Pigment Composition of Two Pigment-Protein Complexes Derived from Anaerobically and Semi-Aerobically Grown Rubrivivax gelatinosus, and Identification of a New Keto-Carotenoid, 2-Ketospirilloxanthin

Pigments of two light-harvesting (LH) pigment-protein complexes,LH 1 and LH 2, isolated from the purple bacterium, Rubrivivaxgelatinosus, grown anaerobically and semi-aerobically in thelight were investigated. In the anaerobic culture, pigment compositionsof both LH 1 and LH 2 complexes were approximately equal; OH-spheroidenewas the major carotenoid accompanying spheroidene and spirilloxanthin.In the semi-aerobic culture, pigment compositions of both complexesagain were approximately equal; an oxidized carotenoid, OH-spheroidenone,was the major component accompanying spheroidenone and 2,2'-diketospirilloxanthin.A novel carotenoid of 2-ketospirilloxanthin, an intermediatebetween spirilloxanthin, and 2,2'-diketospirilloxanthin, wasfound in both LH complexes from the semi-aerobic culture. Basedon these results, we propose the presence of both the spheroideneand the normal spirilloxanthin pathways as the biosyntheticpathway of carotenoids in this bacterium. The oxidation procedureof spirilloxanthin by CrtA was also discussed. ¹ This paper is dedicated to Prof. K. Harashima on the occasionof his 70th birthday and his retirement.     

Characterization of violaxanthin de-epoxidase purified in the presence of Tween 20: effects of dithiothreitol and pepstatin A

Violaxanthin de-epoxidase (VDE) was purified from thylakoid membranes of spinach by conventional column chromatography in the presence of Tween 20. The neutral detergent was necessary to prevent non-specific interaction of VDE with column resins. In anion-exchange chromatography on Mono Q, VDE appeared in two peaks. Both peaks exhibited a polypeptide of 41 kDa when fully reduced with 5 mM dithiothreitol. Re-chromatography of either peak gave rise to both peaks, suggesting that the two forms of VDE are interconvertible. VDE characteristically changed its electrophoretic mobility depending on the concentration of dithiothreitol with which the protein was treated. When non-reduced, it showed two polypeptides of 43 and 42 kDa. These polypeptides moved down to the position of 40 kDa, and then up to the position of 41 kDa, along with the increase in the dithiothreitol concentration from 0 to 2 mM. These findings suggest that VDE has more than one disulfide bond and takes multiple forms depending on the extent of the reduction. Studies with various types of protein-modifying reagent revealed that VDE is sensitive to pepstatin A, a specific inhibitor of aspartic protease. This finding suggests that the reaction center of VDE contains a reactive aspartic acid residue(s).     

Fatty acids of astaxanthin esters in krill determined by mild mass spectrometry

Krill is a major source of astaxanthin, which has strong antioxidant activity. Fractions with astaxanthin monoesters and diesters of Antarctic krill Euphausia superba were isolated. Astaxanthin esters were separated by C18-HPLC depending on the number of carbons and double bonds of esterified fatty acid(s). Small amounts of other lipids remained in the samples, but relative molecular masses of carotenoid esters could be measured by field desorption mass spectrometry without fragmentation and interference from contaminant lipids. The fatty acids were determined by calculation of difference between astaxanthin and astaxanthin esters. Only five kinds of fatty acids, dodecanoate, tetradecanoate, hexadecanoate, hexadecenoate and octadecenoate, were detected. Fast atom bombardment mass spectrometry and secondary ion mass spectrometry showed similar spectra. The fatty acid composition in astaxanthin esters was different from those in krill lipids. Therefore, determination of fatty acids in carotenoid esters by a combination of HPLC elution profile and mild mass spectrometry is found to be a useful tool.     

A single-nucleotide synonymous mutation in the gag gene controlling human immunodeficiency virus type 1 virion production

Viral factors as well as host ones play major roles in the disease progression of human immunodeficiency virus type 1 (HIV-1) infection. We have examined cytotoxic T-lymphocyte activity and HIV-1 DNA PCR results of 312 high-risk seronegative drug users in northern Thailand and identified four seronegative cases positive for both assays. Furthermore, we have identified a synonymous mutation in nucleotide position 75 of the gag p17 gene (A426G) of HIV-1 that belongs to the CRF01_AE virus circulating in Thailand. The replication-competent HIV-1 clone containing the A426G mutation demonstrated a dramatic reduction of virion production and perturbation of viral morphogenesis without affecting viral protein synthesis in cells.     

