Molecular characterization and evolution of sequences encoding light-harvesting components in the chromatically adapting cyanobacterium Fremyella diplosiphon

Responding to light signals: a comprehensive update on photomorphogenesis in cyanobacteria

Cyanobacteria are ancestors of chloroplast and perform oxygen-evolving photosynthesis similar to higher plants and algae. However, an obligatory requirement of photons for their growth results in the exposure of cyanobacteria to varying light conditions. Therefore, the light environment could act as a signal to drive the developmental processes, in addition to photosynthesis, in cyanobacteria. These Gram-negative prokaryotes exhibit characteristic light-dependent developmental processes that maximize their fitness and resource utilization. The development occurring in response to radiance (photomorphogenesis) involves fine-tuning cellular physiology, morphology and metabolism. The best-studied example of cyanobacterial photomorphogenesis is chromatic acclimation (CA), which allows a selected number of cyanobacteria to tailor their light-harvesting antenna called phycobilisome (PBS). The tailoring of PBS under existing wavelengths and abundance of light gives an advantage to cyanobacteria over another photoautotroph. In this work, we will provide a comprehensive update on light-sensing, molecular signaling and signal cascades found in cyanobacteria. We also include recent developments made in other aspects of CA, such as mechanistic insights into changes in the size and shape of cells, filaments and carboxysomes.

Chromatic Acclimation in Cyanobacteria: A Diverse and Widespread Process for Optimizing Photosynthesis

Chromatic acclimation (CA) encompasses a diverse set of molecular processes that involve the ability of cyanobacterial cells to sense ambient light colors and use this information to optimize photosynthetic light harvesting. The six known types of CA, which we propose naming CA1 through CA6, use a range of molecular mechanisms that likely evolved independently in distantly related lineages of the Cyanobacteria phylum. Together, these processes sense and respond to the majority of the photosynthetically relevant solar spectrum, suggesting that CA provides fitness advantages across a broad range of light color niches. The recent discoveries of several new CA types suggest that additional CA systems involving additional light colors and molecular mechanisms will be revealed in coming years. Here we provide a comprehensive overview of the currently known types of CA and summarize the molecular details that underpin CA regulation.

The Tryptophan-Rich Sensory Protein (TSPO) is Involved in Stress-Related and Light-Dependent Processes in the Cyanobacterium Fremyella diplosiphon

The tryptophan-rich sensory protein (TSPO) is a membrane protein, which is a member of the 18 kDa translocator protein/peripheral-type benzodiazepine receptor (MBR) family of proteins that is present in most organisms and is also referred to as Translocator protein 18 kDa. Although TSPO is associated with stress- and disease-related processes in organisms from bacteria to mammals, full elucidation of the functional role of the TSPO protein is lacking for most organisms in which it is found. In this study, we describe the regulation and function of a TSPO homolog in the cyanobacterium Fremyella diplosiphon, designated FdTSPO. Accumulation of the FdTSPO transcript is upregulated by green light and in response to nutrient deficiency and stress. A F. diplosiphon TSPO deletion mutant (i.e., ΔFdTSPO) showed altered responses compared to the wild type (WT) strain under stress conditions, including salt treatment, osmotic stress, and induced oxidative stress. Under salt stress, the FdTSPO transcript is upregulated and a ΔFdTSPO mutant accumulates lower levels of reactive oxygen species (ROS) and displays increased growth compared to WT. In response to osmotic stress, FdTSPO transcript levels are upregulated and ΔFdTSPO mutant cells exhibit impaired growth compared to the WT. By comparison, methyl viologen-induced oxidative stress results in higher ROS levels in the ΔFdTSPO mutant compared to the WT strain. Taken together, our results provide support for the involvement of membrane-localized FdTSPO in mediating cellular responses to stress in F. diplosiphon and represent detailed functional analysis of a cyanobacterial TSPO. This study advances our understanding of the functional roles of TSPO homologs in vivo.

A proteomic approach to the analysis of the components of the phycobilisomes from two cyanobacteria with complementary chromatic adaptation: Fremyella diplosiphon UTEX B590 and Tolypothrix PCC 7601

Tolypothrix PCC 7601 and Fremyella diplosiphon UTEX B590 can produce two alternative phycobilisome (PBS) rods. PE-PBSs with one phycocyanin (PC) disk and multiple phycoerythrin (PE) disks are found in cells grown under green light (GL). PC-PBSs with only PC disks are obtained from cells grown under red light (RL). In this manuscript, we show the localization of the linker proteins and ferredoxin-NADP(+) oxidoreductase (FNR) in the PC-PBS and of PE-PBS rods using visible spectroscopy and mass spectrometry. PE-PBSs with different [PE]/[PC] ratios and PC-PBSs with different [PC]/[AP] (AP, allophycocyanin) ratios were isolated. CpeC was the primary rod linker protein found in the PBSs with a [PE]/[PC] ratio of 1.1, which indicates that this is the rod linker at the interphase PC-PE. CpeC and CpeD were identified in the PBSs with a [PE]/[PC] ratio of 1.6, which indicates that CpcD is the linker between the first and the second PE hexamers. Finally, CpeC, CpeD, and CpeE were found in the PBSs with a [PE]/[PC] ratio of 2.9, indicating the position of CpeE between the second and third PE moieties. CpcI2 was identified in the two PC-PBSs obtained from cells grown under RL, which indicates that CpcI2 is the linker between the first and second PC hexamers. CpcH2 was identified only in the PC-PBSs from Tolypothrix with a high [PC]/[AP] ratio of 1.92, which indicates that CpcH2 is the linker between the second and third PC hexamers. The PC-PBSs contained the rod cap protein L(R)(10) (CpcD), but this protein was absent in the PE-PBSs. PE-PBSs (lacking L(R)(10)) incorporated exogenous rFNR in a stoichiometry of up to five FNRs per PBS. A maximum of two FNRs per PBS were found in PC-PBSs (with L(R)(10)). These observations support the hypothesis that FNR binds at the distal ends of the PBS rods in the vacant site of CpcD L(R)(10). Finally, the molecular mass of the core membrane linker (L(CM)) was determined to be 102 kDa from a mass spectrometry analysis.

Emerging perspectives on the mechanisms, regulation, and distribution of light color acclimation in cyanobacteria

Chromatic acclimation (CA) provides many cyanobacteria with the ability to tailor the properties of their light-harvesting antennae to the spectral distribution of ambient light. CA was originally discovered as a result of its dramatic cellular phenotype in red and green light. However, discoveries over the past decade have revealed that many pairs of light colors, ranging from blue to infrared, can trigger CA responses. The capacity to undergo CA is widespread geographically, occurs in most habitats around the world, and is found within all major cyanobacterial groups. In addition, many other cellular activities have been found to be under CA control, resulting in distinct physiological and morphological states for cells under different light-color conditions. Several types of CA appear to be the result of convergent evolution, where different strategies are used to achieve the final goal of optimizing light-harvesting antenna composition to maximize photon capture. The regulation of CA has been found to occur primarily at the level of RNA abundance. The CA-regulatory pathways uncovered thus far are two-component systems that use phytochrome-class photoreceptors with sensor-kinase domains to control response regulators that function as transcription factors. However, there is also at least one CA-regulatory pathway that operates at the post-transcriptional level. It is becoming increasingly clear that large numbers of cyanobacterial species have the capacity to acclimate to a wide variety of light colors through the use of a range of different CA processes.

