Synthesis and assembly of bacterial and higher plant Rubisco subunits in Escherichia coli

The synthesis in Escherichia coli of both the large and small subunits of cereal ribulose bisphosphate carboxylase/oxygenase has been obtained using expression plasmids and bacteriophages. The level and order of synthesis of the large and small subunits were regulated using different promoters, resulting in different subunit pool sizes and ratios that could be controlled in attempts to optimize the conditions for assembly. Neither assembly nor enzyme activity were observed for the higher plant enzyme. In contrast, cyanobacterial large and small subunits can assemble to give an active holoenzyme in Escherichia coli. By the use of deletion plasmids, followed by infection with appropriate phages, it can be demonstrated that the small subunit is essential for catalysis. However, the small subunit is not required for the assembly of a large subunit octomer core in the case of the Synechococcus enzyme; self-assembly of the octomer will occur in an rbcS deletion strain. The cyanobacterial small subunits can be replaced by wheat small subunits to give an active enzyme in Escherichia coli. The hybrid cyanobacterial large/wheat small subunit enzyme has only about 10% of the level of activity of the wild-type enzyme, reflecting the incomplete saturation of the small subunit binding sites on the large subunit octomer, and possibly a mismatch in the subunit interactions of those small subunits that do bind, giving rise to a lower rate of turnover at the active sites.Abbreviations IPTG isopropyl--D-thiogalactopyranoside - L large subunit - Rubisco ribulose bisphosphate carboxylase/oxygenase - S small subunit     

Cytoplasmic ribosomal proteins from Chlamydomonas reinhardtii: characterization and immunological comparisons

Summary Experiments were undertaken to characterize the cytoplasmic ribosomal proteins (r-proteins) in Chlamydomonas reinhardtii and to compare immunologically several cytoplasmic r-proteins with those of chloroplast ribosomes of this alga, Escherichia coli, and yeast. The large and small subunits of the C. reinhardtii cytoplasmic ribosomes were shown to contain, respectively, 48 and 45 r-proteins, with apparent molecular weights of 12,000–59,000. No cross-reactivity was seen between antisera made against cytoplasmic r-proteins of Chlamydomonas and chloroplast r-proteins, except in one case where an antiserum made against a large subunit r-protein cross-reacted with an r-protein of the small subunit of the chloroplast ribosome. Antisera made against one out of five small subunit r-proteins and three large subunit r-proteins recognized r-proteins from the yeast large subunit. Each of the yeast r-proteins has been previously identified as an rRNA binding protein. The antiserum to one large subunit r-protein cross-reacted with specific large subunit r-proteins from yeast and E. coli.     

Differences in amino acid sequence of the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase from two species of Dasycladaceae

In contrast to other plants the plastid genome of Acetabularia is larger in size and shows a high degree of variability. This study on the chloroplast-encoded large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase demonstrates that strongly conserved areas also exist in the plastid genome of the Dasycladaceae. Searching for differences in the amino acid sequence of the large subunit from Acetabularia mediterranea and Acicularia schenckii, proteolytic peptides which differ in their elution behaviour in reverse-phase high-performance liquid chromatography were sequenced. Only six amino acids were found to be exchanged in the large subunit from these two species. Since these two species diverged approx. 150 million years ago, these results imply that 0.84 amino-acid exchanges per 100 amino acids have occurred in 10⁸ years, underlining the strong conservatism of the large subunit.Abbreviations A Acetabularia mediterranea - Ac. Acicularia schenckii - HPLC high-performance liquid chromatography - LSU large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase - PAGE polyacrylamide gel electrophoresis - RuBPCase ribulose-1,5-bisphosphate carboxylase/oxygenase - SDS sodium dodecyl sulfate     

Differentiation of Fraction 1 protein in relation to age and distribution of Angiosperm groups

