Phycocyanin Subunits Research Articles

Changes in Accumulation and Synthesis of Transcripts Encoding Phycobilisome Components during Acclimation of Fremyella diplosiphon to Different Light Qualities

We have used gene-specific DNA fragments as hybridization probes to quantitate the levels of transcripts encoding several phycobilisome polypeptides in the cyanobacterium Fremyella diplosiphon in response to changes in the light environment. While the levels of transcripts encoding allophycocyanin, the core linker polypeptide, and the constitutive phycocyanin subunits are similar in F. diplosiphon grown either in red or green light, the levels of other transcripts change dramatically. Transcripts encoding the inducible phycocyanin subunits are barely detected in green light-grown cells and very abundant in red light-grown cells, while the level of phycoerythrin mRNA is approximately 10-fold more in green than red light-grown cells. Quantitation of the phycoerythrin and inducible phycocyanin transcripts after transfer of cultures from green to red light and red to green light demonstrate that both increase rapidly upon exposure of cells to inductive illumination. The decrease in the phycoerythrin mRNA level in red light is much slower than the decline in the levels of the inducible phycocyanin transcripts in green light. Since the half-lives of the inducible phycocyanin and phycoerythrin transcripts do not change when F. diplosiphon is exposed to red or green illumination, the steady state levels of these mRNAs are primarily controlled by the rate of transcription. Therefore, the high level of phycoerythrin mRNA maintained for several hours after cultures are transferred from green to red illumination must result from continued transcription of the phycoerythrin gene set. Differences in expression from the phycoerythrin and inducible phycocyanin gene sets in response to light quality are discussed in terms of possible mechanisms involved in their regulation.

Transcriptional organization of the phycocyanin subunit gene clusters of the cyanobacterium Anacystis nidulans UTEX 625

The phycocyanin subunit gene cluster is duplicated on the chromosome of the cyanobacterium Anacystis nidulans UTEX 625. The two gene clusters cpcB1A1 (left) and cpcB2A2 (right) are separated by about 2,500 base pairs, and in each cluster the beta-subunit gene is located upstream from the alpha-subunit gene. Filter hybridizations with phycocyanin-specific probes to total RNA detected at least two major transcripts that were 1,300 to 1,400 nucleotides long. Besides these major mRNA species, two minor transcripts of 3,400 and 3,700 nucleotides covering one of the gene clusters and the region between the clusters were found. No additional minor transcripts were found in the intergenic region between the two phycocyanin gene clusters. The lengths of the major mRNAs indicated that the beta- and alpha-subunit genes were cotranscribed. No apparent homologies were found when the DNA sequences located upstream from the proposed ribosome-binding site of the two phycocyanin beta-subunit genes were compared. Northern hybridizations with gene cluster-specific probes from the regions 5' of the beta-subunit genes, as well as S1 nuclease mapping and mRNA primer extension experiments, showed that both gene clusters were transcribed. The minor transcripts were found to initiate upstream from the left gene cluster. Two mRNA 5' ends were mapped upstream from the cpcB1A1 gene cluster, while only one 5' end was mapped in front of the cpcB2A2 gene cluster. All transcripts were present in RNA preparations from cultures grown under high levels of white light as well as under low levels of red light. The level of phycocyanin-specific mRNA, measured as part of the total RNA, was lower under low levels of red light compared with that under high levels of white light. Conserved sequence motifs were found when the promoter region of the cpcB1A1 gene cluster and promoter regions from other cyanobacterial photosynthesis genes were compared. The DNA sequences covering the proposed transcriptional attenuators and transcriptional stop signals contained several potential hairpin structures. One potential hairpin structure was located immediately downstream of the left phycocyanin gene cluster and was concluded to limit the level of transcription for the minor transcripts initiating upstream of the cpcB1A1 gene cluster.

