Title: Macroarray technology
1 Macroarray technology
2Overview
Lecture One How to obtain cDNA clones to spot on
macroarrays How macroarrays are spotted
Lecture Two Normalization and analysis of
data Demonstration of macroarray spotting
3Macroarray vs. microarray
Macro array Hundreds of cDNA clones spotted on
array
Micro array Thousands of cDNA clones spotted on
array
4Getting clones to spot on macroarray
WHY???
5Getting clones to spot on macroarray
WHY??? cDNA clones are not readily available
from non-traditional animal or plant model systems
6Getting clones to spot on macroarray
Want to examine expression of genes in livers
of fish that are involved in detoxification or Ex
amine expression of genes involved in hypoxia in
sea corals. or _______
7Getting clones to spot on macroarray
Want to examine expression pattern of 3-4 genes
that you already have
8Getting clones to spot on macroarray
Want to examine expression pattern of 3-4 genes
that you already have
Slot blots Northerns RT PCR (Taq man)
X
Macroarrays
9Getting clones to spot on macroarray
Want to examine expression pattern of 3-4 genes
that you already have
Slot blots Northerns RT PCR (Taq man)
X
Macroarrays (15 or more clones)
10Getting 15 or more clones to spot on macroarray
Directed approach vs. non-directed approach
11Getting 15 or more clones to spot on macroarray
Directed approach
Design degenerate primers to desired genes (ex.
Carbonic Anhydrase) using known sequences in the
database.
12 Directed approach
Getting clones to spot on macroarray
Design degenerate primers to desired genes (ex.
Carbonic Anhydrase) using known sequences in the
database.
? Your species ?
Mouse
Human
Drosophila
Conserved region
Conserved region
Unique region
13 Directed approach
Getting clones to spot on macroarray
Design degenerate primers to desired genes (ex.
Carbonic Anhydrase) using known sequences in the
database.
? Your species ?
Mouse
Human
Drosophila
Conserved region
Conserved region
Unique region
14 Directed approach
Getting clones to spot on macroarray
Advantages
-Can target selective genes
15 Directed approach
Getting clones to spot on macroarray
Advantages
-Can target selective genes
Disadvantages
-Designing individual primer sets and testing
them is a time consuming process.
16 Non-Directed approach
Getting clones to spot on macroarray
17 Non-Directed approach
Getting clones to spot on macroarray
Want to examine expression of any genes in
livers of fish that are involved in
detoxification.
18 Non-Directed approach
Getting clones to spot on macroarray
Want to examine expression of any genes in
livers of fish that are involved in
detoxification. TECHNIQUES cDNA
libraries Differential display analysis Subtractiv
e hybridization
19cDNA libraries
Tissue
Modified from D. Moraga slide
20cDNA libraries
Tissue
Isolation
mRNA
Modified from D. Moraga slide
21cDNA libraries
Tissue
Isolation
mRNAs
Reverse Transcription
cDNAs
Modified from D. Moraga slide
22cDNA libraries
Population of different cDNAs
Left
Right
Arms of phage cloning vector
Modified from D. Moraga slide
23cDNA libraries
Population of different cDNAs
Left
Right
Arms of phage cloning vector
Modified from D. Moraga slide
24cDNA libraries
Population of different cDNAs
Left
Right
Arms of phage cloning vector
In vitro packaging
Modified from D. Moraga slide
25cDNA libraries
E. Coli
Modified from D. Moraga slide
26cDNA libraries
E. Coli
Plate
Modified from D. Moraga slide
27cDNA libraries
E. Coli
Plate
Modified from D. Moraga slide
28cDNA libraries
E. Coli
Plate
-In vivo excision -Sequence -Spot on array
Modified from D. Moraga slide
29cDNA libraries
Advantages
-If you already have a cDNA library, you can
easily obtain hundreds of clones to spot onto a
macroarray.
30cDNA libraries
Advantages
-If you already have a cDNA library, you can
easily obtain hundreds of clones to spot onto a
macroarray.
