In vitro synthesis of peritrophic membranes of the blowfly, Calliphora erythrocephala.

Tyrode solution containing added glutamine and Leloup's medium 1 has been used as a basic medium for the in vitro culture of the so-called proventriculus of adult Calliphora erythrocephala to elucidate some of the factors controlling the synthesis of peritrophic membranes (PM) in vitro. The formation rate was chosen as a quantitative criterion for the evaluation of the modifications of the incubation media.After systematic variation of osmolarity, pH, and temperature optimal formation rates were obtained in media with an osmolarity of 320 to 360 mOsmol, a pH of 6·8, and an incubation temperature of 27°C. Under these conditions the average rate of formation was in the modified Tyrode solution 3·0±1·1 mm PM/hr, and in Leloup's medium 3·6±0·8 mm PM/hr. In the modified Tyrode solution the formation of PM was complete after 5 to 7 hr, whereas in Leloup's medium it continued up to 24 hr. The addition of β-ecdysone caused an increase of the formation rate of PM to 4·5 to 5·5 mm PM/hr.The results obtained led to the hypothesis that an osmotically regulated enzyme system could be the limiting factor of the formation rate of peritrophic membranes, i.e. a system which could regulate the internal osmolarity of the formative cells by the interconversion of a bulk polymer and its monomer which are needed for the synthesis of PM.     

The fine structure of peritrophic membranes of the blowfly, Calliphora erythrocephala, grown in vitro under different conditions.

The formation of peritrophic membranes (PM) in vitro was studied in a flow chamber in order to avoid the accumulation of metabolic substances during prolonged incubation. During the first 8 to 10 hr of incubation the production of PM was nearly constant—3·5 ± 1·4 mm PM/hr. After about 10 hr it decreased and stopped after about 35 hr. Between 1 and 8 hr after the beginning of incubation the width of the periodic crossband pattern reached or nearly reached the values found in PM which had formed in vivo; afterwards it decreased more and more. During the first 20 min of incubation a ‘disturbed zone’ of PM without any regular crossband pattern is formed.In the cardia of adult Calliphora erythrocephala there are three formation zones forming three PM of different fine structures. The fine structure of PM 1 to 3 formed in vitro during the first 6 to 8 hr of incubation in Leloup's medium 1, with an osmolarity of 340 mOsmol, a pH of 6·8, and a temperature of 27°C, does not differ from the PM grown in vivo. PM 1–3 grown in vitro in Tyrode's solution with added glutamine or in Leloup's medium with added β-ecdysone show a considerable increase in thickness and a disturbed formation of the electron dense layer of PM 1.     

Temporal relationships between leaving food, ecdysone release, mucoprotein extrusion and puparium formation in Drosophila virilis

The time sequence of various developmental processes at the end of larval life in Drosophila virilis larvae is reported. If reared at 25·3°C the larvae leave their food about 140 hr after oviposition; 6·6 hr later ecdysone release occurs, while 8·5 to 9 hr after leaving food the mucoprotein, synthesized and stored in the salivary gland cells, is extruded into the lumen of the gland. Puparium formation takes place 11·2 hr after leaving food. Changes in the puffing activity are correlated with these processes.     

Dynamics of the pregnancy cycle in the tsetse Glossina morsitans

A normal pregnancy in tsetse involves the successful integration of larval development with maternal activity. At 25°C, ovulation in Glossina morsitans occurs 1 hr after the previous larviposition, the egg hatches on day 3·8 (1·57 mm length, 0·09 mg dry wt.), ecdysis to second instar occurs on day 4·9 (2·3 mm, 0·30 mg), the third instar cuticle is formed on day 6·8 (4·5 mm, 5·0 mg), and parturition occurs on day 9·0 (6·0 mm, 10·0 mg). Melanization of the in utero third instar follows a regular sequence over a 2 day period. Parturition follows a circadian pattern with a peak 9 hr after lights on (12 hr daily photophase). All instars receive nutriment from the female's milk gland. During early pregnancy the rate of milk synthesis is greater than rate of uptake by the larva, thus causing expansion of the secretory reservoirs. After day 6, the volume of the secretory reservoirs decreases, but as is indicated by nuclear volume and larval growth the rate of synthesis remains high until day 8. Feeding activity of the adult female is maximal on day 1, levels off at 60 per cent up to day 6, and then declines sharply towards the end of pregnancy. Oöcyte development proceeds in phase with larval development and thus minimizes a lag period between successive pregnancies.     

