Ignacio Provencio (born 29 June 1965) is an American neuroscientist and the discoverer of melanopsin, [1] an opsin found in specialized photosensitive ganglion cells of the mammalian retina. Provencio served as the program committee chair of the Society for Research on Biological Rhythms from 2008 to 2010. [2]
Provencio was born in Bitburg, Germany and attended Lebanon Catholic High School in Lebanon, PA. During his undergraduate career at Swarthmore College, Provencio became interested in neuroscience while studying crayfish, cockroaches, and fireflies under Jon Copeland. [3] From 1987 to 1989 he worked as a lab technician in Steve Reppert's research laboratory at Massachusetts General Hospital, where he was introduced to the field of circadian biology. He graduated in 1987 from Swarthmore College with a B.A. in Biology and went on to earn his Ph.D. from the University of Virginia, a university with a strong network of circadian biologists, in 1996. During his postdoctoral training at Uniformed Services University, Provencio held assistant and associate professorships at Uniformed Services University, Department of Anatomy, Physiology, and Genetics where he still maintains an adjunct associate professorship. [4] Provencio is a full professor at the University of Virginia. [5]
In 1998, Provencio discovered melanopsin as a new opsin in the photosensitive skin melanophores of the African clawed frog. [6] In 2000, he showed that melanopsin is also present in mouse, rhesus macaques, and humans, where it is only present in the eye. The unique inner retinal localization of melanopsin indicated that melanopsin was not involved in image formation. [7] Later, he demonstrated that the melanopsin pigment might be involved in entrainment of a circadian oscillator to light cycles in mammals. [8]
He found that blind mice without classical photoreceptor cells (rods and cones) still had eye-mediated responses to light. Mice with the melanopsin gene knocked out but with functional rods and cones were also able to entrain. However, when melanopsin was knocked out in blind mice without rods and cones, they exhibited “complete loss of photoentrainment of the circadian oscillator, pupillary light responses, photic suppression of arylalkylamine-N-acetyltransferase transcript, and acute suppression of locomotor activity by light.” [8] Provencio concluded that either melanopsin-containing retinal ganglion cells or outer-retinal photoreceptors (rods and cones) are sufficient to induce a response to light. However, in the absence of either rods and cones or melanopsin, melanopsin becomes necessary for photoentrainment of the circadian oscillator and for other photic responses. [8]
To further investigate the role of melanopsin in light-induced phase shifting in mammals, the Provencio lab studied the locomotor activities of melanopsin-null mice (Opn4 -/-) in response to light. [9] The Opn4 -/- mice showed similar circadian behaviors as the normal mice: they entrained to light/dark cycles and free-ran under constant darkness in a way expected from the normal mice. [9] Researchers in Provencio's lab thus concluded that melanopsin was not involved in the functioning of the master clock oscillation. [9] On the other hand, Opn4-/- mice had difficulties adjusting to new phases in response to pulses of monochromatic light. [9] The implication was that melanopsin was necessary for phase resetting but other mechanisms of light inputs might be involved in circadian entrainment as well. [9]
In 2008, the Provencio lab was able to specifically destroy melanopsin cells in the fully developed mouse retina using an immunotoxin made of an anti-melanopsin antibody conjugated to the protein saporin. [10] This resulted in lowered responsiveness to light/dark cycles; a similar characteristic was observed in gene-knockout mutants lacking rods, cones or melanopsin. Furthermore, light-induced negative masking, mediated by rods, cones and/or melanopsin cells, was missing in the mice lacking melanopsin cells. [10] Therefore, Provencio suggested that cells containing melanopsin might be required to transmit rod and/or cone information for certain non-image forming visual responses. [10]
Provencio's discovery of melanopsin and its function in photoentrainment supports earlier studies showing that some blind patients can entrain to a daily light cycle. [11] Since retinal ganglion cells that express melanopsin have also been found in humans, these studies suggest that blind humans who still retain functional melanopsin cells are those who are able to entrain to daily light cycles. These studies also show that blind patients who cannot entrain and lack melanopsin cells have a significantly greater risk of suffering from circadian rhythm sleep disorders. [12] While enucleation of blind patients and babies was a common practice for cosmetic or analgesic reasons, doctors now must make a more cautious decision on whether to enucleate blind patients, especially infants, because they may still have functioning photosensitive retinal ganglion cells that express melanopsin. [13] In addition, there are now studies attempting to optimize light therapy for those with circadian rhythm sleep disorders that specifically try to stimulate melanopsin cells in blind patients. [14]
Provencio's research team has found that in albino mice, the amount of melanopsin protein in various retinal cells varies based on the environmental light conditions. [15] In constant light conditions, melanopsin cell number did not increase. [15] However, when these constant-light mice were exposed to light-dark schedules, there was regain of melanopsin cell number. [15] This study shows that bouts of darkness or the order of light and dark periods may control the normal development of the melanopsin system. [15]
