Synthesis of pigment-binding protein in toluene-treated Rhodopseudomonas capsulata and in cell-free systems

Solving the Riddle of the Evolution of Shine-Dalgarno Based Translation in Chloroplasts

Chloroplasts originated from an ancient cyanobacterium and still harbor a bacterial-like genome. However, the centrality of Shine–Dalgarno ribosome binding, which predominantly regulates proteobacterial translation initiation, is significantly decreased in chloroplasts. As plastid ribosomal RNA anti-Shine–Dalgarno elements are similar to their bacterial counterparts, these sites alone cannot explain this decline. By computational simulation we show that upstream point mutations modulate the local structure of ribosomal RNA in chloroplasts, creating significantly tighter structures around the anti-Shine–Dalgarno locus, which in-turn reduce the probability of ribosome binding. To validate our model, we expressed two reporter genes (mCherry, hydrogenase) harboring a Shine–Dalgarno motif in the Chlamydomonas reinhardtii chloroplast. Coexpressing them with a 16S ribosomal RNA, modified according to our model, significantly enhances mCherry and hydrogenase expression compared with coexpression with an endogenous 16S gene.

Integrative "omics"-approach discovers dynamic and regulatory features of bacterial stress responses

Bacteria constantly face stress conditions and therefore mount specific responses to ensure adaptation and survival. Stress responses were believed to be predominantly regulated at the transcriptional level. In the phototrophic bacterium Rhodobacter sphaeroides the response to singlet oxygen is initiated by alternative sigma factors. Further adaptive mechanisms include post-transcriptional and post-translational events, which have to be considered to gain a deeper understanding of how sophisticated regulation networks operate. To address this issue, we integrated three layers of regulation: (1) total mRNA levels at different time-points revealed dynamics of the transcriptome, (2) mRNAs in polysome fractions reported on translational regulation (translatome), and (3) SILAC-based mass spectrometry was used to quantify protein abundances (proteome). The singlet oxygen stress response exhibited highly dynamic features regarding short-term effects and late adaptation, which could in part be assigned to the sigma factors RpoE and RpoH2 generating distinct expression kinetics of corresponding regulons. The occurrence of polar expression patterns of genes within stress-inducible operons pointed to an alternative of dynamic fine-tuning upon stress. In addition to transcriptional activation, we observed significant induction of genes at the post-transcriptional level (translatome), which identified new putative regulators and assigned genes of quorum sensing to the singlet oxygen stress response. Intriguingly, the SILAC approach explored the stress-dependent decline of photosynthetic proteins, but also identified 19 new open reading frames, which were partly validated by RNA-seq. We propose that comparative approaches as presented here will help to create multi-layered expression maps on the system level ("expressome"). Finally, intense mass spectrometry combined with RNA-seq might be the future tool of choice to re-annotate genomes in various organisms and will help to understand how they adapt to alternating conditions.

Gene expression of pigment-binding proteins of the bacterial photosynthetic apparatus: Transcription and assembly in the membrane of Rhodopseudomonas capsulata

Lowering of oxygen partial pressure in chemotrophic cultures or reduction of light intensity in phototrophic cultures of Rhodopseudomonas capsulata induced formation of the photosynthetic apparatus. A maximum of mRNA coding for the reaction center (RC) and the light-harvesting 1 B870 antenna complex polypeptides occurred 30 min after induction. Maximal expression of mRNA for B800-B850 antenna proteins appeared with a lag time of about 25 min after RC/B870 mRNA. Pigment-binding polypeptides were inserted into the membrane immediately after mRNA synthesis. It is concluded that the delayed formation of the B800-B850 complex compared to the RC and the B870 complex is caused by sequential expression of the corresponding genes. Biological activity of pigment-protein complexes increased after the incorporation of their polypeptides parallel to the maximum of bacteriochlorophyll synthesis. Studies on mutant strains defective in the formation of pigment-protein complexes suggested that pigment synthesis is of importance for assembly of stable complexes.

