(Received for publication, February 3, 1997, and in revised form, June 19, 1997)
From the Department of Biochemistry, Indian Institute
of Science, Bangalore 560 012, India, ¶ Kansai Medical University,
Fumizonocho Norwich Osaka 570, Japan,
Center for Cellular and
Molecular Biology, Hyderabad, 500 007, India, and ** Jawaharlal Nehru
Centre for Advanced Scientific Research,
Bangalore 560 064, India
The mouse and human malarial
parasites, Plasmodium berghei and Plasmodium
falciparum, respectively, synthesize heme de novo following the standard pathway observed in animals despite the availability of large amounts of heme, derived from red cell
hemoglobin, which is stored as hemozoin pigment. The enzymes,
-aminolevulinate dehydrase (ALAD), coproporphyrinogen oxidase, and
ferrochelatase are present at strikingly high levels in the P. berghei infected mouse red cell in vivo. The isolated
parasite has low levels of ALAD and the data clearly indicate it to be
of red cell origin. The purified enzyme preparations from the
uninfected red cell and the parasite are identical in kinetic
properties, subunit molecular weight, cross-reaction with antibodies to
the human enzyme, and N-terminal amino acid sequence. Immunogold
electron microscopy of the infected culture indicates that the enzyme
is present inside the parasite and, therefore, is not a contaminant. The parasite derives functional ALAD from the host and the enzyme binds
specifically to isolated parasite membrane in vitro,
suggestive of the involvement of a receptor in its translocation into
the parasite. While, ALAD, coproporphyrinogen oxidase, and
ferrochelatase from the parasite and the uninfected red cell
supernatant have identical subunit molecular weights on
SDS-polyacrylamide gel electrophoresis and show immunological
cross-reaction with antibodies to the human enzymes, as revealed by
Western analysis, the first enzyme of the pathway, namely,
-aminolevulinate synthase (ALAS) in the parasite, unlike that of the
red cell host, does not cross-react with antibodies to the human
enzyme. However, ALAS enzyme activity in the parasite is higher than
that of the infected red cell supernatant. We therefore conclude that
the parasite, while making its own ALAS, imports ALAD and perhaps most
of the other enzymes of the pathway from the host to synthesize heme
de novo, and this would enable it to segregate this heme
from the heme derived from red cell hemoglobin degradation. ALAS of the
parasite and the receptor(s) involved in the translocation of the host
enzymes into the parasite would be unique drug targets.
Chloroquine resistance in malarial parasite is assuming serious proportions, and the necessity to discover new drugs to treat malaria is a major challenge. This calls for the identification of newer drug targets.
Studies in this laboratory have revealed that the human malarial
parasite, Plasmodium falciparum, synthesizes heme de
novo. The parasite is able to incorporate
[2-14C]glycine and 4-14C-labeled
-aminolevulinate (ALA),1
but not [1-14C]glutamate into heme, indicating that the
parasite manifests the glycine pathway observed in liver and
erythroids. ALA synthase and ALA dehydrase activities were also
detected in the parasite (1). The synthesis of heme de novo
by the parasite in the intraerythrocytic stage is rather surprising,
since the parasite obtains a surplus of heme from the degradation of
the red cell hemoglobin. However, this heme is stored as the inert
hemozoin pigment (2, 3). Further, most hemoflagellates, parasitic
protozoa in both plants and animals, need preformed heme for growth
(4).
Leishmania tarentolae was found to contain free porphyrins but required intact iron-protoporphyrin for growth in culture, suggesting that it may lack ferrochelatase, the enzyme required to incorporate iron into protoporphyrin (5). Trypanosome cruzi was shown to require hemin/hemoglobin for growth. It was reported to manifest ALA dehydrase activity, but porphobilinogen deaminase was absent. However, functional ferrochelatase could be detected, leading to the conclusion that the parasite has lost part of its heme pathway due to mutations in some of the enzyme sequences, necessitating preformed hemin requirement (6).
