Erhard Mörschel

Isolation and characterization of biliprotein aggregates from Acaryochloris marina, a Prochloron-like prokaryote containing mainly chlorophyll d

Phycobiliprotein aggregates were isolated from the prokaryote Acaryochloris marina, containing chlorophyll d as major pigment. In the electron microscope the biliprotein aggregates appear as rod‐shaped structures of 26.0×11.3 nm, composed of four ring‐shaped subunits 5.8 nm thick and 11.7 nm in diameter. Spectral data indicate that the aggregates contain two types of biliproteins: phycocyanin and an allophycocyanin‐type pigment, with very efficient energy transfer from the phycocyanin‐ to allophycocyanin‐type constituent. The chromophore‐binding polypeptides of the pigments have apparent molecular masses of 16.2 and 17.4 kDa. They crossreact with antibodies against phycocyanin and allophycocyanin from a red alga.

Correlation of photosystem-II complexes with exoplasmatic freeze-fracture particles of thylakoids of the cyanobacterium Synechococcus sp.

The supramolecular structure of the exoplasmic freeze-fracture particles of thylakoids of the thermophilic cyanobacterium Synechococcus sp. is compared with that of isolated photosystem-II complexes. The in-situ EF particles are scattered on the thylakoids or organized in rows of variable length; the latter aligned particles measure 10 nmx20 nm and are separated perpendicular to their long axis into two parts. We propose that they represent dimers composed of two monomeric 10-nm EF particles side by side. Isolated photosystem (PS)II particles correspond in size to the monomeric 10-nm EF particles as analysed by negative contrast and freeze-fracture electron microscopy. Dimeric PSII particles, very similar to the in-situ 10 nmx20 nm EF particles, are obtained after incorporation of purified PSII complexes into liposomes made from phospholipid and cholesterol. Each monomeric complex consists of the reaction center, the water-splitting system, the chlorophyll antennae and phycobilisome-binding polypeptides. We propose that the dimeric complexes bind one hemidiscoidal phycobilisome at their domains exposed to the external side of the thylakoids. The implications of this arrangement of the PSII-phycobilisome complexes within the thylakoids upon excitation-energy distribution are discussed.

Molecular structure, localization and function of biliproteins in the chlorophyll a/d containing oxygenic photosynthetic prokaryote Acaryochloris marina

We investigated the localization, structure and function of the biliproteins of the oxygenic photosynthetic prokaryote Acaryochloris marina, the sole organism known to date that contains chlorophyll d as the predominant photosynthetic pigment. The biliproteins were isolated by means of sucrose gradient centrifugation, ion exchange and gel filtration chromatography. Up to six biliprotein subunits in a molecular mass range of 15.5-18.4 kDa were found that cross-reacted with antibodies raised against phycocyanin or allophycocyanin from a red alga. N-Terminal sequences of the alpha- and beta-subunits of phycocyanin showed high homogeneity to those of cyanobacteria and red algae, but not to those of cryptomonads. As shown by electron microscopy, the native biliprotein aggregates are organized as rod-shaped structures and located on the cytoplasmic side of the thylakoid membranes predominantly in unstacked thylakoid regions. Biochemical and spectroscopic analysis revealed that they consist of four hexameric units, some of which are composed of phycocyanin alone, others of phycocyanin together with allophycocyanin. Spectroscopic analysis of isolated photosynthetic reaction center complexes demonstrated that the biliproteins are physically attached to the photosystem II complexes, transferring light energy to the photosystem II reaction center chlorophyll d with high efficiency.

Development of Nodules of Glycine max Infected with an Ineffective Strain of Rhizobium japonicum

