src/hg/makeDb/trackDb/human/encodeRecombHotspot.html 2e3c89f43f3bb9d386178270200d0acce9fc8050

2e3c89f43f3bb9d386178270200d0acce9fc8050
lrnassar
  Fri Nov 22 17:47:13 2024 -0800
Giving the UI link cronjob some love by fixing all the 301 redirects. These are the bulk of the items listed on the cron. No RM.

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 <H2>Description</H2>
 <P>
 This track shows the location of recombination hotspots detected from
 patterns of genetic variation. It is based on the HapMap ENCODE data,
 in the ten ENCODE regions that have been resequenced:
 <UL>
 <LI>ENr112 (chr2)
 <LI>ENr131 (chr2)
 <LI>ENr113 (chr4)
 <LI>ENm010 (chr7)
 <LI>ENm013 (chr7)
 <LI>ENm014 (chr7)
 <LI>ENr321 (chr8)
 <LI>ENr232 (chr9)
 <LI>ENr123 (chr12)
 <LI>ENr213 (chr18)
 </UL>
 </P>
 <P>
 Observations from sperm studies (Jeffreys <em>et al</em>., 2001) and
 patterns of genetic variation (McVean <em>et al</em>., 2004; Crawford
 <em>et al</em>., 2004) show that recombination rates in the human
 genome vary extensively over kilobase scales and that much
 recombination occurs in recombination hotspots. This provides an
 explanation for the apparent block-like structure of linkage
 disequlibrium (Daly <em>et al</em>., 2001; Gabriel <em>et al</em>.,
 2002).
 </P>
 <P>
 Recombination hotspot estimates provide a new route to
 understanding the molecular mechanisms underlying human recombination.
 A better understanding of the genomic landscape of human recombination
 hotspots would facilitate the efficient design and analysis of
 disease association studies and greatly improve inferences from
 polymorphism data about selection and human demographic history.
 </P>
 
 <H2>Methods</H2>
 <P>
 Recombination hotspots are identified using the likelihood-ratio test
 described in McVean <I>et al</I>. (2004) and Winckler <I>et al</I>. (2005), 
 referred to as LDhot.  For successive intervals of 200 kb, the maximum
 likelihood of a model with a constant recombination rate is compared
 to the maximum likelihood of a model in which the central 2 kb is a
 recombination hotspot (likelihoods are approximated by the composite
 likelihood method of Hudson 2001).  The observed difference in log
 composite likelihood is compared against the null distribution, which
 is obtained by simulations.  Simulations are matched for sample size,
 SNP density, background recombination rate and an approximation to the
 ascertainment scheme (a panel of 12 individuals with a Poisson number
 of chromosomes, mean 1, sampled from this panel, using a single hit
 ascertainment scheme for dbSNP and resequencing of 16 individuals for
 the 10 HapMap ENCODE regions).  Evidence for a hotspot was assessed in
 each analysis panel separately (YRI, CEU and combined CHB+JPT), and
 p-values were combined such that a hotspot requires that two of the
 three populations show some evidence of a hotspot (p &lt; 0.05) and at
 least one population showed stronger evidence for a hotspot
 (p &lt; 0.01). Hotspot centers were estimated at those locations where
 distinct recombination rate estimate peaks occurred with at least a factor 
 of two separation between peaks, within the low p-value intervals.
 </P>
 
 <H2>Validation</H2>
 <P>
 This approach has been validated in three ways: by extensive
 simulation studies and by comparisons with independent estimates of
 recombination rates, both over large scales from the genetic map and
 over fine scales from sperm analysis.  Full details of validation can be 
 found in McVean <em>et al</em>. (2004) and Winckler <em>et al</em>. (2005).
 </P>
 
 <H2>Credits</H2>
 <P>
 The data are based on <A HREF="https://www.ncbi.nlm.nih.gov/variation/news/NCBI_retiring_HapMap/" TARGET=_blank>HapMap</A> 
 release 16a.  The recombination hotspots were ascertained by Simon Myers from the
-<A HREF="http://mathgen.stats.ox.ac.uk/"
+<A HREF="https://mathgen.stats.ox.ac.uk/"
 TARGET=_blank>Mathematical Genetics Group</A> at the University of Oxford.
 </P>
 
 <H2>References</H2>
 <P>
 Crawford, D.C., Bhangale, T., Li, N., Hellenthal, G., Rieder, M.J., 
 Nickerson, D.A. and Stephens, M.
 <A HREF="https://www.nature.com/articles/ng1376"
 TARGET=_blank>Evidence for substantial fine-scale variation in recombination 
 rates across the human genome</A>.
 <em>Nat Genet.</em> <B>36</B>(7), 700-6 (2004).
 </P>
 <P>
 Daly, M.J., Rioux, J.D., Schaffner, S.F., Hudson, T.J. and  Lander, E.S.
 <A HREF="https://www.nature.com/articles/ng1001-229"
 TARGET=_blank>High-resolution haplotype structure in the human genome</A>.
 <em>Nat Genet.</em> <B>29</B>(2), 229-32 (2001).
 </P>
 <P>
 Gabriel, S.B., Schaffner, S.F., Nguyen, H., Moore, J.M., Roy, J., Blumenstiel, 
 B., Higgins, J., DeFelice, M., Lochner, A., Faggart, M. <em>et al</em>.
 <A HREF="https://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=12029063&query_hl=3"
 TARGET=_blank>The structure of haplotype blocks in the human genome</A>.
 <em>Science</em> <B>296</B>(5576), 2225-9 (2002).
 </P>
 <P>
 Hudson, R. R. Two-locus sampling distributions and their application.  <I>Genetics</I> <B>159</B>(4):1805-1817 (2001).
 </P>
 <P>
 Jeffreys, A.J,. Kauppi, L. and Neumann, R.
 <A HREF="https://www.ncbi.nlm.nih.gov/entrez/query.fcgi?holding=npg&cmd=Retrieve&db=PubMed&list_uids=11586303&dopt=Abstract"
 TARGET=_blank>Intensely punctate meiotic recombination in the class II region 
 of the major histocompatibility complex</A>.
 <em>Nat Genet.</em> <B>29</B>(2), 217-22 (2001).
 </P>
 <P>
 McVean, G.A., Myers, S.R., Hunt, S., Deloukas, P., Bentley, D.R. and Donnelly, 
 P.
 <A HREF="https://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=15105499&query_hl=9"
 TARGET=_blank>The fine-scale structure of recombination rate variation in the 
 human genome</A>.
 <em>Science</em> <B>304</B>(5670), 581-4 (2004).
 </P>
 <P>
 Winckler, W., Myers, S.R., Richter, D.J., Onofrio, R.C., McDonald, G.J., 
 Bontrop, R.E., McVean, G.A., Gabriel, S.B., Reich, D., Donnelly, P. 
 <em>et al</em>.
 <A HREF="https://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=15705809&query_hl=9"
 TARGET=_blank>Comparison of fine-scale recombination rates in humans and 
 chimpanzees</A>.
 <em>Science</em> <B>308</B>(5718), 107-11 (2005).
 </P>