Achromatopsia Explained

Thiadens . Alberta A.H.J. . Phan . T. My Lan . Zekveld-Vroon . Renate C. . Leroy . Bart P. . van den Born . L. Ingeborgh . Hoyng . Carel B. . Klaver . Caroline C.W. . Roosing . Susanne . Pott . Jan-Willem R. . van Schooneveld . Mary J. . van Moll-Ramirez . Norka . van Genderen . Maria M. . Boon . Camiel J.F. . den Hollander . Anneke I. . Bergen . Arthur A.B. . April 2012 . Clinical Course, Genetic Etiology, and Visual Outcome in Cone and Cone–Rod Dystrophy . Ophthalmology . 119 . 4 . 819–826 . 10.1016/j.ophtha.2011.10.011.

Achromatopsia
Synonym:Rod Monochromacy
Causes:Congenital malfunction of the Visual phototransduction pathway

Achromatopsia, also known as Rod monochromacy, is a medical syndrome that exhibits symptoms relating to five conditions, most notably monochromacy. Historically, the name referred to monochromacy in general, but now typically refers only to an autosomal recessive congenital color vision condition. The term is also used to describe cerebral achromatopsia, though monochromacy is usually the only common symptom. The conditions include: monochromatic color blindness, poor visual acuity, and day-blindness. The syndrome is also present in an incomplete form that exhibits milder symptoms, including residual color vision. Achromatopsia is estimated to affect 1 in 30,000 live births worldwide.

Signs and symptoms

The five symptoms associated with achromatopsia are:

  1. Color blindness – usually monochromacy
  2. Reduced visual acuity – uncorrectable with lenses
  3. Hemeralopia – with the subject exhibiting photophobia
  4. Nystagmus
  5. Iris operating abnormalities

The syndrome is typically first noticed in children around six months of age due to their photophobia or their nystagmus. The nystagmus becomes less noticeable with age but the other symptoms of the syndrome become more relevant as school age approaches. Visual acuity and stability of the eye motions generally improve during the first six to seven years of life – but remain near 20/200. Otherwise the syndrome is considered stationary and does not worsen with age.

If the light level during testing is optimized, achromats may achieve corrected visual acuity of 20/100 to 20/150 at lower light levels, regardless of the absence of color. The fundus of the eye appears completely normal.

Achromatopsia can be classified as complete or incomplete. In general, symptoms of incomplete achromatopsia are attenuated versions of those of complete achromatopsia. Individuals with incomplete achromatopsia have reduced visual acuity with or without nystagmus or photophobia. Incomplete achromats show only partial impairment of cone cell function.

Cause

Achromatopsia is sometimes called rod monochromacy (as opposed to blue cone monochromacy), as achromats exhibit a complete absence of cone cell activity via electroretinography in photopic lighting. There are at least four genetic causes of achromatopsia, two of which involve cyclic nucleotide-gated ion channels (ACHM2, ACHM3), a third involves the cone photoreceptor transducin (GNAT2, ACHM4), and the last remains unknown.

Known genetic causes of this include mutations in the cone cell cyclic nucleotide-gated ion channels CNGA3 (ACHM2)[1] and CNGB3 (ACHM3), the cone cell transducin, GNAT2 (ACHM4), subunits of cone phosphodiesterase PDE6C (ACHM5, OMIM 613093)[2] and PDEH (ACHM6, OMIM 610024), and ATF6 (ACHM7, OMIM 616517).

Pathophysiology

The hemeralopic aspect of achromatopsia can be diagnosed non-invasively using electroretinography. The response at low (scotopic) and median (mesopic) light levels will be normal but the response under high light level (photopic) conditions will be absent. The mesopic level is approximately a hundred times lower than the clinical level used for the typical high level electroretinogram. When as described; the condition is due to a saturation in the neural portion of the retina and not due to the absence of the photoreceptors per se.

In general, the molecular pathomechanism of achromatopsia is either the inability to properly control or respond to altered levels of cGMP; particularly important in visual perception as its level controls the opening of cyclic nucleotide-gated ion channels (CNGs). Decreasing the concentration of cGMP results in closure of CNGs and resulting hyperpolarization and cessation of glutamate release. Native retinal CNGs are composed of 2 α- and 2 β-subunits, which are CNGA3 and CNGB3, respectively, in cone cells. When expressed alone, CNGB3 cannot produce functional channels, whereas this is not the case for CNGA3. Coassembly of CNGA3 and CNGB3 produces channels with altered membrane expression, ion permeability (Na+ vs. K+ and Ca2+), relative efficacy of cAMP/cGMP activation, decreased outward rectification, current flickering, and sensitivity to block by L-cis-diltiazem.

