1. “Analyzing the Human Gut Microbiome Dynamics in Health and Disease Using Supercomputers and Supernetworks”
Invited Presentation
ESnet CrossConnects Bioinformatics Conference
Lawrence Berkeley National Laboratory
April 12, 2016
Dr. Larry Smarr
Director, California Institute for Telecommunications and Information Technology
Harry E. Gruber Professor,
Dept. of Computer Science and Engineering
Jacobs School of Engineering, UCSD

2. Abstract
To truly understand the state of the human body in health or disease, we now realize that we must consider a much more complex system than medical science considered heretofore. This is because we now know that the human body is host to 100 trillion microorganisms, ten times the number of DNA­bearing cells in the human body and these microbes contain 300 times the number of DNA genes that our human DNA does. The microbial component of our “superorganism” is comprised of hundreds of species with immense biodiversity. Exponential decrease in the cost of genetic sequencing and supercomputing has enabled scientists to finally "read out" the nature of the changes in the microbial ecology in people in health and with disease. We use the fiber optic network of the Pacific Research Platform to rapidly move these large datasets. To put a more personal face on the “patient of the future,” I have been collecting massive amounts of data from my own body over the last five years, which reveals detailed examples of the episodic excursions of my coupled immune­microbial system. As similar techniques become more widely applied, we can look forward to revolutionary changes in medical practice over the next decade.

3. From One to a Trillion Data Points Defining Me in 15 Years: The Exponential Rise in Body Data
Microbial Genome
Time Series
Human Genome
Improving Body
Human Genome SNPs
Discovering Disease
Blood Biomarker
Time Series
Weight

4. My Quarterly Blood Draw
As a Model for the Precision Medicine Initiative, I Have Tracked My Internal Biomarkers To Understand My Body’s Dynamics
My Quarterly Blood Draw
Calit2 64 Megapixel VROOM

5. Episodic Peaks in Inflammation Followed by Spontaneous Drops
Only One of My Blood Measurements Was Far Out of Range--Indicating Chronic Inflammation
27x Upper Limit
Episodic Peaks in Inflammation Followed by Spontaneous Drops
Normal Range <1 mg/L
Complex Reactive Protein (CRP) is a Blood Biomarker for Detecting Presence of Inflammation

6. Active Inflammatory Bowel Disease
Adding Stool Tests Revealed Oscillatory Behavior in an Immune Variable Which is Antibacterial
Typical
Lactoferrin Value for
Active Inflammatory Bowel Disease
(IBD)
124x Upper Limit for Healthy
Normal Range
<7.3 µg/mL
Lactoferrin is a Protein Shed from Neutrophils -
An Antibacterial that Sequesters Iron

7. Confirming the IBD (Colonic Crohn’s) Hypothesis: Finding the “Smoking Gun” with MRI Imaging
Liver
I Obtained the MRI Slices From UCSD Medical Services
and Converted to Interactive 3D Working With Calit2 Staff
Transverse Colon
Small Intestine
Descending Colon
Sigmoid Colon
Threading Iliac Arteries
Major Kink
Diseased Sigmoid Colon
MRI Jan 2012
Cross Section
Severe Colon
Wall Swelling

8. Why Did I Have an Autoimmune Disease like Crohn’s Disease?
Despite decades of research,
the etiology of Crohn's disease remains unknown. Its pathogenesis may involve a complex interplay between host genetics, immune dysfunction, and microbial or environmental factors.
--The Role of Microbes in Crohn's Disease
I Have Been Quantifying All Three
Paul B. Eckburg & David A. Relman
Clin Infect Dis. 44: (2007) 

9. 23andme is Now Collecting 10,000 IBD Patient’s SNPs
I Found I Had One of the Earliest Known SNPs Associated with Crohn’s Disease
From
Polymorphism in Interleukin-23 Receptor Gene — 80% Higher Risk of Pro-inflammatory Immune Response
ATG16L1
IRGM
NOD2
SNPs Associated with CD
23andme is Now Collecting 10,000 IBD Patient’s SNPs

10. I Reasoned That The Driver of My Gut Autoimmune Disease Was a Disturbance in My Gut Microbiome Ecology
Your Body Has 10 Times As Many Microbe Cells As DNA-Bearing Human Cells
99% of Your DNA Genes
Are in Microbe Cells
Not Human Cells
Inclusion of the “Dark Matter” of the Body Will Radically Alter Medicine