In a 2006 study, Provencio explored the role of the protein RPE65 for photoentrainment. RPE65 is an important protein found in intrinsically photosensitive retinal ganglion cells (ipRGCs) that is necessary for regeneration of visual chromophore in rods and cones. RPE65 knockout mice (Rpe65(-/-)) showed much weaker phase shifts when compared to rodless, coneless mice, which suggested that RPE65 might have other roles. [16]
To further define the functions of RPE65, Provencio took Rpe65(-/-) mice and also eliminated rods. The technique used for this was insertion of the rdta transgene, which selectively kills rods. They found that circadian photosensitivity returned in these mice without RPE65 protein and without rods, versus mice without RPE65 protein that still had rods. [16]
Provencio also took Rpe65(-/-) mice and crossed them with melanopsin knockout mice (Opn4(-/-)). This created double RPE and melanopsin knockout mice, which resulted in abnormal photoentrainment and diurnal behavior. From these results, Provencio concluded that RPE65 is not necessary for the function of ipRGCs. However, because of the interesting restoration of circadian photosensitivity in rodless, RPE-less mice, there seems to be a mechanism by which rods can influences ipRGCs and rods may interact. [16]
Free-running sleep is a rare sleep pattern whereby the sleep schedule of a person shifts later every day. It occurs as the sleep disorder non-24-hour sleep–wake disorder or artificially as part of experiments used in the study of circadian and other rhythms in biology. Study subjects are shielded from all time cues, often by a constant light protocol, by a constant dark protocol or by the use of light/dark conditions to which the organism cannot entrain such as the ultrashort protocol of one hour dark and two hours light. Also, limited amounts of food may be made available at short intervals so as to avoid entrainment to mealtimes. Subjects are thus forced to live by their internal circadian "clocks".
Chronobiology is a field of biology that examines timing processes, including periodic (cyclic) phenomena in living organisms, such as their adaptation to solar- and lunar-related rhythms. These cycles are known as biological rhythms. Chronobiology comes from the ancient Greek χρόνος, and biology, which pertains to the study, or science, of life. The related terms chronomics and chronome have been used in some cases to describe either the molecular mechanisms involved in chronobiological phenomena or the more quantitative aspects of chronobiology, particularly where comparison of cycles between organisms is required.
A photoreceptor cell is a specialized type of neuroepithelial cell found in the retina that is capable of visual phototransduction. The great biological importance of photoreceptors is that they convert light into signals that can stimulate biological processes. To be more specific, photoreceptor proteins in the cell absorb photons, triggering a change in the cell's membrane potential.
Cone cells or cones are photoreceptor cells in the retinas of vertebrates' eyes. They respond differently to light of different wavelengths, and the combination of their responses is responsible for color vision. Cones function best in relatively bright light, called the photopic region, as opposed to rod cells, which work better in dim light, or the scotopic region. Cone cells are densely packed in the fovea centralis, a 0.3 mm diameter rod-free area with very thin, densely packed cones which quickly reduce in number towards the periphery of the retina. Conversely, they are absent from the optic disc, contributing to the blind spot. There are about six to seven million cones in a human eye, with the highest concentration being towards the macula.
Retinal is a polyene chromophore. Retinal, bound to proteins called opsins, is the chemical basis of visual phototransduction, the light-detection stage of visual perception (vision).
Melanopsin is a type of photopigment belonging to a larger family of light-sensitive retinal proteins called opsins and encoded by the gene Opn4. In the mammalian retina, there are two additional categories of opsins, both involved in the formation of visual images: rhodopsin and photopsin in the rod and cone photoreceptor cells, respectively.
Giant retinal ganglion cells are photosensitive ganglion cells with large dendritic trees discovered in the human and macaque retina by Dacey et al. (2005).
Intrinsically photosensitive retinal ganglion cells (ipRGCs), also called photosensitive retinal ganglion cells (pRGC), or melanopsin-containing retinal ganglion cells (mRGCs), are a type of neuron in the retina of the mammalian eye. The presence of an additional photoreceptor was first suspected in 1927 when mice lacking rods and cones still responded to changing light levels through pupil constriction; this suggested that rods and cones are not the only light-sensitive tissue. However, it was unclear whether this light sensitivity arose from an additional retinal photoreceptor or elsewhere in the body. Recent research has shown that these retinal ganglion cells, unlike other retinal ganglion cells, are intrinsically photosensitive due to the presence of melanopsin, a light-sensitive protein. Therefore, they constitute a third class of photoreceptors, in addition to rod and cone cells.