Mutations tend to result in the loss of CNGB3 function or gain of function—often increased affinity for cGMP—of CNGA3. cGMP levels are controlled by the activity of the cone cell transducin, GNAT2. Mutations in GNAT2 tend to result in a truncated and, presumably, non-functional protein, thereby preventing alteration of cGMP levels by photons. There is a positive correlation between the severity of mutations in these proteins and the completeness of the achromatopsia phenotype.

Molecular diagnosis can be established by identification of biallelic variants in the causative genes. Molecular genetic testing approaches used in achromatopsia can include targeted analysis for the common CNGB3 variant c.1148delC (p.Thr383IlefsTer13), use of a multigenerational panel, or comprehensive genomic testing.

ACHM2

While some mutations in CNGA3 result in truncated and, presumably, non-functional channels this is largely not the case. While few mutations have received in-depth study, at least one mutation does result in functional channels. Curiously, this mutation, T369S, produces profound alterations when expressed without CNGB3. One such alteration is decreased affinity for Cyclic guanosine monophosphate. Others include the introduction of a sub-conductance, altered single-channel gating kinetics, and increased calcium permeability.

When mutant T369S channels coassemble with CNGB3, however, the only remaining aberration is increased calcium permeability.[3] While it is not immediately clear how this increase in Ca2+ leads to achromatopsia, one hypothesis is that this increased current decreases the signal-to-noise ratio. Other characterized mutations, such as Y181C and the other S1 region mutations, result in decreased current density due to an inability of the channel to traffic to the surface.[4] Such loss of function will undoubtedly negate the cone cell's ability to respond to visual input and produce achromatopsia. At least one other missense mutation outside of the S1 region, T224R, also leads to loss of function.

ACHM3

While very few mutations in CNGB3 have been characterized, the vast majority of them result in truncated channels that are presumably non-functional. This will largely result in haploinsufficiency, though in some cases the truncated proteins may be able to coassemble with wild-type channels in a dominant negative fashion. The most prevalent ACHM3 mutation, T383IfsX12, results in a non-functional truncated protein that does not properly traffic to the cell membrane.

The three missense mutations that have received further study show a number of aberrant properties, with one underlying theme. The R403Q mutation, which lies in the pore region of the channel, results in an increase in outward current rectification, versus the largely linear current-voltage relationship of wild-type channels, concomitant with an increase in cGMP affinity. The other mutations show either increased (S435F) or decreased (F525N) surface expression but also with increased affinity for cAMP and cGMP.[5] It is the increased affinity for cGMP and cAMP in these mutants that is likely the disorder-causing change. Such increased affinity will result in channels that are insensitive to the slight concentration changes of cGMP due to light input into the retina.

ACHM4

Upon activation by light, cone opsin causes the exchange of GDP for GTP in the guanine nucleotide binding protein (G-protein) α-transducing activity polypeptide 2 (GNAT2). This causes the release of the activated α-subunit from the inhibitory β/γ-subunits. This α-subunit then activates a phosphodiesterase that catalyzes the conversion of cGMP to GMP, thereby reducing current through CNG3 channels. As this process is absolutely vital for proper color processing it is not surprising that mutations in GNAT2 lead to achromatopsia. The known mutations in this gene, all result in truncated proteins. Presumably, then, these proteins are non-functional and, consequently, cone opsin that has been activated by light does not lead to altered cGMP levels or photoreceptor membrane hyperpolarization.

Management

Gene therapy

As achromatopsia is linked to only a few single-gene mutations, it is a good candidate for gene therapy. Gene therapy is a technique for injecting functional genes into the cells that need them, replacing or overruling the original alleles linked to achromatopsia, thereby curing it – at least in part. Achromatopsia has been a focus of gene therapy since 2010, when achromatopsia in dogs was partially cured. Several clinical trials on humans are ongoing with mixed results.[6] In July 2023, a study found positive but limited improvements on congenital CNGA3 achromatopsia.[7] [8]

Eyeborg

See main article: Eyeborg.

