Post-translational methylation of asparaginyl residues. Identification of beta-71 gamma-N-methylasparagine in allophycocyanin

A novel post-translationally modified residue, gamma-N-methylasparagine, was detected in the beta subunit of Anabaena variabilis allophycocyanin. Structure determination was accomplished by isolating a decapeptide, AP-beta (63-72) shown to have the following structure: Ser-Asp-Ile-Thr-Arg-Pro-Gly-Gly- Asn[N-CH3]-homoserine lactone Fast atom bombardment-mass spectrometry established that the residue corresponding to position 71 in the protein (DeLange, R. J., Williams, L. C., and Glazer, A. N. (1981) J. Biol. Chem. 256, 9558-9566) contained 13 mass units more than expected for aspartic acid though aspartic acid was recovered after acid hydrolysis. The 1H NMR spectrum of AP-beta (63-72) revealed a strong methyl single at 2.71 ppm characteristic of the methyl derivative of an amide nitrogen. Confirmation of this bond arrangement was obtained by detection of a stoichiometric amount of methylamine in acid hydrolysates of the peptide. This is the first report of gamma-N-methylasparagine in a protein. Amino acid analysis of A. variabilis allophycocyanin subunits showed that the derivative at position 71 can account for the total methylamine released from the beta subunit, while hydrolysis of the alpha subunit released no methylamine. The beta subunits of the allophycocyanins from the cyanobacterium Synechococcus PCC 6301 and the red alga Porphyridium cruentum each released 1 eq of methylamine upon acid hydrolysis. No methylamine was released from the alpha subunits.     

Phycobiliprotein methylation. Effect of the gamma-N-methylasparagine residue on energy transfer in phycocyanin and the phycobilisome

The phycobiliproteins contain a conserved unique modified residue, gamma-N-methylasparagine at beta-72. This study examines the consequences of this methylation for the structure and function of phycocyanin and of phycobilisomes. An assay for the protein asparagine methylase activity was developed using [methyl-3H]S-adenosylmethionine and apophycocyanin purified from Escherichia coli containing the genes for the alpha and beta subunits of phycocyanin from Synechococcus sp. PCC 7002 as substrates. This assay permitted the partial purification, from Synechococcus sp. PCC 6301, of the activity that methylates phycocyanin and allophycocyanin completely at residue beta-72. Using the methylase assay, two independent nitrosoguanidine-induced mutants of Synechococcus sp. PCC 7942 were isolated that do not exhibit detectable phycobiliprotein methylase activity. These mutants, designated pcm 1 and pcm 2, produce phycocyanin and allophycocyanin unmethylated at beta-72. The phycobiliproteins in these mutants are assembled into phycobilisomes and can be methylated in vitro by the partially purified methylase from Synechococcus sp. PCC 6301. The mutants produce phycobiliproteins in amounts comparable to those of wild-type and the mutant and wild-type phycocyanins are equivalent with respect to thermal stability profiles. Monomeric phycocyanins purified from these strains show small spectral shifts that correlate with the level of methylation. Phycobilisomes from the mutant strains exhibit defects in energy transfer, both in vivo and in vitro, that are also correlated with deficiencies in methylation. Unmethylated or undermethylated phycobilisomes show greater emission from phycocyanin and allophycocyanin and lower fluorescence emission quantum yields than do fully methylated particles. The results support the conclusion that the site-specific methylation of phycobiliproteins contributes significantly to the efficiency of directional energy transfer in the phycobilisome.     

Cyanobacterial phycobilisomes. Characterization of the phycobilisomes of Synechococcus sp. 6301.

