6. Eisen Lab “Topics”
Phylogenomic
Methods
& Tools
Microbial
Phylogenomics
&
Evolvability
Phylogenomic
Resources
&
Reference Data
Communication
&
Participation
In Microbiology
& Science
Model
Systems
7. Automated Accurate Genome Tree
Lang JM, Darling AE, Eisen JA (2013) Phylogeny of
Bacterial and Archaeal Genomes Using Conserved
Genes: Supertrees and Supermatrices. PLoS ONE
8(4): e62510. doi:10.1371/journal.pone.0062510
Jenna Lang
8. PhyEco Markers
Phylogenetic group Genome Number Gene Number Maker Candidates
Archaea 62 145415 106
Actinobacteria 63 267783 136
Alphaproteobacteria 94 347287 121
Betaproteobacteria 56 266362 311
Gammaproteobacteria 126 483632 118
Deltaproteobacteria 25 102115 206
Epislonproteobacteria 18 33416 455
Bacteriodes 25 71531 286
Chlamydae 13 13823 560
Chloroflexi 10 33577 323
Cyanobacteria 36 124080 590
Firmicutes 106 312309 87
Spirochaetes 18 38832 176
Thermi 5 14160 974
Thermotogae 9 17037 684
Wu D, Jospin G, Eisen JA (2013) Systematic Identification of Gene Families
for Use as “Markers” for Phylogenetic and Phylogeny-Driven Ecological
Studies of Bacteria and Archaea and Their Major Subgroups. PLoS ONE
8(10): e77033. doi:10.1371/journal.pone.0077033
9. Eisen Lab “Topics”
Phylogenomic
Methods
& Tools
Microbial
Phylogenomics
&
Evolvability
Phylogenomic
Resources
&
Reference Data
Communication
&
Participation
In Microbiology
& Science
Model
Systems
10. 2002-2007: TIGR Tree of Life Project
Figure from Barton, Eisen et al. “Evolution”, CSHL Press based on Baldauf et al Tree
Naomi
Ward
Karen
Nelson
14. GEBA Cyanobacteria
Shih et al. 2013. PNAS 10.1073/pnas.1217107110
0.3
B1
B2
C1
Paulinella
Glaucophyte
Green
Red
Chromalveolates
C2
C3
A
E
F
G
B3
D
A
B
Fig. 2. Implications on plastid evolution. (A) Maxi-
mum-likelihood phylogenetic tree of plastids and cya-
nobacteria, grouped by subclades (Fig. 1). The red dot
Cheryl
Kerfeld
19. Chlorobi
)LUPLFXWHV
Tenericutes
)XVREDFWHULD
Chrysiogenetes
Proteobacteria
)LEUREDFWHUHV
TG3
Spirochaetes
WWE1 (Cloacamonetes)
70
ZB3
093í
'HLQRFRFFXVí7KHUPXV
OP1 (Acetothermia)
Bacteriodetes
TM7
GN02 (Gracilibacteria)
SR1
BH1
OD1 (Parcubacteria)
:6
OP11 (Microgenomates)
Euryarchaeota
Micrarchaea
DSEG (Aenigmarchaea)
Nanohaloarchaea
Nanoarchaea
Cren MCG
Thaumarchaeota
Cren C2
Aigarchaeota
Cren pISA7
Cren Thermoprotei
Korarchaeota
pMC2A384 (Diapherotrites)
BACTERIA ARCHAEA
archaeal toxins (Nanoarchaea)
lytic murein transglycosylase
stringent response
(Diapherotrites, Nanoarchaea)
ppGpp
limiting
amino acids
SpotT RelA
(GTP or GDP)
+ PPi
GTP or GDP
+ATP
limiting
phosphate,
fatty acids,
carbon, iron
DksA
Expression of components
for stress response
sigma factor (Diapherotrites, Nanoarchaea)
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tetra-
peptide
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tetra-
peptide
murein (peptido-glycan)
archaeal type purine synthesis
(Microgenomates)
PurF
PurD
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24. Eisen Lab “Topics”
Phylogenomic
Methods
Tools
Microbial
Phylogenomics
Evolvability
Phylogenomic
Resources
Reference Data
Communication
Participation
In Microbiology
Science
Model
Systems
34. Microbiomania vs. Germophobia
Germophobia Microbiomania
All Microbes Are Bad
Use Antimicrobials
in Everything
Avoid all Microbes
All Microbes Are Good
Use Probiotics
in Everything
Embraces all Microbes
Lick Subway Poles
Fecal Transplants
Will Save World
Avoid Animals
Too
Swab Stories
38. Eisen Lab “Topics”
Phylogenomic
Methods
Tools
Microbial
Phylogenomics
Evolvability
Phylogenomic
Resources
Reference Data
Communication
Participation
In Microbiology
Science
Model
Systems
42. Symbiosis Under Stress
When organisms are placed under selective
pressure or stress where novelty would be
beneficial, can we predict which pathway
they will use?
