Project description:Purpose: The aim of this study was to give a comprehensive overview on spatial distribution of gene expression in the adult mouse retina and integrate this information into existing retinal gene expression databases. Methods: Total RNA was collected by laser capture microdissection from the ganglion cell layer, inner nuclear layer, photoreceptors and the retinal pigmented epithelium of adult mice and was analyzed by oligonucleotide microarrays. The results were validated by quantitative real time PCR and in situ hybridization. Results: The applied method resulted in good separation of cells of different retinal layers. The spatial distribution of gene expression was determined on a global scale in the retina and the RPE. Our results show good correlation with previously reported retinal gene expression and describe genes not yet characterized in the context of the retina. Conclusions: The complexity of the vertebrate retina makes it necessary to determine not only temporal but spatial distributions of gene expression .Our work expands the already significant but still incomplete knowledge of retinal gene expression and hopefully facilitates functional characterization of key factors of retinal development and maintenance. Laser capture microdissected regions of the adult mouse neuronal retina and retinal pigmented epithelium were subjected to microarray analysis. 5 conditions were investigated: ganglion cell layer (GCL, 3 biological replicates), innner nuclear layer (INL, 3 biological replicates), photoreceptor layer from Blk6 (PR-WT, 3 biological replicates) and NrlKO animals (PR-Nrl, 2 biological replicates) and retinal pigmented epithelium (RPE, 1 biological replicate). All samples are co-hybridized with a reference sample (retina). 2 or 3 technical replicates were used for each biological sample. technical replicate - labeled-extract: GC1-1, GC1-2, GC1-3 technical replicate - labeled-extract: GC2-1, GC2-2, GC2-3 technical replicate - labeled-extract: GCpool-1, GCpool-2, GCpool-3 technical replicate - labeled-extract: INL1-1, INL1-2, INL1-3 technical replicate - labeled-extract: INL2-1, INL2-2, INL2-3 technical replicate - labeled-extract: INLpool-1, INLpool-2, INLpool-3 technical replicate - labeled-extract: PR-Nrl1-1, PR-Nrl1-2 technical replicate - labeled-extract: PR-Nrl2-1, PR-Nrl2-2, PR-Nrl2-3 technical replicate - labeled-extract: PR-WT1-1, PR-WT1-2, PR-WT1-3 technical replicate - labeled-extract: PR-WT2-1, PR-WT2-2, PR-WT2-3 technical replicate - labeled-extract: PR-WTpool-1, PR-WTpool-2, PR-WTpool-3 technical replicate - labeled-extract: RPE-1, RPE-2, RPE-3

Project description:Inherited retinal degenerations (IRDs) constitute a group of clinically and genetically diverse vision-impairing disorders. Retinitis pigmentosa (RP), the most common form of IRD, is characterized by gradual dysfunction and degeneration of rod photoreceptors, followed by the loss of cone photoreceptors. Recently, we identified reserpine as a lead molecule for maintaining rod survival in mouse and human retinal organoids as well as in the rd16 mouse, which phenocopy Leber congenital amaurosis caused by mutations in the cilia-centrosomal gene CEP290 (Chen et al. eLife 2023;12:e83205. DOI: https://doi.org/10.7554/eLife.83205). Here, we show the therapeutic potential of reserpine in a rhodopsin P23H rat model of autosomal dominant RP. At postnatal day (P) 68, when males and females are analyzed together, the reserpine-treated rats exhibit higher rod-derived scotopic b-wave amplitudes compared to the controls with little or no change in scotopic a-wave or cone-derived photopic b-wave. Interestingly, the reserpine-treated female rats display enhanced scotopic a- and b-waves and photopic b-wave responses at P68, along with a better contrast threshold and increased outer nuclear layer thickness. The female rats demonstrate better preservation of both rod and cone photoreceptors following reserpine treatment. Retinal transcriptome analysis reveals sex-specific responses to reserpine, with significant upregulation of phototransduction genes and proteostasis-related pathways, and notably, genes associated with stress response. This study builds upon our previously reported results reaffirming the potential of reserpine for gene-agnostic treatment of IRDs and emphasizes the importance of biological sex in retinal disease research and therapy development.