A procedure is described for the preparation of stable phycobilisomes from the unicellular cyanobacterium Synechococcus sp. 6301 (also known as Anacystis nidulans). Excitation of the phycocyanin in these particles at 580 nm leads to maximum fluorescence emission, from allophycocyanin and allophycocyanin B, at 673 nm. Electron microscopy shows that the phycobilisomes are clusters of rods. The rods are made up of stacks of discs which exhibit the dimensions of short stacks made up primarily of phycocyanin (Eiserling, F. A., and Glazer, A. N. (1974) J. Ultrastruct. Res. 47, 16-25). Loss of the clusters, by dissociation into rods under suitable conditions, is associated with loss of energy transfer as shown by a shift in fluorescence emission maximum to 652 nm. Synechococcus sp. 6301 phycobilisomes were shown to contain five nonpigmented polypeptides in addition to the colored subunits (which carry the covalently bound tetrapyrrole prosthetic groups) of the phycobiliproteins. Evidence is presented to demonstrate that these colorless polypeptides are genuine components of the phycobilisome. The nonpigmented polypeptides represent approximately 12% of the protein of the phycobilisomes; phycocyanin, approximately 75%, and allophycocyanin, approximately 12%. Spectroscopic studies that phycocyanin is in the hexamer form, (alpha beta)6, in intact phycobilisomes, and that the circular dichroism and absorbance of this aggregate are little affected by incorporation into the phycobilisome structure.     

Phycoerythrins of marine unicellular cyanobacteria. III. Sequence of a class II phycoerythrin

The genes for the alpha and beta subunits of a novel six bilin-bearing (class II) phycoerythrin were cloned from Synechococcus sp. WH8020 and sequenced. The cloned genes (mpeA and mpeB) were detected by homology with the genes for C-phycoerythrin from Pseudanabaena sp. PCC7409. The mpe locus occurs once in the genome and is arranged similarly to that of many other phycobiliproteins, with mpeA shortly 3' of mpeB. Sequence comparison suggests that this phycoerythrin (and perhaps all class II phycoerythrins) occupy a branch of the phycoerythrin family separate from five-chromophore per alpha beta (class I) phycoerythrins, C-phycoerythrin, and B-phycoerythrin. The position of the sixth chromophore of the class II phycoerythrin of WH8020 was determined by comparison of the amino acid sequence of the chromopeptides (Ong, L. J., and Glazer, A. N. (1991) J. Biol Chem. 266, 9515-9527) with the sequence deduced from the gene. This located the chromophore at residue 75 of the alpha subunit, very close to the alpha-83 chromophore in the primary structure and, presumably, in the three-dimensional structure.     

Detection of methylated asparagine and glutamine residues in polypeptides

A residue of gamma-N-methylasparagine (gamma-NMA) is found at position beta-72 of many phycobiliproteins. delta-N-Methylglutamine is present in some bacterial ribosomal proteins. gamma-NMA was synthesized by reacting the omega-methyl ester of aspartate with methylamine and delta-N-methylglutamine by reaction of pyroglutamate with methylamine. These derivatives and the omega-methyl esters of aspartate and glutamate were characterized by melting point, by thin-layer chromatography, by amino acid analysis, by NMR spectroscopy, and after conversion to the phenylthiohydantoin (PTH) derivative. The gamma-NMA residues in peptides from allophycocyanin, C-phycocyanin, and B-phycoerythrin were stable under the conditions of automated sequential gas-liquid phase Edman degradation. On HPLC, PTH-gamma-NMA co-eluted with PTH-serine and was accompanied by a minor component eluting just prior to dimethylphenylthiourea. Similar results were obtained on manual derivatization of synthetic gamma-NMA to prepare the PTH derivative. The PTH-delta-N-methylglutamine standard eluted near the position of dimethylphenylthiourea under the usual conditions employed for the identification of PTH-amino acid derivatives in automated protein sequencing.     

Phycoerythrins of marine unicellular cyanobacteria. II. Characterization of phycobiliproteins with unusually high phycourobilin content