Bacteroids in ineffective (nitrogenase negative) nodules of Glycine max, infected with Rhizobium japonicum 61-A-24, as compared to those in effective nodules are characterized by reduced specific activities of alanine dehydrogenase to 15%, of 3-hydroxybutyrate dehydrogenase to 50%, and an increase of glutamine synthetase to 400%. In the plant cytoplasm of ineffective nodules, glutamine synthetase activity is reduced to 10–30%, glutamate dehydrogenase to 50–70%, and the aspartate aminotransferase and alanine aminotransferase are enhanced to 120–200%, depending on the age of the nodules. The total pool of soluble amino acids is reduced to 52 μmol per g nodule fresh weight, as compared to 186 μmol in effective nodules, with a replacement of asparagine (42 mol% of the amino acids) by an unknown amino compound. This compound is absent in nitrogenase, repressed and derepressed, free-living Rhizobium japonicum cells and in the uninfected root tissue. In nitrogenase derepressed, as compared to the repressed free-living cells of Rhizobium japonicum 61-A-101, arginine shows the most obvious change with a reduction to less than one tenth. The ultrastructure of the ineffective nodule is different from the effective organ even in the early stages. The membrane envelopes of the infection vacuoles are decomposing in heavily infected cells within 18 to 20 d after infection. In lightly infected cells very large vacuoles develop with only a few bacteroids inside. No close associations of cristae-rich mitochondria with amyloplasts are observed as in effective nodules. The uninfected cells keep their large starch granules even 40 d after infection. Some poly-β-hydroxybutyrate accumulation in the bacteroids is observed but only in the early stages, and it is almost absent in old nodules (40 d). At this age the infected cells are obviously compressed by uninfected cells, whereas in effective nodules with nitrogenase activity and leghaemoglobin formation, the infected cells have a much higher osmotic pressure than the neighbouring uninfected cells.

Differentiation of nodules of Glycine max : Ultrastructural studies of plant cells and bacteroids.

Plants of Glycine max var. Caloria, infected as 14 d old seedlings with a defined titre of Rhizobium japonicum 3Il b85 in a 10 min inoculation test, develop a sharp maximum of nitrogenase activity between 17 and 25 d after infection. This maximum (14±3 nmol C2H4 h-1 mg nodule fresh weight-1), expressed as per mg nodule or per plant is followed by a 15 d period of reduced nitrogen fixation (20–30% of peak activity). 11 d after infection the first bacteroids develop as single cells inside infection vacuoles in the plant cells, close to the cell wall and infection threads. As a cytological marker for peak multiplication of bacteroids and for peak N2-fixation a few days later the association of a special type of nodule mitochondria with amyloplasts is described. 20 d after inoculation, more than 80% of the volume of infected plant cells is occupied by infection vacuoles, mostly containing only one bacteroid. The storage of poly-β-hydroxybutyrate starts to accumulate at both ends of the bacteroids. Non infected plant cells are squeezed between infected cells (25d), with infection vacuoles containing now more than two (up to five) bacteroids per section. Bacteroid development including a membrane envelope is also observed in the intercellular space between plant cells. 35 d after infection, more than 50% of the bacteroid volume is occupied by poly-β-hydroxybutyrate. The ultrastructural differentiation is discussed in relation to some enzymatic data in bacteroids and plant cell cytoplasm during nodule development.

Biliprotein Assembly in the Disc-Shaped Phycobilisomes of Rhodella violacea

Heterogeneous complexes with a molecular weight of about 790000 containing B-phycoerythrin (Bangiales phycoerythrin) and C-phycocyanin (Cyanophyceae phycocyanin) in a molar pigment ratio of 2:1 were isolated from purified, dissociated phycobilisomes. Electron microscopical investigations revealed structures of three discs aggregated face to face with an apparent distance of 1.5 nm between each disc. Two discs may represent phycoerythrin and one phycocyanin. The complexes are structurally identical with tripartite units of the phycobilisome periphery. Fluorescence data confirmed the integrity of isolated tripartite units. Excitation at 546 nm gives a fluorescence maximum at 644 nm, indicating intermolecular transfer of excitation energy from phycoerythrin to phycocyanin. Comparative subunit analyses and spectral data suggested that no allophycocyanin is present. Cross-linking experiments gave evidence for a polar arrangement of phycocyanin within the complex. This pigment itself is an aggregate of two smaller molecules each having a molecular weight of about 140000. Tripartite units contain all the phycoerythrin and phycocyanin of the phycobilisome. On this basis, a phycobilisome model is proposed which combines the aspects of biliprotein distribution, energy transfer and fine structure.

Cryptomonad biliprotein: phycocyanin-645 from a Chroomonas species.