The malarial parasite contains cytochromes (7, 8), and studies in this laboratory have demonstrated a requirement for heme to sustain optimal protein synthesis (9). De novo synthesis of heme is vital to the malarial parasite, since treatment of the culture with succinylacetone, a specific inhibitor of ALA dehydrase, leads to death of the parasite. It has, therefore, been concluded that the parasite utilizes the heme synthesized de novo for metabolic purposes, whereas it stores the surplus heme, which is toxic, derived from hemoglobin degradation as inert hemozoin pigment (1, 9). In view of these results and the possibility that the heme biosynthetic pathway of the malarial parasite could be a new drug target, studies have been carried out on the possible origin of the enzymes of the pathway. The results indicate the interesting feature that the parasite genome may not code for all the enzymes of the pathway. While the parasite makes ALA synthase, the first enzyme of the pathway, it imports ALA dehydrase and perhaps most of the other enzymes of the pathway from the host red cell to acquire the heme biosynthetic potential.
Materials
Antibodies raised against purified CPO and FC preparations from
the human red blood cells in rabbits (10) were used. Antibodies to
human red cell ALAS and full-length mouse erythroid ALAD clone were
kind gifts from Dr.Gloria C. Ferreira, University of South Florida and
Dr. Terry Bishop, Johns Hopkins University, respectively. [2-14C]Glycine and 4-14C-labeled
-aminolevulinic acid were obtained from BRIT (Bombay) and NEN Life
Science, respectively.
Methods
Parasite Maintenance and IsolationSwiss mice were injected with P. berghei, and blood was removed at different stages of parasitemia ranging from 30 to 80%. The parasitized red cells as well as the red cells from uninfected mice (control) were spun down and put into overnight culture as described for P. falciparum (11). In some experiments, P. falciparum maintained on O+ human red blood cells in culture (about 8% parasitemia) as described earlier (1, 11) was also used. After appropriate treatment of culture, the cells were isolated and lysed with 0.15% (w/v) saponin (12). The parasite pellet as well as the infected red cell supernatant (IRS) were obtained by centrifugation. The red cells from uninfected mice were processed similarly to isolate the uninfected red cell supernatant (URS) and the membrane pellet.
Heme Synthesis by P. berghei in CultureMice were injected with P. berghei and blood was removed at different stages of parasitemia ranging from 30 to 80%. The parasitized as well as control red blood cells were spun down and put into overnight culture (8 h), during which time they were incubated with [4-14C]ALA (1 µCi) or [2-14C]Glycine (12.5 µCi). The red cells were pelleted, and the parasite pellet, IRS, and URS were isolated after lysis. The fractions were extracted with ethyl acetate/acetic acid (3:1). The extract was washed with water and then 1.5 N HCl to remove the precursor used and all the porphyrins. The final ethyl acetate layer was washed twice with water to remove acid and used to measure radioactivity incorporated into heme (13). Separate analysis of the ethyl acetate layer by chromatography has revealed that the radioactivity is entirely accounted for by heme (14). The first water wash and the 1.5 N HCl-extracted fractions were used to analyze for radioactivity in ALA plus porphobilinogen (PBG) and coproporphyrin plus protoporphyrin, respectively (13). ALA and porphobilinogen were separated by fractionation on a Dowex-1 (acetate) column (15).
Assay of EnzymesALAS, ALAD, and FC activities were assayed
in isolated fractions of the parasite, IRS, and URS. The parasite
pellet was lysed with 20 mM Tris-HCl (pH 7.5) containing
0.2% Triton X-100 by repeated homogenization, and the membrane
fraction was pelleted at 8000 × g (15 min). This
fraction was used to assay ALAS and FC, since the activities were
located in this fraction. The assay mixture for ALAS contained the
following (16): Tris, pH 7.5 (50 mM), glycine (100 mM), sodium succinate (10 mM),
MgCl2 (5 mM), coenzyme A (500 µM), ATP (5 mM), pyridoxal phosphate (200 µM), partially purified Escherichia coli
succinyl-CoA synthase (20 µg), and the membrane protein (100 µg).
The mixture was incubated for 1 h at 37 °C. The product was
converted to porphobilinogen by the addition of purified ALAD, and
porphobilinogen formed was estimated using modified Ehrlich reagent
(17). FC was also assayed in the membrane fraction (18), and the assay
mixture contained Tris, pH 7.5 (20 mM), protoporphyrin
1 X (100 µM), -mercaptoethanol (1 mM), 59FeCl3 (2.5 µCi), and
membrane protein (50 µg). The mixture was incubated for 1 h at
37 °C under anaerobic conditions. Radioactive heme formed was then
extracted and radioactivity measured. ALAD was assayed in the soluble
fractions after passing the same through a DEAE-Sepharose column to
remove hemoglobin. The enzyme activity was located in the 0.2 M NaCl eluate, and the assay mixture contained Tris, pH 7.5 (20 mM), ALA (50 µM), ZnCl2 (10 µM),
-mercaptoethanol (5 mM), and enzyme
fraction (20 µg of protein). The assay mixture was incubated at
37 °C for 1 h. The porphobilinogen formed was estimated using
modified Ehrlich reagent (17).