A survey of marine unicellular cyanobacterial strains for phycobiliproteins with high phycourobilin (PUB) content led to a detailed investigation of Synechocystis sp. WH8501. The phycobiliproteins of this strain were purified and characterized with respect to their bilin composition and attachment sites. Amino-terminal sequences were determined for the alpha and beta subunits of the phycocyanin and the major and minor phycoerythrins. The amino acid sequences around the attachment sites of all bilin prosthetic groups of the phycocyanin and of the minor phycoerythrin were also determined. The phycocyanin from this strain carries a single PUB on the alpha subunit and two phycocyanobilins on the beta subunit. It is the only phycocyanin known to carry a PUB chromophore. The native protein, isolated in the (alpha beta)2 aggregation state, displays absorption maxima at 490 and 592 nm. Excitation at 470 nm, absorbed almost exclusively by PUB, leads to emission at 644 nm from phycocyanobilin. The major and minor phycoerythrins from strain WH8501 each carry five bilins per alpha beta unit, four PUBs and one phycoerythrobilin. Spectroscopic properties determine that the PUB groups function as energy donors to the sole phycoerythrobilin. Analysis of the bilin peptides unambiguously identifies the phycoerythrobilin at position beta-82 (residue numbering assigned by homology with B-phycoerythrin; Sidler, W., Kumpf, B., Suter, F., Klotz, A. V., Glazer, A. N., and Zuber, H. (1989) Biol. Chem. Hoppe-Seyler 370, 115-124) as the terminal energy acceptor in phycoerythrins.     

Molecular architecture of a light-harvesting antenna. Quaternary interactions in the Synechococcus 6301 phycobilisome core as revealed by partial tryptic digestion and circular dichroism studies

The core of the phycobilisomes of Synechococcus 6301 (Anacystis nidulans) strain AN112 consists of two cylindrical elements each made up of the same four distinct subcomplexes: A (alpha AP beta AP)3; B (alpha AP beta AP)2 . 18.3K . 75K; C (alpha 1APB alpha 2AP beta 3AP) . 10.5K; and D (alpha AP beta AP)3 . 10.5K, where alpha AP and beta AP are the subunits of allophycocyanin, alpha APB is the subunit of allophycocyanin B, and 18.3K, 75K, and 10.5K are polypeptides of 18,300, 75,000, and 10,500 Da, respectively. An 18 S subassembly containing subcomplexes A and B has previously been characterized (Yamanaka, G., Lundell, D. J., and Glazer, A. N. (1982) J. Biol. Chem. 257, 4077-4086; Lundell, D. J., and Glazer, A. N. (1983) J. Biol. Chem. 258, 894-901, 902-908). A ternary core subassembly, containing complexes A, B, and C, was isolated from a limited tryptic digest of AN112 phycobilisomes and characterized with respect to composition and spectroscopic properties. Isolation of this ternary subassembly also establishes that subcomplex D must occupy a terminal position in each of the two core cylinders. Spectroscopic studies of the individual complexes, A-D, of the subassemblies AB and ABC, and of intact AN112 phycobilisomes showed core assembly-dependent changes in the circular dichroism spectra indicative of changes in the environment and/or conformation of the bilin chromophores within the individual subcomplexes. Two terminal energy acceptors are present in the phycobilisome core, alpha APB and 75K. No indication of interaction between the chromophores on these polypeptides was detected by circular dichroism spectroscopy. This result indicates that the bilins on alpha APB and 75K act as independent energy acceptors rather than as exciton pairs.     

CpcM posttranslationally methylates asparagine-71/72 of phycobiliprotein beta subunits in Synechococcus sp. strain PCC 7002 and Synechocystis sp. strain PCC 6803

