Studies on the Hill reaction of membrane fragments of blue-green algae V. A correlation between the solubilization of a photochemically active chromoprotein (ACP) and the inactivation of photosystem II activity in membrane fragments of Anabaena cylindrica

The relationship between a photochemically active chromoprotein(ACP) (cf. ref. 1) and photosystem II was investigated withmembrane fragments of Anabaena cylindrica, A. variabilis andP. boryaman. ACP was solubilized from membrane fragments of A. cylindricabut not from those of A. variabilis or P. boryanum, when themembrane fragments had been incubated in a dilute buffer andhad lost their Hill or photosystem II activity. In A. cylindrica,ACP-solubilization always occurred, independent of photosystemII inactivation, on incubation of the membrane fragments inmedia without PEG. However, the amount of ACP solubilizationaccompanying photosystem II inactivation was twice that withoutphotosystem II inactivation. The increase in ACP solubilizationaccompanying photosystem II inactivation. The kinetics resembledthose for the decrease in 695 nm fluorescence emitted by membranefragments at — 196?C (cf. 2). The ACP solubilized independent of photosystem II inactivationwas assumed to have been released during disruption of intactcells in the preparation of membrane fragments. The slow ACPsolubilization upon the inactivation of photosystem II was attributedto the pigment being bound to membranes. We assume that thephoto-reactive component of ACP, P690 (cf. 3, 4), is releasedfrom the membranes during photosystem II inactivation, and thatP690 is a component of photosystem II which emits the 695 nmfluorescence at — 196?C. (Received March 22, 1974; )     

Photochemical activity fluorescence and absorption spectrum of the photochemically active chromoprotein (ACP) isolated from the blue-green alga Anabaena cylindrica

Photochemical, spectroscopic and fluorescence characteristicsof the active chromo-protein (ACP) of Anabaena cylindrica werestudied with preparations having different spectroscopic characteristics. Purified ACP preparations occasionally showed spectroscopiccharacteristics differing considerably from those of ordinaryACP. A spectroscopic difference in these preparations was observedonly in the relative absorbance in the 620 nm peak. Absorptionpeaks at 430, 460, 480 and 695 nm remained unchanged. Photochemicalactivity and fluorescence yield at 700 nm were fairly constantin these preparations, when excited at absorption bands otherthan 620 nm. Spectroscopic changes caused by heat and detergent (SDS) treatmentsoccurred only in the relative absorbance of the 620 nm peak.Photochemical and fluorescence characteristics of the treatedACP were the same as those of the ACP originally having a differentabsorption spectrum. A comparison of various ACP preparations indicates that ACPis a complex of two pigments, c-phycocyanin and a pigment witha 695 nm absorption maximum. The reduction in the molecularsize of ACP by SDS-treatment indicates that pigment 695 is farsmaller in its molecular size than c-phycocyanin. A possiblefunction of the two pigments in the photochemical reaction isalso discussed. (Received December 10, 1971; )     

两种鼠蚤在新羽化和吸血后不同时间三种酶的组织化学研究

采用组织化学技术,研究了不等单蚤Monopsyllus anisus (Rothschild)和缓慢细蚤Leptopsylla segnis (Schonherr)新羽化和吸血后24 h、48 h和72 h碱性磷酸酶、酸性磷酸酶和三磷酸腺苷酶的分布和活性。显微摄影及定量图像分析结果显示：新羽化蚤碱性和酸性磷酸酶主要存在于中肠、神经细胞核、精子束头部、精巢附腺、射精管、输卵管和受精囊附腺中;三磷酸腺苷酶各组织中均有分布。吸血消化后,两种蚤中肠3种酶活性均有增强;除碱性磷酸酶在消化72 h 后酶活性有所下降外,其余不同消化时间酶活性增强程度上不存在显著差异。两种蚤卵母细胞发育成熟过程中3种酶活性亦见增强。     

Stereospecificity of hydrogen transfer by pyridine nucleotide-dependent enoyl reductases in fatty acid synthesis: Studies with enzymes obtained from developing castor bean seeds and Chlorella vulgaris

