J. Kenneth Hoober

Biosynthesis of Δ-aminolevulinate in greening barley leaves. IX. Structure of the substrate, mode of gabaculine inhibition, and the catalytic mechanism of glutamate 1-semialdehyde aminotransferase

Glutamic acid 1-semialdehyde hydrochloride was synthesized and purified. Its prior structural characterization was extended and confirmed by1H NMR spectroscopy and chemical analyses. In aqueous solution at pH 1 to 2 glutamic acid 1-semialdehyde exists in a stable hydrated form, but at pH 8.0 it has a half-life of 3 to 4 min. Spontaneous degradation of the material at pH 8.0 generated some undefined condensation products, but coincidentally a significant amount isomerized to 5-aminolevulinate. At pH 6.8 to 7.0, glutamate 1-semialdehyde is sufficiently stable to permit routine and reproducible assay for glutamate 1-semialdehyde aminotransferase activity. Only about 20% of the enzyme extracted from chloroplasts was sensitive to inactivation by gabaculine with no pretreatment. However, when the enzyme was exposed to 5-aminolevulinate, levulinate or 4,5-dioxovalerate in the absence of glutamate 1-semialdehyde, it was completely inactivated by gabaculine; 4,6-dioxoheptanoate had no effect on the enzyme. These results lead to the hypothesis that the aminotransferase exists in the chloroplast in a complex with pyridoxamine phosphate, which must be converted to the pyridoxal form before it can form a stable adduct with gabaculine. We propose that the enzyme catalyzes the conversion of glutamate 1-semialdehyde to 5-aminolevulinate via 4,5-diaminovalerate.

Chlorophylls, ligands and assembly of light-harvesting complexes in chloroplasts

Chlorophyll (Chl) b serves an essential function in accumulation of light-harvesting complexes (LHCs) in plants. In this article, this role of Chl b is explored by considering the properties of Chls and the ligands with which they interact in the complexes. The overall properties of the Chls, not only their spectral features, are altered as consequences of chemical modifications on the periphery of the molecules. Important modifications are introduction of oxygen atoms at specific locations and reduction or desaturation of sidechains. These modifications influence formation of coordination bonds by which the central Mg atom, the Lewis acid, of Chl molecules interacts with amino acid sidechains, as the Lewis base, in proteins. Chl a is a versatile Lewis acid and interacts principally with imidazole groups but also with sidechain amides and water. The 7-formyl group on Chl b withdraws electron density toward the periphery of the molecule and consequently the positive Mg is less shielded by the molecular electron cloud than in Chl a. Chl b thus tends to form electrostatic bonds with Lewis bases with a fixed dipole, such as water and, in particular, peptide backbone carbonyl groups. The coordination bonds are enhanced by H-bonds between the protein and the 7-formyl group. These additional strong interactions with Chl b are necessary to achieve assembly of stable LHCs.

Assembly of light-harvesting complex II and biogenesis of thylakoid membranes in chloroplasts

A critical review of studies on import of Lhcb (apoproteins of LHC II) by chloroplasts uncovered a mechanism for initiation of assembly of light-harvesting complexes. Manipulation of in vivo systems and mutagenesis of specific residues in the protein showed that accumulation of physiological amounts of Lhcb by the plastid requires interaction of the protein with Chl within the inner membrane of the chloroplast envelope. ‘Retention motifs’, commonly -EXXHXR- in the first membrane-spanning region (helix-1) and -EXXNXR- in the third membrane-spanning region (helix-3), occur in the primary sequence of the protein. Mutations in these sequences prevent accumulation of Lhcb by isolated chloroplasts. We propose that the His or Asn sidechain and a transient intrahelix ion-pair with the Glu and Arg residues provide ligands for two molecules of Chl in each motif, which serve as a sensing mechanism for the availability of Chl. Interaction of two Chl molecules with both motifs is required for stable insertion of the protein into the membrane. Chl(ide) is possibly quenched by interaction with xanthophylls immediately after synthesis, and Chl-lutein pairs may initiate folding of Lhcb. Lhcb that does not immediately interact with sufficient Chl molecules is not retained by the organelle and, in vivo, is retracted into the cytosol or shunted to vacuoles for degradation rather than imported into the plastid stroma. The ubiquitous existence of retention motifs from small Lhcb-like polypeptides in cyanobacteria to all nuclear-encoded Chl-binding proteins (the Lhcb and Lhca families and related proteins) testify to the importance of these sequences in assembly of Chl-protein complexes.

PHOTODYNAMIC SENSITIZERS FROM CHLOROPHYLL:PURPURIN–18 AND CHLORINp6

Abstract— Two easily prepared derivatives of chlorophyll,purpurin–18 and chlorin p6, are potent sensitizers of cell killing by low‐intensity red light. The internal anhydride group inpurpurin–18 provides the potential of covalently linking in one step the chlorin to cell targeting agents such as antibodies.