Cyanobacteria produce phycobilisomes, which are macromolecular light-harvesting complexes mostly assembled from phycobiliproteins. Phycobiliprotein beta subunits contain a highly conserved gamma-N-methylasparagine residue, which results from the posttranslational modification of Asn71/72. Through comparative genomic analyses, we identified a gene, denoted cpcM, that (i) encodes a protein with sequence similarity to other S-adenosylmethionine-dependent methyltransferases, (ii) is found in all sequenced cyanobacterial genomes, and (iii) often occurs near genes encoding phycobiliproteins in cyanobacterial genomes. The cpcM genes of Synechococcus sp. strain PCC 7002 and Synechocystis sp. strain PCC 6803 were insertionally inactivated. Mass spectrometric analyses of phycobiliproteins isolated from the mutants confirmed that the CpcB, ApcB, and ApcF were 14 Da lighter than their wild-type counterparts. Trypsin digestion and mass analyses of phycobiliproteins isolated from the mutants showed that tryptic peptides from phycocyanin that included Asn72 were also 14 Da lighter than the equivalent peptides from wild-type strains. Thus, CpcM is the methyltransferase that modifies the amide nitrogen of Asn71/72 of CpcB, ApcB, and ApcF. When cells were grown at low light intensity, the cpcM mutants were phenotypically similar to the wild-type strains. However, the mutants were sensitive to high-light stress, and the cpcM mutant of Synechocystis sp. strain PCC 6803 was unable to grow at moderately high light intensities. Fluorescence emission measurements showed that the ability to perform state transitions was impaired in the cpcM mutants and suggested that energy transfer from phycobiliproteins to the photosystems was also less efficient. The possible functions of asparagine N methylation of phycobiliproteins are discussed.     

Pyruvoyl-dependent histidine decarboxylases. Comparative sequences of cysteinyl peptides of the enzymes from Lactobacillus 30a, Lactobacillus buchneri, and Clostridium perfringens

The two cysteinyl residues present in histidine decarboxylase from Lactobacillus 30a differ greatly in reactivity. One (class 1) reacts readily in the native state with dithiobis-(2-nitrobenzoate) with complete loss of enzyme activity; the other (class 2) reacts only after denaturation of the enzyme (Lane, R. S., and Snell, E. E. (1976) Biochemistry 15, 4175-4179). These differences in reactivity permitted use of covalent (disulfide) chromatography to isolate separate peptides that contain these two residues. Sequence analysis showed that the class 1 cysteinyl residue is at position 147 in a hydrophilic portion of the alpha chain (Huynh, Q. K., Recsei, P. A., Vaaler, G. L., and Snell, E. E. (1984) J. Biol. Chem. 259, 2833-2839), while the class 2 cysteinyl residue is present at position 71, adjacent to a hydrophobic portion of the same chain. Cysteinyl peptides identical with or homologous to the class 2 cysteinyl peptide of the Lactobacillus 30a enzyme were isolated from the alpha subunits of histidine decarboxylases from Lactobacillus buchneri and Clostridium perfringens, respectively. The L. buchneri enzyme also contained a peptide homologous to the class 1 cysteinyl peptide from Lactobacillus 30a. However, no corresponding peptide was present in the enzyme from C. perfringens, in which the second cysteinyl residue of the alpha chain occupies position 3, very near the essential pyruvoyl residue. This enzyme, unlike those from Lactobacillus 30a or L. buchneri, also contains one cysteinyl residue in its beta chain. Although Cys 147 is an active site residue in histidine decarboxylase from Lactobacillus 30a, the absence of a corresponding residue in the C. perfringens enzyme confirms previous indications (Recsei, P. A., and Snell, E. E. (1982) J. Biol. Chem. 257, 7196-7202) that this SH group is not essential for decarboxylase action.     

Dynamic aspects of phycobilisome structure

In exponentially growing cells of Synechococcus sp. 6301, over 95% of the phycobiliproteins are located in phycobilisomes, and the remainder is present in the form of low molecular weight aggregates. In addition to the subunits of the phycobiliproteins (C-phycocyanin, allophycocyanin, allophycocyanin B), the phycobilisomes of this unicellular cyanobacterium contain five non-pigmented polypeptides. During the initial phase of starvation (24 h after removal of combined nitrogen from the growth medium), the phycobiliproteins in the low molecular weight fraction largely disappeared. Phycocyanin was lost more rapidly from this fraction than allophycocyanin. Simultaneous changes in the phycobilisome were (1) a decrease in sedimentation coefficient, (2) a decrease in phycocyanin: allophycocyanin ratio, (3) a shift in the fluorescence emission maximum from 673 to 676 nm, and (4) a selective complete loss of a 30,000 dalton non-pigmented polypeptide. Upon extensive nitrogen starvation (72 h), the intracellular level of phycocyanin decreased by over 30-fold. These results indicate that in the early stage of nitrogen starvation, the free phycobiliproteins of the cell are degraded, as well as a significant proportion of the phycocyanin from the periphery of the phycobilisome. However, the structures partially depleted of phycocyanin still function efficiently in energy transfer. On extended starvation, total degradation of residual phycobilisomes takes place, possibly in conjunction with the detachment of these structures from the thylakoids.None of the effects of the absence of combined nitrogen were seen when cells were starved in the presence of chloramphenicol, or in a methionine auxotroph starved for methionine.Abbreviations Used NaK-PO₄ NaH₂PO₄ titrated with K₂HPO₄ to a given pH - SDS sodium dodecyl sulfate - Tris Tris(hydroxymethyl)aminomethane     

