A HYPOTHESIS FOR IMPORT OF THE NUCLEAR‐ENCODED PsaE PROTEIN OF PAULINELLA CHROMATOPHORA (CERCOZOA,RHIZARIA) INTO ITS CYANOBACTERIAL ENDOSYMBIONTS/PLASTIDS VIA THE ENDOMEMBRANE SYSTEM1

The cyanobacterial endosymbionts of Paulinella chromatophora can shed new light on the process of plastid acquisition. Their genome is devoid of many essential genes, suggesting gene transfer to the host nucleus and protein import back into the endosymbionts/plastids. Strong evidence for such gene transfer is provided by the psaE gene, which encodes a PSI component that was efficiently transferred to the Paulinella nucleus. It remains unclear, however, how this protein is imported into the endosymbionts/plastids. We reanalyzed the sequence of Paulinella psaE and identified four potential non‐AUG translation initiation codons upstream of the previously proposed start codon. Interestingly, the longest polypeptide, starting from the first UUG, contains a clearly identifiable signal peptide with very high (90%) predictability. We also found several downstream hairpin structures that could enhance translation initiation from the alternative codon. These results strongly suggest that the PsaE protein is targeted to the outer membrane of Paulinella endosymbionts/plastids via the endomembrane system. On the basis of presence of respective bacterial homologs in the Paulinella endosymbiont/plastid genome, we discuss further trafficking of PsaE through the peptidoglycan wall and the inner envelope membrane. It is possible that other nuclear‐encoded proteins of P. chromatophora also carry signal peptides, but, alternatively, some may be equipped with transit peptides. If this is true, Paulinella endosymbionts/plastids would possess two distinct targeting systems, one cotranslational and the second posttranslational, as has been found in higher plant plastids. Considering the endomembrane system‐mediated import pathway, we also discuss homology of the membranes surrounding Paulinella endosymbionts/plastids.     

Comparative genomic studies suggest that the cyanobacterial endosymbionts of the amoeba Paulinella chromatophora possess an import apparatus for nuclear‐encoded proteins

Plastids evolved from free‐living cyanobacteria through a process of primary endosymbiosis. The most widely accepted hypothesis derives three ancient lineages of primary plastids, i.e. those of glaucophytes, red algae and green plants, from a single cyanobacterial endosymbiosis. This hypothesis was originally predicated on the assumption that transformations of endosymbionts into organelles must be exceptionally rare because of the difficulty in establishing efficient protein trafficking between a host cell and incipient organelle. It turns out, however, that highly integrated endosymbiotic associations are more common than once thought. Among them is the amoeba Paulinella chromatophora, which harbours independently acquired cyanobacterial endosymbionts functioning as plastids. Sequencing of the Paulinella endosymbiont genome revealed an absence of essential genes for protein trafficking, suggesting their residence in the host nucleus and import of protein products back into the endosymbiont. To investigate this hypothesis, we searched the Paulinella endosymbiont genome for homologues of higher plant translocon proteins that form the import apparatus in two‐membrane envelopes of primary plastids. We found homologues of Toc12, Tic21 and Tic32, but genes for other key translocon proteins (e.g. Omp85/Toc75 and Tic20) were missing. We propose that these missing genes were transferred to the Paulinella nucleus and their products are imported and integrated into the endosymbiont envelope membranes, thereby creating an effective protein import apparatus. We further suggest that other bacterial/cyanobacterial endosymbionts found in protists, plants and animals could have evolved efficient protein import systems independently and, therefore, reached the status of true cellular organelles.     

Protein import into the photosynthetic organelles of Paulinella chromatophora and its implications for primary plastid endosymbiosis

The rhizarian amoeba Paulinella chromatophora harbors two photosynthetically active organelles of cyanobacterial origin that have been acquired independently of classic primary plastids. Because their acquisition did take place relatively recently, they are expected to provide new insight into the ancient cyanobacterial primary endosymbiosis. During the process of Paulinella endosymbiont-to-organelle transformation, more than 30 genes have been transferred from the organelle to the host nuclear genome via endosymbiotic gene transfer (EGT). The article discusses step-by-step protein import of EGT-derived proteins into Paulinella photosynthetic organelles with the emphasis on the nature of their targeting signals and the final passage of proteins through the inner organelle membrane. The latter most probably involves a simplified Tic translocon composed of Tic21- and Tic32-like proteins as well as a Hsp70-based motor responsible for pulling of imported proteins into the organelle matrix. Our results indicate that although protein translocation across the inner membrane of Paulinella photosynthetic organelles seems to resemble the one in classic primary plastids, the transport through the outer membrane does not. The differences could result from distinct integration pathways of Paulinella photosynthetic organelles and primary plastids with their respective host cells.     