The properties of phycocyanin-645 from the fresh water cryptomonad Chroomonas spec. were investigated after the pigment was isolated and purified by a combination of differential ammonium sulphate fractionation, gel filtration chromatography and ammonium sulphate gradient elution.Phycocyanin-645 is characterized by absorption maxima at 645 nm, 584 nm, 369 nm, 275 nm and shoulders at 340 nm and 620 nm. The CD spectrum has a negative maximum at 645 nm and a positive maximum at 584 nm with a shoulder at 610 nm.The fluorescence emission spectrum is asymmetrical and shows a maximum at 660 nm and a shoulder at approximately 715 nm. The molecular weight of the native phycocyanin-645, estimated by gel filtration, is 45000 for all multiple pigment forms below.Phycocyanin-645 is heterogenous in charge as revealed by isoelectric focusing with pIs at 7.03, 6.17, 5.75, 5.25 and 4.88, respectively, the main bands lying at pI 7.03 and pI 6.17. This was confirmed by polyacrylamide gel electrophoresis; five pigment components differing in mobility were found. We propose the term “multiple pigment forms” for these five phycocyanin-645 modifications.Calibrated SDS gel electrophoresis shows phycocyanin-645 to consist of three subunits, two light chains (α1, α2), having molecular weights of 9200 and 10400, respectively, and one heavy chain (β), having a molecular weight of 15500. Suggesting a 1:1:2 ratio between the subunits, the quaternary structure of the pigment molecule is α1β1-α2β1.

Lysis of bacterioids in the vicinity of the host cell nucleus in an ineffective (fix-) root nodule of soybean (Glycine max)

In nodules of Glycine max cv. Mandarin infected with a nod +fix- mutant of Rhizobium japonicum (RH 31-Marburg), lysis of bacteroids was observed 20 d after infection, but occurred in the region around the host cell nucleus, where lytic compartments were formed. Bacteroids, and peribacteroid membranes in other parts of the host cell remained stable until senescence (40d after infection). With two other nod+ fix- mutants of R. japonicum either stable bacteroids and peribacteroid membranes were observed throughout the cell (strain 61-A-165) or a rapid degeneration of bacteroids without an apparent lysis (strain USDA 24) occurred. The size distribution of RH 31-Marburg-infected nodules exhibited only two maxima compared with four in wild-type nodules and nodule leghaemoglobin content was found to be reduced to about one half that of the wild type. The RH 31-Marburg-nodule type is discussed in relation to the stability of the bacteroids and the peribacteroid membrane system in soybean.

Biliprotein assembly in the disc-shaped phycobilisomes of Rhodella violacea electron microscopical and biochemical analyses of C-phycocyanin and allophycocyanin aggregates

C-phycocyanin and allophycocyanin from the red alga Rhodella violacea were investigated by electron microscopy and biochemical methods using samples taken from the same fractions.The molecular weights of the native biliprotein aggregates C-phycocyanin and allophycocyanin are about 139,000 (140,000) and 130,000 (145,000) as revealed by calibrated gel chromatography, gradient gel electrophoresis and morphological measurements on the basis of an average protein packing density. These molecular weights are direct evidence for a trimeric aggregation form (αβ)3 of these biliproteins. Independently, their monomers were determined to be about 34,400 (C-phycocyanin) and 33,900 (allophycocyanin).C-phycocyanin and allophycocyanin are ringshaped, six-membered, biliprotein aggregates with dimensions of about 10.2×3.0 nm and 10.0×3.0 nm, respectively. The aggregates are made up of six subunits, 3α and 3β, which are assumed to be associated in alternating positions. They are arranged in regular hexagons in C6 symmetry. Hexameric aggregates (αβ)6, so far only isolated for C-phycocyanin, originate by face to face association of two trimeric aggregates.

Multiple forms of phycoerythrin-545 from Cryptomonas maculata

Three multiple phycoerythrin-545 forms were purified from crude extracts of Cryptomonas maculata by preparative isoelectric focusing. The phycoerythrin forms are charge isomers with isoelectric points at 7.83, 5.05 and 4.84. The multiple pigment forms have similar molecular weights of 44500 daltons and are composed of subunits of unequal size in a 1:1 stoichiometry with molecular weights of (α) 9900 and (β) 15700 daltons, twice. The proposed quarternary structure of the native pigments is (α)2(β)2.The charge differences of the phycoerthrins are caused by a charge heterogeneity of the light α subunits, as revealed by urea gel electrophoresis. The α chains of pigment form pI 7.83 had a greater electrophoretic mobility than those α subunits of the acidic pigment forms pI 5.05 and pI 4.84.The phycoerythrin forms have an absorption spectrum with similar absorption maxima at 544 nm, but differ in the position of the long wavelength shoulders lying at 555 and 557 nm in the negatively charged pigment forms and at 560 nm for the phycoerythrin form with a pI at 7.83.The fluorescence emission spectra coincide in their asymmetrical shape with shoulders at about 620 nm; they slightly differ int he position of the emission maxima at 586 nm for the phycoerythrins with pIs at 4.84 and 5.05 and at 584 nm for phycoerythrin with pI at 7.83.