Hormonal regulation of disaggregation of cellular fragments in the haemolymph of Lucilia cuprina

In the haemolymph of newly emerged adult blowfly (Lucilia cuprina) there is a transient change in the number of circulating, filamentous cellular fragments during the first hours after eclosion. Approximately 1 hr after the fly emerges from its puparium there is a rapid rise in the number of fragments from an undetectable quantity to a maximum of 1·3 × 10⁷ fragments per ml 75 min after eclosion. The number of fragments drops to about 5 × 10⁵ fragments per ml 1 hr later.Release of the fragments from their aggregation site can be inhibited by ligaturing flies between head and thorax as they emerge from their puparia. An injection of blood taken from older flies reverses this inhibition. Appreciable fragment disaggregating hormonal activity (FDH) can be detected in the haemolymph 5 min after eclosion.FDH and the tanning hormone, bursicon, could be the same chemical entity. Their release into the haemolymph is synchronous and both are proteins. The two hormonal activities cannot be separated from each other by ammonium sulphate fractionation or sieving through Sephadex G-50.     

The allantoinase of Lathyrus sativus

The presence of a stable allantoinase in Lathyrus sativas and its de novo synthesis at a maximal rate in the first 48 hr of germination have been demonstrated. The plumule and radicle together exhibited highest enzyme activity. L. sativas allantoinase has been purified nearly 35-fold. The purified enzyme was optically active around pH 7.5, did not require any metal ion for activity and exhibited a K_m of 2·56 mM for (±)-allantoin, and an activation energy of 5·6 kcal/mol. Unlike other plant allantoinases, the L. sativus enzyme is highly specific for (±)-allantoin and is shown to be a sulfhydryl enzyme which apparently exists in a stable form in vivo obviating the need for added sulfhydryl compounds for maximal activity.     

Further studies of the effect of L-canavanine on the tobacco hornworm, Manduca sexta.

Fifth instar Manduca sexta growth response to injected doses of canavanine was concentration-dependent over a range of 0·5 to 2·0 mg/g body weight. Twenty-four hr after injection of ¹⁴C-guanidinooxy-d,l-canavanine, M. sexta larvae incorporated approximately 3·6% of the labelled l-canavanine into protein of non-gut tissue. Adult M. sexta mortality was related to the level of injected canavanine over a range of 2 to 8 mg/g body weight. Injection of as little as 2 mg canavanine/g body weight caused hyperactivity in adult M. sexta. Arginine, able to negate the toxic effects of canavanine during larval growth, was only marginally capable of overcoming canavanine effects on larval-pupal ecdysis.     

Cytochalasin B binding to Ehrlich ascites tumor cells and its relationship to glucose carrier

