Michèle Rahire

Sequence, evolution and differential expression of the two genes encoding variant small subunits of ribulose bisphosphate carboxylase/oxygenase in Chlamydomonas reinhardtii

We have sequenced the two genes for the small subunit of ribulose bisphosphate carboxylase/oxygenase (Rubisco) in Chlamydomonas reinhardtii and analyzed their expression. The two genes encode variant small subunits that differ by four amino acid residues. Both genes are expressed and each is transcribed into an RNA of distinct size. The accumulation of the two RNAs changes depending on the growth conditions, so the small subunit composition of Rubisco may be expected to differ in response to the environment. The C. reinhardtii small subunit sequence is homologous to those of vascular plants or cyanobacteria, but is longer at the amino terminus and in internal positions. The number and location of the intervening sequences in the genes from C. reinhardtii and from other plants differ. In several cases, internal length differences in the polypeptide coincide with the positions of introns in the coding sequence. Thus, changes in the exon structure of the genes during evolution may have been accompanied by substantial changes in the encoded protein. The translation and splicing signals in C. reinhardtii are similar to those of other eukaryotes, but the transcription signals are less conserved and the highly biased codon usage is very unusual.

Sequence of the chloroplast DNA region of Chlamydomonas reinhardii containing the gene of the large subunit of ribulose bisphosphate carboxylase and parts of its flanking genes

Abstract The transcriptional organization and the sequence of a 4000 base region of the chloroplast genome of Chlamydomonas reinhardii have been determined. The region includes the gene for the large subunit (LS) of ribulose bisphosphate carboxylase and portions of two neighbouring genes X and Y which are oriented in opposite direction relative to the LS gene. The transcripts of the LS, X and Y genes are 1600, 2200 and 2400 bases, respectively. The 5′ untranslated regions of the chloroplast messenger RNAs are variable in size: 91 ± 3 and 430 ± 10 bases for LS and X, respectively. The LS gene codes for a polypeptide of 475 amino acids whose sequence diverges 13 to 14% from the LS amino acid sequence of maize and spinach. The corresponding gene sequences differ 23 to 25% from each other. Most of the nucleotide differences occur in the third position of the codons and in the 3′ terminal portion of the gene. The three catalytic sites and the CO 2 activator region of the LS polypeptide have been highly conserved between C. reinhardii , spinach and maize. Only 40 different codons are used in the LS gene of C. reinhardii . The 5′ upstream regions of the LS and X genes contain sequences which resemble bacterial translational and transcriptional signals. Several repetitive elements are interspersed throughout the A + T-rich spacer between the X and LS genes. The 3′ untranslated region of the LS and Y mRNAs display stem-loop secondary structures which are reminiscent of bacterial terminators.

Herbicide resistance and cross-resistance: changes at three distinct sites in the herbicide-binding protein.

Plants and algae resistant to the commonly used s-triazine herbicides display a wide spectrum of cross-resistance to other herbicides that act in a similar manner. Analysis of uniparental mutants of the green alga Chlamydomonas reinhardi showed that three different amino acid residues in the 32-kilodalton thylakoid membrane protein can be independently altered to produce three different patterns of resistance to s-triazine and urea-type herbicides. These results clarify the molecular basis for herbicide resistance and cross-resistance. Two of the mutations do not alter normal electron transport and thus may have applications of agronomic interest.

Chlamydomonas reinhardii gene for the 32 000 mol. wt. protein of photosystem II contains four large introns and is located entirely within the chloroplast inverted repeat.