Multi-step Assembly Pathway of the cbb3-type Cytochrome c Oxidase Complex

The cbb3-type cytochrome c oxidases as members of the heme-copper oxidase superfamily are involved in microaerobic respiration in both pathogenic and non-pathogenic proteobacteria. The biogenesis of these multisubunit enzymes, encoded by the ccoNOQP operon, depends on the ccoGHIS gene products, which are proposed to be specifically required for co-factor insertion and maturation of cbb3-type cytochrome c oxidases. Here, the assembly of the cbb3-type cytochrome c oxidase from the facultative photosynthetic model organism Rhodobacter capsulatus was investigated using blue-native polyacrylamide gel electrophoresis. This process involves the formation of a stable but inactive 210 kDa sub-complex consisting of the subunits CcoNOQ and the assembly proteins CcoH and CcoS. By recruiting monomeric CcoP, this sub-complex is converted into an active 230 kDa CcoNOQP complex. Formation of these complexes and the stability of the monomeric CcoP are impaired drastically upon deletion of ccoGHIS. In a ccoI deletion strain, the 230 kDa complex was absent, although monomeric CcoP was still detectable. In contrast, neither of the complexes nor the monomeric CcoP was found in a ccoH deletion strain. In the absence of CcoS, the 230 kDa complex was assembled. However, it exhibited no enzymatic activity, suggesting that CcoS might be involved in a late step of biogenesis. Based on these data, we propose that CcoN, CcoO and CcoQ assemble first into an inactive 210 kDa sub-complex, which is stabilized via its interactions with CcoH and CcoS. Binding of CcoP, and probably subsequent dissociation of CcoH and CcoS, then generates the active 230 kDa complex. The insertion of the heme cofactors into the c-type cytochromes CcoP and CcoO precedes sub-complex formation, while the cofactor insertion into CcoN could occur either before or after the 210 kDa sub-complex formation during the assembly of the cbb3-type cytochrome c oxidase.

Directed mutagenesis of the Rhodobacter capsulatus puhA gene and orf 214: pleiotropic effects on photosynthetic reaction center and light-harvesting 1 complexes

Rhodobacter capsulatus puhA mutant strains containing either a nonpolar, translationally in-frame deletion or a polar insertion of an antibiotic resistance cartridge were constructed and evaluated for their photosynthetic growth properties, absorption spectroscopy profiles, and chromatophore protein compositions. Both types of mutants were found to be incapable of photosynthetic growth and deficient in the reaction center (RC) and light-harvesting 1 (LH1) complexes. The translationally in-frame puhA deletion strains were restored to the parental strain phenotypes by complementation with a plasmid containing the puhA gene, whereas the polar puhA mutants were not. Analogous nonpolar and polar disruptions of orf 214 (located immediately 3' of the puhA gene) were made, and the resultant mutant strains were evaluated as described above. The strain containing the nonpolar deletion of orf 214 exhibited severely impaired photosynthetic growth properties and had greatly reduced levels of the RC and LH1 complexes. Complementation of this strain with a plasmid that expressed orf 214 from the nifHDK promoter restored photosynthetic growth capability, as well as the RC and LH1 complexes. The polar disruption of orf 214 yielded cells that were incapable of photosynthetic growth and had even lower levels of the RC and LH1 complexes, and complementation in trans with orf 214 only marginally improved these deficiencies. These results indicate that orf 214 and at least one additional gene located 3' of orf 214 are required to obtain the RC and LH1 complexes, and transcription read-through from the puhA superoperon is necessary for optimal expression of these new photosynthesis genes.

