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Regulation of Photosynthesis for Nitrogen Fixation · Heterocyst differentiation: changes in...
Transcript of Regulation of Photosynthesis for Nitrogen Fixation · Heterocyst differentiation: changes in...
Regulation of Photosynthesis for Nitrogen FixationRegulation of Photosynthesis for Nitrogen Fixation
Hendrik Küpper, visit to Aberdeen, February 2014
Nitrogen cycle: intermediate steps
NO3-
Nitrite oxidaseNitrite oxidase Nitrate reductaseNitrate reductase
NONO2
-
Anammox N2OH NOH Anammox N2OH2NOH
N2
NH3
Total equation of biological nitrogen fixation
N2 + 8H+ + 16 MgATP + 8e-N2 + 8H + 16 MgATP + 8e
2NH3 + H2 + 16 MgADP + 16 Pi
Organisms involved in nitrogen fixation
Anabaena TrichodesmiumRhizobienAzolla
AzotobacterGloeothece
Mechanism of biological nitrogen fixation:nitrogenase of cyanobacterianitrogenase of cyanobacteria
Evolution of biological nitrogen fixation in comparison to photosynthesis
Berman-Frank I_Lundgren P_Falkowski P_2003_Research in Microbiology154_157-164
Strategies of photosynthesis regulation for nitrogen fixation in cyanobacteriay
Berman-Frank I_Lundgren P_Falkowski P_2003_Research in Microbiology154_157-164
Unicellular cyanobacteria
Regulation of photosynthesis for nitrogen fixation in unicellular cyanobacteria (II)y ( )
glycogen storage begins
light period: carbon + energy storage
max. photosynthetic capacitydown regulation of photosynthesiscarbon energy storage photosynthesis
maximum glycogen storage
nitrogen fixation beginsup regulation ofphotosynthesis
dark period: nitrogen fixation
y
maximum nitrogen fixationmaximum respiration
Heterocyst forming cyanobacteria
vegetative Zellen
Pro-Heterocyste
Heterocyste
From: Culture service of Instituto de Bioquímica Vegetal y Fotosíntesis, Sevilla, Spain
From:El-Shehawy et al 2003 Physiol Plant 119 (1), 49-55
Heterocyst differentiation:distribution maps of chlorophyll fluorescence kinetic
M i l fl t i ld (F )
distribution maps of chlorophyll fluorescence kinetic parameters
Maximal fluorescence quantum yield (Fm)
25 µm
13 h 36 h 55 h 112 h
Photosystem II activity (F /F )Photosystem II activity (Fv/Fm)
Ferimazova N, Felcmanová K, Šetlíková E, Küpper H, Maldener I, Hauska G, Šedivá B, Prášil O (2013) PhotRes 116, 79-91
Heterocyst differentiation:changes in parameters of chlorophyll fluorescence kineticschanges in parameters of chlorophyll fluorescence kinetics
Ferimazova N, Felcmanová K, Šetlíková E, Küpper H, Maldener I, Hauska G, Šedivá B, Prášil O (2013) PhotRes 116, 79-91
Trichodesmium:anoxygenic photosynthesis energizing nitrogen fixation
i th ll d i th h t i din the same cells during the photoperiod
Trichodesmium• Marine filamentous, non-heterocystous cyanobacteria• contribution of Trichodesmium to marine N2 fixation: 30-50%• Nitrogen fixation is confined to the photoperiod and occurs
simultaneously with oxygenic photosynthesissimultaneously with oxygenic photosynthesis. • How nitrogenase is protected from damage by
photosynthetically produced O2 has remained an enigma.photosynthetically produced O2 has remained an enigma.
