Abstract

BackgroundIt is widely accepted that the last eukaryotic common ancestor and early eukaryotes were intron-rich and intron loss dominated subsequent evolution, thus the presence of only very few introns in some modern eukaryotes must be the consequence of massive loss. But it is striking that few eukaryotes were found to have completely lost introns. Despite extensive research, the causes of massive intron losses remain elusive. Actually the reverse question -- how the few introns can be retained under the evolutionary selection pressure of intron loss -- is equally significant but was rarely studied, except that it was conjectured that the essential functions of some introns prevent their loss. The situation that extremely few (eight) spliceosome-mediated cis-spliced introns present in the relatively simple genome of Giardia lamblia provides an excellent opportunity to explore this question.ResultsOur investigation found three types of distribution patterns of the few introns in the intron-containing genes: ancient intron in ancient gene, later-evolved intron in ancient gene, and later-evolved intron in later-evolved gene, which can reflect to some extent the dynamic evolution of introns in Giardia. Without finding any special features or functional importance of these introns responsible for their retention, we noticed and experimentally verified that some intron-containing genes form sense-antisense gene pairs with transcribable genes on their complementary strands, and that the introns just reside in the overlapping regions.ConclusionsIn Giardia’s evolution, despite constant evolutionary selection pressure of intron loss, intron gain can still occur in both ancient and later-evolved genes, but only a few introns are retained; at least the evolutionary retention of some of the introns might not be due to the functional constraint of the introns themselves but the causes outside of introns, such as the constraints imposed by other genomic functional elements overlapping with the introns. These findings can not only provide some clues to find new genomic functional elements -- in the areas overlapping with introns, but suggest that “functional constraint” of introns may not be necessarily directly associated with intron loss and gain, and that the real functions are probably still outside of our current knowledge.ReviewersThis article was reviewed by Mikhail Gelfand, Michael Gray, and Igor Rogozin.

Highlights

  • It is widely accepted that the last eukaryotic common ancestor and early eukaryotes were intron-rich and intron loss dominated subsequent evolution, the presence of only very few introns in some modern eukaryotes must be the consequence of massive loss

  • Accumulating evidence suggests that the last eukaryotic common ancestor (LECA) and early eukaryotes were relatively intron rich, with subsequent genome evolution dominated by intron loss, and those contemporary eukaryotes with remarkably few introns must have experienced massive intron loss secondarily [7,8,9]

  • To find the reason why these few introns can be retained in Giardia genome under the constant evolutionary selection pressure of loss, we investigated the Intron-containing gene

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Summary

Introduction

It is widely accepted that the last eukaryotic common ancestor and early eukaryotes were intron-rich and intron loss dominated subsequent evolution, the presence of only very few introns in some modern eukaryotes must be the consequence of massive loss. The reverse question -how the few introns can be retained under the evolutionary selection pressure of intron loss -- is significant but was rarely studied, except that it was conjectured that the essential functions of some introns prevent their loss. Accumulating evidence suggests that the last eukaryotic common ancestor (LECA) and early eukaryotes were relatively intron rich, with subsequent genome evolution dominated by intron loss, and those contemporary eukaryotes with remarkably few introns must have experienced massive intron loss secondarily [7,8,9]. The reverse question -how introns, especially the few ones in intron-poor eukaryotes, can be retained under the evolutionary selection pressure of intron loss -- is important, but was rarely carefully studied. The investigation of the evolutionary retention of intron might be helpful to answering the question about intron loss and to understanding the function and evolution of introns

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