Cultured Ehrlich ascites tumor cells equilibrate d-glucose via a carrier mechanism with a K_m and V of 14 mM and 3 μmol/s per ml cells, respectively. Cytochalasin B competitively inhibits this carrier-mediated glycose transport with an inhibition constant (K_i) of approx. 5·10^?7 M. Cytochalasin E does not inhibit this carrier function. With cytochalasin B concentrations up to 1·10^?5 M, the range where the inhibition develops to practical completion, three discrete cytochalasin B binding sites, namely L, M and H, are distinguished. The cytochalasin B binding at L site shows a dissociation constant (K_d) of approx. 1·10^-6 M, represents about 30% of the total cytochalasin B binding of the cell (8·10⁶ molecules/cell), is sensitively displaced by cytochalasin E but not by d-glucose, and is located in cytosol. The cytochalasin B binding to M site shows a K_d of 4–6·10^?7 M, represents approx. 60% of the total saturable binding (14·10⁶ molecules/cell), is specifically displaced by d-glucose with a displacement constant of 15 mM, but not by l-glucose, and is insensitive to cytochalasin E. The sites are membrane-bound and extractable with Triton X-100 but not by EDTA in alkaline pH. The cytochalasin B binding at H site shows a K_d of 2–6 · 10^?8 M, represents less than 10% of the total sites (2 · 10⁶ molecules/cell), is not affected by either glucose or cytochalasin E and is of non-cytosol origin. It is concluded that the cytochalasin B binding at M site is responsible for the glucose carrier inhibition by cytochalasin B and the Ehrlich ascites cell is unique among other animal cells in its high content of this site. Approx. 16-fold purification of this site has been achieved.     

Hypoxia adaptation in the crayfish procambarus clarki

• 1.1. P. elarki is an oxyconformer, with an oxygen uptake rate of 144 ± 4 μl/g wet wt/hr at oxygen tensions above 90% saturation and an uptake rate of 18 ± 3 μl g wet wt/hr at 15 torr.
• 2.2. Between 159 and 40 tort, blood pH decreases slightly from 7.77 ± 0.03 to 7.65 ± .04, and at 15 torr, blood pH drops to 7.36 ± 0.06.
• 3.3. At normoxia, blood lactate levels are low at 0.66 ± 0.01 mM/l blood. After 2 and 5 hr exposure to 15 tort, blood lactate levels increase to 3.29 ± 0.47 and 8.91 ± 0.14 mM/l blood, respectively. Upon return to normoxia, blood lactate levels decrease and are comparable to normoxic controls after 13 hr.
• 4.4. During mild hypoxia, P. elarki maintains adequate oxygen transport by utilizing a high O₂ affinity hemocyanin in conjunction with a low metabolic demand by its tissues.

     

Activation of vitellogenin synthesis in the mosquito Aedes aegypti by ecdysone

Injected β-ecdysone was found to induce the synthesis of yolk protein (vitellogenin) in adult female Aedes aegypti without a blood meal. After injection of 5 μg ecdysone per mosquito, vitellogenin constituted 80 per cent of the total protein secreted by explanted fat body, a proportion comparable to that produced by fat body from blood-fed females. Moreover, the time course of induction of vitellogenin synthesis in ecdysone-injected mosquitoes was similar to that triggered by a blood meal. Response to ecdysone is dosedependent: 0·5 μg per female was required to stimulate synthesis to 50 per cent of the level found 18 hr after a blood meal. Ecdysone was effective in decapitated or ovariectomized mosquitoes, and also when applied directly to fat body preparations in vitro. Thus it appears that ecdysone acts directly on the fat body to induce specific protein synthesis, as does the vitellogenin stimulating hormone (VSH) from the ovary of blood-fed mosquitoes. These results suggest that ecdysone can replace VSH in inducing vitellogenin synthesis in the unfed mosquito.     

Sphaerophysa kotschyana, an endemic species from Central Anatolia: antioxidant system responses under salt stress

