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Nonsense mutation

January 01, 1970

In genetics, a nonsense mutation is a point mutation in a sequence of DNA that results in a nonsense codon, or a premature stop codon in the transcribed mRNA, and leads to a truncated, incomplete, and possibly nonfunctional protein product.[1] Nonsense mutations are not always harmful;[2] the functional effect of a nonsense mutation depends on many aspects, such as the location of the stop codon within the coding DNA.[2] For example, the effect of a nonsense mutation depends on the proximity of the nonsense mutation to the original stop codon, and the degree to which functional subdomains of the protein are affected.[3] As nonsense mutations leads to premature termination of polypeptide chains; they are also called chain termination mutations.[4]

Missense mutations differ from nonsense mutations since they are point mutations that exhibit a single nucleotide change to cause substitution of a different amino acid. A nonsense mutation also differs from a nonstop mutation, which is a point mutation that removes a stop codon. About 10% of patients facing genetic diseases have involvement with nonsense mutations.[5] Some of the diseases that these mutations can cause are Duchenne muscular dystrophy (DMD), cystic fibrosis (CF),[6] spinal muscular atrophy (SMA), cancers, metabolic diseases, and neurologic disorders.[5][7] The rate of nonsense mutations is variable from gene-to-gene and tissue-to-tissue, but gene silencing occurs in every patient with a nonsense mutation.[5]

Simple example edit 

 DNA: 5' - ATG ACT CAC CGA GCG CGA AGC TGA - 3' 3' - TAC TGA GTG GCT CGC GCT TCG ACT - 5' mRNA: 5' - AUG ACU CAC CGA GCG CGA AGC UGA - 3' Protein: Met Thr His Arg Ala Arg Ser Stop

The example above begins with a 5' DNA sequence with 24 nucleotides (8 triplet codons) seen and its complementary strand shown below. The next row highlights the 5' mRNA strand, which is generated through transcription. Lastly, the final row showcases which the amino acids that are translated from each respective codon, with the eighth and final codon representing the stop codon. The codons corresponding to the fourth amino acid, Arginine, are highlighted because they will undergo a nonsense mutation in the following figure of this example. 

 DNA: 5' - ATG ACT CAC TGA GCG CGA AGC TGA - 3' 3' - TAC TGA GTG ACT CGC GCT TCG ACT - 5' mRNA: 5' - AUG ACU CAC UGA GCG CGU AGC UGA - 3' Protein: Met Thr His Stop

Now, suppose that a nonsense mutation was introduced at the fourth codon in the 5' DNA sequence (CGA) causing the cytosine to be replaced with thymine, yielding TGA in the 5' DNA sequence and ACT in the complementary strand. Because ACT is transcribed as UGA, it is translated as a stop codon. This leads the remaining codons of the mRNA to not be translated into protein because the stop codon is prematurely reached during translation. This can yield a truncated (i.e., abbreviated) protein product, which quite often lacks the functionality of the normal, non-mutant protein.[1]

Possible outcomes edit

Deleterious edit

Deleterious outcomes represent the majority of nonsense mutations and are the most common outcome that is observed naturally. Deleterious nonsense mutations decreases the overall fitness and reproductive success of the organism.[8] For example, a nonsense mutation occurring in a gene encoding a protein can cause structural or functional defects in the protein that disrupt cellular biology. Depending on the significance of the functions of this protein, this disruption now could be detrimental to the fitness and survival of that organism.[8]

Neutral edit

When a nonsense mutation is neutral, it does not provide benefits or harm. These occur when the effects of the mutation are unnoticed. In other words, this means that the mutation does not positively or negatively affect the organism. As this effect is unnoticed, there is a lack of papers describing such mutations. An example of this type of nonsense mutation is one that occurs directly before the original stop codon for that given protein.[8] Because this mutation occurred in such close proximity to the end of the protein chain, the impact of this change might not be as significant. This would suggest that this amino acid that was mutated did not have a large impact on the overall structure or function of the protein or the organism as a whole. This scenario is rare, but possible.[8]

Beneficial edit

Beneficial nonsense mutations are considered as the rarest of possible nonsense mutation outcomes. Beneficial nonsense mutations increase the overall fitness and reproductive success of an organism, opposite of the effects of a deleterious mutation.[2][8] Because a nonsense mutation introduces a premature stop codon within a sequence of DNA, it is extremely unlikely that this scenario can actually benefit the organism.[1] An example of this would occur with a nonsense mutation that impacts a dysfunctional protein that releases toxins. The stop codon that this mutation brings would stop this dysfunctional protein from properly carrying out its function. Stopping this protein from performing at full strength causes less toxin to be released and the fitness of the organism to be improved. These types of situations with nonsense mutations occur a lot less frequently than the deleterious outcomes.[8]

Suppressing nonsense mutations edit

 
Pictured on the left is a diagram of normal translation occurring without mutation. Blue circles are the peptides already translated while the grey circles are peptides going to be translated next. In the center is a diagram a nonsense mutation where the UUG codon is translated to the stop codon UAG. The stop codon recruits a release factor, terminating translation. On the right is a diagram of the tRNA suppression mechanism where the codon and the tRNA are both mutated, resulting in tRNA suppression. The mutated Tyr tRNA has the anticodon AUC which recognizes the UAG stop codon, continuing protein translation.[9]

