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Cryo-electron tomography reveals four-membrane architecture of the Plasmodium apicoplast

Leandro Lemgruber1, Mikhail Kudryashev2, Chaitali Dekiwadia3, David T Riglar45, Jake Baum45, Henning Stahlberg2, Stuart A Ralph3* and Friedrich Frischknecht1*

Author Affiliations

1 Parasitology, Department of Infectious Diseases, University of Heidelberg Medical School, Im Neuenheimer Feld 324, Heidelberg 69120, Germany

2 Center for Cellular Imaging and Nano Analytics (C-CINA), Biozentrum, University of Basel, Mattenstrasse 26, Basel, CH-4058, Switzerland

3 Department of Biochemistry and Molecular Biology, Bio21 Molecular Science and Biotechnology Institute, The University of Melbourne, Victoria 3010, Australia

4 Division of Infection and Immunity, The Walter and Eliza Hall Institute of Medical Research, Parkville, VIC, 3052, Australia

5 Department of Medical Biology, University of Melbourne, Parkville, VIC, 3052, Australia

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Malaria Journal 2013, 12:25  doi:10.1186/1475-2875-12-25


The electronic version of this article is the complete one and can be found online at: http://www.malariajournal.com/content/12/1/25


Received:22 November 2012
Accepted:15 January 2013
Published:19 January 2013

© 2013 Lemgruber et al.; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

The apicoplast is a plastid organelle derived from a secondary endosymbiosis, containing biosynthetic pathways essential for the survival of apicomplexan parasites. The Toxoplasma apicoplast clearly possesses four membranes but in related Plasmodium spp. the apicoplast has variably been reported to have either three or four membranes.

Methods

Cryo-electron tomography was employed to image merozoites of Plasmodium falciparum and Plasmodium berghei frozen in their near-native state. Three-dimensional reconstructions revealed the number of apicoplast membranes and the association of the apicoplast with other organelles. Routine transmission electron microscopy of parasites preserved by high-pressure freezing followed by freeze substitution techniques was also used to analyse apicoplast morphology.

Results

Cryo-preserved parasites showed clearly four membranes surrounding the apicoplast. A wider gap between the second and third apicoplast membranes was frequently observed. The apicoplast was found in close proximity to the nucleus and to the rhoptries. The apicoplast matrix showed ribosome-sized particles and membranous whorls.

Conclusions

The Plasmodium apicoplast possesses four membranes, as do the apicoplasts of other apicomplexan parasites. This is consistent with a four-membraned secondary endosymbiotic plastid ancestor.

Keywords:
Apicoplast; Cryo-electron tomography; Symbiosis; Organelle interaction; Malaria

Background

All modern plastids are remnants of a primary endosymbiosis that occurred around one billion years ago, whereby a cyanobacterium was engulfed and retained by a eukaryote. The algae produced by this event possess plastids with two membranes corresponding to the double membranes of the gram-negative cyanobacteria. These algae later diverged into groups known today as Viridiplantae, Glaucophyta and Rhodophyta, and their plastids are known as primary endosymbionts. All existing plastids are either found in these algae, or in later eukaryotes that phagocytosed plastid-bearing organisms and retained their enclosed plastid [1]. Plastids acquired through capture of an organism that contained a primary endosymbiont are referred to as secondary endosymbionts. These organelles would initially have possessed four membranes, deriving from the two primary endosymbiont membranes, plus the plasma membrane of the primary endosymbiont and the phagosomal membrane of the engulfing eukaryote. In some lineages, one of those outer membranes has been secondarily lost to give rise to three-membrane plastids [2]. Algae with secondary endosymbionts can themselves be captured and retained (tertiary endosymbiosis) giving rise to plastids with more than four membranes [3].

Although all extant plastids are believed to derive from a single primary endosymbiosis event, secondary endosymbiosis has occurred a number of times, giving rise to multiple, unrelated plastid-bearing groups. One such hypothesized group is the chromalveolata, proposed to have arisen from a single secondary endosymbiosis involving a rhodophyte (red alga), that gave rise to extremely diverse organisms such as diatoms, dinoflagellates and apicomplexans [4].

