Dahlquist:Evo-Ed Evolution of Lactase Persistence: Difference between revisions
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* [http://jaspar.genereg.net/cgi-bin/jaspar_db.pl pou2f1 entry for mouse in jaspar w/PWM] | * [http://jaspar.genereg.net/cgi-bin/jaspar_db.pl pou2f1 entry for mouse in jaspar w/PWM] | ||
* [http://autosome.ru/HOCOMOCO/modelDetails.php?tf=PO2F1&model=f1 PWM for pou2f1 for human from HOCOMOCO] | * [http://autosome.ru/HOCOMOCO/modelDetails.php?tf=PO2F1&model=f1 PWM for pou2f1 for human from HOCOMOCO] | ||
* [9http://motifmap.ics.uci.edu/ MotifMap: genome-wide maps of regulatory elements.] | |||
== Open Education Resources == | == Open Education Resources == |
Revision as of 17:02, 18 June 2015
This page contains notes from the BioQUEST Curriculumm Consortium Summer Workshop 2015 project on the Evo-Ed Case: The Evolution of Lactase Persistence.
Other Case Studies
Annotated Bibliography
- Boyd, M., Bressendorff, S., Møller, J., Olsen, J., & Troelsen, J. T. (2009). Mapping of HNF4α target genes in intestinal epithelial cells. BMC gastroenterology, 9(1), 68.
- Fang, L., Ahn, J. K., Wodziak, D., & Sibley, E. (2012). The human lactase persistence-associated SNP− 13910* T enables in vivo functional persistence of lactase promoter–reporter transgene expression. Human genetics, 131(7), 1153-1159. (PubMedCentral)
- Fang, R., Santiago, N. A., Olds, L. C., & Sibley, E. (2000). The homeodomain protein Cdx2 regulates lactase gene promoter activity during enterocyte differentiation. Gastroenterology, 118(1), 115-127.
- behind paywall
- Gerstein, M. B., Kundaje, A., Hariharan, M., Landt, S. G., Yan, K. K., Cheng, C., ... & Zilberman-Schapira, G. (2012). Architecture of the human regulatory network derived from ENCODE data. Nature, 489(7414), 91-100.
- Grand, R. J., Montgomery, R. K., Chitkara, D. K., & Hirschhorn, J. N. (2003). Changing genes; losing lactase. Gut, 52(5), 617-619.
- nice review
- Jensen, T. G., Liebert, A., Lewinsky, R., Swallow, D. M., Olsen, J., & Troelsen, J. T. (2011). The− 14010* C variant associated with lactase persistence is located between an Oct-1 and HNF1α binding site and increases lactase promoter activity. Human genetics, 130(4), 483-493.
- behind paywall
- Kuokkanen, M., Enattah, N. S., Oksanen, A., Savilahti, E., Orpana, A., & Järvelä, I. (2003). Transcriptional regulation of the lactase-phlorizin hydrolase gene by polymorphisms associated with adult-type hypolactasia. Gut, 52(5), 647-652.
- Lewinsky, R. H., Jensen, T. G., Møller, J., Stensballe, A., Olsen, J., & Troelsen, J. T. (2005). T− 13910 DNA variant associated with lactase persistence interacts with Oct-1 and stimulates lactase promoter activity in vitro. Human molecular genetics, 14(24), 3945-3953.
- Linnell, J., Mott, R., Field, S., Kwiatkowski, D. P., Ragoussis, J., & Udalova, I. A. (2004). Quantitative high‐throughput analysis of transcription factor binding specificities. Nucleic acids research, 32(4), e44-e44.
- Mattar, R., de Campos Mazo, D. F., & Carrilho, F. J. (2012). Lactose intolerance: diagnosis, genetic, and clinical factors. Clinical and experimental gastroenterology, 5, 113. (PubMedCentral)
- Olds, L. C., Ahn, J. K., & Sibley, E. (2011). − 13915* G DNA polymorphism associated with lactase persistence in Africa interacts with Oct-1. Human genetics, 129(1), 111-113. (PubMedCentral)
- Pennacchio, L. A., Bickmore, W., Dean, A., Nobrega, M. A., & Bejerano, G. (2013). Enhancers: five essential questions. Nature Reviews Genetics, 14(4), 288-295.
- Pruimboom, L., Fox, T., & Muskiet, F. A. (2014). Lactase persistence and augmented salivary alpha-amylase gene copy numbers might have been selected by the combined toxic effects of gluten and (food born) pathogens. Medical hypotheses, 82(3), 326-334.