Gene expression of the B875 light-harvesting prepolypeptides from Rhodospirillum rubrum in Escherichia coli

The gene coding for the prepolypeptides of alpha and beta, obtained as a 429 bp fragment from chromosomal DNA of Rhodospirillum rubrum S1 by polymerase chain reaction amplification, were cloned in tandem into the high-level expression vector pOTSNco 12 for expression in Escherichia coli. The vector pOTSNco12 is a derivative of the pAS vector system, which contains the strong lambda PL promotor and is under tight control by the cI857 repressor encoded by the expression strain AR58. Induction of transcription from the lambda PL promotor is achieved by shifting the growth temperature from 32 to 42 degrees C. Expression of the gene products was monitored by sodium dodecylsulfate polyacrylamide gel electrophoresis and western blotting. The expressed B875 light-harvesting prepolypeptides were located in the E. coli inner membrane and could not be removed by washing with high salt. The amount of expressed B875 light-harvesting prepolypeptides was estimated to be about 0.1% of the total soluble protein.

Identification and solubilization of a signal peptidase from the phototrophic bacterium Rhodobacter capsulatus

In Gram-negative bacteria, exported proteins are synthesized with an amino-terminal signal sequence which is cleaved off by the signal peptidase during, or shortly after the translocation process. Here, we report the identification and solubilization of a signal peptidase from the phototrophic bacterium Rhodobacter capsulatus which cleaves homologous and heterologous precursor proteins at the authentic cleavage site. This signal peptidase is the first identified component of the R. capsulatus protein export machinery.

Incorporation of light-harvesting complex I alpha and beta polypeptides into the intracytoplasmic membrane of Rhodobacter capsulatus

The light-harvesting complex I (LHI) of Rhodobacter capsulatus is an oligomer of basic subunits each consisting of the two different pigment-binding polypeptides LHI alpha and LHI beta, encoded by the pufA (LHI alpha) and pufB (LHI beta) genes. Pulse-labeling experiments showed that in the presence of the LHI alpha polypeptide, the LHI beta polypeptide was inserted earlier into the intracytoplasmic membrane than was the LHI alpha polypeptide. Each of the pufA and pufB genes was deleted to test whether the LHI alpha and beta polypeptides, respectively, are inserted into the intracytoplasmic membrane independently of the LHI partner polypeptide. Neither deletion mutant strain formed the LHI antenna, but a functional reaction center complex was present. Pulse-labeling experiments indicated that the LHI beta polypeptide was inserted into the intracytoplasmic membrane with the same kinetics and in the same amounts regardless of whether the LHI alpha polypeptide was present. However, the LHI beta polypeptide did not accumulate in the membrane in the absence of the LHI alpha protein but was degraded linearly within about 12 min. In contrast to the LHI beta protein, only trace amounts of the LHI alpha polypeptide were inserted into or attached to the membrane if the LHI beta polypeptide was not synthesized.

Endonucleolytic degradation of puf mRNA in Rhodobacter capsulatus is influenced by oxygen

The formation of pigment-protein complexes in facultatively photosynthetic bacteria is regulated by the oxygen tension in the culture. It is shown that the degradation of some mRNA species encoding components of the photosynthetic apparatus is affected by oxygen. The puf mRNA segment, encoding the pigment-binding proteins of the reaction center, and the 0.5-kb puc mRNA species, encoding pigment-binding proteins of the light-harvesting LHII antenna complex of Rhodobacter capsulatus were degraded more rapidly under high oxygen tension than under low oxygen tension. Studies on strains having deletions or insertions in the puf operon indicate that rate-limiting endonucleolytic cleavage in the reaction center coding region of the polycistronic puf mRNA was influenced by growth conditions. However, other mRNA segments, for which exonucleolytic degradation was postulated to be rate-limiting, decayed with the same rate under either high or low oxygen tension. Likewise, the degradation of the puhA mRNA, the cycA mRNA, and the cytfbc mRNA was found to be independent of the oxygen tension in the culture. The data strongly suggest that specific mRNA sequences or structures are responsible for the observed oxygen effect on mRNA stability.