Synthesis of chlorophyll b : Localization of chlorophyllide a oxygenase and discovery of a stable radical in the catalytic subunit

BackgroundAssembly of stable light-harvesting complexes (LHCs) in the chloroplast of green algae and plants requires synthesis of chlorophyll (Chl) b, a reaction that involves oxygenation of the 7-methyl group of Chl a to a formyl group. This reaction uses molecular oxygen and is catalyzed by chlorophyllide a oxygenase (CAO). The amino acid sequence of CAO predicts mononuclear iron and Rieske iron-sulfur centers in the protein. The mechanism of synthesis of Chl b and localization of this reaction in the chloroplast are essential steps toward understanding LHC assembly.ResultsFluorescence of a CAO-GFP fusion protein, transiently expressed in young pea leaves, was found at the periphery of mature chloroplasts and on thylakoid membranes by confocal fluorescence microscopy. However, when membranes from partially degreened cells of Chlamydomonas reinhardtii cw15 were resolved on sucrose gradients, full-length CAO was detected by immunoblot analysis only on the chloroplast envelope inner membrane. The electron paramagnetic resonance spectrum of CAO included a resonance at g = 4.3, assigned to the predicted mononuclear iron center. Instead of a spectrum of the predicted Rieske iron-sulfur center, a nearly symmetrical, approximately 100 Gauss peak-to-trough signal was observed at g = 2.057, with a sensitivity to temperature characteristic of an iron-sulfur center. A remarkably stable radical in the protein was revealed by an isotropic, 9 Gauss peak-to-trough signal at g = 2.0042. Fragmentation of the protein after incorporation of 125I- identified a conserved tyrosine residue (Tyr-422 in Chlamydomonas and Tyr-518 in Arabidopsis) as the radical species. The radical was quenched by chlorophyll a, an indication that it may be involved in the enzymatic reaction.ConclusionCAO was found on the chloroplast envelope and thylakoid membranes in mature chloroplasts but only on the envelope inner membrane in dark-grown C. reinhardtii cells. Such localization provides further support for the envelope membranes as the initial site of Chl b synthesis and assembly of LHCs during chloroplast development. Identification of a tyrosine radical in the protein provides insight into the mechanism of Chl b synthesis.

Chlorophyll Binding to Peptide Maquettes Containing a Retention Motif

The motif Glu-X-X-His/Asn-X-Arg is conserved in the first and third membrane-spanning domains of all light-harvesting chlorophyll a/b- anda/c-binding proteins in chloroplasts. Molecular modeling of synthetic peptides containing the sequence Glu-Ile-Val-His-Ser-Arg, a motif found in the apoprotein of the major light-harvesting complex in plants, generated a loop structure formed by intrapeptide, electrostatic attraction between Glu and Arg. His, Asn, and charge-compensated Glu-Arg pairs are known ligands of the magnesium atom in chlorophyll. The prediction that this structure should bind two molecules of chlorophyll was confirmed experimentally with an assay based on fluorescence resonance energy transfer between peptides and chlorophyll a. Motifs with both potential ligands bound approximately two times the amount of chlorophyll as one in which His was replaced by Ala. These results support the conclusion that formation of this intermediate, within membranes of the envelope, is a crucial step in assembly of light-harvesting complexes and a mechanism that regulates import of the apoproteins into the chloroplast.

TRANSFER OF PROTEINS FROM THE CHLOROPLAST TO VACUOLES IN CHLAMYDOMONAS REINHARDTII (CHLOROPHYTA): A PATHWAY FOR DEGRADATION

Several chloroplast proteins were detected by immunoelectron microscopy within dense granules in cytoplasmic vacuoles in the alga Chlamydomonas reinhardtii Dangeard. Transfer from chloroplast to vacuoles of two major, pulse‐labeled polypeptides, the large subunit of rubisco and the α subunit of ATPase, which are synthesized on chloroplast ribosomes, was demonstrated by the recovery of these polypeptides in vacuolar granules over a several‐hour time period. The ultrastructure of cryofixed algal cells was examined to search for structures that would provide insight into the transfer of chloroplast proteins to vacuoles. Micrographs showed that the two membranes of the envelope were appressed, with no detectable intermembrane space, over most of the chloroplast surface. Protrusions of the outer membrane of the envelope were occasionally found that enclosed stroma, with particles similar in size to chloroplast ribosomes, but generally not thylakoid membranes. These observations suggest that chloroplast material, especially the stromal phase, was extruded from the chloroplast in membrane‐bound structures, which then interacted with Golgi‐derived vesicles for degradation of the contents by typical lysosomal activities. A protein normally targeted to vacuoles through the endomembrane system for incorporation into the cell wall was detected in Golgi structures and vacuolar granules but not the chloroplast.

