Are STOP codons impacted by base insertion or deletion mutation?











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I am learning about base insertion and deletion mutations. An example in my textbook is given below.



GUU CCA CAU AUC.



So if there is an insertion (of guanine):



GUU GCC ACA UAU C_ _ (there will be a detrimental effect on the protein created).



I'm a bit confused about how the stop codon will be read. If we have a new example with a stop codon:



GUU CCA CAU AUC UAG



When the mutation occurs (insertion of guanine) will it become:



1) GUU GCC ACA UAU CUA G



OR



2) GUU GCC ACA UAU C_ _ UAG



If mutation 1) occurs, there would be no stop codon, but mutation 2) looks strange to me. So which is the right one?



Thanks










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    up vote
    1
    down vote

    favorite












    I am learning about base insertion and deletion mutations. An example in my textbook is given below.



    GUU CCA CAU AUC.



    So if there is an insertion (of guanine):



    GUU GCC ACA UAU C_ _ (there will be a detrimental effect on the protein created).



    I'm a bit confused about how the stop codon will be read. If we have a new example with a stop codon:



    GUU CCA CAU AUC UAG



    When the mutation occurs (insertion of guanine) will it become:



    1) GUU GCC ACA UAU CUA G



    OR



    2) GUU GCC ACA UAU C_ _ UAG



    If mutation 1) occurs, there would be no stop codon, but mutation 2) looks strange to me. So which is the right one?



    Thanks










    share|improve this question









    New contributor




    Christopher Uren is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
    Check out our Code of Conduct.






















      up vote
      1
      down vote

      favorite









      up vote
      1
      down vote

      favorite











      I am learning about base insertion and deletion mutations. An example in my textbook is given below.



      GUU CCA CAU AUC.



      So if there is an insertion (of guanine):



      GUU GCC ACA UAU C_ _ (there will be a detrimental effect on the protein created).



      I'm a bit confused about how the stop codon will be read. If we have a new example with a stop codon:



      GUU CCA CAU AUC UAG



      When the mutation occurs (insertion of guanine) will it become:



      1) GUU GCC ACA UAU CUA G



      OR



      2) GUU GCC ACA UAU C_ _ UAG



      If mutation 1) occurs, there would be no stop codon, but mutation 2) looks strange to me. So which is the right one?



      Thanks










      share|improve this question









      New contributor




      Christopher Uren is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
      Check out our Code of Conduct.











      I am learning about base insertion and deletion mutations. An example in my textbook is given below.



      GUU CCA CAU AUC.



      So if there is an insertion (of guanine):



      GUU GCC ACA UAU C_ _ (there will be a detrimental effect on the protein created).



      I'm a bit confused about how the stop codon will be read. If we have a new example with a stop codon:



      GUU CCA CAU AUC UAG



      When the mutation occurs (insertion of guanine) will it become:



      1) GUU GCC ACA UAU CUA G



      OR



      2) GUU GCC ACA UAU C_ _ UAG



      If mutation 1) occurs, there would be no stop codon, but mutation 2) looks strange to me. So which is the right one?



      Thanks







      genetics mutations codon






      share|improve this question









      New contributor




      Christopher Uren is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
      Check out our Code of Conduct.











      share|improve this question









      New contributor




      Christopher Uren is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
      Check out our Code of Conduct.









      share|improve this question




      share|improve this question








      edited 1 hour ago









      Tom Kelly

      1336




      1336






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      asked 3 hours ago









      Christopher Uren

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      New contributor





      Christopher Uren is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
      Check out our Code of Conduct.






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      Check out our Code of Conduct.






















          2 Answers
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          down vote













          Let's start with your example:



          Wild-type gene looks like:




          GUU CCA CAU AUC UAG*




          After G insertion, you end up with




          GUU GCC ACA UAU CUA G




          There are 3 stop codons: UAG*, UAA*, UGA*



          You don't see those in your mutated gene, because you truncated sequence. Let's imagine that gene actually goes like this:




          WT: GUU CCA CAU AUC UAG* GCG UCU AAA ACG CUA



          Mut: GUU GCC ACA UAU CUA GGC GUC UAA* AAC GCU A...




