Purification and properties of a phenol sulphotransferase from Euglena using L-tyrosine as substrate.

A purification procedure based on (NH4)2SO4 precipitation, and chromatography on Affi-Gel Blue, DEAE-cellulose, hydroxyapatite and Bio-Gel P-60 yields a stable 6400-fold-purified active monomeric phenol (tyrosine) sulphotransferase of 26 kDa from W10BSmL, an aplastidic mutant of Euglena gracilis var. bacillaris. The apparent Km for adenosine 3'-phosphate 5'-phosphosulphate (PAPS) is 15 microM (60 microM tyrosine as substrate); adenosine 5'-phosphosulphate is inactive. L-Tyrosine gave the lowest apparent Km (33 microM) (with PAPS at 30 microM), but tyrosine esters, tyrosinamide, L-p-hydroxyphenylglycine and a number of tyrosine dipeptides were also active, with higher Km values. Nitrophenols (m- and p-) and chlorophenols (o-, m- and p-) were active, with higher Km values than for tyrosine. D-Tyrosine was inactive as a substrate, as was D-p-hydroxyphenylglycine and a number of other tyrosine derivatives lacking the carboxy carbonyl or the amino group, or having extra ring substituents or the hydroxy group in the wrong position. Adenosine 3',5'-bisphosphate and tyrosine O4-sulphate, products of the enzyme reaction with PAPS and tyrosine as substrates, showed competitive (Ki = 20 microM) and uncompetitive (Ki = 500 microM) inhibition kinetics respectively. This appears to be the first phenol sulphotransferase to accept tyrosine as substrate. This membrane-bound enzyme may be involved in tyrosine transport as well as detoxification.

Photocontrol and processing of LHCP II apoprotein in Euglena: possible role of Golgi and other cytoplasmic sites.

Like other green photosynthetic eukaryotes, cells of Euglena gracilis var. bacillaris and strain Z contain a light-harvesting chlorophyll a/b complex associated with photosystem II. In Euglena, the formation of the 26.5 kDa principal light-harvesting chlorophyll a/b binding protein of photosystem II (LHCP II) has a number of unusual features. The precursors to LHCP II are large polyproteins containing multiple copies of LHCP II, and photocontrol of their formation is largely translational. Under conditions favoring LHCP II accumulation in the thylakoids, a reaction with anti-LHCP II antibody can be observed in the Golgi by immunogold electron microscopy. The timing of the immunoreaction in the Golgi in synchronous cells and in cells undergoing normal light-induced chloroplast development suggests that the nascent LHCP II passes through the Golgi on the way to the thylakoids. The compartmentalized osmiophilic structure (COS) also shows an immunoreaction. These observations, and other discussed in this paper, suggest that light permits translation of polyprotein LHCP II precursors on cytoplasmic ribosomes of the rough endoplasmic reticulum (ER) and that these pass through the ER to the Golgi where, presumably, further modifications take place. Since an LHCP II immunoreaction is found in Golgi vesicles, these may transport the nascent LHCP II to the plastid and facilitate its uptake.

Purification and properties of two forms of ATP sulfurylase from Euglena.

Two forms of ATP sulfurylase have been purified to homogeneity from mitochondria (ATPSm) and cells (ATPSc) of Euglena gracilis Klebs var. bacillaris Cori (aplastidic mutant W10BSmL). Both forms are monomeric, ATPSc is 52.3 kDa and ATPSm is 55 kDa. The pI is 7.9 for ATPSc and 5.8 for ATPSm. Therefore, ATPSm binds to DEAE-cellulose at pH 7.4; ATPSc does not. After cleavage by CNBr, the two forms of ATP sulfurylase show different sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) patterns, suggesting that they differ in amino acid sequence. ATPSm is mainly associated with the mitochondrial membrane and ATPSc is mainly soluble in the cells. Both enzymes require similar conditions in the molybdolysis assay, but show different pH optima when sulfate is used as substrate. ATPSc is more sensitive to adenosine 5'-phosphosulfate (APS) inhibition than ATPSm in the SO2-4 incorporation reaction. In the reverse reaction, ATPSc requires much higher concentrations of PPi and MgCl2 to saturate the reaction than ATPSm. The data indicate that the two enzymes are quite distinct and may have different roles in cell metabolism.