Nonsense-mediated mRNA decay

Despite an expected tendency for premature termination codons to yield shortened polypeptide products, in fact the formation of truncated proteins does not occur often in vivo. Many organisms—including humans and lower species, such as yeast—employ a nonsense-mediated mRNA decay pathway, which degrades mRNAs containing nonsense mutations before they are able to be translated into nonfunctional polypeptides.

tRNA Suppression

Because nonsense mutations result in altered mRNA with a premature stop codon, one way of suppressing the damage done to the final protein's function is to alter the tRNA that reads the mRNA. These tRNA’s are termed suppressor tRNA's. If the stop codon is UAG, any other amino acid tRNA could be altered from its original anticodon to AUC so it will recognize the UAG codon instead. This will result in the protein not being truncated, but it may still have an altered amino acid. These suppressor tRNA mutations are only possible if the cell has more than one tRNA that reads a particular codon, otherwise the mutation would kill the cell. The only stop codons are UAG, UAA, and UGA. UAG and UAA suppressors read their respective stop codons instead of their original codon, but UAA suppressors also read UAG due to wobble base pairing. UGA suppressors are very rare. Another hurdle to pass in this technique is the fact that stop codons are also recognized by release factors, so the tRNA still needs to compete with the release factors to keep the translation going. Because of this, suppression is usually only 10-40% successful. These suppressor tRNA mutations also target stop codons that are not mutations, causing some proteins to be much longer than they should be. Only bacteria and lower eukaryotes can survive with these mutations, mammal and insect cells die as a result of a suppressor mutation.[4]

For historical reasons the three stop codons were given names (see Stop codons): UAG is called the amber codon, UAA is called the ochre codon, and UGA is called the opal codon.

Common disease-associated nonsense mutations edit

 
Selection of notable mutations, ordered in a standard table of the genetic code of amino acids.[10] nonsense mutations are marked by red arrows.

Nonsense mutations comprise around 20% of single nucleotide substitutions within protein coding sequences that result in human disease.[11] Nonsense mutation-mediated pathology is often attributed to reduced amounts of full-length protein, because only 5-25% of transcripts possessing nonsense mutations do not undergo nonsense-mediated decay (NMD).[12][11] Translation of the remaining nonsense-bearing mRNA may generate abbreviated protein variants with toxic effects.[13]

Twenty-three different single-point nucleotide substitutions are capable of converting a non-stop codon into a stop-codon, with the mutations CGA TGA and CAG TAG being the most common disease-related substitutions characterized in the Human Gene Mutation Database (HGMD).[11] As a result of different substitution frequencies for each nucleotide, the proportions of the three stop codons generated by disease-inducing nonsense mutations differs from stop codon distributions in non-diseased gene variants.[11] Notably, the codon TAG is overrepresented, while the TGA and TAA codons are underrepresented in disease-related nonsense mutations.[11]

Translation termination efficiency is influenced by the specific stop codon sequence on the mRNA, with the UAA sequence yielding the highest termination.[14] Sequences surrounding the stop codon also impact termination efficiency.[14] Consequently, the underlying pathology of diseases caused by nonsense mutations is ultimately dependent on the identity of the mutated gene, and specific location of the mutation.

Examples of diseases induced by nonsense mutations include:

Nonsense mutations in other genes may also drive dysfunction of several tissue or organ systems:

SMAD8

SMAD8 is the eighth homolog of the ENDOGLIN gene family and is involved in the signaling between TGF-b/BMP. It has been identified that novel nonsense mutations in SMAD8 are associated with pulmonary arterial hypertension.[15] The pulmonary system relies on SMAD1, SMAD5, and SMAD 8 to regulate pulmonary vascular function. Downregulation and loss of signals that are normally operated by SMAD8 contributed to pathogenesis in pulmonary arterial hypertension.[15] The ALK1 gene, a part of the TGF-B signaling family, was found to have been mutated while also down-regulating the SMAD8 gene in patients with pulmonary arterial hypertension.[15] SMAD8 mutants were not phosphorylated by ALK1, disrupting interactions with SMAD4 that would normally allow for signaling in wild-type organisms.[15]

LGR4 edit

LGR4 binds R-spondins to activate the Wnt signaling pathway.[16] Wnt signaling regulates bone mass and osteoblast differentiation and is important for the development of bone, heart, and muscle.[16] An LGR4 nonsense mutation in a healthy population has been linked to low bone mass density and symptoms of osteoporosis. LGR4 mutant mice showed the observed low bone mass is not due to age-related bone loss.[16] Mutations in LGR4 have been associated with family lineages with medical histories of rare bone disorders.[16] Wild-type mice lacking LGR4 also displayed delayed osteoblast differentiation during development, showcasing the important role of LGR4 in bone mass regulation and development.[16]