Since 2003, a cybernetic device called the eyeborg has allowed people to perceive color through sound waves. This form of Sensory substitution maps the hue perceived by a camera worn on the head to a pitch experienced through bone conduction according to a sonochromatic scale.[9] This allows achromats (or even the totally blind) to perceive – or estimate – the color of an object. Achromat and artist Neil Harbisson was the first to use the eyeborg in early 2004, which allowed him to start painting in color. He has since acted as a spokesperson for the technology, namely in a 2012 TED Talk. A 2015 study suggests that achromats who use the Eyeborg for several years exhibit neural plasticity, which indicates the sensory substitution has become intuitive for them.[10]

Other accommodations

While gene therapy and the Eyeborg may currently have low uptake with achromats, there are several more practical ways for achromats to manage their condition:

Epidemiology

Achromatopsia is a relatively uncommon disorder, with a prevalence of 1 in 30,000 people.[12]

However, on the small Micronesian atoll of Pingelap, approximately five percent of the atoll's 3,000 inhabitants are affected.[13] This is the result of a population bottleneck caused by a typhoon and ensuing famine in the 1770s, which killed all but about twenty islanders, including one who was heterozygous for achromatopsia.[14]

The people of this region have termed achromatopsia "maskun", which literally means "not see" in Pingelapese. This unusual population drew neurologist Oliver Sacks to the island for which he wrote his 1997 book, The Island of the Colorblind.[15]

Blue cone monochromacy

See main article: Blue cone monochromacy. Blue cone monochromacy (BCM) is another genetic condition causing monochromacy. It mimics many of the symptoms of incomplete achromatopsia and before the discovery of its molecular biological basis was commonly referred to as x-linked achromatopsia, sex-linked achromatopsia or atypical achromatopsia. BCM stems from mutations or deletions of the OPN1LW and OPN1MW genes, both on the X chromosome. As a recessive x-linked condition, BCM disproportionately affects males, unlike typical achromatopsia.

Cerebral achromatopsia

See main article: cerebral achromatopsia. Cerebral achromatopsia is a form of acquired color blindness that is caused by damage to the cerebral cortex. Damage is most commonly localized to visual area V4 of the visual cortex (the major part of the colour center), which receives information from the parvocellular pathway involved in color processing. It is most frequently caused by physical trauma, hemorrhage or tumor tissue growth.[16] If there is unilateral damage, a loss of color perception in only half of the visual field may result; this is known as hemiachromatopsia.[17] Cerebral achromats usually do not experience the other major symptoms of congenital achromatopsia, since photopic vision is still functions.

Color agnosia involves having difficulty recognizing colors, while still being able to perceive them as measured by a color matching or categorizing task.[18]