Stage-dependent localization of LHCP II apoprotein in the Golgi of synchronized cells of Euglena gracilis by immunogold electron microscopy.

We have localized LHCP II apoprotein in the Golgi and thylakoids of Euglena gracilis Klebs var. bacillaris Cori and strain Z Pringsheim by electron microscopy using a specific antibody and protein A-gold. Using synchronized cells (light, 14 h:dark, 10 h) we show that thylakoids are always immunoreactive. There is no reaction in the Golgi at 0 h (the beginning of the light period) but immunoreaction appears in the Golgi soon thereafter, rises to a peak at 8 h and declines to zero by 16 h (2 h into the dark period). The peak in immunoreaction in the Golgi immediately precedes the peak in cellular 14C-labeling of thylakoid LHCP II apoprotein seen by Brandt and von Kessel (Plant Physiol. (1983) 72, 616), supporting our suggestion that processing in the Golgi precedes deposition of LHCP apoprotein in the thylakoids. Substitution of preimmune serum for antiserum eliminates the immunoreaction in the Golgi, and thylakoids of synchronized cells of mutant Gr1BSL which lacks LHCP II apoprotein show no immunoreaction in the Golgi or thylakoids at any stage. Random observations indicate that the compartmentalized osmiophilic structure (COS) shows an immunoreaction with anti-LHCP II apoprotein antibody at 1 h into the light period (when the Golgi is not immunoreactive) and at 10 h into the light period (when the Golgi is fully reactive), suggesting that the COS remains immunoreactive throughout the cell cycle.

Purification and properties of adenosine 5'-phosphosulphate sulphotransferase from Euglena.

Adenosine 5'-phosphosulphate sulphotransferase (APSST) was extracted from Euglena gracilis Klebs var. bacillaris mutant W10BSmL by freezing and thawing and was purified about 10,000-fold (to homogeneity) with 10.5% recovery by (NH4)2SO4 precipitation, Sephadex G-100 chromatography, Reactive Blue-agarose, Reactive Dye-agarose, DEAE-cellulose, preparative isoelectric focusing and non-inactivating SDS/PAGE. The active APSST, with a molecular mass of 102 kDa and multiple forms from pI 5.0 to 5.5, is a tetramer held together by covalent (probably disulphide) bonds. An apparent Km of the purified enzyme for adenosine 5'-phosphosulphate (APS) of 0.1 microM is obtained when dithiothreitol is used as the thiol. The enzyme is stimulated by Mg2+, Ca2+ or Ba2+, and uses almost any thiol; dithiothreitol and dithioerythritol give the highest activity. In the absence of APS, the enzyme is inactivated (and is rendered monomeric) by thiols but is protected from thiol inactivation by AMP, adenosine 5'-phosphoramidate (APA) or adenosine 5'-monosulphate (AMS), which also inhibit APSST activity somewhat. The enzyme resists inactivation by SDS in the absence of thiols; SDS stimulates APSST activity at low concentration, but high concentrations are inhibitory.

Formation of tyrosine O-sulfate by mitochondria and chloroplasts of Euglena.