Mechanism of puf mRNA degradation: the role of an intercistronic stem-loop structure

The puf photosynthesis operon of Rhodobacter capsulatus encodes two major classes of mRNA: operon-length pufBALMX transcripts and short pufBA messages. The pufBA messages, which end in a large intercistronic stem-loop structure, are long-lived processing products of the puf operon transcripts. Decay of the labile pufLMX segment of the operon-length transcripts begins with non-random endonucleolytic cleavage well downstream of the intercistronic hairpin structure. This hairpin, which is necessary but insufficient for the stability of the RNA segment upstream of it, appears to function as an mRNA decay terminator that protects the upstream pufBA segment from 3' exonucleolytic propagation of the initial degradative event. The comparative stability of the pufBA mRNA segment depends not only on the presence of this stem-loop structure, but also on the relative resistance of the pufBA segment to endonuclease attack.

Regulation of tetrapyrrole synthesis by light in chemostat cultures of Rhodobacter sphaeroides

Control of bacteriochlorophyll (Bchl), magnesium protoporphyrin monomethyl ester (MgPME), cytochromes, and coproporphyrin by light was studied with chemostat cultures of Rhodobacter sphaeroides growing at a constant dilution rate. By increasing the growth-limiting light energy flux from 10 to 55 W/m2, specific Bchl contents decreased from 19.3 to 7.9 nmol/mg of protein. This was strictly proportional to a decrease in the ratio of B800-850 to B875 light-harvesting complexes. MgPME levels increased from 1.5 to 5.3 nmol/mg of protein, while cytochrome as well as coproporphyrin levels stayed constant at 0.46 and 1.95 nmol/mg of protein, respectively. Since in chemostat cultures steady-state levels of a product represent the rate of synthesis, these results infer only slight control of the rate-limiting step of total tetrapyrrol formation by light. In substrate-limited cultures MgPME was accumulated when growth and Bchl formation approached substrate saturation. This suggests that light controls a second step, i.e., MgPME conversion, whenever too much precursor is available, owing to the low sensitivity of the initial step of control. MgPME was preferentially localized in a subcellular fraction with high contents of B875 complexes. A second fraction exhibiting increased contents of B800-850 complexes lacked significant levels of MgPME. These results are discussed in terms of localization of Bchl synthesis in the membrane system of R. sphaeroides.

Molecular genetics of photosynthetic membrane biosynthesis in Rhodobacter sphaeroides

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Physiological and structural analysis of light-harvesting mutants of Rhodobacter sphaeroides

Two mutants of Rhodobacter sphaeroides defective in formation of light-harvesting spectral complexes were examined in detail. Mutant RS103 lacked the B875 spectral complex despite the fact that substantial levels of the B875-alpha polypeptide (and presumably the beta polypeptide) were present. The B800-850 spectral complex was derepressed in RS103, even at high light intensities, and the growth rate was near normal at high light intensity but decreased relative to the wild type as the light intensity used for growth decreased. Mutant RS104 lacked colored carotenoids and the B800-850 spectral complex, as well as the cognate apoproteins. This strain grew normally at high light intensity and, as with RS103, the growth rate decreased as the light intensity used for growth decreased. At very low light intensities, however, RS104 would grow, whereas RS103 would not. Structural analysis of these mutants as well as others revealed that the morphology of the intracytoplasmic membrane invaginations is associated with the presence or absence of the B800-850 complex as well as of carotenoids. A low-molecular-weight intracytoplasmic membrane polypeptide, which may play a role in B800-850 complex formation, is described, as is a 62,000-dalton polypeptide whose abundance is directly related to light intensity as well as the absence of either of the light-harvesting spectral complexes. These data, obtained from studies of mutant strains and the wild type, are discussed in light of photosynthetic membrane formation and the abundance of spectral complexes per unit area of membrane. Finally, a method for the bulk preparation of the B875 complex from wild-type strain 2.4.1 is reported.

