Evolution of organelles and eukaryotic genomes

Expression and functional assembly into bacterial ribosomes of a nuclear-encoded chloroplast ribosomal protein with a long NH2-terminal extension

Chloroplast ribosomal protein L13 is encoded in the plant nucleus and is considerably larger than its eubacterial homologue by having NH2- and COOH-terminal extensions with no homology to any known sequences (Phua et al., J Biol. Chem. 264, 1968-1971, 1989). We made two gene constructs of L13 cDNA using the polymerase chain reaction (PCR) and expressed them in Escherichia coli. Analysis of the ribosomes and polysomes from these cells, using an antiserum specific to chloroplast L13, shows that the expressed proteins are incorporated, in the presence of the homologous E. coli L13, into functional ribosomes which participate in protein synthesis (i.e. polysomes). Evidence is obtained that the large NH2-terminal extension probably lies on the surface of these 'mosaic ribosomes.' This first report of the assembly into E. coli ribosomes of nuclear-coded chloroplast ribosomal protein with terminal extensions thus suggest an extraordinary conservation in the function of eubacterial type ribosomal proteins, despite the many changes in protein structure during their evolution inside a eukaryotic system.

The nuclear:organelle distribution of chloroplast ribosomal proteins genes. Features of a cDNA clone encoding the cytoplasmic precursor of L11

The majority of chloroplast ribosomal proteins are encoded in the nuclear genome. In order to characterize these proteins through their mRNA, we have previously constructed a spinach cDNA expression library and raised antisera to several spinach chloroplast ribosomal proteins. Here we describe the immuno isolation of cDNA clones encoding protein L11 and its chloroplast-targeting presequence. The cytoplasmic precursor form of L11 is 224 amino acid residues long (Mr 23,662); the mature L11 and the transit sequence are predicted to be of approximately 159 and approximately 65 residues, respectively. The predicted chloroplast L11 is significantly longer than the E coli L11, but similar (in size) to archaebacterial and yeast cytoplasmic L11. In sequence it is closer to E coli L11 (54% identity) than to the archaebacterial (32%) or yeast (23%) proteins. These results and the conservation of the contexts of the 3 methyl modified residues found in E coli L11 are discussed in the light of the endosymbiont theory and nuclear relocation of the rp/KAJL gene cluster.

Cloning and characterization of the genes for ribosomal proteins L10 and L12 from Synechocystis Sp. PCC 6803: comparison of gene clustering pattern and protein sequence homology between cyanobacteria and chloroplasts

The endosymbiont theory proposes that chloroplasts have originated from ancestral cyanobacteria through a process of engulfment and subsequent symbiotic adaptation. The molecular data for testing this theory have mainly been the nucleotide sequence of rRNAs and of photosystem component genes. In order to provide additional data in this area, we have isolated genomic clones of Synechocystis DNA containing the ribosomal protein gene cluster rplJL. The nucleotide sequence of this cluster and flanking regions was determined and the derived amino acid sequences were compared to the available homologous sequences from other eubacteria and chloroplasts. In Escherichia coli these two genes are part of a larger cluster, i.e., rplKAJL-rpoBC. In Synechocystis, the genes for the RNA polymerase subunit (rpoBC) are shown to be widely separated from the r-protein genes. The Synechocystis gene arrangement is similar to that in the chloroplast system, where the rpoBC1C2 and rplKAJL clusters are separated and located in two cell compartments, the chloroplast and the nucleus, respectively.

Evolutionary and biosynthetic aspects of aspartate aminotransferase isoenzymes and other aminotransferases

The mitochondrial and cytosolic isoenzymes of aspartate aminotransferase are homologous proteins. Both are encoded by nuclear DNA and synthesized on free polysomes. The organization of their genes is very similar, five out of a total of eight introns are located at the same nucleotide position. A variant consensus sequence was observed at the 3' splice site of introns of genes of imported mitochondrial proteins which may reflect the existence of splicing factors specific for the genes of this particular group of nuclear-encoded proteins. To date the amino acid sequences of 22 aminotransferases are known. A rigorous analysis yielded clear evidence that aspartate, tyrosine, and histidinol-phosphate aminotransferases are homologous proteins despite their low degree of sequence identity. The evolutionary relationship among the vitamin B6-dependent enzymes in general appears less clear. Conceivably, their common structural and mechanistic features are dictated by the chemical properties of pyridoxal 5'-phosphate rather than being due to a common ancestor of their protein moieties. In agreement with this notion, the ubiquitous active-site lysine residue that forms a Schiff base with the coenzyme can be replaced in the case of aspartate aminotransferase by a histidine residue without complete loss of catalytic competence.