Mitochondria that have been purified from cells of light-grown wild-type Euglena gracilis Klebs var. bacillaris Cori or dark-grown mutant W10BSmL and incubated with 35SO4(2-) and ATP accumulate a labeled compound in the surrounding medium. This compound is also labeled when mitochondria are incubated with [14C]tyrosine and nonradioactive sulfate under the same conditions. This compound shows exact coelectrophoresis with synthetic tyrosine O-sulfate at pH 2.0, 5.8, and 8.0, and yields sulfate and tyrosine on acid hydrolysis. Treatment with aryl sulfatase from Aerobacter aerogenes yields sulfate and tyrosine but no tyrosine methyl ester; no hydrolysis of tyrosine methyl ester to tyrosine is observed under identical conditions, ruling out methyl esterase activity in the aryl sulfatase preparation. Thus the compound is identified as tyrosine O-sulfate. No tyrosine O-sulfate is found outside purified developing chloroplasts of Euglena incubated with 35SO4(2-) and ATP, but both chloroplasts and mitochondria accumulate labeled tyrosine-O-sulfate externally when incubated with adenosine 3'-phosphate 5'-phospho[35S]-sulfate (PAP35S). Since tyrosine does not need to be added, it must be provided from endogenous sources. Labeled tyrosine O-sulfate is found in the free pools of light-grown Euglena cells grown on 35SO4(2-) or in dark-grown cells incubated with 35SO4(2-) in light, but none is found in the medium after cell growth. No labeled tyrosine O-sulfate is found in Euglena proteins (including those in extracellular mucus) after growth or incubation of cells with 35SO4(2-) or after incubation of organelles with 35SO4(2-) and ATP or PAP35S, ruling out sulfation of the tyrosine in protein or incorporation of free-pool tyrosine O-sulfate into protein. The system forming tyrosine O-sulfate is membrane-bound and may be involved in transporting tyrosine out of the organelles.

A sulphate metabolizing centre in Euglena mitochondria.

We have previously shown that a sulphate activating system is present on the outside of the inner mitochondrial membrane of Euglena gracilis Klebs. var. bacillaris Cori, but efforts to couple this system to ATP produced from oxidative phosphorylation were unsuccessful. In the present work we show that the concentration of Pi ordinarily used to support oxidative phosphorylation in these mitochondria (10 mM) inhibits sulphate activation completely; by reducing the concentration of Pi 10-fold, both processes proceeded normally. Sulphate activation under these conditions is inhibited nearly completely by the uncouplers of oxidative phosphorylation dinitrophenol (0.1 mM) and carbonyl cyanide m-chlorophenylhydrazone (CCCP) (0.2 microM). Sulphate reduction to form free cysteine, most of which appears outside the organelle, and in the cysteine of mitochondrial protein can be demonstrated in the same preparations, is membrane-bound and is inhibited by chloramphenicol (100 micrograms/ml), NaN3 (5 mM), KCN (100 microM); dinitrophenol (0.1 mM) or CCCP (0.2 microM). Digitonin fractionation of the mitochondria into mitoplasts, outer membranes and an intermembrane fraction show that reduction of 35SO4(2-) to form free cysteine and cysteine of protein is located on the mitoplasts; adenosine 5'-phosphosulphate sulphotransferase, the first enzyme of sulphate reduction, is found in the same location. Sulphate activation is highly enriched in the mitochondrial fraction of Euglena; the small amount found in the chloroplast fraction can be attributed to mitochondrial contamination. Thus, in Euglena, sulphate activation and reduction are contained in a sulphate metabolizing centre on the outside of the mitochondrial inner membrane; this centre appears to supply the mitochondrion and the rest of the cell with the products of sulphate activation as well as with reduced sulphur in the form of cysteine. Mitochondria from wild-type Euglena cells and from W10BSmL, a mutant lacking plastids completely, appear to be similar in the properties studied.

Purification, properties, and cellular localization of Euglena ferredoxin-NADP reductase.

