THE OXIDATION-REDUCTION POTENTIAL OF THE LUCIFERIN-OXYLUCIFERIN SYSTEM

The oxidation-reduction potential of the Cypridina luciferin-oxyluciferin system determined by a method of "bracketing" lies somewhere between that of anthraquinone 2-6-di Na sulfonate (E_o ^'' at pH of 7.7 = –.22) which reduces luciferin, and quinhydrone (E_o ^'' at pH of 7.7 = +.24), which oxidizes luciferin. Systems having an E_o ^'' value between –.22 and +.24 volt neither reduce oxyluciferin nor oxidize luciferin. If the luciferin-oxyluciferin system were truly reversible considerable reduction and oxidation should occur between –.22 and +.24. The system appears to be an irreversible one, with both "apparent oxidation" and "apparent reduction potentials" in Conant''s sense. Hydrosulfites, sulfides, CrCl₂, TiCl₃, and nascent hydrogen reduce oxyluciferin readily in absence of oxygen but without luminescence. Luminescence only appears in water solution if luciferin is oxidized by dissolved oxygen in presence of luciferase. Rapid oxidation of luciferin by oxygen without luciferase or oxidation by K₃Fe(CN)₆ in presence of luciferase but without oxygen never gives luminescence.     

CONTROL OF 5S RNA SYNTHESIS DURING EARLY DEVELOPMENT OF ANUCLEOLATE AND PARTIAL NUCLEOLATE MUTANTS OF XENOPUS LAEVIS

Ribosomes of all eukaryotes contain a single molecule of 5S, 18S, and 28S RNA. In the frog Xenopus laevis the genes which code for 18S and 28S RNA are located in the nucleolar organizer, but these genes are not linked to the 5S RNA genes. Therefore the synthesis of the three ribosomal RNAs provides a model system for studying interchromosomal aspects of gene regulation. In order to determine if the synthesis of the three ribosomal RNAs are interdependent, the relative rate of 5S RNA synthesis was measured in anucleolate mutants (o/o), which do not synthesize any 18S or 28S RNA, and in partial nucleolate mutants (p^l-1/o), which synthesize 18S and 28S RNA at 25% of the normal rate. Since the o/o and p^l-1/o mutants have a complete and partial deletion of 18S and 28S RNA genes respectively, but the normal number of 5S RNA genes, they provide a unique system in which to study the dependence of 5S RNA synthesis on the synthesis of 18S and 28S RNA. Total RNA was extracted from embryos labeled during different stages of development and analyzed by polyacrylamide gel electrophoresis. Quite unexpectedly it was found that 5S RNA synthesis in o/o and p^l-1/o mutants proceeds at the same rate as it does in normal embryos. Furthermore, 5S RNA synthesis is initiated normally at gastrulation in o/o mutants in the complete absence of 18S and 28S RNA synthesis.     

Immobilization of luciferase from the firefly Luciola mingrelica — Catalytic properties and stability of the immobilized enzyme

Firefly (Luciola mingrelica) luciferase [Photinus luciferin 4-monooxygenase (ATP-hydrolysing); Photinus luciferin: oxygen 4-oxidoreductase (decarboxylating, ATP-hydrolysing), EC 1.13.12.7] has been immobilized on albumin and polyacrylamide gel, on AH-, CH- and CNBr-Sepharose 4B as well as on Ultragel, Ultradex and cellophane film activated by cyanogen bromide. Only immobilization on cyanogen bromide-activated polysaccharide carriers resulted in highly active immobilized luciferase. Kinetic properties of immobilized luciferase hardly differed from those of the soluble enzyme. The inactivation rate constants of soluble and immobilized luciferase were measured at pH 5.5–9.0 and 25°C as well as at pH 7.8 and 20–40°C. The ΔH^≠ and ΔS^≠ values for inactivation of soluble and immobilized luciferases were obtained. A 1000-fold stabilization effect was noted for the luciferase immobilized on CNBr-Sepharose 4B at pH 7.5 and 25°C. A stabilization mechanism for the immobilized luciferase is discussed.     

