Effects of clavines, ergot alkaloids, on the membrane potential of an identifiable giant neuron of the African giant snail Achatina fulica Ferussac

The effects of seven clavines, alkaloids of ergot, on the electrical activity of an identifiable giant neurone (TAN, tonically autoactive neurone) of the African giant snail were examined. All the substances examined, lysergine, agroclavine, elymoclavine, festuclavine, chanoclavine, rugulovasine A and rugulovasine B, at 2 X 10(-4) kg/l have no constant effect on TAN, indicating that they have no direct effect on this neurone. However, the substances examined, except for chanoclavine, in the same concentration occasionally caused the transient depression with an augmentation of trans-synaptic influences. This depression may be due to the trans-synaptic influences. The four substances examined, lysergine, agroclavine, elymoclavine and festuclavine, in the same concentration produced TAN abnormal spike discharges, doublet or triplet spikes.     

Physiological control and process kinetics of clavine alkaloid production byClaviceps purpurea

Summary Kinetic parameters of production of clavine alkaloids were evaluated in twoClaviceps purpurea strains. Mutagenesis brought about enhanced resistance of the biosynthetic system towards alkaloids. Addition of glucose into the fermentation medium altered the zero order kinetics of production to activation-inhibition kinetics. The glucose treatment allowed performance of both elymoclavine-inhibitionless and clavine alkaloid-decompositionless fermentations if a combination of fermentation and separation units in a closed loop was used.Nomenlacture k ₁ rate constant of agroclavine synthesis (mg Agro · mg Elymo/l·g DW·day for stage 1, mg Agro/g DW·day for stage 2) - k ₂ parameter describing inhibition of agroclavine formation rate by elymoclavine (mg Elymo/l) - k ₃ specific rate of agroclavine decay (l/g DW·day) - k ₄ maximal specific rate of elymoclavine synthesis (stage 1, 1/g DW·day, stage 2, mg Elymo/g DW·day) - k ₄ ^– maximal specific rate of elymoclavine synthesis in stage 1 (inhibition-activation mechanism) (mg Elymo/g DW·day) - k ₅ physiological constant describing the elymoclavine decay rate (l²/g DW·day·mg Elymo) - k ₅ ^– physiological constant describing the activation of elymoclavine biosynthesis by elymoclavine (mg Elymo/l) - k ₆ physiological constant describing the repression of elymoclavine biosynthesis by elymoclavine (mg Elymo/l) - k ₇ maximal specific growth rate (1/day) - k ₈ specific rate of biomass decay (l/g DW·day) - A agroclavine concentration (mg/l) - E elymoclavine concentration (mg/l) - r _A specific rate of agroclavine biosynthesis (mg Agro/g DW·day) - r _E specific rate of elymoclavine biosynthesis (mg Elymo/g DW·day) - r _i specific rate of alkaloid biosynthesis (mg alkaloid/g DW·day) - X dry biomass concentration (g/l) - specific growth rate (1/day) Abbreviations Agro agroclavine - Elymo elymoclavine - Chano chanoclavine - DW dry weight of biomass     

Glycosylation of ergot alkaloids by free and immobilized cells of Claviceps purpurea

Summary A new strain, Claviceps purpurea 88-EP-47, with high invertase activity was selected. Free and Calginate immobilized cultures of this strain were used for fructosylation of ergot alkaloids. By bioconversion from their aglycones, elymoclavine-O--d-fructofuranosyl(21)-O--d-fructofuranoside, and elymoclavine-O--d-fructoside, the respective fructosides of chanoclavine, lysergol and dihydro-lysergol monofructosides were obtained. These substances are formed by -d-fructofuranosidase present in Claviceps cells. The bioconversion activity of the enzyme system (fructose transfer) is strongly dependent on pH, substrate (sucrose) concentration and the developmental profile of invertase activity. The pH optimum for elymoclavine fructosylation is 6.5, for chanoclavine 5.7, and the optimal sucrose concentration is 75 g/l. Fifteen-day-old production cultures had the best glycosylation activities. Fructosylation of alkaloids can be stimulated in production cultures of C. purpurea or C. fusiformis forming elymoclavine or chanoclavine by a pH shift to 6.5 at the end of the production phase. Glycosylating Claviceps strains producing elymoclavine eliminate the free alkaloid into glycosides. The feedback inhibition of alkaloid synthesis by elymoclavine is then strongly reduced, helping to further improve elymoclavine yields. Elymoclavine can be liberated simply by invertase activity of baker's yeast.Offprint requests to: V. Ken     