The chloroplast psbA gene from the green unicellular alga Chlamydomonas reinhardii has been localized, cloned and sequenced. This gene codes for the rapidly‐labeled 32‐kd protein of photosystem II, also identified as as herbicide‐binding protein. Unlike psbA in higher plants which is found in the large single copy region of the chloroplast genome and is uninterrupted, psbA in C. reinhardii is located entirely within the inverted repeat, hence present in two identical copies per circular chloroplast genome, and contains four large introns. These introns range from 1.1 to 1.8 kb in size and fall into the category of Group I introns. Two of the introns contain open reading frames which are in‐frame with the preceding exon sequences. We present the nucleotide sequence for the C. reinhardii psbA 5′‐and 3′ ‐flanking sequences, the coding region contained in five exons and the deduced amino acid sequence. The algal gene codes for a protein of 352 amino acid residues which is 95% homologous, excluding the last eight amino acid residues, with the higher plant protein.

Determinants for stability of the chloroplast psbD RNA are located within its short leader region in Chlamydomonas reinhardtii.

Stability of the chloroplast psbD mRNA encoding the D2 protein of the photosystem II reaction center is drastically decreased in the nuclear photosynthetic mutant nac2‐26 of Chlamydomonas reinhardtii. Using biolistic transformation and genetic crosses we have introduced chimeric genes consisting of the psbD leader fused to a reporter gene into the chloroplast in both wild‐type and mutant nuclear backgrounds. The chimeric message is destabilized in the latter, but not in the former case, indicating that the 74 nt psbD leader includes one of the target sites for psbD RNA degradation in the absence of wild‐type NAC2 function. Increased instability of the psbD leader in mutant versus wild‐type chloroplast lysates is also demonstrated in vitro and the primary cleavage sites have been mapped. The instability of the psbD RNA in the mutant correlates with the loss of binding of a 47 kDa protein to the psbD leader RNA, suggesting that this factor acts as message stabilizer in wild‐type.

Sequence homology between the 32K dalton and the D2 chloroplast membrane polypeptides of Chlamydomonas reinhardii.

SummaryThe region of the chloroplast genome of Chlamydomonas reinhardii containing the gene of the thylakoid polypeptide D2 (psbD) has been sequenced. A unique open reading frame of 350 codons exists in this region. Because the first ATG is followed 11 codons downstream by a second one, the D2 polypeptide consists of either 339 or 350 amino acids. Comparison of the sequences of D2 and the 32K dalton polypeptides, both of which are associated with photosystem II, reveals partial homology. Although, the overall homology of these two polypeptides is only 27%, they contain several related regions and their hydropathic profiles are strikingly similar. These data suggest that the two polypeptides may have related functions and/or that their genes may have originated from a common ancestor. Alternatively, convergent evolution of these polypeptides may be due to structural constraints in the thylakoid membrane. Limited sequence homology is also observed between the D2 polypeptide and some of the subunits of the reaction centers of photosynthetic bacteria.

Lack of the D2 protein in a Chlamydomonas reinhardtii psbD mutant affects photosystem II stability and D1 expression

D1 and D2, two chloroplast proteins with apparent mol. wt of 32 000‐34 000, play an important role in the photosynthetic reactions mediated by the membrane‐bound protein complex of photosystem II (PSII). We have isolated and characterized an uniparental, non‐photosynthetic mutant of Chlamydomonas reinhardtii and show that the mutation is in the chloroplast gene psbD, coding for D2. A 46 bp direct DNA duplication in the coding region of the mutant gene causes a frame‐shift which results in a psbD transcript coding for 186 amino acid residues instead of the normal 352. The truncated D2 peptide is never seen, even after pulse‐labeling, suggesting that the mutant protein is very unstable. In addition, little or no D1 protein is detected in this mutant although the gene and normal levels of mRNA for D1 are present in mutant cells. All other core PSII proteins are synthesized and inserted into the membrane fraction, but never accumulate. These results suggest that D2 contributes not only to the stabilization of the PSII complex in the membrane, but also may play a specific role in the regulation of the D1 protein, either at the translational or post‐translational level.

Identification of cis-acting RNA leader elements required for chloroplast psbD gene expression in Chlamydomonas.

