Photomovement in Cyanophora paradoxa

Photomovement has been studied in the symbiontic association of the colorless flagellate, Cyanophora paradoxa Korschikoff with the cyanelles, Cyanocyta korschikoffiana. There is no phototactic orientation in this organism, but a photokinetic effect. In addition, the cells show a pronounced step-up photophobic response (however no or only a weak step-down response). The phobic response is mediated by a subset of the photosynthetic pigments located in the symbiontic cyanelles. It is linked to the noncyclic photosynthetic electron transport chain but it is independent of the photosynthetic generation of a proton gradient and the ATP synthesis linked to it.Abbreviations CCCP carbonyl cyanide m-chlorophenyl hydrazone - DBMIB 2,5-dibromo-3-methyl-6-isopropylbenzo quinone - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea     

Identification of two different glyceraldehyde-3-phosphate dehydrogenases (phosphorylating) in the photosynthetic protist Cyanophora paradoxa

Two different glyceraldehyde-3-phosphate (G3P) dehydrogenase (phosphorylating) activities, namely NAD- and NADP-dependent, have been found in cell extracts of the cyanelle-bearing photosynthetic protist Cyanophora paradoxa. Whereas the two G3P dehydrogenase activities were detected with similar specific activity levels (0.1 to 0.2 U/mg of protein) in extracts of the photosynthetic organelles (cyanelles), only the NAD-dependent activity was found in the cytosol. Thus, a differential intracellular localization occurred. The perfect overlapping of the two G3P dehydrogenase activity peaks of the cyanelle in both hydrophobic interaction chromatography and subsequent FPLC (fast protein liquid chromatography) gel filtration indicated that the two activities were due in fact to a single NAD(P)-dependent G3P dehydrogenase (EC 1.2.1.-) with a molecular mass of 148,000. SDS-PAGE of active fractions from FPLC gel filtration showed that the intensity of the major protein band (molecular mass, 38,000) of the enzyme preparation clearly paralleled the activity elution profile, thus suggesting a tetrameric structure for the cyanelle dehydrogenase. On the other hand, FPLC gel filtration analysis of the cytoplasmic fraction revealed a NAD-dependent G3P dehydrogenase with a native molecular mass of 142,000, being equivalent to the classical glycolytic enzyme (EC 1.2.1.12) present in the cytosol of all the organisms so far studied. The significance of these results is discussed taking into account that the cyanobacteria, photosynthetic prokaryotes which share many structural and biochemical features with cyanelles and are considered as their ancestors, have a similar NAD(P)-dependent G3P dehydrogenase.Abbreviation FPLC Fast protein liquid chromatography     

The Cyanelles (Organelles of a Low Evolutionary Scale) Possess a Phosphate-Translocator and a Glucose-Carrier in Cyanophora paradoxa

Cyanelles from Cyanophora paradoxa can easily be isolated and assayed for their carrier composition by the silicone oil filtering technique. The present investigation demonstrates a P_i-translocator transferring phosphate, dihydroxyacetone phosphate and 3-phosphoglycerate in a counter exchange mode in cyanelles as in chloroplasts of higher plants. The uptake of P_i is inhibited by dihydroxyacetone phosphate, phosphoglycerate and glucose-6-P, only poorly by phosphoenolpyruvate and not by 2-phosphoglycerate. The inhibitors pyridoxalphosphate and 4,4′diisothiocyanostilbene-2,2K'disulfonic acid at low concentration also affect P_i-uptake. Cyanelles probably transport photosynthate (reductant and ATP) by triosephosphates. This is the first demonstration of a phosphate translocator in an organism of a low evolutionary scale. Cyanelles also transport glucose which proceeds in two phases. In the lower concentration range (≤ 2.5 mM), glucose penetrates by facilitated diffusion, whereas transport follows first-order kinetics at higher amounts (> 2.5 mM). In the low concentration range, glucose-transport is affected by high concentrations of 3-O-methylglucose and fructose. The physiological role of the glucose-transport carrier in Cyanophora is doubtful. It may function in transporting glucose into cyanelles if the carbon level inside them becomes limiting, e.g. in dark periods.     