Characterization of complementary chromatic adaptation in Gloeotrichia UTEX 583 and identification of a transposon-like insertion in the cpeBA operon

Many cyanobacteria are able to alter the pigment composition of the phycobilisome in a process called complementary chromatic adaptation (CCA). The regulatory mechanisms of CCA have been identified in Fremyella diplosiphon, which regulates both phycoerythrin and phycocyanin levels, and Nostoc punctiforme, which regulates only phycoerythrin production. Recent studies show that these species use different regulatory proteins for CCA. We chose to study the CCA response of Gloeotrichia UTEX 583 in an effort to expand our knowledge about CCA and its regulation. We found that Gloeotrichia 583 has a CCA pigment response more similar to that of N. punctiforme rather than F. diplosiphon and exhibits none of the CCA-regulated morphological responses seen in F. diplosiphon. Preliminary experiments suggest that Gloeotrichia 583 contains a homolog to the CCA photoreceptor from N. punctiforme but not the CCA photoreceptor from F. diplosiphon. Additionally, two spontaneous mutants lacking phycoerythrin production were identified. Analysis has shown that these mutants contain a transposon-like insertion in the cpeA gene, which encodes the α subunit of phycoerythrin. These results suggest that CCA in Gloeotrichia UTEX 583 is more similar to that of N. punctiforme than it is to F. diplosiphon, a closely related species.

Functional characterization of a cyanobacterial OmpR/PhoB class transcription factor binding site controlling light color responses

Complementary chromatic acclimation (CCA) allows many cyanobacteria to change the composition of their light-harvesting antennae for maximal absorption of different wavelengths of light. In the freshwater species Fremyella diplosiphon, this process is controlled by the ratio of red to green light and allows the differential regulation of two subsets of genes in the genome. This response to ambient light color is controlled in part by a two-component system that includes a phytochrome class photoreceptor and a response regulator with an OmpR/PhoB class DNA binding domain called RcaC. During growth in red light, RcaC is able to simultaneously activate expression of red light-induced genes and repress expression of green light-induced genes through binding to the L box promoter element. Here we investigate how the L box functions as both an activator and a repressor under the same physiological conditions by analyzing the effects of changing the position, orientation, and sequence of the L box. We demonstrate that changes in the local sequences surrounding the L box affect the strength of its activity and that the activating and repressing functions of the L box are orientation dependent. Also, the spacing between the L box and the transcription start site is critical for it to work as an activator, while its repressing role during light regulation requires additional upstream and downstream DNA sequence elements. The latter result suggests that the repressing function of RcaC requires it to operate in association with multiple additional DNA binding proteins, at least one of which is functioning as an activator.

De novo sequence analysis and intact mass measurements for characterization of phycocyanin subunit isoforms from the blue-green alga Aphanizomenon flos-aquae

In this work, partial characterization of the primary structure of phycocyanin from the cyanobacterium Aphanizomenon flos-aquae (AFA) was achieved by mass spectrometry de novo sequencing with the aid of chemical derivatization. Combining N-terminal sulfonation of tryptic peptides by 4-sulfophenyl isothiocyanate (SPITC) and MALDI-TOF/TOF analyses, facilitated the acquisition of sequence information for AFA phycocyanin subunits. In fact, SPITC-derivatized peptides underwent facile fragmentation, predominantly resulting in y-series ions in the MS/MS spectra and often exhibiting uninterrupted sequences of 20 or more amino acid residues. This strategy allowed us to carry out peptide fragment fingerprinting and de novo sequencing of several peptides belonging to both alpha- and beta-phycocyanin polypeptides, obtaining a sequence coverage of 67% and 75%, respectively. The presence of different isoforms of phycocyanin subunits was also revealed; subsequently Intact Mass Measurements (IMMs) by both MALDI- and ESI-MS supported the detection of these protein isoforms. Finally, we discuss the evolutionary importance of phycocyanin isoforms in cyanobacteria, suggesting the possible use of the phycocyanin operon for a correct taxonomic identity of this species.

A light regulated OmpR-class promoter element co-ordinates light-harvesting protein and chromophore biosynthetic enzyme gene expression

Co-ordination of chromophore and apoprotein biosynthesis is required during photosynthetic light-harvesting antennae production, such as occurs during complementary chromatic adaptation (CCA). This response to ambient light colour changes is controlled by a phytochrome-class photoreceptor and involves changes in the synthesis of cyanobacterial light-harvesting antennae. During growth in red light, CCA activates cpc2 transcription, an operon that encodes the light-harvesting protein phycocyanin. In order to function, this apoprotein must have covalently attached phycocyanobilin chromophores, which are synthesized by PcyA. We show that pcyA is also transcriptionally activated by CCA during red light growth and is not regulated via feedback that senses cpc2 RNA levels. The pcyA and cpc2 promoters contain a common regulatory element, a direct repeat typical of OmpR-class transcription factor binding sites, at similar positions relative to their red light-controlled transcription start sites. Deletion of this element from the pcyA promoter eliminated CCA-regulated transcription, and insertion of the element into a non-light responsive promoter conferred CCA regulation. We conclude that this element is necessary and sufficient to confer CCA transcriptional regulation and that it co-ordinates phycocyanin and phycocyanobilin biosynthesis in red light.

Biochemical bases of type IV chromatic adaptation in marine Synechococcus spp

Chromatic adaptation (CA) in cyanobacteria has provided a model system for the study of the environmental control of photophysiology for several decades. All forms of CA that have been examined so far (types II and III) involve changes in the relative contents of phycoerythrin (PE) and/or phycocyanin when cells are shifted from red to green light and vice versa. However, the chromophore compositions of these polypeptides are not altered. Some marine Synechococcus species strains, which possess two PE forms (PEI and PEII), carry out another type of CA (type IV), occurring during shifts from blue to green or white light. Two chromatically adapting strains of marine Synechococcus recently isolated from the Gulf of Mexico were utilized to elucidate the mechanism of type IV CA. During this process, no change in the relative contents of PEI and PEII was observed. Instead, the ratio of the two chromophores bound to PEII, phycourobilin and phycoerythrobilin, is high under blue light and low under white light. Mass spectroscopy analyses of isolated PEII alpha- and beta-subunits show that there is a single PEII protein type under all light climates. The CA process seems to specifically affect the chromophorylation of the PEII (and possibly PEI) alpha chain. We propose a likely process for type IV CA, which involves the enzymatic activity of one or several phycobilin lyases and/or lyase-isomerases differentially controlled by the ambient light quality. Phylogenetic analyses based on the 16S rRNA gene confirm that type IV CA is not limited to a single clade of marine Synechococcus.

Responding to color: the regulation of complementary chromatic adaptation

The acclimation of photosynthetic organisms to changes in light color is ubiquitous and may be best illustrated by the colorful process of complementary chromatic adaptation (CCA). During CCA, cyanobacterial cells change from brick red to bright blue green, depending on their light color environment. The apparent simplicity of this spectacular, photoreversible event belies the complexity of the cellular response to changes in light color. Recent results have shown that the regulation of CCA is also complex and involves at least three pathways. One is controlled by a phytochrome-class photoreceptor that is responsive to green and red light and a complex two-component signal transduction pathway, whereas another is based on sensing redox state. Studies of CCA are uncovering the strategies used by photosynthetic organisms during light acclimation and the means by which they regulate these responses.