Ferredoxin-NADP reductase from Euglena gracilis Klebs var. Bacillaris Cori purified to apparent homogeneity, yields a typical 36 kDa and an unusual 15 kDa polypeptide on sodium dodecyl sulfate-polyacrylamide gel electrophoresis, exhibits a typical flavoprotein spectrum, contains FAD, and catalyzes NADPH-dependent iodonitrotetrazolium-violet diaphorase, NADPH-specific ferredoxin-dependent cytochrome-c-550 reductase and NADPH-NAD transhydrogenase activities. Rabbit antibody to the purified FNR blocks these activities specifically and also blocks the iodonitrotetrazolium-violet diaphorase activity of Euglena chloroplast completely. The low iodonitrotetrazolium-violet diaphorase activity in the plastidless mutant, W10BSmL, is mitochondrial and is not specifically blocked by the ferredoxin-NADP reductase antibody. Dark-grown non-dividing (resting) wild-type Euglena cells show a 4-fold increase in ferredoxin-NADP reductase activity during greening at 970 lx. Half of the low ferredoxin-NADP reductase activity in dark-grown cells is initially soluble, but by the end of chloroplast development nearly all of the enzyme is membrane-bound. The binding of ferredoxin-NADP reductase on exposure to light correlates with the extent of thylakoid membrane formation. Immunoblots of wild-type extracts during greening indicate that the 15 kDa polypeptide increases in the same manner as the extent of reductase binding to thylakoid membranes.

Light-independent and dependent phases of proplastid development in Euglena gracilis W3BUL.

Cells of Euglena gracilis Klebs var. bacillaris Cori mutant W3BUL grown in darkness on Hutner's pH 3.5 medium without agitation accumulate wax ester. These cells have undeveloped proplastid remnants characteristic of this mutant. If these cells are transferred to an inorganic medium and bubbled with 2-3% CO2 in air, the wax disappears and the proplastid expands and develops in darkness to form prolamellar bodies and membrane vessicles within 96 h. No further development takes place in darkness, but if these cultures are illuminated at 96 h formation of prothylakoids is observed. Thus the wax ester accumulated during growth can be used subsequently to support proplastid development up to the prolamellar body stage, but the formation of prothylakoids is strictly light-dependent. Development in this system takes place at a slower rate than in cells grown with shaking and lacking wax which are transferred to resting medium. As previously shown, all of proplastid development requires light under these conditions. It is suggested that the oxygen-requiring utilization of wax in darkness can provide energy and metabolites for a part of proplastid development but the later steps in these cells, or the entire development in cells lacking wax is supported by paramylum degradation which is strictly light-dependent. However, a specific light reaction required for prothylakoid organization is not ruled out.

Short latency somatosensory and spinal evoked potentials: power spectra and comparison between high pass analog and digital filter.

Medium nerve somatosensory evoked potentials (SSEPs) and intraoperative spinal evoked potentials were analyzed using different analog and zero phase shift digital high pass filter and by power spectrum. Additionally, high pass analog and digital filtering was performed on various sine, triangular and rectangular waves manufactured by a wave form generator. Recordings were also transformed to the 1st and 2nd time derivatives. The great abundance of spectral energy for scalp recorded median nerve SSEPs was below 125 c/sec but lower energy fast frequency components consistently extended to 500 c/sec. Power spectrum of the Erb's point compound nerve action potential revealed a wide band of spectral energy commencing at about 50-100 c/sec, peaking at about 250-270 c/sec and extending to nearly 1000 c/sec. This suggests that synchronous axonal activity generates predominantly faster frequencies above 100 c/sec. High pass analog filter confers phase non-linearity which results in various distortions including latency shift and a morphological change which may be visually similar to the 1st or 2nd time derivatives. High pass zero phase shift digital filter removes selected low frequencies without accompanying phase distortion. This accentuates fast peaks seen at open bandpass as well as transition points between baseline and component ascent or descent. Zero phase shift digital filter may also generate peaks that are not visualized at open pass but which reflect the sum of frequencies which were not removed by filtering. These peaks do not necessarily correspond to discrete singular neuroanatomical structures. Although peaks observed in high pass analog and digital filter appear similar and comparable, their underlying activity may be of different origin. This is because high pass analog filter projects a considerable amount of overlap from earlier onto later waves. For clinical correlation it is important that restricted bandpass analog or digitally filtered recordings be compared with open pass data. Only those peaks visualized in both open and restricted bandpass can be considered authentic. Examples of spinal and scalp SSEPs indicate that selective filtering may, under certain circumstances, distinguish axonal or lemniscal from synaptic generators.