R-phycocyanin II, a new phycocyanin occurring in marine Synechococcus species. Identification of the terminal energy acceptor bilin in phycocyanins

A new member of the phycocyanin family of phycobiliproteins, R-phycocyanin II (R-PC II) has been discovered in several strains of marine Synechococcus sp. R-PC II has absorption maxima at 533 and 554 nm, a subsidiary maximum at 615 nm, and a fluorescence emission maximum at 646 nm. It is the first phycoerythrobilin (PEB)-containing phycocyanin of cyanobacterial origin. The purified protein is made up of alpha and beta subunits in equal amounts and is in an (alpha beta)2 aggregation state. The alpha and beta subunits of this protein are homologous to the corresponding subunits of previously described C- and R-phycocyanins as assessed by amino-terminal sequence determination and analyses of sequences about sites of bilin attachment. R-PC II carries phycocyanobilin (PCB) at beta-84 and PEB at alpha-84 and beta-155 (residue numbering is that for C-phycocyanin), whereas in C-phycocyanin PCB is present at all three positions. In R-phycocyanin, the bilin distribution is alpha-84 (PCB), beta-84 (PCB), beta-155 (PEB). In both R-phycocyanin and R-phycocyanin II excitation at 550 nm, absorbed primarily by PEB groups, leads to emission at 625 nm from PCB. These comparative data support the conclusion that the invariant beta-84 PCB serves as the terminal energy acceptor in phycocyanins.     

Phycobiliprotein synthesis in protoplasts of the unicellular cyanophyte, Anacystis nidulans.

Stable and metabolically active protoplasts were prepared from the unicellular cyanophyte, Anacystis nidulans, by enzymatic digestion of the cell wall with 0.1% lysozyme. The yield of protoplasts from intact algal cells was approx. 50%. Incorporation of L-[U-14C]leucine into cold trichloroacetic acid-insoluble material from protoplasts preparations was linear for 1.5 h and continued for an additional 2.5 h. Incorporation of radiolabeled leucine into hot trichloroacetic acid-insoluble material from protoplast preparations demonstrated protein synthesis in protoplasts in vitro. Phycocyanin is the principal phycobiliprotein and allophycocyanin is a minor phycobiliprotein in A. nidulans cells. The light-absorbing chromophore of both of these phycobiliproteins is the linear tetrapyrrole (bile pigment), phycocyanobilin. Radiolabeled phycocyanin and allophycocyanin were isolated from protoplast preparations which had been incubated with L-[U-14]leucine or delta-amino[4-14C] levulinic acid (a precursor of phycocyanobilin). The radio-labeled phycobiliproteins were purified by ammonium sulfate fractionation and ion-exchange chromatography on brushite columns. The specific radioactivity of phycocyanin and allophycocyanin in brushite column eluates (protoplasts incubated with radiolabeled leucine) was 106 000 and 82 000 dpm/mg, respectively. The specific radioactivity of phycocyanin and allophycocyanin in brushite column eluates (protoplasts incubated with radiolabeled delta-aminolevulinic acid) was 33 000 and 38 000 dpm/mg, respectively. Phycobiliproteins from protoplasts incubated with radiolabeled leucine were examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. 25% of the incorporated radioactivity in protoplast lysates and approx. 60% of the incorporated radioactivity in protoplast lysates and approx. 60% of the incorporated ratioactivity in phycocyanin and allophycocyanin (in brushite column eluates) comigrated with the subunits of these phycobiliproteins on sodium dodecyl sulfate-polyacrylamide gels. Chromic acid degradation of phycobiliproteins from protoplast preparations incubated with delta-amino[4-14C] levulinic acid yielded radiolabeled imides which were derived from the phycocyanobilin chromophore. Imides from radiolabeled phycobiliproteins isolated from protoplast preparations incubated with L-[U-14C]leucine did not contain radioactivity. These results show that both the apoprotein and tetrapyrrolic moieties of phycocyanin and allophycocyanin were synthesized in A. nidulans protoplasts in vitro.     