ALAD was purified from the parasite pellet and mouse and human red blood cells by a slight modification of the known procedure (19). The parasite and red cell lysates were spun at 8000 × g for 15 min, and the soluble fractions were subjected to the following steps: DEAE-Sephacel chromatography, ammonium sulfate fractionation (0-45%), and octyl-Sepharose and phenyl-Sepharose chromatography. The last two column steps were repeated with the preparation obtained to get the pure protein. The preparation from human red blood cells was used to raise antibodies in rabbits.
Western Blot AnalysisThe purified ALAD preparations (75 ng) from the parasite and mouse red blood cells were analyzed on SDS-PAGE (10% gels) and transferred to nitrocellulose for immunoblot analysis. Similarly, membrane fractions (8000 × g pellet, 100 µg of protein) from the parasite, IRS, and URS were used for Western analysis of ALAS, CPO, and FC. The crude soluble fraction (75 µg of protein) was also used for analysis of ALAD. The blots were screened with antibodies to the human enzyme preparations, diluted in the range 1:200 to 1:1000. The blots were finally analyzed with goat anti-rabbit antibodies conjugated to alkaline phosphatase.
N-terminal Sequence AnalysisPurified ALAD from the parasite (P. berghei) was subjected to N-terminal sequence analysis using a Shimadzu gas phase protein sequencer (PSQ1).
Immunogold Electron MicroscopyImmunogold electron microscopy was carried out (20) with the isolated parasite (P. berghei), as well as with the infected and uninfected red cells. These were fixed with 4% paraformaldehyde in 0.1 M phosphate buffer, pH 7.4, and embedded in LR Gold resin. Sections (60-70 nm) were cut and picked on copper grids. In experiments where purified ALAD was incubated with parasite membrane to demonstrate binding, the membrane preparation was first sonicated briefly to get a homogenous preparation. After incubation with ALAD and washing, the membrane pellet was diluted severalfold and used directly for coating copper grids by incubating at room temperature for 1 h. All of the grids were washed with PBS containing 3% bovine serum albumin and incubated for 2 h with ALAD antibodies (1:1000 diluton), washed again, and then incubated with goat anti-rabbit IgG conjugated to gold particles (10 nm in diameter) in PBS containing 1% bovine serum albumin. The grids were stained with 2% osmium tetroxide and examined under the electron microscope.
Influence of Succinylacetone Treatment of the Host Red Cell on ALAD Activity of the Parasite (P. falciparum)Succinylacetone is known to be an irreversible inhibitor of ALAD activity (21). Fresh human RBCs (in complete medium) were incubated with succinylacetone (500 µM in final concentration) overnight at 4 °C. These as well as RBCs not treated with succinylacetone (control) were washed thoroughly with culture medium and then incubated with PBS containing 2 mM ALA for 2 h at 37 °C to remove any free succinylacetone by converting it nonenzymatically to a pyrrole (22). A 3-day-old culture (1.5 ml) of P. falciparum was subcultured in two vials, one receiving succinylacetone-treated RBCs and the other control RBCs. After another 4 days, a second subculturing was done with the respective RBCs. After another 48 h, the cultures were incubated with 1 µCi of [4-14C]ALA overnight as described earlier. Radioactivity incorporation into heme was measured in the parasite and red cell supernatant fractions. In another experiment, several vials were pooled after second subculturing, and ALAD activity was assayed in the parasite and red cell supernatant fractions. To ensure that the succinylacetone-treated RBCs used in culturing did not have any carryover of free succinylacetone to inhibit ALAD activity, untreated and succinylacetone-treated RBCs were lysed, and the enzyme activity was assayed in each of the fractions as well as when they were mixed.