Photocontrol of chloroplast and mitochondrial polypeptide levels in euglena.

Two dimensional polyacrylamide gel electrophoresis resolved protein from intact chloroplasts of wild type Euglena gracilis Klebs var. bacillaris Cori into 185 polypeptides of which 55 were localized on the whole cell polypeptide map. Of these chloroplast polypeptides, the relative amounts of 49 increased, the relative amounts of two decreased, and the relative amounts of four polypeptides were unaltered by exposure of dark grown resting cells to light for 72 hours. Proteins from intact purified mitochondria obtained from a bleached mutant (W(10)BSmL) lacking plastids were resolved into 193 polypeptides of which 44 were localized on the whole cell polypeptide map from wild type cells. Of these mitochondrial polypeptides, the relative amount of one increased, the relative amounts of 12 were unaltered, and the relative amounts of 31 decreased after exposure of the dark grown resting cells to light. Since it is known that the development of the chloroplast in Euglena occurs without a net increase in total cellular protein and without a change in the size of the cellular amino acid pools, the degradation of mitochondrial polypeptides represents a major source of amino acids for the synthesis of chloroplast polypeptides.

Chlorophyll-Protein Complexes from Euglena gracilis and Mutants Deficient in Chlorophyll b: I. Pigment Composition.

The use of n-octyl-beta-d-glucopyranoside along with sodium dodecyl sulfate improves the retention of chlorophyll (Chl) by chlorophyll-protein complexes (CPs) prepared from thylakoids of Euglena gracilis Klebs var bacillaris Cori and yields several additional complexes. Thylakoids from wild-type (WT) cells, solubilized in these detergents and subjected to polyacrylamide gel electrophoresis at 0 degrees C, yield the following CPs, in order of relative molecular weight, containing the pigments shown in parentheses with their respective molar ratios where determined: CP Ia (Chl a, diadinoxanthin and beta-carotene; 100:12:5); CP I (Chl a and beta-carotene; 100:6-12); CPx (Chl and carotenoids); LHCP(2) (light-harvesting CP oligomer) (Chl a, Chl b, diadinoxanthin and neoxanthin; 12:4:3:1); CPy (Chl a, diadinoxanthin and beta-carotene; 100:14:8); CPa (Chl a and beta-carotene; 100:18-25) and LHCP (monomer) (Chl a, Chl b, diadinoxanthin and neoxanthin; 12:6:4:1). The LHCP complexes retain up to 40% of the total Chl and 80% of the Chl b in the thylakoids. CP Ia contains only a trace of Chl b (Chl a/b [mol/mol] = 62). The lower amount of Chl b in Euglena (about 10% of Chl a + b) compared to higher plants (about 30% of Chl a + b) is probably a consequence of the lower Chl b (relative to Chl a) in the LHCPs of Euglena rather than of fewer LHCPs being present. G(1)BU, Gr(1)BSL, and O(4)BSL, mutants of bacillaris low in Chl b (1-2% of Chl a + b), lack the CP Ia, LHCP, and LHCP(2) found in wildtype (WT); G(1) and O(4) also lack CPy. The mutants contain reduced amounts of Chl a (two-thirds of WT in Gr(1) and one-third in G(1) and O(4)) and neoxanthin (20-40% of WT) but retain levels of beta-carotene and diadinoxanthin close to those in cells of WT. The CPs remaining in the mutants have pigment compositions very similar to their counterparts from WT.

Chlorophyll-Protein Complexes from Euglena gracilis and Mutants Deficient in Chlorophyll b: II. Polypeptide Composition.