Chloroplast ribosomal protein L12 is encoded in the nucleus: construction and identification of its cDNA clones and nucleotide sequence including the transit peptide

An architectural feature found in all classes of ribosomes is a thin, 10-nm-long protuberance in the large subunit, generated by multiple copies of r-protein L12. The primary structure of spinach chloroplast r-protein L12 is known [Bartsch, M., Kimura, M., & Subramanian, A. R. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 6871-6875], but the location of its gene, whether in the organelle or in the nucleus, has not been determined. Therefore, we synthesized four oligodeoxynucleotides based on the amino acid sequence data and used them to probe a spinach cDNA library we constructed in lambda gt11 vector. cDNA inserts from four of the hybridizing recombinant clones were characterized and sequenced. The data showed that they are reverse transcripts of varying length, all derived from a single poly(A+) RNA species. The longest cDNA molecule is 900 base pairs (bp) long and includes a 5' noncoding sequence followed by two neighboring AUG codons both in the consensus, eukaryotic initiator context, a 56-codon-long transit peptide sequence (starting from the first AUG codon), the amino acid sequence of mature L12 protein, and a 238 bp long 3' downstream noncoding sequence including a polyadenylation signal and the start of the poly(A) tail. The transit peptide sequence has an unusual amino acid composition similar to that of other known chloroplast transit peptides. Northern blot analysis of the poly(A+) RNA isolated from spinach seedlings and probed with the cDNA insert revealed the occurrence of a strong, broad, 950-nucleotide-long band of the corresponding poly(A+)-containing mRNA species.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of the ndhC-psbG-ORF157/159 operon of maize plastid DNA and of the cyanobacterium Synechocystis sp. PCC6803

The ndhC and ORF159 genes of the maize plastid DNA (ptDNA) were sequenced and maize ORF159 was used to screen a library of genomic DNA of the blue-green alga Synechocystis sp. PCC 6803. The cyanobacterial gene homologous to ORF159 (ORF157) was isolated and sequenced. In sequencing the region upstream of ORF157, reading frames with homology to the ndhC and psbG genes of maize ptDNA were identified. The ndhC and psbG genes overlap in the ptDNAs of maize, tobacco and Marchantia polymorpha, but are separated by a noncoding spacer in Synechocystis. Northern blot analysis showed that the ndhC, psbG and ORF157/159 genes are cotranscribed in maize and Synechocystis. The three genes occur in the same order in ptDNA of maize, tobacco, and M. polymorpha as in Synechocystis 6803. The amino acid sequences of the NDH-C, PSII-G and the ORF157/159 proteins deduced from the maize genes are 65%, 52% and 53% homologous to those of Synechocystis. However, the cyanobacterial and higher plant NDH-C protein sequences are only 23% homologous to the mitochondrial NDH-3 protein. Protein products of in vitro transcription/translation of the Synechocystis transcription unit had apparent molecular masses of 6 kDa (NDH-C), 25 kDa (PSII-G) and 22 kDa (ORF157) on lithium dodecyl sulfate (LDS) polyacrylamide gel electrophoresis. If these are components of an NADH dehydrogenase, cyanobacteria appear to resemble mitochondria more than they do Escherichia coli and Rhodopseudomonas capsulata with regard to this enzyme complex.

Light-dependent, but phytochrome-independent, translational control of the accumulation of the P700 chlorophyll-a protein of photosystem I in barley (Hordeum vulgare L.)

