The plastid aldolase gene fromChlamydomonas reinhardtii: Intron/exon organization, evolution, and promoter structure

Pelzer-Reith, Birgit; Freund, Susanne; Schnarrenberger, Claus; Yatsuki, H.; Hori, Katsuji

doi:10.1007/bf02191648

Cited by 9 publications

(5 citation statements)

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“…Comparing several cytosol to chloroplast stroma transit peptides of nuclear‐encoded chloroplast preproteins in C. reinhardtii and their secondary‐structure predictions using the Rost–Sander method [31–34](Fig. 1[35–55]), we have selected a cTP that exhibits minimal sequence homology with the previously studied ferredoxin cTP [2], and shows the lowest level of reliability in terms of secondary‐structure prediction. The conformational properties of this peptide were investigated using CD and NMR methods to identify possible masked structural features shared with the previously studied ferredoxin cTP [2].…”

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confidence: 99%

“…A lower case h indicates only a loose helix prediction with a reliability index 3–4. Ferredoxin, ferredoxin precursor [35,36]; γATPase, γ chain of ATP synthase [37]; b6f, cytochrome b6f complex 4‐kDa subunit [38]; CAB L1818, chlorophyll A‐B‐binding protein L1818 [39]; F1,6BPA, fructose bisphosphate aldolase () [40,41]; FNR, ferredoxin NADPH reductase () [42]; G3PDH, glyceraldehyde‐3‐phosphate dehydrogenase [43]; MDH NAD, NAD‐dependent malate dehydrogenase (GenBank locus CRU40465, accession number ); PRK, phosphoribulokinase [44]; PSI D, photosystem I reaction center subunit II (photosystem I 20‐kDa protein) [45]; PSI SUIV (E), photosystem I reaction center subunit IV (photosystem I 8.1‐kDa protein) [46]; PSI SUV (G), photosystem I reaction center subunit V (light‐harvesting complex I 10‐kDa protein) [47]; PSI SUVI (H), photosystem I reaction center subunit VI (light‐harvesting complex I 11‐kDa protein) [47]; PSI SUX (K), photosystem I reaction center subunit X (light‐harvesting complex I 8.4‐kDa protein) [47]; Rieske, cytochrome b6f complex iron‐sulfur subunit (Rieske iron‐sulfur protein) [48]; Rubisco Act, ribulose bisphosphate carboxylase/oxygenase activase ([49]; this study); Rubisco , ribulose bisphosphate carboxylase small chain 1 [50,51]; SBPase, sedoheptulose 1,7‐bisphosphatase [52]; Thi, thioredoxin m Ch2 [53–55].…”

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confidence: 99%

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A coil–helix instead of a helix–coil motif can be induced in a chloroplast transit peptide from Chlamydomonas reinhardtii

Krimm

Gans

Hernandez

et al. 1999

European Journal of Biochemistry

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A synthetic peptide MQVTMKSSAVSGQRVGGARVATRSVRRAQLQV corresponding to the 32 amino acid chloroplast transit sequence of the ribulose bisphosphatase carboxylase/oxygenase activase preprotein from Chlamydomonas reinhardtii, required for translocation through the envelope of the chloroplast, has been characterized structurally using CD and NMR under the same experimental conditions as used previously for the 32 amino acid presequence of preferredoxin from the same organism [Lancelin, J.-M., Bally, I., Arlaud, G. J., Blackledge, M., Gans, P., Stein, M. & Jacquot, J.-P. (1994) FEBS Lett. 343, 261±266]. The peptide is found to undergo a conformational transition in aqueous 2,2,2-trifluoroethanol, characterized by three turns of amphiphilic a-helix in the C-terminal region preceded by a disordered coil in the N-terminal region. Compared with the preferredoxin transit peptide, the helical and coiled domains are arranged in the reverse order along the peptide sequence, but the positively charged groups are distributed analogously as well as the hydrophobic residues within the amphiphilic a-helix. It is proposed that such coil±helix or helix±coil motifs, occasionally repeated, could be an intrinsic structural feature of chloroplastic transit peptides, adapted to the proper translocase and possibly to each nuclear-encoded chloroplast preproteins. This feature may distinguish chloroplastic transit sequences from the other organelle-targeting peptides in the eukaryotic green alga C. reinhardtii, particularly the mitochondrial transit sequences.Keywords: Chlamydomonas reinhardtii; chloroplast preproteins; NMR; peptide conformation; transit peptide.An extraordinary diversity is the characteristic of transit sequences attached to the N-terminus of nuclear-encoded mitochondrial preproteins in eukaryotes, particularly the nuclear-encoded chloroplast preproteins in plants. The preproteins are expressed in the cytosol from a nuclear gene and have to be addressed and translocated to the proper organelles where they are matured in their native forms. The variability of the transit presequences, both in terms of peptide length and amino acid sequence, precluded recognition of any consensus sequence and yielded only loose secondary-structure predictions from the peptide sequences [1]. We have previously reported NMR structural studies of a synthetic chloroplast transit peptide (cTP) [2] and a mitochondrial transit peptide (mTP) [3] originating from the same photosynthetic organism, the green alga Chlamydomonas reinhardtii. In agreement with several other studies [4±12], both types of transit peptides exhibit a significant propensity to form amphiphilic helices when they are mixed with either lipids or amphipathic solvents such as 2,2,2-trifluoroethanol (TFE). These coil-to-helix transitions can be observed using far-UV CD and solution NMR.It was found that, in C. reinhardtii, the mTP can be characterized in 65% aqueous TFE as fully helical with two short amphiphilic a-helices with their hydrophobic sectors in discontinuity along the he...