Surface blooms in the Colonies – tuft and puffSurface blooms in the Arafura Sea
Colonies tuft and puff formation
)351 1Aktivitätszyklus von Trichodesmium
Trichodesmium
n fix
atio
n
µg c
hl a
-1 h
-1
25
30
35
e F v
/Fm
0.9
1.0
1.1
T i h d i
Nitr
ogen
nmol
C2H
2 µ
10
15
20
Rel
ativ
e
0.7
0.8Trichodesmium-
bloom
(n
0
5
0.5
0.6
h-1) 60
1 )
-2
2 µ
g ch
l a-1
h
30
40
50
resp
irat
ion
µg c
hl a
-1 h
-1
-10
-8
-6
-4
GP
(µM
O2
0
10
20
Dar
k r
(µM
O2
µ
-16
-14
-12
10
colonies: “Tuft” and “Puff”
Local time (h)
8 10 12 14 16 18 20 22-20
-10
-20
-18
( )
Berman-Frank I, Lundgren P, Chen Yi-B, Küpper H, Kolber Z, Bergman B, Falkowski P (2001) Science 294, 1534-1537
Co-Localisation of nitrogenase and PSII in Trichodesmium
D1 protein (green) and Nitrogenase (rot). Big picture: Overlay, small picture: only nitrogenase (Immunostain)
Berman-Frank I, Lundgren P, Chen Yi-B, Küpper H, Kolber Z, Bergman B, Falkowski P (2001) Science 294, 1534-1537
Inhibitor-Tests: Need of PSII-activity for nitrogen fixation in Trichodesmium
Influence of DCMU (10 µM), ascorbic acid (100 µM), and DTT (100 µM) wereInfluence of DCMU (10 µM), ascorbic acid (100 µM), and DTT (100 µM) were tested for cultures incubated under aerobic (white columns) and anaerobic (blue columns) conditions. Changes in nitrogenase activity as measured by acetylene reduction.
Berman-Frank I, Lundgren P, Chen Yi-B, Küpper H, Kolber Z, Bergman B, Falkowski P (2001) Science 294, 1534-1537
Proof of Mehler-reaction during nitrogen fixation
Staining with DAB (Diaminobenzochinon) shows intracellular di t ib ti f H O b t i i ll lldistribution of H2O2 as brown stain in all cells
Mehler reaction: H O + 2O > H O +OMehler-reaction: H2O + 2O2 --> H2O2+O2
Berman-Frank I, Lundgren P, Chen Yi-B, Küpper H, Kolber Z, Bergman B, Falkowski P (2001) Science 294, 1534-1537
) " b i ht"b i htl0
Diurnal cycle of activity: Distribution of F0 values
10
ntic
al c
ells
) "very bright"= bright type II
brighttype I
normal
low
F0
5bo
urin
g id
eNon-diazotrophic period
0
ps o
f nei
ghb
10
lls o
r gro
up
Diazotrophic period
5
obje
cts
(ce Diazotrophic period
0 10 20 30 40 50 600
Num
ber o
f o
0 10 20 30 40 50 60N
F0
Küpper H, Ferimazova F, Setlík I, Berman-Frank I (2004) Plant Physiology 135, 2120-33
Diurnal cycle of activity: correlation between bright cells, pigment content and nitrogenase activity
Nitrogenaseactivitye
activ
ityre
duct
ion)
)-1.m
in-1)
activityN
itrog
enas
em
l eth
ylen
e (m
l cul
ture
)
68
1012
N((
m .