In vivo analysis of the roles of conserved aspartate and histidine residues within a complex response regulator

RcaC is the founding member of a group of large response regulators with complex domain combinations containing at least two receiver domains, an OmpR-class winged helix-turn-helix DNA binding domain, and a histidine phosphotransfer (HPt) domain. Within its two receiver and HPt domains, RcaC contains consensus phosphorylation sites at aspartates 51, 576 and histidine 316. RcaC operates in the pathway regulating transcription of genes encoding components of photosynthetic light harvesting antenna to changes in light colour. We show that phycocyanin gene expression requires RcaC. RcaC contributes to light regulation of phycoerythrin genes, but is not part of the second light regulation pathway controlling these genes. Substitutions at aspartate 51 or histidine 316 severely impaired light responsiveness while substitutions at aspartate 576 had little effect. Complete loss of light regulation, measured by phycocyanin gene expression, only occurred in the triple mutant. We conclude that aspartate 51 primarily controls light colour responsiveness and is regulated by histidine 316, and that these residues are likely phosphorylated in red light and dephosphorylated in green light. The carboxy-terminal receiver domain has a minor role in controlling this response. RcaC abundance is also light regulated and depends on aspartate 51 and histidine 316, but not aspartate 576.

Genomic DNA microarray analysis: identification of new genes regulated by light color in the cyanobacterium Fremyella diplosiphon

Many cyanobacteria use complementary chromatic adaptation to efficiently utilize energy from both green and red regions of the light spectrum during photosynthesis. Although previous studies have shown that acclimation to changing light wavelengths involves many physiological responses, research to date has focused primarily on the expression and regulation of genes that encode proteins of the major photosynthetic light-harvesting antennae, the phycobilisomes. We have used two-dimensional gel electrophoresis and genomic DNA microarrays to expand our understanding of the physiology of acclimation to light color in the cyanobacterium Fremyella diplosiphon. We found that the levels of nearly 80 proteins are altered in cells growing in green versus red light and have cloned and positively identified 17 genes not previously known to be regulated by light color in any species. Among these are homologs of genes present in many bacteria that encode well-studied proteins lacking clearly defined functions, such as tspO, which encodes a tryptophan-rich sensory protein, and homologs of genes encoding proteins of clearly defined function in many species, such as nblA and chlL, encoding phycobilisome degradation and chlorophyll biosynthesis proteins, respectively. Our results suggest novel roles for several of these gene products and highly specialized, unique uses for others.

CotB is essential for complete activation of green light-induced genes during complementary chromatic adaptation in Fremyella diplosiphon

The dramatic modifications of photosynthetic light harvesting antennae called phycobilisomes that occur during complementary chromatic adaptation in cyanobacteria are controlled by two separate photosensory systems. The first system involves the signal transduction components RcaE, RcaF and RcaC, which appear to make up a complex multistep phosphorelay. This system controls the light responsive expression of the cpcB2A2H2I2D2, cpeBA and cpeCDE operons, which encode phycobilisome proteins. The second system, which is not yet characterized, acts in concert with the first but only regulates the light responses of cpeBA and cpeCDE. We have generated and characterized a new mutant class, named the Tan mutants. In at least one member of this class, light-regulated RNA accumulation patterns are altered for cpeBA and cpeCDE, but not for cpcB2A2H2I2D2. Thus this mutant contains a lesion that may impair the operation of the second system. We demonstrate that several Tan mutants are the result of improper expression of the gene cotB. CotB has limited similarity to lyase class proteins, particularly those related to NblB, which is required for degradation of phycobilisomes in other cyanobacteria. Possible roles of CotB in the biogenesis of phycobilisomes are discussed.

Thymine at -5 is crucial for cpc promoter activity of Synechocystis sp. strain PCC 6714

The levels of transcripts of the cpc operon were highly reduced in a PD-1 mutant of cyanobacterium Synechocystis sp. strain PCC 6714. This was due to a substitution of C for T that occurred at 5 bp upstream of the transcription initiation site of the cpc operon. Any substitution for T at the -5 position drastically reduced both in vivo and in vitro promoter activity in cyanobacterium Synechococcus sp. strain PCC 7942 but not the in vivo activity in Escherichia coli. This suggests that the requirement of -5T appears to be specific for a cyanobacterial RNA polymerase-promoter combination.

Co-ordinated expression of phycobiliprotein operons in the chromatically adapting cyanobacterium Calothrix PCC 7601: a role for RcaD and RcaG

In the cyanobacterium Calothrix sp. PCC 7601 the cpc2 operon encoding phycocyanin 2 (PC2) is expressed if red radiations are available. RcaD was previously identified in extracts from red-light-grown cells as an alkaline phosphatase-sensitive protein that binds upstream of the transcription start point (TSP) of the cpc2 operon. In this work, RcaD was purified, and the corresponding gene cloned with a PCR probe obtained using degenerated primers based on RcaD peptide sequences (accession no. AJ319541). Purified RcaD binds to the cpc2 promoter region and also to those of the constitutive cpc1 and apc1 operons that encode phycocyanin 1 and allophycocyanin. Escherichia coli-overexpressed RcaD can bind to the cpc2 promoter region. The rcaD gene is upstream of an open reading frame (ORF) termed rcaG. Co-transcription of both genes was demonstrated by reverse transcription (RT)-PCR experiments, and found to be independent of the light wavelengths. A single TSP was mapped. Sequence features of RcaD and RcaG led us to propose a functional relationship between these two proteins. A rcaD mutant generated by allelic exchange exhibited altered expression of the cpc2, cpeBA, apc1 and cpc1 operons upon green to red-light shifts. RcaD seems to be a co-activator co-ordinating the transcription of the phycobiliprotein operons upon changes in light spectral quality.

A turquoise mutant genetically separates expression of genes encoding phycoerythrin and its associated linker peptides

During complementary chromatic adaptation (CCA), cyanobacterial light harvesting structures called phycobilisomes are restructured in response to ambient light quality shifts. Transcription of genes encoding components of the phycobilisome is differentially regulated during this process: red light activates cpcB2A2, whereas green light coordinately activates the cpeCDE and cpeBA operons. Three signal transduction components that regulate CCA have been isolated to date: a sensor-photoreceptor (RcaE) and two response regulators (RcaF and RcaC). Mutations in the genes encoding these components affect the accumulation of both cpcB2A2 and cpeBA gene products. We have isolated and characterized a new pigmentation mutant called Turquoise 1. We demonstrate that this mutant phenotype is due to a dramatic decrease in cpeBA transcript abundance and results from a lesion in the cpeR gene. However, in this mutant cpeCDE RNA levels remain near those found in wild-type cells. Our results show that the coordinate regulation of cpeBA and cpeCDE by green light can be uncoupled by the loss of CpeR, and we furnish the first genetic evidence that different regulatory mechanisms control these two operons. Sequence analysis of CpeR reveals that it shares limited sequence similarity to members of the PP2C class of protein serine/threonine phosphatases. We also demonstrate that cpeBA and cpeCDE retain light quality responsiveness in a mutant lacking the RcaE photoreceptor. This provides compelling evidence for the partial control of CCA through an as-yet-uncharacterized second light quality sensing system.