The mechanism of hydrogen incorporation into fatty acids wasinvestigated with fatty acid synthetase systems from developingcastor bean seeds and Chlorella vulgaris. Fatty acids synthesizedin the presence of D₂O or stereospecifically deuterium-labeledNADPH or NADH were isolated and analyzed by mass spectrometryto examine the localization of deuterium atoms in the molecule.The stereospecificities of ß-ketoacyl-acyl carrierprotein (ACP) reductase and enoyl-ACP reductase for reducedpyridine nucleotide were determined with acetoacetyl-ACP andcrotonyl-ACP as substrates. The products were also analyzedby gas chromatography-mass spectrometry. The following resultswere obtained:

1. ß-Ketoacyl-ACP reductases from both castor bean seedsand C. vulgaris used the B-side hydrogen of NADPH.
2. Enoyl-ACPreductase from C. vulgaris required NADH for the activity.
3. Enoyl-ACPreductase from castor bean seeds used the A-side hydrogenofNADPH, whereas that from C. vulgaris used the B-side hydrogenof NADH.
4. When stearate was synthesized with the crude fattyacid synthetasefraction from castor bean seeds, hydrogen atomsfrom water werefound on the even-numbered methylene carbonatoms (two hydrogenatoms per carbon atom) and some were foundon the odd-numberedmethylene carbon atoms. Hydrogen atoms fromthe B-side of NADPHwere found on the odd-numbered methylenecarbon atoms (one hydrogenatom per carbon atom). Hydrogen atomsfrom the A-side of NADPHwere also found on the odd-numberedmethylene carbon atoms,but the number of incorporated hydrogenatoms was less thanexpected.

(Received October 17, 1979; )     

Immunochemical characterization of human red cell acid phosphatase isozymes

An immunological study was performed on human red cell acid phosphatase (ACP1) isozymes encoded by different alleles, each of which is expressed as an electrophoretically fast (f) isozyme and a slow (s) isozyme. These isozymes reacted as two immunochemically different groups. Allele-specific reactions were not detected between either the f isozymes or the s isozymes. Quantitation of ACP1 isozymes in red cells by crossed immunoelectrophoresis revealed a phenotype-dependent variation in the concentration of isozyme protein. A simple gene dosage effect was indicated and the ordering of the ACP1 alleles (ACP1*A < ACP1*B < ACP1*C < ACP1*E) was identical to that found for enzyme activity levels. Also, an allele effect on the proportion between s and f isozymes (s/f) was observed; the ordering here was ACP1* B < ACP1*A < ACP1*, which is the same as that reported for the susceptibility to modulation with purines. These variations in isozyme protein levels appear to account for the phenotypic differences in the intensity of the isozyme bands, when activity-stained after electrophoresis, and in the red cell enzyme activity levels. Investigation of two carriers of a Null allele showed no evidence of an aberrant protein product, and half-normal concentrations of enzyme protein were observed in the red cells of these individuals.     

How Do General Practitioners Conceptualise Advance Care Planning in Their Practice? A Qualitative Study

ObjectivesTo explore how GPs conceptualise advance care planning (ACP), based on their experiences with ACP in their practice.MethodsFive focus groups were held with 36 GPs. Discussions were analysed using a constant comparative method.ResultsFour overarching themes in the conceptualisations of ACP were discerned: (1) the organisation of professional care required to meet patients’ needs, (2) the process of preparing for death and discussing palliative care options, (3) the discussion of care goals and treatment decisions, (4) the completion of advance directives. Within these themes, ACP was both conceptualised in terms of content of ACP and/or in terms of tasks for the GP. A specific task that was mentioned throughout the discussion of the four different themes was (5) the task of actively initiating ACP by the GP versus passively waiting for patients’ initiation.ConclusionsThis study illustrates that GPs have varying conceptualisations of ACP, of which some are more limited to specific aspects of ACP. A shared conceptualisation and agreement on the purpose and goals of ACP is needed to ensure successful implementation, as well as a systematic integration of ACP in routine practice that could lead to a better uptake of all the important elements of ACP.     