An intercistronic stem-loop structure functions as an mRNA decay terminator necessary but insufficient for puf mRNA stability

Segmental differences in stability within the polycistronic transcripts of the puf operon contribute to differential expression of photosynthesis genes in R. capsulatus. The comparatively stable 5' segment of these transcripts ends in a large intercistronic stem-loop structure. We show here that deletion of this RNA hairpin destabilizes the 5' puf mRNA segment but that its insertion at the 3' end of the puf operon transcripts fails to stabilize the labile 3' puf mRNA segment. Evidence is presented that decay of the 3' segment begins with endonucleolytic cleavage in which the intercistronic stem-loop structure does not participate. We conclude that this RNA hairpin is necessary but insufficient for the stability of mRNA upstream of it, and that it functions in message degradation solely as an mRNA decay terminator that protects upstream mRNA segments from degradation by 3' exoribonucleases.

Posttranscriptional regulation by light of the steady-state levels of mature B800-850 light-harvesting complexes in Rhodobacter capsulatus

Photosynthetic organisms exhibit a variety of responses to changes in light intensity, including differential biosynthesis of chlorophyll-protein complexes. Cultures of Rhodobacter capsulatus grown anaerobically with a low intensity of light (2 W/m2) contained about four times as much B800-850 light-harvesting complex as cells grown under high light intensity (140 W/m2). The mRNA transcripts encoding B800-850 beta and alpha peptides were analyzed by Northern blot (RNA blot), S1 nuclease protection, and capping with guanylyl transferase. It was found that the steady-state levels of B800-850 mRNAs in high-light-grown cultures were about four times as great as in cells grown under low light intensity. Therefore, the lesser amounts of mature B800-850 peptide gene products found in cells grown with high light intensity are the result of a posttranscriptional regulatory process. It was also found that there are two polycistronic messages encoding the B800-850 peptides. These messages share a common 3' terminus but differ in their 5'-end segments as a result of transcription initiation at two discrete sites. Moreover, the half-lives of B800-850 mRNAs were about 10 min in cells grown with high light and approximately 19 min in cultures grown with low light. It is concluded that there must be more frequent initiations of transcription of B800-850 genes in cells grown with high light than in those grown with low light, and that the relative amounts of B800-850 complexes under these conditions are controlled by a translational or posttranslational mechanism.

The puf operon region of Rhodobacter sphaeroides

The puf operon of the purple nonsulfur photosynthetic bacterium, Rhodobacter sphaeroides, contains structural gene information for at least two functionally distinct bacteriochlorophyll-protein complexes (light harvesting and reaction center) which are present in a fixed ratio within the photosynthetic intracytoplasmic membrane. Two proximal genes (pufBA) specify subunits of a long wavelength absorbing (i.e., 875 nm) light harvesting complex which are present in the photosynthetic membrane in ≃15 fold excess relative to the reaction center subunits which are encoded by the pufLM genes. This review summarizes recent studies aimed at determining how expression of the R. sphaeroides puf operon region relates to the ratio of individual bacteriochlorophyll-protein complexes found within the photosynthetic membrane. These experiments indicate that puf operon expression may be regulated at the transcriptional, post-transcriptional, translation and post-translational levels. In addition, this review discusses the possible role(s) of newly identified loci upstream of pufB which may be involved in regulating either synthesis or assembly of individual bacteriochrlorophyll-protein complexes as well as the pufX gene, the most distal genetic element within the puf operon whose function is still unknown.

