Abstract
In all jawed vertebrates RAG (recombination activating gene) recombinase orchestrates V(D)J recombination in B and T lymphocyte precursors, assembling the V, D and J germline gene segments into continuous functional entities which encode the variable regions of their immune receptors. V(D)J recombination is the process by which most of the diversity of our specific immune receptors is acquired and is thought to have originated by domestication of a transposon in the genome of a vertebrate. RAG acts similarly to the cut and paste transposases, by first binding two recombination signal DNA sequences (RSSs), which flank the two coding genes to be adjoined, in a process called synaptic or paired complex (PC) formation. At these RSS-coding borders, RAG first nicks one DNA strand, then creates hairpins, thus cleaving the duplex DNA at both RSSs. Although RAG reaction mechanism resembles that of insect mobile element transposases and RAG itself can inefficiently perform intramolecular and intermolecular integration into the target DNA, inside the nuclei of the developing lymphocytes transposition is extremely rare and is kept under proper surveillance. Our review may help understand how RAG synaptic complex organization prevents deleterious transposition. The phosphoryl transfer reaction mechanism of RNAseH-like fold DDE motif enzymes, including RAG, is discussed accentuating the peculiarities described for various transposases from the light of their available high resolution structures (Tn5, Mu, Mos1 and Hermes). Contrasting the structural 3D organization of DNA in these transpososomes with that of the RSSs-DNA in RAG PC allows us to propose several clues for how evolutionarily RAG may have become “specialized” in recombination versus transposition.
Highlights
Introduction2. V(D)J recombination outline, Recombination activating gene proteins (RAG) proteins 3
Our review may help understand how Recombination activating gene proteins (RAG) synaptic complex organization prevents deleterious transposition
45% of the human genome is represented by such mobile elements and, even more surprising, there is strong evidence that LINE-1 retrotransposons, which comprise 17% of the human genome, are polymorphic and active in human populations[3]
Summary
In 2000 USA President Bill Clinton officially announced that a group of scientists from Celera lead by Greg Venter[1] and Francis Collins from the National Institutes of Health U.S Public Genome Project jointly mapped the human genome, the detailed sequenced project has been completely finalized only in 2003. The minimal requirement of their sequence is an active ORF encoding a transposase, which upon specific recognition of the two ends (denoted Insertional sequences IS or Inverted repeats IR) of the transposon, cuts them from its donor place, moving and inserting them to another acceptor or target DNA2 Such "hoping" activity can disrupt or mobilize genes around genome(s), for long time it was thought that their arcane origin is just a reminder of our evolution, but they should be completely inactive, at least in evolved vertebrates. There are five major arguments favoring this hypothesis all addressed in detail by our review: 1) RAG1 subunit of RAG recombinase, which recombines V,D,J segments, is highly homologous to many insect Transib transposases9; 2) RAG1 is a multimodular protein whose linear domain organization parallels that of many described transposases and viral DNA integrases5,10,11; 3) The specific RSS DNA elements. RAG binds alone one 12-RSS forming the single or signal complex 12-SC, 23-SC and PC formation must be facilitated by an ubiquitous set of nuclear proteins HMGB1 or 2 which play an architectural role in bending the two 12/23-RSSs to fit into the final configuration compatible with catalysis[10,21,31,32]
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