Purification and biochemical characterization of lysosomal acid phosphatases (EC 3.1.3.2) from blood stream forms, Trypanosoma brucei brucei

Three Acid phosphatases (ACP) were isolated and characterized from the lysosomes of blood stream forms of Trypanosoma brucei by a combination of isopynic and differential centrifugation through Ficoll, organic solvent precipitation, ion exchange on DEAE cellulose 52 and size exclusion chromatography on Sephadex G-75 columns. The purified ACP emerged as three distinct peaks (ACP I, ACP II and ACP III) with high specific activities and they moved homogenously on 12% SDS-PAGE each as a single band with relative molecular weight of 36 kDa, 25 kDa and 45 kDa respectively. The purified enzymes were active at an optimum pH and temperature of 5.5 and 40 °C respectively. The enzyme activities appeared to be ACP because their activities were enhanced at low pH values and inhibited by the acid phosphatase inhibitor, sodium fluoride. ACP I and ACP II were sensitive to l-tartrate while ACP III was insensitive to l tartrate. The kinetic analysis of the purified enzyme (ACP I, ACP II and ACP III) determined using para-nitrophenylphosphate as substrate gave K_M values of 0.2 mM, 0.15 mM and 0.5 mM. Monofunctional group sulfhydryl group inhibitors; HgCl₂, and AgCl₂ strongly inhibited the activity of ACP III and millimolar concentrations of dithiothreitol and iodoacetamide activated and inhibited the activity of the ACP III respectively, suggesting the involvement of thiol groups at the active site of the enzyme. Thus, differentiating it from ACP I and ACP II. The implication of these findings in relation to the pathology of trypanosomosis is discussed.     

The role of acyl carrier protein isoforms from Cuphea lanceolata seeds in the de-novo biosynthesis of medium-chain fatty acids

To investigate the role of acyl carrier protein (ACP) in determining the fate of the acyl moieties linked to it in the course of de-novo fatty acid biosynthesis in higher plants, we carried out in vitro experiments to reconstitute the fatty acid synthase (FAS) reaction in extracts of spinach (Spinaciaoleracea L.) leaves, rape (Brassicanapus L.) seeds and Cuphea lanceolata Ait. seeds. The action of two major C. lanceolata ACP isoforms (ACP 1 and ACP 2) compared to ACP from Escherichia coli was monitored by saponification of the corresponding FAS products with subsequent analysis of the liberated fatty acids by high-performance liquid chromatography. In a second approach the preference of the medium-chain acyl-ACP-specific thioesterase (EC 3.1.2.14) of C. lanceolata seeds for the hydrolysis of acyl-ACPs prepared from the three ACP types was investigated. Both ACP isoforms from C. lanceolata seeds supported the synthesis of medium-chain fatty acids in a reconstituted FAS reaction of spinach leaf extracts. Compared to the isoform ACP 1, ACP 2 was more effective in supporting the synthesis of such fatty acids in the FAS reaction of rape seed extracts and caused a higher accumulation of FAS products in all experiments. No preference of the medium-chain thioesterase for one specific ACP isoform was observed. The results indicate that the presence of ACP 2 is essential for the synthesis of decanoic acid in C. lanceolata seeds, and its expression in the phase of accumulation of high levels of this fatty acid provides an additional and highly efficient cofactor for stimulating the FAS reaction. Received: 23 June 1997 / Accepted: 23 October 1997     

Acyl carrier proteins from developing seeds of Cuphea lanceolata Ait

The structure of acyl carrier protein (ACP) may determine the fate of the acyl moieties linked to it in the course of de-novo fatty acid synthesis in higher plants. To investigate a possible correlation between the structure of ACP and the synthesis of medium-chain fatty acids, we isolated and characterized ACP from the seeds of Cuphea lanceolata Ait. (subgenus Eucuphea/Section Heterodon), an annual crop that contains up to 90% decanoic (capric) acid in seed triacylglycerols. After a cell-free extract prepared from developing seeds was treated to 65% saturation with ammonium sulfate, two ACP-isoforms (ACP 1 and ACP 2) were identified in the supernatant that could be purified to homogeneity by anion-exchange chromatography and subsequent reversed-phase high-performance liquid chromatography. The molecular mass determined by matrix-assisted ultraviolet-laser desorption ionization mass spectrometry of ACP 1 was 9315 Da, whereas further heterogeneity was observed for ACP 2 with molecular masses of 8598 and 8703 Da. Aminoterminal sequencing was performed showing a high homology in the primary structures of ACP 1 and ACP 2. Both isoforms were present in the embryo, whereas in the chloroplast-containing seed coat ACP 2 was found in minute amounts, if at all. The expression of ACP 2 correlated with the production of capric acid during the phase of storage-lipid accumulation. These data indicate that ACP 2 is part of the machinery for the synthesis of medium-chain fatty acids, whereas ACP 1 appears to be a constitutive protein.Abbreviations ACP acyl carrier protein - clACP acyl carrier protein from Cuphea lanceolata - 2D-PAOE two-dimensional polyacrylamide gel electrophoresis - DTT dithiothreitol - ecACP acyl carrier protein from Escherichia coli - FPLC fast protein liquid chromatography - HPLC high-performance liquid chromatography - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - Tricine N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine This work was supported by a grant from the German Ministry of Research and Technology (BMFT). The authors wish to thank Professor Röbbelen, University of Göttingen, FRG, for kindly providing the plant material and A. Ingendoh, Department of Medical Physics of the University of Münster, FRG, for carrying out the mass-spectrometric analysis. Portions of this paper are part of the doctoral thesis of Markus Robers.     

