Lecture 6- Environmental Microbiology PDF

Summary

This lecture covers environmental microbiology, including readings, past exam questions and a variety of diagrams. The document details multiple biological, chemical, and physical processes, systems and relevant diagrams.

Full Transcript

Readings
Chapter 19 Taking the measurement of microbial
systems (helpful for some tutorial presentations)
molecular approaches
Week 5 Microbial ecology lecture looks at the
basics of ecology in microbial systems
Chapter 20 Microbial ecosystems (Week 6
Environmental microbiology lecture)
Chapter 21 Nutrient cycles (Week 6 Environmental
microbiology lecture)
Chapter 23 Microbial symbioses with microbe, plant
and animals (Lecture 7, Week 8, Microbial
interactions)
Last few slides of microbial
ecology
examinable for finals

Indicator Species
 Bioindicators
Bioindicators can be a biological process, species or
community
A change in their size indicates a change in an
environmental parameter originating
in activity
human
~

Usually anthropogenic but can also be natural
An indicator species will have physiology that is
responsive to the environmental variable
e.g. Canaries in coal mines, frog spawn and pollution
 & not too common
not super rare
~

*
&

common
very
 Microbial Indicators
Microbes are great indicators of biological processes as
they do many of them from
synthesis of organic
C 102
~

Primary productivity
Respiration (BOD)
- demand
biogeochemistry biological oxygen
2
eg
N fixate & etc.

Microbes have been used as indicator species ~ faster & cheaper
Direct (cfu counts) or indirectly (biomarker molecules)
Biomarker molecules include diagnostic molecules for
the presence of an organism such as fatty acid, DNA,
protein
Why are microbial systems so
amenable to ecology?
 Microbial systems
Large populations size
Short generation time budeif abundaneenies
~ can knockoutagene &
Genetic manipulation (ultimate reduction)
& not things
just correlating
Readily sampled
Experimentally tractable
Different modes of genetic inheritance
Environmental Microbiology
Introductory Microbiology
Assoc. Prof. Rebecca Case
SCELSE/SBS
[email protected]
 Life on earth
Many ecosystems exist on earth. An ecosystem is an
environmental unit in which the physical (abiotic) components
interact with the community of organisms (biotic)
Microbial photosynthesis produces:
organic carbon from CO2
and oxygen (waste product)
Primary productivity and the rate at which carbon dioxide is
reduced into organic carbon
CO2 fixation is the production of organic carbon compounds
chemical exts to
from CO2 ~ Yorganic
o o
~ light energy
uses
to make food

for itself
Performed by chemoautotrophs and photoautotrophs
Oxygen accumulated in the atmosphere making it habitable for
humans and most other life forms we know
This made Earth habitable to organisms that respire organic
carbon with oxygen to carbon dioxide
 Oxygenic photosynthesis made Earth
habitable for eukaryotes
in
CO2 is high
low in e
pasta
present
metals became metal oxide
then can be
oxygen
accumulated in atmosphere
microbial fossils
microbial fossils
 inclusi bodies
inside cell ,

forms a fillment
so its multicellular

~800 myo fosilized cyanobacteria from stromatilites
 have characteristic biochemical structures
~
Hopanoids – Molecular Fossils

dructure
eringdifficult
is for
microbes to digest
& is
biologically
inaccessible ,

making it molecular
fossils

~
characteristic of phototrophs
Specific hopanoid for phototrophs (2-methylhopanes) and
this has been used to data photosynthesis before the
oxygenation of the atmosphere
 Hopanoids
~
hydrophobic cructure

Hopanoids are lipids found in cell membranes
Thought to play a role in membrane fluidity, stress and
protein localization much better than
S

They can be used as biomarkers just like DNA, RNA and
proteins
They are much more stable than DNA, RNA and proteins
and therefore are used as biomarkers in fossils
However, they do not contain sequence information and
are therefore harder to identify
2-methylhopanoids as biomarkers for cyanobacteria and
oxygenic photosynthesis date
oxygenic photosynthesis
can
 Life on earth
Microbes drive the biogeochemical cycles required for life
Biogeochemical cycles allow essential elements to be
cycled for reuse through habitats and spheres
Think about the diversity of energy sources for chemo,
e-acceptor &

litho- and auto- trophic organisms elements/cmpds
as these
generate energy
donor to
arl
can as