Allophycocyanin complexes of the phycobilisome from Mastigocladus laminosus. Influence of the linker polypeptide L8.9C on the spectral properties of the phycobiliprotein subunits

The following phycobiliproteins and complexes of the allophycocyanin core were isolated from phycobilisomes of the thermophilic cyanobacterium Mastigocladus laminosus: alpha AP, beta AP, (alpha AP beta AP), (alpha AP beta AP)3, (alpha AP beta AP)3L8.9C, (alpha APB alpha AP2 beta AP3)L8.9C. The six proteins and complexes were characterised spectroscopically with respect to absorption, oscillator strength, extinction coefficient, fluorescence emission, relative quantum yield, fluorescence emission polarisation and fluorescence excitation polarisation. The interpretation of the spectral data was based on the three-dimensional structure model of (alpha PC beta PC)3 (Schirmer et al. (1985) J. Mol. Biol. 184, 257-277), which is related to the allophycocyanin trimer. The absorption and CD spectra of the complexes (alpha AP beta AP)3, (alpha AP beta AP)3L8.9C and (alpha APB alpha AP2 beta AP3)L8.9C could be deconvoluted into the spectra of the phycobiliprotein subunits. The assumptions made for the deconvolution could be checked by the synthesis of the spectra of (alpha APB beta AP)3. The synthesised spectra are in good agreement with the corresponding measured spectra published by other authors. Considering the deconvoluted spectra the following influences on the chromophores could be ascribed to L8.9C: L8.9C neither influences the alpha AP nor the alpha APB chromophores. L8.9C shifts the absorption maximum of the beta AP chromophore to longer wavelength than the absorption maximum of the alpha AP chromophore in trimeric complexes. L8.9C increases the oszillator strength of the beta AP chromophores to about the value of the alpha AP chromophores in trimeric complexes. L8.9C turns the beta AP chromophores from sensitizing into weak fluorescing chromophores. By means of the hydropathy plot and the predicted secondary structure, a postulated three-fold symmetry in the tertiary structure of L8.9C could be confirmed.     

Molecular architecture of a light-harvesting antenna. Structure of the 18 S core-rod subassembly of the Synechococcus 6301 phycobilisome

The 18 S subassembly particles obtained by partial dissociation of phycobilisomes from Synechococcus 6301 (Anacystis nidulans) strain AN 112 contain approximately one-half of the mass of the phycobilisome and include core-rod junctions (Yamanaka, G., Lundell, D. J., and Glazer, A. N. (1982) J. Biol. Chem. 257, 4077-4086). The polypeptide composition of 18 S complexes, determined by analysis of uniformly 14C-labeled phycobilisomes, gave the following stoichiometry: 75K:27K:18.3K:alpha beta allophycocyanin monomer: alpha beta phycocyanin monomer of 1:2:1:5:6; where 75K, 27K, etc. represent polypeptides of 75, 27 kilodaltons, etc. The 18.3K polypeptide is a hitherto underscribed biliprotein bearing a single phycocyanobilin. The NH2-terminal sequence of this subunit was determined to be homologous to that of the beta subunit of allophycocyanin. Chromatography of products resulting from limited trypsin treatment of the 18 S complex led to the isolation of three subcomplexes: a mixture of (alpha beta)3 . 22K and (alpha beta)3 . 24K phycocyanin complexes, an (alpha beta)3 allophycocyanin trimer, and an (alpha beta)2 . 18.3K.40K.11K allophycocyanin-containing complex. The 22K and 24K components were products of the degradation of the 27K polypeptides, whereas the 40K and 11K components were derived from the 75K polypeptide. The subcomplexes accounted for the composition of the 18 S complex. Determination of the composition, stoichiometry, and spectroscopic properties of the subcomplexes has led to a model of the polypeptide arrangement within the 18 S complex and of the pathway of energy transfer among these polypeptides.     