          In mutant you got now new stop codon created



          mRNA doesn't stop at stop codon, there is whole bunch of sequence after it too (3'-UTR and poly-A tail for Eukaryotas)






          share|improve this answer




























            up vote
            1
            down vote













            Yes. Mutations can affect STOP codons and they do relatively commonly. These are important because they can lead to significant changes in the resulting peptide and are likely to affect protein functions or phenotype.



            For a point mutation (a single base substitution), there are several possible effects:




            • silent mutation is a synonymous base substitution which does not change the encoded amino acids (this is neutral variation).


            • missense mutation is a non-synonymous bass substitution which changes only one amino acid in the protein (these can affect protein functions but do not always).


            • nonsense mutation is a change in a coding codon to a STOP codon (this truncates the encoded amino acid sequence prematurely resulting in a shorter peptide).


            • nonstop mutation is a change from a STOP codon to a coding codon (this means the amino acid sequence will continue to the next STOP codon resulting in a longer peptide).



            Insertions and Deletions in DNA sequence (InDels) are important because they change all codons that follow it (not just the base substituted):





            • frameshift mutation adds or removes a base which resulting in a change in the reading frame: all bases following will result in new codons, including STOP codons (this commonly results in entirely new protein domains and proteins of different lengths as STOP codons will also be changed. They are encoded in the reading frame like all other codons.


            As you can see, mutations which affect STOP codons are very important as they drastically change the protein sequence. This usually disrupts the protein function and causes diseases or inviable embryos. Most of these are removed from populations long-term by natural selection. However, it can rarely lead to entirely new proteins beneficial to the organism and evolutionary changes. This is more likely with duplicated genes where one can change while the other retains the original function.



            As such, mutations involving STOP codons are among the most biologically important. Another important case is splice functions. Point mutations and frameshifts can also affect intron-exon boundaries, resulting in new splice variants, skipped exons, and reading further into introns (which may contain splice junctions or STOP codons).






            share|improve this answer





















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              2 Answers
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              2 Answers
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              active

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              active

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              up vote
              1
              down vote













              Let's start with your example:



              Wild-type gene looks like:




              GUU CCA CAU AUC UAG*




              After G insertion, you end up with




              GUU GCC ACA UAU CUA G




              There are 3 stop codons: UAG*, UAA*, UGA*



              You don't see those in your mutated gene, because you truncated sequence. Let's imagine that gene actually goes like this:




              WT: GUU CCA CAU AUC UAG* GCG UCU AAA ACG CUA



              Mut: GUU GCC ACA UAU CUA GGC GUC UAA* AAC GCU A...




              In mutant you got now new stop codon created



              mRNA doesn't stop at stop codon, there is whole bunch of sequence after it too (3'-UTR and poly-A tail for Eukaryotas)






              share|improve this answer

























                up vote
                1
                down vote













                Let's start with your example:



                Wild-type gene looks like:




                GUU CCA CAU AUC UAG*




                After G insertion, you end up with




                GUU GCC ACA UAU CUA G




                There are 3 stop codons: UAG*, UAA*, UGA*



                You don't see those in your mutated gene, because you truncated sequence. Let's imagine that gene actually goes like this:




                WT: GUU CCA CAU AUC UAG* GCG UCU AAA ACG CUA



                Mut: GUU GCC ACA UAU CUA GGC GUC UAA* AAC GCU A...




                In mutant you got now new stop codon created



                mRNA doesn't stop at stop codon, there is whole bunch of sequence after it too (3'-UTR and poly-A tail for Eukaryotas)






                share|improve this answer























                  up vote
                  1
                  down vote










                  up vote
                  1
                  down vote









                  Let's start with your example:



                  Wild-type gene looks like:




                  GUU CCA CAU AUC UAG*




                  After G insertion, you end up with




                  GUU GCC ACA UAU CUA G




                  There are 3 stop codons: UAG*, UAA*, UGA*



                  You don't see those in your mutated gene, because you truncated sequence. Let's imagine that gene actually goes like this:




                  WT: GUU CCA CAU AUC UAG* GCG UCU AAA ACG CUA



                  Mut: GUU GCC ACA UAU CUA GGC GUC UAA* AAC GCU A...