Therapeutics targeting nonsense mutation diseases edit

Therapeutics for diseases caused by nonsense mutations attempt to recapitulate wild-type function by decreasing the efficacy of NMD, facilitating readthrough of the premature stop codon during translation, or editing the genomic nonsense mutation.[17]

Antisense oligonucleotides to suppress the expression of NMD and translation termination proteins are being explored in animal models of nonsense mutation-induced disease.[17][18] Other RNA therapeutics under investigation include synthetic suppressor tRNAs that enable ribosomes to insert an amino acid, instead of initiating chain termination, upon encountering premature stop codons.[17]

CRISPR-Cas9 based single nucleotide substitutions have been used to generate amino acid codons from stop codons, achieving an editing success rate of 10% in cell cultures.[19]

Read-through has been achieved using small molecule drugs such as aminoglycosides and negamycin.[17] An oxadiazole, ataluren (previously PTC124), facilitates the selective read-through of aberrant stop codons, rendering it a potential therapeutic against nonsense mutation-induced disease.[20] Ataluren, sold under the tradename Translarna, is currently an approved treatment for Duchenne muscular dystrophy in the European Economic area and Brazil.[21][22] However, phase III trials of Ataluren as a cystic fibrosis therapeutic have failed to meet their primary endpoints.[23][24]

