- Open Access
Mergers and acquisitions: malaria and the great chloroplast heist
© GenomeBiology.com 2000
Published: 13 October 2000
The origin of the relict chloroplast recently identified in malarial parasites has been mysterious. Several new papers suggest that the parasites obtained their chloroplasts in an ancient endosymbiotic event that also created some major algal groups.
The identification of a relict chloroplast (plastid) in human parasites caused quite a sensation [1,2,3]. How could organisms that live as obligate intracellular parasites in animals share a feature so definitive of algae and plants? The malaria parasite (Plasmodium spp), which invades red blood cells and eats the hemoglobin protein, can scarcely be any less plant-like. But for protistologists the revelation was not quite so strange. Molecular phylogenetics had clearly demonstrated that the malaria parasite, along with many other parasites such as Toxoplasma that together make up the phylum Apicomplexa, are the closest relatives of an algal group known as dinoflagellates . And protistologists are becoming accustomed to strange bedfellows in their evolutionary trees. After all, Euglena's closest cousins are the trypanosomes and leishmanias, and the golden flagellate algae (including the brown kelps and diatoms) are in the same group as Phytophthora, the fungal-like protist that caused the devastating Irish potato blight . Close relationships between parasites and photosynthetic organisms seem unusual to us only because our early evolutionary schemes were based mainly on lifestyle, but technological advances such as electron microscopy, molecular biology and genomics are providing more accurate pictures of natural relationships.
So if malaria and dinoflagellates are close relatives, and both have plastids, what is all the excitement about their plastids? Well, in protist evolution the acquisition of plastids has been a complex tapestry of mergers and takeovers . Indeed, the plastid story rivals the current shenanigans in the biotechnology sector. Just as covetousness for competitors' intellectual property is driving a virtual feeding frenzy of acquisitions and takeovers, a similar feeding frenzy has been playing itself out over hundreds of millions of years in the protist world . But in this little drama, photosynthesis is the key piece of 'intellectual property'. And what better technology to have in-house than the ability to turn sunshine into food? The internecine struggle to control this resource is a bizarre tale of piracy, slavery, double crossing and microscopic treachery.
The origin of plant chloroplasts by endosymbiosis is now the stuff of textbooks. Microscopists recognized the gross similarities between chloroplasts and cyanobacteria and formulated the theory of endosymbiosis , which posits that chloroplasts were derived from cyanobacterium-like cells now living inside a eukaryotic host. Biochemistry and molecular biology have since proven beyond doubt that chloroplasts do indeed derive from endosymbiotic cyanobacteria . But the story does not close there. The cyanobacterial endosymbiosis is the first chapter in a set of endosymbiotic events responsible for the acquisition of plastids in a range of eukaryotic lineages. This first chapter (cyanobacterium + eukaryotic host = photosynthetic eukaryote) is referred to as the primary endosymbiosis. A subsequent chapter in plastid acquisition is referred to as secondary endosymbiosis , and can be described by the equation 'photosynthetic eukaryote + eukaryotic host = different photosynthetic eukaryote'. In this chapter the product of the first equation (photosynthetic eukaryote) is the first component of the second equation. Although primary endosymbiosis happened (to the best of our knowledge) only once, secondary endosymbiosis occurred at least twice and, some would argue, perhaps numerous times  (see Figure 1). Takeover of someone else's photosynthetic unit seems easier than developing one from a bacterial symbiont, and this is where we return to malaria and dinoflagellates.
Although dinoflagellates and Apicomplexa are close relatives , their plastids are of secondary origin , which leaves open the possibility that they have separate secondary acquisitions. How to address this? The standard approach has been to compare genes from the plastid genome of the secondary plastid with the candidates from the pool of primary plastid-containing organisms. For malaria parasites this was no problem since the entire plastid genome was already sequenced by Iain Wilson and colleagues , but, until recently, no plastid genes had been characterized from dinoflagellate plastids. Zhang et al.  now fill that gap by providing the sequence of rRNA genes from the plastids of several dinoflagellates. Dinoflagellate plastid DNA is unique in that each gene is carried on a single minicircle rather than the canonical circular chromosome with multiple genes in transcriptional arrays found in all other plastids [9,10,11]. Trees incorporating rRNA genes show dinoflagellate plastids to be most closely related to plastids of apicomplexan plastids (referred to as sporozoan plastids in ). At face value this relationship suggests that the plastids were acquired by a common secondary endosymbiotic event , but there could be a metaphorical serpent coiled in the branches of the evolutionary trees - a major bugbear of tree inference is rapidly evolving genes. Accumulating mutations at elevated rates, such sequences form long branches in trees. Tree-constructing algorithms tend to group long branches together - even branches that are not related . The branches of dinoflagellate and apicomplexan plastids are extraordinarily long and their grouping must be regarded with abject caution. Moreover, nucleotide bias (a preference for one type of base pair in the genome) can wreak further havoc on tree construction  and dinoflagellate and apicomplexan genes are strongly biased to A/T pairs. This means that the sequence similarity could be convergent and might not reflect common ancestry.