Separation of ergot alkaloids by adsorption on silicates

A mixture of ergot alkaloids (agroclavine, elymoclavine, chanoclavine, and chanoclavine aldehyde) was separated from the Claviceps purpureafermentation broth by adsorption on inorganic adsorbents containing silica. The uptake of alkaloids depended on the concentration of adsorbent and pH. The adsorption capacity for of inorganic materials increased with increasing content of inorganic oxides such as MgO and CaO in the adsorbent. Using statistical thermodynamics, a simple mathematical model describing the multicomponent adsorption equilibrium is proposed and a numerical method suitable for fast computer simulation of multicomponent adsorption was developed.     

Studies onClaviceps parasitic onPanicum species in India

Panicum repens andP. antidotale were found to be infected withClaviceps sp. This is the first report of ergot onP. repens. The pyrenomycete produced abundant sclerotia on the host plants. The sclerotia contained 0.71 and 0.68 % alkaloids, respectively, which predominantly consisted of chanoclavine, festuclavine and agroclavine. The infected grasses were possibly mycotoxic. Submerged cultures ofClaviceps strain isolated fromPanicum spp produced significant amount of chanoclavine, festuclavine and agroclavine. No pharmaceutically important alkaloid was found in sclerotia or in submerged culture.     

Synthesis of α-mannosylated ergot alkaloids employing α-mannosidase

The ergot alkaloids elymoclavine, ergometrine and chanoclavine were α-mannosylated with α-mannosidase as catalyst. The kinetic reaction with p-nitrophenyl α-mannoside as glycosyl donor gave ca 28 % yield of chanoclavine α-mannoside, whereas the equilibrium reaction with mannose as the glycosyl donor gave ca 11 % yield. However, in the case of elymoclavine and ergometrine, higher yields of α-mannosides were obtained with the equilibrium approach (18 and 13 %).     

Relationship between Acid Tolerance, Cytoplasmic pH, and ATP and H+-ATPase Levels in Chemostat Cultures of Lactococcus lactis

The acid tolerance response (ATR) of chemostat cultures of Lactococcus lactis subsp. cremoris NCDO 712 was dependent on the dilution rate and on the extracellular pH (pH_o). A decrease in either the dilution rate or the pH_o led to a decrease in the cytoplasmic pH (pH_i) of the cells, and similar levels of acid tolerance were observed at any specific pH_i irrespective of whether the pH_i resulted from manipulation of the growth rate, manipulation of the pH_o, or both. Acid tolerance was also induced by sudden additions of acid to chemostat cultures growing at a pH_o of 7.0, and this induction was completely inhibited by chloramphenicol. The end products of glucose fermentation depended on the growth rate and the environmental pH_o of the cultures, but neither the spectrum of end products nor the total rate of acid production correlated with a specific pH_i. The rate of ATP formation was not correlated with pH_i, but a good correlation between the cellular level of H⁺-ATPase and pH_i was observed. Moreover, an inverse correlation between the cytoplasmic levels of ATP and pH_i was established. Each pH_i below 6.6 was characterized by unique levels of ATR, H⁺-ATPase, and ATP. High levels of H⁺-ATPase also coincided with high levels of acid tolerance of cells in batch cultures induced with sublethal levels of acid. We concluded that H⁺-ATPase is one of the ATR proteins induced by acid pH_i through growth at an acid pH_o or a slow growth rate.     

