Bile pigment synthesis in plants. Incorporation of haem into phycocyanobilin and phycobiliproteins in Cyanidium caldarium.

A procedure was developed whereby haem was taken up by dark-grown cells of the unicellular rhodophyte Cyanidium caldarium. These cells were subsequently incubated either in the dark with 5-aminolaevulinate, which results in excretion of phycocyanobilin into the suspending medium or incubated in the light, which results in synthesis and accumulation of phycocyanin and chlorophyll a within the cells. Phycocyanobilin was isolated from phycocyanin by cleavage from apoprotein in methanol. Phycocyanobilin prepared from phycocyanin or excreted from cells given 5-aminolaevulinate was methylated and purified by t.l.c. By using 14C labelling either in the haem or in 5-aminolaevulinate administered, haem incorporation into phycocyanobilin was demonstrated in both dark and light systems. Since chlorophyll a synthesized in the light in the presence of labelled haem contained no radioactivity, it was clear that haem was directly incorporated into phycocyanobilin and not first converted into protoporphyrin IX. These results clearly demonstrate phycocyanobilin synthesis via haem and not via magnesium protoporphyrin IX as has also been postulated.     

Biosynthesis of phycocyanobilin from exogenous labeled biliverdin in Cyanidium caldarium

Phycocyanin is a major light-harvesting pigment in bluegreen, red, and cryptomonad algae. This pigment is composed of phycocyanobilin chromophores covalently attached to protein. Phycocyanobilin is an open-chain tetrapyrrole structurally close to biliverdin. Biliverdin is formed in animals by oxidative ring-opening of protoheme. Recent evidence indicates that protoheme is a precursor of phycocyanobilin in the unicellular rhodophyte, Cyanidium caldarium. To find out if biliverdin is an intermediate in the conversion of protoheme to phycocyanobilin, [14C]biliverdin was administered along with N-methylmesoporphyrin IX (which blocks endogenous protoheme formation) to growing cells of C. caldarium. To avoid phototoxic effects due to the porphyrin, a mutant strain was used that forms large amounts of both chlorophyll and phycocyanin in the dark. After 12 or 24 h in the dark, cells were harvested and exhaustively extracted to remove free pigments. Next, protoheme was extracted. Phycocyanobilin was then cleaved from the apoprotein by methanolysis. Protoheme and phycocyanobilin were purified by solvent partition, DEAE-Sepharose chromatography, and preparative reverse-phase high-pressure liquid chromatography. Absorption was monitored continuously and fractions were collected for radioactivity determination. Negligible amounts of label appeared in the protoheme-containing fractions. A major portion of label in the eluates of the phycocyanobilin-containing samples coincided with the absorption peak at 22 min due to phycocyanobilin. In a control experiment, [14C]biliverdin was added to the cells after incubation and just before the phycocyanobilin-apoprotein cleavage step. The major peak of label then eluted with the absorption peak at 12 min due to biliverdin, indicating that during the isolation biliverdin is not converted to compounds coeluting with phycocyanobilin. It thus appears that exogenous biliverdin can serve as a precursor to phycocyanobilin in C. caldarium, and that the route of incorporation is direct rather than by degradation and reincorporation of 14C through protoheme.     

alpha-linolenic acid biosynthesis in Cyanidium caldarium.

Although α-linolenic acid is nearly absent from Cyanidium caldarium cultured at 53 °C, it is the most abundant unsaturated fatty acid in 20 °C-grown cells. A sudden growth temperature shift of 55 to 25 °C does not stimulate the immediate biosynthesis of α-linolenic acid. However, after an induction period of 48 h, synthesis of α-linolenic acid from acetate can be detected, and the fatty acid accumulates in phosphatidyl choline and sulfolipid. The newly synthesized α-linolenic acid appears to be formed primarily by de novo synthesis and to a much lesser extent from the elongation of a previously formed hexadecatrienoic acid precursor. On the other hand, when a cell-free algal preparation was presented with a hexadecatrienoic acid precursor in the presence of [¹⁴C] malonyl-CoA, the α-linolenic acid formed demonstrated a synthesis by elongation of the precursor. While the cell appears enzymatically capable of α-linolenic acid biosynthesis by both the de novo and elongation processes, de novo synthesis of α-linolenic acid appears to be the more significant mode of synthesis.     

