L. C. D. Gibson

Expression of the chlI, chlD, and chlH Genes from the Cyanobacterium Synechocystis PCC6803 in Escherichia coli and Demonstration That the Three Cognate Proteins Are Required for Magnesium-protoporphyrin Chelatase Activity

Magnesium-protoporphyrin chelatase catalyzes the first step unique to chlorophyll synthesis: the insertion of Mg2+ into protoporphyrin IX. Genes from Synechocystis sp. PCC6803 with homology to the bchI and bchD genes of Rhodobacter sp. were cloned using degenerate oligonucleotides. The function of these genes, putatively encoding subunits of magnesium chelatase, was established by overexpression in Escherichia coli, including the overexpression of Synechocystis chlH, previously cloned as a homolog of the Rhodobacter bchH gene. The combined cell-free extracts were able to catalyze the insertion of Mg2+ into protoporphyrin IX in an ATP-dependent manner and only when the products of all three genes were present. The ChlH, ChlI, and ChlD gene products are therefore assigned to the magnesium chelatase step in chlorophyll a biosynthesis in Synechocystis PCC6803. The primary structure of the Synechocystis ChlD protein reveals some interesting features; the N-terminal half of the protein shows 40-41% identity to Rhodobacter BchI and Synechocystis ChlI, whereas the C-terminal half displays 33% identity to Rhodobacter BchD. This suggests a functional as well as an evolutionary relationship between the “I” and “D” genes.

A Putative Mg Chelatase Subunit from Arabidopsis thaliana cv C24 (Sequence and Transcript Analysis of the Gene, Import of the Protein into Chloroplasts, and in Situ Localization of the Transcript and Protein

We have isolated and sequenced a cDNA from Arabidopsis thaliana cv C24 that encodes a putative Mg chelatase subunit. The deduced amino acid sequence shows a very high level of identity to a gene previously characterized from Antirrhinum majus (olive) and also high similarity to bchH, a bacterial gene involved in the Mg chelatase reaction of bacteriochlorophyll biosynthesis. We suggest that this gene be called CHL H. Northern blot analyses were used to investigate the expression of CHL H, another putative Mg chelatase gene, ch-42, and ferrochelatase. The CHL H transcript was observed to undergo a dramatic diurnal variation, rising almost to its maximum level by the end of the dark period, then increasing slightly at the onset of the light and declining steadily to a minimum by the end of the light period; in contrast, transcripts for ch-42 and ferrochelatase remained constant. A model is proposed in which the CHL H protein plays a role in regulating the levels of chlorophyll during this cycle. In situ hybridization revealed that the transcripts are located over the surface of the chloroplasts, a feature in common with transcripts for the ch-42 gene. The CHL H protein was imported into the stromal compartment of the chloroplast and processed in an in vitro assay. Immunoblotting showed that the distribution of CHL H protein between the stroma and chloroplast membranes varies depending on the concentration of Mg2+. In situ immunofluorescence was used to establish that the CHL H and CH-42 proteins are localized within the chloroplast in vivo.

Cloning, sequencing and functional assignment of the chlorophyll biosynthesis gene, chlP, of Synechocystis sp. PCC 6803

A gene from the cyanobacterium Synechocystis sp. PCC 6803 has been cloned and sequenced, and subsequently used to partially complement a bchP mutant of the purple photosynthetic bacterium Rhodobacter sphaeroides. This mutant is blocked in the terminal hydrogenation steps of bchla biosynthesis and possesses only bchl esterified with geranylgeraniol. It also has a reduced cellular level of the light‐harvesting LH2 complex, and the 850 nm absorbance maximum of LH2 is red‐shifted by approximately 6 nm. Upon heterologous expression of the Synechocystis bchP homologue, not only are hydrogenated forms of bchlaGG detectable, but the level of LH2 is increased and the red‐shift reversed by several nm. We conclude that this gene, which we term chlP, encodes the enzyme catalysing the stepwise hydrogenation of geranylgeraniol to phytol during chla biosynthesis.