Control of Lipid Synthesis during Soybean Seed Development: Enzymic and Immunochemical Assay of Acyl Carrier Protein

During soybean seed (Glycine max, var Am Soy 71) development, the rate of lipid biosynthesis per seed increases greatly. As the seed reaches maturity, lipid synthesis declines. To study the controls over the oil synthesis and storage process, we have chosen acyl carrier protein (ACP) as a representative marker for the fatty acid synthetase pathway. We have quantitated soybean ACP levels by both enzymic and immunochemical methods. Escherichia coli acyl-ACP synthetase was used as an assay for enzymically active ACP. Total ACP protein was determined by immunoassay using antibodies prepared in rabbits against spinach ACP. These antibody preparations also bind ACP isolated from soybeans, allowing development of a radioimmunoassay based on competition with [³H]palmitoyl-ACP. The enzymic and immunochemical measurement of ACP at various stages of seed development have indicated that ACP activity and ACP antigen increase markedly in correlation with the in vivo increase in lipid synthesis. These results indicate that a major control over the increase in lipid synthesis arises through regulation of the levels of the fatty acid biosynthetic proteins. However, as the seed reaches maturity and lipid biosynthesis declines, ACP per seed remains relatively high. In the mature seed, we found that more than 95% of the ACP is localized in the cotyledons, less than 5% is in the axis, and less than 1% is in the seed coat.     

Solution structure of B. subtilis acyl carrier protein

BACKGROUND: Acyl carrier protein (ACP) is a fundamental component of fatty acid biosynthesis in which the fatty acid chain is elongated by the fatty acid synthetase system while attached to the 4'-phosphopantetheine prosthetic group (4'-PP) of ACP. Activation of ACP is mediated by holo-acyl carrier protein synthase (ACPS) when ACPS transfers the 4'-PP moiety from coenzyme A (CoA) to Ser36 of apo-ACP. Both ACP and ACPS have been identified as essential for E. coli viability and potential targets for development of antibiotics. RESULTS: The solution structure of B. subtilis ACP (9 kDa) has been determined using two-dimensional and three-dimensional heteronuclear NMR spectroscopy. A total of 22 structures were calculated by means of hybrid distance geometry-simulated annealing using a total of 1,050 experimental NMR restraints. The atomic rmsd about the mean coordinate positions for the 22 structures is 0.45 +/- 0.08 A for the backbone atoms and 0.93 +/- 0.07 A for all atoms. The overall ACP structure consists of a four alpha-helical bundle in which 4'-PP is attached to the conserved Ser36 that is located in alpha helix II. CONCLUSIONS: Structural data were collected for both the apo and holo forms of ACP that suggest that the two forms of ACP are essentially identical. Comparison of the published structures for E. coli ACP and actinorhodin polyketide synthase acyl carrier protein (act apo-ACP) from Streptomyces coelicolor A3(2) with B. subtilis ACP indicates similar secondary structure elements but an extremely large rmsd between the three ACP structures (>4.3 A). The structural difference between B. subtilis ACP and both E. coli and act apo-ACP is not attributed to an inherent difference in the proteins, but is probably a result of a limitation in the methodology available for the analysis for E. coli and act apo-ACP. Comparison of the structure of free ACP with the bound form of ACP in the ACP-ACPS complex reveals a displacement of helix II in the vicinity of Ser36. The induced perturbation of ACP by ACPS positions Ser36 proximal to coenzyme A and aligns the dipole of helix II to initiate transfer of 4'-PP to ACP.     

