Choroideremia

Choroideremia
Classification and external resources
Specialty ophthalmology
ICD-10 H31.2
ICD-9-CM 363.55
OMIM 303100
DiseasesDB 2619
MeSH D015794

Choroideremia /kɒˌrɔɪdˈrmi.ə/ (CHD) is a rare X-linked recessive inherited disorder giving rise to retinal disease and eventual blindness.

The disease results from degeneration of the choriocapillaris of the choroid and of the retinal pigment epithelium of the retina. It causes progressive loss of vision, almost exclusively in males. In childhood, night blindness is the most common first symptom. As the disease progresses, vision-loss results, frequently starting as an irregular ring that gradually expands, both in toward central vision and out toward the extreme periphery. Progression continues throughout the individual's life, but both the rate of change and the degree of visual loss are variable among those affected, even within the same family.

The affected tissues include the retinal pigment epithelium (RPE), which is the pigmented cell layer just outside the neurosensory retina that nourishes retinal visual cells;[1] the RPE overlies the retinal visual cells and is firmly attached to the underlying choroid,[1] where degeneration of the capillary lamina of choroid (choriocapillaris) is also observed. Photoreceptors of the RPE convert light into the electrical impulses that are transferred to the brain, where the images seen as a result are constructed; the vessels of the choriocapillaris provide oxygen and nutrients to the RPE and photoreceptor cells. In the early stages of CHD, the choroid and the retinal pigment epithelium begin to deteriorate, after which loss of photoreceptor occurs, leading to loss of vision. At a molecular level, the root cause of the disease is mutation leading to loss of a specific Rab escort protein 1 (REP1), which, with its partner REP2, are responsible for prenylation of Rab proteins, where the link between the build up of unprenylated Rab proteins and the developing blindness is not yet known.

Medical approaches to the disease have resulted in the application of a diagnostic test for CHD, and 2014 saw the onset of clinical trials for gene therapies using viral vector-borne RP1 gene constructs aimed at protection of cells not yet lost to the disease. In these early clinical studies, patients have consistently shown improvements during the course of study; persistence data are in the process of being gathered.

Pathophysiology and presentation

Choroideremia is caused by the deletion of the Rab escort protein 1 (REP1).[2] Rab escort protein 2 (REP2) is 75% identical and can to an extent compensate for the loss of REP1. Though the eye does express the REP2 protein (no cell could survive without some REP activity) evidently, in the eye, this is not enough. The REPs are essential for the prenylation of Rab proteins. Studies have shown that there is a build up of unprenylated Rab27 in lymphoblasts from choroideremia patients. The link between the build up of unprenylated Rab proteins and blindness is not known.

Generally, only males show symptoms of this disease. Initially a person suffering from choroideremia has night blindness, which begins in youth. As the disease progresses, a CHM sufferer loses their peripheral vision and depth perception, eventually losing all sight by middle age. In some cases, a severe loss of acuity and color perception become evident as the disease progresses.

Although this disease was thought to be limited to the eye, it has been shown that crystals in the leukocytes and fatty acid abnormalities are also present.[3]

Research

Diagnostic testing

There is a genetic blood test to diagnose choroideremia: it was created by Dr. Ian MacDonald at the University of Alberta. Free genetic testing is available for US and Canadian Residents, through the eyeGENE project. This is coordinated by the National Eye Institute, at the US National Institutes of Health.

In the United Kingdom, human gene therapy trials are underway: at Imperial College London (ICL), under the direction of Dr. Miguel Seabra; and at the Moorfields Eye Hospital, also in London, under the direction of Dr. Robert MacLaren.

In the United States, pre-clinical trial work is also underway: at the University of Pennsylvania, under the direction of Dr. Jean Bennett and Dr. Albert Maguire. Human clinical trials are expected to start in the US in 2014.

In Canada, Dr. Ian MacDonald is also conducting clinical trials at the University of Alberta.

The Choroideremia Research Foundation (CRF) is an international non-profit organization. For over ten years, it has been dedicated to raising awareness and securing funding for choroideremia research. It is currently funding pre-clinical trial work for Dr. Seabra and Dr. Bennett. Dr. Ian MacDonald serves on the board of directors for the CRF and receives funding from CRF-Canada; CRF-Canada also supports Dr. Seabra and Dr. Robert MacLaren, as does Fight for Sight (UK).