Effect of External Calcium and of Temperature on Contraction in Snake Muscle Fibers

The effect of external calcium and of temperature on the contractile responses has been studied in voltage clamped snake twitch muscle fibers. Increasing [Ca⁺⁺]_o from 0.2 to 7.0 mM raised contractile threshold by 15–20 mV, the latter coinciding with the appearance of delayed rectification. The duration of contracture, the rates of rise and decay of tension depended on the level of depolarization and [Ca⁺⁺]_o. The minimum duration of repolarization necessary to restore the contractile response was much shorter in high [Ca⁺⁺]_o. When the bathing solution was cooled to 10 from 20°C the time-course of contracture was markedly prolonged and the outward current was reduced without significant change in maximum tension. The threshold for contraction tended to be somewhat lower at the lower temperature. The contractile repriming was much slower at low temperature. However, reduction in temperature slowed the rate of recovery much less at low [Ca⁺⁺]_o than at normal [Ca⁺⁺]_o.     

Mechanism of Inhibition by C-terminal α-Helices of the ? Subunit of Escherichia coli FoF1-ATP Synthase

The ϵ subunit of bacterial F_oF₁-ATP synthase (F_oF₁), a rotary motor protein, is known to inhibit the ATP hydrolysis reaction of this enzyme. The inhibitory effect is modulated by the conformation of the C-terminal α-helices of ϵ, and the “extended” but not “hairpin-folded” state is responsible for inhibition. Although the inhibition of ATP hydrolysis by the C-terminal domain of ϵ has been extensively studied, the effect on ATP synthesis is not fully understood. In this study, we generated an Escherichia coli F_oF₁ (EF_oF₁) mutant in which the ϵ subunit lacked the C-terminal domain (F_oF₁^ϵΔC), and ATP synthesis driven by acid-base transition (ΔpH) and the K⁺-valinomycin diffusion potential (ΔΨ) was compared in detail with that of the wild-type enzyme (F_oF₁^ϵWT). The turnover numbers (k_cat) of F_oF₁^ϵWT were severalfold lower than those of F_oF₁^ϵΔC. F_oF₁^ϵWT showed higher Michaelis constants (K_m). The dependence of the activities of F_oF₁^ϵWT and F_oF₁^ϵΔC on various combinations of ΔpH and ΔΨ was similar, suggesting that the rate-limiting step in ATP synthesis was unaltered by the C-terminal domain of ϵ. Solubilized F_oF₁^ϵWT also showed lower k_cat and higher K_m values for ATP hydrolysis than the corresponding values of F_oF₁^ϵΔC. These results suggest that the C-terminal domain of the ϵ subunit of EF_oF₁ slows multiple elementary steps in both the ATP synthesis/hydrolysis reactions by restricting the rotation of the γ subunit.     

Characterisation of ionisations that influence the redox potential of mitochondrial cytochrome c and photosynthetic bacterial cytochromes c2

Several cytochromes c₂ from the Rhodospirillaceae show a pH dependence of redox potential in the physiological pH range which can be described by equations involving an ionisation in the oxidised form (pK_o) and one in the reduced form (pK_r). These cytochromes fall into one of two groups according to the degree of separation of pK_o and pK_r. In group A, represented here by the Rhodomicrobium vannielii cytochrome c₂, the separation is approx. one pH unit and the ionisation is that of a haem propionic acid. Members of this group are unique among both cytochromes c₂ and mitochondrial cytochromes c in lacking the conserved residue Arg-38. We propose that the role of Arg-38 is to lower the pK of the nearby propionic acid, so that it lies out of the physiological pH range. Substitution of this residue by an uncharged amino acid leads to a raised pK for the propionic acid. In group B, represented here by Rhodopseudomonas viridis cytochrome c₂, the separation between pK_o and pK_r is approx. 0.4 pH unit and the ionisable group is a histidine at position 39. This was established by NMR spectroscopy and confirmed by chemical modification. Only a few other members of the cytochrome c₂/mitochondrial cytochrome c family have a histidine at this position and of these, both Crithidia cytochrome c-557 and yeast cytochrome c were found to have a pH-dependent redox potential similar to that of Rps. viridis cytochrome c₂. Using Coulomb's law, it was found that the energy required to separate pK_o and pK_r could be accounted for by simple electrostatic interactions between the haem iron and the ionisable group.     