Project description:The rep1 gene of the maize pathogen Ustilago maydis encodes a pre-pro-protein that is processed in the secretory pathway into 11 peptides. These so-called repellents form amphipathic amyloid fibrils at the surface of aerial hyphae. Strains in which the rep1 gene is inactivated (∆rep1 strain) are affected in aerial hyphae formation. This makes these strains instrumental to assess changes in global gene expression as a consequence of aerial growth. Microarray analysis revealed that only 31 genes in the ∆rep1 SG200 strain had a fold change in expression of >= 2. Twenty-two of these genes are up-regulated and half of them encode small secreted proteins (SSP’s) with unknown functions. Seven of the SSP genes and two other genes that are over-expressed in the ∆rep1 SG200 strain encode secreted cysteine-rich proteins (SCRP’s). Interestingly, most of the SCRP’s are predicted to form amyloids. The SCRP gene um00792 showed the highest up-regulation in the ∆rep1 strain. Using GFP as a reporter, it was shown that this gene is over-expressed in the layer of hyphae at the medium-air interface. Taken together, it is concluded that only minor changes occur in the expression profile when U. maydis forms aerial structures. Key words: aerial hypha, repellent, hydrophobin-like protein, Ustilago maydis, SSP, SCRP, fungal pathogenicity.

Project description:Outer retinal degenerative diseases (RDDs) and injuries leading to photoreceptor (PR) loss are prevailing causes of blindness worldwide. While significant progress has been made in the manufacture of human pluripotent stem cell (hPSC)-derived PRs, robust production of PSC-PRs from pigs, a popular preclinical large animal model, would provide an avenue to collect conspecific functional and safety data to complement human xenograft studies. Toward this goal, we describe the highly efficient generation of PR-dominant pig induced PSC (piPSC)-derived retinal organoids (ROs) using modifications of our established hPSC-RO differentiation protocol. Pig iPSC-ROs were characterized using immunocytochemistry (ICC) and single cell RNA-sequencing (scRNA-seq), which revealed the presence and maturation of major neural retina cell types, including PRs and retinal ganglion cells, that possess molecular signatures akin to those found in hPSC-ROs. In late piPSC-ROs, a highly organized outer neuroepithelium was observed with rods and cones possessing outer segments and axon terminals expressing pre-synaptic markers adjacent to dendritic terminals of bipolar cells. The existence of piPSC lines and protocols that support reproducible, scalable production of female and male ROs will facilitate transplant studies in pig models of retinal injury and RDD unconfounded by immunological and evolutionary incompatibilities inherent to human xenografts.

Project description:Gene Expression Profiling of Oral Leukoplakia (OPL) and Early Stage Oral Squamous Cell Carcinoma (OSCC) was performed to delineate candidate gene/s clusters with potential to distinguish normal, OPL and tumor tissue from Gingivobuccal complex. All tissue samples were collected after obtaining written informed consent. The RNA profile of 15 OPL and 34 OSCC samples was compared with 1 independent controls Gingivobuccal complex tissue from healthy donors.