Sphaerophysa kotschyana is a Turkish endemic and endangered plant that grows near Salt Lake, in Konya, Turkey. However, little is known about the ability of this plant to generate/remove reactive oxygen species (ROS) or its adaptive biochemical responses to saline environments. After exposure of S. kotschyana to 0, 150, and 300 mM NaCl for 7 and 14 days, we investigated (1) the activities and isozyme compositions of the antioxidant enzymes superoxide dismutase (SOD), catalase (CAT), peroxidase (POX), ascorbate peroxidase (APX), and glutathione reductase (GR); (2) the oxidative stress parameters NADPH oxidase (NOX) activity, lipid peroxidation (MDA), total ascorbate (tAsA) content, and total glutathione content (tGlut); and (3) ROS levels for superoxide anion radical (O ₂ ^·? ), hydrogen peroxide (H₂O₂), hydroxyl radicals (OH·), and histochemical staining of O ₂ ^·? and H₂O₂. H₂O₂ content increased after 14 days of salt stress, which was consistent with the results from histochemical staining and NOX activity measurements. In contrast, oxidative stress induced by 150 mM NaCl was more efficiently prevented, as indicated by low malondialdehyde (MDA) levels and especially at 7 days, by increased levels of SOD, POX, APX, and GR. However, at 300 mM NaCl, decreased levels of protective enzymes such as SOD, CAT, POX, and GR, particularly with long-term stress (14 days), resulted in limited ROS scavenging activity and increased MDA levels. Moreover, at 300 mM NaCl, the high H₂O₂ content caused oxidative damage rather than inducing protective responses against H₂O₂. These results suggest that S. kotschyana is potentially tolerant to salt-induced damage only at low salt concentrations.     

α-Glucosidase activity in haemolymph of the American cockroach, Periplaneta americana

α-Glucosidase activity of whole haemolymph has been investigated in adult males of the American cockroach, Periplaneta americana. Two electrophoretically distinguishable enzymes capable of hydrolysing α-glucosidic linkages are present in the serum component of the haemolymph, and one of these hydrolyses trehalose. Trehalase activity is also present in haemocytes, and the haemocyte enzyme shares an identical electrophoretic mobility and similar pH sensitivity with the serum trehalase. Furthermore, both enzymes are inhibited to the same extent by sodium ethylene diamine tetracetate (EDTA); thus it is suggested that the same enzyme may be responsible for trehalase activity in the two components. The K_m of EDTA-inhibited trehalase is 3·3 mM and this value is reduced to 1·8 mM upon activation of the enzyme by calcium ions. The properties of the trehalase are discussed in light of the possible rôle of the enzyme in regulating haemolymph trehalose and glucose concentrations.     

Isolation and properties of watermelon isocitrate lyase

The glyoxylate cycle enzyme, isocitrate lyase (EC 4.1.3.1) was purified from cotyledons of Citrullus vulgaris (watermelon). The final preparation, which had been 97-fold purified with a specific activity of 16.1 units/mg protein in a yield of 36%, was homogeneous by gel- and immunoelectrophoretic criteria. The tetrameric enzyme had: a molecular weight of 277 000, a sedimentation coefficient of 12.4 s, and a K_m for D_s-isocitrate equal to 0.25 mM. Isocitrate lyase from this source is not a glycoprotein as shown by total carbohydrate content after precipitation by trichloroacetic acid of the purified enzyme. Reduction of the enzyme with thiols increased activity and maximal activity was obtained with at least 5 mM dithiothreitol. EDTA partially substituted for thiol in freshly isolated enzyme. Watermelon isocitrate lyase was also protected against thermal denaturation at 60° for at least 1 hr by 5 mM Mg²⁺ plus 5 mM oxalate. Oxalate was a competitive inhibitor with respect to isocitrate (K_i: 1.5 μM, pH 7.5, 30°).     

Water exchange and effect of water vapour activity on metabolic rate in the dust mite, Dermatophagoides.

Oxygen consumption by Dermatophagoides farinae was found to vary with temperature and water vapour activity. The relationship between temperature and O₂ consumed/hr per mite was first order. Q₁₀'s were equal to exp (k 10°C) and were found to be 3·04 and 2·49 for 1 to 6 and 6 to 22 hr monitoring periods respectively. A significant difference between O₂ consumed/hr per mite for 1 to 6 and 6 to 22 hr monitoring periods was found. Inactivity of mites explained 29·6 and 31·8 per cent of this reduction. Dehydrating conditions and reduced permeability of the water and gas exchange surface explained a further reduction to 58·7 and 60·8 per cent.     

Stimulation of hydrocarbon biosynthesis by ecdysterone in the flesh fly Sarcophaga bullata.