These cycles are a series of redox reactions that Bacteria
and Archaea use for energy (electron (e) acceptors and
donors) and to make organic carbon
Nitrogen, Phosphorus, Carbon (C:N:P)
Bust don’t forget Oxygen, Hydrogen and Sulfur!
These elements also make up the biomolecules that
make life (DNA, RNA, proteins)
 The Sulfur Cycle
S04-2>SO3-2>SO2>S2O32->
different states of
s >modendant S>H2S
& &
rotten eqp small
yellow
colour
 Sulfate reduction
~ e-acceptor => [H) to
-

SO42- + 2H+ + 2e- > SO32- + H2O 1 ATP generated
[H)
S

SO32- + 6H+ + 6e- > S2- +3H2O 3ATP

Sulfate-reducing bacteria have very short electron
transport chains (ETC) because little energy is available
relative to O2
Sulfidogens are microbes that produce H2S. Obligate
anaerobes are common in soil and marine environments
-
killed
by normal atmospheric

Very diverse. Best known example: Desulfovibrio
From sulfate reducers to sulfidigens
outside to
protons pumped
create electron potential

generated

e whole doesn't generallywouldexists
in all
be a
usually
one
bacteria ,

sulfate reducer , another will be a
sulfidogen
lot from e
[H) a

more asi energy generated all
member to
converses is too much for e

handle
 Sulfur oxidation (chemoautotrophs)
~
reverse e-flow
ETC can be reversed in sulfur oxidizers because HS-, S2O32-
and S0 are weaker electron donors than NAD/NADH (NADH reduct
generates NADH by equir for com
& TH) as

required for CO2 fixation) sulfur
fixation as
also
oxidisers are
&
chemoautotrophs
Electrons from these fuel sources fed into ETC at level need organic to
reduce co2
C

equivalent to their E0
Proton motive force formed at quinone (Q) and terminal
oxidase (cytochrome – cyt)

bringinginprora p
The Nitrogen Cycle
NO3 >NO2 >NO>
- -

N2O>N2>NH3>NH4+
 I most oxidised form
~ takes
back to N2

(neutral State)

N fixate

creduced forms

most reduced

~ If
n a

form
 ~ NO

Stepwise Nitrate Reduction: Denitrification
1. NO3- + 2H+ + 2e- > NO2- + H2O 2 ATP some microbes can

step but many microbes
do>

& 14
just doI step
2. 2NO2- + 2H+ + 2e- > 2NO + 2OH- 2 ATP produce enough energy
for
themselves

3. 2NO + 2H+ + 2e- > N2O + H2O 2 ATP
4. N2O + 2H+ + 2e- > N2 + H2O 2 ATP
& most reduced form

1st step: nitrate respiration is carried out by E. coli and
many other bacteria
Sequential reduction of nitrate (NO3-) to N-gases (NO,
N2O, and N2) = denitrification
N2O (nitrous oxide) is a potent greenhouse gas
produced mainly by denitrification in agricultural soils
(and laughing gas)
 Nitrogen Fixation
Reduction of dinitrogen gas (N2) to ammonia (NH3) by the
enzyme nitrogenase – very O2 sensitive (major process
~
anaerobic
limitat )
=

Life as we know it depends on the rapid cycling of nitrogen
into biologically available forms
Two enzyme complex (dinitrogenase and dinitrogenase
reductase requirement of being process
an anaerobic

energetically~ expensive (triple bond)
Only prokaryotes do it! And lots of different kinds
symbiotic bacteria (e.g. Rhizobia that associated with
plants)
Cell differentiation (e.g. Cyanobacteria)
Free-living aerobes (e.g. Azotobacter
Free-living anaerobes (e.g. Clostridium)
&
N2 have 3 N
hard to
bonds ,
very
break up ,
a lot of
energy required
N2 NH4+