References

Sources

External links

Notes and References

  1. Kohl . Susanne . Marx . Tim . Giddings . Ian . Jägle . Herbert . Jacobson . Samuel G. . Apfelstedt-Sylla . Eckhart . Zrenner . Eberhart . Sharpe . Lindsay T. . Wissinger . Bernd . Total colourblindness is caused by mutations in the gene encoding the α-subunit of the cone photoreceptor cGMP-gated cation channel . Nature Genetics . July 1998 . 19 . 3 . 257–259 . 10.1038/935. 9662398 . 12040233 .
  2. Thiadens . Alberta A.H.J. . den Hollander . Anneke I. . Roosing . Susanne . Nabuurs . Sander B. . Zekveld-Vroon . Renate C. . Collin . Rob W.J. . De Baere . Elfride . Koenekoop . Robert K. . van Schooneveld . Mary J. . Strom . Tim M. . van Lith-Verhoeven . Janneke J.C. . Lotery . Andrew J. . van Moll-Ramirez . Norka . Leroy . Bart P. . van den Born . L. Ingeborgh . Hoyng . Carel B. . Cremers . Frans P.M. . Klaver . Caroline C.W. . Homozygosity Mapping Reveals PDE6C Mutations in Patients with Early-Onset Cone Photoreceptor Disorders . The American Journal of Human Genetics . August 2009 . 85 . 2 . 240–247 . 10.1016/j.ajhg.2009.06.016. 19615668 . 2725240 .
  3. Tränkner . Dimitri . Jägle . Herbert . Kohl . Susanne . Apfelstedt-Sylla . Eckart . Sharpe . Lindsay T. . Kaupp . U. Benjamin . Zrenner . Eberhart . Seifert . Reinhard . Wissinger . Bernd . 2004-01-07 . Molecular Basis of an Inherited Form of Incomplete Achromatopsia . The Journal of Neuroscience . 24 . 1 . 138–147 . 10.1523/JNEUROSCI.3883-03.2004 . 0270-6474 . 6729583 . 14715947.
  4. Patel . Kirti A. . Bartoli . Kristen M. . Fandino . Richard A. . Ngatchou . Anita N. . Woch . Gustaw . Carey . Jannette . Tanaka . Jacqueline C. . 2005-07-01 . Transmembrane S1 Mutations in CNGA3 from Achromatopsia 2 Patients Cause Loss of Function and Impaired Cellular Trafficking of the Cone CNG Channel . Investigative Opthalmology & Visual Science . 46 . 7 . 2282–2290 . 10.1167/iovs.05-0179 . 15980212 . 1552-5783.
  5. Peng . Changhong . Rich . Elizabeth D. . Varnum . Michael D. . 2003 . Achromatopsia-associated Mutation in the Human Cone Photoreceptor Cyclic Nucleotide-gated Channel CNGB3 Subunit Alters the Ligand Sensitivity and Pore Properties of Heteromeric Channels . Journal of Biological Chemistry . 278 . 36 . 34533–34540 . 10.1074/jbc.M305102200. free . 12815043 .
  6. Farahbakhsh . Mahtab . Anderson . Elaine J . Maimon-Mor . Roni O . Rider . Andy . Greenwood . John A . Hirji . Nashila . Zaman . Serena . Jones . Pete R . Schwarzkopf . D Samuel . Rees . Geraint . Michaelides . Michel . Dekker . Tessa M . A demonstration of cone function plasticity after gene therapy in achromatopsia . Brain . 24 August 2022 . 145 . 11 . 3803–3815 . 10.1093/brain/awac226. 35998912 . 9679164 .
  7. McKyton . Ayelet . Marks Ohana . Devora . Nahmany . Einav . Banin . Eyal . Levin . Netta . July 2023 . Seeing color following gene augmentation therapy in achromatopsia . Current Biology . 33 . 16 . 3489–3494.e2 . 10.1016/j.cub.2023.06.041. 37433300 . 2023CBio...33E3489M . 259504295 .
  8. Web site: Jackson . Justin . Xpress . Medical . Gene therapy to restore color vision in complete achromatopsia patients shows modest improvement . 2023-08-28 . medicalxpress.com .
  9. Book: Ronchi, Alfredo M. . eCulture . 2009 . Springer Berlin Heidelberg . 978-3-540-75273-8 . Berlin, Heidelberg . 10.1007/978-3-540-75276-9.
  10. Alfaro . Arantxa . Bernabeu . Ángela . Agulló . Carlos . Parra . Jaime . Fernández . Eduardo . Hearing colors: an example of brain plasticity . Frontiers in Systems Neuroscience . 14 April 2015 . 9 . 56 . 10.3389/fnsys.2015.00056. 25926778 . 4396351 . free .
  11. Web site: Windsor . Richard . Windsor . Laura . Driving Issues . achromatopsia.info . 21 October 2022 .
  12. Thiadens . Alberta A.H.J. . Phan . T. My Lan . Zekveld-Vroon . Renate C. . Leroy . Bart P. . van den Born . L. Ingeborgh . Hoyng . Carel B. . Klaver . Caroline C.W. . Roosing . Susanne . Pott . Jan-Willem R. . van Schooneveld . Mary J. . van Moll-Ramirez . Norka . van Genderen . Maria M. . Boon . Camiel J.F. . den Hollander . Anneke I. . Bergen . Arthur A.B. . 2012 . Clinical Course, Genetic Etiology, and Visual Outcome in Cone and Cone–Rod Dystrophy . Ophthalmology . 119 . 4 . 819–826 . 10.1016/j.ophtha.2011.10.011. 22264887 .
  13. Brody . Jacob A. . Hussels . Irena . Brink . Edward . Torres . Jose . 1970 . Hereditary blindness among Pingelapese people of Eastern Caroline Islands . The Lancet . 295 . 7659 . 1253–1257 . 10.1016/S0140-6736(70)91740-X.
  14. Sundin . Olof H. . Yang . Jun-Ming . Li . Yingying . Zhu . Danping . Hurd . Jane N. . Mitchell . Thomas N. . Silva . Eduardo D. . Maumenee . Irene Hussels . Genetic basis of total colourblindness among the Pingelapese islanders . Nature Genetics . 2000 . 25 . 3 . 289–293 . 10.1038/77162 . 10888875 . 22948732 . 18 August 2022.
  15. Book: Sacks . Oliver W. . The island of the colorblind; and Cycad island . 1997 . A.A. Knopf . New York . 473230128 . 18 August 2022.
  16. Bouvier . Seth E. . Engel . Stephen A. . 2006-02-01 . Behavioral Deficits and Cortical Damage Loci in Cerebral Achromatopsia . Cerebral Cortex . 16 . 2 . 183–191 . 10.1093/cercor/bhi096 . 15858161 . 1460-2199.
  17. Burns . Martha S. . 2004 . Clinical Management of Agnosia . Topics in Stroke Rehabilitation . 11 . 1 . 1–9 . 10.1310/N13K-YKYQ-3XX1-NFAV . 14872395 . 1074-9357.
  18. Zeki . Semir . Semir Zeki . 1990 . A century of cerebral achromatopsia . Brain . 113 . 6 . 1721–1777 . 10.1093/brain/113.6.1721 . 2276043 . 0006-8950.