Specific Binding of Host Red Cell ALAD to the Parasite (P. berghei) MembraneThe parasites were isolated from infected mouse red blood cells by saponin lysis as described earlier. The parasites were then lysed in 20 mM Tris-HCl buffer (pH 7.5) containing 0.2% Triton X-100 for 1 h at 4 °C. The lysate was spun down at 12,000 × g for 30 min, and the pellet was washed with PBS. The membrane pellet was suspended in 20 mM Tris-HCl buffer (pH 7.5) containing 0.5% Triton X-100 and an aliquot (200 µg of protein) was incubated with partially purified ALAD from mouse RBCs at room temperature for 1 h with gentle shaking. A similar incubation was carried out with mouse red cell membrane and trypsin-treated, washed parasite membrane. Another control employed was the incubation of bacterially expressed glutathione S-transferase and glutathione S-transferase-retinoic acid X receptor fusion proteins with the parasite membrane under similar conditions. After the incubations, the membrane fractions were reisolated by centrifugation and washed repeatedly with PBS, and the pellet was then subjected to SDS-PAGE (10% gels) followed by Western analysis with anti-ALAD and anti-fusion protein antibodies. In addition, the membrane fraction was also examined through immunoelectron micrography as described earlier.
Determination of the Number of Binding Sites for ALAD on the Parasite MembraneFull-length mouse erythroid ALAD-cDNA was
cloned and expressed with histidine tag in the T7 polymerase promoter
based vector, pRSETB. The transformed E. coli cells were
grown in 5 ml of LB medium (inoculated from an overnight culture) and
after 2 h of growth (OD 0.6), 1 mM
isopropyl-1-thio--D-galactopyranoside and 200 µCi of
[35S]methionine were added. After another 21/2 h
of incubation, labeled ALAD was isolated from E. coli cells
and purified on a nickel-nitrolotriacetic acid (Qiagen) column, using a
single-step affinity procedure. The parasite membrane (2.4 mg of
protein) was solubilized using 2.5% Triton X-100, 0.5% sodium
cholate, and 0.5 M NaCl for suspension followed by
sonication. The insoluble debris was removed by centrifugation, and the
solubilized membrane was loaded onto nitrocellulose membrane filters.
These filters were then blocked with 5% skimmed milk powder in TTBS
(0.1% Triton X-100, 50 mM Tris-buffered saline) containing
1% bovine serum albumin. The nitrocellulose membrane was then
incubated with increasing amounts of labeled ALAD for 1 h in the
presence and absence of a 100-fold excess of nonradioactive ALAD. The
nitrocellulose membrane filters were washed thrice with TTBS and dried,
and radioactivity was measured. The data were used to generate the
saturation curve and the Scatchard plot to calculate the dissociation
constant and the number of binding sites.
In the
case of P. berghei, blood from infected and uninfected mice
was spun down, and the cells were incubated with
[2-14C]glycine or [4-14C]ALA for 8 h
in culture. In the case of P. falciparum, the parasite maintained in culture was incubated with the radiolabeled precursors overnight. The cells were then pelleted down, washed, and lysed with
saponin, and the parasite pellet, IRS, and URS were used for
measurement of radioactivity in the heme fraction. The results presented in Fig. 1 (A and
B) indicate that similar results are obtained with P. berghei and P. falciparum. The parasite-infected red
cell synthesizes 5-8-fold more heme than the uninfected red cell.
Certain interesting features of the incorporation pattern of the
precursors into heme are also evident. With [4-14C]ALA as
precursor, 80% of the radioactive heme is recovered in IRS, whereas
with [2-14C]glycine as precursor, the bulk of the
radioactive heme is recovered in the parasite pellet.
Next, it was of interest to examine the heme biosynthetic potential of the isolated fractions. These experiments were carried out with P. berghei, since high yields of the parasite could be obtained from infected mice. The IRS, URS, and the parasite pellet were individually incubated with [4-14C]ALA, and the incorporation of radioactivity into heme and intermediates of the pathway was measured. The results presented in Table I indicate certain interesting features. First, maximum heme synthesis is again seen in IRS that is ~ 4-5-fold more than URS or parasite pellet. The parasite pellet has a substantial amount of [4-14C]ALA remaining unutilized compared with URS or IRS. This correlates with the low levels of ALAD detected in P. berghei (this study) as well as in P. falciparum (1). Nevertheless, the parasite converts the porphyrin intermediates to heme efficiently and is more effective than the URS. This suggests that FC, catalyzing iron incorporation into protoporphyrin, could be present at significant levels in the parasite.