This work reports on the regulation of synthesis of the P700 chlorophyll-a apoprotein of photosystem I in barley. The mRNA for the P700 apoprotein is almost exclusively confined to the plastid membrane-bound polysomes. However, the mRNA for the 32-kDa herbicide-binding protein of photosystem II is found in both the soluble and membrane-bound polysomes.The mRNA for the P700 apoprotein is found in similar amounts in dark-grown and light-grown wild-type as well as mutant xantha-l(81) barley. The latter mutant is deficient in chlorophyll biosynthesis. However, while wild-type leaves accumulate the P700 chlorophyll-a protein only in the light, mutant leaves never accumulate the P700 apoprotein.A more sensitive approach was taken using isolated plastids to study P700 apoprotein synthesis. Etioplasts did not synthesize detectable P700 apoprotein even when the etioplasts were exposed to light. However, only a 1-min exposure of leaves to light was necessary to induce P700 apoprotein synthesis by isolated plastids.Phytochrome involvement in controlling P700 apoprotein synthesis was tested by using red/farred light treatment of leaves. These treatments showed no far-red reversibility of red-induced P700-apoprotein synthesis in isolated plastids even after 3 h of darkness after the light treatments. From these data we conclude that the accumulation of P700 apopootein is not under the control of phytochrome and that the light induction of P700 apoprotein is most likely mediated through the protochlorophyllide/chlorophyllide system. This control, however, may also involve cytoplasmic signals as the synthesis of the P700 apoprotein is not turned on in illuminated etioplasts.

Ribosomal RNA and the major lines of evolution: a perspective

Does the "universal tree" based on small-subunit ribosomal RNA sequences show the phylogenetic relationship of all modern organisms? The answer is "yes" only if all these rRNAs are orthologous. Herein I argue that the major rRNA lineages (e.g. eubacterial, one or more archaebacterial and eukaryotic nucleocytoplasmic) probably arose from a divergent population of rRNAs in the progenote, antedating the universal common ancestral organism. Thus the major lineages of rRNA are probably not orthologous, but paralogous. The extrapolated date for the origin of the common ancestral small-subunit rRNA (3.6-4.7 x 10(9) years ago) is consistent with major rRNA lineages being paralogous. This perspective on the early evolution of genes and organisms rationalizes the presence of unexpected ribosomal characters in microsporidia, and bears on xenogenous and endogenous theories of the origin of the organelles in eukaryotes.

The light-dependent accumulation of the P700 chlorophyll a protein of the photosystem I reaction center in barley. Evidence for translational control

The light-dependent accumulation of the P700 chlorophyll a protein of the photosystem I reaction center has been studied in greening barley (Hordeum vulgare L.) seedlings. Immunoblot analysis of total cellular protein fractions and immunogold labelling of the P700 chlorophyll a protein in ultrathin sections of Lowicryl-embedded leaf tissue revealed that the concentration of this chlorophyll-binding protein in plastids of dark-grown barley seedlings is below the limit of detection. Upon illumination with white light, a rapid accumulation of this protein is induced. This light effect seems not to be regulated at the level of transcription. The gene for the P700 chlorophyll a protein has been mapped within the large single-copy region of the plastid DNA of barley. High levels of transcripts of this gene are present already in dark-grown seedlings and remain fairly constant throughout an extended illumination period. Polysomes were isolated from etioplasts and chloroplasts. The same high relative concentration of mRNA encoding the P700 chlorophyll a protein was present in both polysome fractions. This result suggests that the light-dependent accumulation of the P700 chlorophyll a protein during chloroplast formation in barley seedlings is regulated at the translational, or posttranslational, level.

Prokaryotic features of a nucleus-encoded enzyme. cDNA sequences for chloroplast and cytosolic glyceraldehyde-3-phosphate dehydrogenases from mustard (Sinapis alba)

Two cDNA clones, encoding cytosolic and chloroplast glyceraldehyde-3-phosphate dehydrogenases (GAPDH) from mustard (Sinapis alba), have been identified and sequenced. Comparison of the deduced amino acid sequences with one another and with the GAPDH sequences from animals, yeast and bacteria demonstrates that nucleus-encoded subunit A of chloroplast GAPDH is distinct from its cytosolic counterpart and the other eukaryotic sequences and relatively similar to the GAPDHs of thermophilic bacteria. These results are compatible with the hypothesis that the nuclear gene for subunit A of chloroplast GAPDH is of prokaryotic origin. They are in puzzling contrast with a previous publication demonstrating that Escherichia coli GAPDH is relatively similar to the eukaryotic enzymes [Eur. J. Biochem. 150, 61-66 (1985)].