-
Soil (community)
can Cultured microbe
&
look Gene for path
e of NUnt
&
Study
have Chizobia inoculated no Rhizobin on roots
e
on roofs
in size &
larger greener
they are

(more chlorophyll)
-
> more
photosynthesis
& grow better
 see w
dijih is what we

called modules
our eyes ,

not like that
&
they i
are
bacteria infects
until

k ,
a
,
e density of alls is

immature organ I root
of
noduce which require I infects
thread (in blue)

anaerobic
infeste multiply ,
it is

& causes maturate of e organ

Gene promoter e infecte thread-microbes colonizat

fusions
-Lac expression,
Xgal BLUE
- GREEN
Fluorescent
protein
 Nitrogen fixing symbionts
colonised
Rhizobia (alpha proteobacteria) – terrestrial plants
Eukaryotes unable to metabolise atmospheric nitrogen
so access nitrogen from prokaryotes (symbiotic relationship)
Rhizobia fix (or reduce) atmospheric nitrogen
Make it available to plants
form
through a direct (symbiotic)
of heterotrophic roof modules & consume
plants organic
feed i
sugar solute toe (rhizobia
interaction
C are
& in excess
anaerobic
c d also be
organic can

fixate for nitrogen

Rhizobia induce cell differentiation in host plant to
create niche (chemical communication)
Root nodules have reduced oxygen as nitrogen fixation
is an anaerobic process levels
cyanobacteria polies O
I out
can
carry
&
photosynthesis
nitrogen fixate
"strictly
anaerobia
process
 red shows
presence of
chlorophyll

Nitrogen
fixation is
anaerobic and
therefore no
-blue represents N fixntq photosynthesis
cells (heterocuses)
,
they occurs in
don't have chlorophyll
heterocysts
(blue)
 complex morphologies
~
Heterocysts
Cyanobacteria are also capable of fixing (reducing nitrogen) in
aquatic systems
Specialised cells called heterocysts fix nitrogen
Heterocysts have several features for nitrogen fixation:
thickened cell walls to reduce cell permeability to oxygen
No chlorophyll so no photosynthesis (i.e. oxygen is not
generated in the heterocyst) expression of photosynthetic genes
-
no

Reduced nitrogen (NH4+ or organic N) is transported from
the heterocyst to the vegetative cells doing photosynthesis
who
~
are

There is sugar transported from vegetative cells to
heterocysts organic
&
C from photosynthesis
~
heterocysts
Sugars are supplied in excess so they leak out of the cell,
this attracts heterotrophic bacteria ~
that consume both
oxygen and the sugars reducing O lowering heterocysts making
=>
to colonise
and I cell ,
it anaerobic

The diffusion of these compounds (sugars and organic N)
determines heterocyst spacing
 A schematic diagram of the molecular
regulation of heterocyst patterning.

regulatoai make
heterocupts
~

not literally
cuffq but
causes Hetre
to be misfolded

Peptide signal 5 amino acid signal
~
lots of it made in
heterocycls cell d acts solikewhen
a

molecular scissors
RESER birds to HetR , it degrades
HetR

HetR made
reterocysts it is
immediately degraded by pentapeptide
although is in
,
inside
ecell
causing it to be recognised a degraded
Starvation sensor
from I further you more

diffuses from heterocysts for all towell as organic
N

pentapeptides
,

induce an
TRESURJt causing [HetR] ↑ accumulate this
& can
theres less chemicals
Risser D D , Callahan S M PNAS 2009;106:19884-19888 away ,

thick cell wall d etc.
of all e
genes needed to make a
heterocytes e.

g
expe.
 Heterocyst spacing
A schematic diagram of the molecular regulation of
heterocyst patterning. The activator of heterocyst formation,
HetR, is expressed under nitrogen starvation. The RGSGR
pentapeptide (a signal) promotes HetR decay and therefore
inhibits heterocyst formation. The RGSGR pentapeptide
diffuses away from source cells (heterocysts) to
neighbouring cells (vegetative) establishing an inhibitor
concentration gradient along the filament, which in turn
promotes an inverse gradient of the activator, HetR. Arrows
indicate positive regulation. Scissors indicate decay.
 Aerobic N2 fixation