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

The major light-harvesting complex in eukaryotic red algae and prokaryotic cyanobacteria is the phycobilisome, a water-soluble complex located on the outer surface of the photosynthetic membranes and composed of both pigmented phycobiliproteins (85%) and non-pigmented linker (15%) polypeptides. The phycobiliproteins are encoded by a gene family and exhibit varying degrees of sequence homology (25 to 55%). Some cyanobacteria can maximize the absorption of prevalent wavelengths of light by adjusting the phycobiliprotein composition of the phycobilisome, a process called complementary chromatic adaptation. In the chromatically adapting species Fremyella diplosiphon, there are at least two sets of phycocyanin genes; one is transcribed as two red light-induced transcripts and the other is encoded on a single transcript present in both red and green light. We have determined the complete nucleotide sequences of both sets of phycocyanin subunit genes and their associated 5′ and 3′ regulatory regions. Based on S 1 nuclease protection experiments, the transcripts (1600 and 3800 bases) encoding the inducible phycocyanin subunits have the same 5′ end, and possible mechanisms for their synthesis are presented. The 5′ end of the 1500-base transcript encoding the constitutive phycocyanin subunits was determined and revealed an Escherichia coli-like “-10” and “-35” region, and sequences near the transcription initiation site homologous to the analogous region of the phycocyanin gene set of Anabaena sp. 7120. Determination of the 3′ ends of the transcripts encoding both F. diplosiphon phycocyanin gene sets revealed regions of potential secondary structure that may be important for transcription termination and/or transcript stability. In addition, the sequence of an open reading frame (encoding a 30 kDa polypeptide), located 3′ to the constitutive phycocyanin gene set in F. diplosiphon and highly conserved in at least three cyanobacterial species, is presented. The same high degree of sequence homology between the two F. diplosiphon PC α and PC β sequences (85 and 77%, respectively) was found at both the nucleotide and amino acid levels, and similar results were obtained for interspecies comparisons. Implications of these homologies with regard to the evolution of phycobiliprotein subunits are discussed.

A multigene family in Calothrix sp. PCC 7601 encodes phycocyanin, the major component of the cyanobacterial light-harvesting antenna

In cyanobacteria, light is harvested by phycobilisomes which are essentially made up of chromophoric proteins called phycobiliproteins. We have characterized two gene clusters (cpcB1, cpcA1 and cpcB3, cpcA3) each encoding the two subunits of phycocyanin (βPC and αPC, respectively), one of the major phycobiliproteins in Calothrix 7601. Downstream from the gene encoding the PCα subunit in cluster 1, an open reading frame was found, cpcE1. These genes are organized in two transcriptional units, namely: cpcB3 A3 and cpcB1 A1 E1. All these genes are transcribed whatever the chromatic light received during cell growth. Consequently, although only one type of “constitutive” PC has been biochemically characterized, we have demonstrated that there are two cpc operons “constitutively” transcribed in this strain. With the previously described red light “inducible” cpcB2 A2 operon, there are three copies of the PC encoding genes in Calothrix 7601. The significance of this newly described multigene family in cyanobacteria is discussed. We have also mapped the 5′ and 3′ termini of the major transcript from the cpc1 operon. Analysis of the 5′ untranslated region of this transcript has revealed alternative secondary structures which are proposed to play a role in the regulation of the expression of this operon.

Isolation and characterization of light-regulated phycobilisome linker polypeptide genes and their transcription as a polycistronic mRNA.

Several cyanobacteria adjust both the phycobiliprotein and linker protein composition of the phycobilisome, a light-harvesting complex in cyanobacteria and some eucaryotic algae, to maximize absorption of prevalent wavelengths of light. This process is called complementary chromatic adaptation. We sequenced the amino terminus of a linker polypeptide which is associated with phycocyanin and accumulates to high levels during growth of the cyanobacterium Fremyella diplosiphon in red light. A mixed oligonucleotide encoding a region of this amino terminus was synthesized and used to identify a fragment of F. diplosiphon genomic DNA encoding the linker polypeptide. This linker gene was located between two other linker genes and contiguous to the red-light-induced phycocyanin gene set. Sequences of all three linker genes are presented. These genes were transcribed together onto a large polycistronic mRNA which also encoded the red-light-induced phycocyanin subunits. The relationship of this transcript to the biogenesis of the phycobilisome when F. diplosiphon is grown under different conditions of illumination is discussed.