Isolation of <Emphasis Type="Italic">Serratia marcescens</Emphasis> involved in chitin degradation in the bulb mite <Emphasis Type="Italic">Rhizoglyphus robini</Emphasis>

Cymbomonas tetramitiformis is a peculiar green alga that unites in one cell the abilities of photosynthesis and phagocytosis, which makes it a very useful model for the study of the evolution of plastid endosymbiosis. We have pondered over this issue and propose an evolutionary scenario of trophic strategies in eukaryotes, including primary and secondary plastid endosymbioses. C. tetramitiformis is a prototroph, just like the common ancestor of Archaeplastida was, and can synthesize most small organic molecules contrary to other eukaryotic phagotrophs, e.g. some metazoans, amoebozoans, and ciliates, which have not evolved tight endosymbiotic relationships. In order to establish a permanent photosynthetic endosymbiont they do not have to become prototrophs, but have to acquire the genes necessary for plastid retention via horizontal (including endosymbiotic) gene transfer. Such processes occurred successfully in the ancestors of eukaryotes with permanent secondary plastids and thus led to their great diversification. The preservation of phagocytosis in Cymbomonas (and some other prasinophytes as well) seems to result from nutrient deficiency in their oligotrophic habitats. This forces them to supplement their diet with phagocytized prey, in contrasts to the thecate amoeba Paulinella chromatophora, which also successfully transformed cyanobacteria into permanent organelles. Although Paulinella endosymbionts were acquired very recently in comparison to primary plastids, Paulinella has lost the ability to phagocytose, most probably due to the fact that it inhabits nutrient-rich environments, which renders the phagotrophy nonessential.     

How do endosymbionts become organelles? Understanding early events in plastid evolution

What factors drove the transformation of the cyanobacterial progenitor of plastids (e.g. chloroplasts) from endosymbiont to bona fide organelle? This question lies at the heart of organelle genesis because, whereas intracellular endosymbionts are widespread in both unicellular and multicellular eukaryotes (e.g. rhizobial bacteria, Chlorella cells in ciliates, Buchnera in aphids), only two canonical eukaryotic organelles of endosymbiotic origin are recognized, the plastids of algae and plants and the mitochondrion. Emerging data on (1) the discovery of non‐canonical plastid protein targeting, (2) the recent origin of a cyanobacterial‐derived organelle in the filose amoeba Paulinella chromatophora, and (3) the extraordinarily reduced genomes of psyllid bacterial endosymbionts begin to blur the distinction between endosymbiont and organelle. Here we discuss the use of these terms in light of new data in order to highlight the unique aspects of plastids and mitochondria and underscore their central role in eukaryotic evolution. BioEssays 29:1239–1246, 2007. © 2007 Wiley Periodicals, Inc.     

Origins of the secondary plastids of Euglenophyta and Chlorarachniophyta as revealed by an analysis of the plastid‐targeting,nuclear‐encoded gene psbO1

Because the secondary plastids of the Euglenophyta and Chlorarachniophyta are very similar to green plant plastids in their pigment composition, it is generally considered that ancestral green algae were engulfed by other eukaryotic host cells to become the plastids of these two algal divisions. Recent molecular phylogenetic studies have attempted to resolve the phylogenetic positions of these plastids; however, almost all of the studies analyzed only plastid‐encoded genes. This limitation may affect the results of comparisons between genes from primary and secondary plastids, because genes in endosymbionts have a higher mutation rate than the genes of their host cells. Thus, the phylogeny of these secondary plastids must be elucidated using other molecular markers. Here, we compared the plastid‐targeting, nuclear‐encoded, oxygen‐evolving enhancer (psbO) genes from various green plants, the Euglenophyta and Chlorarachniophyta. A phylogenetic analysis based on the PsbO amino acid sequences indicated that the chlorarachniophyte plastids are positioned within the Chlorophyta (including Ulvophyceae, Chlorophyceae, and Prasinophyceae, but excluding Mesostigma). In contrast, plastids of the Euglenophyta and Mesostigma are positioned outside the Chlorophyta and Streptophyta. The relationship of these three phylogenetic groups was consistent with the grouping of the primary structures of the thylakoid‐targeting domain and its adjacent amino acids in the PsbO N‐terminal sequences. Furthermore, the serine‐X‐alanine (SXA) motif of PsbO was exactly the same in the Chlorarachniophyta and the prasinophycean Tetraselmis. Therefore, the chlorarachniophyte secondary plastids likely evolved from the ancestral Tetraselmis‐like alga within the Chlorophyta, whereas the Euglenophyte plastids may have originated from the unknown basal lineage of green plants.     