A phycocyanin-deficient mutant of synechocystis PCC 6714 with a single-base substitution upstream of the cpc operon

The structure and expression of the cpc operon encoding phycocyanin subunits and linker polypeptides in a phycocyanin-deficient mutant (PD-1) and the wild-type of Synechocystis PCC 6714 were analyzed. The results of sequence and Northern blot analyses of the wild type indicate that the cpc operon consists of cpcB, cpcA, cpcC1, cpcC2 and cpcD, in that order. The levels of the transcripts in PD-1 were one-tenth to one-sixth as high as those in the wild type. In the PD-1 genome, a single-base substitution of C for T has occurred at base 259 upstream of the translational initiation codon of cpcB (at three bases downstream of the putative -10 region). To evaluate the in vivo transcription activities of these promoters in a cyanobacterium, we constructed vectors for the transformation of Synechococcus PCC7942, pANY1 and pANY2, which contain the upstream region of cpcB of the wild type (pANY1) or PD-1 (pANY2) and the promoter-less luxAB fusion. The bioluminescence of the transformants with pANY2 was one-tenth to one-sixth as high as that with pANY1. The coincidence of the results of Northern analysis and the promoter assay shows that the phycocyanin deficiency of PD-1 is due to the single-base substitution in the upstream region of the cpc operon.

A polypeptide with similarity to phycocyanin alpha-subunit phycocyanobilin lyase involved in degradation of phycobilisomes

To optimize the utilization of photosynthate and avoid damage that can result from the absorption of excess excitation energy, photosynthetic organisms must rapidly modify the synthesis and activities of components of the photosynthetic apparatus in response to environmental cues. During nutrient-limited growth, cyanobacteria degrade their light-harvesting complex, the phycobilisome, and dramatically reduce the rate of photosynthetic electron transport. In this report, we describe the isolation and characterization of a cyanobacterial mutant that does not degrade its phycobilisomes during either sulfur or nitrogen limitation and exhibits an increased ratio of phycocyanin to chlorophyll during nutrient-replete growth. The mutant phenotype was complemented by a gene encoding a polypeptide with similarities to polypeptides that catalyze covalent bond formation between linear tetrapyrrole chromophores and subunits of apophycobiliproteins. The complementing gene, designated nblB, is expressed at approximately the same level in cells grown in nutrient-replete medium and medium devoid of either sulfur or nitrogen. These results suggest that the NblB polypeptide may be a constitutive part of the machinery that coordinates phycobilisome degradation with environmental conditions.

rpbA controls transcription of the constitutive phycocyanin gene set in Fremyella diplosiphon

Three gene sets encode alpha and beta subunits of the phycobiliprotein phycocyanin (PC) in the filamentous cyanobacterium Fremyella diplosiphon. The cpcB1A1 set (encodes PC1) is constitutively expressed, whereas the cpcB2A2 set (encodes PC2) is expressed only in red light and the cpcB3A3 set (encodes PC3) is expressed only during sulfur-limited growth. Primary pigment mutant strain FdBM1 is characterized by elevated levels of PC. DNA hybridization analysis showed that like many pigment mutants in our strain collection, strain FdBM1 harbors an extra genomic copy of endogenous transposon Tn5469. By direct cloning from FdBM1 genomic DNA, the extra copy of Tn5469 was localized to an open reading frame, which we have designated the rpbA gene. Complementation experiments correlated rpbA activity to the phenotype of strain FdBM1. The predicted RpbA protein contains two regions resembling the characterized helix-turn-helix motif which is involved in DNA recognition by many bacterial and phage transcription regulator proteins. RNA hybridization analysis showed that relative to the parental strain Fd33, the level of transcripts from cpcB1A1, but not cpcB2A2 or cpcB3A3, was significantly elevated in strain FdBM1. Introduction of the intact rpbA gene into strain FdBM1 restored the cpcB1A1 transcript level to that of strain Fd33. These results suggest that the rpbA gene product functions in controlling constitutive transcription from the cpcB1A1 gene set, possibly as a DNA-binding transcriptional repressor element.

Effect of the nitrogen source on phycobiliprotein synthesis and cell reserves in a chromatically adapting filamentous cyanobacterium

Cyanobacteria can utilize nitrate or ammonium as a source of fixed nitrogen for cell growth. In the filamentous Calothrix sp. strain PCC 7601, these two sources of nitrogen differently influenced the phycobiliprotein composition of the phycobilisomes, the major light-harvesting antennae. When compared to nitrate, growth in the presence of ammonium resulted in intracellular steady-state levels 35% lower for phycoerythrin and 46% higher for phycocyanin. Besides these differences in cell pigmentation, a rapid but transient accumulation of cyanophycin granule polypeptide occurred in ammonium-grown cells, while these macromolecules were not detected in cells grown with nitrate. In contrast, glycogen reserves displayed a dynamic pattern of accumulation and disappearance during cell growth which varied only slightly with the nitrogen source. The observed changes in cell pigmentation are reminiscent of the phenomenon of complementary chromatic adaptation, in which green and red wavelengths promote the syntheses of phycoerythrin and phycocyanin-2, respectively. As in complementary chromatic adaptation, the regulation of synthesis of phycoerythrin and phycocyanin-2 by the nitrogen source occurred mainly at the mRNA level. Moreover, the transcriptional start sites for the expression of the cpeBA and the cpc2 operons, which respectively encode the two subunits of phycoerythrin and phycocyanin-2, were the same in cells grown in nitrate or ammonium, and identical to those in green- and red-light-grown cells. The results of this study suggest that acclimation to the spectral light quality and to the nitrogen source share some common regulatory elements.

High-level expression of human superoxide dismutase in the cyanobacterium Anacystis nidulans 6301

A chemically synthesized gene encoding human CuZn superoxide dismutase (hSOD) was cloned into the shuttle vector pBAX18R and expressed in Anacystis nidulans 6301 (Synechococcus sp. strain PCC 6301) under the control of a ribulose-1,5-bisphosphate carboxylase/oxygenase gene (rbc) promoter derived from A. nidulans 6301. The sequences immediately upstream from the hSOD coding region and the distances between the ribosomal binding site and ATG initiation codon strongly affected the expression of the hSOD gene in A. nidulans cells. Optimal expression of hSOD was obtained with the expression vector pBAXSOD8-I, which contained a GGAGAG sequence. In defined conditions, irradiation with light increased hSOD enzyme activity in the transformants > 18-fold and the level of the hSOD protein reached a value of about 3% of the total soluble protein. The transformants that expressed hSOD acquired the ability to extenuate photooxidative damage induced by methyl viologen.