Rat small-intestinal β-galactosidases: Influence of pH on the hydrolysis of different substrates

1. The influence of pH and the kind of buffer on the hydrolysis of lactose and four hetero-β-galactosides (phenyl β-galactoside, o-nitrophenyl β-galactoside, p-nitrophenyl β-galactoside and 6-bromo-2-naphthyl β-galactoside) by homogenates of rat small-intestinal mucosa has been studied. 2. There are at least two β-galactosidases present in the homogenates, one with optimum pH3–4 and another with optimum pH5–6. 3. The enzyme with the lower pH optimum is mainly a heterogalactosidase. It hydrolyses lactose slowly. The other enzyme is mainly a disaccharidase, since it hydrolyses lactose much more rapidly than the heterogalactosides. 4. Under the conditions used, citrate had an inhibitory effect on the 6-bromo-2-naphthyl β-galactosidase activity at pH3–4, but did not influence the 6-bromo-2-naphthyl β-galactosidase activity at pH5–6 or the hydrolysis of the other substrates at any pH.     

Effects of internal ph on the nonselective cation channel from the mouse collecting tubule

We investigated the effects of internal pH on Ca-activated, nucleotide-inhibited nonselective cation channels in the basolateral membranes of mouse collecting tubules, using the inside-out variant of the patch clamp technique. pH modulated the channel open probability (P _o ), giving a bell-shaped curve peaking at pH 6.8/7.0: P _o at pH 6.0 was 11±6% of P _o at pH 7.2 and 32 ±7% at pH 8.0. The open and closed time distributions, best fitted to the sum of two exponentials, were differently sensitive to acid and alkaline conditions. Low pH reduced the short and long open times to 38 and 24% of their pH 7.2 values, while high pH produced a 4-fold increase in the long closed time. As previously reported, 4-acetamido-4′-isothiocyanatostilbene-2,2′-disulfonic acid (SITS) induced a quasi-permanent opening of the channel. The inhibition of the channel produced by high pH disappeared in the presence of SITS, while the inhibition produced by low pH was unaffected. These results suggest that the pH dependence of the channel is due to two separate mechanisms. pH was without effect on the ATP-evoked inhibition of the channel, while high pH profoundly reduced the steepness of the AMP inhibition curve, without altering the half-maximal inhibitory AMP concentration.     

Some effects of o-phenanthroline on electron transport in chromatophores from photosynthetic bacteria

The midpoint potentials of the primary electron acceptors in chromatophores from Rhodopseudomonas spheroides and Chromatium have been studied by titrating the laser-induced P605 and cytochrome c oxidations, respectively. Both midpoint potentials are pH dependent (60 mV/pH unit).o-Phenanthroline shifts the midpoint potentials of the primary acceptors, by +40 mV in Rps spheroides and +135 mV in Chromatium. A similar though less extensive change in midpoint potential was observed in the presence of batho-phenanthroline, but not with 8-hydroxyquinoline. The shifted midpoints retain the same dependence on pH.Some of the effects of o-phenanthroline can be explained by assuming that it chelates the reduced form of the primary electron acceptor. This suggests the presence in the primary electron acceptor of a metal chelated by o- and batho-phenanthroline.In Rps spheroides chromatophores o-phenanthroline inhibits the laser- and flash-induced carotenoid shift at all redox potentials, stimulates the laser-induced P605 oxidation at redox potentials between +350 and +420 mV and slows the decay of the laser-induced cytochrome c oxidation below +180 mV. These effects show that o-phenanthroline may have more than one site of action.     

Chemistry,clones, and circadian control of the dinoflagellate bioluminescent system. The Marlene DeLuca memorial lecture

Bioluminescence in the dinoflagellate Gonyaulax polyedra occurs as brief bright flashes, originating from many (～400) small (～0.5 μm) cytoplasmic organelles which protrude into the acidic vacuole, and are thus surrounded by the tonoplast. Biochemically, the substrate is unusual; it is an open chain tetrapyrrole, highly unstable to air but protected in the cell at pH? 8 by virtue of a luciferin binding protein (LBP). This molecule is a dimer of 72 kDa subunits which, upon a decrease in pH, releases luciferin to react with oxygen in the luciferase (～140 kDa) catalysed luminescent reaction. cDNAs for both luciferase and LBP have been isolated and cloned, and the identity of LBP was confirmed by hybrid selection and in vitro translation of the message. The tenfold circadian (day to night) change in the amount of LBP, which parallels the in vivo rhythm of luminescence, is due to de novo synthesis and subsequent degradation of the protein each day. The LBP mRNA levels, as determined by in vitro translations and by Northern hybridizations, do not vary over the daily cycle, indicating that circadian control of bioluminescence in this species is mediated at the level of translation.     