In neuroanatomy, the retinohypothalamic tract (RHT) is a photic neural input pathway involved in the circadian rhythms of mammals. The origin of the retinohypothalamic tract is the intrinsically photosensitive retinal ganglion cells (ipRGC), which contain the photopigment melanopsin. The axons of the ipRGCs belonging to the retinohypothalamic tract project directly, monosynaptically, to the suprachiasmatic nuclei (SCN) via the optic nerve and the optic chiasm. The suprachiasmatic nuclei receive and interpret information on environmental light, dark and day length, important in the entrainment of the "body clock". They can coordinate peripheral "clocks" and direct the pineal gland to secrete the hormone melatonin.
The visual cycle is a process in the retina that replenishes the molecule retinal for its use in vision. Retinal is the chromophore of most visual opsins, meaning it captures the photons to begin the phototransduction cascade. When the photon is absorbed, the 11-cis retinal photoisomerizes into all-trans retinal as it is ejected from the opsin protein. Each molecule of retinal must travel from the photoreceptor cell to the RPE and back in order to be refreshed and combined with another opsin. This closed enzymatic pathway of 11-cis retinal is sometimes called Wald's visual cycle after George Wald (1906–1997), who received the Nobel Prize in 1967 for his work towards its discovery.
Light effects on circadian rhythm are the response of circadian rhythms to light.
Mammals normally have a pair of eyes. Although mammalian vision is not so excellent as bird vision, it is at least dichromatic for most of mammalian species, with certain families possessing a trichromatic color perception.
Russell Grant Foster, CBE, FRS FMedSci is a British professor of circadian neuroscience, the Director of the Nuffield Laboratory of Ophthalmology and the Head of the Sleep and Circadian Neuroscience Institute (SCNi). He is also a Nicholas Kurti Senior Fellow at Brasenose College at the University of Oxford. Foster and his group are credited with key contributions to the discovery of the non-rod, non-cone, photosensitive retinal ganglion cells (pRGCs) in the mammalian retina which provide input to the circadian rhythm system. He has written and co-authored over a hundred scientific publications.
King-Wai Yau is a Chinese-born American neuroscientist and Professor of Neuroscience at Johns Hopkins University School of Medicine in Baltimore, Maryland.
Samer Hattar is a chronobiologist and a leader in the field of non-image forming photoreception. He is the Chief of the Section on Light and Circadian Rhythms at the National Institute of Mental Health, part of the National Institutes of Health. He was previously an associate professor in the Department of Neuroscience and the Department of Biology at Johns Hopkins University in Baltimore, MD. He is best known for his investigation into the role of melanopsin and intrinsically photosensitive retinal ganglion cells (ipRGC) in the entrainment of circadian rhythms.
Steve A. Kay is a British-born chronobiologist who mainly works in the United States. Dr. Kay has pioneered methods to monitor daily gene expression in real time and characterized circadian gene expression in plants, flies and mammals. In 2014, Steve Kay celebrated 25 years of successful chronobiology research at the Kaylab 25 Symposium, joined by over one hundred researchers with whom he had collaborated with or mentored. Dr. Kay, a member of the National Academy of Sciences, U.S.A., briefly served as president of The Scripps Research Institute. and is currently a professor at the University of Southern California. He also served on the Life Sciences jury for the Infosys Prize in 2011.
Vertebrate visual opsins are a subclass of ciliary opsins and mediate vision in vertebrates. They include the opsins in human rod and cone cells. They are often abbreviated to opsin, as they were the first opsins discovered and are still the most widely studied opsins.
In chronobiology, photoentrainment refers to the process by which an organism's biological clock, or circadian rhythm, synchronizes to daily cycles of light and dark in the environment. The mechanisms of photoentrainment differ from organism to organism. Photoentrainment plays a major role in maintaining proper timing of physiological processes and coordinating behavior within the natural environment. Studying organisms’ different photoentrainment mechanisms sheds light on how organisms may adapt to anthropogenic changes to the environment.
Tiffany M. Schmidt is an American researcher and chronobiologist, currently working as an associate professor of Neurobiology at Northwestern University. Schmidt, who works in Evanston, Illinois, studies the role of retinal ganglion cells (RGC) to determine how light can affect behavior, hormonal changes, vision, sleep, and circadian entrainment.
Russell Van Gelder is an American clinician-scientist and board-certified ophthalmologist; he has served as the chair of the University of Washington Medicine Department of Ophthalmology since 2008 and Editor-in-Chief of the journal Ophthalmology since 2022. He is known for his research on the mechanisms of uveitis, non-visual photoreception in the eye, and vision-restoration methods for retinal degenerative disease, as well as his leadership and advisory positions in various American ophthalmological and medical societies.