Presence and abundance of Diaphorina citri in Murraya paniculata in urban areas free of huanglongbing in Brazil

Asian citrus psyllid (ACP), Diaphorina citri Kuwayama (Hemiptera: Liviidae), is the vector of the bacterium Candidatus Liberibacter sp., a quarantine pathogen in citrus production areas such as Australia, Europe, and northeast Brazil, associated with huanglongbing (HLB). The psyllids’ preferred host is Murraya paniculata (L.) Jacq. (Rutaceae), an ornamental plant native to Asia and Oceania, and commonly found in urban areas next to citrus groves around the world. As there are insecticide application restrictions for urban areas, monitoring and use of biological control to suppress ACP are essential for an area-wide HLB management strategy, especially for production areas predominantly composed of small citrus farms. For this, it is necessary to understand the occurrence cycles of ACP and vegetative flush of the ornamental host. This study characterized the occurrence cycles of M. paniculata flush shoot and accumulated rainfall, and the association with ACP presence (proportion of monitored trees) and abundance (per tree) in a Brazilian urban area free of HLB. A 3-year time series was constructed using spectral and co-spectral analysis. Spectral analysis showed the occurrence of at least seven flush shoot cycles of M. paniculata, nearly 10 ACP presence and abundance cycles, and monthly cycles of accumulated rainfall. Cycles of ACP presence were associated with ACP abundance, with ACP presence cycles occurring around 7 days before ACP abundance cycles and the correlation and co-spectral analyses indicated an almost simultaneous occurrence of the main cycles of M. paniculata flush shoots and ACP occurrence. These findings will facilitate the development of an ACP biological control program based on parasitoid releases in urban areas in HLB-free citrus groves.     

<Superscript>1</Superscript>H NMR analysis of <Emphasis Type="Italic">Citrus macrophylla</Emphasis> subjected to Asian citrus psyllid (<Emphasis Type="Italic">Diaphorina citri</Emphasis> Kuwayama) feeding

The Asian citrus psyllid (ACP) is a phloem-feeding insect that can host and transmit the bacterium Candidatus Liberibacter asiaticus (CLas), which is the putative causative agent of the economically important citrus disease, Huanglongbing (HLB). ACP are widespread in Florida, and are spreading in California; they are the primary mode of CLas transmission in citrus groves. To understand the effects of ACP feeding, different numbers of ACP [0 ACP (control), 5 ACP (low), 15–20 ACP (medium), and 25–30 ACP (high)] were allowed to feed on Citrus macrophylla greenhouse plants. After 7 days of feeding, leaves were collected and analyzed using ¹H NMR. Metabolite concentrations from leaves of trees with ACP feeding had higher variability than control trees. Many metabolites were higher in concentration in the low ACP feeding group relative to control; however, leaves from trees with high ACP feeding had lower concentrations of many metabolites relative to control, including many amino acids such as phenylalanine, arginine, isoleucine, valine, threonine, and leucine. These results suggest ACP density-dependent changes in primary metabolism that can be measured by ¹H NMR. The implications in plant defense are discussed.     

Characterization of Five Putative Acyl Carrier Protein (ACP) Isoforms from Developing Seeds of <Emphasis Type="Italic">Arachis hypogaea</Emphasis> L.

Five putative acyl carrier protein (ACP) cDNAs were isolated from developing peanut seeds by searching ESTs of a peanut immature-seed cDNA library and PCR-based cloning. Five peanut ACPs contained a strictly conserved Ser residue in the Asp-Ser-Leu (DSL) motif, which is an important characteristic of ACPs in plants and bacteria. Three AhACPs, AhACP1, AhACP4, AhACP5, were predicted to be located in chloroplast, while two AhACPs, AhACP2 and AhACP3, in mitochondria. Comparison of genomic DNA and cDNA sequences demonstrated three chloroplast ACPs (cpACPs) comprising of four exons and three introns while two mitochondrial ACPs (mtACPs) contained two exons and one intron. More than two homologs of each AhACP were expressed in developing peanut seeds. Most homologs were verified by corresponding genomic DNA sequences. Semi-quantitative RT-PCR analysis suggested AhACP1 was a seed-predominant ACP isoform. AhACP4 and AhACP5 showed same mRNA profile in different organs and during seed development. Two mtACPs expressed highly in peanut flower tissue which was distinct from three cpACPs.     