Fraction 1 protein (F-1-protein) (ribulose bisphosphate carboxy-lase-oxygenase) contained inLemnaceae has been evolving for at least 50 million years because fossils of these plants have been identified in strata belonging to the Upper Cretaceous. Electrofocusing F-1-protein resolves the large subunit polypeptides coded by extranuclear DNA and the small subunit polypeptides coded by nuclear DNA. Four differences affecting isoelectric points of the large subunit polypeptides and eight affecting the small subunit polypeptides are now present among eleven species representing the four genera comprising theLemnaceae. In comparison, four differences in the large and 13 in the small subunit polypeptides exist among 63 species ofNicotiana; four differences in the large and eight differences in the small subunit polypeptides exist among 19 species ofGossypium. The number of differences in F-1-protein composition being of the same order of magnitude for the generaNicotiana, Gossypium, and the familyLemnaceae, we infer that these Angiosperms are of similar antiquity. Nicotiana species indigenous to Australia and Africa contain F-1-proteins whose large subunit polypeptides are different but some of whose small subunit polypeptides are like those found in species from the Western Hemisphere. The same situation is found for the F-1-protein inGossypium. These results are in harmony with the view that species ofNicotiana andGossypium have arrived in Australia via former land connections between S. America, Antarctica, and Australia.     

Mapping of the ADP-glucose pyrophosphorylase genes in barley

cDNA probes encoding the barley endosperm ADP-glucose pyrophosphorylase (AGP) small subunit (bepsF2), large subunit (bepl10), and leaf AGP large subunit (blpl) were hybridized with barley genomic DNA blots to determine copy number and polymorphism. Probes showing polymorphism were mapped on a barley RFLP map. Probes that were not polymorphic were assigned to chromosome arms using wheat-barley telosomic addition lines. The data suggested the presence of a single-copy gene corresponding to each of the cDNA probes. In addition to the major bands, several weaker cross-hybridizing bands indicated the presence of other, related sequences. The weaker bands were specific to each probe and were not due to cross-hybridization with the other probes examined here. The endosperm AGP small subunit (bepsF2) majorband locus was associated with chromosome 1P and designated Aga1. The endosperm AGP large subunit (bepl10) major-band locus was mapped to chromosome 5M and designated Aga7. The endosperm AGP large-subunit minor bands were not mapped. The leaf AGP large-subunit major band was associated with chromosome 7M and designated Aga5. One of the leaf AGP large-subunit minor bands was mapped to chromosome 5P and designated Aga6. A clone for the wheat endosperm AGP large-subunit (pAga7) hybridized to the same barley genomic DNA bands as the corresponding barley probe indicating a high degree of identity between the two probes.     

How to avoid undesirable interactions during ribosome assembly?

Ribosome subunit assembly in bacteria is assisted by several non‐ribosomal proteins, the absence of which leads to assembly defects. The two DEAD‐box RNA helicases SrmB and DeaD/CsdA are required for efficient assembly of the ribosome large subunit, in particular at low temperature, but their sites of action on rRNA were not known until now. In this issue of Molecular Microbiology, Proux et al. show that SrmB acts far away from its tethering site on the assembly intermediate particle. A genetic screen identified mutations in complementary sequences of 23S and 5S rRNA that help to bypass SrmB deficiency, partially correcting the large subunit assembly defect. The results suggest that 5S rRNA and 23S rRNA can interact via base‐pairing, forming a non‐native structure that needs to be corrected. The authors discuss attractive hypotheses on SrmB acts during large subunit assembly.     

Plant-like substitutions in the large-subunit carboxy terminus of <Emphasis Type="Italic">Chlamydomonas</Emphasis> Rubisco increase CO<Subscript>2</Subscript>/O<Subscript>2</Subscript> Specificity

Background  

Ribulose-1,5-bisphosphate is the rate-limiting enzyme in photosynthesis. The catalytic large subunit of the green-algal enzyme from Chlamydomonas reinhardtii is ~90% identical to the flowering-plant sequences, although they confer diverse kinetic properties. To identify the regions that may account for species variation in kinetic properties, directed mutagenesis and chloroplast transformation were used to create four amino-acid substitutions in the carboxy terminus of the Chlamydomonas large subunit to mimic the sequence of higher-specificity plant enzymes.     

Organization of the mitochondrial genome of <Emphasis Type="Italic">Fusarium oxysporum</Emphasis> (anamorphic Hypocreales)

A 33.4-kb fragment of the mitochondrial genome of Fusarium oxysporum has been sequenced. The fragment contains the complete gene sequences for 13 of the 14 proteins typically encoded by the mitochondrial genome of filamentous ascomycetes. Similarity searching revealed all encoded proteins to be most similar to those from other members of the Hypocreales. The fragment contains the complete small subunit rRNA gene, partial large rRNA subunit gene, and 12 tRNAs. Two introns were present, one in the nad5 gene and one in the large rRNA subunit gene, the latter containing a ribosomal protein gene.     