- behind paywall
- Schultheis, P. J., & Bowling, B. V. (2011). Analysis of a SNP linked to lactase persistence: An exercise for teaching molecular biology techniques to undergraduates. Biochemistry and Molecular Biology Education, 39(2), 133-140.
- Sibley, E., & Ahn, J. K. (2011). Theodore E. Woodward Award: lactase persistence SNPs in African populations regulate promoter activity in intestinal cell culture. Transactions of the American Clinical and Climatological Association, 122, 155. (PubMedCentral)
- Stegmann, A., Hansen, M., Wang, Y., Larsen, J. B., Lund, L. R., Ritié, L., ... & Olsen, J. (2006). Metabolome, transcriptome, and bioinformatic cis-element analyses point to HNF-4 as a central regulator of gene expression during enterocyte differentiation. Physiological genomics, 27(2), 141-155.
- Link to database of mouse enterocyte expression data
- BUT the gene encoding Lactase-phlorizin hydrolase was not on the Affy chip in this dataset.
- Troelsen, J., Mitchelmore, C., Spodsberg, N., Jensen, A., Noren, O., & Sjostrom, H. (1997). Regulation of lactase–phlorizin hydrolase gene expression by the caudal-related homoeodomain protein Cdx-2. Biochem. J, 322, 833-838.
- Troelsen, J. T. (2005). Adult-type hypolactasia and regulation of lactase expression. Biochimica et Biophysica Acta (BBA)-General Subjects, 1723(1), 19-32.
- behind paywall
- Wang, Z., Fang, R., Olds, L. C., & Sibley, E. (2004). Transcriptional regulation of the lactase-phlorizin hydrolase promoter by PDX-1. American Journal of Physiology-Gastrointestinal and Liver Physiology, 287(3), G555-G561.
- Wang, Z., Maravelias, C., & Sibley, E. (2006). Lactase gene promoter fragments mediate differential spatial and temporal expression patterns in transgenic mice. DNA and cell biology, 25(4), 215-222.
- behind paywall
- Siggers, T., & Gordân, R. (2013). Protein–DNA binding: complexities and multi-protein codes. Nucleic acids research, gkt1112.
- Wilt, T. J., Shaukat, A., Shamliyan, T., Taylor, B. C., MacDonald, R., Tacklind, J., ... & Levitt, M. (2010). Lactose intolerance and health. Evidence Reports/Technology Assessments, No. 192 (NCBI Bookshelf)
Protein Structure Exercises
POU2F1 (aka OCT-1)
Background
In this exercise, you will explore the structure of a the regulatory transcription factor POU2F1 (OCT-1) from human, bound to its regulatory DNA. The binding of POU2F1 to an enhancer upstream of the LCT gene that encodes lactase activates lactase expression. Variants in the enhancer motif are responsible for lactase persistence, which enables humans to digest the milk sugar, lactose, after weaning.
Learning objectives
At the end of this exercise, the student should be able to
- define and show the differences between different levels of protein structure: primary, secondary, tertiary, and quaternary.
- locate a domain and explain its relationship to the levels of structure mentioned above
- identify the types of amino acid side chains that interact with the DNA and name the types of weak, noncovalent bonds responsible for the interaction
- describe the relationship of structure to function for POU2F1 and how this relates to lactase persistence
SNP Data and Human Genome Browser
- NCBI Variation Viewer: rs4988235
- NCBI dbSNP: rs4988235
- UCSC genome browser: rs4988235 (via blat search)
Gene Regulatory Network
- OCT-1 Gene Regulatory Network in Human
- LCT gene page in NCBI gene database
- http://www.regulatorynetworks.org/ human
- pazar
- oreganno
- Genome-wide map of regulatory interactions in the human genome
- pou2f1 entry for mouse in jaspar w/PWM
- PWM for pou2f1 for human from HOCOMOCO
- [9http://motifmap.ics.uci.edu/ MotifMap: genome-wide maps of regulatory elements.]
Open Education Resources
- http://www.hippocampus.org
- http://www.thenrocproject.org/#/
- http://www.goorulearning.org
- https://www.oercommons.org/
- https://nsdl.oercommons.org/
- http://openrefine.org
- http://learningregistry.org
- http://www.lrmi.net
- http://www.corestandards.org
- http://www.dataone.org
- http://opencontext.org: for archaeology
- http://openstaxcollege.org
- MOOC image
- http://wikiseat.org
Assessment
- QRLA
- BioSQuaRE v4 online, via Qualtrics