% bright cells
ht c
ells
0246
% B
righ
M)
0 2
0.3
0.4
entra
tion
(µM
Chl
06 00 09 00 12 00 15 00 18 00 21 00 00 000.0
0.1
0.2
Chl
con
ce
06:00 09:00 12:00 15:00 18:00 21:00 00:00 control 5% oxygen 50% oxygen
Küpper H, Ferimazova F, Setlík I, Berman-Frank I (2004) Plant Physiology 135, 2120-33
Küpper H, Ferimazova F, Setlík I, Berman-Frank I (2004) Plant
Physiology 135, 2120-33
Hypothesis about the regulation of photosynthesis for nitrogen fixation in Trichodesmium
Licht initiates photosynthesis
Energy and reduction equivalent for CO2-Reduction of the PQ poolassimilation
Induction of a state 2 --> state 1-transition –cells have a high F0 (“bright cells type I”) due
to surplus phycobiliproteinsto surplus phycobiliproteins
Stimulation of pseudocyclic electron transport High respiration rates in early light period
Oxygen consumption exceeds oxygen production: Opportunity for nitrogen fixation
Carbohydrates are consumed
Respiration decreases, transition to the “normal F0 inactive” or “quenching” stateRespiration decreases, transition to the normal F0 inactive or quenching state
Intracellular oxygen rises
Nitrogenase becomes inhibited, no further nitrogen fixation until the following day, cells return to "normal F0 active" state
Deconvolution of spectrally resolved in vivo fluorescence kinetics shows reversible coupling of individual
ph cobiliproteinsphycobiliproteinsBasic dark-adapted fluorescence yield F0 Non-photochemical changes in fluorescence yield
quenching normal F0 active bright I =diazotrophic
Küpper H, Andresen E, Wiegert S, Šimek M, Leitenmaier B, Šetlík I (2009) Biochim. Biophys. Acta (Bioenergetics) 1787, 155-167
Sequence of uncoupling events in a „bright II cell“„ g
Küpper H, Andresen E, Wiegert S, Šimek M, Leitenmaier B, Šetlík I (2009) Biochim. Biophys. Acta (Bioenergetics) 1787, 155-167
Reversible coupling of individual
...as a basis for diazotrophic photosynthesis
phycobiliproteins...p y
Küpper H, Andresen E, Wiegert S, Šimek M, Leitenmaier B, Šetlík I (2009) Biochim.
Biophys. Acta (Bioenergetics) 1787, 155-167
Iron limitation: rescue of photosynthetic components......by sacrificing nitrogenase
PsaCPsaC
new PE isoform
Küpper H, Šetlík I, Seibert S, Prášil O, Šetlikova E, Strittmatter M, Levitan O, Lohscheider J, Adamska I, Berman-Frank I (2008) New Phytologist 179, 784-798
Conclusions
• For Trichodesmium, photosystem II activity is essential for providing energy for nitrogen fixation.
• Regulation of PSII activity for nitrogen fixation is achieved mainly by quickly reversible (un)coupling of individual phycobiliproteins.
• The nitrogen fixing activity state is characterised by a particularly large PSII-associated antenna, which is achieved mainly by coupling of additional units of phycourobilin (PUB) isoformsof phycourobilin (PUB) isoforms.
• Therefore, acclimation to light limitation (“low light stress”) involves enhanced th i i l f h bili hi h i th i l l d t PSIIsynthesis mainly of phycourobilin, which is then mainly coupled to PSII.
Synthesis and levels of other photosynthetic components decrease.
• Because of their vital importance, when adverse conditions require a choice, Trichodesmium in contrast to other cyanobacteria does not sacrifice its phycobilisomes, but rather its nitrogenase.p y , g
• Stress leads to expression of alternative phycobiliprotein isoforms
Current and former lab membersinvolved in this project
Elisa Andresen, Barbara Leitenmaier, Qiyan Wang-Müller, Sven Seibert, Verena Rösch, Christian Lang
CollaboratorsNaila Ferimazova, Ivan Šetlík, Eva
Š lík O d j P šil Ph h iIwona Adamska, Jens
Šetlíkova, Ondrej Prašil: Photosynthesis Research Centre, Institute of
Microbiology, Třeboň, Czech Republic
Lohscheider, Martina Strittmatter: Universität
Konstanz, Germany
Yi Bu Chen Zbigniew Kolber Paul
Ilana Berman-Frank: Bar Ilan University, Israel
Pernilla Lundgren Birgitta
, y
Yi-Bu Chen, Zbigniew Kolber, Paul Falkowski:
Rutgers University, U.S.A
Pernilla Lundgren, Birgitta Bergman: Stockholm University
Sweden
Main sources of external fundingDeutsche Forschungsgemeinschaft
NATO “Science for Peace” programmeMinistry of Education of the Czech Republic
All slides of my lectures can be downloaded
from my workgroup homepage www uni-konstanz de Department of BiologyWorkgroups Küpper labwww.uni-konstanz.de Department of Biology Workgroups Küpper lab,
or directlyhttp://www.uni-konstanz.de/FuF/Bio/kuepper/Homepage/AG_Kuepper_Homepage.html
and
on the ILIAS websiteon the ILIAS website