Metabolic changes during substrate shifts in continuous cultures of the yeast Candida boidinii variant 60

Summary Substrate shift experiments in chemostat cultures with either methanol or glucose as carbon source were performed with the yeast Candida boidinii variant 60. At low dilution rates of 0.064 h^–1 the culture may be easily shifted from methanol to glucose medium and back again to methanol. From these experiments it can be seen that glucose does not give rise to any catabolite inhibition of alcohol oxidase. Alcohol oxidase and formaldehyde dehydrogenase seem to be regulated by a repression-derepression mechanism, as small basal activities of both these enzymes can still be measured during growth on glucose. On the other hand, formate dehydrogenase activity is completely absent in the presence of glucose. This kind of regulation seems to favor the smooth switch from growth on glucose to methanol metabolism.With methanol or glucose, growth yields (Y_S) of 0.3 and 0.35, respectively may be obtained, and oxygen consumption (Q_{O 2}) is much higher in methanol cultures than in glucose-grown cells. Accordingly, the RQ values during growth on methanol decrease to about 0.5. Based on the yield coefficient of 0.3, it is possible to calculate that 38% of the methanol consumed must be incorporated into biomass, whereas 62% of the methanol is oxidized to CO₂. The corresponding RQ of 0.56 could not be experimentally ascertained.The activities of three mitochondrial enzymes were found to be higher in methanol-grown cells than in cells from glucose cultures. The low activites of enzymes for the phosphogluconate route in methanol-grown cells indicates that a cyclic oxidation of formaldehyde via hexose phosphate to CO₂ cannot be of great importance for methanol metabolism.List of Symbols D 1/h Dilution rate - 1/h Specific growth rate - Q_{CO 2} mmol/g·h Specific CO₂ production rate - Q_{O 2} mmol/g·h Specific O₂ comsumption rate - Q_S g/g·h Specific substrate consumption rate - RQ ./. Respiratory quotient (Q_{CO 2}/Q_{O 2}) - S_O g/l Substrate concentration in the feeding medium - $#x0073;$#x0304 g/l Substrate concentration in the fermentor - $#x0078;$#x0304 g/l Biomass in the fermentor - Y_{O 2} g/mmol O₂ Biomass yield on oxygen - Y_S g/g Biomass yield on carbon source     

STUDIES ON THE BIOCHEMISTRY AND FINE STRUCTURE OF SILICA SHELL FORMATION IN DIATOMS. II. THE STRUCTURE OF THE CELL WALL OF NAVICULA PELLICULOSA (BRÉB.) HILSE

The cell wall of the freshwater diatom Navicula pelliculosa (Bréb.) Hilse is composed of the silica shell and an organic skin which surrounds it. Isolated skins can be prepared by first removing the contents of the cell by mechanical shaking, followed by a posttreatment of these isolated cell walls with HF vapor to remove the silica shell. T h e skins can also be seen in sections, particularly well after the silica shell has been removed B y H. F; vapor. The origin and morphological composition of the shin in N. pelliculosa are not yet completely ascertaincd. As parts of the cell wn11, both the silica shell and the skin are extracellularly located. The growth of the silica shell, however, occurs intracellularly inside a vesicle delimited by a triple-layered membrane, the silicalemma. This membrane or secondary excreted organic material or both in various proportions may compose the skin.     

Synthesis and characterization of iodopropyl derivatives of adenosine 3′,5′-cyclic-monophosphate: Potential affinity labels of cAMP binding sites in enzymes

The syntheses of two potential cAMP affinity lables, 1,N ⁶-(3-iodopropyleno)adenosine 3′,5′-cyclic-monophosphate and 2′-O-(2-iodo-3-hydroxypropyl) adenosine 3′,5′-cyclic-monophosphate, by a two-step chemical procedure are described. TheN ⁶- and 2′-O-allyl intermediates were prepared selectively by alkylation of cAMP in organic and alkaline aqueous solutions, respectively. Treatment of theN ⁶-allyl derivative withN-iodosuccinimide resulted in iodine addition to the double bond and cyclization to theN ¹ position of the purine ring. The iodohydrin analog was synthesized by reaction of 2′-O-allyl-cAMP with potassium iodide and thallium trichloride in acetate buffered solution. The products were isolated by column chromatography and characterized by thin-layer chromatography, elemental analysis, and ultraviolet,¹³C, and¹H NMR spectroscopy. The cAMP analogs were found to react with lysine and cysteine. Both cAMP derivatives were tested for their reaction with the low-K _m cAMP phosphodiesterase of human platelets. The ribose-substituted analog functioned as a competitive inhibitor (K _I =0.72 μM) and caused a time-dependent irreversible inactivation of the phosphodiesterase. In contrast, the purine-substituted derivative acted neither as a reversible competitive inhibitor nor as an irreversible inactivator of the enzyme. These results indicate the specificity of these potential cAMP analogs in their interaction with the phosphodiesterase.     

