Vistas in Student Involvement in Genomics Research Laura L Mays Hoopes Pomona College 2008.
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Transcript of Vistas in Student Involvement in Genomics Research Laura L Mays Hoopes Pomona College 2008.
Step 1: Expression Microarrays• GCAT support for materials, colleagues for consultations• Student-originated experiments with predictions and data analysis
– Yeast replicative aging (Yiu, G* Alejandra McCord*, Laty Cahoon, Alison Wise*, Rishi Jindal*, Jennifer Hardee*, Allen Kuo*, Michelle Yuen Shimogawa*, Michelle Wu, John Kloke, Johanna Hardin, and Laura L. Mays Hoopes. Gene Expression During Replicative Aging in Yeast. J Gerontology :Biological Sciences 63A (1):21-34 (2008.)
– Todd Eckdahl, Adam Brown, Steven Hart, Kelly Malloy, Laurie Heyer, Martha Shott, Laura L. Mays Hoopes, Gloria Yiu*, Laurie Heyer. Microarray analysis of the in vivo sequence preferences of a minor groove binding drug BMC Genomics. (2008), 9:32.
– Stress-related TFs in yeast aging (Cameron et al, ms in preparation)
– Gene expression during meiotic aging clock resetting (Zhao et al, ms in preparation)
Clustering of Genes Significantly Changed in Expression at 12g and
18-20g
mRNAs increased in aging
mRNAs decreased in aging
1g 12g 20g
Data: Gloria Yiu, Alejandra McCord, Rishi Jindal, Jennifer Hardee, Allen Kuo, Michele Yuen, Laty Cahoon, Michele Wu.
BioConductor Showed Functional Groups of Dysregulated Genes
Significant mRNA Changes in Aging
Nucleolus/ribosome Carbohydrate metabolism Transcription&Translation
Golgi & ER Mating N anabolism
Cell wall,Osmotic Transport Stress, HS, Chaperones
Methylation DNA Replication, Repair Other
Yiu et al, J Gerontol, Jan, 2008
Important Molecule in Yeast Aging: Sir2 Protein
• Sir2 is a NAD+-dependent histone deacetylase that compacts chromatin
• Sir2 turns off gene expression
• Sir2 moves from the telomeres to the ribosomal RNA genes during aging in yeast.
How Do We Know Sir2 Is Important in Aging?
• Deletions of sir2 have ~30% shorter life spans than wild type
• Strains with one extra copy of SIR2 gene have life spans extended ~30%.
• Homologs in animals sometimes affect life span
Predictions Related to SIR2 in Aging
• Sir2 might increase in aging and/or an enzyme that produces NAD+, its coenzyme, could increase and activate it more
• Sir2/Sir3/Sir4 proteins start at telomeres in young cells; move to rDNA during aging, thus telomeric genes could turn on as yeast get older
Expression Patterns of Yeast Chromosomes with Age
Yellow: Y=O, Red: O>>Y (More mRNA, Green O<<Y (Less mRNA)
1g (yellow) 12g (some red/green) 20g (more red/green)
Closeup of Left Telomeric Regions of Chromosomes 1-7 at 20 g
Conclusion: While some ‘red’ or induced genes are telomeric, there’s no special concentration of up-regulated genes there.
green chromosome axis
genes on Watson strand
genes on Crick strandleft telomere
average mRNA compared to 1g, 7 arrays
Gene: 1g 12g 20g
SIR2 0.731 0.812 0.858
PNC1 1.13 1.47 3.58 **
SIR3 0.435 1.783 1.352
HST1 1.154 1.146 1.128
HST2 1.462 1.421 1.52
HST4 0.554 0.996 1.164
** Statistically significant at p < 0.05
NB HST3 and SIR4 data rejected (excessive variation)
Sir2 Related Aging Gene Expression
In agreement with Sinclair’s data on Pnc1, its mRNA increased and the NAD+ produced by the enzyme could be activating Sir2.
Environmental Stress Response
• Gasch et al. (Mo Bio Cell, 2000, 11:4241) found about 900 genes are affected similarly in expression by different environmental stresses
• Gene groups include ribosomal genes, stress response genes, a few DNA repair genes
• Some ESR genes are induced by stresses and others are repressed
Genes with STRE –containing promoters such as CTT1(4.27x), SIP18 (4.74x), GRE1(5.97x), GRE2 (2.14x)
Positive Regulation Negative Regulation
C source limitation
Reg1(3.099x)-Glc7 Phosphatase moves Msn2,4 to nucleus
Other regulatory factors: Sds22 (5.42x), Glc8 (3.607x), Shp1 (2.035x), Reg2 (7.9x)), GCN1 (4.9x)
Msn2 (1.33x) and Msn4 (3.756x), TFs
Ras
Protein kinase A, cAMP (BCY1, TPK1, 2, 3)
Phosphate sends Msn2, 4 to cytoplasm
Sip2 2.41x
Snf1Snf4Sip1 protein kinase
Protein Phosphatase/Kinase Stress Response Cascades Affected by Aging
18-20g ratio to 1g expression given in parentheses
Pseudostationary Phase Features
Hexose Transporter mRNAs at 18-20g (average 2.77 fold)
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•HXT induction
•Glycogen gene induction
•SNZ or snooze gene induction
•Diauxic response gene induction/repression
•Shift from ethanolic anaerobic fermentation to aerobic respiration
HOWEVER: KEPT IN LOG PHASE, NOT IN STATIONARY PHASE!!
Why increase glucose import? Glucose is not all gone! Hypothesis: it’s because of big sizes of elderly cells so it’s hard to diffuse glucose within cells.