What leads to interactions / symbioses
being a potential solution?
Can we manipulate interactions and/or force
new ones upon systems?
43. HMS Type 1: Nutrient Acquisition
Host
Microbiome Nutrients
44. HMS Type 1: Nutrient Acquisition
Glassy Winged Sharpshooter
Gut
Endosymbionts
Trying to
Live on
Xylem Fluid
Nancy Moran
Dongying Wu
45. HMS Type 1: Nutrient Acquisition
Oloton
Corn
Mucilage
Microbiome
Low
N
46. HMS Type 2: Pathogens
Host
Microbiome Pathogen
47. HMS Type 2: Pathogens
Ducks
Gut
Microbiome
Flu
Walter
Boyce
Holly
Ganz
Sarah
Hird
Ladan
Daroud
Alana
Firl
48. HMS Type 2: Pathogens
Koala
Gut
Microbiome
Chlamydia
Antibiotics
Katherine
Dahlhausen
60. Seagrass Microbiomes?
• Many reasons for interest
• Convergence of microbiomes?
• Comparison to other monocots
• Adaptations to salt / marine environment
• But …
• No experience in our mega-group working with
seagrass …
• Little literature on seagrass microbiomes
• So? ….
62. Jay Stachowicz - Seagrass Guru
• Stachowicz lab
Image from Reynolds PL. Seagrass and Seagrass Beds
http://ocean.si.edu/seagrass-and-seagrass-beds
• Seagrass Importance
• Ecosystem Structure
• Living Habitat
• Foundation of Food
Webs
63. Jay Stachowicz - Seagrass Guru
• Stachowicz lab
Image from Reynolds PL. Seagrass and Seagrass Beds
http://ocean.si.edu/seagrass-and-seagrass-beds
• Seagrass Importance
• Ecosystem Structure
• Living Habitat
• Foundation of Food
Webs
64. Slide from Jay Stachowicz
Z. marina is abundant throughout northern hemisphere
66. Seagrass Microbiome
● Aim 1: How have the microbial communities associated with
seagrasses co- evolved with their hosts and what roles in the
past and currently do microbes play in adaptations of plants
to fresh and marine water life?
● Aim 2: What drives the community assembly of the
seagrass microbiome, and specifically within the Zostera
marina model system?
● Aim 3: What role does the microbial community play in the
functional ecology of the Zostera marina (with a specific focus
on sulfur and nitrogen metabolism and primary production)?
Jenna LangJessica GreenJay StachowiczJonathan Eisen
68. Seagrass Microbiome
● Aim 1: How have the microbial communities associated with
seagrasses co- evolved with their hosts and what roles in the
past and currently do microbes play in adaptations of plants
to fresh and marine water life?
● Aim 2: What drives the community assembly of the
seagrass microbiome, and specifically within the Zostera
marina model system?
● Aim 3: What role does the microbial community play in the
functional ecology of the Zostera marina (with a specific focus
on sulfur and nitrogen metabolism and primary production)?
Jenna LangJessica GreenJay StachowiczJonathan Eisen
71. Rhizome Roots vs. Shoot Roots vs. Leaf
Variation in microbial community composition in Z. marina. PCoA plot of weighted Unifrac distances between
samples. Communities cluster by tissue type (PERMANOVA, p 0.001). Within root samples, rhizome roots
differ from shoot roots (PERMANOVA, p 0.001).