Cloning and light regulation of expression of the phycocyanin operon of the cyanobacterium Anabaena.

The biliprotein phycocyanin (PC) is a major constituent of the light-harvesting apparatus of cyanobacteria and red algae. A DNA fragment encoding the beta and alpha subunits of PC was isolated from a genomic library of the cyanobacterium Anabaena 7120 DNA. The single-copy PC genes are part of a larger operon which consists of five open reading frames (ORFs) encoding, in order, the beta and alpha subunits of PC, two linker polypeptides associated with PC in phycobilisome rods, and a fifth ORF, which may encode a linker polypeptide involved in attachment of the phycobilisome rod to the core of the structure. The operon yields three major transcripts, the first of which (1.4 kb) encodes only the PC subunits. A second (3.6 kb) encodes all five ORFs, and appears to arise from partial read-through of a terminator following the PC subunit genes. The third transcript (1.4 kb) encodes the last two ORFs. The relative levels of the three transcripts in vivo are modulated by light intensity, but they are not altered by the removal of fixed nitrogen from the growth medium. The site of light regulation appears to be the terminator following the PC genes, rather than a promoter.

Fast preparative isoelectric focusing of phycocyanin subunits in layers of granulated gels

AbstractA new method is presented for the fast preparative separation of the light‐harvesting photosynthetic pigment C‐phycocanin into its α and β subunits, which is based on isoelectric focusing in layers of granutaled gels containing 7 M urea. The method has been successful in cases where other separation procedures failed. The recovery of the separated chains of the light ‐sensitive biliprotein amounts to 70 ± 10 % when the separation is carried out under light exclusion and in an argon atmosphere. A simple and inexpensive setup for work under an atmosphere of protective gas is described.

The Diazo Reaction of Bilirubins and Phycorubins: A Quantitative Study*

A quantitative study of the diazo reaction has been made with several bilirubins including a 2,3- dihydrobilirubin and several phycorubins. The latter have been prepared from the integral phycocyanin of two cyanobacteria (Mastigocladus laminosus and Spirulina platensis), and from the phycocyanin subunits. These phycorubins have been subjected to the diazo reaction in order to test for the presence of a second covalent chromophore protein bond in the latter. 1)The diazo reaction of unsymmetrically substituted bilirubins, mesobilirubin (3) and bilirubin IXα (13) in aqueous solution yields four products, two isomeric 9-azo-dipyrromethenones, and two isomeric 9-hydroxymethyl-dipyrromethenones. The maximum total yield is ≥ 97% with diazotized sulfanilic acid, and ≤ 60% with diazotized ethylanthranilate. 2)The diazo reaction of the 2,3-dihydrobilirubin (16) yields likewise four products, two of them containing the 2,3-dihydrogenated ring A/B fragment. The attack is regioselective at C-11 (6:4). 3)The diazo reaction of the phycorubins with ethylanthranilate yields two peptide bound products, containing the ring A/B fragment, and two low molecular weight products. The latter correspond to the C/D fragment and are identical with the respective products derived from mesobilirubin 3. The attack is preferential at C-9 (≥ 4:1 with ≤ 1 mole reagent added). These results show, that there is no second covalent chromophore peptide bond in the PC investigated at the ring C/D fragment.

Subunit separation (alpha,alpha',beta) of cryptomonad biliproteins.

