Browsing by Subject "phototransduction"
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Item Open Access Photoreceptors in a Mouse Model of Leigh Syndrome are Capable of Normal Light-Evoked Signaling.(The Journal of biological chemistry, 2019-06-27) Gospe, Sidney M; Travis, Amanda M; Kolesnikov, Alexander V; Klingeborn, Mikael; Wang, Luyu; Kefalov, Vladimir J; Arshavsky, Vadim YMitochondrial dysfunction is an important cause of heritable vision loss. Mutations affecting mitochondrial bioenergetics may lead to isolated vision loss or life-threatening systemic disease, depending on a mutation's severity. Primary optic nerve atrophy resulting from death of retinal ganglion cells is the most prominent ocular manifestation of mitochondrial disease. However, dysfunction of other retinal cell types has also been described, sometimes leading to a loss of photoreceptors and retinal pigment epithelium that manifests clinically as pigmentary retinopathy. A popular mouse model of mitochondrial disease that lacks NADH:ubiquinone oxidoreductase subunit S4 (NDUFS4), a subunit of mitochondrial complex I, phenocopies many traits of the human disease Leigh syndrome, including the development of optic atrophy. It has also been reported that ndufs4-/- mice display diminished light responses at the level of photoreceptors or bipolar cells. By conducting electroretinography (ERG) recordings in live ndufs4-/- mice, we now demonstrate that this defect occurs at the level of retinal photoreceptors. We found that this deficit does not arise from retinal developmental anomalies, photoreceptor degeneration, or impaired regeneration of visual pigment. Strikingly, the impairment of ndufs4-/- photoreceptor function was not observed in ex vivo ERG recordings from isolated retinas, indicating that photoreceptors with complex I deficiency are intrinsically capable of normal signaling. The difference in electrophysiological phenotypes in vivo and ex vivo suggests that the energy deprivation associated with severe mitochondrial impairment in the outer retina renders ndufs4-/- photoreceptors unable to maintain the homeostatic conditions required to operate at their normal capacity.Item Open Access Temporal resolution of single photon responses in primate rod photoreceptors and limits imposed by cellular noise.(Journal of neurophysiology, 2018-11-28) Field, Greg D; Uzzell, Valerie; Chichilnisky, EJ; Rieke, FredSensory receptor noise corrupts sensory signals, contributing to imperfect perception and dictating central processing strategies. For example, noise in rod phototransduction limits our ability to detect light and minimizing the impact of this noise requires precisely tuned nonlinear processing by the retina. But detection sensitivity is only one aspect of night vision: prompt and accurate behavior also requires that rods reliably encode the timing of photon arrivals. We show here that the temporal resolution of responses of primate rods is much finer than the duration of the light response and identify the key limiting sources of transduction noise. We also find that the thermal activation rate of rhodopsin is lower than previous estimates, implying that other noise sources are more important than previously appreciated. A model of rod single-photon responses reveals that the limiting noise relevant for behavior depends critically on how rod signals are pooled by downstream neurons.Item Open Access The Functional and Pathophysiological Consequences of Transducin γ-Subunit Knockout(2019) Dexter, Paige MerrittThe initial steps of vertebrate vision take place in the retina, where light-sensitive rod and cone photoreceptor cells translate light into an electrical signal through a biochemical process called phototransduction. Transducin, a heterotrimeric G protein, is central to this process in rod photoreceptors. In rods, phototransduction begins when transducin is activated by the light-stimulated G protein-coupled receptor rhodopsin, setting off a cascade of cellular events that ultimately generates the visual signal, or photoresponse. Many aspects of transducin’s function were uncovered through studies of knockout mice lacking its individual subunits. Of particular interest is the knockout mouse lacking the transducin γ-subunit, Gγ1 (the Gγ1-/- mouse), which exhibits unique characteristics that have thus far remained incompletely understood. First, Gγ1-/- rods retain the ability to detect light, despite lacking the canonical transducin Gβ1γ1 complex. Second, these cells experience chronic proteostatic stress, consisting of an insufficient capacity for protein degradation by the ubiquitin-proteasome system (UPS), which leads to the progressive dysfunction and eventual death of Gγ1-/- rods.
This dissertation focuses on uncovering the molecular mechanisms underlying the unique functional and pathophysiological consequences of Gγ1 knockout in rod photoreceptors. In Chapter 3, we investigate the mechanism driving light-signaling in Gγ1-/- rods. In Chapter 4, we evaluate whether the chronic proteostatic stress observed in degenerating rods could result from insufficient activity of a specific component of the UPS: the substrate-processing complex formed by the AAA+ ATPase P97 (aka VCP) and associated cofactors.
We determined that the level of photoresponse sensitivity of Gγ1-/- rods was comparable to the expression levels of Gαt and Gβ1, the remaining components of the transducin heterotrimer, in the outer segments of these cells. We found that two additional G protein γ-subunits (Gγ2 and Gγ3) are present in the outer segments of both WT and Gγ1-/- rods. Finally, we demonstrated that Gβ1, which normally forms an inseparable heterodimer with Gγ1, also forms complexes with Gγ2 and Gγ3 in both WT and Gγ1-/- rods. Thus, we conclude that the canonical transducin Gβ1γ1 complex is not the sole Gβγ complex able to facilitate phototransduction and that transducin complexes utilizing alternative γ-subunits support transducin activation in Gγ1-/- rods.