72. Zostera Experimental Network (ZEN)
• 40 Sites in 24 countries
• Eelgrass genetic composition
• Eelgrass above and below
ground biomass
• Associated epifauna and
infauna
Original experimental sites
Zostera marina
Emmett Duffy
Pamela Reynolds Kevin Hovel
Jay Stachowicz
http://zenscience.org
74. ZEN Microbiome Sampling
Emmett Duffy
Pamela Reynolds Kevin Hovel
Jay Stachowicz
http://zenscience.org
• Sent kits
• Asked to sample leaves,
roots, sediment and water
76. Global Structure of Eelgrass Microbiome
Results
PcoA Environmental
Similarity
• Leaf, roots and
sediment different
• Leaves resemble
water
• Leaves more similar
to local water
Fahimipour AK, Kardish MR, Lang JM, Green JL, Eisen JA,
Stachowicz JJ. 2017. Global-scale structure of the eelgrass
microbiome. Appl Environ Microbiol 83:e03391-16. https://
doi.org/10.1128/AEM.03391-16.
Jenna
Lang
Ashkaan
Fahimipour
Melissa
Kardish
77. Don’t Forget the Fungi
Ettinger CL, Eisen JA. Characterization of the mycobiome of the seagrass, Zostera marina, reveals
putative associations with marine chytrids. Frontiers in Microbiology 10: 2476. doi: 10.3389/fmicb.
2019.02476.
Cassie Ettinger
85. Seagrass Microbiome
● Aim 1: How have the microbial communities associated with
seagrasses co- evolved with their hosts and what roles in the
past and currently do microbes play in adaptations of plants
to fresh and marine water life?
● Aim 2: What drives the community assembly of the
seagrass microbiome, and specifically within the Zostera
marina model system?
● Aim 3: What role does the microbial community play in the
functional ecology of the Zostera marina (with a specific focus
on sulfur and nitrogen metabolism and primary production)?
Jenna LangJessica GreenJay StachowiczJonathan Eisen
86. Predicted Sulfur Metabolism Enriched on Roots
Results
Fahimipour AK, Kardish MR, Lang JM, Green JL, Eisen JA, Stachowicz JJ. 2017. Global-scale
structure of the eelgrass microbiome. Appl Environ Microbiol 83:e03391-16. https://doi.org/10.1128/
AEM.03391-16.
87. Edge Effects: Does in Matter Where Plants Are?
Ettinger CL, Voerman SE, Lang JM, Stachowicz JJ,
Eisen JA. (2017) Microbial communities in sediment
from Zostera marina patches, but not the Z. marina leaf
or root microbiomes, vary in relation to distance from
patch edge. PeerJ 5:e3246 https://doi.org/10.7717/
peerj.3246
Jenna
Lang
Cassie
Ettinger
Sofie
Voerman
88. Edge Effect in Sediment Not Plant Microbiomes
• Plant parts (root, leaf) and near-by sediment different from each other.
• Edge effects not seen for plant microbiomes
• Edge effect seen for sediment
90. Succession During Ammonification
Ettinger CL, Williams SL, Abbott JM, Stachowicz JJ,
Eisen JA. (2017) Microbiome succession during
ammonification in eelgrass bed sediments. PeerJ
5:e3674 https://doi.org/10.7717/peerj.3674
Susan
Williams
Cassie
Ettinger
Jessica
Abbott
Changes appear
driven by sulfur
cycling w/
decreases in sulfur
reducers
(Desulfobacterales)
and corresponding
increases in sulfide
oxidizers
(Alteromonadales
and Thiotrichales).
92. David Coil
Jeanine
Olsen
Laura
Vann
Yves van
De Peer
Guillaume
Jospin
Melissa
Kardish
Alana
Firl
Laura
Reynolds
Jessica
Abbott
Susan
Williams
Katie
DuBois
Cassie
Ettinger
Sofie
Voerman
Ashkaan
Fahimipour
Russell
Neches
James
Doyle
Jenna LangJessica GreenJay Stachowicz
Hannah
Holland-Moritz
Ruth
Lee
Pamela
Reynolds
• Karley Lujuan
• Marcus Cohen
• Katie Somers
• Taylor Tucker
• Hoon San Ong
• Neil Brambhatt
• Hena Hundal
• Daniel Oberbauer
• Briana Pompa-Hogan
• Alex Alexiev
• Ruth Lee
95. Zostera marina as model HMS System
• What makes a model system for host-
microbiome studies?