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The next step was to assay the activities of ALAS, ALAD, and FC in P. berghei and mouse IRS and URS fractions. ALAS and FC activities were detected in the 8000 × g pellet in each case, whereas ALAD activity was detected in the soluble fractions. The results presented in Table II indicate that ALAS activity in the parasite is 3-4-fold more than in IRS or URS. FC activity in the parasite is as high as that in IRS and is 9-10-fold more than in URS. ALAD activity in the parasite is ~20-fold lower than IRS and 4-5-fold lower than in URS. From the results presented, it is also clear that, whereas the activity of ALAS is the same in infected and uninfected RBC preparations, the activities of ALAD and FC are at least 5-fold greater in IRS than in URS.
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ALAD was purified to homogeneity from P. berghei (Fig. 2), mouse and human
red blood cells. The human enzyme preparation was used to raise
antibodies in rabbits. The parasite and mouse red cell (uninfected)
enzymes appear identical on the basis of several criteria. Both of the
purified preparations show a Km of about 1.5 × 104 M for ALA. They exhibit a broad pH
optimum with a peak at about 7.2. Both preparations show a requirement
for zinc. Succinylacetone at a concentration of 50 µM
brings about 50% inhibition of the activities of both of the enzyme
preparations. Both enzyme species have identical subunit molecular mass
(~37 kDa) on SDS-PAGE and cross-react equally well with antibodies to
the human enzyme (Fig. 3A).
The N-terminal 20-amino acid sequence of both of the preparations is
identical (Fig. 3B). In view of the fact that ALAD
preparation from humans and mice differ by as many as 3 amino acids and
are totally different between mice and yeast in this stretch (23), it
has to be concluded that the P. berghei and mouse red cell (uninfected) ALAD activities are due to the same protein species.
To further prove that the parasite ALAD is of host red cell origin, attempts were made to demonstrate that when the host red cell ALAD is inhibited irreversibly by succinylacetone, the parasite (P. falciparum) cultured with such RBCs also acquires the inhibited enzyme. First, it was found that while the parasite cultured in control RBCs had a detectable ALAD activity, the activity was too low to be detected in parasites derived from succinylacetone-treated RBCs. This was further substantiated by measuring [4-14C]ALA incorporation into heme in the parasite and IRS fractions. The results presented in Table III indicate that incorporation of [4-14C]ALA into heme in the parasite and IRS fractions derived from succinylacetone-treated RBCs is around 10% of the corresponding fractions derived from control RBCs. ALAD activity assays from control, succinylacetone-treated, and mixed RBC lysates indicate that there is no free succinylacetone left to inhibit the enzyme activity or heme synthesis in the parasite (Table IV). It has also been noted that the parasitemia tends to fall when the parasite is cultured in succinylacetone treated RBCs, and there is a striking inhibition of parasite growth after three or four subculturings with such RBCs, indicating that the level of ALAD in the parasite is too low to sustain an optimal rate of de novo heme synthesis to support growth.
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First, the parasite fraction used to assay or purify ALAD
was thoroughly washed, till the washings did not carry a detectable enzyme activity. Second, the parasite membrane fraction as isolated after lysis of the intact parasite does not contain detectable ALAD
enzyme activity or the protein species detectable by Western analysis
under conditions where the activity can be demonstrated in the parasite
cytosol fraction. Third, the recoveries of ALAS, ALAD, CPO, and FC
proteins in the parasite do not follow the trend seen in the RBC
supernatant (Fig. 6). Further, to rule out the presence of ALAD in the
parasite fraction as an experimental contaminant, in situ
immunogold labeling of the enzyme was carried out with the isolated
parasite as well as with the infected red cell. In both cases,
immunoelectron microscopy indicates that the grains are seen inside the
parasite and not on the periphery, supporting the possibility of import
of the host enzyme into the parasite and ruling out experimental
contamination (Fig. 4). It is also interesting to note that the infected red cell has many more grains than the uninfected red cell, confirming the enzyme activity model presented in Table II.
