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DECIPHER

From Wikipedia, the free encyclopedia

This article is about the biological database. For other uses, see Decipher (disambiguation).
A segment of the human reference genome, viewed using Ensembl with the DECIPHER track enabled. Red bars represent individual mutations for anonymous patients with deletions across this region, while green bars represent patients with duplications across this region. The region shown encompasses the segment of chromosome missing in patients with 17q21.3 recurrent microdeletion syndrome.

DECIPHER is a web-based resource and database of genomic variation data from analysis of patient DNA.[1][2][3] It documents submicroscopic chromosome abnormalities (microdeletions and duplications) and pathogenic sequence variants (single nucleotide variants - SNVs, Insertions, Deletions, InDels), from over 25000 patients and maps them to the human genome using Ensembl or UCSC Genome Browser.[1][2][4] In addition it catalogues the clinical characteristics from each patient and maintains a database of microdeletion/duplication syndromes, together with links to relevant scientific reports and support groups.[1][5]

An acronym of DatabasE of Chromosomal Imbalance and Phenotype in Humans using Ensembl Resources, DECIPHER was initiated in 2004 at the Sanger Institute in the United Kingdom, funded by the Wellcome Trust.[1] However it is supported by an international research consortium, with patient data contributed by more than 240 clinical genetics centres from 33 countries. Each centre is represented by an experienced clinical geneticist and a senior molecular cytogeneticist.[6]

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  • How to Decipher an Ancient Script - Decipherment Club #1

Transcription

This ancient message took centuries to crack. We could always read this message. We still have no clue how to read this message. Why? What if history were hiding something from you? Would you want to know about it? Well, if you stick with me a few minutes, we’ll start getting you to think like a decipherer. Then you can join the club and hold a flickering lamp up to an old wall and with your perceptive gaze, nod slowly in enlightened appreciation of the symbols. I’ll bring the symbols and techniques. You’re buying the hat and the lamp, though. If you stay for this series, we’ll tell tales of decipherment that take us from the sands of Egypt through the Central American jungle to the middle of the Pacific. You’ll work alongside history’s great decoders and some crackpots in their relentless attempts to recover voices long vanished. We already saw what decipherment is not like: cryptography or cryptanalysis. But what is it yes like? Decipherment is something we do with a message we can’t read. That was a bit vague. Let’s go again. Decipherment is an operation performed on an unknown message, and it requires two components. First, a script, a writing system. These visual, etched, inked, carved, whatevered symbols that we’re eager to read, mocking us silently across the ages, are called glyphs. The meaningful units we’re trying to identify among these glyphs are called graphemes. The other thing we need is a language. If there’s no language underlying the symbols at all, there’s no linguistic message to decipher. Some claim this is true of the Indus Scripts or the Tartaria tablets. Before this video, you talked about decipherment the way people normally do: deciphering symbols to dig up the hidden ancient message inside of them. We built on that by admitting that we have to identify the message’s writing system and language to unearth its meaning. That’s our first understanding of decipherment. Let’s call it model #1. But if you’re joining our secret club, you have to change the way you look at decipherment. Decipherment binds certain language bits to certain writing bits, and sees if they coordinate, if the message reads naturally with that writing system and that language. Model #1… I really don’t like these names. Let’s see, this one has layers or kind of hidden guts? And this one is matching pieces? Hidden guts is more romantic, more oracular. But what happens when some hack decipherer comes along and challenges your reading? Hidden guts tells you to peer through the graphemic haze like a kind of seer-sage. Matching pieces invites you to compare texts and find a best fit. It even invites predictions when we find texts and more texts in the language. It’s a fresh starting point for thinking about how to decipher. But what can you decipher? What can’t you decipher? That's actually a great question for next time.

Aims

A schematic representation of a chromosome deletion. DECIPHER maps small deletions detected in patients to the reference genome produced by the Human Genome Project.

