5 results on '"Katarzyna A. Hussey"'
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2. Patterning and Development of Photoreceptors in the Human Retina
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Katarzyna A. Hussey, Sarah E. Hadyniak, and Robert J. Johnston
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genetic structures ,sense organs ,Cell Biology ,eye diseases ,Developmental Biology - Abstract
Humans rely on visual cues to navigate the world around them. Vision begins with the detection of light by photoreceptor cells in the retina, a light-sensitive tissue located at the back of the eye. Photoreceptor types are defined by morphology, gene expression, light sensitivity, and function. Rod photoreceptors function in low-light vision and motion detection, and cone photoreceptors are responsible for high-acuity daytime and trichromatic color vision. In this review, we discuss the generation, development, and patterning of photoreceptors in the human retina. We describe our current understanding of how photoreceptors are patterned in concentric regions. We conclude with insights into mechanisms of photoreceptor differentiation drawn from studies of model organisms and human retinal organoids.
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- 2022
3. Spatiotemporal specification of human green and red cones
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Sarah E. Hadyniak, Kiara C. Eldred, Boris Brenerman, Katarzyna A. Hussey, Joanna F. D. Hagen, Rajiv C. McCoy, Michael E. G. Sauria, James A. Kuchenbecker, Thomas Reh, Ian Glass, Maureen Neitz, Jay Neitz, James Taylor, and Robert J. Johnston
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chemistry.chemical_compound ,genetic structures ,chemistry ,Trichromacy ,Organoid ,Retinoic acid ,Retinal ,sense organs ,Cone (category theory) ,Biology ,Natural variation ,NR2F2 Gene ,Cell biology - Abstract
Trichromacy is unique to primates among mammals, enabled by blue (short/S), green (medium/M), and red (long/L) cones. In humans and Old World monkeys, cones make a poorly understood choice between M and L cone subtype fates. To determine mechanisms specifying M and L cones, we developed an approach to visualize expression of the highly similarM- andL-opsinmRNAs.M-opsin, but notL-opsin, was observed during early human eye development, suggesting that M cones are generated before L cones. In adult human tissue, the early-developing central retina contained a mix of M and L cones compared to the late-developing peripheral region, which contained a high proportion of L cones. Retinoic acid (RA)-synthesizing enzymes are highly expressed early in retinal development. High RA signaling early was sufficient to promote M cone fate and suppress L cone fate in retinal organoids. Across a human population sample, natural variation in the ratios of M and L cone subtypes was associated with a noncoding polymorphism in theNR2F2gene, a mediator of RA signaling. Our data suggest that RA promotes M cone fate early in development to generate the pattern of M and L cones across the human retina.
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- 2021
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4. Spatial and temporal control of targeting Polo-like kinase during meiotic prophase
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Katarzyna A. Hussey, Yumi Kim, and James N. Brandt
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Polo-like kinase ,Biology ,Protein Serine-Threonine Kinases ,Article ,Chromosome segregation ,Prophase ,Meiosis ,Chromosome Segregation ,CDC2 Protein Kinase ,Genetics ,Animals ,Phosphorylation ,Caenorhabditis elegans ,Caenorhabditis elegans Proteins ,Spatial Analysis ,Synaptonemal Complex ,Synapsis ,Nuclear Proteins ,Cell Biology ,Cell biology ,Synaptonemal complex ,enzymes and coenzymes (carbohydrates) ,Chromosome Pairing ,Holocentric ,biological phenomena, cell phenomena, and immunity ,Cell Cycle and Division - Abstract
Brandt et al. establish mechanisms that target Polo-like kinase during meiotic prophase in C. elegans. CDK-1 phosphorylates a synaptonemal complex component, SYP-1, to generate docking sites for PLK-2, whose association is prevented until crossover formation to ensure homologue pairing, synapsis, and chromosome remodeling., Polo-like kinases (PLKs) play widely conserved roles in orchestrating meiotic chromosome dynamics. However, how PLKs are targeted to distinct subcellular localizations during meiotic progression remains poorly understood. Here, we demonstrate that the cyclin-dependent kinase CDK-1 primes the recruitment of PLK-2 to the synaptonemal complex (SC) through phosphorylation of SYP-1 in C. elegans. SYP-1 phosphorylation by CDK-1 occurs just before meiotic onset. However, PLK-2 docking to the SC is prevented by the nucleoplasmic HAL-2/3 complex until crossover designation, which constrains PLK-2 to special chromosomal regions known as pairing centers to ensure proper homologue pairing and synapsis. PLK-2 is targeted to crossover sites primed by CDK-1 and spreads along the SC by reinforcing SYP-1 phosphorylation on one side of each crossover only when threshold levels of crossovers are generated. Thus, the integration of chromosome-autonomous signaling and a nucleus-wide crossover-counting mechanism partitions holocentric chromosomes relative to the crossover site, which ultimately defines the pattern of chromosome segregation during meiosis I.