Cloning, DNA sequence, and expression of the Rhodobacter sphaeroides light-harvesting B800-850-alpha and B800-850-beta genes

Two deoxyoligonucleotide probes were synthesized in accordance with the available amino acid sequence of the B800-850-beta polypeptide from Rhodobacter sphaeroides and were used to isolate a 2.6-kilobase PstI fragment from R. sphaeroides 2.4.1 chromosomal DNA. Identification of the B800-850-beta and B800-850-alpha structural genes, pucB and pucA, was confirmed by DNA sequencing. Northern (RNA) blot analysis, using restriction endonuclease fragments from the cloned genes as probes, revealed a single puc-operon-specific, highly stable transcript of approximately 640 bases present in photosynthetically grown cells. In vitro transcription-translation analysis of the puc operon revealed that the maximum synthesis of the puc operon gene products was achieved when the entire 2.6-kilobase PstI fragment was used as the template, although a 537-base-pair XmaIII fragment was sufficient to direct the synthesis of pucB and pucA fusion product.

DNA sequence and in vitro expression of the B875 light-harvesting polypeptides of Rhodobacter sphaeroides

The genes for the Rhodobacter sphaeroides light-harvesting B875-beta, and B875-alpha polypeptides (pufB and pufA) are closely linked to the genes for the reaction center L and reaction center M polypeptides (pufL and pufM) on what has been termed the puf operon (gene order, pufB, A, L, M). The DNA sequence of the pufB and pufA structural genes from wild-type R. sphaeroides 2.4.1 was determined and aligned with the available amino acid sequence of the wild-type B875-beta and B875-alpha polypeptides. The relative levels of the B875-beta and B875-alpha and the reaction center L and reaction center M polypeptides synthesized in a homologous cell-free transcription-translation system were compared with those found in vivo. Analysis of the gene products produced in vitro with plasmids containing deletions upstream of the pufB structural gene identified a region of DNA required for expression of the B875-beta and B875-alpha polypeptides. These results support the hypothesis that the mapped 5' termini of the large and small puf operon transcripts represent transcription initiation sites.

Oxygen-regulated mRNAs for light-harvesting and reaction center complexes and for bacteriochlorophyll and carotenoid biosynthesis in Rhodobacter capsulatus during the shift from anaerobic to aerobic growth

The stability and regulation by oxygen of mRNAs for the photosynthetic apparatus in Rhodobacter capsulatus have been studied by using proflavin to inhibit transcription and by shifting cells from anaerobic to aerobic conditions. The results from the inhibition experiments show that the mRNA for the light-harvesting LH-II polypeptides (beta, alpha) is more stable than that for the light-harvesting LH-I polypeptides (beta, alpha) during anaerobic growth, whereas the mRNAs for the reaction center polypeptides L (RC-L), M (RC-M), and H (RC-H) are less stable than both the LH-I and LH-II mRNAs. When photosynthetic cells are shifted from anaerobic to aerobic conditions, an immediate decrease in the levels of mRNA for the LH-I, LH-II, RC-L, RC-M, and RC-H proteins was observed. The level of mRNA for the LH-II proteins, however, is more sensitive to oxygen and is reduced faster than the level of mRNA for the LH-I proteins. These results suggest that oxygen represses the expression of genes coding for the light-harvesting antenna and reaction center complexes and may selectively accelerate the degradation of mRNA for the LH-II proteins. The mRNAs for several enzymes in the bacteriochlorophyll biosynthetic pathway are regulated by oxygen in a similar manner. The mRNAs for carotenoid biosynthetic enzymes, however, are regulated by oxygen in a different way. We have found that the amounts of mRNAs for carotenoid biosynthetic enzyme, relative to the amounts of mRNAs for LH and RC, increased during the shift from anaerobic to aerobic conditions. We have particularly shown that although the expression of most photosynthetic genes in R. capsulatus is repressed by oxygen, the crtA gene, located in the BamHI H fragment of the R' plasmid pRPS404 and responsible for the oxidation of spheroidene to spheroidenone, responds to oxygen in an opposite fashion. This exzymatic oxidation may protect the photosynthetic apparatus from photooxidative damage.