Selection of Ergot Alkaloid Producers by Induced Mutagenesis

Using the induced mutagenesis technique, a series of genetically modified Clavicepssp. VKM F-2609 strains that display high levels of agroclavine and elymoclavine synthesis were selected by induced mutagenesis. Compared to the parent strain, c106 displayed a 40-fold higher level of agroclavine synthesis, and c66 displayed an eightfold higher level of elymoclavine synthesis. The levels of synthesis of other alkaloids were decreased in these strains. The effects of various carbohydrates on the strain growth and ergot alkaloid biosynthesis was then investigated in both the parent strain and c106. The largest amount of agroclavine was synthesized by c106 strain growing on a medium with maltose.     

Optimization of Conditions for Storage and Cultivation of the Fungus Claviceps sp., a Producer of the Ergot Alkaloid Agroclavine

Conditions of agroclavine biosynthesis by the mutant Claviceps sp. strain c106 were studied. The content of agroclavine was maximum (1.5–2 g/l) on days 15–16 of cultivation in the complex medium T25, containing sucrose, citric acid, and yeast extract. Agroclavine was the major component of the alkaloid fraction (90–95%). Storage of the culture at –70°C in T25 supplemented by 7% glycerol provided a stable level of alkaloid formation.     

Acclimation of photosynthesis to temperature in eight cool and warm climate herbaceous C3 species: Temperature dependence of parameters of a biochemical photosynthesis model

To determine how parameters of a Farquhar-type photosynthesis model varied with measurement temperature and with growth temperature, eight cool and warm climate herbaceous crop and weed species were grown at 15 and 25 °C and single leaf carbon dioxide and water vapor exchange rates were measured over the range of 15 – 35 °C. Photosynthetic parameters examined were the initial slope of the response of assimilation rate (A) to substomatal carbon dioxide concentration (C_i), A at high C_i, and stomatal conductance. The first two measurements allow calculation of V_Cmax, the maximum rate of carboxylation of ribulose bisphosphate carboxylase and J_max, the maximum rate of photosynthetic electron transport, of Farquhar-type photosynthesis models. In all species, stomatal conductance increased exponentially with temperature over the whole range of 15 – 35 °C, even when A decreased at high measurement temperature. There were larger increases in conductance over this temperature range in the warm climate species (4.3 ×) than in the cool climate species (2.5 ×). The initial slope of A vs. C_i exhibited an optimum temperature which ranged from 20 to 30 °C. There was a larger increase in the optimum temperature of the initial slope at the warmer growth temperature in the cool climate species than in the warm climate species. The optimum temperature for A at high C_i ranged from 25 to 30 °C among species, but changed little with growth temperature. The absolute values of both the initial slope of A vs. C_i and A at high C_i were increased about 10% by growth at the warmer temperature in the warm climate species, and decreased about 20% in the cool climate species. The ratio of J_max — V_Cmax normalized to 20 °C varied by more than a factor of 2 across species and growth temperatures, but differences in the temperature response of photosynthesis were more related to variation in the temperature dependencies of J_max and V_Cmax than to the ratio of their normalized values.This revised version was published online in October 2005 with corrections to the Cover Date.     

A new control strategy for yeast production based on the L/A* approach

Summary We studied the effect of temperature on the production of an extracellular neutral metalloproteinase of Bacillus megaterium in a laboratory fermentor under constant aeration and pH. The optimal temperature for growth (35–38° C) was higher than that for the synthesis of proteinase during exponential growth (below 31° C). The critical biomass concentration at which the exponential growth terminated decreased with increase in cultivation temperature. The specific rate of proteinase synthesis decreased when the critical biomass concentration was achieved. The observed decrease in proteinase synthesis was related to the cultivation temperature. The temperature also influenced the level of mRNA coding for proteinase. We formulated a mathematical model of cultivation describing the dependence of growth and proteinase synthesis on dissolved oxygen and temperature. The parameters of the model were identified for temperature intervals from 21 to 41° C using a computer. The optimum temperature for the enzyme production was 21° C. The productivity (enzyme activity/time) was maximal at 24–28° C. When optimizing the temperature profile of cultivation, we designed a suboptimal solution represented by a linear temperature profile. We have found that under conditions of continuous decrease in temperature, the maximal production of the proteinase was achieved at a broad range of temperature (26–34° C) when the rate of temperature decrease was 0.2–0.8° C/h. The initial optimal temperature for the enzyme productivity was in the range of 32–34° C. The optimum temperature decrease was 0.8° C/h. Offprint requests to: J. Chaloupka     