A previous study of apicomplexan plastid genes concluded that the apicomplexan plastid derived from a secondary endosymbiotic green alga . This made a common origin with plastids of dinoflagellates impossible, since dinoflagellates almost certainly contain a red algal endosymbiont [10,14]. Another factor is the inconsistency in membrane number; standard dinoflagellate plastids have three , whereas Apicomplexa are believed to have four bounding membranes [3,15], although the number of apicomplexan plastid membranes has been under debate , making it difficult to assess the relevance of this character. Another obstacle to common origin was the belief that two putatively early diverging Apicomplexa (Perkinsus and Colpodella) might lack a plastid , suggesting that a plastid was acquired by Apicomplexa after they diverged from dinoflagellates .
Several new lines of evidence now lend support to Zhang et al.  for a common origin from a red algal endosymbiont, however. In contrast to the gene trees suggesting a green endosymbiont for Apicomplexa, apicomplexan plastid gene operon structure is much more congruent with a red algal endosymbiont [18,19,20]. In addition, new molecular evidence suggests that Perkinsus does have a plastid (X. Zhao and D.W. Duszinski, personal communication), removing one of the obstacles to a common origin. Thus, Zhang et al.  are out on a limb, but not entirely alone. The last, and potentially most telling, pieces of evidence for a common origin come not from the 'difficult-to-tree' plastid genes but from the nuclei of the hosts. Cells hosting secondary endosymbionts contain genes encoding plastid proteins in their nuclei . The products of these genes are synthesized in the host cytoplasm and targeted into the plastid across the multiple membranes . Typically these genes derive ultimately from the cyanobacterial endosymbiont and carry such a phylogenetic signal. Naomi Fast and colleagues (personal communication) are examining one such gene for glyceraldehyde-3-phosphate dehydrogenase (GAPDH) in Apicomplexa, dinoflagellates and other algae. As expected, the GAPDH genes of plants, green algae and red algae (all descendants of the primary endosymbiosis) have a cyanobacterial ancestry; they transferred to the eukaryotic host nucleus as part of the establishment of the primary endosymbiosis (N.M. Fast, J. Kissinger, D. Roos, P. Keeling, personal communication). In secondary endosymbiosis, the nuclear genes of the engulfed endosymbiont typically undergo yet another transfer into the new host nucleus [21,22]. Fast and colleagues, therefore, anticipated that the GAPDH genes in nuclei of secondary hosts should also show the cyanobacterial signature. Not so. In the Apicomplexa and dinoflagellates, as well as the heterokont and cryptomonad algae, the GAPDH targeted to the plastid is not cyanobacterial in origin but simply a duplicate of the secondary host nuclear gene for cytosolic GAPDH (N.M. Fast et al., personal communication). Apparently evolution has taken a short cut. Rather than transferring the secondary endosymbiont's gene to the nucleus, these algae have copied their nuclear gene and appended a targeting leader to the amino terminus. Importantly, the structure of the GAPDH trees implies that this peculiar recruitment process happened just once (N.M. Fast et al., personal communication). That means dinoflagellates, Apicomplexa, heterokonts, and perhaps even cryptomonads, could all have acquired their plastids in one common secondary endosymbiosis of a red alga (Figure 1), supporting the trees of Zhang et al. . Moreover, recent phylogenetic analyses indicate that these organisms all belong in a previously unrecognised meta-assemblage dubbed the 'Chromalveolates' (Figure 1) [23 ] (S.L. Baldauf, A.J. Roger, I. Wenk-Siefert, W.F. Doolittle, personal communication).