See also edit

External links and references edit

  1. ^ a b c Sharma, Jyoti; Keeling, Kim M.; Rowe, Steven M. (2020-08-15). "Pharmacological approaches for targeting cystic fibrosis nonsense mutations". European Journal of Medicinal Chemistry. 200: 112436. doi:10.1016/j.ejmech.2020.112436. ISSN 0223-5234. PMC 7384597. PMID 32512483.
  2. ^ a b c Potapova, Nadezhda A. (2022-05-01). "Nonsense Mutations in Eukaryotes". Biochemistry (Moscow). 87 (5): 400–412. doi:10.1134/S0006297922050029. ISSN 1608-3040. PMID 35790376. S2CID 248793651.
  3. ^ Balasubramanian, Suganthi; Fu, Yao; Pawashe, Mayur; McGillivray, Patrick; Jin, Mike; Liu, Jeremy; Karczewski, Konrad J.; MacArthur, Daniel G.; Gerstein, Mark (2017-08-29). "Using ALoFT to determine the impact of putative loss-of-function variants in protein-coding genes". Nature Communications. 8 (1): 382. Bibcode:2017NatCo...8..382B. doi:10.1038/s41467-017-00443-5. ISSN 2041-1723. PMC 5575292. PMID 28851873.
  4. ^ a b Clark, David P.; Pazdernik, Nanette J.; McGehee, Michelle R. (2019), "Mutations and Repair", Molecular Biology, Elsevier, pp. 832–879, doi:10.1016/b978-0-12-813288-3.00026-4, ISBN 9780128132883, S2CID 239340633, retrieved 2022-12-02
  5. ^ a b c "Nonsense mutation correction in human diseases an approach for targeted medicine | WorldCat.org". www.worldcat.org. Retrieved 2022-12-02.
  6. ^ Guimbellot, Jennifer; Sharma, Jyoti; Rowe, Steven M. (November 2017). "Toward inclusive therapy with CFTR modulators: Progress and challenges". Pediatric Pulmonology. 52 (Suppl 48): S4–S14. doi:10.1002/ppul.23773. ISSN 8755-6863. PMC 6208153. PMID 28881097.
  7. ^ Benhabiles, Hana; Jia, Jieshuang; Lejeune, Fabrice (2016-01-01), Benhabiles, Hana; Jia, Jieshuang; Lejeune, Fabrice (eds.), "Chapter 2 - Pathologies Susceptible to be Targeted for Nonsense Mutation Therapies", Nonsense Mutation Correction in Human Diseases, Boston: Academic Press, pp. 77–105, ISBN 978-0-12-804468-1, retrieved 2022-12-02
  8. ^ a b c d e f Editors, B. D. (2018-08-26). "Nonsense Mutation - Definition, Example, Outcomes". Biology Dictionary. Retrieved 2022-12-02. {{cite web}}: |last= has generic name (help)
  9. ^ Murgola, Emanuel J. (December 1985). "tRNA, SUPPRESSION, AND THE CODE". Annual Review of Genetics. 19 (1): 57–80. doi:10.1146/annurev.ge.19.120185.000421. ISSN 0066-4197. PMID 2417544.
  10. ^ References for the image are found in Wikimedia Commons page at: Commons:File:Notable mutations.svg#References.
  11. ^ a b c d e Mort, Matthew; Ivanov, Dobril; Cooper, David N.; Chuzhanova, Nadia A. (August 2008). "A meta-analysis of nonsense mutations causing human genetic disease". Human Mutation. 29 (8): 1037–1047. doi:10.1002/humu.20763. PMID 18454449. S2CID 205918343.
  12. ^ Isken, Olaf; Maquat, Lynne E. (2007-08-01). "Quality control of eukaryotic mRNA: safeguarding cells from abnormal mRNA function". Genes & Development. 21 (15): 1833–1856. doi:10.1101/gad.1566807. ISSN 0890-9369. PMID 17671086.
  13. ^ Khajavi, Mehrdad; Inoue, Ken; Lupski, James R. (October 2006). "Nonsense-mediated mRNA decay modulates clinical outcome of genetic disease". European Journal of Human Genetics. 14 (10): 1074–1081. doi:10.1038/sj.ejhg.5201649. ISSN 1476-5438. PMID 16757948. S2CID 3450423.
  14. ^ a b Keeling, Kim M.; Du, Ming; Bedwell, David M. (2013). Therapies of Nonsense-Associated Diseases. Landes Bioscience.
  15. ^ a b c d Shintani, M; Yagi, H; Nakayama, T; Saji, T; Matsuoka, R (2009-05-01). "A new nonsense mutation of SMAD8 associated with pulmonary arterial hypertension". Journal of Medical Genetics. 46 (5): 331–337. doi:10.1136/jmg.2008.062703. ISSN 0022-2593. PMID 19211612. S2CID 44932041.
  16. ^ a b c d e Styrkarsdottir, Unnur; Thorleifsson, Gudmar; Sulem, Patrick; Gudbjartsson, Daniel F.; Sigurdsson, Asgeir; Jonasdottir, Aslaug; Jonasdottir, Adalbjorg; Oddsson, Asmundur; Helgason, Agnar; Magnusson, Olafur T.; Walters, G. Bragi; Frigge, Michael L.; Helgadottir, Hafdis T.; Johannsdottir, Hrefna; Bergsteinsdottir, Kristin (2013-05-23). "Nonsense mutation in the LGR4 gene is associated with several human diseases and other traits". Nature. 497 (7450): 517–520. Bibcode:2013Natur.497..517S. doi:10.1038/nature12124. ISSN 0028-0836. PMID 23644456. S2CID 205233843.
  17. ^ a b c d Morais, Pedro; Adachi, Hironori; Yu, Yi-Tao (2020-06-20). "Suppression of Nonsense Mutations by New Emerging Technologies". International Journal of Molecular Sciences. 21 (12): 4394. doi:10.3390/ijms21124394. ISSN 1422-0067. PMC 7352488. PMID 32575694.
  18. ^ Huang, Lulu; Aghajan, Mariam; Quesenberry, Tianna; Low, Audrey; Murray, Susan F.; Monia, Brett P.; Guo, Shuling (August 2019). "Targeting Translation Termination Machinery with Antisense Oligonucleotides for Diseases Caused by Nonsense Mutations". Nucleic Acid Therapeutics. 29 (4): 175–186. doi:10.1089/nat.2019.0779. ISSN 2159-3345. PMC 6686700. PMID 31070517.
  19. ^ Lee, Choongil; Hyun Jo, Dong; Hwang, Gue-Ho; Yu, Jihyeon; Kim, Jin Hyoung; Park, Se-eun; Kim, Jin-Soo; Kim, Jeong Hun; Bae, Sangsu (2019-08-07). "CRISPR-Pass: Gene Rescue of Nonsense Mutations Using Adenine Base Editors". Molecular Therapy. 27 (8): 1364–1371. doi:10.1016/j.ymthe.2019.05.013. ISSN 1525-0016. PMC 6698196. PMID 31164261.
  20. ^ Welch, Ellen M.; Barton, Elisabeth R.; Zhuo, Jin; Tomizawa, Yuki; Friesen, Westley J.; Trifillis, Panayiota; Paushkin, Sergey; Patel, Meenal; Trotta, Christopher R.; Hwang, Seongwoo; Wilde, Richard G.; Karp, Gary; Takasugi, James; Chen, Guangming; Jones, Stephen (2007-05-03). "PTC124 targets genetic disorders caused by nonsense mutations". Nature. 447 (7140): 87–91. Bibcode:2007Natur.447...87W. doi:10.1038/nature05756. ISSN 1476-4687. PMID 17450125. S2CID 4423529.
  21. ^ "PTC Therapeutics". PTC Therapeutics | Measured by Moments. Retrieved 2022-12-01.
  22. ^ "ANVISA approves PTC Translarna indication expansion to ambulatory children". Pharmaceutical Technology. 2021-10-26. Retrieved 2022-12-01.
  23. ^ Kerem, Eitan; Konstan, Michael W; De Boeck, Kris; Accurso, Frank J; Sermet-Gaudelus, Isabelle; Wilschanski, Michael; Elborn, J Stuart; Melotti, Paola; Bronsveld, Inez (2014-07-01). "Ataluren for the treatment of nonsense-mutation cystic fibrosis: a randomised, double-blind, placebo-controlled phase 3 trial". The Lancet Respiratory Medicine. 2 (7): 539–547. doi:10.1016/S2213-2600(14)70100-6. PMC 4154311. PMID 24836205.
  24. ^ Konstan, M. W.; VanDevanter, D. R.; Rowe, S. M.; Wilschanski, M.; Kerem, E.; Sermet-Gaudelus, I.; DiMango, E.; Melotti, P.; McIntosh, J.; De Boeck, K.; ACT CF Study Group (July 2020). "Efficacy and safety of ataluren in patients with nonsense-mutation cystic fibrosis not receiving chronic inhaled aminoglycosides: The international, randomized, double-blind, placebo-controlled Ataluren Confirmatory Trial in Cystic Fibrosis (ACT CF)". Journal of Cystic Fibrosis. 19 (4): 595–601. doi:10.1016/j.jcf.2020.01.007. ISSN 1873-5010. PMC 9167581. PMID 31983658.