Soluble tyrosinases from pharate pupal integument of the tobacco hornworm,Manduca sexta (L.)

Two soluble phenoloxidases were partially purified from pharate pupal integument of Manduca sexta by gel filtration or sucrose density gradient centrifugation. Thiourea was used to retard the formation of higher molecular weight aggregates. Subsequent analysis by gel filtration HPLC showed that the apparent molecular weights were about 300 kD and >700 kD. The smaller phenoloxidase was further purified by anion exchange HPLC. In comparative studies with mushroom tyrosinase and a fungal laccase, the Manduca phenoloxidases were identified as tyrosinases, since they exhibited monophenol mono-oxygenase activity (EC 1.14.18.1) and catechol oxidase activity (EC 1.10.3.1). Both enzyme preparations catalyzed ortho-hydroxylation of tyrosine at a relatively show rate, oxidized o-diphenols at a much faster rate than p-diphenols or monophenols, had broad pH optima from about pH 5.5–7.5, and were completely inhibited by 1 μM phenylthiourea, N-β-alanyldopamine (NBAD) and N-β-alanylnorepinephrine (NBANE), which are both abundant in pupal cuticle, were oxidized to o-quinones by the tyrosinases, with the former catecholamine oxidizing at a 10-fold higher rate than the latter. NBANE was synthesized from NBAD, apparently by spontaneous tautomerization of the o-quinone to a p-quinone methide, which then reacted with water to form the β-hydroxylated product. The possible role of tyrosinase in insect integument is discussed.     

Separate Gating Mechanisms Mediate the Regulation of K2P Potassium Channel TASK-2 by Intra- and Extracellular pH

TASK-2 (KCNK5 or K_2P5.1) is a background K⁺ channel that is opened by extracellular alkalinization and plays a role in renal bicarbonate reabsorption and central chemoreception. Here, we demonstrate that in addition to its regulation by extracellular protons (pH_o) TASK-2 is gated open by intracellular alkalinization. The following pieces of evidence suggest that the gating process controlled by intracellular pH (pH_i) is independent from that under the command of pH_o. It was not possible to overcome closure by extracellular acidification by means of intracellular alkalinization. The mutant TASK-2-R224A that lacks sensitivity to pH_o had normal pH_i-dependent gating. Increasing extracellular K⁺ concentration acid shifts pH_o activity curve of TASK-2 yet did not affect pH_i gating of TASK-2. pH_o modulation of TASK-2 is voltage-dependent, whereas pH_i gating was not altered by membrane potential. These results suggest that pH_o, which controls a selectivity filter external gate, and pH_i act at different gating processes to open and close TASK-2 channels. We speculate that pH_i regulates an inner gate. We demonstrate that neutralization of a lysine residue (Lys²⁴⁵) located at the C-terminal end of transmembrane domain 4 by mutation to alanine abolishes gating by pH_i. We postulate that this lysine acts as an intracellular pH sensor as its mutation to histidine acid-shifts the pH_i-dependence curve of TASK-2 as expected from its lower pK_a. We conclude that intracellular pH, together with pH_o, is a critical determinant of TASK-2 activity and therefore of its physiological function.     

ON THE QUANTA OF LIGHT PRODUCED AND THE MOLECULES OF OXYGEN UTILIZED DURING CYPRIDINA LUMINESCENCE

A study of the oxygen consumed per lumen of luminescence during oxidation of Cypridina luciferin in presence of luciferase, gives 11.4 x 10^–5 gm. oxygen per lumen or 88 molecules per quantum of λ = 0.48µ, the maximum in the Cypridina luminescence spectrum. For reasons given in the text, the actual value is probably somewhat less than this, perhaps of the order of 6.48 x 10^–5 gm. per lumen or 50 molecules of oxygen and 100 molecules of luciferin per quantum. It is quite certain that more than 1 molecule per quantum must react. On the basis of a reaction of the type: luciferin + 1/2 O₂ = oxyluciferin + H₂O + 54 Cal., it is calculated that the total efficiency of the luminescent process, energy in luminescence/heat of reaction, is about 1 per cent; and that a luciferin solution containing 4 per cent of dried Cypridina material should rise in temperature about 0.001°C. during luminescence, and contain luciferin in approximately 0.00002 molecular concentration.     

