Transcript Slide 1

BRANCHED TRICARBOXYLIC
ACID METABOLISM IN
Plasmodium falciparum
( Kellen L. Olszewski,Michael W. Mather,Joanne M. Morrisey,Benjamin A.
Garcia,Akhil B. Vaidya,Joshua D. Rabinowitz,and Manuel Llinás )
Submitted by
Selma Abdul Samad
BCH 10-05-02
S2 MSc.Biochemistry
Dept. of Biochemistry
TCA cycle
Also called citric acid cycle
 The central hub of carbon metabolism – connects
glycolysis,gluconeogenesis,respiration, aminoacid synthesis and
other biosynthetic pathways
 Final products – CO2 , water and energy
 Begins with the transfer of a two-carbon acetyl group from acetylCoA to the four-carbon acceptor compound (oxaloacetate) to form a
six-carbon compound (citrate)
 The citrate then goes through a series of chemical transformations,
losing two carboxyl groups as CO2. The carbons lost as CO2
originate from what was oxaloacetate, not directly from acetyl-CoA
 For each acetyl group that enters the citric acid cycle, three
molecules of NADH are produced
 At the end of each cycle, the four-carbon oxaloacetate has been
regenerated, and the cycle continues
 Several catabolic pathways converge on the TCA cycle
 The citric acid cycle is regulated by the energy needs of the cell
 So,ATP and NADH exert a negative feed back control on citrate
synthase and iso-citrate dehydrogenase
TCA cycle
Plasmodium falciparum
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A protozoan parasite
cause malaria in humans
transmitted by the female Anopheles mosquito
Most dangerous of the Plasmodium species
It causes severe malaria via a distinctive property not shared by any
other human malaria, that of sequestration.Within the blood stage
cycle, the mature forms change the surface properties of infected
erythrocytes causing them to stick to endothelial walls of blood vessels(a
process called cytoadherence).This leads to obstruction of the
microcirculation and results in dysfunction of multiple organs, typically
the brain in cerebral malaria.
 The life cycle of all Plasmodium species is complex
 Infected female Anopheles mosquito bites
Sporozoites released from its salivary gland enters bloodstream and invade
hepatocytes
For 14 days liver-stage parasites differentiate ;undergo asexual multiplication
forming merozoites
Merozoites invade erythrocytes ; continue multiplication ; invade more and
more erythrocytes
Malaria with all its symptoms manifested(fever ,chill, RBC rupture)
TCA metabolism in Plasmodium falciparum
 Blood-stage Plasmodium parasites rely almost entirely on glucose
fermentation for energy and consume minimal amounts of oxygen
 Yet the parasite genome encodes all of the enzymes necessary for a
complete TCA cycle
 By tracing 13C-labeled compounds using mass spectrometry,the
researchers showed that TCA metabolism in the human malaria parasite
P. falciparum is largely disconnected from glycolysis and is organized
along a fundamentally different architecture
 This pathway is not cyclic but rather a branched structure in which the
major carbon sources are the amino acids glutamate and glutamine
 As a consequence of this branched architecture, several reactions must
run in the reverse of the standard direction thereby generating two-carbon
units in the form acetyl-CoA
 It is further shown that glutamine-derived acetyl-CoA is used for histone
acetylation while glucose-derived acetyl-CoA is used to acetylate
aminosugars
 Thus the parasite has evolved two independent acetyl-CoA-production
mechanisms with different biological functions
Metabolites in red – wastes to be effluxed into medium
Red arrows – reductive pathway of TCA metabolism
Blue arrows – oxidative pathway
* - citrate cleavage step enzyme (unclear)
** - 2 enzymes are predicted – cytosolic malate dH or mitoch. malate:quinone oxidoreductase
OG – 2-oxoglutarate ; ICT – Isocitrate ; Ac-R – Acetate/acetyl Co.A
 The mitochondrion of P.falciparum
- contains smallest genome sequenced
- evolved reduced functional roles
- limited mitochondrial cristae
- minimal oxygen consumption
- rapid glucose fermentation
All these suggest that oxidative phosphorylation is not a significant
source of ATP generation during the blood stage
 The critical metabolic function of electron transport during blood stage
growth is the regeneration of ubiquinone in order to supply pyrimidine
biosynthesis
 TCA metabolism plays an active role in the metabolism of the parasite.