                  In mutant you got now new stop codon created



                  mRNA doesn't stop at stop codon, there is whole bunch of sequence after it too (3'-UTR and poly-A tail for Eukaryotas)






                  share|improve this answer












                  Let's start with your example:



                  Wild-type gene looks like:




                  GUU CCA CAU AUC UAG*




                  After G insertion, you end up with




                  GUU GCC ACA UAU CUA G




                  There are 3 stop codons: UAG*, UAA*, UGA*



                  You don't see those in your mutated gene, because you truncated sequence. Let's imagine that gene actually goes like this:




                  WT: GUU CCA CAU AUC UAG* GCG UCU AAA ACG CUA



                  Mut: GUU GCC ACA UAU CUA GGC GUC UAA* AAC GCU A...




                  In mutant you got now new stop codon created



                  mRNA doesn't stop at stop codon, there is whole bunch of sequence after it too (3'-UTR and poly-A tail for Eukaryotas)







                  share|improve this answer












                  share|improve this answer



                  share|improve this answer










                  answered 2 hours ago









                  aaaaaa

                  2,630423




                  2,630423






















                      up vote
                      1
                      down vote













                      Yes. Mutations can affect STOP codons and they do relatively commonly. These are important because they can lead to significant changes in the resulting peptide and are likely to affect protein functions or phenotype.



                      For a point mutation (a single base substitution), there are several possible effects:




                      • silent mutation is a synonymous base substitution which does not change the encoded amino acids (this is neutral variation).


                      • missense mutation is a non-synonymous bass substitution which changes only one amino acid in the protein (these can affect protein functions but do not always).


                      • nonsense mutation is a change in a coding codon to a STOP codon (this truncates the encoded amino acid sequence prematurely resulting in a shorter peptide).


                      • nonstop mutation is a change from a STOP codon to a coding codon (this means the amino acid sequence will continue to the next STOP codon resulting in a longer peptide).



                      Insertions and Deletions in DNA sequence (InDels) are important because they change all codons that follow it (not just the base substituted):





                      • frameshift mutation adds or removes a base which resulting in a change in the reading frame: all bases following will result in new codons, including STOP codons (this commonly results in entirely new protein domains and proteins of different lengths as STOP codons will also be changed. They are encoded in the reading frame like all other codons.


                      As you can see, mutations which affect STOP codons are very important as they drastically change the protein sequence. This usually disrupts the protein function and causes diseases or inviable embryos. Most of these are removed from populations long-term by natural selection. However, it can rarely lead to entirely new proteins beneficial to the organism and evolutionary changes. This is more likely with duplicated genes where one can change while the other retains the original function.



                      As such, mutations involving STOP codons are among the most biologically important. Another important case is splice functions. Point mutations and frameshifts can also affect intron-exon boundaries, resulting in new splice variants, skipped exons, and reading further into introns (which may contain splice junctions or STOP codons).






                      share|improve this answer

























                        up vote
                        1
                        down vote













                        Yes. Mutations can affect STOP codons and they do relatively commonly. These are important because they can lead to significant changes in the resulting peptide and are likely to affect protein functions or phenotype.



                        For a point mutation (a single base substitution), there are several possible effects:




                        • silent mutation is a synonymous base substitution which does not change the encoded amino acids (this is neutral variation).


                        • missense mutation is a non-synonymous bass substitution which changes only one amino acid in the protein (these can affect protein functions but do not always).


                        • nonsense mutation is a change in a coding codon to a STOP codon (this truncates the encoded amino acid sequence prematurely resulting in a shorter peptide).


                        • nonstop mutation is a change from a STOP codon to a coding codon (this means the amino acid sequence will continue to the next STOP codon resulting in a longer peptide).



                        Insertions and Deletions in DNA sequence (InDels) are important because they change all codons that follow it (not just the base substituted):





                        • frameshift mutation adds or removes a base which resulting in a change in the reading frame: all bases following will result in new codons, including STOP codons (this commonly results in entirely new protein domains and proteins of different lengths as STOP codons will also be changed. They are encoded in the reading frame like all other codons.