Why does the bioluminescent fungus <Emphasis Type="Italic">Armillaria mellea</Emphasis> have luminous mycelium but nonluminous fruiting body?

By determining the components involved in the bioluminescence process in luminous and nonluminous organs of the honey fungus Armillaria mellea, we have established causes of partial luminescence of this fungus. The complete set of enzymes and substrates required for bioluminescence is formed only in the mycelium and only under the conditions of free oxygen access. Since the synthesis of luciferin precursor (hispidin) and 3-hydroxyhispidin hydroxylase in the fruiting bodies is blocked, the formation of luciferin—the key component of fungal bioluminescent system—was not observed. That is why the fruiting body of Armillaria mellea is nonluminous despite the presence of luciferase, the enzyme that catalyzes the oxidation of luciferin with a photon emission.     

Chemical intermediates in dopamine oxidation by tyrosinase,and kinetic studies of the process

A minor pathway for dopamine oxidation to dopaminochrome, by tyrosinase, is proposed. Characterization of intermediates in this oxidative reaction and stoichiometric determination have both been undertaken. After oxidizing dopamine with mushroom tyrosinase or sodium periodate in a pH range from 6.0 to 7.0, it was spectrophotometrically possible to detect o-dopaminoquinone-H⁺ as the first intermediate in this pathway. The steps for dopamine transformation to dopaminochrome are as follows: dopamine → o-dopaminequinone-H⁺ → o-dopaminequinone → leuko-dopaminochrome → dopaminochrome. No participation of oxygen was detected in the conversion of leukodopaminochrome to dopaminochrome. Scanning spectroscopy and graphical analysis of the obtained spectra also verified that dopaminequinone-H⁺ was transformed into aminochrome in a constant ratio. The stoichiometry equation for this conversion is 2 o-dopaminequinone-H⁺ → dopamine + dopaminochrome. The pathway for dopamine oxidation to dopaminochrome by tyrosinase has been studied as a system of various chemical reactions coupled to an enzymatic reaction. A theoretical and experimental kinetic approach is proposed for such a system; this type of mechanism has been named “Enzymatic-chemical-chemical” (E_ZCC). Rate constants for the implied chemical steps at different pH and temperature values have been evaluated from the measurement of the lag period arising from the accumulation of dopaminochrome that took place when dopamine was oxidized at acid pH. The thermodynamic activation parameters of the chemical steps, the deprotonation of dopaminequinone-H⁺ to dopaminequinone, and the internal cyclization of dopaminequinone to leukodopaminochrome have been calculated.     

Potassium transport in Neurospora. Evidence for a multisite carrier at high pH

At low extracellular pH (4–6), net uptake of potassium by Neurospora is a simple exponential process which obeys Michaelis kinetics as a function of [K]_o. At high pH, however, potassium uptake becomes considerably more complex, and can be resolved into two distinct exponential components. The fast component (time constant = 1.2 min) is matched quantitatively by a rapid loss of sodium; it is attributed to ion exchange within the cell wall, since it is comparatively insensitive to low temperature and metabolic inhibitors. By contrast, the slower component (time constant = 10.9 min) is inhibited markedly at 0°C and by CN and deoxycorticosterone, and is thought to represent carrier-mediated transport of potassium across the cell membrane. This transport process exhibits sigmoid kinetics as a function of [K]_o; the data can be fitted satisfactorily by two different two-site models (one involving a carrier site and a modifier site, the other an allosteric model). Either of these models could also accommodate the simple Michaelis kinetics at low pH.     

Studies on cell enzyme systems; the kinetics of heat inactivation of cypridina luciferase