Disadvantages
-Generating a cDNA library is both time
consuming and expensive. -You may spot redundant
cDNAs onto the macroarray. -No guarantee
that any cDNA clones that you spot on the
macroarrays will be differential regulated.
31Differential Display Analysis
Genhunter
32Differential Display Analysis
Genhunter
mRNA
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
33Differential Display Analysis
Genhunter
mRNA
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Reverse transcribe
34Differential Display Analysis
Genhunter
mRNA
Anchor Primer (3)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Reverse transcribe
35Differential Display Analysis
Genhunter
mRNA
Anchor Primer (3)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Reverse transcribe
36Differential Display Analysis
Genhunter
mRNA
Anchor Primer (3)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Reverse transcribe
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
37cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
PCR Amplify
labeled dNTPs
38Anchor Primer (3)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
PCR Amplify
labeled dNTPs
39Anchor Primer (3)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Arbitrary Primers (80)
PCR Amplify
labeled dNTPs
40Anchor Primer (3)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Arbitrary Primers (80)
PCR Amplify
labeled dNTPs
X
Y
Z
41Anchor Primer (3)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Arbitrary Primers (80)
PCR Amplify
labeled dNTPs
X
Y
Z
Run on denaturing Polyacrylamide gel
42Anchor Primer (3)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Arbitrary Primers (80)
PCR Amplify
labeled dNTPs
X
Y
Z
Run on denaturing Polyacrylamide gel
43(No Transcript)
44Constant
Induced
Induced
45Constant
Induced
Induced
46Gel extract
PCR amplify
47Gel extract
PCR amplify
Ligate in vector, transformminiprep and
sequence
48Gel extract
PCR amplify
Ligate in vector, transformminiprep and
sequence
Spot sequences on arrays
49Differential Display Analysis
Genhunter
Advantages
-Technology is fairly simple. -You increase your
probability that the clones that you
spot on the macroarrays will be differentially
regulated.
50Differential Display Analysis
Genhunter
Advantages
-Technology is fairly simple. -You increase your
probability that the clones that you
spot on the macroarrays will be differentially
regulated.
Disadvantages
-It would be fairly expensive to get hundreds of
differentially expressed clones. -Hard to
identify the sequences that you clone in
the data base using genehunter technology.
51Differential Display Analysis
Genhunter
Anchor Primer (3)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Arbitrary Primers (80)
52Differential Display Analysis
Genhunter
Anchor Primer (3)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Arbitrary Primers (80)
53Differential Display Analysis
Qbiogene
Generate cDNA (similar to the Genehunter method)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
54Differential Display Analysis
Qbiogene
Generate cDNA (similar to the Genehunter method)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Restriction digest
55Differential Display Analysis
Qbiogene
Generate cDNA (similar to the Genehunter method)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Restriction digest
Ligate adapters
56Differential Display Analysis
Qbiogene
Generate cDNA (similar to the Genehunter method)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Restriction digest
Ligate adapters
57Differential Display Analysis
Qbiogene
Generate cDNA (similar to the Genehunter method)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Restriction digest
Ligate adapters
58Differential Display Analysis
Qbiogene
Generate cDNA (similar to the Genehunter method)
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Restriction digest
Ligate adapters
PCR Amplify
XYZ
59Differential Display Analysis
Qbiogene
Advantages
-Get sequences in the coding region.
60Differential Display Analysis
Qbiogene
Advantages
-Get sequences in the coding region.
Disadvantages
-Technology is NOT robust.
61Subtractive Hybridization Clontech
62Subtractive Hybridization
RNA from experimental tissue.
RNA from Control tissue.
Reverse transcription
63Subtractive Hybridization
RNA from experimental tissue.
RNA from Control tissue.
Reverse transcription
cDNA
cDNA
Digestion Addition of adapters Denature and mix
samples
64Subtractive Hybridization
RNA from experimental tissue.