CYANOPHYTE AND CYANELLE DNA: A SEARCH FOR THE ORIGINS OF PLASTIDS1

Cyanophyte-like prokaryotes are widely presumed to be the progenitors of eukaryote plastids. A few rare protistan species bearing cyanophyte-like cyanelles may represent intermediate stages in the evolution of true organelles. Cyanophyte DNA disposition in the cell, so far as is known from electron microscopy, seems uniform within the group and distinctly different from the several known arrangements of DNA in plastids. Therefore a survey of representative cyanophytes and protistan cyanelles was undertaken to determine whether forms reminiscent of plastids could be found. DNA-specific fluorochromes were utilized, along with epifluorescent microscopy, to study the DNA arrangement in situ in whole cells. Only the endospore (baeocyte)-forming Cyanophyta contained more than one, centrally located DNA skein per cell, and then only for the period just preceding visible baeocyte formation. Such forms might, with modification, presage the “scattered nucleoid” DNA disposition found in plastids of several groups, including Rhodophytes, Cryptophytes, Chlorophytes and higher plants. The DNA arrangement in cyanelles of two protists, Cyanophora and Glaucocystis, appear different from each other and possibly related to, respectively, the cyanophytes Gloeobacter and Synechococcus. Cyanelles of the third protist, Glaucosphaera, like the cells of the unique prokaryote Prochloron, appear to have multiple sites of DNA, somewhat similar to those of the “scattered nucleoid” line of plastid evolution. No obvious precursor of the “ring nucleoid” or other types of plastid DNA conformation was found.     

Metabolic activities in Cyanophora paradoxa and its cyanelles

Isolated cyanelles of Cyanophora paradoxa perform photosystem I and II dependent Hill reactions. The photosynthetic electron transport of the cyanelles does not show special features uncommon in cyanobacteria or chloroplasts of red algae. A preparation of cyanelles performs photosynthetic O₂-evolution with approximately 1/3 of the rate of intact Cyanophora, in only, however, the first three minutes of the experiment. All attempts to stabilize the CO₂-fixation activity of isolated cyanelles failed. Isolated cyanelles do not perform KCN-sensitive O₂-uptake, indicating that respiratory cytochrome oxidase is lacking in cyanelles. O₂-consumption by crude extracts from Cyanophora is inhibited by KCN when N-tetramethyl-p-phenylenediamine/ascorbate or NADH but not NADPH are supplied as the electron donors in contrast to the situation in cyanobacteria. These findings suggest that cyanelles do not respire. It is concluded that cyanelles are not so much related to cyanobacteria as formerly believed, but share many properties with chloroplasts of eukaryotic cells.Abbreviations Chl chlorophyll - DCPIP dichlorophenol-indophenol - TMPD N-tetramethyl-p-phenylenediamine To whom correspondence should be addressed     

Evidence for a peptidoglycan envelope in the cyanelles of Glaucocystis nostochinearum Itzigsohn

Glaucocystis nostochinearum is a eukaryotic organism with chloroplasts that have usually been assumed to be cyanelles — i.e., endosymbiotic cyanobacteria. Previous attempts by others to support this assumption by demonstrating the presence of a limiting peptidoglycan envelope have been unsuccessful.In the present study disruption of intact Glaucocystis cells with a glass tissue homogenizer permitted the isolation of the uniquely-shaped cyanelles. That these cyanelles were lunited by a peptidoglycan-containing envelope was concluted from the following evidence: (1) stability of isolated cyanelles in distilled water as determined by the preservation of their intactness and peculiar asymmetrical shape; (2) lysozyme sensitivity as demonstrated by lysis of isolated cyanelles when treated with low concentrations of lysozyme; (3) inhibition of the lysozyme-mediated lysis by N-acetyl-glucosamine-2, a known competitive inhibitor of lysozyme, (4) visualization of a thin, electron dense layer between the two limiting membranes around the cyanelle, and (5) isolation and identification of the peptidoglycan-specific amino acid, diaminopimelic acid, from the cyanelles.     

Analyses of ribosomal RNA sequences from glaucocystophyte cyanelles provide new insights into the evolutionary relationships of plastids

Glaucocystophyte algae (sensu Kies, Berl. Deutsch. Bot. Ges. 92, 1979) contain plastids (cyanelles) that retain the peptidoglycan wall of the putative cyanobacterial endosymbiont; this and other ultrastructural characters (e.g., unstacked thylakoids, phycobilisomes) have suggested that cyanelles are primitive plastids that may represent undeveloped associations between heterotrophic host cells (i.e., glaucocystophytes) and cyanobacteria. To test the monophyly of glaucocystophyte cyanelles and to determine their evolutionary relationship to other plastids, complete 16S ribosomal RNA sequences were determined for Cyanophora paradoxa, Glaucocystis nostochinearum, Glaucosphaera vacuolata, and Gloeochaete wittrockiana. Plastid rRNAs were analyzed with the maximum-likelihood, maximumparsimony, and neighbor joining methods. The phylogenetic analyses show that the cyanelles of C. paradoxa, G. nostochinearum, and G. wittrockiana form a distinct evolutionary lineage; these cyanelles presumably share a monophyletic origin. The rDNA sequence of G. vacuolata was positioned within the nongreen plastid lineage. This result is consistent with analyses of nuclear-encoded rRNAs that identify G. vacuolata as a rhodophyte and support its removal from the Glaucocystophyta. Results of a global search with the maximumlikelihood method suggest that cyanelles are the first divergence among all plastids; this result is consistent with a single loss of the peptidoglycan wall in plastids after the divergence of the cyanelles. User-defined tree analyses with the maximum-likelihood method indicate, however, that the position of the cyanelles is not stable within the rRNA phylogenies. Both maximumparsimony and neighbor-joining analyses showed a close evolutionary relationship between cyanelles and nongreen plastids; these phylogenetic methods were sensitive to inclusion/exclusion of the G. wittrockiana cyanelle sequence. Base compositional bias within the G. wittrockiana 16S rRNA may explain this result. Taken together the phylogenetic analyses are interpreted as supporting a near-simultaneous radiation of cyanelles and green and nongreen plastids; these organelles are all rooted within the cyanobacteria.Correspondence to: D. Bhattacharya     