Pseudostationary Phase Component: Diauxie
• Yeast begin using glucose through glycolysis with ethanol as the end product
• When they near stationary phase glucose in the medium is almost exhausted, they switch metabolism
• During the switch, they begin to metabolize ethanol aerobically via the TCA cycle, electron transport, and oxidative phosphorylation
• During the switch, they also induce/repress some of the environmental stress response genes, for example ribosome synthesis is switched off in stress and in diauxie
Yeast Diauxie Growth Curve from Joseph DeRisi, V. Iyer, P.O. Brown, Science
278:660 (1997)
Pre-Diauxie(Log phase)
Post Diauxic Shift
Aging mRNA re Metabolic Changes
OLE1, lipid metabolism
COX20, electron transport
HXT15, hexose import
Largest Category of Aging Expression Changes: Nucleolus/Ribosome
Vacuole
Nucleus
Rough ERRibosome
Nucleolus; rDNA is transcribed and rRNA is processed; ribosomes are assembled
Ribosomes are exported from nucleolus/nucleus to cytoplasm
Brief review: making ribosomes.
Nucleolus/Ribosome Potential Regulons in Aging Yeast Cells
Nucleolar “RBB” and Ribosomal Protein (RP) Gene regulons. Numbers are the number of genes in each group.
83
104
19
Overlap in Aging and RBB sets
14
107
74
Overlap in Aging and RP sets
RBB overlaps but probably isn’t the aging regulon, lots of RBB genes unchanged in aging(83)
RP Tentative aging regulon, only 14 RP genes that aren’t changed in aging.
Could DNA Damage Contribute to Yeast Aging?
• Overall, DNA repair mRNAs are unchanged from in young cells
• Gene from one DNA repair pathway are significantly overexpressed for many genes in the pathway: NER
• The overexpression level of NER is low (only about 2 fold) at 18-20g. (Yiu et al, 2008)
NER Gene Induction, p <0.05
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Genes with changes significant at p < 0.05 are RAD2, RAD3, RAD4, RAD7, RAD10, RAD14, and RAD28. NER genes without significant differences were RAD1, 16, 23, and 23.
mRNAs Increased for Nucleotide Excision Repair Pathway
Yiu et al, 2008
Overall Summary of Gene Expression Changes in Aging Yeast
• Environmental Stress Response turned on (1/2 of the ~900 genes)
• Protein Phosphatase1 subunits and stress response up-regulated
• Metabolism switched: Pseudostationary phase– Respiration up, fermentation and fat metabolism down – Anabolism down-regulated
• Nucleolar/Ribosome functions down-regulated (RP, some ribosome assembly functions)
• DNA Repair: NER up-regulated; rest unchanged• Methylation: down-regulated• Cell Wall functions: up-regulated• Mating/Sporulation functions: down-regulated
Data of Yiu, Cameron, Cahoon, McCord, Jindal, Hardee, Yuen, Wu, Wise, Hardin, and Hoopes J Gerontology, January, 2008.
What’s Good About Microarray Student Research?
• Students can see the mRNAs from the entire genome, not just the mRNAs predicted to change. Holistic/discovery approach makes them see the whole organism better.
• Whole pathway changes in expression are robust and repeatable, while single gene changes can be false positive/false negative.
What’s Frustrating about Microarray Research?
• There is too much data. For example our published study had 27 datasets with ~6000 pieces of data each. You need a good statistical collaborator if possible.
• Good data, passing the scanner’s quality control, may not be “real.”
• An independent method should be used to confirm important findings, such as qPCR.
Step 2: Beyond Expression Arrays
• CGH…comparative genomic hybridization, enables you to search for deletions or insertions of major regions.
• ChIP on chip…Chromatin Immuno Precipitation isolates DNA where a protein is bound; DNA is isolated and hybridized to identify targets in vivo.
• Nucleosomal placement…cut chromatin with Micrococcal nuclease, see which parts of the DNA are still there to hybridize with the array. Need genomic DNA arrays, not just ORFs.
Step 3: Beyond Arrays…
• Massively parallel sequencing. New generation of sequencers can be used to examine mRNAs of a cell (Nagatakshmi et al, Science 320:1344, 2008). More next slide.
• Single molecule sequencing. Anticipated generation after next sequencers, which have been demostrated in principle, can sequence individual molecules for 1500 or so nucleotides in massively parallel sequencers.
The 454 Sequencer
Genome sequencing in microfabricated high-density picolitre reactors Margulies, M. Eghold, M. et al. Nature. 2005 Sep 15; 437(7057):326-7 454's ground breaking Nature paper describing the 454 Sequencing technology
1. Fluidic Assembly
2. Flow chamber with fiber optic slide
3. CDC camera
4. Computer
First 454 Model’s Statistics
Genome sequencing in microfabricated high-density picolitre reactors Margulies, M. Eghold, M. et al. Nature. 2005 Sep 15; 437(7057):326-7
Advantages of Parallel Sequencing over Microarrays for Expression
• Replication not of just a few standards as on our WU slides but of every mRNA sequenced
• Can see direct evidence for alternative splice variants and assess prevalence
• Can detect overlapping genes easily
• Can find genes not predicted by gene-calling software
Yeast Transcriptome
Nagalakshmi et al. Science 320:1344 (2008) The Transcriptional Landscape of the Yeast Genome Defined by RNA Sequencing.
deletion
Time to Guess:
• What percent of DNA in yeast is not expressed?– 52%– 24%– 12%
See next slide for data!
Yeast, cont 4: Discovery of new gene by sequencing
Study found a transcribed gene in this region that was not previously annotated (khaki bar; see transcription on upper graph).