In vivo and in vitro characterization of the light-regulated cpcB2A2 promoter of Fremyella diplosiphon

When exposed to different spectral qualities of light, many cyanobacteria dramatically alter their phycobilisome rod composition in a process termed complementary chromatic adaptation. In the cyanobacterium Fremyella diplosiphon, this response is associated with differential expression of the cpcB2A2, cpeBA, and cpeCDE operons, which code for the phycobiliproteins phycocyanin and phycoerythrin and the phycoerythrin linker polypeptides, respectively. To define components of the signal transduction pathway involved in light-regulated expression of genes encoding phycobilisome polypeptides, we have used in vivo and in vitro techniques to identify cis-acting sequences and trans-acting factors necessary for the regulation of the red-light-inducible cpcB2A2 operon. Deletion of the cpcB2A2 upstream sequences to -76 bp with respect to the transcription start site had no effect on red-light induction of a cpcB2A2-beta-glucuronidase (GUS) chimeric gene, while deletion to -37 bp abolished GUS expression. Furthermore, a fragment of the cpcB2A2 gene from -76 to +25 bp linked to the untranslated leader of cpcB1A1 (a constitutively expressed operon encoding phycocyanin) is sufficient to drive high-level GUS expression in red light. Therefore, the sequence between positions -76 and -37 is necessary for the expression of cpcB2A2, and the region extending from -76 to +25 is sufficient for red-light induction of the operon. Attempts were made to correlate the in vivo data with protein binding in the region upstream of the transcription start site of cpcB2A2. Using in vitro analysis, we detected two protein-binding sites in the cpcB2A2 promoter which were localized to positions -162 to -122 and -37 to +25. Proteins from both red- and green-light-grown cells interacted with the former site, while only proteins present in extracts from red-light-grown cells interacted with the latter site. The data from both the in vivo and in vitro analyses suggest that while two regions upstream of the cpcB2A2 transcription initiation site specifically bind proteins, only the binding site bordering the transcription start site is important for complementary chromatic adaptation.

A phosphorylated DNA-binding protein is specific for the red-light signal during complementary chromatic adaptation in cyanobacteria

Complementary chromatic adaptation is a mechanism by which some cyanobacteria that are able to synthesize phycoerythrin can adapt their pigment (phycobiliprotein) content to the incident wavelengths of the light. In Calothrix sp. PCC 7601 it concerns phycoerythrin (cpe operon), synthesized under green light, and phycocyanin-2 (cpc2 operon), expressed under red light, and involves transcriptional controls. With cell-free extracts from Calothrix sp. PCC 7601 grown under various light regimes, a protein designated RcaD was found by gel retardation experiments to specifically bind to the cpc2 promoter region and to be present only in red-light-grown cells. This protein was partially purified and its binding activity was shown to be sensitive to an alkaline phosphatase treatment. RcaD can protect two regions of the cpc2 promoter sequence against degradation by DNase I. Because its activity is detected only under the conditions required for cpc2 expression, we propose that RcaD is a positive effector of transcription.

The complete amino acid sequence of R-phycocyanin-I alpha and beta subunits from the red alga Porphyridium cruentum. Structural and phylogenetic relationships of the phycocyanins within the phycobiliprotein families

We present here the complete primary structure of R-phycocyanin-I alpha and beta subunits from the red alga Porphyridium cruentum. The alpha chain is composed of 162 amino acid residues (18049 Da, calculated from sequence, including chromophore) and carries a phycocyanobilin pigment covalently linked to Cys84. The beta chain contains 172 amino acids (19344Da, calculated from sequence, including chromophores) and carries a phycocyanobilin pigment covalently linked at Cys82 and a phycoerythrobilin pigment at Cys153. A gamma-N-methyl asparagine residue was also characterised at position beta 72 similar to other phycobiliprotein beta subunits. R-phycocyanin-I from Porphyridium cruentum shares high sequence identity with C-phycocyanins (69-83%), R-phycocyanins (66-70%) and in a less extent with phycoerythrocyanins (57-65%) from various sources. The presented phylogenetic trees are based on a comparison of all phycobiliprotein amino acid sequences known so far and confirm the clear affiliation of the R-phycocyanins in the phycocyanin family. In spite of their particular phycobilin pattern, they do not represent intermediate forms between the phycocyanin and the phycoerythrin family. Phycoerythrocyanin, a phycocyanin-related phycobiliprotein adapted to green light harvesting, is also shown to belong to the phycocyanin family. However, the phycoerythrocyanins diverge from phycocyanins in their different function and it is suggested that they should be assigned to a separate group within the phycocyanin family.

The phycobilisome, a light-harvesting complex responsive to environmental conditions

Photosynthetic organisms can acclimate to their environment by changing many cellular processes, including the biosynthesis of the photosynthetic apparatus. In this article we discuss the phycobilisome, the light-harvesting apparatus of cyanobacteria and red algae. Unlike most light-harvesting antenna complexes, the phycobilisome is not an integral membrane complex but is attached to the surface of the photosynthetic membranes. It is composed of both the pigmented phycobiliproteins and the nonpigmented linker polypeptides; the former are important for absorbing light energy, while the latter are important for stability and assembly of the complex. The composition of the phycobilisome is very sensitive to a number of different environmental factors. Some of the filamentous cyanobacteria can alter the composition of the phycobilisome in response to the prevalent wavelengths of light in the environment. This process, called complementary chromatic adaptation, allows these organisms to efficiently utilize available light energy to drive photosynthetic electron transport and CO2 fixation. Under conditions of macronutrient limitation, many cyanobacteria degrade their phycobilisomes in a rapid and orderly fashion. Since the phycobilisome is an abundant component of the cell, its degradation may provide a substantial amount of nitrogen to nitrogen-limited cells. Furthermore, degradation of the phycobilisome during nutrient-limited growth may prevent photodamage that would occur if the cells were to absorb light under conditions of metabolic arrest. The interplay of various environmental parameters in determining the number of phycobilisomes and their structural characteristics and the ways in which these parameters control phycobilisome biosynthesis are fertile areas for investigation.

Organization and transcription of the genes encoding two differentially expressed phycocyanins in the cyanobacterium Pseudanabaena sp. PCC 7409

The cpc1 and cpc2 operons of the group III chromatically adapting cyanobacterium Pseudanabaena sp. PCC 7409 were isolated and their nucleotide sequences determined. The cpc1 operon consists of the genes cpcB1A1EF and gives rise to an abundant 1400-nucleotide transcript encoding the cpcB1A1 genes and two low-abundance transcripts of 1000 nucleotides and 1100 nucleotides encoding the cpcF gene. Two extremely low-abundance transcripts of approximately 2900 nucleotides and 4800 nucleotides possibly encode cpcB1A1E and cpcB1A1EF, respectively. All transcripts were present in cultures grown in either red or green light. The transcription start of the cpcB1A1 mRNA was mapped to a position 238 bp 5' to the cpcB1 translation start. The cloned fragment containing the cpcB2A2 genes was found to contain only a portion of the cpc2 operon and consisted of the cpcB2A2 genes and the 5' portion of the linker gene cpcH2. On the basis of biochemical evidence, as well as sequence data from other cpc operons, it is probable that the complete Pseudanabaena sp. PCC 7409 cpc2 operon consists of the genes cpcB2A2H2I2D2. This operon is almost exclusively transcribed in cells grown in red light and gives rise to an abundant mRNA 1400 nucleotides in length that encodes the cpcB2A2 genes. A second transcript of 2400 nucleotides encodes the cpcB2A2H2 genes. A third transcript of 3800 nucleotides encodes the cpcB2A2H2 genes and probably the cpcI2 and cpcD2 genes as well. Transcription of the cpc2 mRNAs inititates 219 bp 5' to the cpcB2 translation start. The promoter region of the Pseudanabaena sp. PCC 7409 cpc1 operon contains the sequence 5' ttGTATaa 3' that is also found to occur within 20 bp of the transcription initiation sites of a number of other constitutively expressed cpc promoters. A high level of sequence similarity also occurs between the red-light-inducible cpc2 promoters of Pseudanabaena sp. PCC 7409 and Calothrix sp. PCC 7601.