11. The Carl Woese Tree of Life Shows The Most Life on Earth is Bacterial
Source: Carl Woese, et al (1990)
Hug, et al.
Nature Microbiology 

12. The Human Gut as a Super-Evolutionary Microbial Cauldron
Enormous Density
1000x Ocean Water
Highly Dynamic Microbial Ecology
Hundreds to Thousands of Species
Horizontal Gene Transfer
Phages
Adaptive Selection Pressures (Immune System)
Innate Immune System
Adaptive Immune System
Macrophages and Antimicrobial proteins
Constantly Changing Environmental Pressures
Diet
Antibiotics
Pharmaceuticals

13. Our Team Used 25 CPU-years to Compute Comparative Gut Microbiomes
To Map Out the Dynamics of Autoimmune Microbiome Ecology Couples Next Generation Genome Sequencers to Big Data Supercomputers
Source: Weizhong Li, UCSD
Illumina HiSeq 2000 at JCVI
Our Team Used 25 CPU-years
to Compute
Comparative Gut Microbiomes
Starting From
2.7 Trillion DNA Bases
of My Samples
and Healthy and IBD Controls
SDSC Gordon Data Supercomputer

14. We Gathered Raw Illumina Reads on 275 Humans and Generated a Time Series of My Gut Microbiome
Each Sample Has Million Illumina Short Reads (100 bases)
“Healthy” Individuals
Inflammatory Bowel Disease (IBD) Patients
250 Subjects
1 Point in Time
2 Ulcerative Colitis Patients,
6 Points in Time
Larry Smarr
(Colonic Crohn’s)
7 Points in Time
5 Ileal Crohn’s Patients, 3 Points in Time
Total of 27 Billion Reads
Or 2.7 Trillion Bases
Source: Jerry Sheehan, Calit2
Weizhong Li, Sitao Wu, CRBS, UCSD

15. PI: (Weizhong Li, CRBS, UCSD):
Computational NextGen Sequencing Pipeline: From Sequence to Taxonomy and Function
PI: (Weizhong Li, CRBS, UCSD):
NIH R01HG ( , $1.1M)

16. Results Include Relative Abundance of Hundreds of Microbial Species
Average Over 250 Healthy People
From NIH Human Microbiome Project
Note Log Scale
Clostridium difficile

17. Using Microbiome Profiles to Survey 155 Subjects for Unhealthy Candidates

18. We Found Major State Shifts in Microbial Ecology Phyla Between Healthy and Three Forms of IBD
Average HE
Most
Common
Microbial
Phyla
Average Ileal Crohn’s Disease
Average Ulcerative Colitis
Average LS
Colonic Crohn’s Disease

19. Time Series Reveals Oscillations in Immune Biomarkers Associated with Time Progression of Autoimmune Disease
Immune &
Inflammation
Variables
2009
2010
2011
2012
2013
2014
2015
Weekly Symptoms
Pharma
Therapies
Stool
Samples

20. Larry’s 40 Stool Samples Over 3.5 Years to Rob’s lab on April 30, 2015
In 2016 We Are Extending My Stool Time Series by Collaborating with the UCSD Knight Lab
Larry’s 40 Stool Samples Over 3.5 Years to Rob’s lab on April 30, 2015

21. Precision Medicine: Coupling Longitudinal Phenotypic Changes to Longitudinal Microbiome Evolution
Larry Smarr’s Weight Over 15 Years
Time Period of 16S Microbial Sequences
Source: Larry Smarr, UCSD

22. Larry Smarr Gut Microbiome Ecology Shifted After Drug Therapy Between Two Time-Stable Equilibriums Correlated to Physical Symptoms
Frequent IBD Symptoms
Weight Loss
5/1/12 to 12/1/14
Blue Balls on Diagram to the Right
Weekly Weight (Red Dots Stool Sample)
Few IBD Symptoms
Weight Gain
1/1/14 to 1/1/16
Red Balls on Diagram to the Right
Few IBD Symptoms
Weight Gain
1/1/14 to 1/1/16
Red Balls on Diagram to the Right
12/1/13 to 1/1/14
12/1/13-1/1/14
Antibiotics
Prednisone
1/1/12 to 5/1/12
5/1/12
Lialda & Uceris
Principal Coordinate Analysis of Microbiome Ecology
PCoA by Justine Debelius and Jose Navas, Knight Lab, UCSD
Weight Data from Larry Smarr, Calit2, UCSD

