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authorAlexander Kabui2021-05-07 00:54:03 +0300
committerBonfaceKilz2021-05-07 11:53:06 +0300
commit1a6091b23751e5be8dd70369fc87e612de327bc9 (patch)
tree1152efea9af2083fbdd6cadeeefce11f458d1a58
parent15d8d3030da70f421ff103c0fee6ef9b883794a7 (diff)
downloadgn-docs-1a6091b23751e5be8dd70369fc87e612de327bc9.tar.gz
replace relative img path
-rw-r--r--blog/2021/proteome/Wang_WIlliams_Rat_Brain_Proteome_For_Blog.md46
1 files changed, 33 insertions, 13 deletions
diff --git a/blog/2021/proteome/Wang_WIlliams_Rat_Brain_Proteome_For_Blog.md b/blog/2021/proteome/Wang_WIlliams_Rat_Brain_Proteome_For_Blog.md
index b29d28b..8f28873 100644
--- a/blog/2021/proteome/Wang_WIlliams_Rat_Brain_Proteome_For_Blog.md
+++ b/blog/2021/proteome/Wang_WIlliams_Rat_Brain_Proteome_For_Blog.md
@@ -68,7 +68,10 @@ End of context; on with the topic at hand:
One small molecule of great fame--DOPAMINE--and its modulation,
variation, and contribution to addiction
-![](media/image1.png)
+
+<img class="control-img img-1" style="max-width: 100%" alt="Dopamine" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image1.png"/>
+
+
THE BIG QUESTION: **What proteins related to dopamine and its many roles in behavior are strongly modulated by DNA variants, and can we determine what gene variants are related both to dopamine function and substance use disorders. **
>
@@ -95,7 +98,7 @@ There are two ways to do this:
to [***https://www.genenetwork.org***](https://www.genenetwork.org) and
set up the **Select and search **screen to look as shown below:
-![](media/image2.png)
+<img class="control-img img-2" style="max-width: 100%" alt="Select and search" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image2.png"/>
Note that in the **Combined** field above, I have entered the string
@@ -127,7 +130,9 @@ linked to *dopamine* AND that have reasonable genetic linkage in the HXB
family to a particular genome coordinate (usually a SNP). The **Search
Results** table should look like the screenshot below. 
-![](media/image3.png)
+
+<img class="control-img img-3" style="max-width: 100%" alt="Search Results" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image3.png"/>
+
I have highlighted the row 8--the ARNTL protein--a major transcription
factor involved in circadian rhythms that is upregulated by DRD2
@@ -140,7 +145,9 @@ screenshot below I have scrolled over to the right to display the **Peak
Location** column after having performing the sort. All of these
proteins map to Chr 1 at about 43.7 megabases (Mb).
-![](media/image4.png)
+
+<img class="control-img img-4" style="max-width: 100%" alt="Search Results" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image4.png"/>
+
We see ARNTL again and eight other proteins that are genetically
downstream of one or many DNA variants located on the proximal part of
@@ -166,7 +173,9 @@ window, or you can just paste this URL command into a browser:
If all goes well, your browser will display this content (and much more
too):
-![](media/image5.png)
+
+<img class="control-img img-5" style="max-width: 100%" alt="mapping" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image5.png"/>
+
Before we map SYT7 protein expression, you may be curious to know how
@@ -175,7 +184,9 @@ this protein has been linked to dopamine. 
The answer is one click away. Tap on the **GeneWiki** button,
highlighted below in grey.
-![](media/image6.png)
+
+<img class="control-img img-6" style="max-width: 100%" alt="" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image6.png"/>
+
A **GeneWiki** window will open, and RIF number 18 explains the
association with *dopamine* and also links to a 2011 paper (PMID
@@ -187,7 +198,7 @@ Again we pause briefly for \"data due diligence\". In the **Statistics**
levels in 21 strains has a hint of bimodality--that is a good thing.
Bimodality worked well for Gregor Mendel, and may work well for us.
-<img src="media/image7.png" width="300">
+<img class="control-img img-7" width="300" alt="" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image7.png"/>
There are no outliers, so we can map these logged protein expression
data \"as given\" without further normalization.
@@ -199,7 +210,9 @@ updated GEMMA linear mixed model mapping function in GeneNetwork.
Open the **Mapping Tools** window
-![](media/image8.png)
+
+<img class="control-img img-8" style="max-width: 100%" alt="" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image8.png"/>
+
In the screenshot above I have mapped variation in SYT7 protein level
using the new **Genotypes file: Experimental (smoothed)**
@@ -214,13 +227,16 @@ Jonathan, David, Hakan, Tristan, Victor, Jun, many others\....).
The Manhattan plot of variation in SYT7 protein expression should look
like this: 
-![](media/image9.png)
+
+<img class="control-img img-9" style="max-width: 100%" alt="" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image9.png"/>
+
Beneath the Manahattan plot there is a **Mapping Statistics** table that
provides estimates a SNP coordinates (Rnor6 assembly) calculated by
GEMMA with -logP values and additive effects (log2 scale).
-![](media/image10.png)
+
+<img class="control-img img-10" style="max-width: 100%" alt="" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image10.png"/>
A -logP value of 5.27 is good--normally at or above genome-wide
threshold of significance. (This assertion does need more support, and
@@ -251,7 +267,8 @@ case.
This will generate a chromosome-specific view; part shown below.
-<img src="media/image11.png" width="300">
+
+<img class="control-img img-11" width="300" alt="" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image11.png"/>
The QTL peak is a \"non-recombinant\" plateau that extends from 35.5 to
45 Mb---confirming visually what we had already determined from the
@@ -263,7 +280,9 @@ You can keep zooming in on a specific region of a chromosome by clicking
on the pink horizontal bar alonge the top. Here is the plateau region of
the SYT7 protein expression QTL.
-![](media/image12.png)
+
+<img class="control-img img-12" style="max-width: 100%" alt="" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image12.png"/>
+
As you can tell from the screenshot, there are lots of genes--real and
putative--that call this part of Chr 1 home.
@@ -356,7 +375,8 @@ Simple--clip out all of those positional candidate genes and paste them
into the search **Get Any** window of GeneNetwork. It should look like
this:
- ![](media/image13.png)
+<img class="control-img img-13" style="max-width: 100%" alt="" src="https://github.com/genenetwork/gn-docs/raw/master/blog/2021/proteome/media/image13.png"/>
+
About 12 of these proteins have reasonably high expression in the rat
brain, and three of these also are associated with reasonably strong