External links edit

  • Nonsense mutation foundation, supporting nonsense mutation patients across all genes

January 01, 1970
nonsense, mutation, genetics, nonsense, mutation, point, mutation, sequence, that, results, nonsense, codon, premature, stop, codon, transcribed, mrna, leads, truncated, incomplete, possibly, nonfunctional, protein, product, always, harmful, functional, effect. In genetics a nonsense mutation is a point mutation in a sequence of DNA that results in a nonsense codon or a premature stop codon in the transcribed mRNA and leads to a truncated incomplete and possibly nonfunctional protein product 1 Nonsense mutations are not always harmful 2 the functional effect of a nonsense mutation depends on many aspects such as the location of the stop codon within the coding DNA 2 For example the effect of a nonsense mutation depends on the proximity of the nonsense mutation to the original stop codon and the degree to which functional subdomains of the protein are affected 3 As nonsense mutations leads to premature termination of polypeptide chains they are also called chain termination mutations 4 Missense mutations differ from nonsense mutations since they are point mutations that exhibit a single nucleotide change to cause substitution of a different amino acid A nonsense mutation also differs from a nonstop mutation which is a point mutation that removes a stop codon About 10 of patients facing genetic diseases have involvement with nonsense mutations 5 Some of the diseases that these mutations can cause are Duchenne muscular dystrophy DMD cystic fibrosis CF 6 spinal muscular atrophy SMA cancers metabolic diseases and neurologic disorders 5 7 The rate of nonsense mutations is variable from gene to gene and tissue to tissue but gene silencing occurs in every patient with a nonsense mutation 5 Contents 1 Simple example 2 Possible outcomes 2 1 Deleterious 2 2 Neutral 2 3 Beneficial 3 Suppressing nonsense mutations 4 Common disease associated nonsense mutations 4 1 LGR4 5 Therapeutics targeting nonsense mutation diseases 6 See also 7 External links and references 8 External linksSimple example editDNA 5 ATG ACT CAC CGA GCG CGA AGC TGA 3 3 TAC TGA GTG GCT CGC GCT TCG ACT 5 mRNA 5 AUG ACU CAC CGA GCG CGA AGC UGA 3 Protein Met Thr His Arg Ala Arg Ser Stop The example above begins with a 5 DNA sequence with 24 nucleotides 8 triplet codons seen and its complementary strand shown below The next row highlights the 5 mRNA strand which is generated through transcription Lastly the final row showcases which the amino acids that are translated from each respective codon with the eighth and final codon representing the stop codon The codons corresponding to the fourth amino acid Arginine are highlighted because they will undergo a nonsense mutation in the following figure of this example DNA 5 ATG ACT CAC TGA GCG CGA AGC TGA 3 3 TAC TGA GTG ACT CGC GCT TCG ACT 5 mRNA 5 AUG ACU CAC UGA GCG CGU AGC UGA 3 Protein Met Thr His Stop Now suppose that a nonsense mutation was introduced at the fourth codon in the 5 DNA sequence CGA causing the cytosine to be replaced with thymine yielding TGA in the 5 DNA sequence and ACT in the complementary strand Because ACT is transcribed as UGA it is translated as a stop codon This leads the remaining codons of the mRNA to not be translated into protein because the stop codon is prematurely reached during translation This can yield a truncated i e abbreviated protein product which quite often lacks the functionality of the normal non mutant protein 1 Possible outcomes editDeleterious edit Deleterious outcomes represent the majority of nonsense mutations and are the most common outcome that is observed naturally Deleterious nonsense mutations decreases the overall fitness and reproductive success of the organism 8 For example a nonsense mutation occurring in a gene encoding a protein can cause structural or functional defects in the protein that disrupt cellular biology Depending on the significance of the functions of this protein this disruption now could be detrimental to the fitness and survival of that organism 8 Neutral edit When a nonsense mutation is neutral it does not provide benefits or harm These occur when the effects of the mutation are unnoticed In other words this means that the mutation does not positively or negatively affect the organism As this effect is unnoticed there is a lack of papers describing such mutations An example of this type of nonsense mutation is one that occurs directly before the original stop codon for that given protein 8 Because this mutation occurred in such close proximity to the end of the protein chain the impact of this change might not be as significant This would suggest that this amino acid that was mutated did not have a large impact on the overall structure or function of the protein or the organism as a whole This scenario is rare but possible 8 Beneficial edit Beneficial nonsense mutations are considered as the rarest of possible nonsense mutation outcomes Beneficial