Merge pull request #5205 from solgenomics/topic/generic_trial_upload

[sgn.git] / cgi-bin / community / feature / 200503.pl

use strict;
use CXGN::Page;
my $page=CXGN::Page->new('200503.html','html2pl converter');
my $stylesheet=<<END_STYLESHEET;
<style type="text/css">
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$page->header('Stack/Anderson Lab', undef, $stylesheet);
print<<END_HEREDOC;

  <center>
    <h1>Stack/Anderson Lab</h1>
  </center>

  <p class="footnote"><img src="/static_content/community/feature/200503-1.png" border="0" width=
  "442" height="212" alt="Stack/Anderson Lab Lab" /><br />
  <strong>Front Row (left to right):</strong> Dr. Lorrie Anderson
  (assistant professor), Ann Lai (research associate), Jia Cheng
  (graduate student), Stephanie Lum (undergraduate). <strong>Back
  Row (left to right):</strong> Joe Qiao (graduate student), Kevin
  Su (undergraduate), Dr. Stephen Stack (professor), Suzanne Royer
  (research associate), Erin Benson (undergraduate), Song-Bin Chang
  (post doc). Absent from photo: Brittany Howard
  (undergraduate).</p>

  <p>We work primarily with two proteinaceous structures: the
  synaptonemal complex (SC) and recombination nodules (RNs). The SC
  looks like a railroad track that is formed between synapsed
  homologous chromosomes, and RNs are 100 nm particles that occur
  on SCs at sites where crossing over occurs and where chiasmata
  will form later. We pioneered a technique for spreading complete
  sets of plant SCs for analysis by electron microscopy. We use
  this technique to determine the pattern and frequency of crossing
  over in wild type plants and in plants with chromosome
  aberrations such as translocations and inversions.</p>

  <p class="footnote" style=
  "float:right; width:375; text-align:center;"><img src=
  "/static_content/community/feature/200503-2.png" border="0" width="350" height="190" alt=
  "FISH on tomato synaptonemal complexes" /><br />
  Fluorescence in situ hybridization (FISH) on spreads of tomato
  synaptonemal complexes.</p>

  <p>We are particularly interested in the relation between genes
  and chromosome structure and the physical relation of
  recombination proteins to SCs and RNs. Ultimately we would like
  to determine the roles of SCs and RNs in crossing over and
  interference.</p>

  <p>This is an exciting time in cytogenetics with so much new
  information, so many interesting questions, and so many new
  techniques and instruments to help find the answers. All that
  must be added for continued progress is imagination and hard
  work.</p>

  <p>Currently we are involved in the following projects:</p>

  <ol type="I" style="margin-left: 75px; text-align: justify;">
    <li>Fluorescence in situ hybridization (FISH) on spreads of
    tomato synaptonemal complexes (SCs = pachytene chromosomes) to
    determine the physical location of tomato DNA inserts in
    bacterial artificial chromosomes (BACs) (See chromosome image
    above.). FISH is integral to the tomato genome sequencing
    project 1) to keep the sequencing effort confined primarily to
    euchromatin, 2) to locate problem BACs, and 3) to define the
    size of gaps in chromosome walks.</li>

    <li>Light and electron microscopic immunolocalization of
    proteins thought to be involved in recombination. This work
    concentrates on the timing of the appearance and disappearance
    of these proteins in relation to the SC and recombination
    nodules (RNs). See figure below.</li>

    <li>Light and electron microscopic characterization of
    chiasmata and RNs in maize mutants that show changes in the
    rate and/or location of crossing over.</li>

    <li>Spreading SCs from both plants and mammals to characterize
    the effects of chromosome aberrations such as translocations
    and inversions on the number and distribution of crossover
    events as indicated by RNs.</li>
  </ol>

  <h2>Contact Information</h2>

  <p class="footnote" style=
  "float:right; width:400; text-align:center; font-size: smaller;">
  <img src="/static_content/community/feature/200503-3.png" border="0" width="374" height="263" alt=
  "Tomato immunolabeling" /><br />
  Tomato immunolabeling: The photo is of a tomato spread (early
  zygotene, as the chromosomes are beginning to synapse)
  immunolabeled with Mre11 (green spots) and Smc1 (red). Mre11 is a
  DNA double-strand break repair protein and Smc1 is labeling the
  chromosome core (therefore enabling us to see the synaptonemal
  complex under fluorescent microscopy).</p>

