Add to ORKGSince it was first recognised that eukaryotic genes are fragmented into coding segments (exons) separated by non-coding segments (introns), the reason for this phenomenon has been debated. There are two dominant theories: that the piecewise arrange-ment of genes allows functional protein domains, represented by exons, to recombine by shuffling to form novel proteins with combinations of functions; or that introns represent parasitic DNA that can infest the eukaryotic genome because it does not interfere grossly with the fitness of its host. Differing distributions of exon lengths are predicted by these two theories. In this paper we examine distributions of exon lengths for six different organisms and find that they offer empirical evidence...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
AbstractExon insertions and exon duplications, two major mechanisms of exon shuffling, are shown to ...
In this work, 21 completely sequenced eukaryotic genomes were analyzed using an intragene compar-iso...
Since it was first recognised that eukaryotic genes are fragmented into coding segments (exons) sepa...
Abstract Background The origin and importance of exon-intron architecture comprises one of the remai...
Abstract Background Most eukaryotic genes are interru...
Abstract Background Most eukaryotic genes are interru...
Intron phase is a conserved evolutionary character that refers to the location of introns relative t...
Motivation. Length and number of introns in genes of different eukaryotes, including human, varied w...
Two possibilities have been proposed for the origin of split structures observed in protein-coding e...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
BACKGROUND: Most eukaryotic genes are interrupted by spliceosomal introns. The evolution of exon-int...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
AbstractExon insertions and exon duplications, two major mechanisms of exon shuffling, are shown to ...
In this work, 21 completely sequenced eukaryotic genomes were analyzed using an intragene compar-iso...
Since it was first recognised that eukaryotic genes are fragmented into coding segments (exons) sepa...
Abstract Background The origin and importance of exon-intron architecture comprises one of the remai...
Abstract Background Most eukaryotic genes are interru...
Abstract Background Most eukaryotic genes are interru...
Intron phase is a conserved evolutionary character that refers to the location of introns relative t...
Motivation. Length and number of introns in genes of different eukaryotes, including human, varied w...
Two possibilities have been proposed for the origin of split structures observed in protein-coding e...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
BACKGROUND: Most eukaryotic genes are interrupted by spliceosomal introns. The evolution of exon-int...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
Accurate gene prediction in eukaryotes is a difficult and subtle problem. Here we point out a useful...
AbstractExon insertions and exon duplications, two major mechanisms of exon shuffling, are shown to ...
In this work, 21 completely sequenced eukaryotic genomes were analyzed using an intragene compar-iso...