Parasite (P. berghei) Membrane Specifically Binds Host Red Cell ALAD
To examine whether a possible receptor for host red cell
ALAD could exist on the parasite membrane, partially purified ALAD from
the red cell was incubated with parasite membrane fraction for 1 h
at 25 °C, and the membrane fraction was reisolated, washed thoroughly, and then analyzed for ALAD protein by Western analysis after SDS-PAGE. The results presented in Fig.
5A indicate that the parasite
membrane can specifically bind to host red cell ALAD. Under identical
conditions, the red cell membrane has no sites for binding the protein.
Incubation of the parasite membrane with bacterially expressed
mammalian glutathione S-transferase and glutathione
S-transferase-retinoic acid X receptor fusion protein does
not lead to detectable binding of these proteins. Trypsinized and
washed parasite membrane fails to bind ALAD (Fig. 5B,
lanes 3-5). The ALAD protein can be recovered in the
supernatant fraction, suggesting that the failure to detect membrane
binding is not due to degradation of ALAD by leftover trypsin. Finally,
the parasite membrane incubated with partially pure ALAD was
reisolated, washed, and subjected to immunoelectron micrography. A
specific association of the enzyme with the parasite membrane can be
clearly demonstrated, while the red blood cell manifests negligible
binding (Fig. 5C).
Attempts were then made to estimate the number of binding sites for
ALAD on the parasite membrane. Initial attempts to label the native
protein using radiolabeled iodine led to some degradation of the
protein and irreproducible binding data. Therefore, the mouse erythroid
ALAD was expressed in E. coli and biosynthetically labeled
with [35S]methionine. Since the protein was expressed
with a histidine tag, it could be purified on a nickel-nitrolotriacetic
acid column. Once again, binding experiments with intact parasite
membrane gave high background, perhaps due to difficulty in effective
washing of the membrane by centrifugation. Therefore, binding of
35S-labeled ALAD to solubilized parasite membrane loaded on
to nitrocellulose membrane filters was carried out. This approach gave
reproducible results, and the binding of radioactive ALAD could be
chased by the nonradioactive species to an extent of 85-90%. The
binding of ALAD to NC filters in the absence of parasite membrane
preparation was negligible. The saturation curve and the Scatchard plot
are given in Fig. 6 (A and
B). The nonspecific binding was deducted to generate the
Scatchard plot. The data indicate a fairly high affinity of binding
(dissociation constant, 6.3 ± 0.4 × 109) with
the number of binding sites estimated at 1550 ± 26/parasite.
Western analysis of ALAS, CPO, and FC in the membrane
fractions of the parasite, IRS, and URS reveals interesting features (Fig. 7). First, antibodies to human
erythroid ALAS do not cross-react with the parasite enzyme, although
the mouse red cell membrane preparation shows a strong cross-reaction
(~72 kDa). However, the membrane preparation used actually shows
3-4-fold more ALAS enzyme specific activity in the parasite than in
the mouse red cell. CPO is hardly detectable in the parasite and URS,
although strikingly large amounts are seen in IRS (~37 kDa). Separate
experiments reveal that when more protein is loaded on gels, the
parasite CPO can be shown to move with a mobility identical to that
of the host CPO, both cross-reacting with antibodies to the human enzyme (data not presented). FC protein levels in the parasite and IRS
are about the same, with only traces detected in URS. Once again, the
protein preparations from all three preparations have identical
mobilities in SDS gels (~42 kDa) and cross-react with antibodies to
the human enzymes.
The almost equal FC enzyme activity detected in the parasite and IRS (Table II) correlates with the Western blot analysis (Fig. 7). ALAD protein was analyzed in the soluble fraction. The bulk of the protein is seen in the IRS with lower levels in URS and parasite (Fig. 7). This result also correlates well with the enzyme activity pattern shown in Table II.
The present study on the localization of the enzymes of the heme-biosynthetic pathway in the malarial parasite indicates a dual origin for these proteins. The first enzyme of the pathway, namely ALAS, is detectable in the parasite membrane at a level significantly higher than that of the host red cell membrane in terms of activity. However, the parasite enzyme, unlike that of the host red cell enzyme, does not cross-react with antibodies against human erythroid ALAS. This suggests the parasite origin of the ALAS localized in the parasite membrane. This suggestion is supported by a recent report on the successful cloning of the ALAS gene from P. falciparum (24). Parasite ALAD, CPO, and FC fall into another category. These are induced in the host (mice) in response to parasite (P. berghei) infection, and an amount is then perhaps translocated into the parasite.