Isolation and characterization of cyclic AMP-independent glycogen synthase kinase from rat skeletal muscle

Glycogen synthase kinase was isolated from rat skeletal muscle. This kinase, which is cyclic nucleotide-independent and calcium-independent, was separated from phosphorylase kinase, cyclic AMP-dependent protein kinase and phosvitin kinase by phosphocellulose chromatography. Gel filtration on Sephadex G-100 resolved the glycogen synthase kinase into two fractions with apparent molecular weights of 68 000 (peak I) and 52 000 (peak II). This step also separated glycogen synthase kinase from the catalytic subunit of the cyclic AMP-dependent protein kinase, which had an apparent molecular weight of 39 000. Peak II glycogen synthase kinase activity was not affected by the addition of calcium, EGTA or a number of cyclic nucleotides. In addition to ATP, dATP would serve as the phosphate donor. Other trinucleotides tested were either poor or ineffective substrates. Activity was about 5-fold greater with Mg2+ than with Mn2+. Glycogen stimulated activity about 25%. Modifications of the methods of Soderling et al. ((1970) J. Biol. Chem. 245, 6317--6328) and Nimmo et al. ((1976) Eur. J. Biochem. 68, 21--30) were developed for purification of glycogen synthease (UDPglucose:glycogen 4-alpha D-glucosyltransferase, EC 2.4.1.11) to specific activity of 35 units/mg of protein. Using this preparation of glycogen synthase as substrate, the phosphorylation and inactivation catalyzed by glycogen synthase kinase was compared to that catalyzed by cyclic AMP-dependent protein kinase or phosphorylase kinase. Each of the kinases had different specificities for phosphorylation sites on glycogen synthase.     

Glycogen synthase in diabetic rat skeletal muscle: activation by insulin

Summary Glycogen synthase in skeletal muscle of 3-day alloxan-diabetic rats was found to be in a less active state than in normal muscle. Both the activity ratio (activity without G6P divided by activity with 7.2 mM G6P at 4.4 mM UDPG, pH 7.8) and fractional velocity (activity with 0.25 mM G6P divided by activity with 10 mM G6P at 0.03 mM UDPG, pH 6.9) were significantly lower in the diabetic tissue. Correspondingly, the S_0.5 for UDPG and A_0.5 for G6P were significantly higher in diabetic tissue, suggesting decreased affinity for substrate and activator, respectively. The kinetic changes in the diabetic synthase were identical whether the alloxan-treated animals were maintained on insulin for 7 days prior to withdrawal for 3 days, or studied 3 days immediately after alloxan treatment. The diabetes-induced changes in synthase could be reversed by injecting the diabetic rat with insulin 10 min prior to sacrifice. After insulin treatment, the S_0.5 for UDPG and A_0.5 for G6P decreased to control levels or lower and the activity ratios and fractional velocities increased to control levels or higher.The activity of glycogen synthase phosphatase was not decreased in diabetic skeletal muscle. This observation, coupled with the rapid response of the diabetic synthase to in vivo insulin treatment, suggests that, unlike the phosphatase in cardiac muscle and liver, the glycogen synthase phosphatase in skeletal muscle is not altered by the diabetic state.Abbreviations UDPG uridine diphosphoglucose - G6P glucose 6-phosphate - EDTA ethylene diamine tetraacetic acid - IP intraperitoneally - MOPS morpholinopropane sulfonic acid - -ME -mercaptoethanol - V_G6P calculated velocity of the enzyme in the presence of infinite G6P concentration - V_UDPG calculated velocity of the enzyme in the presence of infinite UDPG concentration     

