Exon

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An exon is any part of a gene that will become a part of the final mature RNA produced by that gene after introns have been removed by RNA splicing. The term exon refers to both the DNA sequence within a gene and to the corresponding sequence in RNA transcripts. In RNA splicing, introns are removed and exons are covalently joined to one another as part of generating the mature messenger RNA.

History

The term exon derives from the expressed region and was coined by American biochemist Walter Gilbert in 1978: "The notion of the cistron… must be replaced by that of a transcription unit containing regions which will be lost from the mature messenger – which I suggest we call introns (for intragenic regions) – alternating with regions which will be expressed – exons."[1]

This definition was originally made for protein-coding transcripts that are spliced before being translated. The term later came to include sequences removed from rRNA[2] and tRNA,[3] and it also was used later for RNA molecules originating from different parts of the genome that are then ligated by trans-splicing.[4]

Contribution to genomes and size distribution

Although unicellular eukaryotes such as yeast have either no introns or very few, metazoans and especially vertebrate genomes have a large fraction of non-coding DNA. For instance, in the human genome only 1.1% of the genome is spanned by exons, whereas 24% is in introns, with 75% of the genome being intergenic DNA.[5] Across all eukaryotic genes in GenBank there were (in 2002), on average, 5.48 exons per gene. The average exon encoded 30-36 amino acids.[6] While the longest exon in the human genome is 11555 bp long, several exons have been found to be only 2 bp long.[7] In fact, a single-nucleotide exon was recently reported from the Arabidopsis genome.[8]

Structure and function

In protein-coding genes, the open reading frame (ORF) that codes for a specific portion of the complete protein are located in the exons. However, the term exon is often misused to refer only to coding sequences for the final protein. This is incorrect, since many noncoding exons are known in human genes.[9][10]

Gene structure.svg

The figure shows a heterogeneous nuclear RNA (hnRNA), i.e. an unedited mRNA transcript, or pre-mRNA. Exons can include both sequences that code for amino acids (red) and untranslated sequences (grey). Stretches of unused sequence called introns (blue) are removed, and the exons are joined together to form the final functional mRNA. The notation 5' and 3' refer to the direction of the DNA template in the chromosome and is used to distinguish between the two untranslated regions (grey).

Some of the exons will be wholly or part of the 5' untranslated region (5' UTR) or the 3' untranslated region (3' UTR) of each transcript. The untranslated regions are important for efficient translation of the transcript and for controlling the rate of translation and half-life of the transcript. Furthermore, transcripts made from the same gene may not have the same exon structure, since parts of the mRNA could be removed by the process of alternative splicing. Some mRNA transcripts have exons with no ORFs and, thus, are sometimes referred to as non-coding RNA.

Exonization is the creation of a new exon, as a result of mutations in intronic sequences.[11]

Polycistronic messages have multiple ORFs in one transcript and also have small regions of untranslated sequence between each ORF.

Experimental approaches using exons

Exon trapping or 'gene trapping' is a molecular biology technique that exploits the existence of the intron-exon splicing to find new genes.[12] The first exon of a 'trapped' gene splices into the exon that is contained in the insertional DNA. This new exon contains the ORF for a reporter gene that can now be expressed using the enhancers that control the target gene. A scientist knows that a new gene has been trapped when the reporter gene is expressed.

Splicing can be experimentally modified so that targeted exons are excluded from mature mRNA transcripts by blocking the access of splice-directing small nuclear ribonucleoprotein particles (snRNPs) to pre-mRNA using Morpholino antisense oligos.[13] This has become a standard technique in developmental biology. Morpholino oligos can also be targeted to prevent molecules that regulate splicing (e.g. splice enhancers, splice suppressors) from binding to pre-mRNA, altering patterns of splicing.

See also

References

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  7. Sakharkar M.K. et al (2004) Distributions of exons and introns in the human genome, In Silico Biology 4, 0032
  8. Lei Guo & Chun-Ming Liu (2015) A single-nucleotide exon found in Arabidopsis. Scientific Reports 5, Article number: 18087, doi:10.1038/srep18087
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General references

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External links