Transposable elements as the key to a 21st century view of evolution.

:Cells are capable of sophisticated information processing. Cellular signal transduction networks serve to compute data from multiple inputs and make decisions about cellular behavior. Genomes are organized like integrated computer programs as systems of routines and subroutines, not as a collection of independent genetic 'units'. DNA sequences which do not code for protein structure determine the system architecture of the genome. Repetitive DNA elements serve as tags to mark and integrate different protein coding sequences into coordinately functioning groups, to build up systems for genome replication and distribution to daughter cells, and to organize chromatin. Genomes can be reorganized through the action of cellular systems for cutting, splicing and rearranging DNA molecules. Natural genetic engineering systems (including transposable elements) are capable of acting genome-wide and not just one site at a time. Transposable elements are subject to regulation by cellular signal transduction/computing networks. This regulation acts on both the timing and extent of DNA rearrangements and (in a few documented cases so far) on the location of changes in the genomes. By connecting transcriptional regulatory circuits to the action of natural genetic engineering systems, there is a plausible molecular basis for coordinated changes in the genome subject to biologically meaningful feedback.

Shapiro JA 《GENETICA》

A 21st century view of evolution: genome system architecture, repetitive DNA, and natural genetic engineering.

The last 50 years of molecular genetics have produced an abundance of new discoveries and data that make it useful to revisit some basic concepts and assumptions in our thinking about genomes and evolution. Chief among these observations are the complex modularity of genome organization, the biological ubiquity of mobile and repetitive DNA sequences, and the fundamental importance of DNA rearrangements in the evolution of sequenced genomes. This review will take a broad overview of these developments and suggest some new ways of thinking about genomes as sophisticated informatic storage systems and about evolution as a systems engineering process.

Shapiro JA 《GENE》

Transposable elements in gene regulation and in the evolution of vertebrate genomes.

Repetitive DNA and in particular transposable elements have been intimately linked to eukaryotic genomes for millions of years. Once overlooked for being only a collection of selfish debris and a nuisance for sequence assembly, genomic repeats are now being recognized as a key driving force in genome evolution. Indeed, by changing the DNA landscape of genomes, transposable elements have been a rich source of innovation in genes, regulatory elements and genome structures. In this review, I will focus on recent advances that demonstrate that genomic repeats have had a global impact on vertebrate gene regulatory networks. I will also summarize results that show how transposable elements have been a major catalyst of structural rearrangements throughout evolution.

Bourque G 《-》

Mobile genetic elements as natural tools for genome evolution.

Transposable elements (TEs) are ubiquitous components of all living organisms, and in the course of their coexistence with their respective host genomes, these parasitic DNAs have played important roles in the evolution of complex genetic networks. The interaction between mobile DNAs and their host genomes are quite diverse, ranging from modifications of gene structure and regulation to alterations in general genome architecture. Thus over evolutionary time these elements can be regarded as natural molecular tools in shaping the organization, structure, and function of eukaryotic genes and genomes. Based on their intrinsic properties and features, mobile DNAs are widely applied at present as a technical "toolbox," essential for studying a diverse spectrum of biological questions. In this chapter we aim to review both the evolutionary impact of TEs on genome evolution and their valuable and diverse methodological applications as the molecular tools presented in this book.

Miller WJ ，Capy P 《-》

What transposable elements tell us about genome organization and evolution: the case of Drosophila.

Transposable elements (TEs) have been identified in every organism in which they have been looked for. The sequencing of large genomes, such as the human genome and those of Drosophila, Arabidopsis, Caenorhabditis, has also shown that they are a major constituent of these genomes, accounting for 15% of the genome of Drosophila, 45% of the human genome, and more than 70% in some plants and amphibians. Compared with the 1% of genomic DNA dedicated to protein-coding sequences in the human genome, this has prompted various researchers to suggest that the TEs and the other repetitive sequences that constitute the so-called "noncoding DNA", are where the most stimulating discoveries will be made in the future (Bromham, 2002). We are therefore getting further and further from the original idea that this DNA was simply "junk DNA", that owed its presence in the genome entirely to its capacity for selfish transposition. Our understanding of the structures of TEs, their distribution along the genomes, their sequence and insertion polymorphisms within genomes, and within and between populations and species, their impact on genes and on the regulatory mechanisms of genetic expression, their effects on exon shuffling and other phenomena that reshape the genome, and their impact on genome size has increased dramatically in recent years. This leads to a more general picture of the impact of TEs on genomes, though many copies are still mainly selfish or junk DNA. In this review we focus mainly on discoveries made in Drosophila, but we also use information about other genomes when this helps to elucidate the general processes involved in the organization, plasticity, and evolution of genomes.

Biémont C ，Vieira C 《-》