The plastid of apicomplexan parasites - the apicoplast - has received considerable attention, in part because of the evolutionary implications of the presence of a plastid in this phylum [5,6], but mainly because apicomplexans are of immense medical and veterinary significance and the apicoplast is the target for important antiparasitic drugs [7]. If the chromalveolate hypothesis holds, the common ancestor of all apicomplexans possessed a four-membrane plastid, although at least one apicomplexan genus, Cryptosporidium, has subsequently lost its plastid. Apicoplasts lack a photosynthetic apparatus, but a recently identified close relative of the Apicomplexa, the alga Chromera[8], is photosynthetic and possesses a four-membrane plastid that appears to derive from the same red algal origin as the apicoplast [9].

Descriptions of apicoplast membranes are many and varied. Because the apicoplast identity was established long after apicomplexans had been ultrastructurally investigated there are many descriptions of the apicoplast with differing generic names, eg, spherical body, hohlzylinder and Golgi adjunct. Micrographs since the description of the apicoplast establish plastids with four membranes for many of the apicomplexans, including Toxoplasma gondii[10], Sarcocystis[11], Garnia gonadati[12], and Babesia bovis[13] as do many of the older micrographs for diverse apicomplexans (discussed in [14]). However, descriptions of the apicoplast of Plasmodium species, the causative agents of malaria, are conflicting. Some preparations appear to support a four-membrane interpretation in sporozoites [15]; however this was based on a single observation and thus was not further commented upon. In contrast other electron micrographs suggest an apicoplast with only three membranes [16-18]. This has led to an ongoing disagreement in the number of apicoplast membranes of Plasmodium. Loss of one of the four membranes clearly found in other apicomplexans would have considerable molecular consequences for understanding protein trafficking and biogenesis for the Plasmodium apicoplast, so the resolution of this question is desirable.

To investigate this discrepancy, electron microscopy of cryopreserved parasites from Plasmodium falciparum and Plasmodium berghei coupled to tomographic reconstructions was used. Cryo-electron tomography is widely regarded to introduce the fewest artefacts during preparation as the specimen is rapidly frozen (within a few milliseconds) thus preserving molecular details and membrane arrangements [19,20]. This technique has been used successfully to investigate membranous and cytoskeletal structures in sporozoites of P. berghei[15,21-23] and Maurer’s clefts of P. falciparum infected red blood cells [24,25]. Cryo-electron tomography does not include staining with heavy metal salts and thus provides lower contrast, though being sufficient to examine membranes [26]. Reconstructed tomograms of both P. falciparum and P. berghei merozoites clearly show the apicoplast with four delimiting membranes. These membranes often appear paired with a gap between the second and third membranes. In some individual sections through the tomograms, only three membranes are apparent around some apicoplasts, but three-dimensional reconstructions of these resolves the local appositions of two membranes to a total of four delimiting membranes.

Methods

Ethics statement

All animal experiments were performed according to the FELASA and GV-SOLAS standard guidelines. Animal experiments were approved by the German authorities (Regierungspräsidium Karlsruhe).

Obtaining Plasmodium merozoites

Plasmodium falciparum parasites from strains 3D7 and D10 were maintained using standard procedures. Cultures were grown in human erythrocytes in RPMI 1640 supplemented with L-glutamine, HEPES, hypoxanthine, and gentamycin. Some cultures were supplemented with human heat-inactivated serum and albumax, and others were supplemented with albumax alone. Parasites were incubated at 37°C in a gas mixture of 5% CO2, 1% O2, and 94% N2. For merozoites subject to cryopreservation prior to electron tomography, late schizonts were harvested by magnetic cell sorting and resuspended in medium. Merozoites were mechanically isolated by passage in a needle.

For P. falciparum merozoites to be subject to conventional glutaraldehyde and osmium fixation or for high pressure freezing and freeze substitution (see below), purification was performed as described by Boyle and colleagues [27].

To obtain P. berghei merozoites, blood of an infected mouse was collected in T-medium (RPMI, 20% FCS, 0.03% gentamicin) plus heparin, centrifuged (110 × g for 8 min) and resuspended in T-medium and placed on a shaker (50 rpm) overnight at 37°C. Mature schizonts were harvested with a Nycodenz gradient (Axis-Shield PoC, Norway), washed and resuspended in RPMI medium prior to freezing.