The CO2/O2 specificity of ribulose 1,5-bisphosphate carboxylase/oxygenase

The substrate specificity factor, V _cK_o/V_oK_c, of spinach (Spinacia oleracea L.) ribulose 1,5-bisphosphate carboxylase/oxygenase was determined at ribulosebisphosphate concentrations between 0.63 and 200 M, at pH values between 7.4 and 8.9, and at temperatures in the range of 5° C to 40° C. The CO₂/O₂ specificity was the same at all ribulosebisphosphate concentrations and largely independent of pH. With increasing temperature, the specificity decreased from values of about 160 at 5° C to about 50 at 40° C. The primary effects of temperature were on K _c [Km(CO₂)] and V _c [Vmax (CO₂)], which increased by factors of about 10 and 20, respectively, over the temperature range examined. In contrast, K _o [Ki (O₂)] was unchanged and V _o [Vmax (O₂)] increased by a factor of 5 over these temperatures. The CO₂ compensation concentrations () were calculated from specificity values obtained at temperatures between 5° C and 40° C, and were compared with literature values of . Quantitative agreement was found for the calculated and measured values. The observations reported here indicate that the temperature response of ribulose 1,5-bisphosphate carboxylase/oxygenase kinetic parameters accounts for two-thirds of the temperature dependence of the photorespiration/photosynthesis ratio in C₃ plants, with the remaining one-third the consequence of differential temperature effects on the solubilities of CO₂ and O₂.Abbreviations RuBPC/O(ase) ribulose 1,5-bisphosphate carboxylase/oxygenase - RuBP ribulose 1,5-bisphosphate - CO₂ compensation concentration     

Laboratory production of ergot alkaloids by species of balansia.

Four species of Balansia (clavicipitaceous systemic grass pathogens) isolated from pastures where cattle showed signs of ergot toxicity were grown in culture. Balansia epichlo?, one isolate of B. claviceps, B. henningsiana and two isolates of B. strangulans produced conidia in submerged culture during the first stage of a two-stage fermentation procedure. When tranferred to a glucose/sorbitol/inorganic salts medium during the second stage, these four species produced ergot alkaloids in stationary cultures. The transfer of fungi cultured in the first medium to the second medium was necessary for alkaloid biosynthesis. One isolate of B. claviceps did not produce alkaloids. Balansia epichlo? produced chanoclavine (I), agroclavine, penniclavine, elymoclavine, ergonovine and ergonovinine. Balansia claviceps produced chanoclavine (I), ergonovine and ergonovinine. This is the first report of isolating ergonovine and ergonovinine, two lysergic acid derivatives, from fungi outside the genus Claviceps. Only chanoclavine (I) was identified from extracts of B. strangulans and B. henningsiana. Chanoclavine (I) and ergonovine were identified from smut grass (Sporobolus poiretii) parasitized by B. epichlo?, indicating that this endophyte produces alkaloids both in vivo and in vitro.     

Diversity in amylopectin structure, thermal and pasting properties of starches from wheat varieties/lines

Structural, thermal and pasting diversity of starches from Indian and exotic lines of wheat was studied. Majority of the starches showed amylose content ranging between 22% and 28%. Endotherm temperatures (T_o, T_p and T_c) of the starches showed a range between 56–57, 60 –61 and 65.5–66.5 °C, respectively. Exotherms with T_p between 87.0 and 88.2 °C were observed during cooling of heated starches, indicating the presence of amylose–lipid complexes. Exotherm temperatures were negatively correlated to swelling power. Amylopectin unit chains with different degree of polymerization (DP) were observed to be associated with pasting temperature, setback and thermal (endothermic T_o, T_p, and T_c) parameters. Amylopectin unit chains of DP 13–24 showed positive relationship with endothermic T_o, T_p and T_c. Pasting temperature showed positive correlation with short chains (DP 6–12) while negative correlation with medium chain (DP 13–24) amylopectins. Setback was positively correlated to DP 16–18 and negatively to DSC amylose–lipid parameters.     