Expression of transfected human Na+/H+ exchanger (NHE-1) in the basolateral membrane of opossum kidney cells

Some epithelial cells have Na⁺/H⁺ exchanger (NHE) activity in both apical and basolateral membranes. Amiloride-sensitive NHE-1 is generally identified in the basolateral membrane. The renal cell line, OK7a, targets amiloride-resistant NHE predominantly to the apical membrane. It is controversial whether the transfected NHE-1 is targeted preferentially to the basolateral membrane in OK7a cells, when human NHE-1 is chronically expressed under control of constitutively active promoters. We tried to identify the membranes in which the transfected human NHE-1 could be detected following acute expression in OK7a cells. We have always observed small Na⁺-dependent pH recovery in the basolateral membrane in OK7a cells. It is, however, controversial whether or not OK7a cells express NHE activity in the basolateral membrane. We also characterized Na⁺-dependent pH recovery in the basolateral membrane. It was not inhibited by [4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid] (DIDS), [4-acetamido-4′-isothiocyanatostilbene-2,2′-disulfonic acid] (SITS), or contralateral amiloride. Li⁺ but not K⁺, chol⁺, or NMG⁺ could replace Na⁺. These results are consistent with the presence of the NHE in the basolateral membrane. NHE activities were predominant in the apical membrane and those in both membranes were resistant to amiloride analogs. After stable transfection with human NHE-1 in a vector utilizing the metallothionein promoter, overnight induction with Zn²⁺ increased the NHE activity and its sensitivity to amiloride only in the basolateral membrane in OK7a cells. We conclude that the transfected human NHE-1 is exclusively targeted to the basolateral membrane of OK7a cells during acute induction. J Cell Physiol 178:44–50, 1999. © 1999 Wiley-Liss, Inc.     

Na+/H+ exchanger (NHE) in the basolateral membrane is encoded by NHE-1 mRNA in LLC-PK1 clone 4 cells

Several isoforms of Na⁺/H⁺ exchanger (NHE-1–5) have been identified. LLC-PK1 clone 4 (CL4) expresses the amiloride-sensitive type of NHE predominantly in the basolateral membrane, which is believed to be NHE-1. It is not clear whether CL4 expresses NHE in the apical membrane and which side of NHE is encoded by the NHE-1 mRNA. Using acidified CL4 cells on the filter membrane, we examined Na⁺-dependent pH recovery of the apical and basolateral membranes separately. Na⁺ applied to the apical membrane recovered cell pH. Na⁺-dependent pH recovery in the apical membrane was not inhibited by SITS, DIDS, or contralateral amiloride. Li⁺ but not K⁺, chol⁺, or NMG⁺ could replace Na⁺. These data are consistent with the presence of NHE in the apical membrane. Transfection with an antisense oligonucleotide corresponding to the 5′ terminal site of NHE-1 cDNA of CL4 decreased NHE activity in the basolateral membrane but not in the apical membrane. We conclude that CL4 expresses NHE activities in both apical and basolateralmembranes and that NHE-1 mRNA encodes NHE only in the basolateral membrane. J. Cell. Physiol. 171:318–324, 1997. © 1997 Wiley-Liss, Inc.     

Carotenoids in Rhodoplanes Species: Variation of Compositions and Substrate Specificity of Predicted Carotenogenesis Enzymes

Phototrophic bacteria necessarily contain carotenoids for photosynthesis, and accumulate unusual carotenoids in some cases. The carotenoids in all established species of Rhodoplanes (Rpl.), a representative of phototrophic genera, were identified using spectroscopic methods. The major carotenoid was spirilloxanthin in Rpl. roseus and Rpl. serenus, and rhodopin in "Rpl. cryptolactis". Rpl. elegans contained rhodopin, anhydrorhodovibrin, and spirilloxanthin. Rpl. pokkaliisoli contained not only rhodopin but also 1,1'-dihydroxylycopene and 3,4,3',4'-tetrahydrospirilloxanthin. These variations in carotenoid composition suggested that Rpl. roseus and Rpl. serenus had normal substrate specificity of the carotenogenesis enzymes of CrtC (acyclic carotene 1,2-hydratase), CrtD (acyclic carotenoid 3,4-desaturase), and CrtF (acyclic 1-hydroxycarotenoid methyltransferase). On the other hand, CrtC of Rpl. elegans, CrtD of "Rpl. cryptolactis", and CrtC, CrtD, and CrtF of Rpl. pokkaliisoli might have different characteristics from the usual activity of these normal enzymes in the normal spirilloxanthin pathway. These results suggest that the variation of carotenoids among the species of Rhodoplanes results from modified substrate specificity of the carotenogenesis enzymes involved.     