Presequence Acquisition During Secondary Endocytobiosis and thePossible Role of Introns

Targeting of nucleus-encoded proteins into chloroplasts is mediated by N-terminal presequences. During evolution of plastids from formerly free-living cyanobacteria by endocytobiosis, genes for most plastid proteins have been transferred from the plastid genome to the nucleus and subsequently had to be equipped with such plastid targeting sequences. So far it is unclear how the gene domains coding for presequences and the respective mature proteins may have been assembled. While land plant plastids are supposed to originate from a primary endocytobiosis event (a prokaryotic cyanobacterium was taken up by a eukaryotic cell), organisms with secondary plastids like diatoms experienced a second endocytobiosis step involving a eukaryotic alga taken up by a eukaryotic host cell. In this group of algae, apparently most genes encoding chloroplast proteins have been transferred a second time (from the nucleus of the endosymbiont to the nucleus of the secondary host) and thus must have been equipped with additional targeting signals. We have analyzed cDNAs and the respective genomic DNA fragments of seven plastid preproteins from the diatom Phaeodactylum tricornutum. In all of these genes we found single spliceosomal introns, generally located within the region coding for the N-terminal plastid targeting sequences or shortly downstream of it. The positions of the introns can be related to the putative phylogenetic histories of the respective genes, indicating that the bipartite targeting sequences in these secondary algae might have evolved by recombination events via introns.The nucleotide sequences have been deposited at Genbank under accession numbers AY191862, AY191863, AY191864, AY191865, AY191866, AY191867, and AY191868.     

The Origin of Chlorarachniophyte Plastids, as Inferred from Phylogenetic Comparisons of Amino Acid Sequences of EF-Tu

A molecular phylogenetic analysis of elongation factor Tu (EF-Tu) proteins from plastids was performed in an attempt to identify the origin of chlorarachniophyte plastids, which are considered to have evolved from the endosymbiont of a photosynthetic eukaryote. Partial sequences of the genes for plastid EF-Tu proteins (1,080–1,089 bp) were determined for three algae that contain chlorophyll b, namely, Gymnochlora stellata (Chlorarachniophyceae), Bryopsis maxima (Ulvophyceae), and Pyramimonas disomata (Prasinophyceae). The deduced amino acid sequences were used to construct phylogenetic trees of the plastid and bacterial EF-Tu proteins by the maximum likelihood, the maximum parsimony, and the neighbor joining methods. The trees obtained in the present analysis suggest that all plastids that contain chlorophyll b are monophyletic and that the chlorarachniophyte plastids are closely related to those of the Ulvophyceae. The phylogenetic trees also suggest that euglenophyte plastids are closely related to prasinophycean plastids. The results indicate that the chlorarachniophyte plastids evolved from a green algal endosymbiont that was closely related to the Ulvophyceae and that at least two secondary endosymbiotic events have occurred in the lineage of algae with plastids that contain chlorophyll b. Received: 10 March 1997 / Accepted: 28 July 1997     

Early steps in plastid evolution: current ideas and controversies

Some nuclear‐encoded proteins are imported into higher plant plastids via the endomembrane (EM) system. Compared with multi‐protein Toc and Tic translocons required for most plastid protein import, the relatively uncomplicated nature of EM trafficking led to suggestions that it was the original transport mechanism for nuclear‐encoded endosymbiont proteins, and critical for the early stages of plastid evolution. Its apparent simplicity disappears, however, when EM transport is considered in light of selective constraints likely encountered during the conversion of stable endosymbionts into fully integrated organelles. From this perspective it is more parsimonious to presume the early evolution of post‐translational protein import via simpler, ancestral forms of modern Toc and Tic plastid translocons, with EM trafficking arising later to accommodate glycosylation and/or protein targeting to multiple cellular locations. This hypothesis is supported by both empirical and comparative data, and is consistent with the relative paucity of EM‐based transport to modern primary plastids.     