Life history,resting egg formation,and hatching may explain the temporal-geographical distribution ofArtemia strains in the Mediterranean basin

Life history traits are presented for the sexual species (Artemia tunisiana) and for parthenogenetic diploid and tetraploid strainsA. parthenogenetica reared at 15 °, 24 ° and 29.5 °C.In laboratory cultures, we present evidence that the seasonal appearance of the sexualArtemia tunisiana (the dominant winter-spring population), and of two parthenogenetic populations ofArtemia (the dominant spring-summer populations) in certain Spanish saltworks is controlled by temperature through its effect on reproductive and survival traits. Minimum and maximum reproductive output and survival for the sexual and parthenogenetic populations, respectively, occurred at a typical temperature (24 °C) of the late-spring season when the sexual population is replaced by parthenogenetic forms. Furthermore, the high production and hatchability of cysts from the sexual population at low temperatures (15 °C), and of the parthenogenetic populations at middle temperature (24 °C), indicate the role of dormancy as an adaptation regulating seasonal occurrence.     

Reproduction of Diaeretiella rapae on Russian wheat aphid hosts at different temperatures

Diaeretiella rapae (M'Intosh), a polyphagous and cosmopolitan parasite of aphids, was imported from China to the USA for biological control of Diuraphis noxia (Mordwilko), a pest of small grains. We studied several aspects of its biology on D. noxia hosts in the laboratory at 3 constant temperatures, 10.0, 21.1, and 26.7 °C. Females lived significantly longer than males at all 3 temperatures, and longevity was greatest at 10 °C, followed by 21.1 and 26.7 °C. Fecundity (= number of mummies) did not differ significantly among the 3 temperatures studied. The ovarian egg-load was 129.1 ± 9.3, and was significantly affected by the size of adult females. A pre-oviposition period ± 0.26 days) was detected at 10 °C, but not at the other temperatures. Pre-imaginal survivorship was similar among temperatures, while R _o and T _c decreased with temperature, and r _m increased with temperature. The offspring sex ratio (proportion females) was lowest at 26.7 °C, and similar between 10.0 and 21.1 °C. In addition, the offspring sex ratio significantly declined with the age of the female parent. The suitability of D. rapae for colonization against D. noxia in North America is discussed in relation to its responses to temperature and the climate of its home range.     

Temperature and pressure effects on structural and conformational properties of POPC/SM/cholesterol model raft mixtures—a FT-IR, SAXS, DSC, PPC and Laurdan fluorescence spectroscopy study

We report on the effects of temperature and pressure on the structure, conformation and phase behavior of aqueous dispersions of the model lipid “raft” mixture palmitoyloleoylphosphatidylcholine (POPC)/bovine brain sphingomyelin (SM)/cholesterol (Chol) (1:1:1). We investigated interchain interactions, hydrogen bonding, conformational and structural properties as well as phase transformations of this system using Fourier transform-infrared (FT-IR) spectroscopy, small-angle X-ray scattering (SAXS), differential scanning calorimetry (DSC) coupled with pressure perturbation calorimetry (PPC), and Laurdan fluorescence spectroscopy. The IR spectral parameters in combination with the scattering patterns from the SAXS measurements were used to detect structural and conformational transformations upon changes of pressure up to 7-9 kbar and temperature in the range from 1 to about 80 °C. The generalized polarization function (GP) values, obtained from the Laurdan fluorescence spectroscopy studies also reveal temperature and pressure dependent phase changes. DSC and PPC were used to detect thermodynamic properties accompanying the temperature-dependent phase changes. In combination with literature fluorescence spectroscopy and microscopy data, a tentative p,T stability diagram of the mixture has been established. The data reveal a broad liquid-order/solid-ordered (l_o + s_o) two-phase coexistence region below 8 ± 2 °C at ambient pressure. With increasing temperature, a l_o + l_d + s_o three-phase region is formed, which extends up to ∼27 °C, where a liquid-ordered/liquid-disordered (l_o + l_d) immiscibility region is formed. Finally, above 48 ± 2 °C, the POPC/SM/Chol (1:1:1) mixture becomes completely fluid-like (liquid-disordered, l_d). With increasing pressure, all phase transition lines shift to higher temperatures. Notably, the l_o + l_d (+s_o) phase coexistence region, mimicking raft-like lateral phase separation in natural membranes, extends over a rather wide temperature range of about 40 °C, and a pressure range, which extends up to about 2 kbar for T = 37 °C. Interestingly, in this pressure range, ceasing of membrane protein function in natural membrane environments has been observed for a variety of systems.     