Selection in Bacillus subtilis giving rise to strains with mutational alterations in a variety of ribosomal proteins

Summary To facilitate mapping of ribosomal protein genes in Bacillus subtilis, a selection was devised which gave rise to strains with alterations in any one of a variety or ribosomal proteins. Alterations in eighteen ribosomal proteins were identified when eighty mutants were analysed. In addition, one strain showed a major assembly defect in the large ribosomal subunit resulting in the presence of a particle sedimenting at about 40S. Eighteen large subunit proteins were present on this particle in normal amounts, while twelve proteins were much reduced in amount or undetectible.     

Heterologous expression of heterodimeric laccase from Pleurotus ostreatus in Kluyveromyces lactis

Among the laccases produced by the white-rot fungus Pleurotus ostreatus, there are two closely related atypical isoenzymes, POXA3a and POXA3b. These isoenzymes are endowed with quaternary structure, consisting of two subunits very different in size. The POXA3 large subunit is clearly homologous to other known laccases, while the small subunit does not show significant homology with any protein in data banks. To investigate on the singular structure of the POXA3 complex, a new system for recombinant expression of heterodimer proteins in the yeast Kluyveromyces lactis has been set up. A unique expression vector has been used and the cDNAs encoding the two subunits have been cloned under the control of the same bi-directionally acting promoter. Expression of the large subunit alone and co-expression of both subunits in the same host have been demonstrated and the properties of the recombinant proteins have been compared. Clones expressing the large subunit alone exhibited always notably lower activity than those expressing both subunits. In addition to the activity increase, the presence of the small subunit led to a significant increase of laccase stability. Therefore, a role of the small subunit in POXA3 stabilisation is suggested.     

The Origin of Red Algae and Cryptomonad Nucleomorphs: A Comparative Phylogeny Based on Small and Large Subunit rRNA Sequences ofPalmaria palmata, Gracilaria verrucosa,and theGuillardia thetaNucleomorph

The complete large subunit rRNA sequences from the red algaePalmaria palmataandGracilaria verrucosa,and from the nucleomorph of the cryptomonadGuillardia theta,were determined in order to assess their phylogenetic relationships relative to each other and to other eukaryotes. Neighbor-joining, maximum-parsimony, and maximum-likelihood trees were constructed on the basis of small subunit rRNA, large subunit rRNA, and a combination of both molecules. Our results support the hypothesis that the cryptomonad plastid is derived from a primitive red alga, in that an ancient common ancestor of rhodophytes and cryptomonad nucleomorphs is indicated. This cluster shows some affinity with chlorobionts, which could point to a monophyletic origin of green and red plastids. However, the exact branching order of the crown eukaryotes remains uncertain and further research is required.     

Transcription profiles of hydrogenases related genes in the cyanobacterium Lyngbya majuscula CCAP 1446/4

Background  

Lyngbya majuscula CCAP 1446/4 is a N₂-fixing filamentous nonheterocystous strain that contains two NiFe-hydrogenases: an uptake (encoded by hupSL) and a bidirectional enzyme (encoded by hoxEFUYH). The biosynthesis/maturation of NiFe-hydrogenases is a complex process requiring several accessory proteins for e.g. for the incorporation of metals and ligands in the active center (large subunit), and the insertion of the FeS clusters (small subunit). The last step in the maturation of the large subunit is the cleavage of a C-terminal peptide from its precursor by a specific endopeptidase. Subsequently, the mature large and small subunits can assemble forming a functional enzyme.     

Electrophoretic and immunological comparisons of chloroplast and prokaryotic ribosomal proteins reveal that certain families of large subunit proteins are evolutionarily conserved