A single origin of the photosynthetic organelle in different Paulinella lineages

Background  

Gaining the ability to photosynthesize was a key event in eukaryotic evolution because algae and plants form the base of the food chain on our planet. The eukaryotic machines of photosynthesis are plastids (e.g., chloroplast in plants) that evolved from cyanobacteria through primary endosymbiosis. Our knowledge of plastid evolution, however, remains limited because the primary endosymbiosis occurred more than a billion years ago. In this context, the thecate "green amoeba" Paulinella chromatophora is remarkable because it very recently (i.e., minimum age of ≈ 60 million years ago) acquired a photosynthetic organelle (termed a "chromatophore"; i.e., plastid) via an independent primary endosymbiosis involving a Prochlorococcus or Synechococcus -like cyanobacterium. All data regarding P. chromatophora stem from a single isolate from Germany (strain M0880/a). Here we brought into culture a novel photosynthetic Paulinella strain (FK01) and generated molecular sequence data from these cells and from four different cell samples, all isolated from freshwater habitats in Japan. Our study had two aims. The first was to compare and contrast cell ultrastructure of the M0880/a and FK01 strains using scanning electron microscopy. The second was to assess the phylogenetic diversity of photosynthetic Paulinella to test the hypothesis they share a vertically inherited plastid that originated in their common ancestor.     

Fates of Evolutionarily Distinct,Plastid‐type Glyceraldehyde 3‐phosphate Dehydrogenase Genes in Kareniacean Dinoflagellates

The ancestral kareniacean dinoflagellate has undergone tertiary endosymbiosis, in which the original plastid is replaced by a haptophyte endosymbiont. During this plastid replacement, the endosymbiont genes were most likely flowed into the host dinoflagellate genome (endosymbiotic gene transfer or EGT). Such EGT may have generated the redundancy of functionally homologous genes in the host genome—one has resided in the host genome prior to the haptophyte endosymbiosis, while the other transferred from the endosymbiont genome. However, it remains to be well understood how evolutionarily distinct but functionally homologous genes were dealt in the dinoflagellate genomes bearing haptophyte‐derived plastids. To model the gene evolution after EGT in plastid replacement, we here compared the characteristics of the two evolutionally distinct genes encoding plastid‐type glyceraldehyde 3‐phosphate dehydrogenase (GAPDH) in Karenia brevis and K. mikimotoi bearing haptophyte‐derived tertiary plastids: “gapC1h” acquired from the haptophyte endosymbiont and “gapC1p” inherited from the ancestral dinoflagellate. Our experiments consistently and clearly demonstrated that, in the two species examined, the principal plastid‐type GAPDH is encoded by gapC1h rather than gapC1p. We here propose an evolutionary scheme resolving the EGT‐derived redundancy of genes involved in plastid function and maintenance in the nuclear genomes of dinoflagellates that have undergone plastid replacements. Although K. brevis and K. mikimotoi are closely related to each other, the statuses of the two evolutionarily distinct gapC1 genes in the two Karenia species correspond to different steps in the proposed scheme.     

The genome of an endosymbiotic methanogen is very similar to those of its free‐living relatives

The methanogenic endosymbionts of anaerobic protists represent the only known intracellular archaea, yet, almost nothing is known about genome structure and content in these lineages. Here, an almost complete genome of an intracellular Methanobacterium species was assembled from a metagenome derived from its host ciliate, a Heterometopus species. Phylogenomic analysis showed that the endosymbiont was closely related to free‐living Methanobacterium isolates, and when compared with the genomes of free‐living Methanobacterium, the endosymbiont did not show significant reduction in genome size or GC content. Additionally, the Methanobacterium endosymbiont genome shared the majority of its genes with its closest relative, though it did also contain unique genes possibly involved in interactions with the host via membrane‐associated proteins, the removal of toxic by‐products from host metabolism and the production of small signalling molecules. Though anaerobic ciliates have been shown to transmit their endosymbionts to daughter cells during division, the results presented here could suggest that the endosymbiotic Methanobacterium did not experience significant genetic isolation or drift and/or that this lineage was only recently acquired. Altogether, comparative genomic analysis identified genes potentially involved in the establishment and maintenance of the symbiosis, as well provided insight into the genomic consequences for an intracellular archaeum.     

Is Protein Import into Plastids with Four‐Membrane Envelopes Dependent on Two Toc Systems Operating in Tandem?