Isolation and characterization of the genes encoding allophycocyanin subunits and two linker proteins from Synechocystis 6714

Genes encoding the phycobilisome core subunits allophycocyanin alpha and beta and a small core linker protein in Synechocystis sp. strain PCC 6714 were cloned and sequenced. These genes form an operon, apcABC, with a single transcription start site and two possible termination sites, one following apcB and the other following apcC. The promoter region, like those of the apcABC operons of other cyanobacteria, does not resemble the consensus promoter sequences of Escherichia coli. However, the apcABC promoters identified in four strains of cyanobacteria have conserved sequences centered at -50 and -10 with respect to the start of transcription. The apcE gene, encoding the protein that links the phycobilisome core to the thylakoid membrane, was also cloned from Synechocystis 6714 and sequenced. It is unlinked to the apcABC operon. As in other Synechocystis strains, the LCM polypeptide encoded by the apcE gene contains three repeats of the basic phycobiliprotein linker domain. The apcE gene promoter sequence bears little resemblance to either the E. coli consensus or the apcABC promoter region, but it is similar to the corresponding regions of other cyanobacterial apcE genes. In these cases, there are conserved sequences centered at -40 and -10 with respect to the transcription start site. These conserved promoter elements from the apcABC and apcE genes were also identified in the corresponding 5'-flanking regions of eleven transcript starts for cpc genes encoding phycocyanin subunits in cyanobacteria and algal chloroplasts. These results suggest that a factor yet to be described participates in transcription of phycobiliprotein genes.

In vivo and in vitro footprinting of a light-regulated promoter in the cyanobacterium Fremyella diplosiphon

Certain filamentous cyanobacteria, such as Fremyella diplosiphon, modulate the components of their light-harvesting complexes, the phycobilisomes, and undergo complex morphological changes in response to the wavelength of incident light, or light quality. The operon encoding the subunits of phycoerythrin, cpeBA, is transcriptionally activated in green light and is expressed at very low levels in red light. To begin elucidating the signal transduction pathway between the detection of specific light wavelengths and changes in gene expression, we have used in vivo footprinting to show that a protein is bound to the region upstream of the cpeBA transcription start site in both red and green light: two guanosine residues at -55 and -65 bp are protected from dimethyl sulfate modification in vivo. Using DNA mobility shift gel electrophoresis, we have shown that partially purified extracts of F. diplosiphon from both red and green light contain DNA-binding activity specific for the cpeBA promoter region. Using in vitro footprinting with dimethyl sulfate and DNase I, we have defined a binding site for this putative transcription factor, designated PepB (phycoerythrin promoter-binding protein), that extends from -67 to -45 bp on the upper strand and from -62 to -45 bp on the bottom strand, relative to the transcription start site. The binding site includes two hexameric direct repeats separated by 4 bp, TTGTTAN4TTGTTA. We conclude from these results that PepB is bound to the region upstream of the cpeBA promoter in F. diplosiphon in both red and green light. Therefore, additional factors or protein modifications must be required to allow light-regulated transcription of this operon.

Environmental effects on the light-harvesting complex of cyanobacteria

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Characterization and transcript analysis of the major phycobiliprotein subunit genes from Aglaothamnion neglectum (Rhodophyta)

The genes encoding the alpha and beta subunits of allophycocyanin, phycocyanin and phycoerythrin from the red alga Aglaothamnion neglectum were isolated and characterized. While the operons containing the different phycobiliprotein genes are dispersed on the plastid genome, the genes encoding the alpha and beta subunits for each phycobiliprotein are contiguous. The beta subunit gene is 5' for both the phycocyanin and phycoerythrin operons, while the alpha subunit gene is 5' for the allophycocyanin operon. The amino acid sequences of A. neglectum phycobiliproteins, as deduced from the nucleotide sequences of the genes, are 65-85% identical to analogous proteins from other red algae and cyanobacteria. The conserved nature of the plastid-encoded red algal and cyanobacterial phycobiliprotein genes supports the proposed origin of red algal plastids from cyanobacterial endosymbionts. Many environmental factors effect phycobilisome biosynthesis. The effect of both nutrient availability and light quantity on the level of A. neglectum phycobiliprotein subunits and the mRNA species encoding those subunits is described.

Events in the phytochrome molecule after irradiation

The photoconversion of Pr to Pfr has been investigated by a large number of investigators. We have previously demonstrated that Z, E isomerization of the tetrapyrrole chromophore is involved in the photoconversion. It is the best candidate for the primary photoreaction. Conformation and configuration of the Pr chromophore will be compared with that of chromophores in phycocyanin. The crystal structure of phycocyanin had been elucidated by x-ray analysis. Proton transfer and/or Z, E isomerization of the tetrapyrrole are probably involved in different steps of the photoconversion in phytochrome and in photoreversible phycobiliproteins. Fluorescence decay kinetics of irradiated Pr and intermediate formation show heterogeneity. Possible reasons for this heterogeneity will be discussed.

Characterization of a light-regulated gene encoding a new phycoerythrin-associated linker protein from the cyanobacterium Fremyella diplosiphon

Cyanobacteria utilize multimeric protein complexes, the phycobilisomes, as their major light-harvesting antennae. Associated with the chromophorylated phycobiliproteins in these complexes are nonpigmented proteins, designated linker proteins. These linker proteins are believed to mediate assembly of the phycobilisome and energy transfer to the photosynthetic reaction center. We cloned and sequenced a gene, cpeE, encoding a previously uncharacterized linker protein which is expressed in green light in Fremyella diplosiphon. This gene is part of an operon containing two other phycoerythrin-associated linker genes, cpeC and cpeD. Transcription of the cpeCDE operon in green light results in two predominant species of mRNA of approximately 2,100 and 3,200 nucleotides. The shorter transcript encodes only CpeC and CpeD, while the longer contains the coding regions for all three linker proteins. By altering the pH of the resolving gel and the running buffer during sodium dodecyl sulfate-polyacrylamide gel electrophoresis, this third linker protein CpeE can be resolved from the rod-core linker and the other rod linker proteins. The three proteins have an overall similarity of approximately 62%, and the genes encoding the three proteins are approximately 59% identical.

Identification of replication and stability functions in the complete nucleotide sequence of plasmid pUH24 from the cyanobacterium Synechococcus sp. PCC 7942

The complete nucleotide sequence is presented for pUH24, the small plasmid of Synechococcus sp. PCC 7942. pUH24 consists of 7835bp and has a G + C content of 59%. The distribution of translation start and stop codons in the sequence allows 36 open reading frames that potentially encode polypeptides of 50 or more amino acids. We postulate that eight of these open reading frames are actual coding sequences. A region has been identified, by experiment, that contains two functions, designated pmaA and pmaB, involved in the segregational stability of the plasmid. The minimal region of pUH24 fully capable of supporting autonomous replication consists of a 3.6kb DNA fragment, which is almost entirely occupied by two overlapping genes most likely coding for essential replication proteins (repA and repB).