DECIPHER was established in 2004 by Nigel Carter of the Wellcome Trust Sanger Institute and Helen Firth, a clinical genetics consultant at Addenbrooke's Hospital in Cambridge. It has three main aims:[6][7]

  • Aid in the interpretation of plausibly pathogenic variants from genome- wide analyses by placing them in the context of known pathogenic variants, other plausibly pathogenic variants and population variation
  • Annotate plausibly pathogenic variants with their likely functional impact using Ensembl tools to compare sequence and structural variants with the latest functional annotation of the current human reference genome e.g. define which genes are involved in a specific copy number variant (microdeletion / microduplication) or for sequence variants, whether they are positioned within a gene or regulatory element.
  • Facilitate research into the study of genes that affect human health and development to improve diagnosis, management and therapy of rare diseases.

As a tool for clinical geneticists, cytogeneticists and molecular biologists, DECIPHER is used to determine whether gene copy number variations identified in patients are of clinical significance. Members can visualise the genes within the region of DNA altered in their patients, and ascertain whether any are known to be implicated in disease. Chromosomal imbalances are a major cause of developmental delay, learning disabilities and congenital abnormalities and — according to Emily Niemitz writing in Nature Genetics — the database facilitates collaboration between researchers and clinicians who have patients with similar clinical characteristics, which can "assist in the discovery of new syndromes and in the recognition of genes of clinical importance."[4][5]

Process

Patients are entered into DECIPHER by registered consortium members. Typically a clinical geneticist arranges for a chromosome analysis (usually microarray based) of a patient's DNA. A potential microdeletion/microduplication may be identified, but the medical significance is not known.[8] The clinician may enter the anonymised data into the restricted, password protected DECIPHER database and map the location and size of the chromosomal deletion/duplication to the reference genome. Using DECIPHER, the clinician can then identify the specific genes affected by the deletion/duplication, determine whether any have known clinical significance (for example, whether tumour suppressor genes have been deleted),[9] and view the region in the Ensembl genome browser to see whether there are any other consented patients in DECIPHER with overlapping deletion/duplications.[8] This enables a better ascertainment of whether a copy number change is a normal polymorphic variant, or the likely cause of the patient's clinical symptoms. The clinician can then counsel the patient on the likely significance of the deletion/duplication, and its implications for their health.[8]

Each patient's data is anonymized, and represented only by an ID with an associated genotype and set of clinical symptoms (phenotypes). Patient data is made accessible to other members of the consortium and viewable through Ensembl if a consent form is signed by the patient.[8] With informed consent, the anonymized deletion/duplication and phenotypes become available for view to DECIPHER consortium members and public users, with different levels of access (e.g. only logged users can see the contact details of the centre that entered the data). Public users who wish to find more information about a patient may send a request to DECIPHER, which then will forward it to the clinician coordinator responsible for the submitting center.

Most patients deposited in DECIPHER display genetic mutations with a very low occurrence in the general population. Hence the probability of the same clinicians encountering similar patients are also low. Since DECIPHER is opened to any accredited clinician or cytogeneticist from around the world, the chances of finding similar rare cases are significantly increased. This on-line sharing of clinical genetic information not only promotes better understanding of microdeletions/microduplications and their associated pathogenic phenotypes, it has also facilitated the discovery of new syndromes.[10][11][12][13] As of January 2014, over 23000 patients have been entered into the DECIPHER database of which over 10000 are consented.

Ethics and privacy

The appropriate consent to enter patient data into DECIPHER is obtained by the submitting clinician.[14] Patient consent can be withdrawn at any time, and their data is removed.[7] Often children's records are displayed with the consent of their parents of guardians. DECIPHER advises that, when the child reaches the age of sixteen years, he or she be made aware of the entry and be given the opportunity to withdraw or continue as a participant.[7] Each member centre that uses DECIPHER obtains ethical approval from a research ethics committee in their own institution or country, where applicable. In the UK, the Information Commissioner's Office has been notified about DECIPHER in accordance with the Data Protection Act 1998.[14] The project is overseen by an advisory board representatives from the field of human genetics, computational biology, ethics and law.[15]

To ensure information privacy, data is served over an encrypted TLS/SSL connection. Only trusted individuals from recognized medical research centres can access the identity of the center that submitted another patient (permitting them to contact the patient's clinicians should they wish to collaborate). Members of the public may browse consented anonymized patient data in DECIPHER and Ensembl, without the identity of the submitting centre being shown.[8][14]