Purification and Characterization of a Membrane-Bound Protease from Chlamydomonas reinhardtii.

In Chlamydomonas reinhardtii y-1, newly synthesized chlorophyll a/b-binding apoproteins are degraded when chlorophylls are not present for assembly of stable light-harvesting complexes. A protease was purified from the membrane fraction of degreened y-1 cells, which digested chlorophyll a/b-binding proteins in membranes from C. reinhardtii pg-113, a protease-deficient strain. This protease was active with p-nitroanilides of nonpolar amino acids (Leu and Phe), but not of basic amino acids (Lys and Arg). The apparent molecular weight of the enzyme is 38,000 +/- 2,000 as determined by electrophoresis in the presence of sodium dodecyl sulfate. Typical inhibitors of the major classes of proteases were ineffective with this enzyme. Protease activity was constant from pH 7.5 to 9; a plot of log V versus pH suggested that deprotonation of an ionizable group with a pK value of 6.0 to 6.5 is required for activity. The protease was inactivated by diethylpyrocarbonate and by photooxidation sensitized by rose bengal. These results suggested that a histidyl residue is required for catalysis. Although very sensitive to photodynamic conditions in vitro, the enzyme was not inactivated in vivo when cells were exposed to light.

Structural similarities between the major polypeptides of thylakoid membranes from Chlamydomonas reinhardtii

Abstract The major polypeptides of thylakoid membranes from Chlamydomonas reinhardtii were purified by preparative gel electrophoresis and examined for structural similarities. The largest of these polypeptides has an apparent molecular mass of 29,500 ± 500 daltons, whereas the other two both have an apparent mass of 26,000 ± 500 daltons. The amino acid compositions and uv-absorption spectra of the 29K- and 26K-dalton polypeptides are very similar. The same pattern of release of amino acids was obtained from both fractions by digestion with carboxypeptidase Y. Endoproteolytic digestion with trypsin, chymotrypsin, staphylococcal protease, and mild acid yielded identical patterns of N-terminal amino acids from both the 29K- and 26K-dalton polypeptides. However, different patterns of peptides were found after electrophoresis of fragments generated by digestion with staphylococcal protease. Conditions of electrophoresis were defined that permitted separation of the 26K-dalton fraction into two components, designated as polypeptides 16 and 17 in the identification system of Chua and Bennoun (1975 , Proc. Nat. Acad. Sci. USA72, 2175–2179). Amino acid compositions of these two polypeptides are nearly identical. Polypeptide 16 contained N-terminal isoleucine, but no free N-terminal amino group was detected in polypeptide 17. Electrophoretic analysis of staphylococcal protease digests of these two polypeptides revealed significant differences in the patterns of peptides. These data confirm that there are three distinct major polypeptides in these membranes, which are present at nearly equal amounts. However, the data also suggest that significant similarities in amino acid sequence exist between these polypeptides.

Tumoricidal capacities of macrophages photodynamically activated with hematoporphyrin derivative

Four days after administration to mice of small amounts (30–600ng/mouse) of hematoporphyrin derivative (HPD), peritoneal macrophages exhibited a greatly enhanced Fc‐receptor mediated phagocytic capacity as assayed by ingestion activity of IgG‐coated sheep erythrocytes. Much higher doses (>3000 ng/mouse) did not have this effect. The peritoneal macrophages activated by administration of HPD have tumoricidal capacity for IgG‐coated retinoblastoma cells. We then studied in vitro photodynamic activation of macrophages by white and red fluorescent light irradiation of mouse peritoneal cells (mixture of macrophages and B and T lymphocytes) in media containing very low concentrations of HPD. A short (5 s) white fluorescent light exposure (lWm‐2) of peritoneal cells in a medium containing 0.03 ng HPD/mL produced the maximal level of ingestion activity of macrophages. A 15 s red fluorescent light exposure (lWm‐Z) of peritoneal cells in a medium containing 0.1 ng HPD/mL produced the maximal level of ingestion activity of macrophages. Thus, photodynamic activation of macrophages with white fluorescent light is more efficient than that with red fluorescent light. This can be explained by the fact that HPD has a large absorption peak at about 364 nm which extends into the visible range, and decreasingly smaller absorption bands at 500, 535, 570 and 630 nm. In vitro photodynamically activated macrophages showed efficient tumoricidal activity regardless of the type (white or red) of light used. These results suggest that a low level of HPD promotes therapeutic immunopotentiation