recombination signal sequences

RSSs are made up of highly conserved heptamer sequences (7 base pairs), spacer sequences, and conserved nonamer sequences (9 base pairs) that are adjacent to the V, D and J sequences in the heavy-chain region of DNA and the V and J sequences in the light-chain DNA region.{{Cite journal|last1=Schatz|first1=David G.|last2=Oettinger|first2=Marjorie A.|last3=Schlissel|first3=Mark S.|year=1992|title=V(D)J Recombination: Molecular Biology and Regulation|journal=Annual Review of Immunology|volume=10|pages=359–383|doi=10.1146/annurev.immunol.10.1.359|pmid=1590991 }} Spacer sequences are located between heptamer and nonamer sequences and exhibit base pair variety but are always either 12 base pairs or 23 base pairs long.{{Cite journal|last=Roth|first=David B.|year=2014|title=V(D)J Recombination: Mechanism, Errors, and Fidelity|journal=Microbiology Spectrum|volume=2|issue=6|pages=1–11|pmid=26104458|pmc=5089068|doi=10.1128/microbiolspec.MDNA3-0041-2014|isbn=9781555819200}} Heptamer sequences are usually CACAGTG and nonamers are usually ACAAAAACC. The nucleotides in bold are more highly conserved. The RAG1/RAG2 enzyme complex follows the 12-23 rule when joining V, D, and J segments, pairing 12-bp spacer RSSs to 23-bp spacer RSSs. This prevents two different genes coding for the same region from recombining (ex. V-V recombination). RSSs are located between V, D, and J segments of the germ-line DNA of maturing B and T lymphocytes and are permanently spliced out of the final Ig mRNA product after V(D)J recombination is complete.

File:Jv recombination.pdf

The RAG1/RAG2 enzyme complex recognizes the heptamer sequences flanking the V and J coding regions and nicks their 5' end, releasing the intervening DNA between the V and J coding regions. In the heavy-chain coding region of DNA, the RAG1/RAG2 enzyme complex recognizes the RSSs flanking the D and J segments and brings them together, forming a loop containing intervening DNA.{{Cite journal|last=Rodgers|first=Karla|year=2017|title=Riches in RAGs: Revealing the V(D)J Recombinase Through High-Resolution Structures|journal=Trends in Biochemical Sciences|volume=42|issue=1|pages=72–84|doi=10.1016/j.tibs.2016.10.003|pmid=27825771|pmc=5182142}} The RAG1/RAG2 complex then introduces a nick at the 5' end of the RSS heptamers adjacent to the coding regions on both the D and J segments, permanently removing the loop of intervening DNA and creating a double-stranded break that is repaired by VDJ recombinase enzymes. This process is repeated for the joining of V to DJ. In light-chain rearrangement, only V and J segments are brought together.

Cryptic RSSs are gene sequences that resemble authentic RSSs and are occasionally mistaken for them by the RAG1/RAG2 enzyme complex. Recombining an RSS with a cRSS can lead to chromosome translocations, which can lead to cancer.

Some infants born with autosomal recessive SCIDS lack a functional copies of the genes that code for the RAG1/RAG2 enzyme complex because of missense mutations.{{Cite journal|last=Buckley|first=Rebecca H.|year=2004|title=Molecular Defects in Human Severe Combined Immunodeficiency And Approaches to Immune Reconstitution|journal=Annual Review of Immunology|volume=22|pages=625–655|doi=10.1146/annurev.immunol.22.012703.104614|pmid=15032591}}{{Cite journal|last1=Elnour|first1=Ibtisam B|last2=Ahmed|first2=Shakeel|last3=Halim|first3=Kamel|last4=Nirmala|first4=V|year=2007|title=Omenn's Syndrome: A rare primary immunodeficiency disorder|journal=Sultan Qaboos University Medical Journal|volume=7|issue=2 |pages=1–6|pmid=21748095|pmc=3074865}} These infants will produce a non-functional RAG1/RAG2 enzyme complex that cannot recognize RSSs and therefore cannot initiate V(D)J recombination effectively. This disorder is characterized by a lack of functioning B and T cells.

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Category:Immune system