Molecular genetic and chemotaxonomic characterization of the terrestrial cyanobacterium Nostoc commune and its neighboring species

The phylogeny of the terrestrial cyanobacterium Nostoc commune and its neighboring Nostoc species was studied using molecular genetic and chemotaxonomic approaches. At least eight genotypes of N. commune were characterized by the differences among 16S rRNA gene sequences and the petH gene encoding ferredoxin-NADP? oxidoreductase and by random amplified polymorphic DNA analysis. The genotypes of N. commune were distributed in Japan without regional specificity. The nrtP gene encoding NrtP-type nitrate/nitrite permease was widely distributed in the genus Nostoc, suggesting that the occurrence of the nrtP gene can be one of the characteristic features that separate cyanobacteria into two groups. The wspA gene encoding a 36-kDa water stress protein was only found in N. commune and Nostoc verrucosum, suggesting that these Nostoc species that form massive colonies with extracellular polysaccharides can be exclusively characterized by the occurrence of the wspA gene. Fifteen species of Nostoc and Anabaena were investigated by comparing their carotenoid composition. Three groups with distinct patterns of carotenoids were related to the phylogenic tree constructed on the basis of 16S rRNA sequences. Nostoc commune and Nostoc punctiforme were clustered in one monophyletic group and characterized by the occurrence of nostoxanthin, canthaxanthin, and myxol glycosides.     

Introduction of new carotenoids into the bacterial photosynthetic apparatus by combining the carotenoid biosynthetic pathways of Erwinia herbicola and Rhodobacter sphaeroides.

Carotenoids have two major functions in bacterial photosynthesis, photoprotection and accessory light harvesting. The genes encoding many carotenoid biosynthetic pathways have now been mapped and cloned in several different species, and the availability of cloned genes which encode the biosynthesis of carotenoids not found in the photosynthetic genus Rhodobacter opens up the possibility of introducing a wider range of foreign carotenoids into the bacterial photosynthetic apparatus than would normally be available by producing mutants of the native biosynthetic pathway. For example, the crt genes from Erwinia herbicola, a gram-negative nonphotosynthetic bacterium which produces carotenoids in the sequence of phytoene, lycopene, beta-carotene, beta-cryptoxanthin, zeaxanthin, and zeaxanthin glucosides, are clustered within a 12.8-kb region and have been mapped and partially sequenced. In this paper, part of the E. herbicola crt cluster has been excised and expressed in various crt strains of Rhodobacter sphaeroides. This has produced light-harvesting complexes with a novel carotenoid composition, in which the foreign carotenoids such as beta-carotene function successfully in light harvesting. The outcome of the combination of the crt genes in R. sphaeroides with those from E. herbicola has, in some cases, resulted in an interesting rerouting of the expected biosynthetic sequence, which has also provided insights into how the various enzymes of the carotenoid biosynthetic pathway might interact. Clearly this approach has considerable potential for studies on the control and organization of carotenoid biosynthesis, as well as providing novel pigment-protein complexes for functional studies.     

Carotenogenesis diversification in phylogenetic lineages of Rhodophyta

Carotenoid composition is very diverse in Rhodophyta. In this study, we investigated whether this variation is related to the phylogeny of this group. Rhodophyta consists of seven classes, and they can be divided into two groups on the basis of their morphology. The unicellular group (Cyanidiophyceae, Porphyridiophyceae, Rhodellophyceae, and Stylonematophyceae) contained only β‐carotene and zeaxanthin, “ZEA‐type carotenoids.” In contrast, within the macrophytic group (Bangiophyceae, Compsopogonophyceae, and Florideophyceae), Compsopogonophyceae contained antheraxanthin in addition to ZEA‐type carotenoids, “ANT‐type carotenoids,” whereas Bangiophyceae contained α‐carotene and lutein along with ZEA‐type carotenoids, “LUT‐type carotenoids.” Florideophyceae is divided into five subclasses. Ahnfeltiophycidae, Hildenbrandiophycidae, and Nemaliophycidae contained LUT‐type carotenoids. In Corallinophycidae, Hapalidiales and Lithophylloideae in Corallinales contained LUT‐type carotenoids, whereas Corallinoideae in Corallinales contained ANT‐type carotenoids. In Rhodymeniophycidae, most orders contained LUT‐type carotenoids; however, only Gracilariales contained ANT‐type carotenoids. There is a clear relationship between carotenoid composition and phylogenetics in Rhodophyta. Furthermore, we searched open genome databases of several red algae for references to the synthetic enzymes of the carotenoid types detected in this study. β‐Carotene and zeaxanthin might be synthesized from lycopene, as in land plants. Antheraxanthin might require zeaxanthin epoxydase, whereas α‐carotene and lutein might require two additional enzymes, as in land plants. Furthermore, Glaucophyta contained ZEA‐type carotenoids, and Cryptophyta contained β‐carotene, α‐carotene, and alloxanthin, whose acetylenic group might be synthesized from zeaxanthin by an unknown enzyme. Therefore, we conclude that the presence or absence of the four enzymes is related to diversification of carotenoid composition in these three phyla.