The implication of a plastid-derived factor in the transcriptional control of nuclear genes encoding the light-harvesting chlorophyll a/b protein

In carotenoid-deficient albina mutants of barley and in barley plants treated with the herbicide Norflurazon the light-dependent accumulation of the mRNA for the light-harvesting chlorophyll a/b protein (LHCP) is blocked. Thus, the elimination of a functional chloroplast, either as a result of mutation or as a result of herbicide treatment, can lead to the specific suppression of the expression of a nuclear gene encoding a plastid-localized protein. These results confirm and extend earlier observations on maize [Mayfield and Taylor (1984) Eur. J. Biochem. 144, 79-84]. The inhibition of mRNA accumulation appears to be specific for the LHCP; the mRNAs encoding the small subunit of ribulose-1,5-bisphosphate carboxylase and the NADPH: protochlorophyllide oxidoreductase are relatively unaffected. The failure of the albina mutants and of Norflurazon-treated plants to accumulate the LHCP mRNA is not exclusively caused by an instability of the transcript but rather by the inability of the plants to enhance the rate of transcription of the LHCP genes during illumination. Several chlorophyll-deficient xantha mutants of barley, which are blocked after protoporphyrin IX or Mg-protoporphyrin, and the chlorophyll-b-less mutant chlorina f2 accumulate the LHCP mRNA to almost normal levels during illumination. Thus, if any of the reactions leading to chlorophyll formation is involved in the control of LHCP mRNA accumulation it should be one between the formation of protochlorophyllide and the esterification of chlorophyllide a. While the nature of the regulatory factor(s) has not been identified our results suggest that, in addition to phytochrome (Pfr), plastid-dependent factors are required for a continuous light-dependent transcription of nuclear genes encoding the LHCP.

Maize plastid photogenes: mapping and photoregulation of transcript levels during light-induced development

Positively photoregulated regions that show increased transcript levels upon illumination of dark-grown seedlings are scattered over approximately 19% of the maize plastid chromosome. Some photogenes, i.e., genes within these regions, are transcribed individually, whereas others that are transcribed as polycistronic mRNAs appear to be functionally organized into operons. Multiple light-induced transcripts are complementary to most photogenes; these mRNAs are not present in equimolar amounts during plastid photomorphogenesis, but particular transcripts predominate at specific stages of development. Most, but not all, photogene RNA pools reach a maximum size (after either 10, 20, or 44 h of illumination) and then fall to approximately preillumination levels. These data and other considerations argue that photogene expression control is fundamentally transcriptional and that there is more than one expression class. Transcripts of the maize plastid gene for the large subunit of ribulose bisphosphate carboxylase reach a maximum by 20 h of illumination; transcripts of the nuclear gene for the small subunit of this enzyme continue to accumulate and fall considerably later. These data suggest that the level of transcription of the latter gene in the nucleus may be regulated by events in the chloroplast.

Growth inhibition of Leishmania tropica amastigotes in vitro by rifampicin combined with amphotericin B

Rifampicin and Amphotericin B (AMB) were studied separately and in combination to determine their effect in vitro on intracellular Leishmania tropica amastigotes. On the fourth day of treatment, rifampicin at 200 micrograms ml-1 or AMB at 0.15 microgram ml-1 reduced the parasites' survival index (PSI) to 10% compared with the untreated control. In combination, there was a significant synergistic effect at several concentrations. The synergistic therapeutic effects were not accompanied by toxicity to the host cells, although each drug alone caused cellular degeneration in the ultrastructure of the parasites with the formation of large autophagic-like vacuoles, while the combination increased the percentage of degenerate cells.