Effect of uncoupler on assembly pathway for pigment-binding protein of bacterial photosynthetic membranes

The uncoupler carbonylcyanide m-chlorophenylhydrazone (CCCP) was used to investigate membrane protein assembly in the phototrophic bacterium Rhodobacter capsulatus. As found for Escherichia coli (T. Date, G. Zwizinsky, S. Ludmerer, and W. Wickner, Proc. Natl. Acad. Sci. 77:827-831, 1980) and mitochondrial proteins (N. Nelson and G. Schatz, Proc. Natl. Acad. Sci. USA 76:4365-4369, 1979), assembly across the bacterial photosynthetic membranes was sensitive to CCCP. At uncoupler concentrations which were sufficient to block the export of the periplasmic cytochrome c2 and an outer membrane protein, the integration of pigment-binding protein into the photosynthetic apparatus was abolished. The unassembled protein was detected on the inner surface of the intracytoplasmic membrane. After inactivation of CCCP, accumulated protein continued insertion into the membrane. The data suggest that after binding to the cytoplasmic face of the membrane, translocation of protein into a transmembrane orientation takes place, which is a prerequisite for the formation of a functional pigment-protein complex.

In vitro biosynthesis and membrane association of photosynthetic reaction center subunits from Rhodopseudomonas sphaeroides

The reaction center of Rhodopseudomonas sphaeroides is an integral membrane protein complex responsible for primary photochemical charge separation in photosynthesis. We report the synthesis of two of the three subunits of the photosynthetic reaction center using a DNA-directed in vitro transcription-translation system prepared from R. sphaeroides. The in vitro-synthesized polypeptides, as resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, had apparent Mrs of 24,000 and 21,000 and were shown to be synthesized in equimolar amounts. This corresponds precisely to the in vivo reaction center subunits M and L, respectively. The in vitro-synthesized polypeptides were immunoprecipitated with antibody prepared against whole native reaction centers. In addition, the identity of the in vitro-synthesized polypeptides as L and M was verified by comparing the protease digestion products of in vivo- with in vitro-synthesized reaction center subunits. Both of the in vitro-synthesized polypeptides were also found to partition with the particulate material in the transcription-translation system and to associate with added membranes.

Isolation and partial characterization of the messenger RNA encoding the B880 holochrome protein of Rhodospirillum rubrum

The B880 holochrome messenger RNA was extracted from cultures of the photosynthetic bacterium Rhodospirillum rubrum. It was purified by chromatography on Sepharose 4B followed by sucrose density gradient centrifugation. The purified fractions were shown to program an Escherichia coli cell-free system into synthesizing both the alpha and the beta polypeptides of the holochrome. The translation products were identified by immunoprecipitation with specific antibodies raised against these polypeptides. The latter are effective competitors with the translation products for antigen-antibody complex formation. The purest mRNA preparations contained approximately 33% holochrome messenger RNA activity. Its most probable size, as determined by agarose gel electrophoresis in the presence of 6 M urea or methylmercuric hydroxide, is approximately 620 nucleotides. Since the combined sizes of the alpha and beta polypeptides add up to only 106 amino acid residues, we conclude that the holochrome mRNA is most probably polycistronic.

Differential expression of photosynthesis genes in R. capsulata results from segmental differences in stability within the polycistronic rxcA transcript

We report that the light-harvesting and reaction center genes in the rxcA locus of R. capsulata are contained within a single operon and that their differential expression results predominantly from marked segmental differences in stability within the polycistronic rxcA transcript. The 3' portion of this transcript is rapidly degraded to give rise to either of two slowly decaying mRNA remnants, both of which encode only the light-harvesting polypeptides. The greater stability of these remnants accounts for nearly all of the difference between the concentrations of the light-harvesting and reaction center proteins. The unstable 3' portion of the transcript is delimited by two alternative stem-and-loop structures, which apparently act as barriers to 3' exoribonucleases and thereby protect the upstream RNA segment. When a DNA fragment containing the rxcA locus was fused to a plasmid promoter and transcribed in E. coli, the long precursor transcript was processed to two short messages of greater stability, as in R. capsulata.