Ecdysterone has been shown to stimulate hydrocarbon biosynthesis in Sarcophaga bullata at pupariation. When post-feeding larva were treated with ³H-acetate 10·5 hr after hormone administration, a 1·3 times greater quantity of ³H-acetate was incorporated into hydrocarbon in the ecdysterone injected insects than controls. A similar experiment with a 24 hr delay of ³H-acetate administration following hormone treatment resulted in 3·3 times greater incorporation into hydrocarbon of treated animals.Isolated integuments synthesize hydrocarbon from acetate better than internal tissues, and the integuments of ecdysterone-treated insects incorporate acetate into hydrocarbon 9·8 times better than integuments of control insects. This indicates that cuticular hydrocarbon biosynthesis not only occurs in the integument, but that a locus of regulation is present in the integument.     

Photoperiodic time measurement in the aphid Megoura viciae

Megoura produces parthenogenetic virginoparae in long day conditions, gamic oviparae in short days. The nature of this photoperiodic response has been analysed by rearing parent apterae in a wide range of circadian and non-circadian light cycles. By varying the light and dark components independently in a two-component cycle it has been established that the time measuring function is associated primarily with the dark period. There is no evidence that an endogenous circadian oscillation is implicated: thus (a) the ‘short day’ response is abolished by ‘night interruptions’ positioned in the early or late night. But this bimodal response pattern remains unchanged when the duration of the ‘main’ photoperiod is varied from ca. 6 hr to at least 25·5 hr. The stability of the maxima within the scotophase is inconsistent with the ‘coincidence’ models of photoperiodic timing that have been proposed. It is suggested that the essential timing process operates on the hour-glass principle, beginning anew with the onset of each period of darkness; (b) night interruption experiments employing very long (up to 72 hr) scanned dark periods yielded response maxima explicable in terms of the hour-glass hypothesis but did not reveal any circadian relationship between the maxima.The ‘dark reaction’ comprises a sequence of four stages, definable by the effects of light. Stage 1, extending from dark hr 0 to ca. 2·5, is fully photoreversible: at the next dark period the entire timing sequence is repeated up to the 9·5 hr critical night length. Towards the end of stage 1 reversibility is gradually lost and after a light interruption the reaction is resumed from a later time equivalent than dark hr 0; the subsequent critical night length is therefore reduced. The extent of the photoreversal is related to light duration. The period of maximum light insensitivity (stage 2) is attained at the end of the fourth hour. From ca. dark hr 5 to just short of the critical night length light exerts an increasingly promotive action which favours the production of virginoparae. This dark process is not photoreversible. Stage 4, which begins at hr 9·5, marks the end of the timing sequence. Light will not then annul the non-promotive action of the previous long night.Light has three effects which are determined by its duration and position within the cycle. The two terminal effects, mentioned above, are associated with the interception of dark stages 1 and 3 by either short (1 hr) or longer photoperiods. Light also prepares or primes the dark period timer. Thus the critical length is increased, and timing accuracy lost, if the preceding photoperiod is less than ca. 6 hr. Light during stage 4 has a priming action but no terminal function. Repeated cycles are ‘read’ in various ways, depending on the cycle structure. For example, if light intercepts stage 3, a two-component cycle is interpreted as the overlapping sequence light/dark/light. One and the same photoperiod then acts terminally in respect of the preceding dark period and as a primer for the next dark period.There is also a mechanism for summing the promotive effects produced by repeated interruption of dark stage 3. With complex (four-component) cycles both halves of the same cycle may contribute. ‘Product accumulation’ falls below threshold if the frequency of presentation of a given promotive cycle is too low. This occurs if there are very long, relatively non-promotive dark components. Such cycles are accepted as ‘continuous darkness’.     