The role of the specificity-determining loop of the integrin beta subunit I-like domain in autonomous expression, association with the alpha subunit, and ligand binding

Integrin beta subunits contain a highly conserved I-like domain that is known to be important for ligand binding. Unlike integrin I domains, the I-like domain requires integrin alpha and beta subunit association for optimal folding. Pactolus is a novel gene product that is highly homologous to integrin beta subunits but lacks associating alpha subunits [Chen, Y., Garrison, S., Weis, J. J., and Weis, J. H. (1998) J. Biol. Chem. 273, 8711-8718] and a approximately 30 amino acid segment corresponding to the specificity-determining loop (SDL) in the I-like domain. We find that the SDL is responsible for the defects in integrin beta subunit expression and folding in the absence of alpha subunits. When transfected in the absence of alpha subunits into cells, extracellular domains of mutant beta subunits lacking SDL, but not wild-type beta subunits, were well secreted and contained immunoreactive I-like domains. The purified recombinant soluble beta1 subunit with the SDL deletion showed an elongated shape in electron microscopy, consistent with its structure in alphabeta complexes. The SDL segment is not required for formation of alpha5beta1, alpha4beta1, alphaVbeta3, and alpha6beta4 heterodimers, but is essential for fomation of alpha6beta1, alphaVbeta1, and alphaLbeta2 heterodimers, suggesting that usage of subunit interface residues is variable among integrins. The beta1 SDL is required for ligand binding and for the formation of the epitope for the alpha5 monoclonal antibody 16 that maps to loop segments connecting blades 2 and 3 of beta-propeller domain of alpha5, but is not essential for nearby beta-propeller epitopes.     

Determination of N- and C-terminal borders of the transmembrane domain of integrin subunits

Previous studies on the membrane-cytoplasm interphase of human integrin subunits have shown that a conserved lysine in subunits alpha(2), alpha(5), beta(1), and beta(2) is embedded in the plasma membrane in the absence of interacting proteins (Armulik, A., Nilsson, I., von Heijne, G., and Johansson, S. (1999) in J. Biol. Chem. 274, 37030-37034). Using a glycosylation mapping technique, we here show that alpha(10) and beta(8), two subunits that deviate significantly from the integrin consensus sequences in the membrane-proximal region, were found to have the conserved lysine at a similar position in the lipid bilayer. Thus, this organization at the C-terminal end of the transmembrane (TM) domain seems likely to be general for all 24 integrin subunits. Furthermore, we have determined the N-terminal border of the TM domains of the alpha(2), alpha(5), alpha(10), beta(1), and beta(8) subunits. The TM domain of subunit beta(8) is found to be 22 amino acids long, with a second basic residue (Arg(684)) positioned just inside the membrane at the exoplasmic side, whereas the lipidembedded domains of the other subunits are longer, varying from 25 (alpha(2)) to 29 amino acids (alpha(10)). These numbers implicate that the TM region of the analyzed integrins (except beta(8)) would be tilted or bent in the membrane. Integrin signaling by transmembrane conformational change may involve alteration of the position of the segment adjacent to the conserved lysine. To test the proposed "piston" model for signaling, we forced this region at the C-terminal end of the alpha(5) and beta(1) TM domains out of the membrane into the cytosol by replacing Lys-Leu with Lys-Lys. The mutation was found to not alter the position of the N-terminal end of the TM domain in the membrane, indicating that the TM domain is not moving as a piston. Instead the shift results in a shorter and therefore less tilted or bent TM alpha-helix.     

Functional expression of plastid allophycocyanin genes in a cyanobacterium.