Chlorophyll-protein complexes (CPs) obtained from thylakoids of Euglena gracilis Klebs var bacillaris Cori contain the following polypeptides (listed in parentheses in order of prominence after Coomassie R-250 staining of polyacrylamide gels): CP Ia (66, 18, 22, 22.5, 27.5, 21, 28, 24, 25.5, and 26 kilodaltons [kD]); CP I (66 kD); CPx (41 kD); LHCP(2) (an oligomer of LHCP) (26.5, 28, and 26 kD); CPy (27 and 19 kD); CPa (54 kD); and LHCP (26.5, 28, and 26 kD). Mutants of bacillaris low in chlorophyll b (Gr(1)BSL, G(1)BU, and O(4)BSL; Chl a/b [mol/mol] = 50-100) which lack CP Ia, LHCP(2), and LHCP also lack or are deficient in polypeptides associated with these complexes in wild-type cells. Mutants G(1) and O(4), which also lack CPy, lack the CPy-associated polypeptides found in wild-type and Gr(1). Using an antiserum which was elicited by and reacts strongly and selectively with the SDS-treated major polypeptide (26.5 kD) of the LHCP complexes of wild-type, this polypeptide is undetectable in the mutants (<<0.25% of the level in wild-type on a cell basis); the antiserum does not react with the SDS-treated 28 kD polypeptide of the Euglena LHCP complexes and cross-reacts only very weakly with components in SDS-treated cells of Chlamydomonas reinhardtii Dangeard and chloroplasts of Spinacia oleracea L. cv Winter Bloomsdale. Rates of photosynthesis of the wild-type and mutant cells of Euglena are approximately equal on a cell basis when measured at light saturation, consistent with the selective loss of major antenna components but not CP I or CPa from the mutants.

Localization of a sulphate-activating system within Euglena mitochondria.

Intact mitochondria, obtained from Euglena gracilis Klebs var. bacillaris Cori mutant W10BSmL, which lacks plastids, and purified on Percoll density gradients, form adenosine 3'-phosphate 5'-phosphosulphate from sulphate. The optimal conditions include addition of 17 mM-Tricine/KOH, pH 7.6, 18 mM-MgCl2, 250 mM-sucrose, 5.66 mM-sodium ADP (or 0.94 mM-sodium ATP), 1 mM-K2SO4, carrier-free 35SO4(2-) (32.1 microCi) and 1.0 mg of mitochondrial protein in a total volume of 2.65 ml and incubation at 30 degrees C. Experiments with the inhibitor of adenylate kinase P1, P5-di(adenosine 5'-)pentaphosphate indicate that ATP is the preferred substrate for sulphate activation; ADP is utilized by conversion into ATP via adenylate kinase. ATP sulphurylase, adenylylsulphate kinase (APS kinase) and inorganic pyrophosphatase constitute the sulphate-activating system; ADP sulphurylase is undetectable. Fractionation of Euglena mitochondria with digitonin and centrifugation allowed the separation of outer-membrane vesicles and mitoplasts as judged by electron microscopy and selected enzymic markers. The detergent-labile association of the sulphate-activating system with the mitoplasts (similar to that of adenylate kinase), the fact that most of the adenosine 3'-phosphate 5'-phosphosulphate formed by intact mitochondria is found in the surrounding medium, and the ease with which nucleotide substrates reach the activating system in intact organelles, suggest that the enzymes of sulphate activation are located on the outer surface of the mitochondrial inner membrane.

Light-triggered organization of the stigma in dark-grown nondividing cells of Euglena gracilis.

Dark-grown cells of Euglena gracilis Klebs var. bacillaris Cori contain amorphous stigma material. When these cells are placed on resting medium for 3 days in darkness, the cells cease division; the organization of a normal stigma from the amorphous material requires continuous illumination for 72-96 hr. We have now found that if dark-grown cells are placed on resting medium for 8 days, a 40-min light pulse is sufficient to cause normal organization of the stigma in a subsequent 72-hr dark period. Thus stigma development is light-dependent at 3 days of resting but becomes light-triggered at 8 days. Other examples of light-triggered phenomena in Euglena are discussed and a model based on turnover of protein molecules repressing development that are ordinarily removed by exposure to light is presented; it is suggested that as the cells become more starved their ability to replace repressor molecules removed by light becomes limited and the system thereby becomes light-triggered rather than light-dependent.