Cryo-electron tomography

Tomography was performed essentially as described before [15,21,23,24,28]. Merozoites in RPMI medium mixed with 10 nm colloidal gold particles were transferred onto glow-discharged holey carbon Quantifoil EM grids. Grids were blotted at 90% humidity using a Vitrobot (FEI). After removing the liquid excess, the material was rapidly plunge frozen into liquid ethane and stored in liquid nitrogen. The grids were observed in a Titan Krios (FEI) operating at 300 kV and equipped with a Gatan post column energy filter and post-GIF CCDs operating at liquid nitrogen temperature. Tilt series were acquired with an increment of 2º covering -60º to +60º, with a cumulative dose under 10,000 electrons/nm2 and a defocus of -3 to -15 μm on a 2k Ultrascan 1000 CCD camera (Gatan).

For this study a total of 12 (for P. berghei) and 24 (for P. falciparum) tomograms were reconstructed by weighted back-projection using the Etomo program in the IMOD software package (Boulder Laboratory for 3D electron microscopy) [29]. Reconstructed tomograms were filtered using non-linear anisotropic diffusion [30]. Visualization, volume rendering and segmentation were performed using the 3dmod program of the IMOD package [29].

High-pressure freezing and freeze substitution

Purified P. falciparum merozoites from strain D10 were allowed to invade red blood cells, then 10 min post invasion were high-pressure frozen using a LeicaEM high-pressure freezer. The infected erythrocyte samples were freeze substituted with 1% uranyl acetate at -90°C for 24 hrs using a Leica AFS automatic freeze substitution machine. Samples were further freeze substituted with acetone and then infiltrated with increasing concentrations of Lowicryl HM20 resin in acetone. Resin was polymerized using UV light treatment for 48 hrs at -45°C then a further 48 hrs at room temperature. Sections of approximately 90 nanometers were cut at room temperature, stained with uranyl acetate and lead citrate and examined using a Philips CM120 BioTWIN transmission electron microscope at 120 kV (Advanced Microscopy facility, School of Botany, the University of Melbourne, Australia).

Conventional transmission electron microscopy

Purified P. falciparum merozoites (as described above) were fixed in 2.5% glutaraldehyde in pH 7.4 phosphate buffer on ice. Cells were washed in phosphate buffer and fixed in 1% osmium tetroxide (ProSciTech, Australia) in 0.1 M phosphate buffer for one hour on ice. Samples were washed in water, then dehydrated in increasing concentrations of ethanol before embedding in LR Gold resin (ProSciTech, Australia) and polymerized using benzoyl peroxide (SPI-Chem, USA). Sections were cut, stained and inspected as described above.

Results and discussion

In images of merozoites processed in conventional transmission electron microscopy protocols, some organelles are clearly observed such as rhoptries, while even the nucleus can appear in a distorted fashion (Figures 1A-C). This is due to the use of fixative compounds, dehydration and embedding in resin. Better preservation of structural organization can be achieved when specimens are frozen at high pressure and all the steps for transmission electron microscopy are carried out at low temperatures [31]. But even then, where the post-fixation processing is carried out in low temperatures, high-pressure freezing still requires the use of fixative, dehydration and resin, which in turn can also lead to modifications in the structural organization of the merozoites. In addition, the material is stained and uncontrolled, selective depositions of heavy metal salts further obscure fine details just as in classic transmission electron microscopy. Thus, these techniques can lead to misinterpretation. These considerations are not a concern in cryo-electron microscopy, where the parasites are rapidly frozen close to their native state and not subjected to any other procedure that may affect fine structure [20]. However, images of merozoites processed for cryo-electron microscopy, appear more noisy (Figures 1D-F) and it can be more difficult to readily identify the organelles.

thumbnailFigure 1. Structural organization of merozoites processed by different electron microscopy techniques. A to C – different examples of merozoites processed by conventional transmission electron microscopy. Rhoptries (r), micronemes (m) and the nucleus (n) are clearly observed. D to F – different sections from a tomogram of a cryo-preserved merozoite. Although more difficult to identify, some structures stand out like the rhoptries (r), the polar rings (arrowhead) and the apicoplast (arrow).