The spatial distribution of acid phosphatase activity in ectomycorrhizal tissues depends on soil fertility and morphotype, and relates to host plant phosphorus uptake

Acid phosphatase (ACP) enzymes are involved in the mobilization of soil phosphorus (P) and polyphosphate accumulated in the fungal tissues of ectomycorrhizal roots, thereby influencing the amounts of P that are stored in the fungus and transferred to the host plant. This study evaluated the effects of ectomycorrhizal morphotype and soil fertility on ACP activity in the extraradical mycelium (ACP(myc)), the mantle (ACP(mantle)) and the Hartig net region (ACP(Hartig)) of ectomycorrhizal Nothofagus obliqua seedlings. ACP activity was quantified in vivo using enzyme-labelled fluorescence-97 (ELF-97) substrate, confocal laser microscopy and digital image processing routines. There was a significant effect of ectomycorrhizal morphotype on ACP(myc), ACP(mantle) and ACP(Hartig), while soil fertility had a significant effect on ACP(myc) and ACP(Hartig). The relative contribution of the mantle and the Hartig net region to the ACP activity on the ectomycorrhizal root was significantly affected by ectomycorrhizal morphotype and soil fertility. A positive correlation between ACP(Hartig) and the shoot P concentration was found, providing evidence that ACP activity at the fungus:root interface is involved in P transfer from the fungus to the host. It is concluded that the spatial distribution of ACP in ectomycorrhizas varies as a function of soil fertility and colonizing fungus.     

Toxicity of insecticidal soaps to the Asian citrus psyllid and two of its natural enemies

The Asian citrus psyllid (ACP), Diaphorina citri Kuwayama (Hemiptera: Psyllidae), is an important pest of citrus because it transmits plant pathogens responsible for a serious disease of citrus known as huanglongbing. Conventional insecticides are frequently used to manage ACP. Insecticidal soaps (hereafter ‘soaps’) are an insect control option labelled for commercial use as well as for use by homeowners and organic growers. Soaps have been shown to be toxic to some insect pests and therefore might be an alternative to conventional pesticides for control of ACP, but the efficacy of soaps against ACP was largely unknown. Our objective was to test whether different concentrations of two insecticidal soaps, M‐Pede and Safer Insecticidal Soap Concentrate, caused mortality of ACP adults, nymphs and eggs. In addition, we tested whether these soaps were toxic to two natural enemies of ACP, adults of the lady beetle Cycloneda sanguinea (L.) (Coleoptera: Coccinellidae) and the parasitoid Tamarixia radiata (Waterston) (Hymenoptera: Eulophidae). Direct sprays of M‐Pede or Safer Insecticidal Soap were acutely toxic to ACP adults (regardless of gender) and nymphs when applied in solutions of 0.8–2% in water. Insecticidal soaps were non‐toxic to eggs at rates of up to 2%. Residues of soap were less toxic to adult ACP than direct sprays, even when applied at concentrations of up to 4%. M‐Pede or Safer soap at high concentrations (for example, 2% v/v in water) may be an effective alternative to conventional pesticides to manage adult and nymphal ACP, although multiple applications may be needed if a target population includes eggs. A 2% concentration of either soap applied as a direct spray was non‐toxic to adult C. sanguinea but acutely toxic to adult T. radiata. Soaps therefore may be compatible with biological control of ACP by adult coccinellids but not the parasitoid T. radiata.     

Change in Levels of Acyl Carrier Proteins in Greening Plants

The levels of acyl carrier proteins (ACP) in greening spinachcotyledons and greening oat leaves were examined by immunoblottingwith antiserum raised against spinach ACP I. Two isoforms ofACP, ACP I and ACP II, were found in spinach cotyledons, asthey were in the green leaves. The level of ACP II was higherthan that of ACP I in etiolated cotyledons. The level of ACPI increased markedly with greening. In the greened cotyledons,the major isoform was ACP I as was the case in green spinachleaves. In oat leaves, two isoforms were also identified, oatACPI (about 12kDa) and ACP II (about 17kDa), which cross-reactedwith the antiserum against spinach ACP I, but which were differentfrom spinach ACPs I and II. The levels of oat ACPs I and IIwere very low in etiolated leaves. The increase in levels ofboth ACPs corresponded to the change in the activity of fattyacid synthesis during illumination for 24 h. During furtherillumination for 24 h, the level of ACP II increased a littlein parallel with the change in the activity of fatty acid synthesis,whereas the level of ACP I increased somewhat more. The functionof oat ACPs I and II is discussed in connection with the formationof chloroplast. (Received March 27, 1989; Accepted September 18, 1989)     