Azotobacter vinelandii
Under low O2, no slime layer
-acts as a

barrier
Under high O2, large slime layer
upregulate
Slime retards diffusion of O2 biosynthesis
EPS
>
-

into cell
Nitrogenase will not be
inactivated upregulate of nitrogenase
&
C
Eps : extravellular
geres polysaccharide
very sticky & de,a
The Phosphorus Cycle
P>PO4
& more abundant
 washed
phosphate &
out of rocks

goes into water

photo credit: Raven, Peter,
Linda Berg. Environment
third edition. Harcourt:2001
Lady Musgrave Island, GBR, Australia. The island is made of Guano (bird
poop) which was mined for phosphate used in industry and agriculture.
 Douglas-fir seedlings with and
without mycorrhizae inoculation.
phosphate mobilisate
plants also rely on
fungi as they can do

roof associates
transport into plants by

plantgrowsthet are
Redwood seedlings with (right) and without (left) mycorrhizae.
Mike Amaranthus, USDA
mushrooms (Borneo)
mycelium
 structures that penetrate
on i surface surface layer epidermis
↑

e
into dark yellow cells

not inside cells but
they are ,

I cells this maximises
betw as

SA to maximise exchange of
befor
unfrients a
coupds fungus
a plant
 Phosphate
Fungi secrete H+ to lower the pH of soil (from ~8 to 5),
making metals more bio-available
H+ displaces the metal cations in salts or complexes so
available
biologically
~
they can be taken up (dissolves them) ~ they
exclude bacteria
i

This change in pH also serves to create a niche for the
fungi as they are acid adapted and bacteria are less
competitive in low pH environments
Phosphatases (enzymes used for phosphate uptake) are
adapted to a low pH in fungi and a neutral-basic pH in
bacteria
Bacterial phosphate uptake important in wastewater
processing to accumulate polyphosphate removed -
is

Phosphorus is usually oxidized as PO4+2 in soils and this is
the form microbes usually uptake
 Mycorrhizae
Mycorrhizae are the symbiotic system formed
between plant roots and fungi
Found on 95% of plants examined (small sample
of real diversity, but prevalent)
Symbiosis formed primarily for nutrition exchange

Two Types: (slide 42)
1. VAM Arbuscular Mycorrhizae (inside plant root)
2. Ectomycorrhizae (outside plant root)
 Mycorrhizae
The fungus has enzymes that dissolve tightly bound
minerals like phosphorus, sulfur, iron and all the major and
minor nutrients used by plants
The primary exchange usually found is:

Fungus access phosphate from soil and
exchanges it for
Sugars produced by the plant through photosynthesis

Essential in phosphate limited systems
in
type) :

arbuscular means

webbed-like struct

> maximisa
interface betw
cells as it
only imports phosphate
I sells
to specific cells & from there
other cells and it
transports it to

however, phosphate is not equally
distributed among
I plant
Diagram indicating possible sites of plant and
fungal phosphate transporters and fungal glucose
transporters in membranes of an arbuscular
mycorrhiza.
Phosphate transport: 1, phosphate uptake across
membranes in the external hyphae; 2, phosphate
efflux across the arbuscule membrane; 3,
phosphate uptake across the peri-arbuscular
membrane (2&3 inside plant). The net transfer is
from the soil into the plant as the fungus is able to
efficiently scavenge phosphate.
Carbon transport: 2 and 4, possible sites of glucose
uptake by the fungus. Carbon transport is inside the
plant because the plant makes organic carbon
through photosynthesis.
 is maintained as wants
it
to differentiate betw self a fungus

may
< Himtransport is
so
 polymerised into

n
sugaa f

art funsa wall
throughall wall
plant
 Mycorrhizal Benefits

Improved transplant survival and growth
More effective rooting place
holdsI soil in less eros?
mycelium
,

Improved soil structure
~
organic c which
is
& also ofholds it a lot impt

in fertiliser
uptake of more nutrients

Increased fertilizer utilization
~

plant by
water soil @
greater
Decreased drought stress depths
-
more held I
in
e
in roots