Selection of ergot alkaloid producers by induced mutagenesis

Using the induced mutagenesis technique, A series of genetically modified Claviceps sp. VKM F-2609 strains that display high levels of agroclavine and elymoclavine synthesis were selected by induced mutagenesis. Compared to the parent strain, c106 displayed a 40-fold higher level of agroclavine synthesis, and c66 displayed an eightfold higher level of elymoclavine synthesis. The levels of synthesis of other alkaloids were decreased in these strains. The effects of various carbohydrates on the strain growth and ergot alkaloid biosynthesis was then investigated in both the parent strain and c106. The largest amount of agroclavine was synthesized by c106 strain growing on a medium with maltose.     

Potassium and the Recovery of Arterial Smooth Muscle after Cold Storage

The influence of K on the performance of vascular smooth muscle was studied by observing the mechanical performance of the muscle under conditions in which the magnitudes of [K_i] and of the [K_i]:[K_o] ratio varied in opposite directions. During prolonged storage at 4°C the artery strips lost K and their ability to respond to stimuli. Subsequently they were transferred to recovery solutions of various [K_o] at 38°C. The initial rate of K_i reaccumulation and steady state [K_i] were greater in solutions of higher [K_o]. Conversely for any time during recovery, the greater [K_o], the smaller the [K_i]:[K_o] ratio. When the strip was placed in the warm recovery solution it first contracted and then relaxed. The initial contraction was not relatable to [K_o] of the recovery solution but the subsequent relaxation was greater in rate and magnitude as [K_o] was greater. As the muscles recovered further they went into tonic contracture. As the [K_o] in the recovery solutions was greater these contractures occurred after shorter recovery times, and attained greater amplitude at a faster rate. Solution-switching experiments indicated a dependence of responses to electrical shocks on both the [K_i]:[K_o] ratio and [K_i]. Conclusions drawn were: (a) increased [K_i] increases contractility, (b) increased [K_i] increases the rate of relaxation, (c) excitability is decreased by too high or low a [K_i]: [K_o] ratio, and (d) the extent of tonic shortening depends on the [K_i]:[K_o] ratio.     

Ion channel involvement in the temperature-sensitive response of the rabbit corneal endothelial cell resting membrane potential

Previous studies have shown that the resting potential (E _m) of the corneal endothelium hyperpolarizes following an increase in temperature above 24°C. Whole-cell studies using the perforated-patch technique were used to compare currents and E _mvalues from isolated corneal endothelial cells at 24 and 32°C. These studies revealed a small, outwardly rectifying, slowly activating, weakly voltage-dependent current with a reversal potential showing K⁺ selectivity (E _rev = –80 mV). This current had features similar to the whole-cell current seen following addition of HCO₃ ^– to these cells. E _mmeasurements found an average 24 mV hyperpolarization following temperature elevation in NaCl Ringer. Single channel studies found the only change in channel activity following an elevation in temperature to be an increase in the open probability (P _o) of a K⁺ channel previously reported in this cell type to be activated by external anions. P _o(–30 mV) at 24 and 32°C equaled 0.003 and 0.06, respectively. Increases in P _owere found at all voltages examined. This increased P _ocan account for the magnitude of the hyperpolarization seen in these cells following temperature elevation. Addition of HCO₃ ^– along with elevated temperature produced a synergistic effect on the increase in P _oalong with an increased hyperpolarization of the cell, pointing to separate mechanisms of activation from these two stimuli.The authors would like to thank Ms. Helen Hendrickson for her technical support and Drs. Gianrico Farrugia and Adam Rich for their helpful comments. This work was supported by NIH grants EY09673, EY03282, EY06005, and an unrestricted award from Research to Prevent Blindness.