nonsense mutations increase the overall fitness and reproductive success of an organism opposite of the effects of a deleterious mutation 2 8 Because a nonsense mutation introduces a premature stop codon within a sequence of DNA it is extremely unlikely that this scenario can actually benefit the organism 1 An example of this would occur with a nonsense mutation that impacts a dysfunctional protein that releases toxins The stop codon that this mutation brings would stop this dysfunctional protein from properly carrying out its function Stopping this protein from performing at full strength causes less toxin to be released and the fitness of the organism to be improved These types of situations with nonsense mutations occur a lot less frequently than the deleterious outcomes 8 Suppressing nonsense mutations edit nbsp Pictured on the left is a diagram of normal translation occurring without mutation Blue circles are the peptides already translated while the grey circles are peptides going to be translated next In the center is a diagram a nonsense mutation where the UUG codon is translated to the stop codon UAG The stop codon recruits a release factor terminating translation On the right is a diagram of the tRNA suppression mechanism where the codon and the tRNA are both mutated resulting in tRNA suppression The mutated Tyr tRNA has the anticodon AUC which recognizes the UAG stop codon continuing protein translation 9 Nonsense mediated mRNA decayDespite an expected tendency for premature termination codons to yield shortened polypeptide products in fact the formation of truncated proteins does not occur often in vivo Many organisms including humans and lower species such as yeast employ a nonsense mediated mRNA decay pathway which degrades mRNAs containing nonsense mutations before they are able to be translated into nonfunctional polypeptides tRNA SuppressionBecause nonsense mutations result in altered mRNA with a premature stop codon one way of suppressing the damage done to the final protein s function is to alter the tRNA that reads the mRNA These tRNA s are termed suppressor tRNA s If the stop codon is UAG any other amino acid tRNA could be altered from its original anticodon to AUC so it will recognize the UAG codon instead This will result in the protein not being truncated but it may still have an altered amino acid These suppressor tRNA mutations are only possible if the cell has more than one tRNA that reads a particular codon otherwise the mutation would kill the cell The only stop codons are UAG UAA and UGA UAG and UAA suppressors read their respective stop codons instead of their original codon but UAA suppressors also read UAG due to wobble base pairing UGA suppressors are very rare Another hurdle to pass in this technique is the fact that stop codons are also recognized by release factors so the tRNA still needs to compete with the release factors to keep the translation going Because of this suppression is usually only 10 40 successful These suppressor tRNA mutations also target stop codons that are not mutations causing some proteins to be much longer than they should be Only bacteria and lower eukaryotes can survive with these mutations mammal and insect cells die as a result of a suppressor mutation 4 For historical reasons the three stop codons were given names see Stop codons UAG is called the amber codon UAA is called the ochre codon and UGA is called the opal codon Common disease associated nonsense mutations edit nbsp Selection of notable mutations ordered in a standard table of the genetic code of amino acids 10 nonsense mutations are marked by red arrows Nonsense mutations comprise around 20 of single nucleotide substitutions within protein coding sequences that result in human disease 11 Nonsense mutation mediated pathology is often attributed to reduced amounts of full length protein because only 5 25 of transcripts possessing nonsense mutations do not undergo nonsense mediated decay NMD 12 11 Translation of the remaining nonsense bearing mRNA may generate abbreviated protein variants with toxic effects 13 Twenty three different single point nucleotide substitutions are capable of converting a non stop codon into a stop codon with the mutations CGA displaystyle longrightarrow nbsp TGA and CAG displaystyle longrightarrow nbsp TAG being the most common disease related substitutions characterized in the Human Gene Mutation Database HGMD 11 As a result of different substitution frequencies for each nucleotide the proportions of the three stop codons generated by disease inducing nonsense mutations differs from stop codon distributions in non diseased gene variants 11 Notably the codon TAG is overrepresented while the TGA and TAA codons are underrepresented in disease related nonsense mutations 11 Translation termination efficiency is influenced by the specific stop codon sequence on the mRNA with the UAA sequence yielding the highest termination 14 Sequences surrounding the stop codon also impact termination efficiency 14 