Tolerance of environmental extremes
Reduces off-site pollution of surface and
groundwater mycorrhizal gets
& toxicof soil
ecmpds out I

Disease reduction
 Mycorrhizae in succession
mycorrhizae exports enzymes
out of t cell

Essential-role in developing soils
Exo-enxymes make micronutrients available to
biosphere enabling further succession
Change soil (habitat) characteristics
i dificatirreversibly so that their hosts are often excluded
from the environment (acidification – conifer
&
forests the best example) forest diff plant diversity can lose
exclude as acidificate can other
plants
Possible mechanisms of reduction of
infection by root pathogens by
mycorrhizae
Production of antibiotics by fungal symbionts
Mechanical barrier created by fungal mantle
Chemical exudation of mycorrhizae
&
Protective microbial rhizosphere populations
acidificat encourages specific bacteria
acid-tolerant
that are

living
in
i chizosphere
,

shaping rhizosphere community
 Relationships between phylotype diversity
(Shannon index) and MAT, latitude, PET, and soil pH

driven by
corrhizal
~ my

only acidificate forces
diversity
=> downward influence on
& able
microbial diversity
to exclude a lot of species
a
and root also
living ,

diseases
exclude many

Fierer N , Jackson R B PNAS 2006;103:626-631
©2006 by National Academy of Sciences
 Past exam questions

2-methylhopanoids were proposed as biomarkers in
paleobiology for:
A.Anoxygenic photosynthesis
B.Oxygenic photosynthesis
C.Methanotrophy
D.Alphaproteobacteria
E.Gammaproteobacteria
 Past exam questions
~ simpler
form
Anoxygenic photosynthesis:
A.Postdates oxygenic photosynthesis and requires
PhotoSystem I or II
B.Postdates oxygenic photosynthesis and requires
PhotoSystem I and II
C.Predates oxygenic photosynthesis and requires
PhotoSystem I or II
D.Predates oxygenic photosynthesis and requires both
PhotoSystem I and II
E.Predates oxygenic photosynthesis and doesn’t
require a PhotoSystem
Definitys
Past exam questions
The energy and carbon sources for chemoheterotrophs, chemolithotrophs,
photoheterotrophs and photoautotrophs are (respectively):
A. Energy from light, carbon from CO2; energy from light, carbon from organic
sources; energy from oxidation of inorganic compounds, carbon from CO2;
energy and carbon from organic substrate
B. Energy from organic substrate, carbon only from CO2; energy from oxidation
of inorganic compounds, carbon from CO2; energy from light, carbon from
organic sources; energy from light, carbon from CO2
C.Energy and carbon from organic substrate; energy from oxidation of inorganic
compounds, carbon from CO2; energy from light, carbon from CO2; energy
from light, carbon from organic sources
D.Energy from oxidation of inorganic compounds, carbon from CO2; energy and
carbon from organic substrate; energy from light, carbon from organic
sources; energy from light, carbon from CO2
E. Energy and carbon from organic substrate; energy from oxidation of
inorganic compounds, carbon from CO2; energy from light, carbon from
organic sources; energy from light, carbon from CO2
 Past exam questions

Going from the most oxidized to the most reduced forms in
the sulfur cycle can look like:
SO4-2 > SO3-2 > SO2 > S2O3-2 > S > H2S
more abundant & rea shorter ET
~

The reduction of SO4-2 to SO3-2, compared to the
reduction of SO4-2 to H2S, is:
A.More common and tightly controlled within a cell
B.Less common and not as well controlled within a cell
C.Less common and tightly controlled within a cell
D.More common and not as well controlled within a cell
E.More common and generates more ATP
 Past exam questions

The enzyme nitrogenase, an important part of nitrogen
fixation, is responsible for the reduction of:
A.NO2- to NO
B.N2 to NH3
C.NH3 to NH4+
D.NO3- to NO2-
E.NO to N2O
 Past exam questions

What type of cell do cyanobacteria use for nitrogen fixation?
A.Akinetes
B.Vegetative cells
C.Hormogonia
D.Heterocysts
E.None, cyanobacteria cannot fix nitrogen