23. 8x Compute Resources Over Prior Study
To Expand IBD Project the Knight/Smarr Labs Were Awarded ~ 1 CPU-Century Supercomputing Time
Smarr Gut Microbiome Time Series
From 7 Samples Over 1.5 Years
To 50 Samples Over 4 Years
IBD Patients: From 5 Crohn’s Disease and 2 Ulcerative Colitis Patients to ~100 Patients
50 Carefully Phenotyped Patients Drawn from Sandborn BioBank
43 Metagenomes from the RISK Cohort of Newly Diagnosed IBD patients
New Software Suite from Knight Lab
Re-annotation of Reference Genomes, Functional / Taxonomic Variations
Novel Compute-Intensive Assembly Algorithms from Pavel Pevzner
8x Compute Resources Over Prior Study

24. Data Source: David Haussler, Brad Smith, UCSC
Cancer Genomics Hub (UCSC) Demonstrates Need for SuperNetworks: Large Data Flows to End Users at UCSC, UCB, UCSF, … 1G 8G
30,000 TB
Per Year
15G
Jan 2016
Data Source: David Haussler, Brad Smith, UCSC

25. Building a UC San Diego High Performance Cyberinfrastructure to Support Distributed Integrative Omics
FIONA
12 Cores/GPU
128 GB RAM
3.5 TB SSD
48TB Disk
10Gbps NIC
Knight Lab
10Gbps
Gordon
Data Oasis
7.5PB, 200GB/s
Knight 1024 Cluster
In SDSC Co-Lo
CHERuB
100Gbps
Emperor & Other Vis Tools
64Mpixel Data Analysis Wall
120Gbps
1.3Tbps
PRP/
40Gbps

26. Based on Community Input and on ESnet’s Science DMZ Concept, NSF Has Funded Over 100 Campuses to Build Local Big Data Freeways
Red CC-NIE Awardees
Yellow 2013 CC-NIE Awardees
Green CC*IIE Awardees
Blue CC*DNI Awardees
Purple Multiple Time Awardees
CC-NIE / CC*IIE / CC*DNI Programs
Source: NSF

27. Source: John Hess, CENIC
The Pacific Wave Platform Creates a Regional Science-Driven “Big Data Freeway System”
Funded by NSF $5M Oct
PI: Larry Smarr, UC San Diego Calit2
Co-PIs:
Camille Crittenden, UC Berkeley CITRIS,
Tom DeFanti, UC San Diego Calit2,
Philip Papadopoulos, UC San Diego SDSC,
Frank Wuerthwein, UC San Diego Physics and SDSC
Flash Disk to Flash Disk File Transfer Rate
Source: John Hess, CENIC

28. How Will the Quantified Consumer
The Emergence of Precision or P4 Medicine -- Predictive, Preventive, Personalized, Participatory
How Will the Quantified Consumer
Be Integrated into Healthcare Systems?
Lee Hood, Director ISB
Systems Biology & Systems Medicine
Consumer-Driven Social Networks P4
MEDICINE
Digital Revolution
Big Data

29. Thanks to Our Great Team!
Future Patient Team
Jerry Sheehan
Tom DeFanti
Joe Keefe
John Graham
Kevin Patrick
Mehrdad Yazdani
Jurgen Schulze
Andrew Prudhomme
Philip Weber
Fred Raab
Ernesto Ramirez
JCVI Team
Karen Nelson
Shibu Yooseph
Manolito Torralba
Ayasdi
Devi Ramanan
Pek Lum
UCSD Metagenomics Team
Weizhong Li
Sitao Wu
SDSC Team
Michael Norman
Mahidhar Tatineni
Robert Sinkovits
Dell/R Systems
Brian Kucic
John Thompson
UCSD Health Sciences Team
David Brenner
Rob Knight Lab
Justine Debelius
Jose Navas
Gail Ackermann
Greg Humphrey
William J. Sandborn Lab
Elisabeth Evans
John Chang
Brigid Boland