Merozoites processed in conventional transmission electron microscopy protocols, ie, room temperature processing, appear to show apicoplasts with three [16,17] or four apparent membranes (Figure 2A). High-pressure frozen merozoites presented four membranes delimiting the apicoplast (Figure 2B). Both in routine (Figure 2A) and in high-pressure (Figure 2B) processing, the apicoplast presented a granular matrix with the first and the second membranes as well as the third and the fourth close to each other. Also, a gap between the second and the third membranes was observed. This general organization is similar to that described previously for the Toxoplasma gondii apicoplast [32].

thumbnailFigure 2. Apicoplast ultrastructure in Plasmodium falciparum merozoites. A – Apicoplast of a Plasmodium falciparum merozoite processed by glutaraldehyde and osmium chemical fixation and examined by transmission electron microscopy. The plastid is clearly surrounded by four membranes (arrowheads), with a gap between the two outermost membranes and the two innermost membranes (asterisk) in some regions. B – When processed by high-pressure freezing and freeze substitution, the apicoplast (arrow) ultrastructure was better preserved, also presenting four membranes. The gap between the membranes 2 and 3 is still present. Scale bars: A = 50 nm; B = 200 nm.

Reconstructed tomograms of cryo-fixed P. berghei merozoites again showed four membranes delimiting the apicoplast (Figures 3 and 4). This is quantitatively observed on the density profiles across an apicoplast, revealing a clear peak for each of the four membranes (Figure 3A) and in a 3D model of the organelle (Figure 3B and Additional file 1: Video 1). It is noteworthy that membranous profiles were also observed within the apicoplast matrix (Figures 3A and 3B). The biological nature and purpose of these matrix membranes is unclear, but similar structures have previously been described inside the apicoplast of Plasmodium[16] and Toxoplasma[32]. Cryo-electron tomography revealed gaps not only between the second and the third membranes (Figures 3C and 4A) but also, though less frequently, between the third and the fourth membranes (Figure 3D) and the first and the second membranes (Figure 4B).

thumbnailFigure 3. Tomographic reconstruction of the apicoplast in a Plasmodium berghei merozoite. Panel A shows a virtual section of an apicoplast, with the four apicoplast membranes indicated by the coloured arrowheads and a graphed density distribution. The apicoplast matrix presents an internal membranous whorl as indicated (white arrowhead). Panel B shows a rendered model of the apicoplast, highlighting the internal whorls (purple) and the four membranes (yellow, red, blue and green). Panels C and D show sections where a gap is observed between membranes 2 and 3 (white arrows). In Panel E, a close apposition is observed between the nucleus and the apicoplast (black arrowhead). Scale bars: A = 60 nm; B-E = 20 nm.

thumbnailAdditional file 1. Video 1. View of the 3D model from a reconstructed tomogram of a Plasmodium berghei apicoplast. This video is related to Figure 3.

Format: AVI Size: 4MB Download file | Watch movieOpen Data

thumbnailFigure 4. Gaps between apicoplast membranes. A to C – Different sections of a reconstructed tomogram of a Plasmodium berghei merozoite. The apicoplast with its four membranes is located close to the nucleus. The plastid presents a widening between the two inner membranes and the two outer membranes (white arrowhead). A gap between the two outermost membranes is also occasionally observed (black arrow). In C, electron dense structures (white arrow) are present on some apicoplast membranes, possibly corresponding to protein complexes such as import apparatus. Scale bar = 50 nm.