Our examination of proteostatic stress in degenerating rods focused on two mouse models of retinal degeneration: the Gγ1-/- mouse and the knockin mouse expressing a single copy of the rhodopsin P23H mutation (the P23H mouse). Rods of both strains exhibit proteostatic stress, consisting of an insufficient capacity for protein degradation by the UPS, linked to the requirement to degrade misfolded photoreceptor proteins. We investigated whether insufficient UPS function in these cells results from an insufficient cellular capacity for substrate processing by P97 complexes, a critical step in the proteasomal degradation of a large subset of UPS targets. Gγ1-/- and P23H retinas displayed strikingly different patterns of accumulation of two complementary in vivo proteasomal activity reporters whose degradation is either P97-dependent or P97-independent. Based on these patterns, we conclude that the proteostatic stress observed in Gγ1-/- and P23H rods likely originates from distinct pathophysiological mechanisms in which protein degradation by the UPS may or may not be limited by the cellular capacity for substrate processing by P97 complexes. We show that UPS function in Gγ1-/- rods is likely limited by insufficient P97-dependent substrate processing, whereas proteasomal degradation itself limits UPS function in P23H rods. Finally, we found that, despite being aphenotypic in several other tissues, P97 overexpression is toxic to rod photoreceptors and increases proteostatic stress in Gγ1-/- rods.
Together, these studies broaden our understanding of photoreceptor cell biology. In addition to illuminating the mechanisms underlying light-signaling in rods, the work described in this dissertation highlights phototransduction in Gγ1-/- rods as a compelling example of the functional interchangeability of G protein γ-subunits. To our knowledge, this represents the first direct demonstration of multiple Gβγ complexes performing the same function in a living animal. Further, this work highlights the complexity of pathophysiological mechanisms related to degrading misfolded proteins in mutant photoreceptors, which must be accounted for in the development of effective strategies to ameliorate these blinding conditions.
Item Open Access Transducin β-Subunit Can Interact with Multiple G-Protein γ-Subunits to Enable Light Detection by Rod Photoreceptors.(eNeuro, 2018-05) Dexter, Paige M; Lobanova, Ekaterina S; Finkelstein, Stella; Spencer, William J; Skiba, Nikolai P; Arshavsky, Vadim YThe heterotrimeric G-protein transducin mediates visual signaling in vertebrate photoreceptor cells. Many aspects of the function of transducin were learned from knock-out mice lacking its individual subunits. Of particular interest is the knockout of its rod-specific γ-subunit (Gγ1). Two studies using independently generated mice documented that this knockout results in a considerable >60-fold reduction in the light sensitivity of affected rods, but provided different interpretations of how the remaining α-subunit (Gαt) mediates phototransduction without its cognate Gβ1γ1-subunit partner. One study found that the light sensitivity reduction matched a corresponding reduction in Gαt content in the light-sensing rod outer segments and proposed that Gαt activation is supported by remaining Gβ1 associating with other Gγ subunits naturally expressed in photoreceptors. In contrast, the second study reported the same light sensitivity loss but a much lower, only approximately sixfold, reduction of Gαt and proposed that the light responses of these rods do not require Gβγ at all. To resolve this controversy and elucidate the mechanism driving visual signaling in Gγ1 knock-out rods, we analyzed both mouse lines side by side. We first determined that the outer segments of both mice have identical Gαt content, which is reduced ∼65-fold from the wild-type (WT) level. We further demonstrated that the remaining Gβ1 is present in a complex with endogenous Gγ2 and Gγ3 subunits and that these complexes exist in wild-type rods as well. Together, these results argue against the idea that Gαt alone supports light responses of Gγ1 knock-out rods and suggest that Gβ1γ1 is not unique in its ability to mediate vertebrate phototransduction.Item Open Access UVB radiation generates sunburn pain and affects skin by activating epidermal TRPV4 ion channels and triggering endothelin-1 signaling.(Proc Natl Acad Sci U S A, 2013-08-20) Moore, Carlene; Cevikbas, Ferda; Pasolli, H Amalia; Chen, Yong; Kong, Wei; Kempkes, Cordula; Parekh, Puja; Lee, Suk Hee; Kontchou, Nelly-Ange; Yeh, Iwei; Jokerst, Nan Marie; Fuchs, Elaine; Steinhoff, Martin; Liedtke, Wolfgang BAt our body surface, the epidermis absorbs UV radiation. UV overexposure leads to sunburn with tissue injury and pain. To understand how, we focus on TRPV4, a nonselective cation channel highly expressed in epithelial skin cells and known to function in sensory transduction, a property shared with other transient receptor potential channels. We show that following UVB exposure mice with induced Trpv4 deletions, specifically in keratinocytes, are less sensitive to noxious thermal and mechanical stimuli than control animals. Exploring the mechanism, we find that epidermal TRPV4 orchestrates UVB-evoked skin tissue damage and increased expression of the proalgesic/algogenic mediator endothelin-1. In culture, UVB causes a direct, TRPV4-dependent Ca(2+) response in keratinocytes. In mice, topical treatment with a TRPV4-selective inhibitor decreases UVB-evoked pain behavior, epidermal tissue damage, and endothelin-1 expression. In humans, sunburn enhances epidermal expression of TRPV4 and endothelin-1, underscoring the potential of keratinocyte-derived TRPV4 as a therapeutic target for UVB-induced sunburn, in particular pain.