Three C-phycoerythrin-associated linker polypeptides in the phycobilisome of green-light-grown Calothrix sp. PCC 7601 (cyanobacteria)

Microanalyses by SDS-PAGE and microsequencing demonstrate that, under green-light conditions, 3 C-phycoerythrin associated rod-linker polypeptides with different N-terminal amino acid sequences are present in phycobilisomes (PBS) from Calothrix sp. 7601 cells. Two of these polypeptides, corresponding to SDS-PAGE bands at 36 and 37 kDa, could be assigned, respectively, to the cpeC and cpcD genes found on a separate cpeCD-operon in Calothrix sp. 7601 (Federspiel, N.A. and Grossman, A.R. (1990) J. Bacteriol, 172, 4072-4081). The third C-PE rod-linker polypeptide, LR,2PE,33, requires, therefore, a third gene with the suggested locus designation 'cpeE'. A C-PE (alpha beta)6-LR,2PE,33 complex containing this third rod-linker polypeptide could be isolated from phycobilisomes and characterized. PBS from both green- and red-light cells of Calothrix contain a single, unique LRC28 rod-core linker polypeptide which is not altered during chromatic adaptation.

Molecular cloning and transcriptional analysis of the cpeBA operon of the cyanobacterium Pseudanabaena species PCC7409

The cpeBA operon of the Group III chromatically adapting cyanobacterium Pseudanabaena species PCC 7409 was cloned, sequenced and characterized. The cpeBA genes are transcribed in green-light-grown cells as an abundant 1400-nucleotide mRNA which initiates 69 nucleotides upstream from the cpeB translation start. Extensive sequence identity, extending 70 nucleotides 5' to the transcription start, occurs among cpeBA promoters of Group II and III chromatic adapters. Cell extracts of green-light-grown Calothrix species PCC 7601 contain an activity which specifically binds a restriction fragment containing the Pseudanabanea species PCC 7409 cpeBA promoter. Green-light-dependent cpeBA transcription in Group II and III chromatically adapting cyanobacteria is suggested to be similarly controlled by a transcriptional activator.

A small multigene family encodes the rod-core linker polypeptides of Anabaena sp. PCC7120 phycobilisomes

The cpc operon of Anabaena sp. PCC7120 is shown to encode ten genes: 5'-cpcB-cpcA-cpcC-cpcD-cpcE-cpcF- cpcG1-cpcG2-cpcG3-cpcG4-3'. The 3' portion of this operon includes four tandemly repeated genes encoding phycocyanin (PC)-associated, rod-core linker polypeptides of the phycobilisomes (PBS). The products of these four genes are most similar at their N termini, and overall are 50-61% identical and 68-76% similar to one another. The four CpcG proteins of Anabaena sp. PCC7120 are 41-47% identical and 62-65% similar to the single CpcG rod-core linker protein in Synechococcus sp. PCC7002. The N-terminal domains of the polypeptides are also more distantly related to the conserved domains of other types of rod-linker polypeptides associated with PC, phycoerythrin, and allophycocyanin (AP). Three of these rod-core linker proteins (CpcG1, CpcG2, and CpcG4) were demonstrated to occur in isolated PBS by N-terminal amino acid sequence analyses. These results indicate that previously proposed models for the PBS of Anabaena sp. are incorrect. It is suggested that the PBS of Anabaena sp. have eight peripheral rods, each of which interacts with the AP of the core via a specific rod-core linker (CpcG) polypeptide.

Characterization of two insertion sequences, IS701 and IS702, from the cyanobacterium Calothrix species PCC 7601

We describe the characterization of two insertion elements, IS701 and IS702, isolated from Calothrix species PCC 7601. These insertion elements were cloned from spontaneous pigmentation mutants. Both show the characteristics of typical bacterial insertion sequences, i.e. they present long terminal inverted repeats and they duplicate target DNA upon insertion. These elements share no homology with the only other cyanobacterial insertion sequence described so far, IS891. At least 15 copies of IS701 and 9 copies of IS702 were detected by hybridization experiments in the Calothrix 7601 genome. Their occurrence in several cyanobacterial strains is also reported.

Isolation, crystallization, crystal structure analysis and refinement of constitutive C-phycocyanin from the chromatically adapting cyanobacterium Fremyella diplosiphon at 1.66 A resolution

Constitutive phycocyanin from cyanobacterium Fremyella diplosiphon (Calothrix sp. PCC 7601) grown in green light, has been isolated and crystallized. The crystals belong to the space group R3 with cell constants a = b = 180.26 A, c = 61.24 A, alpha = beta = 90 degrees, gamma = 120 degrees. The crystal structure has been determined by Patterson search techniques using the molecular model of C-phycocyanin from the cyanobacterium Agmenellum quadruplicatum. The asymmetric unit of the crystal cell consists of two (alpha beta)-monomers related by a local dyad. Three asymmetric units are arranged around a crystallographic triad and form an (alpha beta)6-hexamer, the functional unit in the native antenna rod. The initial structure has been refined in a cyclic manner by energy-restrained crystallographic refinement and modelling until the conventional crystallographic R-factor converged at 18.1% with data to a resolution of 1.66 A. The molecular structure resembles closely the C-phycocyanins of Mastigocladus laminosus and A. quadruplicatum. The conformation and configuration of the alpha-84 and beta-84 chromophores is very similar to the corresponding chromophores in the trimeric C-phycocyanin of M. laminosus, whereas the beta-155 chromophore differs in configuration with C(4)-Z, C(10)-Z and C(15)-Z compared to C(4)-Z, C(10)-Z, C(15)-Z,E. The stereochemistry of the beta-155 chiral centres is C(2)-RC(3)-R and C(31)-S, respectively, whereas alpha-84 and beta-84 have C(2)-RC(3)-R and C(31)-R. The amino acid sequences of constitutive and inducible phycocyanin differ mainly in residues located on the surface of the beta-subunits that mediate the inter-hexameric contacts.

Characterization of the light-regulated operon encoding the phycoerythrin-associated linker proteins from the cyanobacterium Fremyella diplosiphon

Many biological processes in photosynthetic organisms can be regulated by light quantity or light quality or both. A unique example of the effect of specific wavelengths of light on the composition of the photosynthetic apparatus occurs in cyanobacteria that undergo complementary chromatic adaptation. These organisms alter the composition of their light-harvesting organelle, the phycobilisome, and exhibit distinct morphological features as a function of the wavelength of incident light. Fremyella diplosiphon, a filamentous cyanobacterium, responds to green light by activating transcription of the cpeBA operon, which encodes the pigmented light-harvesting component phycoerythrin. We have isolated and determined the complete nucleotide sequence of another operon, cpeCD, that encodes the linker proteins associated with phycoerythrin hexamers in the phycobilisome. The cpeCD operon is activated in green light and expressed as two major transcripts with the same 5' start site but differing 3' ends. Analysis of the kinetics of transcript accumulation in cultures of F. diplosiphon shifted from red light to green light and vice versa shows that the cpeBA and cpeCD operons are regulated coordinately. A common 17-base-pair sequence is found upstream of the transcription start sites of both operons. A comparison of the predicted amino acid sequences of the phycoerythrin-associated linker proteins CpeC and CpeD with sequences of other previously characterized rod linker proteins shows 49 invariant residues, most of which are in the amino-terminal half of the proteins.