Consequently the underlying pathology of diseases caused by nonsense mutations is ultimately dependent on the identity of the mutated gene and specific location of the mutation Examples of diseases induced by nonsense mutations include Cystic fibrosis caused by the G542X mutation in the cystic fibrosis transmembrane conductance regulator CFTR Beta thalassaemia b globin Hurler syndrome Dravet syndrome Usher syndrome Nonsense mutations in other genes may also drive dysfunction of several tissue or organ systems SMAD8SMAD8 is the eighth homolog of the ENDOGLIN gene family and is involved in the signaling between TGF b BMP It has been identified that novel nonsense mutations in SMAD8 are associated with pulmonary arterial hypertension 15 The pulmonary system relies on SMAD1 SMAD5 and SMAD 8 to regulate pulmonary vascular function Downregulation and loss of signals that are normally operated by SMAD8 contributed to pathogenesis in pulmonary arterial hypertension 15 The ALK1 gene a part of the TGF B signaling family was found to have been mutated while also down regulating the SMAD8 gene in patients with pulmonary arterial hypertension 15 SMAD8 mutants were not phosphorylated by ALK1 disrupting interactions with SMAD4 that would normally allow for signaling in wild type organisms 15 LGR4 edit LGR4 binds R spondins to activate the Wnt signaling pathway 16 Wnt signaling regulates bone mass and osteoblast differentiation and is important for the development of bone heart and muscle 16 An LGR4 nonsense mutation in a healthy population has been linked to low bone mass density and symptoms of osteoporosis LGR4 mutant mice showed the observed low bone mass is not due to age related bone loss 16 Mutations in LGR4 have been associated with family lineages with medical histories of rare bone disorders 16 Wild type mice lacking LGR4 also displayed delayed osteoblast differentiation during development showcasing the important role of LGR4 in bone mass regulation and development 16 Therapeutics targeting nonsense mutation diseases editTherapeutics for diseases caused by nonsense mutations attempt to recapitulate wild type function by decreasing the efficacy of NMD facilitating readthrough of the premature stop codon during translation or editing the genomic nonsense mutation 17 Antisense oligonucleotides to suppress the expression of NMD and translation termination proteins are being explored in animal models of nonsense mutation induced disease 17 18 Other RNA therapeutics under investigation include synthetic suppressor tRNAs that enable ribosomes to insert an amino acid instead of initiating chain termination upon encountering premature stop codons 17 CRISPR Cas9 based single nucleotide substitutions have been used to generate amino acid codons from stop codons achieving an editing success rate of 10 in cell cultures 19 Read through has been achieved using small molecule drugs such as aminoglycosides and negamycin 17 An oxadiazole ataluren previously PTC124 facilitates the selective read through of aberrant stop codons rendering it a potential therapeutic against nonsense mutation induced disease 20 Ataluren sold under the tradename Translarna is currently an approved treatment for Duchenne muscular dystrophy in the European Economic area and Brazil 21 22 However phase III trials of Ataluren as a cystic fibrosis therapeutic have failed to meet their primary endpoints 23 24 See also editEmily s Entourage a cystic fibrosis nonprofit researching nonsense mutations Missense mRNA Nonsense suppressor Protein truncating variantsExternal links and references edit a b c Sharma Jyoti Keeling Kim M Rowe Steven M 2020 08 15 Pharmacological approaches for targeting cystic fibrosis nonsense mutations European Journal of Medicinal Chemistry 200 112436 doi 10 1016 j ejmech 2020 112436 ISSN 0223 5234 PMC 7384597 PMID 32512483 a b c Potapova Nadezhda A 2022 05 01 Nonsense Mutations in Eukaryotes Biochemistry Moscow 87 5 400 412 doi 10 1134 S0006297922050029 ISSN 1608 3040 PMID 35790376 S2CID 248793651 Balasubramanian Suganthi Fu Yao Pawashe Mayur McGillivray Patrick Jin Mike Liu Jeremy Karczewski Konrad J MacArthur Daniel G Gerstein Mark 2017 08 29 Using ALoFT to determine the impact of putative loss of function variants in protein coding genes Nature Communications 8 1 382 Bibcode 2017NatCo 8 382B doi 10 1038 s41467 017 00443 5 ISSN 2041 1723 PMC 5575292 PMID 28851873 a b Clark David P Pazdernik Nanette J McGehee Michelle R 2019 Mutations and Repair Molecular Biology Elsevier pp 832 879 doi 10 1016 b978 0 12 813288 3 00026 4 ISBN 9780128132883 S2CID 239340633 retrieved 2022 12 02 a b c Nonsense mutation correction in human diseases an approach for targeted medicine WorldCat org www worldcat org Retrieved 2022 12 02 Guimbellot Jennifer Sharma Jyoti Rowe Steven M November 2017 Toward inclusive therapy with CFTR modulators Progress and challenges Pediatric Pulmonology 52 Suppl 48 S4 S14 doi 10 1002 ppul 23773 ISSN 8755 6863 PMC 6208153 PMID 28881097 Benhabiles Hana Jia Jieshuang