Abstract— Phycocyanin 645, phycocyanin 612 and phycoerythrin 545 are biliproteins isolated from the cryptomonad algae, Chroornonas species, Hemiselmis virescens and Rhodomonas lens, respectively. The protein has α and β subunits. which are separated on an ion exchange column by using a urea gradient and omitting 2‐mercaptoethanol from the solvent. This separation establishes that the α and β subunits are not joined by disulfide bonds. In addition it has recently been shown that mercaptoethanol can produce spurious results in the calculation of the chromophore contents of these biliproteins (Guard‐Friar and MacColl, 1984). The mercaptoethanol‐free experiments allow analysis of the chromophore content in a rapid and artifact‐free manner. When the ion exchange chromatography of phycocyanin 645 is manipulated by changing the type of urea gradient, two distinct a subunit fractions are obtained. These two fractions have identical visible absorption spectra but different amino acid compositions. At least two different gene products are, thus. responsible for the a subunits. The sole chromophore on the two a subunits of phycocyanin 645 is the unique 697‐nm bilin as seen in acidic urea. Its reactivity with mercaptoethanol is determined. The α subunits of phycoerythrin 545 have two different bilins: cryptoviolin and phycoerythrobilin. Phycocyanobilin is the chromophore on the α subunit of phycocyanin 612.

Cyanobacterial light-harvesting complex subunits encoded in two red light-induced transcripts.

The major light-harvesting complex in cyanobacteria and red algae, the phycobilisome, is composed of chromophoric and nonchromophoric polypeptides. Two linked genes encoding major chromophoric components, the polypeptide subunits of phycocyanin, were isolated from the cyanobacterium Fremyella diplosiphon. Transcripts from this phycocyanin subunit gene cluster were present as major species in the cyanobacterium grown in red light, but not in cultures maintained in green light. The genes for the subunits of the red light-induced phycocyanin were transcribed together (beta-phycocyanin followed by alpha-phycocyanin) on two messenger RNA species; one contained 1600 bases while the other had 3800 bases. The latter, which encompassed the smaller transcript, contained additional sequences extending from the 3' end of the coding region of the alpha-phycocyanin gene. It may encode other light-induced components of the phycobilisome. Since phycocyanin, which effectively absorbs red light, becomes a dominant constituent of the phycobilisome in red light, these different levels may reflect an important adaptive mechanism of these organisms to their environment.

Major light-harvesting polypeptides encoded in polycistronic transcripts in a eukaryotic alga.

By sequence analysis of previously identified fragments and low stringency hybridization of an identified gene for a phycobiliprotein subunit to total plastid DNA, we have identified four phycobiliprotein subunit genes in a eukaryotic alga, Cyanophora paradoxa. The four phycobiliprotein subunits, alpha and beta of phycocyanin (PC) and allophycocyanin (APC), comprise the bulk of the light-harvesting complex in this alga. The alpha and beta subunit genes encoding each phycobiliprotein (the products of which are required in a 1:1 ratio in the light-harvesting complex) are contiguous; however, the genes for different phycobiliproteins, PC and APC, are located in different regions of the genome. The two PC subunit genes are in the small single copy region of the plastid genome whereas the APC subunit genes are in the large single copy region and the two sets of phycobiliprotein genes are transcribed from opposite strands. The alpha and beta subunits of both PC and APC are encoded in dicistronic transcripts and this arrangement may provide a mechanism by which the two subunits can be synthesized in equimolar amounts. Levels of the PC transcript are approximately five times that of the APC transcript which may reflect the relative abundance of their gene products in the phycobilisome. The 5' ends of the transcripts for PC and APC were mapped and the regulatory regions identified. Several features of the promoter regions for these highly transcribed genes are described.

Genes for the alpha and beta subunits of phycocyanin.

Phycocyanin (PC) is a light-harvesting protein common to blue-green and red algae. We have isolated the genes for the two apoprotein subunits, alpha and beta, of PC from the blue-green alga Agmenellum quadruplicatum PR-6. We synthesized eight sense-strand tetradecameric oligonucleotide probes that could encode a particular pentapeptide in PC alpha from A. quadruplicatum. Only one probe hybridized with total RNA from this organism. This oligonucleotide showed homology to a unique restriction fragment when used to probe Southern blots of A. quadruplicatum DNA. The probe-homologous 3.1-kilobase pair HindIII fragment was cloned. The nucleotide sequence of a 1.7-kilobase pair segment of this clone was determined. Two open reading frames are contained in this region, which correspond in deduced amino acid sequence to PC alpha and PC beta subunits. Both coding sequences are in the same orientation, separated by 105 base pairs, with the PC beta gene 5' to the PC alpha gene. Each gene has a Shine-Dalgarno-type sequence near the initiation codon. Codon frequencies in the two genes may be correlated with the abundance of their products. The deduced amino acid sequences of the gene products show considerable homology with the alpha and beta PC subunits from other species.