Interestingly, there is no induction of ALAS in the IRS, once again indicating a difference in its origin in the parasite. Preliminary studies reveal that in P. falciparum maintained in culture, there is no significant increase in ALAD in the IRS, unlike the situation seen in mice with P. berghei infection in vivo. This is to be expected, since the erythrocytes used to culture P. falciparum represent a terminally differentiated state and are incapable of RNA or protein synthesis. Therefore, the higher level of heme synthesis in parasite-infected cultures of P. falciparum should be due to the contribution of ALAS and perhaps FC from the parasite. The high levels of ALAD, CPO, and FC detected in P. berghei-infected mouse erythrocytes should be related to induction of these enzymes during the red cell maturation in vivo, perhaps due to stimulus provided by parasite-mediated red cell degeneration.
Detailed studies with ALAD reveal that the parasite (P. berghei) enzyme is identical to that of the host red cell but is not a contaminant. The immunogold labeling experiments and the demonstration of specific binding of host red cell ALAD to isolated parasite membrane suggest that this enzyme from the host may be translocated into the parasite through a receptor. These studies indicate that the host ALAD binds to the parasite membrane with high affinity, with the number of binding sites coming to about 1550/parasite. This can only be considered as a minimal estimate, since the binding studies have been carried out with solubilized membrane for reasons mentioned earlier.
A similar mechanism of translocation from the host may also operate, in the cases of CPO and FC, on the basis that these enzymes from the parasite have identical mobilities on SDS-PAGE with those of the host and that the parasite and host enzymes cross-react with antibodies to the human erythroid species, although further studies are needed to establish this point. However, unlike in the case of ALAD and CPO, the parasite has significantly high levels of FC. In mammalian mitochondria, both ALAS and FC, the first and last enzymes of the heme-biosynthetic pathway, are localized in the inner mitochondrial membrane (25). There is a possibility that FC like ALAS may also be coded for by the parasite genome, or it may be of dual origin.
While there is extensive literature on the transport of proteins made by the parasite into the host erythrocyte (20, 26, 27), internalization of host hemoglobin and its degradation in parasite food vacuoles lead to generation of amino acids for parasite protein synthesis and large amounts of heme, detoxified and stored as inert hemozoin pigment. Superoxide dismutase represents another example, where 20% of the activity in the parasite is accounted for by the parasite gene coding for the protein and the rest is accounted for by the host red cell superoxide dismutase internalized by the parasite. However, the adopted superoxide dismutase has not been proven to participate functionally in the parasite (28, 29). In the case of ALAD, it is clear that the entire functional enzyme of the parasite is derived from the host. Besides, it has not so far been possible to identify the ALAD gene in the parasite genome (studies in this laboratory), although this cannot be taken as an evidence for its absence.
The results obtained with [4-14C]ALA incorporation into heme in cultures of P. falciparum and P. berghei indicate that 80% of the radioactivity is recovered in IRS. This correlates well with the higher levels of ALAD and the subsequent enzymes in IRS than in the parasite. In contrast to this situation, the results obtained with [2-14C]glycine incorporation into heme clearly indicate that 80% of the radioactivity is recovered in the parasite fraction. This suggests that this precursor is essentially handled by ALAS in the parasite membrane and that the level of this enzyme is also significantly higher than that of the red cell membrane enzyme. The results also indicate that there is no significant loss of the intermediates from the parasite into the IRS, or perhaps import of the intermediates from IRS into the parasite also does not take place. The parasite has evolved a mechanism to import the required enzymes rather than the biosynthetic intermediates or preformed heme. Heme should be essentially synthesized within the mitochondrion of the parasite, as is the case with mammalian mitochondria, and then distributed to the other parasite compartments. Thus, the parasite has evolved a strategy to segregate and divert the heme derived from red cell hemoglobin into the inert hemozoin pigment while making use of the heme synthesized de novo for metabolic purposes.
These studies have also identified new potential drug targets. These would be ALAS species unique to the parasite and the receptor(s) on the parasite membrane to import ALAD and perhaps the other enzymes of the pathway from the host. It would also be of interest to examine in this context whether the parasite employs additional mechanisms for making ALA.
The help on Scatchard plot provided by Animesh Nandi is acknowledged.