See also

References

  1. ^ a b c d Firth HV, Richards SM, Bevan AP, Clayton S, Corpas M, et al. (April 2009). "DECIPHER: Database of Chromosomal Imbalance and Phenotype in Humans Using Ensembl Resources". Am. J. Hum. Genet. 84 (4): 524–33. doi:10.1016/j.ajhg.2009.03.010. PMC 2667985. PMID 19344873.
  2. ^ a b Swaminathan GJ; Bragin E; Chatzimichali EA; Corpas M; et al. (2012). "DECIPHER: web-based community resource for clinical interpretation of rare variants in developmental disorders". Hum. Mol. Genet. 21 (R1): R37–R44. doi:10.1093/hmg/dds362. PMC 3459644. PMID 22962312.
  3. ^ Bragin E; Chatzimichali EA"; et al. (2014). "DECIPHER: database for the interpretation of phenotype-linked plausibly pathogenic sequence and copy-number variation". Nucleic Acids Res. 42 (Database issue): D993–D1000. doi:10.1093/nar/gkt937. PMC 3965078. PMID 24150940.
  4. ^ a b Stewart, A; Brice, P; Burton, H (2007). Genetics, health care, and public policy: an introduction to public health genetics. Cambridge University Press. p. 159. ISBN 978-0-521-52907-5.
  5. ^ a b Niemitz, E (2009). "DECIPHERing chromosomal imbalances". Nature Genetics. 41 (5): 514. doi:10.1038/ng0509-514.
  6. ^ a b "About DECIPHER". Wellcome Trust Sanger Institute. Retrieved 12 February 2014.
  7. ^ a b c Firth, HV (January 2009). "Welcome to the DECIPHER database: An introduction for Families" (PDF). Wellcome Trust Sanger Institute. Retrieved 12 February 2014.[permanent dead link]
  8. ^ a b c d e Firth, HV. "Data Flow Chart for the DECIPHER Database" (PDF). Wellcome Trust Sanger Institute. Archived from the original (PDF) on 19 May 2015. Retrieved 12 February 2014.
  9. ^ Genes of established clinical significance, including those listed in OMIM, are highlighted as are imprinted genes.
  10. ^ Shaw-Smith C, Redon R, Rickman L, et al. (April 2004). "Microarray based comparative genomic hybridisation (array-CGH) detects submicroscopic chromosomal deletions and duplications in patients with learning disability/mental retardation and dysmorphic features". J. Med. Genet. 41 (4): 241–8. doi:10.1136/jmg.2003.017731. PMC 1735726. PMID 15060094.
  11. ^ Shaw-Smith C, Pittman AM, Willatt L, et al. (September 2006). "Microdeletion encompassing MAPT at chromosome 17q21.3 is associated with developmental delay and learning disability". Nat. Genet. 38 (9): 1032–7. doi:10.1038/ng1858. PMID 16906163. S2CID 38047848.
  12. ^ Zahir F, Firth HV, Baross A, et al. (September 2007). "Novel deletions of 14q11.2 associated with developmental delay, cognitive impairment and similar minor anomalies in three children". J. Med. Genet. 44 (9): 556–61. doi:10.1136/jmg.2007.050823. PMC 2597953. PMID 17545556.
  13. ^ Malan V, Raoul O, Firth HV, et al. (September 2009). "19q13.11 deletion syndrome: a novel clinically recognisable genetic condition identified by array comparative genomic hybridisation". J. Med. Genet. 46 (9): 635–40. doi:10.1136/jmg.2008.062034. PMID 19126570. S2CID 8491797.
  14. ^ a b c Firth, HV. "Ethical framework for DECIPHER" (PDF). Wellcome Trust Sanger Institute. Retrieved 24 June 2010.[permanent dead link]
  15. ^ "DECIPHER Advisory Board". Wellcome Trust Sanger Institute. Retrieved 24 June 2010.

External links

This page was last edited on 28 April 2023, at 22:24
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