• Which are / are not available for ZM?
96. Drosophila microbiome
Both natural surveys and
laboratory experiments
indicate that host diet plays a
major role in shaping the
Drosophila bacterial
microbiome. Laboratory strains
provide only a limited model of
natural host–microbe
interactions
Jenna
Lang
Angus
Chandler
97. Model Systems - Rice
Edwards et al. 2015. Structure, variation,
and assembly of the root-associated
microbiomes of rice. PNAS
9
Supplementary Figures31
32
Fig. S1 Map depicting soil collection locations for greenhouse experiment.33
10
234
Fig. S2. Sampling and collection of the rhizocompartments. Roots are collected from rice235
plants and soil is shaken off the roots to leave ~1mm of soil around the roots. The ~1 mm of soil236
three separate rhizocompartments: the rhizosphere, rhizoplane,
and endosphere (Fig. 1A). Because the root microbiome has
been shown to correlate with the developmental stage of the
plant (10), the root-associated microbial communities were
sampled at 42 d (6 wk), when rice plants from all genotypes were
well-established in the soil but still in their vegetative phase of
growth. For our study, the rhizosphere compartment was com-
w
i
t
i
(
t
s
z
i
m
a
r
t
t
(
t
m
P
h
t
P
p
(
i
M
P
a
t
o
s
q
a
n
v
v
p
t
p
s
G
Fig. 1. Root-associated microbial communities are separable by rhizo-
compartment and soil type. (A) A representation of a rice root cross-section
depicting the locations of the microbial communities sampled. (B) Within-
sample diversity (α-diversity) measurements between rhizospheric compart-
ments indicate a decreasing gradient in microbial diversity from the rhizo-
sphere to the endosphere independent of soil type. Estimated species
richness was calculated as eShannon_entropy
. The horizontal bars within boxes
represent median. The tops and bottoms of boxes represent 75th and 25th
quartiles, respectively. The upper and lower whiskers extend 1.5× the
interquartile range from the upper edge and lower edge of the box, re-
spectively. All outliers are plotted as individual points. (C) PCoA using the
WUF metric indicates that the largest separation between microbial com-
munities is spatial proximity to the root (PCo 1) and the second largest
source of variation is soil type (PCo 2). (D) Histograms of phyla abundances in
each compartment and soil. B, bulk soil; E, endosphere; P, rhizoplane; S,
rhizosphere; Sac, Sacramento.
2 of 10 | www.pnas.org/cgi/doi/10.1073/pnas.1414592112
igate the relationship between rice ge-
icrobiome, domesticated rice varieties
rated growing regions were tested. Six
spanning two species within the Oryza
2 d in the greenhouse before sampling.
a) cultivars M104, Nipponbare (both
ties), IR50, and 93-11 (both indica va-
gside two cultivars of African cultivated
g7102 (Glab B) and TOg7267 (Glab E).
ed that rice genotype accounted for
ariation between microbial communities
% of the variance, P 0.001; Dataset
f the variance, P 0.066; Dataset S5H);
ntations for clustering patterns of the
nt on the first two axes of unconstrained
ppendix, Fig. S10). We then used CAP
effect of rice genotype on the microbial
ng on rice cultivar and controlling for
and technical factors, we found that ge-
ice have a significant effect on root-
mmunities (5.1%, P = 0.005, WUF, Fig.
, UUF, SI Appendix, Fig. S11A). Ordi-
AP analysis revealed clustering patterns
only partially consistent with genetic
UF and UUF metrics. The two japonica
her and the two O. glaberrima cultivars
ver, the indica cultivars were split, with
O. glaberrima cultivars and IR50 clus-
cultivars.
enotypic effect manifests in individual
eparated the whole dataset to focus on
vidually and conducted CAP analysis
and technical factors. The rhizosphere
eight sites were operated under two cultivation practices: organic
cultivation and a more conventional cultivation practice termed
“ecofarming” (see below). Because genotype explained the least
variance in the greenhouse data, we limited the analysis to one
cultivar, S102, a California temperate japonica variety that is
widely cultivated by commercial growers and is closely related to
M104 (26). Field samples were collected from vegetatively
growing rice plants in flooded fields and the previously defined
rhizocompartments were analyzed as before. Unfortunately,
collection of bulk soil controls for the field experiment was not
Fig. 3. Host plant genotype significantly affects microbial communities in
the rhizospheric compartments. (A) Ordination of CAP analysis using the
WUF metric constrained to rice genotype. (B) Within-sample diversity
measurements of rhizosphere samples of each cultivar grown in each soil.