Synthetic abilities of Euglena chloroplasts in darkness.

Protein synthesis, normally a light-dependent process in isolated mature chloroplasts of Euglena gracilis var. bacillaris will take place in darkness if ATP and Mg2+ (ATP/Mg) are supplied. Either 5 or 10 mM ATP plus 15 mM MgCl2 are optimal and rates equal to those in the light can be obtained. Since ATP and Mg2+ are not stoichiometrically related, and since the optimal Mg2+ concentration is similar to that which stabilizes chloroplast ribosomes in vitro, it is suggested that the chloroplast is freely permeable to Mg2+ under these conditions. Protein synthesis under these conditions is not inhibited appreciably by DCMU, FCCP, cycloheximide, or by the addition of ribonuclease, but is highly sensitive to chloramphenicol. Carbon dioxide fixation is also a light-dependent process in isolated mature chloroplasts from Euglena, but addition of ATP (5 mM) and fructose bisphosphate (5 mM) plus aldolase (1.0 unit/ml) (fructose-1,6-bisphosphate/aldolase) yields CO2 fixation rates in darkness that are 43% of those normally obtained in the light. Mg2+ higher than 1.0 mM (e.g., 16 mM) is somewhat inhibitory. Chlorophyll synthesis from 5-aminolevulinate in 36 h developing chloroplasts from Euglena is also light-dependent, but addition of ATP/Mg and fructose-1,6-bis-phosphate/aldolase in darkness brings about the accumulation of a compound having the same RF on chromatography as protochlorophyllide from Barley; a subsequent brief illumination of the chloroplasts converts this compound to a compound with the RF of chlorophyll. Thus Euglena chloroplasts supplied with appropriate additions can carry out protein synthesis, carbon dioxide fixation and most of chlorophyll synthesis in darkness. This versatility is appropriate in photosynthetic organelles isolated from photo-organotrophic cells.

Brainstem auditory evoked potentials in Guillain-Barré syndrome.

Brainstem auditory evoked potentials were abnormal in five of six patients with Guillain-Barré syndrome. The abnormalities imply focal demyelination in the extramedullary portion of the auditory nerve.

Chlorophyll biosynthesis from glutamate or 5-aminolevulinate in intact Euglena chloroplasts.

Chloroplasts observed, by electron microscopy, to be intact and uncontaminated, with high rates of light-dependent protein synthesis and CO2 fixation were isolated from cells grown on low-vitamin-B12 medium in the light or from cells grown in the same medium in the dark and then exposed to light for 36 h. Both types of chloroplasts were active but less variability was encountered with developing chloroplasts from 36-h cells. The 36-h chloroplasts showed good light-dependent incorporation of 5-amino-levulinic acid (ALA) or L-glutamic acid into chlorophyll (Chl) a which was linear for approx. 1 h. The specific activity of the Chl a remained the same after conversion to pheophytin a, methylpheophorbide a or pyromethylpheophorbide a and rechromatography, indicating that the label was in the tetrapyrrole. Incorporation of ALA was inhibited by levulinic acid, and by chloramphenicol and other inhibitors of translation of 70S-type chloroplast ribosomes at concentrations which did not appreciably inhibit photosynthesis but which blocked plastid protein synthesis nearly completely. Cycloheximide, an inhibitor of translation on 87S cytoplasmic ribosomes of Euglena, was without effect. The 70S inhibitors did not block uptake of labeled ALA. Although labeled glycine was taken up by the plastids, no incorporation into Chl a was observed. Thus the developing chloroplasts appear to contain all of the enzymatic machinery necessary to convert glutamic acid to Chl via the C5 pathway of ALA formation but the Shemin pathway from succinyl coenzyme A and glycine to ALA appears to be absent. The requirement for plastid protein synthesis concomitant with Chl synthesis indicates a regulatory interaction and also indicates that at least one protein influencing Chl synthesis is synthesized on 70S-type plastid ribosomes and is subject to metabolic turnover.