Synthesis of wall glucan from sucrose by enzyme preparations from Pisum sativum

Radioactive sucrose, supplied through the cut base to Pisum sativum epicotyls, was transported to the growing apex (plumule and hook) and used there for the synthesis mainly of uridine diphosphoglucose (UDP- glucose), fructose and cell wall glucan. Enzyme extracts of the apical tissue contained sucrose synthetase activity which was freely reversible, i.e. formed UDP-glucose and fructose from sucrose (pH optimum = 6·6 for the cleavage reaction, K_m for sucrose = 63 mM). Particulate fractions of the same tissue contained a β-glucan synthetase which utilized UDP-glucose for formation of alkali-soluble and -insoluble products (pH optimum = 8·4, K_m for UDP-glucose = 1·9 mM). Values for V_max and yields of these two synthetase activities were sufficient to account for observed rates of cellulose deposition during epicotyl growth (15–25 μg/hr/epicotyl). When soluble pea enzyme was supplied with sucrose and UDP at pH 6·6 and then the preparation was supplemented with particles bearing β-glucan synthetase at pH 8·4, the glucose moiety of sucrose was converted to glucan in vitro. The results indicate that it is feasible for these synthetases to co-operate in vivo to generate β-glucan for expanding cell walls.     

Silica-free silicone rubber in isolated heart perfusion with blood at 13 °C

Isolated lamb hearts were perfused at 13 °C for 24 hr with whole fresh blood using a silicone rubber circuit and a membrane lung (N = 7); there was formation of thrombi, deposition of fibrin, and an increase in resistance to blood flow in the membrane lung. The perfused hearts fibrillated at hypothermia and showed unequal recovery of function upon final rewarming.There was less rise in membrane lung resistance when the perfusion circuit was primed with blood at 38 instead of 13 °C and then cooled progressively to 13 °C. Some hearts perfused in these circuits were well preserved but others became edematous with loss of ventricular contractility (N = 6).Coating the perfusion circuit with a hypothrombogenic material, silica-free silicone rubber and priming the circuit at 38 °C prevented any rise in membrane lung resistance during blood perfusion. All the hearts perfused in these circuits (N = 6) had the same left ventricular function before and after cold perfusion.Thus isolated hearts can be perfused in vitro with whole blood at hypothermic temperature without loss in function when attention is paid to thrombogenicity of materials used to construct the perfusion circuit.     

Effects of sucrose on blood avidity in mosquitoes.

Within 10 min after engorging on 10% sucrose, most females of Aedes aegypti do not seek a human blood meal, but remain quiescent and unresponsive to a human hand in a 1 ft³ cage. The duration of this inhibition in blood avidity varies greatly among individuals, but may last for 2 to 5 hr after drinking sucrose. There was no specific correlation between abdominal distension and blood avidity. When females engorged on varying concentrations of sucrose, it was found that as the concentration increased, fewer mosquitoes would take blood when it was offered after 1 hr. Only 25% of the females which engorged on 0·5 to 1 M sucrose took human blood at this time. As the concentration of sucrose increases, there is a marked decrease in spontaneous flight activity during the first hour after feeding. When unfed females are injected with 10% sucrose or trehalose, none of them took blood for 3 hr, whereas 50% of the saline-injected controls fed on blood.     

Formation of β-cyanoalanine and pyruvate by Acacia georginae

Pyruvate is formed on incubation of l-cysteine with acetone powder preparations of Acacia georginae but in the presence of cyanide, β-cyanoalanine is produced and pyruvate production is highly depressed. The pH optimum for pyruvate production is 8·5. In the presence of fluoride (1·5 mM), the pH profile is unchanged and in the presence of cyanide (1·5 mM), minimal pyruvate production occurs at pH 8·5. Although addition of pyridoxal phosphate had no influence on pyruvate or β-Cyanoalanine production, these processes were prevented by sodium borohydride, an inhibitor of pyridoxal enzymes. Neither l-serine nor O-acetyl-l-serine serve as alternative substrates for pyruvate production. β-Fluoroalanine was not detected on incubating fluoride with an enzyme preparation from A. georginae acetone powders.