Mechanism of bile-pigment synthesis in algae. 18O incorporation into phycocyanobilin in the unicellular rhodophyte, Cyanidium caldarium.

The origin of the lactam oxygen atoms of phycocyanobilin from Cyanidium caldarium was studied using 18O labelling. By inhibiting photosynthesis, a high 18O enrichment was maintained in the gas phase and the resulting incorporation of label showed that the lactam oxygen atoms were derived from two oxygen molecules. Slow exchange of these oxygen atoms with water was demonstrated directly by using H218O.     

Biosynthesis of phycobiliproteins. Incorporation of biliverdin into phycocyanin of the red alga Cyanidium caldarium

14C-labelled biliverdin IX alpha was administered to cultures of Cyanidium caldarium that were actively synthesizing photosynthetic pigments in the light. Between 9 and 12% of the phycobiliprotein chromophore produced in such cultures was derived from exogenous biliverdin. These results demonstrate that biliverdin is an intermediate in the biosynthesis of phycobiliproteins.     

Anaerobic fermentation in Cyanidium caldarium

Cyanidium caldarium cells kept anaerobically in the dark have no detectable gas exchange and form exclusively d-(-)-lactate at the expense of their starch content. The addition of acetate enhances both starch breakdown and lactate accumulation by a factor of two. During prolonged anaerobiosis Cyanidium is able to keep its energy charge at a low, but fairly constant level. The adenylate-kinase equilibrium, however, undergoes considerable changes, indicative of a regulatory mechanism which maintains a high energy charge particularly by accumlating AMP instead of ADP.     

Recovery of metals from acid waste water by Cyanidium caldarium

Summary Cyanidium caldarium grows in acid water obtained from a bacterial leaching procedure and the alga is capable of precipitating metals from the solution. This study demonstrates that changes in culture and oxidation-reduction conditions may result in a different bioaccumulation of metals.     

Mechanism of aluminium tolerance in Cyanidium caldarium

Cyanidium caldarium, an acidophilic, thermophilic red alga, specifically tolerates Al. The tolerance increases at lower culture temperatures. The intracellular Al concentration is kept at low levels, especially when the cells are cultured at lower temperatures. Lower Al incorporation accounts for the Al tolerance in this alga. Fe incorporation antagonizes the Al incorporation, implying that Fe transporters incorporate Al ions. Treatment with an uncoupler, carbonylcyanide m-chlorophenylhydrazone, increases the intracellular concentration of Al. These results support the hypothesis that Al ions taken up by the algal cells are exported by an energy-dependent mechanism.     

Heterotrophic growth patterns in the unicellular alga Cyanidium caldarium

A strain of Cyanidium caldarium has been studied which is able to grow in darkness using amino acids as sole energy sources. During growth ammonia was released into the external medium as a catabolic end product. With either threonine or glutamate similar rates of ammonia formation and similar kinetics of growth were observed. These observations suggest that the amounts of energy made available for cell growth from the two amino acids are equivalent.Deamination of threonine and glutamate by whole cells exhibited similar temperature-dependence profiles and similar Arrhenius energies of activation. Thus it is suggested that a partially common pathway is involved in the catabolism of these amino acids. Threonine dehydrase may play a role in this pathway.The threonine dehydrase of C. caldarium was inhibited by isoleucine and activated by valine. In the absence of isoleucine no cooperative effect of threonine was observed.Succinate or 2-ketoglutarate supported a faster growth than did amino acids. Growth tests in the presence of both a krebs cycle intermediate and an amino acid have shown that the oxidative metabolism of amino acids is in some way controlled by the more suitable energy sources, presumably through catabolite inhibition and catabolite repression.     

Phycocyanobilin synthesis in the unicellular rhodophyte Cyanidium caldarium.