Pronounced structural similarities between the small subunit ribosomal RNA genes of wheat mitochondria and Escherichia coli

We present here the nucleotide sequence of the small subunit (18S) rRNA gene from wheat mitochondria. Aside from five discrete variable domains, this gene and the analogous (16S) rRNA gene in Escherichia coli show essentially a one-to-one correspondence in their potential secondary structures, with regions accounting for 86% of the bacterial 16S rRNA having a strict secondary structure counterpart in the mitochondrial 18S rRNA. Primary sequence identity between the two rRNAs ranges from 73% to 85% (76% overall) within regions of conserved secondary structure. Within a smaller secondary structure core common to all small subunit rRNAs, the wheat mitochondrial sequence shares substantially more primary sequence identity with the E. coli (eubacterial) sequence (88%) than with the small subunit rRNA sequences of Halobacterium volcanii (an archaebacterium) (71%) or Xenopus laevis cytoplasm (61%). Moreover, the wheat mitochondrial sequence contains a very high proportion of certain lineage-specific residues that distinguish eubacterial/plastid 16S rRNAs from archaebacterial 16S and eukaryotic cytoplasmic 18S rRNAs. These data establish that the ancestry of the wheat mitochondrial 18S rRNA gene can be traced directly and specifically to the eubacterial primary kingdom, and the data provide compelling support for a relatively recent xenogenous (endosymbiotic) origin of plant mitochondria from eubacteria-like organisms.

Characterization of a prokaryotic topoisomerase I activity in chloroplast extracts from spinach

A topoisomerase I activity has been partially purified from crude extracts of spinach chloroplasts. This activity relaxes the supercoiled covalently closed circular DNA of pBR322. The enzyme requires Mg++, but not ATP, and has an apparent molecular weight of about 115,000. It catalyzes a unit change in the linkage number of supercoiled DNA but cannot relax positive supercoiled DNA. These characteristics of the topoisomerase suggest it is of the prokaryotic type and would tend to support the endosymbiotic theory of plastid origin and evolution.

The light-dependent control of chloroplast development in barley (Hordeum vulgare L)

The light-induced greening of etiolated barley plants is used as a model to study the light-dependent control of plastid development. Upon illumination a rapid transformation of etioplasts to chloroplasts is induced. The effect of illumination does not only include the light-dependent chlorophyll synthesis but also the appearance or decline of specific proteins within the plastid membrane fractions. So far two of these proteins have been studied in detail. The light-harvesting chlorophyll a/b protein (LHCP) is one of the major protein constituents of the thylakoid membrane of chloroplasts. However, this protein is not detectable among the membrane polypeptides of etioplasts. Illumination of dark-grown barley plants induces a massive insertion of the LHCP. The appearance of the protein is controlled by the cooperation of at least two distinct photoreceptors: protochlorophyllide and phytochrome. In dark-grown barley plants not only the LHCP but also its mRNA is not detectable. The light-dependent appearance of mRNA activity for the LHCP is under the control of phytochrome (Pfr). Even though the appearance of mRNA activity is induced via Pfr by a single red light pulse, the assembly of the complete LHCP takes place only under continuous illumination, which allows chlorophyll synthesis. The second protein analyzed so far is the NADPH-protochlorophyllide-oxidoreductase. This enzyme catalyzes the light-dependent reduction of protochlorophyllide to chlorophyllide and thus controls one of the first detectable light-dependent reactions during the greening period. It is generally assumed that this enzyme is responsible for the overall chlorophyll synthesis and accumulation during the greening period.(ABSTRACT TRUNCATED AT 250 WORDS)

The presence and synthesis of the NADPH-protochlorophyllide oxidoreductase in barley leaves with a high temperature-induced deficiency of plastid ribosomes

High-temperature-induced deficiency of plastid ribosomes in barley plants (Hordeum vulgare L.) was used as a system for studying the role of the cytoplasm in the synthesis of the NADPH-protochlorophyllide oxidoreductase. The enzyme is present in 33° C-grown plants. The failure of high-temperature-grown plants to accumulate chlorophyll during illumination is not caused by the absence of the protochlorophyllide-reducing enzyme. The synthesis of the NADPH-protochlorophyllide oxidoreductase was studied by feeding [(35)S]methionine to the seedling and by following the incorporation of the radioactively labeled amino acid into plastid proteins. The NADPH-protochlorophyllide oxidoreductase was labeled in high-temperature-grown barley plants to the same extent as in control plants grown at 25° C. It is concluded that the 36,000-Mr polypeptide of the NADPH-protochlorophyllide oxidoreductase is synthesized outside the plastid on cytoplasmic 80S ribosomes.