RNA from Control tissue.
Reverse transcription
cDNA
cDNA
Digestion Addition of adapters Denature and mix
samples
Amt
cDNA pool
cDNA pool
65Subtractive Hybridization
RNA from experimental tissue.
RNA from Control tissue.
Reverse transcription
cDNA
cDNA
Digestion Addition of adapters Denature and mix
samples
Amt
cDNA subtracted out
66Subtractive Hybridization
RNA from experimental tissue.
RNA from Control tissue.
Reverse transcription
cDNA
cDNA
Digestion Addition of adapters Denature and mix
samples
PCR amplified, cloned, sequenced
Amt
cDNA subtracted out
67Subtractive Hybridization
Advantages
-Can generate hundreds of clones quickly.
68Subtractive Hybridization
Advantages
-Can generate hundreds of clones quickly.
Disadvantages
-Get redundant sequences. -Technology is slightly
expensive.
69Summary
Directed Degenerate primers Non-directed cDNA
library Differential display Subtractive
hybridization
70Strategy
Start with Differential Display or subtractive
hybridization
71Strategy
Start with Differential Display or subtractive
hybridization Fill in select genes with
degenerate primers
72Strategy
Start with Differential Display or subtractive
hybridization Fill in select genes with
degenerate primers and add Non-select genes
with cDNA library
73Overview
Lecture One Obtaining cDNA clones to spot on
macroarray Spotting cDNA clones on macroarray
74How arrays work.
75How arrays work.
cDNA clones spotted on array Obtained
from DD cDNA libraries Subtractive
hybridization Degenerate primers
76How arrays work.
cDNA clones spotted on array Obtained
from DD cDNA libraries Subtractive
hybridization Degenerate primers
TARGETS
77How arrays work.
RNA (total or mRNA) that is labeled
cDNA clones spotted on array Obtained
from DD cDNA libraries Subtractive
hybridization Degenerate primers
TARGETS
78How arrays work.
RNA (total or mRNA) that is labeled
PROBES
cDNA clones spotted on array Obtained
from DD cDNA libraries Subtractive
hybridization Degenerate primers
TARGETS
79How arrays work.
RNA (total or mRNA) that is labeled
PROBES
cDNA clones spotted on array Obtained
from DD cDNA libraries Subtractive
hybridization Degenerate primers
TARGETS
80How arrays work.
Matrix Membranes Glass slides Plastic slides
81Matrix (glass slides)
82Matrix (glass slides)
Advantages
-One N per slide. -Can spot thousands of
genes on slides.
83Matrix (glass slides)
Advantages
-One N per slide. -Can spot thousands of
genes on slides.
Disadvantages
-Generally higher background on
slides. -Unequal labeling efficiency.
84Matrix (Membranes)
85Matrix (Membranes)
Advantages
-Low background. -Technology well worked out.
86Matrix (Membranes)
Advantages
-Low background. -Technology well worked out.
Disadvantages
-Two membranes per N. -Can only spot
hundreds of cDNA clones.
87Matrix (Plastic)
?????
88Matrix (Plastic)
Advantages
-2 N per slide.
?????
89Matrix (Plastic)
Advantages
-2 N per slide.
Disadvantages
?????
-Technology is new.