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A coil–helix instead of a helix–coil motif can be induced in a chloroplast transit peptide from Chlamydomonas reinhardtii

Krimm

Gans

Hernandez

et al. 1999

European Journal of Biochemistry

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“…Both the existence of an upstream stop codon in frame with the ATG initiation site, and the correlation between predicted and observed protein size by Western blot analysis (see below), indicate that the cDNAs are full‐length clones and encode the entire protein. Two putative CAAT‐boxes are present in the 5′‐flanking region and the 3′ untranslated region (UTR) contains three putative polyadenylation signals specific for C. reinhardtii (Pelzer‐Reith et al. , 1995; Silflow, 1998).…”

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confidence: 99%

Two adjacent nuclear genes are required for functional complementation of a chloroplast trans‐splicing mutant from Chlamydomonas reinhardtii

et al. 2005

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SummaryThe chloroplast tscA gene from Chlamydomonas reinhardtii encodes a co-factor RNA that is involved in transsplicing of exons 1 and 2 of the psaA mRNA encoding a core polypeptide of photosystem I. Here we provide molecular and genetic characterization of the trans-splicing mutant TR72, which is defective in the 3¢-end processing of the tscA RNA and consequently defective in splicing exons 1 and 2 of the psaA mRNA. Using genomic complementation, two adjacent nuclear genes were identified, Rat1 and Rat2, that are able to restore the photosynthetic growth of mutant TR72. Restoration of the photosynthesis phenotype, however, was successful only with a DNA fragment containing both genes, while separate use of the two genes did not rescue the wild-type phenotype. This was further confirmed by using a set of 10 gene derivatives in complementation tests. The deduced amino acid sequence of Rat1 shows significant sequence homology to the conserved NAD þ -binding domain of poly(ADP-ribose) polymerases of eukaryotic organisms. However, mutagenesis of conserved residues in this putative NAD þ -binding domain did not reveal any effect on restoration efficiency. Immunodetection analyses with enriched fractions of chloroplast proteins indicated that Rat1 is associated with chloroplast membranes. Using the yeast three-hybrid system, we were able to demonstrate the specific binding of tscA RNA by the Rat1 polypeptide. We propose that the two nuclear factors Rat1 and Rat2 are involved in processing of chloroplast tscA RNA and in subsequent splicing of psaA exons 1 and 2.

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“…In animals, only type-! FBAs are 189 known, whereas fungi appear to rely solely on FBA IT enzymes [5). Red algae and glaucocystophytes may possess type-IT FBAs in their cytosol and type-I FBAin their plastids [6], while land plants only possess class I enzymes in plastids and cytosol.…”

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“…( 4 ) Some proteins such as some nuclear components do not possess recognizable transport signals, because their transport involves their binding to and piggybacking on proteins dlat are actively in1ported into the organelle [18). (5) There are examples of fusion proteins which contain the amino acid sequence of two enzymes fused to each other; here theN-terminal enzyme usual!J de.lines the inttaceliLLiar localization [19,20).…”

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confidence: 99%

Deducing Intracellular Distributions of Metabolic Pathways from Genomic Data

Gruber

Kroth

2013

Methods in Molecular Biology

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In the recent years, a large number of genomes from a variety of different organisms have been sequenced. Most of the sequence data has been publicly released and can be assessed by interested users. However, this wealth of information is currently underexploited by scientists not directly involved in genome annotation. This is partially because sequencing, assembly, and automated annotation can be done much faster than the identification, classification, and prediction of the intracellular localization of the gene products. This part of the annotation process still largely relies on manual curation and addition of contextual information. Users of genome databases who are unfamiliar with the types of data available from (whole) genomes might therefore find themselves either overwhelmed by the vast amount and multiple layers of data or dissatisfied with less-than-meaningful analyses of the data.In this chapter we present procedures and approaches to identify and characterize gene models of enzymes involved in metabolic pathways based on their similarity to known sequences. Furthermore we describe how to predict the subcellular location of the proteins using publicly available prediction servers and how to interpret the obtained results. The strategies we describe are generally applicable to organisms with primary plastids such as land plants or green algae. Additionally, we describe strategies suitable for those groups of algae with secondary plastids (for instance diatoms), which are characterized by a different cellular topology and a larger number of intracellular compartments compared to plants.

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The plastid aldolase gene fromChlamydomonas reinhardtii: Intron/exon organization, evolution, and promoter structure

Cited by 9 publications

References 44 publications

A coil–helix instead of a helix–coil motif can be induced in a chloroplast transit peptide from Chlamydomonas reinhardtii

A coil–helix instead of a helix–coil motif can be induced in a chloroplast transit peptide from Chlamydomonas reinhardtii

Two adjacent nuclear genes are required for functional complementation of a chloroplast trans‐splicing mutant from Chlamydomonas reinhardtii

Deducing Intracellular Distributions of Metabolic Pathways from Genomic Data

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