                        As you can see, mutations which affect STOP codons are very important as they drastically change the protein sequence. This usually disrupts the protein function and causes diseases or inviable embryos. Most of these are removed from populations long-term by natural selection. However, it can rarely lead to entirely new proteins beneficial to the organism and evolutionary changes. This is more likely with duplicated genes where one can change while the other retains the original function.



                        As such, mutations involving STOP codons are among the most biologically important. Another important case is splice functions. Point mutations and frameshifts can also affect intron-exon boundaries, resulting in new splice variants, skipped exons, and reading further into introns (which may contain splice junctions or STOP codons).






                        share|improve this answer























                          up vote
                          1
                          down vote










                          up vote
                          1
                          down vote









                          Yes. Mutations can affect STOP codons and they do relatively commonly. These are important because they can lead to significant changes in the resulting peptide and are likely to affect protein functions or phenotype.



                          For a point mutation (a single base substitution), there are several possible effects:




                          • silent mutation is a synonymous base substitution which does not change the encoded amino acids (this is neutral variation).


                          • missense mutation is a non-synonymous bass substitution which changes only one amino acid in the protein (these can affect protein functions but do not always).


                          • nonsense mutation is a change in a coding codon to a STOP codon (this truncates the encoded amino acid sequence prematurely resulting in a shorter peptide).


                          • nonstop mutation is a change from a STOP codon to a coding codon (this means the amino acid sequence will continue to the next STOP codon resulting in a longer peptide).



                          Insertions and Deletions in DNA sequence (InDels) are important because they change all codons that follow it (not just the base substituted):





                          • frameshift mutation adds or removes a base which resulting in a change in the reading frame: all bases following will result in new codons, including STOP codons (this commonly results in entirely new protein domains and proteins of different lengths as STOP codons will also be changed. They are encoded in the reading frame like all other codons.


                          As you can see, mutations which affect STOP codons are very important as they drastically change the protein sequence. This usually disrupts the protein function and causes diseases or inviable embryos. Most of these are removed from populations long-term by natural selection. However, it can rarely lead to entirely new proteins beneficial to the organism and evolutionary changes. This is more likely with duplicated genes where one can change while the other retains the original function.



                          As such, mutations involving STOP codons are among the most biologically important. Another important case is splice functions. Point mutations and frameshifts can also affect intron-exon boundaries, resulting in new splice variants, skipped exons, and reading further into introns (which may contain splice junctions or STOP codons).






                          share|improve this answer












                          Yes. Mutations can affect STOP codons and they do relatively commonly. These are important because they can lead to significant changes in the resulting peptide and are likely to affect protein functions or phenotype.



                          For a point mutation (a single base substitution), there are several possible effects:




                          • silent mutation is a synonymous base substitution which does not change the encoded amino acids (this is neutral variation).


                          • missense mutation is a non-synonymous bass substitution which changes only one amino acid in the protein (these can affect protein functions but do not always).


                          • nonsense mutation is a change in a coding codon to a STOP codon (this truncates the encoded amino acid sequence prematurely resulting in a shorter peptide).


                          • nonstop mutation is a change from a STOP codon to a coding codon (this means the amino acid sequence will continue to the next STOP codon resulting in a longer peptide).



                          Insertions and Deletions in DNA sequence (InDels) are important because they change all codons that follow it (not just the base substituted):





                          • frameshift mutation adds or removes a base which resulting in a change in the reading frame: all bases following will result in new codons, including STOP codons (this commonly results in entirely new protein domains and proteins of different lengths as STOP codons will also be changed. They are encoded in the reading frame like all other codons.


                          As you can see, mutations which affect STOP codons are very important as they drastically change the protein sequence. This usually disrupts the protein function and causes diseases or inviable embryos. Most of these are removed from populations long-term by natural selection. However, it can rarely lead to entirely new proteins beneficial to the organism and evolutionary changes. This is more likely with duplicated genes where one can change while the other retains the original function.



                          As such, mutations involving STOP codons are among the most biologically important. Another important case is splice functions. Point mutations and frameshifts can also affect intron-exon boundaries, resulting in new splice variants, skipped exons, and reading further into introns (which may contain splice junctions or STOP codons).







                          share|improve this answer












                          share|improve this answer



                          share|improve this answer










                          answered 1 hour ago









                          Tom Kelly

                          1336




                          1336






















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