90Spotting cDNA clones on macroarray
91Spotting cDNA clones on macroarray
Vector
92Spotting cDNA clones on macroarray
Vector
PCR amplify
93Spotting cDNA clones on macroarray
Vector
PCR amplify
PCR purify (kit) Concentrate (speedvac) Denature
94Spotting cDNA clones on macroarray
Vector
PCR amplify
PCR purify (kit) Concentrate (speedvac) Denature
Robotically spot 1-10 ng on membrane (UV
crosslink)
95Spotting cDNA clones on macroarray
TARGETS
96Spotting cDNA clones on macroarray
RNA (total or mRNA) that is labeled
Hybridize
TARGETS
97Spotting cDNA clones on macroarray
RNA (total or mRNA) that is labeled
Hybridize Wash
TARGETS
98Spotting cDNA clones on macroarray
RNA (total or mRNA) that is labeled
Hybridize Wash Detection
TARGETS
99Spotting cDNA clones on macroarray
RNA (total or mRNA) that is labeled
Hybridize Wash Detection Data analysis
TARGETS
100(No Transcript)
101 Macroarray technology
102Overview
Lecture One How to obtain cDNA clones to spot on
macroarrays How macroarrays are spotted
Lecture Two Normalization and analysis of
data Demonstration of macroarray spotting
103Some chemicals found in the environment influence
endocrine pathways (endocrine disruptors) Our
lab is interested in chemicals that disrupt the
estrogen pathway.
104Estrogen Pathway
Liver
Ovary
Estrogen
Oocyte
ER Receptor
Vtg
Follicle Cells
Adapted from Tata and Smith,1979 Rec Prog Horm Res
105Some endocrine disrupting chemicals found in the
environment that bind to ER
Ethinylestradiol used in oral
contraceptives. Methoxychlor organochlorine
used in pesticides. Nonylphenol by product of
alkyl phenols, which are
used in surfactants and emulsifiers.
106Estrogen Pathway
EC
Liver
ER Receptor
Vtg
107Estrogen Pathway
EC
Liver
ER Receptor
Expression in male and female fish
Vtg
Vtg synthesis and release
108Develop a macroarray chip which will be used to
monitor the presence and distribution of
estrogenic compounds in coastal habitats.
109Model system used to generate the targets and
probes were male sheepshead minnows (Cyprinodon
variegatus)
110Generating targets
54 clones that were spotted on the array
were isolated from differential display (DD)
analysis.
Some clones were E2 up-regulated. Some clones
were E2 down-regulated. Some clones were
constitutive.
111Various controls were also spotted on the arrays.
Spiking genes (Arabidopsis)
Hybridization efficiency.
112Spotting cDNA clones on macroarray
RNA (total or mRNA) that is labeled
RNA (total or mRNA) that is labeled
Hybridize
113Spotting cDNA clones on macroarray
RNA (total or mRNA) that is labeled Plus spiking
RNA
RNA (total or mRNA) that is labeled Plus spiking
RNA
Hybridize
Spiking genes spotted on arrays
114Spotting cDNA clones on macroarray
RNA (total or mRNA) that is labeled Plus spiking
RNA
RNA (total or mRNA) that is labeled Plus spiking
RNA
Hybridize
Spiking genes spotted on arrays
115Various controls were also spotted on the arrays.
Spiking genes (Arabidopsis) M13 sequence
(vector, but no cDNA insert)
Hybridization efficiency. How much binding to
vector sequence.
116pGEM
PCR amplify
Spot on a array
117pGEM
pGEM
PCR amplify
PCR amplify
Spot on a array
Spot on a array
118Various controls were also spotted on the arrays.
Spiking genes (Arabidopsis) M13 sequence
(vector, but no cDNA insert) Poly A
stretch
Hybridization efficiency. How much binding to
vector sequence. How much binding to poly
A regions of clones.
119Clones spotted on array were originally Isolated
from DD.
cDNA(s)
Coding region
5 UTR
3 UTR
AAAAAAAn
UCG
Arbitrary Primers (80)
120Various controls were also spotted on the arrays.
Spiking genes (Arabidopsis) M13 sequence
(vector, but no cDNA insert) Poly A
stretch Cot-1 repetitive sequences
Hybridization efficiency. How much binding to
vector sequence. How much binding to poly
A regions of clones. Pre-hybridization
efficiency.
121 RNA (total or mRNA) that is labeled
Pre-Hybridize Block with repetitive
sequences (salmon sperm, cot-1)
Hybridize
122 RNA (total or mRNA) that is labeled
Pre-Hybridize Block with repetitive
sequences (salmon sperm, cot-1)
Hybridize
Add ss or cot-1 Sequence to array
123Generating probes
Radiolabeled total RNA from livers of SHMs
that were exposed to estrogenic
compounds or TEG (control fish).