Summary Antibodies to individual chloroplast ribosomal (r-)proteins ofChlamydomonas reinhardtii synthesized in either the chloroplast or the cytoplasm were used to examine the relatedness ofChlamydomonas r-proteins to r-proteins from the spinach (Spinacia oleracea) chloroplast,Escherichia coli, and the cyanobacteriumAnabaena 7120. In addition,³⁵S-labeled chloroplast r-proteins from large and small subunits ofC. reinhardtii were coelectrophoresed on 2-D gels with unlabeled r-proteins from similar subunits of spinach chloroplasts,E. coli, andAnabaena to compare their size and net charge. Comigrating protein pairs were not always immunologically related, whereas immunologically related r-protein pairs often did not comigrate but differed only slightly in charge and molecular weight. In constrast, when³⁵S-labeled chloroplast r-proteins from large and small subunits of a closely related speciesC. smithii were coelectrophoresed with unlabeledC. reinhardtii chloroplast r-proteins, only one pair of proteins from each subunit showed a net displacement in mobility.Analysis of immunoblots of one-dimensional SDS and two-dimensional urea/SDS gels of large and small subunit r-proteins from these species revealed more antigenic conservation among the four species of large subunit r-proteins than small subunit r-proteins.Anabaena r-proteins showed the greatest immunological similarity toC. reinhardtii chloroplast r-proteins. In general, antisera made against chloroplast-synthesized r-proteins inC. reinhardtii showed much higher levels of cross-reactivity with r-proteins fromAnabaena, spinach, andE. coli than did antisera to cytoplasmically synthesized r-proteins. All spinach r-proteins that cross-reacted with antisera to chloroplast-synthesized r-proteins ofC. reinhardtii are known to be made in the chloroplast (Dorne et al. 1984b). FourE. coli r-proteins encoded by the S10 operon (L2, S3, L16, and L23) were found to be conserved immunologically among the four species. Two of the large subunit r-proteins, L2 and L16, are essential for peptidyltransferase activity. The third (L23) and two otherE. coli large subunit r-proteins (L5 and L27) that have immunological equivalents among the four species are functionally related to but not essential for peptidyltransferase activity.     

Independent localization and regulation of carbamyl phosphate synthetase A polypeptides of Neurospora crassa

Summary Carbamyl phosphate synthetase A is a two-polypeptide, mitochondrial enzyme of arginine synthesis in Neurospora. The large subunit is encoded in the arg-3 locus and can catalyze formation of carbamyl-P with ammonia as the N donor. The small subunit is encoded in the unlinked arg-2 locus and imparts to the holoenzyme the ability to use glutamine, the biological substrate, as the N donor. By using nonsense mutations of arg-3, it was shown that the small subunit of the enzyme enters the mitochrondrion independently and is regulated in the same manner as it is in wild type. Similarly, arg-2 mutations, affecting the small subunit, have no effect on the localization or the regulation of the large subunit. The two subunits are regulated differently. Like most polypeptides of the pathway, the large subunit is not repressible and derepresses 3- to 5-fold upon argininestarvation of mycelia. In contrast, the glutamine-dependent activity of the holoenzyme is fully repressible and has a range of variation of over 100-fold. In keeping with this behavior, it is shown here that the small polypeptide, as visualized on two-dimensional gels, is also fully repressible. We conclude that the two subunits of the enzyme are localized independently, controlled independently and over different ranges, and that aggregation kinetics cannot alone explain the unusual regulatory amplitude of the native, two-subunit enzyme. The small subunit molecular weight was shown to be approximately 45,000.     

Frankia KB5 Possesses a Hydrogenase Immunologically Related to Membrane-Bound [NiFe]-Hydrogenases

The immunological relationship of the hydrogenase in Frankia KB5 to hydrogenases in other microorganisms was investigated using antisera raised against holo-[NiFe]-hydrogenases isolated from Alcaligenes latus, Azotobacter vinelandii, Ralstonia eutropha, and the small and large hydrogenase subunits from Bradyrhizobium japonicum. The antisera raised against the A. latus, R. eutropha, and B. japonicum (large subunit) polypeptides were found to recognize two polypeptides, corresponding to the unprocessed and processed forms of the hydrogenase subunit in Frankia KB5. None of the antisera, including the antibodies produced against the small hydrogenase subunit isolated from B. japonicum, recognized any polypeptide related to the small hydrogenase subunit in Frankia KB5. An immunogold localization study of the intracellular distribution of hydrogenase in Frankia KB5, with the cryo-section technique, showed that labeling in the membrane of both hyphae and vesicles was positively correlated with hydrogenase activity. Received: 6 November 2000 / Accepted: 18 December 2000     

Cloning and sequencing of the genes encoding the large and the small subunits of the H2 uptake hydrogenase (hup) of Rhodobacter capsulatus