The parasite genome encodes orthologues for all TCA cycle enzymes,
which are all transcribed during the blood stage
 The presence of an essential de novo heme biosynthesis pathway in
P. falciparum further implies that succinyl-CoA must be generated in the
mitochondrion
 It has recently been demonstrated that the P. falciparum PDH complex
localizes not to the mitochondrion but the apicoplast
 Thus,instead of its canonical role of feeding glucose-derived carbon into
the TCA cycle, the suggested role of PDH is solely to produce acetylCoA for fatty acid elongation
 The major carbon source contributing to the accumulation of TCA
intermediates was determined - By culturing synchronized parasiteinfected RBCs in media supplemented with C13 labelled glucose,C13 and
N15 labelled aspartate & glutamine ( LC and MS)
 In cultures with C13 labelled glucose, all glycolytic intermediates were
labelled, while carboxylic acid pool labelling was limited (some malate
and fumarate )
 The absence of labeling into other TCAintermediates suggests that these
labeled dicarboxylic acids derive from cytosolic pathways independent
of mitochondrial TCA metabolism
 Similarly, growth on 13C-15N-aspartate results only in the generation of
13C-malate and 13C-fumarate which can also occur in the cytosol
 Feeding of labeled glucose results in labeling of only a small fraction of
the total acetyl-CoA pool, suggesting the presence of additional sources
for two-carbon units
 These data raised the possibility that glucose and aspartate-derived
metabolites are disconnected from mitochondrial TCA metabolism
 Fed with C13N15glutamine – significant labelling of all TCA compounds
 Extracellular glutamine is rapidly taken up by parasitized RBCs and
deamidated to glutamate, which can donate its carbon skeleton to TCA
metabolism through conversion to 2-oxoglutarate
Figure
Glutamine drives reverse flux through the TCA cycle
 And finally it is concluded from the datas that several TCA cycle reactions
are running with net flux in the reverse direction, in the process generating
C2 units from 2-oxoglutarate via citrate
 To further dissect the biological role of this reverse TCA branch,the major
metabolic fates for C2 units: fatty acid synthesis, protein modification and
small molecule acetylation,were investigated
 When parasites are cultured in medium containing either 13Cglucose or
13C-15N-glutamine ,robust labeling of the acetyl groups was observed,in
histone tails,only in the 13C-15N-glutamine-fed cultures
 However,UDP-GlcNAc,a nucleotide aminosugar acetylated in the
endoplasmic reticulum during the biosynthesis of GPI-anchored proteins
associated with malaria pathogenesis,is labeled at the acetyl group only
during growth on 13C-glucose
Figure 2
Acetyl groups deriving from glucose and glutamine are functionally distinct
 Thus it appears that the malaria parasite has evolved two independent
pathways that produce acetyl-CoA for different metabolic functions
 How glucose and glutamine derived C2 units are maintained as
functionally distinct pools and transported from their respective
organelles to different sites of acetylation remains to be investigated
 The metabolic labeling data suggest a branched architecture for
mitochondrial carbon metabolism in which both arms produce malate. In
order to achieve a net flux through these pathways it would be necessary
to remove this terminal product, either by conversion or excretion
 They found that malate, 2-oxoglutarate and, to a lesser extent, fumarate
are excreted from infected RBCs at a significant rate
 Based on these results,a new model for central carbon metabolism in
blood stage Plasmodium sp. was proposed
Figure
Malate excretion by P. falciparum-infected RBC cultures
Figure
An integrated model for central carbon metabolism in P. falciparum
 In this pathway the ultimate carbon source for mitochondrial carboxylic
acid pools are the amino acids glutamine and glutamate, and carbon flux
in the mitochondrion is organized into two independent linear branches
 Branch 1 begins with the reductive carboxylation of 2-oxoglutarate to
isocitrate, which is then isomerized to citrate. This citrate is cleaved into a
C2 compound and oxaloacetate, which is reduced to malate (red in figure)
 Branch 2 comprises the standard clockwise turning of the TCA cycle to
oxidize 2-oxoglutarate to malate, in the process generating reducing
power and succinyl-CoA, an essential precursor for heme biosynthesis
(blue in figure)
 The fact that two labeled forms are observed for malate and fumarate but
no other TCA intermediates during growth on 13C-15N-glutamine suggests
that both branches converge at these metabolites and they are the terminal
products of each
 The P. falciparum genome encodes only an NADP(H) specific,
mitochondrial IDH, suggesting that it may have entirely lost the ability to
run a TCA cycle and is effectively locked into this branched architecture
 It is proposed that the mitochondrial NADPH required by this reductive
pathway may be generated by the parasite's NADP(H)-specific glutamate
dehydrogenase and glutamate oxidation has been detected in isolated
P. falciparum mitochondria
 This branched TCA pathway maybe an evolutionary trade-off in which
metabolic flexibility is lost in order to optimize growth within the specific
environment of the host cell
Reference
Nature. 2010 August 5; 466(7307): 774–778.
Branched Tricarboxylic Acid Metabolism in
Plasmodium falciparum
Kellen L. Olszewski,1 Michael W. Mather,2 Joanne M. Morrisey,2 Benjamin A.
Garcia,3 Akhil B. Vaidya,2 Joshua D. Rabinowitz,4 and Manuel Llinás1*
1Department of Molecular Biology & Lewis-Sigler Institute for Integrative Genomics, Princeton University, Princeton, NJ
08544
2Center for Molecular Parasitology, Drexel University College of Medicine, Philadelphia, PA 19129
3Department of Molecular Biology, Princeton University, Princeton, NJ 08544
4Department of Chemistry & Lewis-Sigler Institute for Integrative Genomics, Princeton University, Princeton, NJ 08544
Author Contributions K.O. cultured the parasites, collected and analyzed all LC-MS and GC-MS data; B.A.G. performed mass
spectrometric analysis of histones. M.W.M. and J.M.M. carried out IDH localization studies. M.W.M. purified
mitochondria and K.O. did biochemical assays. K.O., M.L., J.D.R., M.W.M., A.B.V. and B.A.G. designed the study;
J.D.R. provided the metabolomic technology. M.L. and K.O. wrote the paper. All authors discussed the results and
commented on the manuscript.