Nucleotide sequence and expression of the two genes encoding D2 protein and the single gene encoding the CP43 protein of Photosystem II in the cyanobacterium synechococcus sp. PCC 7002

The unicellular photoheterotrophic cyanobacterium Synechococcus sp. PCC 7002 was shown to encode two genes for the Photosystem II reaction center core protein D2 and one gene for the reaction center chlorophyhll-binding protein CP43. These three genes were cloned and their DNA sequences determined along with their flanking DNA sequences. Northern hybridization experiments show that both genes which encode D2, psbD1 and psbD2, are expressed at roughly equivalent levels. For each of the two psbD genes, there are 18 nucleotide differences among the 1059 nucleotides which are translated. The DNA sequences surrounding the coding sequences are nearly 70% divergent. Despite the DNA sequence differences in the genes, the proteins encoded by the two genes are predicted to be identical. The proteins encoded by psbD1 and psbD2 are ∼92% homologous to other sequenced cyanobacterial psbD genes and ∼86% homologous to sequenced chloroplast-encoded psbD genes.The single gene for CP43, psbC, overlaps the 3' end of psbD1 and is co-transcribed with it. Results from previous sequencing of psbC genes encoded by chloroplasts suggest that the 5' end of the psbC gene overlaps the 3' end of the coding sequence of psbD by ∼50 nucleotides. In Synechococcus sp. PCC 7002, the methionine codon previously proposed to be the start codon for psbC is replaced by an ACG (threonine) codon. We propose an alternative start for the psbC gene at a GTG codon 36 nucleotides downstream from the threonine codon. This GTG codon is preceded by a consensus E. coli-like ribosome binding sequence. Both the GTG start codon and its preceding ribosome binding sequence are conserved in all psbC genes sequenced from cyanobacteria and chloroplasts. This suggests that all psbC genes start at this alternative GTG codon. Based on this alternative start codon, the gene product is ∼85% identical to other cyanobacterial psbC gene products and ∼77% identical to eucaryotic chloroplast-encoded psbC gene products.

Structure and light-regulated expression of phycoerythrin genes in wild-type and phycobilisome assembly mutants of Synechocystis sp. strain PCC 6701

Phycoerythrin is a major pigmented component of the phycobilisome, a cyanobacterial light-harvesting complex. It contains bilin-type chromophores that absorb and transfer light energy to chlorophyll protein complexes of the photosynthetic membranes. In many cyanobacteria, phycoerythrin expression is regulated by light wavelength in a response known as chromatic adaptation. Green light-grown cells contain higher levels of this biliprotein than do cells grown in red light. The phycoerythrin gene set from the unicellular cyanobacterium Synechocystis sp. strain PCC 6701 was cloned and sequenced, and the 5' end of the phycoerythrin mRNA was localized. The amino acid sequences of the phycoerythrin subunits from Synechocystis strain 6701 and Fremyella diplosiphon were 90% identical. As observed in F. diplosiphon, the Synechocystis strain 6701 phycoerythrin transcript accumulated to high levels in green light-grown cells and low levels in red light-grown cells. Similar nucleotide sequences, which might control gene expression, occurred upstream of the transcription initiation sites of the phycoerythrin genes in both organisms. While the phycoerythrin structure and light-regulated transcript accumulation were similar in Synechocystis strain 6701 and F. diplosiphon, the steady-state levels of phycoerythrin subunits during growth in red light were quite different for the two organisms. This observation suggests that control of phycoerythrin levels in Synechocystis strain 6701 is complex and may involve posttranscriptional processes. We also characterized the phycoerythrin genes and mRNA levels in two phycobilisome assembly mutants, UV16-40 and UV16.

Genes for phycocyanin subunits in Synechocystis sp. strain PCC 6701 and assembly mutant UV16

The cyanobacterial phycobilisome is a large protein complex located on the photosynthetic membrane. It harvests light energy and transfers it to chlorophyll for use in photosynthesis. Phycobilisome assembly mutants in the unicellular cyanobacterium Synechocystis sp. strain 6701 have been characterized. One such mutant, UV16, contains a defect in the assembly of the biliprotein phycocyanin. We report the cloning and sequencing of the phycocyanin genes from wild-type Synechocystis strain 6701 and demonstrate an alteration in the gene for the phycocyanin alpha subunit in UV16. Possible consequences of the lesion on phycobilisome assembly were assessed from its position in the phycocyanin tertiary and quaternary structures. The UV16 phenotype is complex and includes a reduced level of phycocyanin relative to that in the wild type. To determine whether the lower phycocyanin content results from lower transcript levels, a fragment of cpcBA was used as a probe for quantitating phycocyanin mRNA. Both the wild type and UV16 contained two phycocyanin transcripts of approximately 1.4 and 1.5 kilobases that were equal in abundance and that did not vary with light quality during cell growth. Equal levels of these transcripts in the wild type and UV16 suggest that the lower phycocyanin content in the mutant may be due to posttranscriptional events. The 5' ends of the two phycocyanin mRNAs were mapped at 100 and 223 base pairs upstream of the cpcB initiation codon. Homologous regions upstream of the putative transcription initiation sites may be important for maintaining high levels of transcription from the Synechocystis strain 6701 phycocyanin gene set.

Molecular characterization of phycobilisome regulatory mutants of Fremyella diplosiphon

Three classes of pigment mutants were generated in Fremyella diplosiphon in the course of electroporation experiments. The red mutant class had high levels of phycoerythrin in both red and green light and no inducible phycocyanin in red light. Thus, this mutant behaved as if it were always in green light, regardless of light conditions. Blue mutants exhibited normal phycoerythrin photoregulation, whereas the inducible phycocyanin was present at high levels in both red- and green-light-grown cells. Furthermore, the absolute amount of allophycocyanin was increased threefold in comparison with our wild-type strain. Green mutants lost the capacity to accumulate phycoerythrin in green light but showed normal photoregulation of phycocyanin. Analyses of transcript abundance in these mutants demonstrated that changes in the levels of the different phycobilisome components correlated with changes in the levels of mRNAs encoding those components. The characterization of these mutants supports hypotheses previously discussed concerning molecular mechanisms involved in the regulation of the phycobiliprotein gene sets during chromatic adaptation.

Genes encoding core components of the phycobilisome in the cyanobacterium Calothrix sp. strain PCC 7601: occurrence of a multigene family

The phycobilisome is the major light-harvesting complex of cyanobacteria. It is composed of a central core from which six rods radiate. Allphycocyanin, an alpha beta oligomer (alpha AP and beta AP), is the main component of the core which also contains three other phycobiliproteins (alpha APB, beta 18.3, and L92CM) and a small linker polypeptide (L7.8C). By heterologous DNA hybridization, two EcoRI DNA fragments of 3.5 and 3.7 kilobases have been cloned from the chromatically adapting cyanobacterium Calothrix sp. strain PCC 7601. Nucleotide sequence determination has allowed the identification of five apc genes: apcA1 (alpha AP1), apcA2 (alpha AP2), apcB1 (beta AP1), apcC (L7.8C), and apcE (L92CM). Four of these genes are adjacent on the chromosome and form the apcEA1B1C gene cluster. In contrast, no genes have been found close to the apcA2 gene which is carried by the 3.5-kilobase EcoRI fragment. Transcriptional analysis and 5'-end-mapping experiments were performed. The results obtained demonstrate that the apcEA1B1C gene cluster forms an operon from which segmented transcripts originate, whereas the apcA2 gene behaves as a monocistronic unit. Qualitatively, the same transcripts were identified regardless of the light wavelengths received during cell growth. The deduced amino acid sequences of the apc gene products are very similar to their known homologs of either cyanobacterial or eucaryotic origin. It was interesting, however, that in the apcA1 and apcA2 genes, whose products correspond to alpha-type allophycocyanin subunits, nucleotide sequences were more conserved (67%) than were the deduced amino acid sequences (59%).