Summary The structural genes (hup) of the H₂ uptake hydrogenase of Rhodobacter capsulatus were isolated from a cosmid gene library of R. capsulatus DNA by hybridization with the structural genes of the H₂ uptake hydrogenase of Bradyrhizobium japonicum. The R. capsulatus genes were localized on a 3.5 kb HindIII fragment. The fragment, cloned onto plasmid pAC76, restored hydrogenase activity and autotrophic growth of the R. capsulatus mutant JP91, deficient in hydrogenase activity (Hup^-). The nucleotide sequence, determined by the dideoxy chain termination method, revealed the presence of two open reading frames. The gene encoding the large subunit of hydrogenase (hupL) was identified from the size of its protein product (68108 dalton) and by alignment with the NH₂ amino acid protein sequence determined by Edman degradation. Upstream and separated from the large subunit by only three nucleotides was a gene encoding a 34 256 dalton polypeptide. Its amino acid sequence showed 80% identity with the small subunit of the hydrogenase of B. japonicum. The gene was identified as the structural gene of the small subunit of R. capsulatus hydrogenase (hupS). The R. capsulatus hydrogenase also showed homology, but to a lesser extent, with the hydrogenase of Desulfovibrio baculatus and D. gigas. In the R. capsulatus hydrogenase the Cys residues, (13 in the small subunit and 12 in the large subunit) were not arranged in the typical configuration found in [4Fe–4S] ferredoxins.     

The ribosomal components responsible for kasugamycin dependence, and its suppression, in a mutant of Escherichia coli

Summary The phenotype of a kasugamycin dependent mutant, MV17, was found to be the product of a kasugamycin resistance mutation in ksgA, together with a dependentizing mutation in rplW, the gene for large ribosomal subunit protein L23. Revertants from dependence on this small subunit targeted antibiotic were found to have mutational alterations in ribosomal proteins L23, L1, L11, and S9. The mutations causing alterations in L1 and L23 were shown to be responsible for the reversion and that altering L11 to be involved in the reversion.     

The cytoplasmic ribosomes of Chlamydomonas reinhardtii: characterization of antibiotic sensitivity and cycloheximide-resistant mutants

Summary In vitro protein synthesis was used to characterize the antibiotic sensitivity of cytoplasmic ribosomes from wild-type and antibiotic-resistant strains of Chlamydomonas reinhardtii. Cytoplasmic ribosomes from two cycloheximide-resistant mutants, act-1 and act-2, were resistant to the antibiotic in vitro. The alteration effected by the act-1 mutation, which was dominant in diploids, was localized to the large subunit of the cytoplasmic ribosomes, but no ribosomal protein alterations were detected using two-dimensional gel electrophoresis. The act-2 mutation, which was semidominant in diploids, was frequently associated with a charge alteration in the large subunit ribosomal protein (r-protein) cyL38 that segregated independently from the antibiotic-resistant phenotype in crosses.     

DNA sequence and secondary structures of the large subunit rRNA coding regions and its two class I introns of mitochondrial DNA fromPodospora anserina

Summary DNA sequence analysis has shown that the gene coding for the mitochondrial (mt) large subunit ribosomal RNA (rRNA) fromPodospora anserina is interrupted by two class I introns. The coding region for the large subunit rRNA itself is 3715 bp and the two introns are 1544 (r1) and 2404 (r2) bp in length. Secondary structure models for the large subunit rRNA were constructed and compared with the equivalent structure fromEscherichia coli 23S rRNA. The two structures were remarkably similar despite an 800-base difference in length. The additional bases in theP. anserina rRNA appear to be mostly in unstructured regions in the 3 part of the RNA. Secondary structure models for the two introns show striking similarities with each other as well as with the intron models from the equivalent introns inSaccharomyces cerevisiae, Neurospora crassa, andAspergillus nidulans. The long open reading frames in each intron are different from each other, however, and the nucleotide sequence similarity diverges as it proceeds away from the core structure. Each intron is located within regions of the large subunit rRNA gene that are highly conserved in both sequence and structure. Computer analysis showed that the open reading frame for intron r1 contained a common maturase-like polypeptide. The open reading frames of intron r2 apeared to be chimeric, displaying high sequence similarity with the open reading frames in the r1 and ATPase 6 introns ofN. crassa.