124Validation of arrays
How reproducible is one membrane to another?
Aliquots of identical RNA (from C or E2) were
hybridized to two separate membranes.
125Validation of arrays
Blot 1
Blot 2
126Normalization of arrays
127Normalization of arrays
Aliquot of RNA that is labeled
Aliquot of RNA that is labeled
Hybridize
128Normalization of arrays
Aliquot of RNA that is labeled If slightly more
RNA was labeled
Aliquot of RNA that is labeled
Hybridize
129Normalization of arrays
Aliquot of RNA that is labeled If slightly more
RNA was labeled
Aliquot of RNA that is labeled
Hybridize
Overall signal (of all the spots) will be
slightly higher
130Normalization of arrays
Aliquot of RNA that is labeled If slightly more
RNA was labeled
Aliquot of RNA that is labeled
Hybridize
Overall signal (of all the spots) will be
slightly higher
131Normalization of arrays
Aliquot of RNA that is labeled If slightly more
RNA was labeled
Aliquot of RNA that is labeled
Hybridize
C1 vs. C2 E1 vs. E2
Overall signal (of all the spots) will be
slightly higher
132Normalization of arrays
Aliquot of RNA that is labeled If slightly more
RNA was labeled
Aliquot of RNA that is labeled
Hybridize
C1 vs. C2 E1 vs. E2 C vs. E
Overall signal (of all the spots) will be
slightly higher
133Normalization of arrays (if expression pattern of
cDNAs that are spotted are normally distributed)
Spotted high numbers of clones (1000s)
134Normalization of arrays (if expression pattern of
cDNAs that are spotted are normally distributed)
Spotted high numbers of clones (1000s)
cDNAs
C
E
Expression
135Normalization of arrays (if expression pattern of
cDNAs that are spotted are normally distributed)
Spotted high numbers of clones (1000s)
cDNAs
C
E
Expression
136Normalization of arrays (if expression pattern of
cDNAs that are spotted are normally distributed)
Spotted high numbers of clones (1000s)
cDNAs
C
E
Expression
137Normalization of arrays (if expression pattern of
cDNAs that are spotted are normally distributed)
Spotted high numbers of clones (1000s)
cDNAs
C
E
Expression
138Normalization of arrays (if expression pattern of
cDNAs that are spotted are normally distributed)
Spotted high numbers of clones (1000s)
Up regulated genes
cDNAs
C
E
Expression
139Normalization of arrays (clones isolated from DD
are not normally distributed)
Spotted low numbers of clones (100s)
140Normalization of arrays (clones isolated from DD
are not normally distributed)
Spotted low numbers of clones (100s)
E
C
cDNAs
Expression
141Normalization of arrays (clones isolated from DD
are not normally distributed)
Spotted low numbers of clones (100s)
E
C
cDNAs
Expression
142Normalization of arrays (clones isolated from DD
are not normally distributed)
Spotted low numbers of clones (100s)
cDNAs
C
E
Expression
143Normalization of arrays (clones isolated from DD
are not normally distributed)
Spotted low numbers of clones (100s)
cDNAs
C
E
Expression
144Normalization of arrays (clones isolated from DD
are not normally distributed)
Spotted low numbers of clones (100s)
Should be up regulated genes
cDNAs
C
E
Expression
145Normalization of arrays Housekeeping
genes Expression of genes is same for
experimental and control samples (need to
verify).
146Normalization of arrays Housekeeping
genes Expression of genes is same for
experimental and control samples (need to
verify). -Beta actin -Alpha tubulin -18S
ribosomal -Histones
147Normalization of arrays Genes found to be
constitutive by chance Identified via DD, cDNA
library etc
148Constant
Induced
Induced
149Validation of arrays
Blot 1
Blot 2
150Validation of arrays
How reproducible is one membrane to another?