Evolutionary divergence of chloroplast and cytosolic glyceraldehyde-3-phosphate dehydrogenases from angiosperms

Extracts from 13 different angiosperm species (spinach, mustard, pea, bean, tomato, cucumber, pumpkin, maize, sorghum, rye, wheat, oats, barley) were submitted to electrophoresis under nondenaturing conditions and stained for enzyme activities of cytosolic and chloroplast glyceraldehyde-3-phosphate dehydrogenases by a modified tetrazolium test of high sensitivity. Zymograms of the cytosolic enzyme revealed a single band of similar electrophoretic mobility for all but one species, the tomato, which displayed an ordered set of five different bands. In contrast, zymograms of the chloroplast dehydrogenase are highly different, containing between two and five distinct bands of variable electrophoretic mobilities according to the plant species examined. This variability of the native chloroplast enzyme is paralleled by a remarkable interspecific heterogeneity of the enzyme with respect to subunit size and number, as shown by dodecylsulfate electrophoresis of the purified chloroplast enzyme from 11 different angiosperm species. The present data suggest that cytosolic and chloroplast glyceraldehyde-3-phosphate dehydrogenases belong to two separate protein families of different evolutionary rate. While the cytosolic enzyme is probably an extremely conservative protein like the corresponding enzymes from animals, yeast and bacteria, the chloroplast enzyme seems to change rather rapidly during evolution.

The protochlorophyllide holochrome of barley (Hordeum vulgare L.). Phytochrome-induced decrease of translatable mRNA coding for the NADPH: protochlorophyllide oxidoreductase

During the illumination of dark-grown barley plants light induces a rapid decrease of a translatable mRNA which codes for a polypeptide of Mr 44000. This component was identified as a precursor of the NADPH:protochlorophyllide oxidoreductase. The precursor has an Mr larger than the authentic protein by approximately 8000. The light-induced change in the level of translatable mRNA can be induced by a 15-s red-light pulse followed by 5 h of darkness. The red-light effect is reversed by a subsequent far-red-light treatment. It is concluded that the light-induced decline of translatable mRNA for the NADPH:protochlorophyllide oxidoreductase is controlled by phytochrome. The significance of this finding for present concepts of light-dependent control of chloroplast development and chlorophyll synthesis is discussed.

Capacity for RNA synthesis in 70S ribosome-deficient plastids of heat-bleached rye leaves

In the leaves of rye seedlings (Secale cereale L.) grown at an elevated temperature of 32°C the formation of plastidic 70S ribosomes is specifically prevented. The resulting plastid ribosome-deficient leaves, which are chlorotic in light, represent a system for the identification of translation products of the 80S ribosomes among the chloroplastic proteins. Searching for the primary heat-sensitive event causing the 70S ribosome-deficiency, the thermostability of the chloroplastic capacity for RNA synthesis was investigated. The RNA polymerase activity of isolated normal chloroplasts from 22°-grown rye leaves was not inactivated in vitro at temperatures between 30° and 40°C. The ribosome-deficient plastids purified from bleached 32°-grown leaf parts contained significant RNA polymerase activity which was, however, lower than in functional chloroplasts. After application of [(3)H]uridine to intact leaf tissues [(3)H]uridine incorporation was found in ribosome-deficient plastids of 32°C-grown leaves. The amount of incorporation was similar to that in the control chloroplasts from 22°C-grown leaves. According to these results, it is unlikely that the non-permissive temperature (32°C) causes a general inactivation of the chloroplastic RNA synthesis in rye leaves.