Estimated species richness was calculated as eShannon_entropy
. The horizontal
bars within boxes represent median. The tops and bottoms of boxes repre-
sent 75th and 25th quartiles, respectively. The upper and lower whiskers
extend 1.5× the interquartile range from the upper edge and lower edge of
the box, respectively. All outliers are plotted as individual points.
oi/10.1073/pnas.1414592112 Edwards et al.
fields are too high to find representative soil that is unlikely to
be affected by nearby plants. Amplification and sequencing of
the field microbiome samples yielded 13,349,538 high-quality
sequences (median: 54,069 reads per sample; range: 12,535–
148,233 reads per sample; Dataset S13). The sequences were
clustered into OTUs using the same criteria as the greenhouse
experiment, yielding 222,691 microbial OTUs and 47,983 OTUs
with counts 5 across the field dataset.
We found that the microbial diversity of field rice plants is
significantly influenced by the field site. α-Diversity measure-
ments of the field rhizospheres indicated that the cultivation site
significantly impacts microbial diversity (SI Appendix, Fig. S14A,
P = 2.00E-16, ANOVA and Dataset S14). Unconstrained PCoA
using both the WUF and UUF metrics showed that microbial
communities separated by field site across the first axis (Fig. 4B,
WUF and SI Appendix, Fig. S14B, UUF). PERMANOVA agreed
with the unconstrained PCoA in that field site explained the
largest proportion of variance between the microbial communi-
ties for field plants (30.4% of variance, P 0.001, WUF, Dataset
S5O and 26.6% of variance, P 0.001, UUF, Dataset S5P). CAP
analysis constrained to field site and controlled for rhizocom-
partment, cultivation practice, and technical factors (sequencing
batch and biological replicate) agreed with the PERMANOVA
results in that the field site explains the largest proportion of
variance between the root-associated microbial communities in
field plants (27.3%, P = 0.005, WUF, SI Appendix, Fig. S15A
and 28.9%, P = 0.005, UUF, SI Appendix, Fig. S15E), sug-
gesting that geographical factors may shape root-associated
microbial communities.
Rhizospheric Compartmentalization Is Retained in Field Plants. Sim-
ilar to the greenhouse plants, the rhizospheric microbiomes of
field plants are distinguishable by compartment. α-Diversity of
the field plants again showed that the rhizosphere had the
highest microbial diversity, whereas the endosphere had the least
S15). PCoA
the WUF a
compartmen
Appendix, F
separation i
ond largest
(20.76%, P
UUF, Data
biomes cons
trolled for f
agreed with
variance bet
compartmen
and 10.9%,
Taxonomi
overall sim
Chloroflexi,
microbiota.
endosphere
Proteobacter
and Plancto
distribution
trend from t
Appendix, F
We again
OTUs in the
S16). We fo
endosphere c
representing
Fig. S17). Th
the genus A
and Alphap
terestingly,
found to b
greenhouse
OTUs were
sisted of tax
and Myxoco
bidopsis roo
Cultivation Pr
The rice fiel
practices, org
tion called
farming in th
are all perm
harvest fumi
itself does si
partments ov
a significant
the rhizocom
indicating th
affected diffe
the rhizosph
practice, with
zospheres th
Dataset S14)
crobial comm
tests; Datase
practices are
the WUF m
S14D). PERFig. 4. Root-associated microbiomes from field-grown plants are separable
by cultivation site, rhizospheric compartment, and cultivation practice. (A)
Variation w/in Plant
Cultivation Site Effects
Rice Genotype Effects
and mitochondrial) reads to analyze microbial abundance in
the endosphere over time (Fig. 6A). Using this technique, we
confirmed the sterility of seedling roots before transplantation.