Abstract: Plastids with four‐membrane envelopes have evolved by several independent endosymbioses involving a eukaryotic alga as the endosymbiont and a protozoan predator as the host. It is assumed that their outermost membrane is derived from the phagosomal membrane of the host and that protein targeting to and across this membrane proceeds co‐translationally, including ER and the Golgi apparatus (e.g., chlorarachniophytes) or only ER (e.g., heterokonts). Since the two inner membranes (or the plastid envelope) of such a complex plastid are derived from the endosymbiont plastid, they are probably provided with Toc and Tic systems, enabling post‐translational passage of the imported proteins into the stroma. The third envelope membrane, or the periplastid one, originates from the endosymbiont plasmalemma, but what import apparatus operates in it remains enigmatic. Recently, Cavalier‐Smith (1999^[5]) has proposed that the Toc system, pre‐existing in the endosymbiont plastid, has been relocated to the periplastid membrane, and that plastids having four envelope membranes contain two Toc systems operating in tandem and requiring the same targeting sequence, i.e., the transit peptide. Although this model is parsimonious, it encounters several serious obstacles, the most serious one resulting from the complex biogenesis of Toc75 which forms a translocation pore. In contrast to most proteins targeted to the outer membrane of the plastid envelope, this protein carries a complex transit peptide, indicating that a successful integration of the Toc system into the periplastid membrane would have to be accompanied by relocation of the stromal processing peptidase to the endosymbiont cytosol. However, such a relocation would be catastrophic because this enzyme would cleave the transit peptide off all plastid‐destined proteins, thus disabling biogenesis of the plastid compartment. Considering these difficulties, I suggest that in periplastid membranes two Toc‐independent translocation apparatuses have evolved: a porin‐like channel in chlorarachniophytes and cryptophytes, and a vesicular pathway in heterokonts and haptophytes. Since simultaneous evolution of a new transport system in the periplastid membrane and in the phagosomal one would be complicated, it is argued that plastids with four‐membrane envelopes have evolved by replacement of plastids with three‐membrane envelopes. I suggest that during the first round of secondary endosymbioses (resulting in plastids surrounded by three membranes), myzocytotically‐engulfed eukaryotic alga developed a Golgi‐mediated targeting pathway which was added to the Toc/Tic‐based apparatus of the endosymbiont plastid. During the second round of secondary endosymbioses (resulting in plastids surrounded by four membranes), phagocytotically‐engulfed eukaryotic alga exploited the Golgi pathway of the original plastid, and a new translocation system had to originate only in the periplastid membrane, although its emergence probably resulted in modification of the import machinery pre‐existing in the endosymbiont plastid.     

EVOLUTIONARY ANALYSES OF THE NUCLEAR‐ENCODED PHOTOSYNTHETIC GENE psbO FROM TERTIARY PLASTID‐CONTAINING ALGAE IN DINOPHYTA1

Although the dinophytes generally possess red‐algal‐derived secondary plastids, tertiary plastids originating from haptophyte and diatom ancestors are recognized in some lineages within the Dinophyta. However, little is known about the nuclear‐encoded genes of plastid‐targeted proteins from the dinophytes with diatom‐derived tertiary plastids. We analyzed the sequences of the nuclear psbO gene encoding oxygen‐evolving enhancer protein from various algae with red‐algal‐derived secondary and tertiary plastids. Based on our sequencing of 10 new genes and phylogenetic analysis of PsbO amino acid sequences from a wide taxon sampling of red algae and organisms with red‐algal‐derived plastids, dinophytes form three separate lineages: one composed of peridinin‐containing species with secondary plastids, and the other two having haptophyte‐ or diatom‐derived tertiary plastids and forming a robust monophyletic group with haptophytes and diatoms, respectively. Comparison of the N‐terminal sequences of PsbO proteins suggests that psbO genes from a dinophyte with diatom‐derived tertiary plastids (Kryptoperidinium) encode proteins that are targeted to the diatom plastid from the endosymbiotic diatom nucleus as in the secondary phototrophs, whereas the fucoxanthin‐containing dinophytes (Karenia and Karlodinium) have evolved an additional system of psbO genes for targeting the PsbO proteins to their haptophyte‐derived tertiary plastids from the host dinophyte nuclei.     