Phycobiliprotein synthesis in the unicellular rhodophyte, Cyanidium caldarium. Cell-free translation of the mRNAs for the alpha and beta subunit polypeptides of phycocyanin.

Phycobiliproteins are a class of abundant light-harvesting proteins assembled in complex multimeric aggregates located on thylakoid membranes of red algae and cyanobacteria. This study was undertaken to investigate the molecular basis of phycobiliprotein synthesis in the unicellular red alga, Cyanidium caldarium. RNA was isolated and separated into poly(A)-enriched and poly(A)-deficient fractions by oligo(dT)-cellulose chromatography. Both fractions stimulated incorporation of radiolabeled amino acids into protein in a reticulocyte lysate translation system. The alpha and beta subunit polypeptides of phycocyanin were among the products of poly(A)-deficient (but not poly(A)-enriched) RNA directed translation reactions on the basis of Mr and immunological cross-reactivity with immune serum prepared against native phycocyanin. After chromatography of post-oligo(dT)-cellulose poly(A)-deficient RNA on poly(U) agarose, the messenger RNAs for the alpha and beta subunit polypeptides of phycocyanin were again recovered in the poly(A)-deficient fraction, confirming that these messenger RNAs did not appear to be polyadenylated. Automated radiosequencing of in vitro synthesized alpha and beta subunit polypeptides of phycocyanin labeled with either [35S]methionine, [3H]isoleucine, or [3H]phenylalanine revealed partial amino acid sequences which were the same as the NH2-terminal sequences of native phycocyanin subunits. This demonstrates that a "transit peptide", such as that found in several proteins made in the cytosol and transported into chloroplasts, is not present on the subunits of phycocyanin.

Growth and Chromatic Adaptation of Nostoc sp. Strain MAC and the Pigment Mutant R-MAC

A spontaneous, stable, pigmentation mutant of Nostoc sp. strain MAC was isolated. Under various growth conditions, this mutant, R-MAC, had similar phycoerythrin contents (relative to allophycocyanin) but significantly lower phycocyanin contents (relative to allophycocyanin) than the parent strain. In saturating white light, the mutant grew more slowly than the parent strain. In nonsaturating red light, MAC grew with a shorter generation time than the mutant; however, R-MAC grew more quickly in nonsaturating green light.When the parental and mutant strains were grown in green light, the phycoerythrin contents, relative to allophycocyanin, were significantly higher than the phycoerythrin contents of cells grown in red light. For both strains, the relative phycocyanin contents were only slightly higher for cells grown in red light than for cells grown in green light. These changes characterize both MAC and R-MAC as belonging to chromatic adaptation group II: phycoerythrin synthesis alone photocontrolled.A comparative analysis of the phycobilisomes, isolated from cultures of MAC and R-MAC grown in both red and green light, was performed by polyacrylamide gel electrophoresis in the presence of 8.0 molar urea or sodium dodecyl sulfate. Consistent with the assignment of MAC and R-MAC to chromatic adaptation group II, no evidence for the synthesis of red light-inducible phycocyanin subunits was found in either strain. Phycobilisomes isolated from MAC and R-MAC contained linker polypeptides with relative molecular masses of 95, 34.5, 34, 32, and 29 kilodaltons. When grown in red light, phycobilisomes of the mutant R-MAC appeared to contain a slightly higher amount of the 32-kilodalton linker polypeptide than did the phycobilisomes isolated from the parental strain under the same conditions. The 34.5-kilodalton linker polypeptide was totally absent from phycobilisomes isolated from cells of either MAC or R-MAC grown in green light.