- McFadden GI, Reith M, Munholland J, Lang-Unnasch N: Plastid in human parasites. Nature. 1996, 381: 482-10.1038/381482a0.PubMedView ArticleGoogle Scholar
- Wilson RJM, Denny PW, Preiser PR, Rangachari K, Roberts K, Roy A, Whyte A, Strath M, Moore DJ, Moore PW, Williamson DH: Complete gene map of the plastid-like DNA of the malaria parasite Plasmodium falciparum. J Mol Biol. 1996, 261: 155-172. 10.1006/jmbi.1996.0449.PubMedView ArticleGoogle Scholar
- Köhler S, Delwiche CF, Denny PW, Tilney LG, Webster P, Wilson RJM, Palmer JD, Roos DS: A plastid of probable green algal origin in apicomplexan parasites. Science. 1997, 275: 1485-1488. 10.1126/science.275.5305.1485.PubMedView ArticleGoogle Scholar
- Wolters J: The troublesome parasites: molecular and morphological evidence that Apicomplexa belong to the dinoflagellate-ciliate clade. Biosystems. 1991, 25: 75-84. 10.1016/0303-2647(91)90014-C.PubMedView ArticleGoogle Scholar
- Delwiche CF: Tracing the thread of plastid diversity through the tapestry of life. Amer Naturalist. 1999, 154: S164-S177. 10.1086/303291.View ArticleGoogle Scholar
- Mereschkowsky C: Theorie der zwei Plasmaarten als Grundlage der Symbiogenesis, einer neuen Lehre von der Entstehung der Organismen [Theoretical interpretation of the two types of plasma as a basis for symbiogenesis, a new theory about the origin of organisms]. Biol Zentralbl. 1910, 30: 278-367.Google Scholar
- McFadden GI: Endosymbiosis and evolution of the plant cell. Curr Opin Plant Biol. 1999, 2: 513-519. 10.1016/S1369-5266(99)00025-4.PubMedView ArticleGoogle Scholar
- Zhang Z, Green B, Cavalier-Smith T: Phylogeny of ultra-rapidly evolving dinoflagellate chloroplast genes: a possible common origin for sporozoan and dinoflagellate plastids. J Mol Evol. 2000, 51: 26-40.PubMedGoogle Scholar
- McFadden G: Chloroplasts: ever decreasing circles. Nature. 1999, 400: 119-120. 10.1038/22011.PubMedView ArticleGoogle Scholar
- Zhang Z, Green B, Cavalier-Smith T: Single gene circles in dinoflagellate chloroplast genomes. Nature. 1999, 400: 155-159. 10.1038/22099.PubMedView ArticleGoogle Scholar
- Barbrook AC, Howe CJ: Minicircular plastid DNA in the dinoflagellate Amphidinium operculatum. Mol Gen Genet. 2000, 263: 152-158. 10.1007/s004380050042.PubMedView ArticleGoogle Scholar
- Felsenstein J: Cases in which parsimony or compatibility methods will be positively misleading. Syst Zool. 1978, 27: 401-410.View ArticleGoogle Scholar
- Lockhart PJ, Steel MA, Hendy MD, Penny D: Recovering evolutionary trees under a more realistic model of sequence evolution. Mol Biol Evol. 1994, 11: 605-612.PubMedGoogle Scholar
- Durnford DG, Deane JA, Tan S, McFadden GI, Gantt E, Green BR: A phylogenetic assessment of plastids and eukaryotic light-harvesting antenna proteins. J Mol Evol. 1999, 48: 59-68.PubMedView ArticleGoogle Scholar
- McFadden GI, Roos DS: Apicomplexan plastids as drug targets. Trends Microbiol. 1999, 7: 328-333. 10.1016/S0966-842X(99)01547-4.PubMedView ArticleGoogle Scholar
- Hopkins J, Fowler R, Krishna S, Wilson I, Mitchell G, Bannister L: The plastid in Plasmodium falciparum asexual blood stages: a three-dimensional ultrastructural analysis. Protist. 1999, 150: 283-295.PubMedView ArticleGoogle Scholar
- McFadden GI, Hofmann CJB, Gilson PR: . Origins of the Algae. Edited by Bhattacharya D. Vienna: Springer;. 2000.Google Scholar
- McFadden GI, Waller RF, Reith M, Munholland J, Lang-Unnasch N: Plastids in apicomplexan parasites. Plant Syst Evol. 1997, [Suppl.] 11: 261-287.View ArticleGoogle Scholar
- McFadden GI, Waller RF: Plastids in parasites of humans. BioEssays. 1997, 19: 1033-1040.PubMedView ArticleGoogle Scholar
- Blanchard J, Hicks JS: The non-photosynthetic plastid in malarial parasites and other apicomplexans is derived from outside the green plastid lineage. J Euk Microbiol. 1999, 46: 367-375.PubMedView ArticleGoogle Scholar
- Deane J, Fraunholz M, Su V, Maier U-G, Martin W, Durnford D, McFadden G: Evidence for nucleomorph to host nucleus gene transfer: light harvesting complex proteins from cryptomonads and chlorarachniophytes. Protist. 2000, 151: 239-252.PubMedView ArticleGoogle Scholar
- McFadden GI: Plastids and protein targeting. J Euk Microbiol. 1999, 46: 339-346.PubMedView ArticleGoogle Scholar
- Cavalier-Smith T: Membrane heredity and early chloroplast evolution. Trends Plant Sci. 2000, 5: 174-182. 10.1016/S1360-1385(00)01598-3.PubMedView ArticleGoogle Scholar