The photosynthesis gene cluster of Rhodobacter sphaeroides

The photosynthetic bacteria are at the forefront of the study of many aspects of photosynthesis, including photopigment biosynthesis, photosynthetic-membrane assembly, light-harvesting, and reaction center photochemistry. The facultative growth of some photosynthetic bacteria, their simple photosystems, and their ease of genetic manipulation have all contributed to advances in these areas. Amongst these bacteria, the purple non-sulfur bacterium Rhodobacter sphaeroides has emerged as, arguably, the leading contender for a model system in which to integrate the studies of all the different aspects of the assembly and function of the photosynthetic apparatus. Many of the genes encoding photosynthesis-related proteins are known to be clustered within a small region of the genome in this organism. As a further aid to studying the assembly and function of the photosystem of Rb. sphaeroides, the DNA sequence for a genomic segment containing this photosynthesis gene cluster (PGC) has been assembled from previous EMBL submissions and formerly unpublished data. The Rb. sphaeroides PGC is 40.7 kb in length and consists of 38 open reading frames encoding the reaction center H, L and M subunits, the α and β polypeptides of the light-harvesting I (B875) complex, and the enzymes of bacteriochlorophyll and carotenoid biosynthesis. PGCs are a feature of gene organization in several photosynthetic bacteria, and the similarities between the clusters of Rb. sphaeroides and Rb. capsulatus have been apparent for some time. Here we present the first comprehensive analysis of the PGC of Rb. sphaeroides, as well as a comparison with that of Rb. capsulatus.

Magnesium chelatase from Rhodobacter sphaeroides: initial characterization of the enzyme using purified subunits and evidence for a BchI-BchD complex.

The enzyme magnesium-protoporphyrin IX chelatase (Mg chelatase) catalyses the insertion of Mg into protoporphyrin IX, the first committed step in (bacterio)chlorophyll biosynthesis. In the photosynthetic bacterium Rhodobacter sphaeroides, this reaction is catalysed by the products of the bchI, bchD and bchH genes. These genes have been expressed in Escherichia coli so that the BchI, BchD and BchH proteins are produced with N-terminal His6 affinity tags, which has led to the production of large amounts of highly purified, highly active Mg chelatase subunits from a single chromatography step. Furthermore, BchD has been purifed free of contamination with the chaperone GroEL, which had proven to be a problem in the past. BchD, present largely as an insoluble protein in E. coli, was purified in 6 M urea and refolded by addition of BchI, MgCl2 and ATP, yielding highly active protein. BchI/BchD mixtures prepared in this way were used in conjunction with BchH to determine the kinetic parameters of R. sphaeroides Mg chelatase for its natural substrates. We have been able to demonstrate for the first time that BchI and BchD form a complex, and that Mg2+ and ATP are required to establish and maintain this complex. Gel filtration data suggest that BchI and BchD form a complex of molecular mass 200 kDa in the presence of Mg2+ and ATP. Our data suggest that, in vivo, BchD is only folded correctly and maintained in its correct conformation in the presence of BchI, Mg2+ and ATP.

The bacteriochlorophyll biosynthesis gene, bchM, of Rhodobacter sphaeroides encodes S-adenosyl-L-methionine: Mg protoporphyrin IX methyltransferase

The bchM gene of Rhodobacter sphaeroides has been sequenced and then overexpressed in E. coli producing a protein of M r approximately 27,500. Cell‐free extracts of the transformed E. coli strain are able to methylate added Mg protoporphyrin, resulting in the formation of Mg protoporphyrin monomethyl ester. The identity of this product was verified by HPLC. The bchM gene product is therefore assigned to the methyltransferase step in bacteriochlorophyll biosynthesis.

Introduction of a new branchpoint in tetrapyrrole biosynthesis in Escherichia coli by co‐expression of genes encoding the chlorophyll‐specific enzymes magnesium chelatase and magnesium protoporphyrin methyltransferase

The genes encoding the three Mg chelatase subunits, ChlH, ChlI and ChlD, from the cyanobacterium Synechocystis PCC6803 were all cloned in the same pET9a‐based Escherichia coli expression plasmid, forming an artificial chlH‐I‐D operon under the control of the strong T7 promoter. When a soluble extract from IPTG‐induced E. coli cells containing the pET9a‐ChlHID plasmid was assayed for Mg chelatase activity in vitro, a high activity was obtained, suggesting that all three subunits are present in a soluble and active form. The chlM gene of Synechocystis PCC6803 was also cloned in a pET‐based E. coli expression vector. Soluble extract from an E. coli strain expressing chlM converted Mg‐protoporphyrin IX to Mg‐protoporphyrin monomethyl ester, demonstrating that chlM encodes the Mg‐protoporphyrin methyltransferase of Synechocystis. Co‐expression of the chlM gene together with the chlH‐I‐D construct yielded soluble protein extracts which converted protoporphyrin IX to Mg‐protoporphyrin IX monomethyl ester without detectable accumulation of the Mg‐protoporphyrin IX intermediate. Thus, active Mg chelatase and Mg‐protoporphyrin IX methyltransferase can be coupled in E. coli extracts. Purified ChlI, ‐D and ‐H subunits in combination with purified ChlM protein were subsequently used to demonstrate in vitro that a molar ratio of ChlM to ChlH of 1 to 1 results in conversion of protoporphyrin IX to Mg‐protoporphyrin monomethyl ester without significant accumulation of Mg‐protoporphyrin.