Bacterial endosymbiont infections in ‘living fossils’: a case study of North American vaejovid scorpions

Bacterial endosymbionts are common among arthropods, and maternally inherited forms can affect the reproductive and behavioural traits of their arthropod hosts. The prevalence of bacterial endosymbionts and their role in scorpion evolution have rarely been investigated. In this study, 61 samples from 40 species of scorpion in the family Vaejovidae were screened for the presence of the bacterial endosymbionts Cardinium, Rickettsia, Spiroplasma and Wolbachia. No samples were infected by these bacteria. However, one primer pair specifically designed to amplify Rickettsia amplified nontarget genes of other taxa. Similar off‐target amplification using another endosymbiont‐specific primer was also found during preliminary screenings. Results caution against the overreliance on previously published screening primers to detect bacterial endosymbionts in host taxa and suggest that primer specificity may be higher in primers targeting nuclear rather than mitochondrial genes.     

Genome-based reconstruction of the protein import machinery in the secondary plastid of a chlorarachniophyte alga

Most plastid proteins are encoded by their nuclear genomes and need to be targeted across multiple envelope membranes. In vascular plants, the translocons at the outer and inner envelope membranes of chloroplasts (TOC and TIC, respectively) facilitate transport across the two plastid membranes. In contrast, several algal groups harbor more complex plastids, the so-called secondary plastids, which are surrounded by three or four membranes, but the plastid protein import machinery (in particular, how proteins cross the membrane corresponding to the secondary endosymbiont plasma membrane) remains unexplored in many of these algae. To reconstruct the putative protein import machinery of a secondary plastid, we used the chlorarachniophyte alga Bigelowiella natans, whose plastid is bounded by four membranes and still possesses a relict nucleus of a green algal endosymbiont (the nucleomorph) in the intermembrane space. We identified nine homologs of plant-like TOC/TIC components in the recently sequenced B. natans nuclear genome, adding to the two that remain in the nucleomorph genome (B. natans TOC75 [BnTOC75] and BnTIC20). All of these proteins were predicted to be localized to the plastid and might function in the inner two membranes. We also show that the homologs of a protein, Der1, that is known to mediate transport across the second membrane in the several lineages with secondary plastids of red algal origin is not associated with plastid protein targeting in B. natans. How plastid proteins cross this membrane remains a mystery, but it is clear that the protein transport machinery of chlorarachniophyte plastids differs from that of red algal secondary plastids.     

Endosymbiosis and evolution of the plant cell

The bacterial origins of plastid division and protein import by plastids are beginning to emerge - thanks largely to the availability of a total genome sequence for a cyanobacterium. Despite existing for hundreds of millions of years within the plant cell host, the chloroplast endosymbiont retains clear hallmarks of its bacterial ancestry. Plastid division relies on proteins that are also responsible for bacterial division, although may of the genes for these proteins have been confiscated by the host. Plastid protein import on the other hand relies on proteins that seem to have functioned originally as exporters but that have now been persuaded to operate in the reverse direction to traffic proteins from the host cell into the endosymbiont.     

The ancestor of the <Emphasis Type="Italic">Paulinella</Emphasis> chromatophore obtained a carboxysomal operon by horizontal gene transfer from a <Emphasis Type="Italic">Nitrococcus</Emphasis>-like γ-proteobacterium

Background  

Paulinella chromatophora is a freshwater filose amoeba with photosynthetic endosymbionts (chromatophores) of cyanobacterial origin that are closely related to free-living Prochlorococcus and Synechococcus species (PS-clade). Members of the PS-clade of cyanobacteria contain a proteobacterial form 1A RubisCO (ribulose-1,5-bisphosphate carboxylase/oxygenase) that was acquired by horizontal gene transfer (HGT) of a carboxysomal operon. In rDNA-phylogenies, the Paulinella chromatophore diverged basal to the PS-clade, raising the question whether the HGT occurred before or after the split of the chromatophore ancestor.     

Sequence Analysis of DNA Fragments from the Genome of the Primary Endosymbiont of the Whitefly <Emphasis Type="Italic">Bemisia tabaci</Emphasis>

The whitefly Bemisia tabaci contains a primary prokaryotic endosymbiont housed within specialized cells in the body cavity. Two DNA fragments from the endosymbiont, totaling 33.3 kilobases, were cloned and sequenced. In total, 37 genes were detected and included the ribosomal RNA operon and genes for ribosomal RNA proteins. The guanine plus cytosine of the DNA was 30.2 mol%, different from that of endosymbionts of other plant sap-sucking insects.