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Evolutionary ecology research
2016;17 603-617.

A fluorescence hybridization (FISH) protocol for stickleback tissue.

Noelle James, Xiaochen Liu, Alison Bell
Author Information
  1. Noelle James: Neuroscience Program, University of Illinois at Urbana-Champaign, Urbana, Illinois, USA.
  2. Xiaochen Liu: Carl R. Woese Institute for Genomic Biology, University of Illinois at Urbana-Champaign, Urbana, Illinois, USA.
  3. Alison Bell: Neuroscience Program, University of Illinois at Urbana-Champaign, Urbana, Illinois, USA.
PMID: 29046617

Abstract

BACKGROUND: Threespine stickleback are an important model for behaviour and evolutionary studies. A growing number of quantitative trait loci (QTL) and gene expression studies are identifying genes related to ecologically important traits in sticklebacks. In order to visualize the expression of candidate genes, we developed a fluorescence hybridization (FISH) protocol.
METHODS: We present a protocol for FISH on fresh or flash-frozen dissected tissue, using either cryo- or Paraffin embedding. The protocol covers probe design guidelines and synthesis, sample embedding, sectioning, and the hybridization process. The protocol is optimized for brain tissue. Key steps for modifying the protocol for other tissues are noted.
RESULTS: The FISH protocol resulted in specific labelling under all combinations of dissection and embedding conditions. Paraffin embedding preserved morphology better than cryo-embedding. We provide representative results showing the expression of glial fibrillary acidic protein (), oxytocin receptor (), and tyrosine hydroxylase () in the brain.

Keywords

Gasterosteus aculeatus RNA fluorescence in situ hybridization fluorescence methods gene expression gene localization in situ hybridization threespine stickleback

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Grants

  1. R01 GM082937/NIGMS NIH HHS
Journal Article

Word Cloud

Created with Highcharts 10.0.0protocolhybridizationexpressionfluorescenceFISHembeddingsticklebackgenetissueimportantstudiesgenesbrainsituBACKGROUND:ThreespinemodelbehaviourevolutionarygrowingnumberquantitativetraitlociQTLidentifyingrelatedecologicallytraitssticklebacksordervisualizecandidatedevelopedMETHODS:presentfreshflash-frozendissectedusingeithercryo-paraffincoversprobedesignguidelinessynthesissamplesectioningprocessoptimizedKeystepsmodifyingtissuesnotedRESULTS:resultedspecificlabellingcombinationsdissectionconditionsParaffinpreservedmorphologybettercryo-embeddingproviderepresentativeresultsshowingglialfibrillaryacidicproteinoxytocinreceptortyrosinehydroxylaseGasterosteusaculeatusRNAmethodslocalizationthreespine

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