The psbD mRNA of Chlamydomonas reinhardtii is one of the most abundant chloroplast transcripts and encodes the photosystem II reaction center polypeptide D2. This RNA exists in two forms with 5′ untranslated regions of 74 and 47 nucleotides. The shorter form, which is associated with polysomes, is likely to result from processing of the larger RNA. Using site-directed mutagenesis and biolistic transformation, we have identified two major RNA stability determinants within the first 12 nucleotides at the 5′ end and near position −30 relative to the AUG initiation codon of psbD. Insertion of a polyguanosine tract at position −60 did not appreciably interfere with translation of psbD mRNA. The same poly(G) insertion in the nac2-26 mutant, which is known to be deficient in psbD mRNA accumulation, stabilized the psbD RNA. However, the shorter psbD RNA did not accumulate, and the other psbD RNAs were not translated. Two other elements were found to affect translation but not RNA stability. The first comprises a highly U-rich sequence (positions −20 to −15), and the second, called PRB1 (positions −14 to −11), is complementary to the 3′ end of the 16S rRNA. Changing the PRB1 sequence from GGAG to AAAG had no detectable effect on psbD mRNA translation. However, changing this sequence to CCUC led to a fourfold diminished rate of D2 synthesis and accumulation. When the psbD initiation codon was changed to AUA or AUU, D2 synthesis was no longer detected, and psbD RNA accumulated to wild-type levels. The singular organization of the psbD 5′ untranslated region could play an important role in the control of initiation of psbD mRNA translation.

The chloroplast ycf7 (petL) open reading frame of Chlamydomonas reinhardtii encodes a small functionally important subunit of the cytochrome b6f complex.

The small chloroplast open reading frame ORF43 (ycf7) of the green unicellular alga Chlamydomonas reinhardtii is cotranscribed with the psaC gene and ORF58. While ORF58 has been found only in the chloroplast genome of C.reinhardtii, ycf7 has been conserved in land plants and its sequence suggests that its product is a hydrophobic protein with a single transmembrane alpha helix. We have disrupted ORF58 and ycf7 with the aadA expression cassette by particle‐gun mediated chloroplast transformation. While the ORF58::aadA transformants are indistinguishable from wild type, photoautotrophic growth of the ycf7::aadA transformants is considerably impaired. In these mutant cells, the amount of cytochrome b6f complex is reduced to 25–50% of wild‐type level in mid‐exponential phase, and the rate of transmembrane electron transfer per b6f complex measured in vivo under saturating light is three to four times slower than in wild type. Under subsaturating light conditions, the rate of the electron transfer reactions within the b6f complex is reduced more strongly in the mutant than in the wild type by the proton electrochemical gradient. The ycf7 product (Ycf7) is absent in mutants deficient in cytochrome b6f complex and present in highly purified b6f complex from the wild‐type strain. Ycf7‐less complexes appear more fragile than wild‐type complexes and selectively lose the Rieske iron‐sulfur protein during purification. These observations indicate that Ycf7 is an authentic subunit of the cytochrome b6f complex, which is required for its stability, accumulation and optimal efficiency. We therefore propose to rename the ycf7 gene petL.

A chloroplast gene is required for the light-independent accumulation of chlorophyll in Chlamydomonas reinhardtii.

The light‐independent pathway of chlorophyll synthesis which occurs in some lower plants and algae is still largely unknown. We have characterized a chloroplast mutant, H13, of Chlamydomonas reinhardtii which is unable to synthesize chlorophyll in the dark and is also photosystem I deficient. The mutant has a 2.8 kb deletion as well as other rearrangements of its chloroplast genome. By performing particle gun mediated chloroplast transformation of H13 with defined wild‐type chloroplast DNA fragments, we have identified a new chloroplast gene, chlN, coding for a 545 amino acid protein which is involved in the light‐independent accumulation of chlorophyll, probably at the step of reduction of protochlorophyllide to chlorophyllide. The chlN gene is also found in the chloroplast genomes of liverwort and pine, but is absent from the chloroplast genomes of tobacco and rice.