  <p><strong>Stephen Stack</strong><br />
  Department of Biology<br />
  Colorado State University<br />
  Fort Collins, Colorado 80523-1878<br />
  USA<br />
  Telephone: 970-491-6802<br />
  FAX: 970-491-0649<br />
  E-mail <a href=
  "mailto:sstack\@lamar.colostate.edu">sstack\@lamar.colostate.edu</a></p>

  <p><strong>Lorinda Anderson</strong><br />
  Department of Biology<br />
  Colorado State University<br />
  Fort Collins, Colorado 80523<br />
  USA<br />
  Telephone: 970-491-4856<br />
  FAX: 970-491-0649<br />
  E-mail: <a href=
  "mailto:lorrie\@lamar.colostate.edu">lorrie\@lamar.colostate.edu</a></p><br clear="all" />


  <h2>Selected Publications</h2>

  <p class="bibliography">Sherman, J.D. and S. M. Stack. 1995.
  Two-dimensional spreads of synaptonemal complexes from
  solanaceous plants. VI. High resolution recombination nodule map
  for tomato (Lycopersicon esculentum). Genetics 141:683-708</p>

  <p class="bibliography">Peterson, D.G., H.J. Price, J.S.
  Johnston, and S.M. Stack. 1996. DNA content of heterochromatin
  and euchromatin in tomato (Lycopersicon esculentum) pachytene
  chromosomes. Genome 39:77-82</p>

  <p class="bibliography">Peterson, D.G., K.S. Boehm, and S.M.
  Stack. 1997. Isolation of milligram quantities of nuclear DNA
  from tomato (Lycopersicon esculentum), a plant containing high
  levels of polyphenolic compounds. Plant Molec. Biol. Reporter
  15:148-153</p>

  <p class="bibliography">Peterson, D.G., W.R. Pearson, S.M. Stack.
  1998. Characterization of the tomato (Lycopsersicon esculentum)
  genome using in vitro and in situ DNA reassociation. Genome
  41:346-356</p>

  <p class="bibliography">Peterson, D.G., N.L.V. Lapitan, and S.M.
  Stack. 1999. Localization of single- and low-copy sequences on
  tomato synaptonemal complex spreads using fluorescence
  hybridization (FISH). Genetics 152:427-439</p>

  <p class="bibliography">Stack, S.M. and L.K. Anderson. 2001. A
  model for chromosome structure during the mitotic and meiotic
  cell cycles. Chromosome Research 9:175-198</p>

  <p class="bibliography">Anderson, L.K. and S.M. Stack 2001.
  Distribution of early recombination nodules on zygotene bivalents
  from plants. Genetics 159:1259-1269</p>

  <p class="bibliography">Anderson, L.K., K.D. Hooker, and S.M.
  Stack 2001. The distribution of early recombination nodules on
  zygotene bivalents from plants. Genetics 159:1259-1269</p>

  <p class="bibliography">Stack, S.M. and L.K. Anderson 2002.
  Crossing over as assessed by late recombination nodules is
  related to the pattern of synapsis and the distribution of early
  recombination nodules in maize. Chromosome Research
  10:329-345</p>

  <p class="bibliography">Anderson, L.K. and S.M. Stack 2002.
  Meiotic recombination in plants. Current Genomics 3:507-526</p>

  <p class="bibliography">Tenaillon, M.I., M.C. Sawkins, L.K.
  Anderson, S.M. Stack, J. Doebley, and B.S. Gaut 2002. Patterns of
  diversity and recombination along chromosome 1 of maize (Zea mays
  ssp. Mays L.) Genetics 162:1401-1413</p>

  <p class="bibliography">Anderson, L.K., G.C. Doyle, B. Brigham,
  J. Carter, K.D. Hooker, A. Lai, M. Rice, and S.M. Stack. 2003.
  High resolution Crossover maps for each bivalent of Zea mays
  using recombination nodules. Genetics 165:849-865.</p>

  <p class="bibliography">Anderson, L.K., N. Salameh, H.W. Bass,
  L.C. Harper, W.Z. Cande, G. Weber, and S.M. Stack. 2004.
  Integrating genetic linkage maps with pachytene chromosome
  structure in maize. Genetics 166:1923-1933.</p>
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