We found that microbial penetrance into the endosphere oc-
curred at or before 24 h after transplantation and that the pro-
portion of microbial reads to organellar reads increased over the
first 2 wk after transplantation (Fig. 6A). To further support the
evidence for microbiome acquisition within the first 24 h, we
sampled root endospheric microbiomes from sterilely germi-
nated seedlings before transplanting into Davis field soil as well
as immediately after transplantation and 24 h after transplan-
tation (SI Appendix, Fig. S24). The root endospheres of sterilely
germinated seedlings, as well as seedlings transplanted into
Davis field soil for 1 min, both had a very low percentage of
microbial reads compared with organellar reads (0.22% and
0.71%), with the differences not statistically significant (P = 0.1,
Wilcoxon test). As before, endospheric microbial abundance
increased significantly, by 10-fold after 24 h in field soil (3.95%,
P = 0.05, Wilcoxon test). We conclude that brief soil contact
does not strongly increase the proportion of microbial reads, and
therefore the increase in microbial reads at 24 h is indicative of
endophyte acquisition within 1 d after transplantation.
α-Diversity significantly varied by rhizocompartment (P 2E-
16; Dataset S23) and there was a significant interaction between
rhizocompartment and collection time (P = 0.042; Dataset S23);
however, when each rhizocompartment was analyzed individ-
(13 d) approach the endosphere and rhizoplane microbiome
compositions for plants that have been grown in the green-
house for 42 d.
There are slight shifts in the distribution of phyla over time;
however, there are significant distinctions between the com-
partments starting as early as 24 h after transplantation into soil
(Fig. 6D, SI Appendix, Figs. S24B and S26, and Dataset S24).
Because each phylum consists of diverse OTUs that could ex-
hibit very different behaviors during acquisition, we next ex-
amined the dynamics and colonization patterns of specific
OTUs within the time-course experiment. The core set of 92
endosphere-enriched OTUs obtained from the previous green-
house experiment (SI Appendix, Fig. S9C) was analyzed for
relative abundances at different time points (Fig. 6E). Of the 92
core endosphere-enriched microbes present in the greenhouse
experiment, 53 OTUs were detectable in the endosphere in the
time-course experiment. The average abundance profile over
time revealed a colonization pattern for the core endospheric
microbiome. Relative abundance of the core endosphere-
enriched microbiome peaks early (3 d) in the rhizosphere and
then decreases back to a steady, low level for the remainder of
the time points. Similarly, the rhizoplane profile shows an in-
crease after 3 d with a peak at 8 d with a decline at 13 d. The
endosphere generally follows the rhizoplane profile, except that
relative abundance is still increasing at 13 d. These results sug-
gest that the core endospheric microbes are first attracted to the
Fig. 5. OTU coabundance network reveals modules of OTUs associated with methane cycling. (A) Subset of the entire network corresponding to 11
modules with methane cycling potential. Each node represents one OTU and an edge is drawn between OTUs if they share a Pearson correlation of
greater than or equal to 0.6. (B) Depiction of module 119 showing the relationship between methanogens, syntrophs, methanotrophs, and other
methane cycling taxonomies. Each node represents one OTU and is labeled by the presumed function of that OTU’s taxonomy in methane cycling. An
edge is drawn between two OTUs if they have a Pearson correlation of greater than or equal to 0.6. (C) Mean abundance profile for OTUs in module 119
across all rhizocompartments and field sites. The position along the x axis corresponds to a different field site. Error bars represent SE. The x and y axes
represent no particular scale.
PLANTBIOLOGYPNASPLUS
Function x Genotype
of magnitude greater than in any single plant species to date.
Under controlled greenhouse conditions, the rhizocompartments
described the largest source of variation in the microbial com-
munities sampled (Dataset S5A). The pattern of separation be-
tween the microbial communities in each compartment is
consistent with a spatial gradient from the bulk soil across the
rhizosphere and rhizoplane into the endosphere (Fig. 1C).