In Cyanophora paradoxa, the allophycocyanin apoprotein subunits, alpha and beta, are encoded in the cyanelle (plastid) genome. These genes were transferred to the cyanobacterium Synechococcus sp. PCC 7002 on a plasmid replicon. Phycobilisomes isolated from transformed cyanobacteria were found to contain C. paradoxa allophycocyanin subunits. Thus, these plastid genes are expressed in the cyanobacterium as polypeptides which become linked to a chromophore and are incorporated into the light-harvesting apparatus.     

The complete amino-acid sequence of the alpha and beta subunits of B-phycoerythrin from the rhodophytan alga Porphyridium cruentum

Determination of the complete amino-acid sequence of the subunits of B-phycoerythrin from Porphyridium cruentum has shown that the alpha subunit contains 164 amino-acid residues and the beta subunit contains 177 residues. When the sequences of B- and C-phycoerythrins are aligned with those of other phycobiliproteins, it is obvious that B-phycoerythrin lacks a deletion at beta-21-22 present in C-phycoerythrin. However, relative to C-phycoerythrin from Fremyella diplosiphon (Calothrix) (Sidler, W., Kumpf, B., Rüdiger, W. and Zuber, H. (1986) Biol. Chem. Hoppe-Seyler 367, 627-642), B-phycoerythrin has deletions at beta-141k-o, beta-142, beta-143, beta-147 and beta-148. The four singly-linked phycoerythrobilins at positions alpha-84, alpha-143a, beta-84 and beta-155, and the doubly-linked phycoerythrobilin at position beta-50/61 are at sites homologous to the attachment sites in C-phycoerythrin. The aspartyl residues (alpha-87, beta-87, and beta-39), that interact with the bilins at alpha-84, beta-84, and beta-155 in C-phycocyanin, are found in the homologous positions in B-phycoerythrin. B-Phycoerythrin, in common with other phycobiliproteins, contains a N gamma-methylasparagine residue at position beta-72.     

Role of the ATP synthase alpha-subunit in conferring sensitivity to tentoxin.

Tentoxin, produced by phytopathogenic fungi, selectively affects the function of the ATP synthase enzymes of certain sensitive plant species. Binding of tentoxin to a high affinity (K(i) approximately 10 nM) site on the chloroplast F(1) (CF(1)) strongly inhibits catalytic function, whereas binding to a second, lower affinity site (K(d) > 10 microM) leads to restoration and even stimulation of catalytic activity. Sensitivity to tentoxin has been shown to be due, in part, to the nature of the amino acid residue at position 83 on the catalytic beta subunit of CF(1). An aspartate in this position is required, but is not sufficient, for tentoxin inhibition. By comparison with the solved structure of mitochondrial F(1) [Abrahams, J. P., Leslie, A. G. W., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628], Asp83 is probably located at an interface between alpha and beta subunits on CF(1) where residues on the alpha subunit could also participate in tentoxin binding. A hybrid core F(1) enzyme assembled with beta and gamma subunits of the tentoxin-sensitive spinach CF(1), and an alpha subunit of the tentoxin-insensitive photosynthetic bacterium Rhodospirillum rubrum F(1) (RrF(1)), was stimulated but not inhibited by tentoxin [Tucker, W. C., Du, Z., Gromet-Elhanan, Z. and Richter, M. L. (2001) Eur. J. Biochem. 268, 2179-2186]. In this study, chimeric alpha subunits were prepared by introducing short segments of the spinach CF(1) alpha subunit from a poorly conserved region which is immediately adjacent to beta-Asp83 in the crystal structure, into equivalent positions in the RrF(1) alpha subunit using oligonucleotide-directed mutagenesis. Hybrid enzymes containing these chimeric alpha subunits had both the high affinity inhibitory tentoxin binding site and the lower affinity stimulatory site. Changing beta-Asp83 to leucine resulted in loss of both inhibition and stimulation by tentoxin in the chimeras. The results indicate that tentoxin inhibition requires additional alpha residues that are not present on the RrF(1) alpha subunit. A structural model of a putative inhibitory tentoxin binding pocket is presented.