Project description:Recently we reported that the rat inner retina undergoes significant functional changes during maturation. Aiming to gain knowledge on additional aspects of retinal development and maturation, we used the microarray system to monitor gene expression patterns in the rat retina at ages 5, 11, and 20 weeks. The analysis revealed the expression of many well-documented retinal genes as well as a high number of nonâ??annotated genes. Quantitative realtime PCR analysis verified the microarray results in the majority of studied genes. A statistical analysis of the 4 microarray slides revealed 603 differentially expressed genes which were grouped into 6 expression clusters. A bioinformatic analysis of these clusters revealed sets of genes encoding proteins with functions that are likely to be relevant to inner retinal function (e.g. potassium, sodium, calcium, and chloride channels, synaptic vesicle transport, and axonogenesis). In addition, we performed a histological analysis of the maturing retina and studied different aspects of retinal structure. The analysis revealed a significant reduction of outer nuclear layer thickness between 11 and 19 weeks of age and a significant reduction of retinal ganglion cell number at 11 and 19 weeks comparing to 5 weeks. We identified in this study genes with differential expression pattern during retinal maturation. Some of the genes encode proteins that may be involved in the functional maturation of inner retinal cells. These data, taken together with our histological and electrophysiological data, contribute to our understanding of the developmental processes occurring in the retina of this widely-used animal model. Experiment Overall Design: Rat retinal samples at ages 5, 11, and 20 weeks were studied using 4 microarray slides in a dye-swap design: 5-11, 11-5, 5-20, and 20-5.

Project description:We applied time-series SE50bp RNA-seq with 35M reads per sample in wild-type, MZsox19b, MZspg, and double MZspgsox19b mutants in zebrafish embryos to understand the role of Pou5f3 and Sox19b during zebrafish zygotic genome activation. In total we sequenced 4 biological replicates (rep1-4) for WT time curve and 2 biological replicates (rep1-2) for each mutant. WT rep5 are technical replicates for WT rep1, while MZsox19b rep3 and MZspg rep3 are techical replicates for MZsox19b rep1 and MZspg rep1, respectively.

Project description:Retinal ganglion cells (RGCs) are the projection neurons that transmit visual information from the retina to the brain via the optic nerve. A substantial proportion of RGCs are eliminated by programmed cell death during development to regulate their final number, yet how cell death impacts RGC development in human retinas remains poorly understood. Here, we characterized the timing and cell-type-specificity of cell death in human fetal retinas and retinal organoids. We identified two waves of apoptosis: an early wave targeting retinal neuronal precursors and a late wave affecting RGCs and other neurons. In addition to these two waves of apoptosis, organoids displayed a distinct wave of necrosis in the innermost core region that eliminates nearly all RGCs during long-term culture. To investigate the functions of the apoptotic waves during retinal development, we differentiated BAX/BAK double mutant organoids that are deficient for apoptosis. In these mutant organoids, RGC survival was improved, RGC neurogenesis and maturation were delayed, and RGCs were lost through a compensatory increase in necrosis. Our data suggest that the waves of developmental apoptosis promote human RGC neurogenesis and maturation. Together, our results highlight the roles of cell death in human RGC development and the challenges in retinal organoid design. Overcoming these obstacles would improve the utility of retinal organoids for modeling optic neuropathies like glaucoma

Project description:Array Comparative Genomic Hybridization (CGH) profiling of Oral Leukoplakia (OPL) and early stage Oral Squamous Cell Carcinoma (OSCC) was performed to delineate candidate non-random chromosomal loci associated with disease progression and clinico-pathological parameters. The array CGH hybridizations were performed for 24 OPL and 38 OSCC samples with pooled gender matched controls. All tissue samples were collected after obtaining written informed consent.

Project description:We used single cell RNA-seq to comprehensively map all retinal microglia populations in a mouse model of oxygen-induced PR. We unveiled several unique types of PR-associated microglia (PRAM) and identified markers, signaling pathways, and regulons associated with these cells. Among these microglial subpopulations, we found a highly proliferative subset of cells with a high self-renewal capacity and a subset of cells with hypermetabolism that expresses high levels of activating microglia markers, glycolytic enzymes, and pro-angiogenic insulin-like growth factor 1. Immunohistochemical staining shows that PRAMs were spatially located within neovascular tufts. These unique microglial subtypes have the potential to promote retinal angiogenesis, which may have important implications for the future treatment of PR and other ocular diseases characterized by pathological angiogenesis.