A method for the determination of the half-life of mitochondrial translation products in yeast in vivo is proposed. The method uses inhibitors of cytoplasmic and mitochondrial protein synthesis and is based on double-labelling pulse-chase techniques, the second label being used to estimate 'post-incorporation' during the 'chase'. For the first time the difference between post-incroporation and the widely known recycling of the label is considered. These studies show that, in the turnover of mitochondrial translation products, the problem is of post-incorporation into mitochondria (especially from the cell sap) is predominant. The results obtained with this procedure indicate that the half-life of the products of mitochondrial protein synthesis in yeast at the late-exponential phase is about 60 min. The results suggest that mitochondrial transplantation products are subject to proteolysis to acid-soluble forms.     

Chloroplast Nucleoids during Greening of Cyanidium caldarium M-8 Type

Cyanidium caldarium M-8 type grown in the dark was illuminatedfor 3 days, and changes of its cell and cell organelle structuresand of photosynthetic activity were observed quantitatively.Dark grown (DG) cells showed no photosynthetic activity andno phycocyanin. During 3 day illumination they fully recoveredtheir photosynthetic activities as measured by Hill reaction,and also synthesized chlorophyll a and phycocyanins. Sizes ofcell, cell nucleus, chloroplast and its nucleoid observed byfluorescence microscopy after staining with DAPI increased simultaneouslyupon illumination. The chloroplast and its ring shaped nucleoidsizes increased especially rapidly, concomitant with the recoveryof Hill activity. In fully recovered cells after 3 days, a goodcorrelation was found among the sizes of cells, chloroplastsand chloroplast nucleoids. ( Revision received June 28, 1986. Accepted December 23, 1986)     

delta-Aminolevulinic acid synthesis in a Cyanidium caldarium mutant unable to make chlorophyll a and phycobiliproteins.

Wild-type cells of the unicellular rhodophyte, Cyanidium caldarium, synthesize chlorophyll a, phycobiliproteins, and heme from δ-aminolevulinic acid during light-dependent chloroplast development but are unable to make photosynthetic pigments in the dark. C. caldarium, mutant GGB-Y, is an obligate heterotroph which, in the light, produces a chloroplast devoid of photosynthetic pigments. The present investigation has shown that δ-aminolevulinic acid is synthesized in cells of mutant GGB-Y incubated with levulinic acid, a competitive inhibitor of δ-aminolevulinic acid dehydrase (the second enzyme in the porphyrin biosynthetic pathway). In vivo, cells of mutant GGB-Y preferentially incorporated C₁ of glutamate and α-ketoglutarate into the C₅ fragment (formaldehyde) of δ-aminolevulinic acid after alkaline periodate degradation. This suggested that δ-aminolevulinic acid arises directly from the carbon skeleton of glutamate and α-ketoglutaric acid. The pattern of incorporation of C₃, C₄, and C₅ of α-ketoglutarate into the C₁–C₄ (succinic acid) fragment of δ-aminolevulinic acid after alkaline periodate degradation was consistent with the origin of δ-aminolevulinic acid from a five-carbon precursor. C₁ and C₂ of glycine and C₂ and C₃ of succinate were incorporated into both the formaldehyde and succinate fragments of δ-aminolevulinic acid in a manner inconsistent with condensation of glycine and succinyl CoA by δ-aminolevulinic acid synthetase, the rate-limiting enzyme in the porphyrin pathway in animals and bacteria. Extracts of the soluble protein from cells of mutant GGB-Y displayed a Soret band at 410 nm indicating the presence of hemoproteins. This shows that mutant GGB-Y cells synthesize heme. The respiration of radiolabeled glutamate, α-ketoglutarate, and glycine to ¹⁴CO₂ is consistent with the existence of mitochondrial cytochromes in cells of mutant GGB-Y and with the ability of the mutant to synthesize δ-aminolevulinic acid. The present results suggest that δ-aminolevulinic acid is synthesized directly from glutamate or α-ketoglutarate and that this is the only process by which the rate-limiting intermediate in the porphyrin pathway is synthesized in C. caldarium. If correct, the rate-limiting, regulative enzyme in the biosynthetic pathway for synthesis of chlorophyll a, bile pigment (phycocyanobilin), and heme must have been completely different in the evolutionary antecedents of modern-day plants and animals.