Similarly, microbial diversity patterns within samples hold the
same pattern where there is a gradient in α-diversity from the
rhizosphere to the endosphere (Fig. 1B). Enrichment and de-
pletion of certain microbes across the rhizocompartments indi-
cates that microbial colonization of rice roots is not a passive
process and that plants have the ability to select for certain mi-
crobial consortia or that some microbes are better at filling the
root colonizing niche. Similar to studies in Arabidopsis, we found
that the relative abundance of Proteobacteria is increased in the
endosphere compared with soil, and that the relative abundances
of Acidobacteria and Gemmatimonadetes decrease from the soil
to the endosphere (9–11), suggesting that the distribution of
different bacterial phyla inside the roots might be similar for all
land plants (Fig. 1D and Dataset S6). Under controlled green-
house conditions, soil type described the second largest source
of variation within the microbial communities of each sample.
However, the soil source did not affect the pattern of separation
between the rhizospheric compartments, suggesting that the
rhizocompartments exert a recruitment effect on microbial con-
sortia independent of the microbiome source.
By using differential OTU abundance analysis in the com-
partments, we observed that the rhizosphere serves an enrich-
ment role for a subset of microbial OTUs relative to bulk soil
(Fig. 2). Further, the majority of the OTUs enriched in the
rhizosphere are simultaneously enriched in the rhizoplane and/or
endosphere of rice roots (Fig. 2B and SI Appendix, Fig. S16B),
consistent with a recruitment model in which factors produced by
the root attract taxa that can colonize the endosphere. We found
that the rhizoplane, although enriched for OTUs that are also
Time Series
98. Z. marina as a model system
Jay
Stachowicz
Maggie
Sogin
99. JGI Seagrass Pop Geno/Microbiomics
216 Zostera marina
Thalassia testudinum
Cymodocea nodosa
Posidonia oceanica
Potamogeton crispus
Spirodela
Jeanine
Olsen
Jay
Stachowicz
Slide by Laura Vann from Tree from Les et al., Syst. Bot. 1997
Yves van
De Peer
Laura Vann
100. http://zenscience.org
• Sent kits
• Sampled microbiomes of
leaves, roots, sediment
• Sampled leaves for genomes Jeanine
Olsen
Laura
Vann
Jay
Stachowicz
JGI Seagrass Population Sampling
102. Probiotic consortium from Pocillopora damicornis
BMC screening
7 strains
Microbial Manipulation of Coral
103. Massively Parallel Undergraduates
Pic of Karley Lujuan
David Coil
• Karley Lujuan
• Marcus Cohen
• Katie Somers
• Taylor Tucker
• Hoon San Ong
• Neil Brambhatt
• Hena Hundal
• Daniel Oberbauer
• Briana Pompa-Hogan
• Alex Alexiev
• Ruth Lee
115. Istmobiome Project
~ 3 million years
ago…
Formation of the Panama
Isthmus split the Atlantic
and Pacific Oceans
This geographic barrier
facilitated the speciation of
macro- and micro-organisms
“Divergence of Marine Symbiosis After the
Rise of the Isthmus of Panama”
Collaboration Between STRI and UC Davis
See http://istmobiome.net
Bill Wcislo
117. Diana Chin,
Ph.D. candidate Stony Brook
Ipek Yasmin Meric,
UC Davis undergraduate reasearcher
Gustav Paulay,
Florida Museum
Jay Osvatic
Ph.D. candidate
Uni Vienna
Benedict Yuen,
Postdoc Uni
Vienna
Jillian Petersen,
Professor Uni Vienna
Lucinid
collaborators
118. A.1
A.2
A.3
A.4
A.1-A.4; Wilkins 2019,
Mol Ecol
B
Codakia sister pair
Ctena sister pair
Bacterial symbiont genomes
Sister species locations
Other lucinids sampled
(Clathrolucina spp.)
Other lucinids sampled
(Ctena spp.)
Yellow: Caribbean
Blue: Pacific
119. 4 Phacoides
Atlantic
Promiscuous Istmobiome Atlantic clade
4 Lucinoma Dall clade
Atlantic
Istmobiome Atlantic
5 Chiquita clade (Pacific)
Istmobiome Pacific
Ctena Hawai’i
Clathrolucina clad
Galapagos Codakia
233 high quality bins clustered roughly into 8 clades
! 80% completion, 4% contamination
GTDBTk
Phylogeny
Istmobiome means
Ctena and Codakia hosts
Symbionts:
Other lucinids sampled
(Ctena spp.)
Yellow: Caribbean
Blue: Pacific