Solutions of the enzyme luciferase, extracted from Cypridina, were subjected at pH 6.8 to temperatures from 40–55°C. for times up to 24 hours. After the desired exposures samples were cooled rapidly to room temperature, mixed with luciferin, and the first order velocity constants (representing luciferase activity) of the resulting luminescent reactions were determined by a photo electric method. The form of the curve relating luciferase activity to time of exposure to a temperature in the above range is compound in nature. If the exposure to the high temperature is not too long, about two-thirds of the lost activity is slowly regained on standing at room temperature. The data were described by an equation which represents the following mechanism: See PDF for Equation A plot of the logarithm of the rate constant, k₁, against the reciprocal of the absolute temperature yielded an experimental activation energy for this reaction of about 57,000 calories, typical of protein denaturation processes. Log k₂ plotted against 1/T was described by either a curve or two straight lines, high activation energies resulting in either case, again indicating protein denaturation. The plot of log k₃: vs. 1/T showed no apparent dependence upon temperature, k₃ being practically constant over the range studied. This may indicate that the underlying mechanism is not actually as simple as pictured. Two other mechanisms that were also considered were discarded because of lack of experimental support. Measurements of the decrease of luciferase activity at 48°C. and at pH 6.7, pH 5.5, and pH 7.9 showed that inactivation of the enzyme at this temperature was much more rapid at pH 7.9 than at pH 6.7 and was even faster at pH 5.5. These results from the Cypridina luminescent system were compared with those of other investigators on other systems.     

Tryptophan 207 is crucial to the unique properties of the human voltage-gated proton channel,hHV1

Part of the “signature sequence” that defines the voltage-gated proton channel (H_V1) is a tryptophan residue adjacent to the second Arg in the S4 transmembrane helix: RxWRxxR, which is perfectly conserved in all high confidence H_V1 genes. Replacing Trp²⁰⁷ in human H_V1 (hH_V1) with Ala, Ser, or Phe facilitated gating, accelerating channel opening by 100-fold, and closing by 30-fold. Mutant channels opened at more negative voltages than wild-type (WT) channels, indicating that in WT channels, Trp favors a closed state. The Arrhenius activation energy, E_a, for channel opening decreased to 22 kcal/mol from 30–38 kcal/mol for WT, confirming that Trp²⁰⁷ establishes the major energy barrier between closed and open hH_V1. Cation–π interaction between Trp²⁰⁷ and Arg²¹¹ evidently latches the channel closed. Trp²⁰⁷ mutants lost proton selectivity at pH_o >8.0. Finally, gating that depends on the transmembrane pH gradient (ΔpH-dependent gating), a universal feature of H_V1 that is essential to its biological functions, was compromised. In the WT hH_V1, ΔpH-dependent gating is shown to saturate above pH_i or pH_o 8, consistent with a single pH sensor with alternating access to internal and external solutions. However, saturation occurred independently of ΔpH, indicating the existence of distinct internal and external pH sensors. In Trp²⁰⁷ mutants, ΔpH-dependent gating saturated at lower pH_o but not at lower pH_i. That Trp²⁰⁷ mutation selectively alters pH_o sensing further supports the existence of distinct internal and external pH sensors. Analogous mutations in H_V1 from the unicellular species Karlodinium veneficum and Emiliania huxleyi produced generally similar consequences. Saturation of ΔpH-dependent gating occurred at the same pH_o and pH_i in H_V1 of all three species, suggesting that the same or similar group(s) is involved in pH sensing. Therefore, Trp enables four characteristic properties: slow channel opening, highly temperature-dependent gating kinetics, proton selectivity, and ΔpH-dependent gating.     

Effect of Growth Conditions on Yield and Heme Content of Vitreoscilla

Vitreoscilla, a gliding bacterium in the Beggiatoaceae, is an obligate aerobe in which cytochrome o functions as the terminal oxidase. Protoheme IX is the only heme type present in this organism. The yield and heme content of Vitreoscilla cells grown in yeast extract, peptone, and acetate were dependent on growth conditions. Cells harvested in early stationary phase contained roughly three times as much heme as cells in early log phase. There was an optimal shaking rate for maximum heme content of cells harvested in stationary phase at fixed initial nutrient concentration. The heme content of cells grown at a fixed shaking rate increased from 5 nmol/g (wet weight) in media which had low nutrient concentration to a maximum of 45 nmol/g (wet weight) in media which had high nutrient concentration, and there was a corresponding sixfold increase in cytochrome o content and an eightfold increase in respiratory rate, evidence that some of the additional heme was incorporated into respiratory pigments. Heme content may be controlled jointly by competition for oxygen and availability of nutrients. Temperature and initial pH affected the growth rate but not the final yield or heme content. Growth rate was optimal at pH 8.0 to 8.5. A defined medium for Vitreoscilla, which is based on glutamate as the carbon source, is described; the other organic components of this medium are acetate, tryptophan, thiamine, biotin, and riboflavin.