The nucleotide sequence of five ribosomal protein genes from the cyanelles ofCyanophora paradoxa: Implications concerning the phylogenetic relationship between cyanelles and chloroplasts

Summary The nucleotide sequences of the ribosomal protein genesrps18, rps19, rpl2, rpl33, and partial sequence ofrpl22 from cyanelles, the photosynthetic organelles of the protistCyanophora paradoxa, have been determined. These genes form two clusters oriented in opposite and divergent directions. One cluster contains therpl33 andrps18 genes; the other contains therpl2, rps19, andrpl22 genes, in that order. Phylogenetic trees were constructed from both the DNA sequences and the deduced protein sequences of cyanelles,Euglena gracilis and land plant chloroplasts, andEscherichia coli, using parsimony or maximum likelihood methods. In addition, a phylogenetic tree was built from a distance matrix comparing the number of nucleotide substitutions per site. The phylogeny inferred from all these methods suggests that cyanelles fall within the chloroplast line of evolution and that the evolutionary distances between cyanelles and land plant chloroplasts are shorter than betweenE. gracilis chloroplasts and land plant chloroplasts.     

Exchange of Metabolites in Cyanophora paradoxa and its Cyanelles*

The flagellate Cyanophora paradoxa contains blue-greenish, organelle-like inclusions termed cyanelles which perform photosynthetic CO₂-fixation in place of chloroplasts. By the use of the HPLC-technique, Cyanophora was shown to form glucose, sucrose, maltose, mannitol, ribose, glycerol and trehalose. Extracts from the whole organism and from the eucaryotic host, but not from the cyanelles, convert ¹⁴C-labelled UDP-glucose to polyglucan. Synthesis of sucrose from UDP-glucose and fructose-6-P or fructose could not be demonstrated in any extract from Cyanophora. The transfer of metabolites into cyanelles was monitored by the silicone oil filtering technique. The solute spaces for ¹⁴C-labelled sorbitol and ³H₂O were the same indicating that sorbitol freely penetrated the plasma membrane of cyanelles in contrast to the situation found in chloroplasts. The measurements of the solute spaces for the different compounds showed that maltose and sucrose were not accumulated by isolated cyanelles. Other compounds like fructose, fucose, glutamine or glycine had intermediate sizes of their solute spaces. Cyanelles apparently possess a rapidly transporting glucose carrier and not a malate/oxaloacetate shuttle and also not an ATP/ADP translocator. The carrier composition at the plasma membrane of cyanelles and at the inner envelope membrane of chloroplasts seems to be totally different.     

Isolation and characterization of outer and inner envelope membranes of cyanelles from a glaucocystophyte, Cyanophora paradoxa

Envelope membranes were isolated by sucrose density gradient floatation centrifugation from the homogenate of cyanelles prepared from Cyanophora paradoxa. Two yellow bands were separated after 40 h of centrifugation. The buoyant density of one of the two fractions (fraction Y2) coincided with that of inner envelope membranes of spinach or plasma membranes of cyanobacteria. The other yellow fraction (fraction Y1) migrated to top of sucrose-gradient even at 0% sucrose. Pigment analysis revealed that the heavy yellow fraction was rich in zeaxanthin while the light fraction was rich in β-carotene, and the both fractions contained practically no chlorophylls. Another yellow fraction (fraction Y3) was isolated from the phycobiliprotein fraction, which was the position where the sample was placed for gradient centrifugation. Its buoyant density and absorption spectra were similar to outer membranes of cyanobacteria. We have assigned fractions Y2 and Y3 as inner and outer envelope membrane fractions of cyanelles, respectively. Protein compositions were rather different between the two envelope membranes indicating little cross-contamination among the fractions. H. Koike and Y. Ikeda contributed equally.