Cyanobacterial phycobilisomes. Phycocyanin assembly in the rod substructures of anabaena variabilis phycobilisomes.

Phycocyanin complexes with "linker" polypeptides (Lundell, D. J., Williams, R. C., and Glazer, A. N. (1981) J. Biol. Chem. 256, 3580-3592) of 27 and 32.5 kilodaltons have been isolated from dissociated Anabaena variabilis phycobilisomes. In 0.05 M phosphate at pH 7.0, these "trimeric" complexes have the molar composition (alpha beta)3 . 27,000 and (alpha beta)3 . 32,500, where alpha and beta are the subunits of phycocyanin and 27,000 and 32,500 denote single copies of the linker polypeptides. The (alpha beta)3 . 27,000 and (alpha beta)3 . 32,500 complexes have lambda max at 638 and 629 nm and fluorescence emission maxima at 651 and 646 nm, respectively. In 0.6 M phosphate at pH 8.0, the (alpha beta)3 . 27,000 complex forms an (alpha beta)6 . 27,000 disc-shaped aggregate as seen in the electron microscope, whereas the (alpha beta)3 . 32,500 complex forms discs, (alpha beta)6 . 32,500, and stacked disc rods of varying lengths. The former material, containing the 27,000 polypeptide, when mixed with the (alpha beta)6 . 32,500 discs, limits their assembly into rods. The spectroscopic properties of the discs and rods assembled in vitro indicate that energy transfer in phycobilisome rod substructures proceeds from (alpha beta)6 . 32,500 discs to the (alpha beta)6 . 27,000 disc proximal to the core and thence to the core.

Effects of chromatic illumination on cyanobacterial phycobilisomes. Evidence for the specific induction of a second pair of phycocyanin subunits in Pseudanabaena 7409 grown in red light.

Pseudanabaena 7409 is a chromatically cyanobacterium which photocontrols the synthesis of both phycoerythrin and phycocyanin [Tandeau de Marsac (1977) J. Bacteriol. 130, 82--91]. Phycobilisomes, isolated from cells grown in either green or red light, have been dissociated and the component biliproteins purified and characterized. Phycobilisomes isolated from cells grown in green light were composed of allophycocyanin B, allophycocyanin, two phycocyanin subunits (one alpha-type and one beta-type subunit), phycoerythrin and eight uncolored polypeptides. When dissociated phycobilisomes were chromatographed on DEAE-cellulose at pH 5.5, most of the phycocyanin was recovered as part of a large (17.3 S) multiprotein complex with phycoerythrin (molar ratio 1 : 1). This complex also contained five of the uncolored polypeptides found in intact phycobilisomes isolated from cells grown in green light. Phycobilisomes isolated from cells grown in red light were composed of allophycocyanin B, allophycocyanin, four phycocyanin subunits (two alpha-type and two beta-type subunits), and six uncolored polypeptides. When these phycobilisomes were dissociated, the phycocyanin was recovered as a large (21.0 S) multiprotein complex which was composed of the four phycocyanin subunits types and four uncolored polypeptides. This complex was morphologically identical to the rod-like stacks of discs about 6 x 12 nm which form the peripheral rods of intact phycobilisomes. Each of the four phycocyanin subunits found in the complex isolated from the phycobilisomes of cells grown in red light was purified to homogeneity and characterized. Amino acid compositions of the four subunits indicated that each subunit was a unique gene product. Two of the subunits of the complex were apparently identical to those of the phycocyanin purified from phycobilisomes isolated from cells grown in green light. These studies suggest that one pair of phycocyanin subunits was synthesized constitutively (i.e. irrespective of the light wavelength to which the cells were exposed during growth) while the synthesis of the second pair of phycocyanin subunits was specifically induced during growth in red light.

The photoregulated expression of multiple phycocyanin species. A general mechanism for the control of phycocyanin synthesis in chromatically adapting cyanobacteria.