Lejeune Fabrice 2016 01 01 Benhabiles Hana Jia Jieshuang Lejeune Fabrice eds Chapter 2 Pathologies Susceptible to be Targeted for Nonsense Mutation Therapies Nonsense Mutation Correction in Human Diseases Boston Academic Press pp 77 105 ISBN 978 0 12 804468 1 retrieved 2022 12 02 a b c d e f Editors B D 2018 08 26 Nonsense Mutation Definition Example Outcomes Biology Dictionary Retrieved 2022 12 02 a href Template Cite web html title Template Cite web cite web a last has generic name help Murgola Emanuel J December 1985 tRNA SUPPRESSION AND THE CODE Annual Review of Genetics 19 1 57 80 doi 10 1146 annurev ge 19 120185 000421 ISSN 0066 4197 PMID 2417544 References for the image are found in Wikimedia Commons page at Commons File Notable mutations svg References a b c d e Mort Matthew Ivanov Dobril Cooper David N Chuzhanova Nadia A August 2008 A meta analysis of nonsense mutations causing human genetic disease Human Mutation 29 8 1037 1047 doi 10 1002 humu 20763 PMID 18454449 S2CID 205918343 Isken Olaf Maquat Lynne E 2007 08 01 Quality control of eukaryotic mRNA safeguarding cells from abnormal mRNA function Genes amp Development 21 15 1833 1856 doi 10 1101 gad 1566807 ISSN 0890 9369 PMID 17671086 Khajavi Mehrdad Inoue Ken Lupski James R October 2006 Nonsense mediated mRNA decay modulates clinical outcome of genetic disease European Journal of Human Genetics 14 10 1074 1081 doi 10 1038 sj ejhg 5201649 ISSN 1476 5438 PMID 16757948 S2CID 3450423 a b Keeling Kim M Du Ming Bedwell David M 2013 Therapies of Nonsense Associated Diseases Landes Bioscience a b c d Shintani M Yagi H Nakayama T Saji T Matsuoka R 2009 05 01 A new nonsense mutation of SMAD8 associated with pulmonary arterial hypertension Journal of Medical Genetics 46 5 331 337 doi 10 1136 jmg 2008 062703 ISSN 0022 2593 PMID 19211612 S2CID 44932041 a b c d e Styrkarsdottir Unnur Thorleifsson Gudmar Sulem Patrick Gudbjartsson Daniel F Sigurdsson Asgeir Jonasdottir Aslaug Jonasdottir Adalbjorg Oddsson Asmundur Helgason Agnar Magnusson Olafur T Walters G Bragi Frigge Michael L Helgadottir Hafdis T Johannsdottir Hrefna Bergsteinsdottir Kristin 2013 05 23 Nonsense mutation in the LGR4 gene is associated with several human diseases and other traits Nature 497 7450 517 520 Bibcode 2013Natur 497 517S doi 10 1038 nature12124 ISSN 0028 0836 PMID 23644456 S2CID 205233843 a b c d Morais Pedro Adachi Hironori Yu Yi Tao 2020 06 20 Suppression of Nonsense Mutations by New Emerging Technologies International Journal of Molecular Sciences 21 12 4394 doi 10 3390 ijms21124394 ISSN 1422 0067 PMC 7352488 PMID 32575694 Huang Lulu Aghajan Mariam Quesenberry Tianna Low Audrey Murray Susan F Monia Brett P Guo Shuling August 2019 Targeting Translation Termination Machinery with Antisense Oligonucleotides for Diseases Caused by Nonsense Mutations Nucleic Acid Therapeutics 29 4 175 186 doi 10 1089 nat 2019 0779 ISSN 2159 3345 PMC 6686700 PMID 31070517 Lee Choongil Hyun Jo Dong Hwang Gue Ho Yu Jihyeon Kim Jin Hyoung Park Se eun Kim Jin Soo Kim Jeong Hun Bae Sangsu 2019 08 07 CRISPR Pass Gene Rescue of Nonsense Mutations Using Adenine Base Editors Molecular Therapy 27 8 1364 1371 doi 10 1016 j ymthe 2019 05 013 ISSN 1525 0016 PMC 6698196 PMID 31164261 Welch Ellen M Barton Elisabeth R Zhuo Jin Tomizawa Yuki Friesen Westley J Trifillis Panayiota Paushkin Sergey Patel Meenal Trotta Christopher R Hwang Seongwoo Wilde Richard G Karp Gary Takasugi James Chen Guangming Jones Stephen 2007 05 03 PTC124 targets genetic disorders caused by nonsense mutations Nature 447 7140 87 91 Bibcode 2007Natur 447 87W doi 10 1038 nature05756 ISSN 1476 4687 PMID 17450125 S2CID 4423529 PTC Therapeutics PTC Therapeutics Measured by Moments Retrieved 2022 12 01 ANVISA approves PTC Translarna indication expansion to ambulatory children Pharmaceutical Technology 2021 10 26 Retrieved 2022 12 01 Kerem Eitan Konstan Michael W De Boeck Kris Accurso Frank J Sermet Gaudelus Isabelle Wilschanski Michael Elborn J Stuart Melotti Paola Bronsveld Inez 2014 07 01 Ataluren for the treatment of nonsense mutation cystic fibrosis a randomised double blind placebo controlled phase 3 trial The Lancet Respiratory Medicine 2 7 539 547 doi 10 1016 S2213 2600 14 70100 6 PMC 4154311 PMID 24836205 Konstan M W VanDevanter D R Rowe S M Wilschanski M Kerem E Sermet Gaudelus I DiMango E Melotti P McIntosh J De Boeck K ACT CF Study Group July 2020 Efficacy and safety of ataluren in patients with nonsense mutation cystic fibrosis not receiving chronic inhaled aminoglycosides The international randomized double blind placebo controlled Ataluren Confirmatory Trial in Cystic Fibrosis ACT CF Journal of Cystic Fibrosis 19 4 595 601 doi 10 1016 j jcf 2020 01 007 ISSN 1873 5010 PMC 9167581 PMID 31983658 External links editNonsense mutation foundation supporting nonsense mutation patients across all genes Retrieved from https en wikipedia org w index php title Nonsense mutation amp oldid 1212862908, wikipedia, wiki, book, books, library,

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