Therapeutics

Robert MacLaren, Professor of Ophthalmology at the University of Oxford, and leader of the Clinical Ophthalmology Research Group at the Nuffield Laboratory of Ophthalmology (NLO), part of the John Radcliffe Hospital, also in Oxford, has, with his colleagues, used a gene therapy protocol first attempted when he was at the Moorfields Eye Hospital in London[4]—to attempt to treat the choroideremic REP1 deficiency that leads to degeneration of the choriocapillaris and retinal pigment epithelium and loss of light sensitivity, and eventually, sight.[4][5]

The objectives of the protocol, funded by the U.K.'s Health Innovation Challenge Fund were to "assess the safety and tolerability of the AAV.REP1 vector" used to introduce the replacement REP1 gene, through its administration to the retinas of 12 choroideremia patients at 2 doses, and secondarily, to seek to observe therapeutic benefit during the study, and at a 24-month post-treatment time point, based on functional and anatomical tests to evaluate any "slowing down of… retinal degeneration" in treatment versus control groups.[6]

The work is an outgrowth of an earlier, promising gene therapy approach to treat Leber congenital amaurosis (LCA),[7] where this effort attempts to introduce new, functioning copies of the REP1 gene to the eye using an adenoviral vector, so to halt cell death associated with this deficiency; the trial gave initial, promising results in January 2014: all of the 6 patients in the treatment group (those receiving the gene replacement) had degeneration to varying degrees before the treatment, and all described vision improvement.[4][5][8][9] In 2016, researchers were optimistic that the positive results of 32 choroideremia patients treated over four and a half years with gene therapy in four countries could be long-lasting.[10]

Celebrities afflicted

A number of individuals in very visible public roles are afflicted, and some have been involved in fundraising efforts for the disease. The former UK Labour Member of Parliament Siôn Simon is a known sufferer. Comic and activist E.J. Scott, partner of Daredevil actress Deborah Ann Woll, also suffers from the disease, and is involved in regular fundraising efforts.[11][12]

References

  1. 1 2 B. Cassin; S. Solomon (2001). Dictionary of eye terminology. Gainesville, FL: Triad Pub. Co. pp. TBD. ISBN 0-937404-63-2.
  2. van den Hurk JA, Schwartz M, van Bokhoven H, van de Pol TJ, Bogerd L, Pinckers AJ, Bleeker-Wagemakers EM, Pawlowitzki IH, Rüther K, Ropers HH, Cremers FP (1997) Molecular basis of choroideremia (CHM): mutations involving the Rab escort protein-1 (REP-1) gene. Hum Mutat 9(2):110-117
  3. Zhang AY, Mysore N, Vali H, Koenekoop J, Cao SN, Li S, Ren H, Keser V, Lopez-Solache I, Siddiqui SN, Khan A, Mui J, Sears K, Dixon J, Schwartzentruber J, Majewski J, Braverman N, Koenekoop RK (2015) Choroideremia is a systemic disease With lymphocyte crystals and plasma lipid and RBC membrane abnormalities. Invest Ophthalmol Vis Sci. 56(13):8158-8165. doi: 10.1167/iovs.14-15751
  4. 1 2 3 Pallab Ghosh, 2011, "Health: Gene therapy used in a bid to save a man's sight," at BBC News (online), October 27, 2011, see , accessed 23 April 2015.
  5. 1 2 Abigail Beall, 2014, "Gene therapy restores sight in people with eye disease," New Scientist (online), January 16, 2014, see , accessed 23 April 2015.
  6. CT.gov, 2014, "Gene Therapy for Blindness Caused by Choroideremia (Sponsor:University of Oxford): NCT01461213," at ClinicalTrials.gov, see , accessed 23 April 2015.
  7. Ewen Callaway, 2008, "Gene therapy success 'reverses' blindness," New Scientist (online), April 28, 2008, see and and , accessed 23 April 2015.
  8. Hendrik P. N. Schollemail & José A Sahel, 2014, "Comment: Gene therapy arrives at the macula," Lancet, 383:1105 (March 29, 2014; online, January 16), DOI 10.1016/S0140-6736(14)60033-7, see , accessed 23 April 2015.
  9. MacLaren, R. E.; Groppe, M.; Barnard, A. R.; Cottriall, C. L.; Tolmachova, T.; Seymour, L.; Clark, K. R.; During, M. J.; Cremers, F. P. M.; Black, G. C. M.; Lotery, A. J.; Downes, S. M.; Webster, A. R.; Seabra, M. C. (2014). "Retinal gene therapy in patients with choroideremia: Initial findings from a phase 1/2 clinical trial". The Lancet. 383 (9923): 1129–37. doi:10.1016/S0140-6736(13)62117-0. PMID 24439297.
  10. Ghosh, Pallab (28 April 2016). "Gene therapy reverses sight loss and is long-lasting". BBC News, Science & Environmemt. Retrieved 29 April 2016.
  11. Bill Dwyre, 2013, "Though going blind, E.J. Scott keeps looking ahead, moving forward," L.A. Times (online), January 11, 2013, see , accessed 23 April 2015.
  12. E.J. Scott, 2015, "This is my 40: Running 7 continents in 1 year, blindfolded," at Crowdrise (online crowdsourcing), undated, see , accessed 23 April 2015.


Further reading

External links

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