The regulation of phycocyanin synthesis in response to growth in chromatic illumination was studied in 69 strains of cyanobacteria. Cyanobacteria (24 of 31 strains examined), which chromatically adapt by modulating the synthesis of both phycocyanin and phycoerythrin, controlled phycocyanin synthesis through the differential, photoregulated expression of two phycocyanin species (two alpha-type and two beta-type subunits). For these strains the expression of one pair of phycocyanin subunits was constitutive (i.e. irrespective of the light wavelength in which the cells were grown); the expression of the second pair of phycocyanin subunits occurred specifically during growth in red light. Two facultatively heterotrophic cyanobacteria, Calothrix strains 7101 and 7601, synthesized both the constitutive and the inducible pairs of phycocyanin subunits when grown heterotrophically in the dark after transfer from either red or green light. No evidence for the existence of multiple and/or photoregulated phycocyanin species was found for cyanobacteria (25 strains) incapable of chromatic adaptation, nor for cyanobacteria (13 strains) which chromatically adapt by modulating the synthesis of phycoerythrin alone.

Phycobilin-apoprotein linkages in the alpha and beta subunits of phycocyanin from the unicellular rhodophyte, Cyanidium caldarium. Amino acid sequences of 35S-labeled chromopeptides.

Phycobilin-apoprotein linkages in the alpha and beta subunits of phycocyanin from the unicellular rhodophyte, Cyanidium caldarium. Amino acid sequences of 35S-labeled chromopeptides.

Quantitative degradation of radiolabeled phycobiliproteins. Chromic acid degradation of C-phycocyanin.

Phycocyanin and allophycocyanin are bile-pigment apoprotein complexes found in the photo-synthetic apparatus of red and blue-green algae. Phycocyaninand allophycocyanin, in which the bile pigment (phycobilin) chromophore was radiolabeled (but the apoprotein was unlabeled), were prepared by incubating cells of the unicellular red alga, Cyanidum caldarium, with δ-amino[4-14C]-levulinic acid. The radiolabeled phycobiliproteins were isolated and purified, and the radiolabeled chromophore was cleaved from apoprotein by boiling in methanol. the chromophore-free acid (phycobilin1) was converted to the dimethylester (phycobilin 2) and the subunits of phycocyanin, allophycocyanin, and phycobilins 1–3 were subjected to chromic acid degradation at 25°C and 100°C. The imide fingerprints and quantiative recovery of imides from rings I–IV of phyco-bilins and phycobiliproteins (chromophore covalently attached) were determined. A different recovery pattern of imides from rings I–IV of phycobilins 1–3 was observed but the pattern was normally reproducible for a given phycobilin 1 after degradation at 100°C as was recovered at 25 °C. Chromic acid degradation of phycobiliproteins at 25 °C yielded rings II and IV as hematinic acid and mi=ethylethylmaleimide, respectively, in a 1 : 1 ratio. Chromic acid degradation at 100 °C yielded twice as much hematinic acid (rings II and III) and the same amount of methyl-ethylmaleimide as obtained at 25°C, in addition to ring I as 2-ehtylidene-3-methylsccinimide. These imide profiles and recovferies from phycobiliprotein. The imide fingerprints and recovery of imides from phycobilin 1 and phycobiliproteins are discussed in relation to the premise that rings I and III of the chromophore are covalently attached and to elucidation of phycobilin-apoprotein linkages by micro-degradative techniques.

Phycocyanin synthesis and degradation in the blue-green bacterium Anacystis nidulans.

Cellular content and rates of synthesis of the apoprotein subunits of phycocyanin in Anacystis nidulans cultures undergoing, and recovering from, nitrate starvation were measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of total and immunoprecipitable soluble proteins. Results indicated that (i) nitrate starvation provokes coordinate degradation of apoprotein subunits: (ii) de novo synthesis of these subunits is selectively depressed during starvation; (iii) nitrate restoration provokes coordinate increases in the rates of synthesis of these subunits, although maximal rates are not achieved for 6 to 10 h after readdition of nitrate; and (iv) illumination affects both relative and absolute rates of apoprotein formation.