Aliquots of identical RNA (from C or E2) were
hybridized to two separate membranes.
151Validation of arrays
152Develop arrays to monitor estrogenic compounds
153Develop arrays to monitor estrogenic compounds
Liver
Aqueously exposed male SHMs to (1) E2 (2)
EE2 (3) Methoxychlor (4) Nonylphenol
ER Receptor
Vtg
154Develop arrays to monitor estrogenic compounds
Liver
Aqueously exposed male SHMs to (1) E2 (2)
EE2 (3) Methoxychlor (4) Nonylphenol
ER Receptor
Exposed fish
Vtg
Unexposed fish
155Estradiol arrays
156Estradiol arrays
Control SHM
157Estradiol arrays
Control SHM
Estradiol treated SHM
1581.0E7
Control
E2
1.0E6
1.0E5
Log (intensity)
1.0E4
1.0E3
1
5
10
15
20
25
30
35
40
45
50
55
60
cDNA clones
1591.0E7
Control
Vtg a
Transferrin
E2
ZP2
1.0E6
Vtg ß
1.0E5
Log (intensity)
1.0E4
1.0E3
1
5
10
15
20
25
30
35
40
45
50
55
60
cDNA clones
160Fold induction (E2/C)
161Fold induction (E2/C)
1000
1000
100
100
10
10
2
2
log (intensity)
log (intensity)
cDNA clones
1
1
cDNA
clones
cDNA
clones
0.2
0.2
162Fold induction (E2/C)
1000
1000
100
100
10
10
2
2
log (intensity)
log (intensity)
cDNA clones
1
1
cDNA
clones
cDNA
clones
0.2
0.2
163Fold induction (E2/C)
1000
1000
100
100
E2 up-regulated genes
10
10
2
2
log (intensity)
log (intensity)
cDNA clones
1
1
cDNA
clones
cDNA
clones
0.2
0.2
164Fold induction (E2/C)
Vtg a
1000
1000
ZP2
100
100
Vtg ß
E2 up-regulated genes
10
10
2
2
log (intensity)
log (intensity)
cDNA clones
1
1
cDNA
clones
cDNA
clones
0.2
0.2
165Fold induction (E2/C)
Vtg a
1000
1000
ZP2
100
100
Vtg ß
E2 up-regulated genes
10
10
2
2
log (intensity)
log (intensity)
cDNA clones
1
1
E2 down-regulated genes
cDNA
clones
cDNA
clones
0.2
0.2
166Fold induction (E2/C)
Vtg a
1000
1000
ZP2
100
100
Vtg ß
E2 up-regulated genes
10
10
2
2
log (intensity)
log (intensity)
cDNA clones
1
1
E2 down-regulated genes
cDNA
clones
cDNA
clones
Transferrin
0.2
0.2
167Correlation of array data with differential
display and northern data
Control SHM
E2 SHM
168Correlation of array data with differential
display and northern data (ZP2)
Control SHM
E2 SHM
169Correlation of array data with differential
display and northern data (ZP2)
Control SHM
E2 SHM
ZP2 (26)
Control
E2
170Correlation of array data with differential
display and northern data (ZP2)
Control SHM
E2 SHM
ZP2 (26)
Control
E2
Northern
Control
E2
171Correlation of array data with differential
display and northern data (Vtg a)
Control SHM
E2 SHM
172Correlation of array data with differential
display and northern data (Vtg a)
Control SHM
E2 SHM
Vtg a (26)
Control
E2
173Correlation of array data with differential
display and northern data (Vtg a)
Control SHM
E2 SHM
Vtg a (26)
Control
E2
Northern
Control
E2
174Ethinyl estradiol array Methoxychlor
array Nonylphenol array
175Control
Estradiol
176Control
Estradiol
EE2
177Control
Estradiol
EE2
Methoxychlor
178Control
Estradiol
EE2
Methoxychlor
Nonylphenol