The apicoplast of P. falciparum merozoites (Figure 5) showed the same general morphology as those of P. berghei. The apicoplast was not only located close to the nucleus but its outer most membrane was also observed in close apposition to the rhoptries and the mitochondrion (Figures 5B-G). Gaps between the membranes were also observed (Figures 5D and E). Ribosome-like particles were clearly observed in the apicoplast’s matrix (Figures 5C and 5E-G). Also, large protein complexes were present within the gap between the membranes (Figure 5B). However the high noise in tomograms due to the thickness of the reconstructed volumes (600–800 nm) hampered further interpretation of these complexes. Similar gaps and material between membranes was also observed in Eimeria[33].

thumbnailFigure 5. Slices through a reconstructed tomogram of a Plasmodium falciparum merozoite. The apicoplast appears close to the nucleus and the rhoptries. White arrowhead points to an interaction between the apicoplast membrane and the rhoptry membrane. Within the apicoplast matrix, several ribosome-like particles were observed (black arrowheads). Black arrows indicate the different regions with a widening between the two outermost membranes and the two innermost membranes. White arrows indicate electron dense structures (possibly translocons) in the apicoplast membranes. In H, the density distribution over the lines show that the apicoplast has four membranes (top profile), but in some slices through the tomogram only three electron dense lines are apparent (bottom profile), due to the close apposition of two membranes. Scale bars: A-G = 25 nm.

The relationship between the apicoplast and the endoplasmic reticulum (ER) has been the subject of some conjecture [16,31,34]. In heterokonts the plastid resides within the lumen of the ER [35], and a similar arrangement is formally possible for the apicoplast (see reviews in [14,34,36] for more detailed discussions of such models). Such an arrangement might predict that the outer membrane of the plastid contained ribosomes, necessary for the insertion of apicoplast-targeted proteins. As with previous examinations, such ribosomes on the outer membrane of the plastid, and continuities between the membranes of the plastid and ER were not observed. However, in merozoites, where all organelles are more closely apposed, the apicoplast was observed in close proximity to the nucleus and ER (Figures 3E and 4A), as previously described for Plasmodium[16], Toxoplasma[32] and Sarcocystis[11]. Although there appeared to be some contact points with the nuclear envelope and with the ER (Figure 3E), no continuity between these membranes is apparent.

Much has been discussed about how proteins are transported across the apicoplast’s surrounding membranes, with various membranous translocon proteins already described [37-41]. In the acquired cryo-tomograms, structures were observed in merozoites’ apicoplast of both P. berghei and P. falciparum, potentially resembling a translocon (Figures 4C and 5C), although this cannot be resolved with the current images. These features were located between the second and the third membranes.

Going through the virtual sections of a reconstructed tomogram, one can observe that depending on the section the apicoplast can show three or four membranes, or even at the same section both arrangements (Figure 5H). This is usually due to the close apposition of the second membrane with the first one, which can explain the discrepancies in the previously published apicoplast structure descriptions [16-18].

Conclusion

The Plasmodium apicoplast was shown to contain four membranes as in other apicomplexan parasites. The apicoplast was found in close proximity to the membranes of the nucleus, inner membrane complex, the mitochondrion and rhoptries. The apicoplast membranes are arranged such that the outer and innermost membranes were closely associated to each other while some space occurred between the two doublet membranes. The presented data reconciles molecular evidence as to how transport into the apicoplast is thought to work in Toxoplasma and Plasmodium with electron microscopy data and shows the capacity of cryo-electron tomography to reveal fine structural details in thin parasites.

Competing interests

The authors declare that they have no competing interests.

Authors’ contribution

LL, MK, SAR, FF designed the experiments and carried out data analysis; LL, MK, CD, DTR performed the experiments; HS, JB contributed essential materials; LL, SAR, FF wrote the paper. All authors read and approved the final manuscript.

Acknowledgements

We thank Marek Cyrklaff for discussions, Claudia Kuss for P. falciparum culture, Jessica Kehrer and Mirko Singer for help with P. berghei infections and Oliver Grünvogel for helping with the computational modelling.

The work was funded by the Chica and Heinz Schaller Foundation and an ERC starting grant to FF, a postdoctoral fellowship of the University of Heidelberg Cluster of Excellence CellNetworks to LL, the Swiss initiative for Systems Biology (SystemsX.ch, grant CINA) to MK and HS, a Pratt Foundation postgraduate scholarship through the University of Melbourne to DTR. FF is a member of the European Network of Excellence EVIMalaR. DTR received a travel fellowship from the Australian Society for Biochemistry and Molecular Biology and a Harold Mitchell Travel Fellowship, and CD an OzeMalR travel award. SAR is supported by an ARC Future fellowship (FT0990350).

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