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Using the Package

From within R, install from the Sage internal CRAN serverGet the source from Github and build the package:

Code Block

source('http://sage.fhcrc.org/CRAN.R'); pkgInstall("SageBionetworksCoex")

...

# Install the dependencies, from R:
> install.packages(pkgs=c("WGCNA", "flashClust", "dynamicTreeCut"))
# now, from the command line, clone the Github repository
git clone https://github.com/Sage-Bionetworks/SageBionetworksCoex.git
# again, from the command line, build the package
R CMD INSTALL SageBionetworksCoex

In R, load the library:

Code Block
> library(SageBionetworksCoex)

For guidance on using the package:

Code Block

?SageBionetworksCoex

Table of Contents

Table of Contents

Goals

1) Make the Sage coexpression software runnable by any data analyst in R.

Document the analysis steps, package functions, and adjustable parameters.  Write start-to-finish vignette(s) having sufficient detail to guide a new analyst through the software, including making parameter settings and other intermediate decisions.  Refactoring software to enhance readability and/or to make decision points and adjustable parameters explicit, is within scope for this goal.

2) Clearly explain the methodology underlying the coexpression algorithms.

This includes contrasting the Sage algorithms with the separately published “WGCNA” algorithms and explaining the rationale for the differences and the decision process for choosing which to use.

3) Make the Sage coexpression software publicly available.

The code must be available through a standard R distribution channel (CRAN or Bioconductor).  An option is to merge Sage-specific algorithms or steps into WGCNA (if the two are sufficiently overlapping).

4) Make the Sage coexpression software perform well, on commonly available hardware.

Currently, special high capacity hardware is required to run the Sage coexpression software on commonly encountered data set sizes.  The goal is to optimize the code to run on commonly available hardware, at a minimum the code should be runnable on the 68GB, quad core servers available through Amazon Web Services. Ideally, the code would be runnable on a “heavy” Sage laptop (8 GB total RAM).

Strategy

The steps for Sage Coexpression are: 

...

Performance questions:  For datasets having >18,000 probes, how much time and space does each algorithm use?

Dataset

# Probes

# Samples

Sage Time

Sage Space

Package Time

Package Space

Sage beta

Package beta

Gene trees same, independent beta?

Gene trees same, same beta?

Module difference****, independent beta

Module difference****, same beta

Female mouse liver

3600

135

---

---

---

---

6.5

6.5

TRUE

TRUE

3.7%

3.7%

Cranio

2534

249

---

---

---

---

4.0

4.5

FALSE

TRUE

44%

0.9%

Methylation, top 5K genes

5000

555

---

---

---

---

8.5

8.5

TRUE

TRUE

0

0

Colon cancer, top 5K genes

5000

322

---

---

---

---

3

3.5

FALSE

TRUE

11%

0.5%

Human liver cohort, top 5K genes

5000

427

---

---

---

---

11

11

TRUE

TRUE

1.0%

1.0%

PARC*

18,392

960

5h:55m

83.9 GB

1h:40m

71 GB

8

7.5

FALSE

FALSE

4.7%

0.6%

Methylation (full set)*

27,578

555

24h:45m

180 GB

6h:38m

196 GB

8

11.5

FALSE

FALSE

14%

0.2%

Colon cancer, top 45K genes***

45,000

322

---

---

5h:52

368 GB

---

---

---

---

---

---

Human liver cohort***

40,102

427

---

---

5h:13m

313 GB

---

---

---

---

---

---

...

Goals, Revisited

Goal

How we met it

Make the Sage coexpression software runnable by any data analyst in R

Created easy to use, documented R package.  (TODO: training class)

Clearly explain the methodology underlying the coexpression algorithms.

Included links to literature in the R package documentation.

Make the Sage coexpression software publicly available.

TBD  (see below)

Make the Sage coexpression software perform well, on commonly available hardware.

Used UCLA's accelerated algorithms.  Accelerated the 'intra-module statistics' computation.  Profiled datasets of up to 27,000 genes on inexpensive, high capacity cloud resources.

Choices for package 'publication' include:

...