Properties of the Plastidial Acyl-(Acyl-Carrier-Protein): Glycerol-3-Phosphate Acyltransferase from the Chilling-Sensitive Plant Squash (Cucurbita moschata)

To determine whether the plastidial acyl-(acyl-carrier-protein(ACP)): glycerol-3-phosphate acyltransferase from chilling-sensitiveplants exhibits fatty acid selectivities different from thoseof resistant plants, we characterized this enzymic activityfrom the chilling-sensitive plant Cucurbita moschata. In squashcotyledons, the glycerol-3-phosphate acyltransferase (AT) occurredas three isomeric forms: one with an isoelectric point at pH6.6 (ATI) and two at about pH 5.5 (AT2 and AT3). These isomershad approximately equal total activities in plastids. All threeforms specifically directed acyl groups to the C-l positionof glycerol-3-phosphate. However, ATI differed from the twoother isomeric forms on the basis of kinetic data determinedwith different acyl-ACPs as substrates. These kinetic differenceswere reflected in the different fatty acid selectivities ofthe acyltransferases. ATI preferably utilized oleoyl groupsin comparison to palmitoyl and stearoyl groups while AT2 andAT3 hardly discriminated between the acyl-ACP thioesters. However,the observed selectivity of ATI was significantly reduced byincreasing the pH of the reaction mixture from 7.4 to 8.0, whichis the stroma pH of illuminated chloroplasts. Consequently,the glycerol-3-phosphate acyltransferases from squash cotyledonscould account for the high proportion of saturated acyl groupsfound at the C-l position of the plastidial phosphatidylglycerolfrom this plant. (Received April 7, 1987; Accepted July 8, 1987)     

Photoaffinity cross-linking of acyl carrier protein to Escherichiacoli membranes

Acyl Carrier Protein (ACP) is a small acidic protein which interacts with the various enzymes implicated in the biosynthesis of fatty acids in E. coli. It also interacts with the inner membrane proteins implicated in the biosynthesis of phospholipids. Samples of radioactive ACP were prepared with high specific activities and bearing photoactivable aryl azide derivatives. Two photoactivable reagents were used: para azido phenacyl bromide (pAPA) which reacts with the SH of the ACP prosthetic group and the N-hydroxysuccinimide ester of 4-azido salicilic acid (NHS-ASA) which reacts with the amino groups of the protein. Various methods were used to demonstrate that ACP could be cross-linked specifically to an inner membrane protein of E. coli, most probably to the glycerol-3-phosphate acyl transferase (GPAT). This covalent link should provide a powerful tool for further analysis of the structure of GPAT and its role in phospholipid biosynthesis. These photoactivable aryl azide derivatives of ACP could also be very useful for studying the interaction of ACP with the soluble enzymes implicated in fatty acid biosynthesis.     

Intein-mediated Cyclization of Bacterial Acyl Carrier Protein Stabilizes Its Folded Conformation but Does Not Abolish Function

Bacterial acyl carrier protein (ACP) is essential for the synthesis of fatty acids and serves as the major acyl donor for the formation of phospholipids and other lipid products. Acyl-ACP encloses attached fatty acyl groups in a hydrophobic pocket within a four-helix bundle, but must at least partially unfold to present the acyl chain to the active sites of its multiple enzyme partners. To further examine the constraints of ACP structure and function, we have constructed a cyclic version of Vibrio harveyi ACP, using split-intein technology to covalently join its closely apposed N and C termini. Cyclization stabilized ACP in a folded helical conformation as indicated by gel electrophoresis, circular dichroism, fluorescence, and mass spectrometry. Molecular dynamics simulations also indicated overall decreased polypeptide chain mobility in cyclic ACP, although no major conformational rearrangements over a 10-ns period were noted. In vivo complementation assays revealed that cyclic ACP can functionally replace the linear wild-type protein and support growth of an Escherichia coli ACP-null mutant strain. Cyclization of a folding-deficient ACP mutant (F50A) both restored its ability to adopt a folded conformation and enhanced complementation of growth. Our results thus suggest that ACP must be able to adopt a folded conformation for biological activity, and that its function does not require complete unfolding of the protein.