Effect of mitochondrial functions on synthesis of yeast cytochrome c

The effects of the mitochondrial protein synthesis inhibitor chloramphenicol and the mitochondrial F0 adenosine triphosphatase inhibitor oligomycin on the synthesis of nucleus-encoded cytochrome c protein were studied. Both inhibitors stimulated cytochrome c protein synthesis in the derepressed state (growth in media containing 2% raffinose) but had no effect on the synthesis of the cytochrome c protein in the repressed state (growth in media containing 5% glucose). Oligomycin uncoupled the synthesis of the apoprotein from its processing into the hemoprotein. Neither antibiotic had a significant effect on the rate of glucose repression of cytochrome protein synthesis. The kinetics of cytochrome c derepression and the effects of these two antibiotics on these kinetics were also studied. Cells were derepressed by transfer from glucose- to faffinose-containing media, and the rate of cytochrome c synthesis increased from the repressed to the derepressed level during the second hour of derepression. Chloramphenicol delayed this derepression, but after 5 h the rate of cytochrome c protein synthesis increased to twice the rate of synthesis in uninhibited cells. On the other hand, oligomycin inhibited derepression of cytochrome c. These results are discussed with respect to the effects of mitochondrial function in the derepressed and repressed states and during the processes of repression and derepression of cytochrome c.

Nucleotide sequences of chloroplast 5S ribosomal ribonucleic acid in flowering plants

Evidence for the sequence of duckweed (Lemna minor) chloroplast 5S rRNA was derived from the analysis of partial and complete enzymic digests of the 32P-labelled molecule. The possible sequence of the chloroplast 5S rRNA from three other flowering plants was deduced by complete digestion with T1 ribonuclease and comparison of the sequences of the oligonucleotide products with homologous sequences in the duckweed 5S rRNA. This analysis indicates that the chloroplast 5S rNA species differ appreciably from their cytosol counterparts but bear a strong resemblance to one another and to the 5S rRNA species of prokaryotes. Structural features apparently common to all 5S rRNA molecules are also discussed.

Nucleotide polymorphism in chloroplast dna of Nicotiana debneyi

EcoR1 restriction endonuclease analysis of chloroplast DNA isolated from several distinct populations of Nicotiana debneyi has revealed a naturally occurring polymorphism. The chloroplast DNA of seven of the nine populations analysed possessed an additional EcoRl site. The origin of the additional restriction endonuclease fragments was confirmed by hybridisation of [(32) P]-cRNA to fractionated EcoRl restricted chloroplast-DNA fragments adsorbed to nitrocellulose filters. Reciprocal f1 hybrids between plants carrying the variant chloroplast-DNA's confirmed maternal inheritance of chloroplast-DNA.

The kinetic complexity of Acetabularia chloroplast DNA

The kinetic complexity of Acetabularia cliftonii chloroplast DNA is 1.52 +/- 0.26 . 10(9) daltons, compared to 0.2 .10(9) daltons for Chlamydomonas chloroplast DNA. There is an average of three genomes per chloroplast. The unusually large size of the Acetabularia genome may reflect the ancient evolutionary history of this organism.

The effect of cycloheximide on Euglena gracilis phenylalanyl-tRNA synthetases

The effect of cycloheximide on the chloroplastic, cytoplasmic and mitochondrial phenylalanyl-transfer RNA synthetases of Euglena gracilis was studied by growing both logarithmic and stationary phase cultures in the presence of the antibiotic. Enzyme activity was measured relative to untreated control cultures. At very low concentrations of cycloheximide (1 microgram/ml), all three log phase enzymes showed an increase in activity of 40-50%. At slightly higher concentrations (2.5 microgram/ml), the phenylalanyl-tRNA synthetase activities were comparable to those of the control cultures. At a cycloheximide concentration of 5 microgram/ml the enzyme activities from stationary phase cultures showed only very slight decreases (5-20%). The cytoplasmic and mitochondrial enzymes behaved similarly in log phase cultures at this concentration. However, the chloroplastic phenylalanyl-tRNA synthetase from log phase cultures treated with 5 microgram/ml cycloheximide showed a marked decrease in activity (70%). A further increase in antibiotic concentration to 10 microgram/ml resulted in significant losses of activity of all three enzymes, from both growth stages. The implications of the data with regard to identification of the site(s) of chloroplast enzyme synthesis are discussed.