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- 2020
5. Thyroid hormone signaling specifies cone subtypes in human retinal organoids
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James Taylor, Robert J. Johnston, Sarah E. Hadyniak, Valentin M. Sluch, Xitiz Chamling, Karl J. Wahlin, Derek S. Welsbie, Katarzyna A. Hussey, Kiara C. Eldred, Donald J. Zack, Ping Wu Zhang, Samer Hattar, and Boris Brenerman
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Nervous system ,0301 basic medicine ,Thyroid Hormones ,Opsin ,genetic structures ,Color vision ,DIO2 ,Cell fate determination ,Biology ,Retina ,Article ,Cell Line ,Thyroid hormone receptor beta ,03 medical and health sciences ,chemistry.chemical_compound ,0302 clinical medicine ,Organoid ,medicine ,Humans ,Hormone signaling ,Embryonic Stem Cells ,030304 developmental biology ,Regulation of gene expression ,0303 health sciences ,Multidisciplinary ,Thyroid ,Gene Expression Regulation, Developmental ,Retinal ,Cone (formal languages) ,eye diseases ,Cone cell ,Cell biology ,Organoids ,030104 developmental biology ,medicine.anatomical_structure ,chemistry ,Mutation ,Proteolysis ,Retinal Cone Photoreceptor Cells ,sense organs ,CRISPR-Cas Systems ,030217 neurology & neurosurgery ,Hormone - Abstract
INTRODUCTION: Cone photoreceptors in the human retina enable daytime, color, and high-acuity vision. The three subtypes of human cones are defined by the visual pigment that they express: blue-opsin (short wavelength; S), green-opsin (medium wavelength; M), or red-opsin (long wavelength; L). Mutations that affect opsin expression or function cause various forms of color blindness and retinal degeneration. RATIONALE: Our current understanding of the vertebrate eye has been derived primarily from the study of model organisms. We studied the human retina to understand the developmental mechanisms that generate the mosaic of mutually exclusive cone subtypes. Specification of human cones occurs in a two-step process. First, a decision occurs between S versus L/M cone fates. If the L/M fate is chosen, a subsequent choice is made between expression of L- or M-opsin. To determine the mechanism that controls the first decision between S and L/M cone fates, we studied human retinal organoids derived from stem cells. RESULTS: We found that human organoids and retinas have similar distributions, gene expression profiles, and morphologies of cone subtypes. During development, S cones are specified first, followed by L/M cones. This temporal switch from specification of S cones to generation of L/M cones is controlled by thyroid hormone (TH) signaling. In retinal organoids that lacked thyroid hormone receptor β (Thrβ), all cones developed into the S subtype. Thrβ binds with high affinity to triiodothyronine (T3), the more active form of TH, to regulate gene expression. We observed that addition of T3 early during development induced L/M fate in nearly all cones. Thus, TH signaling through Thrβ is necessary and sufficient to induce L/M cone fate and suppress S fate. TH exists largely in two states: thyroxine (T4), the most abundant circulating form of TH, and T3, which binds TH receptors with high affinity. We hypothesized that the retina itself could modulate TH levels to control subtype fates. We found that deiodinase 3 (DIO3), an enzyme that degrades both T3 and T4, was expressed early in organoid and retina development. Conversely, deiodinase 2 (DIO2), an enzyme that converts T4 to active T3, as well as TH carriers and transporters, were expressed later in development. Temporally dynamic expression of TH-degrading and -activating proteins supports a model in which the retina itself controls TH levels, ensuring low TH signaling early to specify S cones and high TH signaling later in development to produce L/M cones. CONCLUSION: Studies of model organisms and human epidemiology often generate hypotheses about human biology that cannot be studied in humans. Organoids provide a system to determine the mechanisms of human development, enabling direct testing of hypotheses in developing human tissue. Our studies identify temporal regulation of TH signaling as a mechanism that controls cone subtype specification in humans. Consistent with our findings, preterm human infants with low T3 and T4 have an increased incidence of color vision defects. Moreover, our identification of a mechanism that generates one cone subtype while suppressing the other, coupled with successful transplantation and incorporation of stem cell-derived photoreceptors in mice, suggests that the promise of therapies to treat human diseases such as color blindness, retinitis pigmentosa, and macular degeneration will be achieved in the near future. ■, Graphical Abstract Temporally regulated TH signaling specifies cone subtypes. (A) Embryonic stem cell-derived human retinal organoids [wild type (WT)] generate S and L/M cones. Blue, S-opsin; green, L/M-opsin. (B) Organoids that lack thyroid hormone receptor β (Thrβ KO) generate all S cones. (C) Early activation of TH signaling (WT + T3) specifies nearly all L/M cones. (D) TH-degrading enzymes (such as DIO3) expressed early in development lower TH and promote S fate, whereas TH-activating regulators (such as DIO2) expressed later promote L/M fate., Summary The mechanisms underlying specification of neuronal subtypes within the human nervous system are largely unknown. The blue (S), green (M), and red (L) cones of the retina enable high-acuity daytime and color vision. To determine the mechanism that controls S versus L/M fates, we studied the differentiation of human retinal organoids. Organoids and retinas have similar distributions, expression profiles, and morphologies of cone subtypes. S cones are specified first, followed by L/M cones, and thyroid hormone signaling controls this temporal switch. Dynamic expression of thyroid hormone–degrading and –activating proteins within the retina ensures low signaling early to specify S cones and high signaling late to produce L/M cones. This work establishes organoids as a model for determining mechanisms of human development with promising utility for therapeutics and vision repair.
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- 2018
- Full Text
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