fiber cells, TDRD7 is necessary for the RG-mediated post-transcriptional control of critical lens mRNAs, while in the testis it functions as a component of a specialized RG, the chromatoid body. These findings define a new role for RGs in vertebrate organogenesis, and a novel mechanism for cataractogenesis.

Project description:Analysis of Tdrd7 deficiency in mouse lens epithelial-derived cell line at gene expression level. The hypothesis tested was that Tdrd7 is involved in post-transcriptional control of gene expression in the lens. Results provide evidence for differential regulation of genes involved in lens homeostasis and cataract formation in the absence of Tdrd7. In eukaryotic cells, cytoplasmic RNA granules (RGs) function in the post-transcriptional control of gene expression. However, the involvement of RGs and their component proteins in vertebrate organogenesis is unknown. We report two independent cases of pediatric cataract with loss-of-function mutations in TDRD7, which encodes a Tudor domain RNA binding protein. TDRD7 deficiency in chick lens produces cataracts, and Tdrd7 null mouse mutants develop cataracts, as well as features of glaucoma and male sterility due to azoospermia. In lens fiber cells, TDRD7 is necessary for the RG-mediated post-transcriptional control of critical lens mRNAs, while in the testis it functions as a component of a specialized RG, the chromatoid body. These findings define a new role for RGs in vertebrate organogenesis, and a novel mechanism for cataractogenesis.

Project description:Analysis of Tdrd7 deficiency in mouse lens epithelial-derived cell line at gene expression level. The hypothesis tested was that Tdrd7 is involved in post-transcriptional control of gene expression in the lens. Results provide evidence for differential regulation of genes involved in lens homeostasis and cataract formation in the absence of Tdrd7. In eukaryotic cells, cytoplasmic RNA granules (RGs) function in the post-transcriptional control of gene expression. However, the involvement of RGs and their component proteins in vertebrate organogenesis is unknown. We report two independent cases of pediatric cataract with loss-of-function mutations in TDRD7, which encodes a Tudor domain RNA binding protein. TDRD7 deficiency in chick lens produces cataracts, and Tdrd7 null mouse mutants develop cataracts, as well as features of glaucoma and male sterility due to azoospermia. In lens fiber cells, TDRD7 is necessary for the RG-mediated post-transcriptional control of critical lens mRNAs, while in the testis it functions as a component of a specialized RG, the chromatoid body. These findings define a new role for RGs in vertebrate organogenesis, and a novel mechanism for cataractogenesis.

Project description:Analysis of Tdrd7 deficiency in mouse lens epithelial-derived cell line at gene expression level. The hypothesis tested was that Tdrd7 is involved in post-transcriptional control of gene expression in the lens. Results provide evidence for differential regulation of genes involved in lens homeostasis and cataract formation in the absence of Tdrd7. In eukaryotic cells, cytoplasmic RNA granules (RGs) function in the post-transcriptional control of gene expression. However, the involvement of RGs and their component proteins in vertebrate organogenesis is unknown. We report two independent cases of pediatric cataract with loss-of-function mutations in TDRD7, which encodes a Tudor domain RNA binding protein. TDRD7 deficiency in chick lens produces cataracts, and Tdrd7 null mouse mutants develop cataracts, as well as features of glaucoma and male sterility due to azoospermia. In lens fiber cells, TDRD7 is necessary for the RG-mediated post-transcriptional control of critical lens mRNAs, while in the testis it functions as a component of a specialized RG, the chromatoid body. These findings define a new role for RGs in vertebrate organogenesis, and a novel mechanism for cataractogenesis. Total RNA obtained from Tdrd7 knockdown cells compared to lentiviral GFP control in 21EM15 lens epithelial-derived cell line

Project description:Mutations of the RNA-granule component TDRD7 (OMIM: 611258) cause pediatric cataract in humans. Here, we applied an integrated approach to elucidate the molecular pathology of cataract in Tdrd7 targeted-knockout (Tdrd7-/-) mice. Tdrd7-/- animals precipitously develop lens fiber cell abnormalities early in life, suggesting a global-level breakdown/mis-regulation of key cellular processes. High-throughput RNA-sequencing followed by iSyTE-integrated bioinformatics-based analysis identified the molecular chaperone and cytoskeletal-modulator, HSPB1 (HSP27), among the high-priority down-regulated candidates in Tdrd7-/- lens. Moreover, a protein 2-D fluorescence difference gel electrophoresis-coupled mass spectrometry screen also identified HSPB1 to be reduced in Tdrd7-/- lens, offering independent support for focusing efforts on this factor to explain Tdrd7-/- cataract. Reduction of HSPB1 preceded lens morphological abnormalities, suggesting that cytoskeletal defects underlie the Tdrd7-/- cataract phenotype. In agreement, scanning electron microscopy revealed abnormal fiber cell membrane protrusions in Tdrd7-/- lenses. Significantly, abnormal F-actin staining was detected specifically in Tdrd7-/- fiber cells that exhibit nuclear degradation, thereby revealing that there are distinct mechanisms based on pre- or post-nuclear degradation differentiation stage for F-actin cytoskeletal maintenance in fiber cells. Further, RNA-immunoprecipitation identified Hspb1 mRNA in wild-type lens lysate TDRD7-pulldowns, and single-molecule RNA-imaging showed co-localization of TDRD7 protein with cytoplasmic Hspb1 mRNA in a specific pre-nuclear degradation area of differentiating fiber cells, indicating that TDRD7-ribonucleoprotein complexes are necessary for controlling optimal levels of key factors in lens development. Together, these data uncover a novel role for TDRD7 in regulating elevation of stress-responsive chaperones for cytoskeletal maintenance in post-nuclear degradation lens fiber cells, perturbation of which causes early-onset cataracts.

Project description:Genome-wide analysis of Tdrd7 knockdown in lens epithelial-derived cell line 21EM15