Phosphate Regulation of Nitrate Assimilation in Soybean

It is known that phosphorus deficiency results in alterationsin the assimilation of nitrogen. An experiment was conductedto investigate mechanisms involved in altered ¹⁵NO^–₃ uptake,endogenous ¹⁵N translocation, and amino acid accumulation insoybean (Glycine max L. Merrill, cv. Ransom) plants deprivedof an external phosphorus supply for 20 d in solution culture.Phosphorus deprivation led to decreased rates of ¹⁵NO^–₃uptake and increased accumulation of absorbed ¹⁵N in the root.Both effects became more pronounced with time. Asparagine, theprimary transport amino acid in soybean, accumulated in largeexcess in roots and stems. In roots of phosphorus-deprived plants,concentrations of ATP and inorganic phosphate declined rapidly,but dry weight accumulation was similar to or above that ofthe control even after 20 d of treatment. Arginine accumulationin leaves was greatly enhanced, even though ¹⁵N partitioninginto the insoluble reduced-N fraction of leaves was unaffected.The results suggest that decreases in NO^–₃ uptake in lowphosphorus plants could be caused by feedback control factorsand by limited ATP availability. The decline in endogenous Ntransport from the root to the shoot may be associated withchanges in membrane properties, which also result in paralleleffects on hydraulic conductance and the upward flow of waterthrough the plant. Key words: Phosphorus stress, nitrate uptake, nitrate translocation, arginine     

Production of 1,3-propanediol by Clostridium butyricum DSM 5431 and product tolerant mutants in fedbatch culture: Feeding strategy for glycerol and ammonium

Summary A fedbatch strategy was developed coupling the feeding of the two inhibitory substrates glycerol and ammonium to alkali consumption. A continuous, automated substrate addition was achieved responding directly to the needs of the culture. Thus substrate concentrations were kept on a constant low, but non limiting level. The feeding was applied for the cultivation of Clostridium butyricum DSM 5431 and mutants with increased product tolerance. Compared to fedbatch cultivations with intermittent feeding cultivation times were considerably shortened.     

Biomechanics of the joints of the large toe. Shape and movement of the first tarsometatarsal joint and of the medial cuneonavicular joint]

90% of the first (hallucal) tarsometatarsal joints are screw-shaped; the axis is directed upwards to the front touching the lateral edge of the joint. Thus the plantar flexion is inevitably accompanied by an adduction and a pronation, and vice versa a dorsiflexion is consequently accompanied by an abduction and a supination, when the articular surfaces exactly slide along each other. 10% of these joints, however, are ellipsoid-shaped; in this case the distal articular surface of the medial cuneiform bone has the form of an ovoid head, and a strong ligament situated next to the lateral edge of the joint effects the same kind of motion described above. The medial cuneonavicular joint is always ellipsoid-shaped, the head of which is made up by the medial facet of the distal articular surface of the navicular bone. Each of the two joints mentioned has a considerable range of mobility.     

Compartmentalization of cholesterol metabolism and cellular growth in cultured intestinal crypt cells

Growth of rat intestinal crypt derived cells IEC-6 ceased when the key enzyme of cholesterol synthesis, hydroxymethylglutaryl-CoA reductase, was blocked by the competitive inhibitor mevinolin. This effect was reversed by the addition of mevalonolactone. LDL suppressed reductase activity as well as cholesterol synthesis from [14C]octanoate and stimulated acyl-CoA cholesterol acyltransferase, but failed to support cell growth despite rapid receptor mediated degradation even in the presence of low mevalonolactone concentrations. Inhibition of cholesterol esterification by Sandoz-Compound 58-035 enhanced cell growth in the presence of mevinolin, but did not promote proliferation in the additional presence of low-density lipoproteins. HDL3 but not HDL2 or tetranitromethane-modified HDL3 totally reversed the mevinolin induced inhibition of cell growth. This rescue by HDL3 was overcome by an increased dose of mevinolin. HDL3 derepressed reductase, stimulated cholesterol synthesis and reduced cholesterol esterification, but did not reverse the cholesterol synthesis inhibition by mevinolin. It is concluded that IEC-6 cells preferentially use endogenously synthesized cholesterol for membrane formation rather than low-density lipoprotein cholesterol. High-density lipoproteins appear to normalize cell growth in the presence of mevinolin by inhibition of cholesterol esterification and probably by inducing the formation of non sterol products of mevalonate.