The combined relationship of temperature and molybdenum concentration to nitrogen fixation byAnabaena cylindrica

The joint effects of growth temperature, incubation temperature, and molybdenum concentration on the nitrogen fixation rate ofAnabaena cylindrica were determined using the acetylene-reduction technique. The nitrogen-fixation response to increased molybdenum concentration varied among three growth temperatures (15°, 23°, and 30° C). The pattern of rate change was similar within a growth temperature but increased overall in magnitude with the three incubation temperatures (also 15°, 23°, and 30° C). The maximum rate of nitrogen fixation occurred at 30°C regardless of previous growth temperature. The minimum molybdenum concentration necessary to yield substantial acetylene reduction varied with growth temperature: at 15°C, 15g 1^–1 was effective; at 23°C, less than 5g 1^–1 was effective; and at 30°C, 50g 1^–1 was effective. At all three growth temperatures, increases in molybdenum concentration above the minimum effective concentration produced increases in acetylene reduction. However, at higher molybdenum concentrations inhibition of nitrogen fixation occurred.     

The response of white clover (Trifolium repens L.) seedlings to spring root temperatures: The relative roles of the plant and the Rhizobium bacteria

Three experiments are reported which examine the relative roles of host and Rhizobium genotypes as factors limiting clover (Trifolium repens L.) growth at low soil temperatures.In the first experiment un-nodulated clover and perennial ryegrass (Lolium perenne L.) were grown with non-limiting nitrate at root temperatures of 8, 10 and 12°C. The ryegrass had substantially better relative growth rates (RGR) than the clover with the biggest difference occurring at 8°C. Alterations in growth rate with temperature were more marked in clover than in ryegrass but the latter still produced several times more dry matter than clover at each temperature.In the subsequent experiments clover nodulated with different strains of rhizobia was grown with and without non-limiting additions of nitrate at root temperatures of 9, 12 and 15°C. Plants receiving nitrate generally produced more dry matter than those dependent upon Rhizobium for nitrogen but differences in yield between these treatments did not alter with temperature. This suggests that limitations imposed by nitrogen fixation are similar at both high and low temperatures. Indeed, there was some evidence that nitrogen limitations were rather more pronounced at the highest temperature. The first experiment clearly demonstrated that the clover genotype makes particularly poor use of nitrate at low root temperatures when compared to its common companion perennial ryegrass.It can be concluded that improvements in spring growth of clover will rest largely with alterations to the plant genotype and its ability to use combined nitrogen for growth at lower temperatures rather than with changes in rhizobia or any symbiotic characters.     

Evaluation of host and pathogen responses for screening soil amendments to control Sclerotium rolfsii

Three strains of Bradyrhizobium, 280A, 2209A and 32H1, that nodulated peanuts (Arachis hypogaea L.), were tested for their ability to grow and survive at elevated temperatures of up to 42°C in laboratory culture. Strain 32H1 was unable to grow at 37°C and was more sensitive to elevated temperatures than the other two strains. All three produced heat-shock proteins of molecular weights 17 kDa and 18 kDa. Two greenhouse experiments were conducted to determine the effect of high root temperature on nodulation, growth and nitrogen fixation of peanut. Two peanut varieties (Virginia cv NC7 and Spanish cv Pronto) were inoculated and exposed to root temperatures of 30°, 37° and 40°C. Nodulation and nitrogen fixation were strongly affected by root temperature but there was no variety × temperature interaction. At a constant 40°C root temperature no nodules were formed. Nodules were formed when roots were exposed to this temperature with diurnal cycling but no nitrogen fixation occurred. Highest plant dry weight, shoot nitrogen content and total nitrogen were observed at a constant root temperature of 30°C. Increasing root temperature to 37°C reduced average nitrogen content by 37% and total nitrogen by 49% but did not reduce nodulation. The symbiotic performance of the strains corresponded to their abilities to grow and survive at high temperature in culture.     

Effect of Elevated Temperature on Nitrite and Nitrate Reduction in Leaves and Intact Chloroplasts

Barley (Hordeum vulgare L.) leaves and intact spinach (Spinacia oleracea L.) chloroplasts were exposed to short-term heating, and the aftereffects of heat treatment on in vitro andin vivo activities of nitrate reductase and noncyclic electron transport associated with nitrite reduction were studied. Heating of leaves at temperatures above 40°C led to a monotonic decrease in nitrate reductase in vitro activity. On the contrary, the in vivo enzyme activity, assayed in intact leaf tissues after 5-min heat treatment, increased 1.5 times upon elevating the pretreatment temperature from 37 to 40°C and gradually decreased at higher temperatures. Noncyclic electron transport related to CO₂ fixation in intact chloroplasts decreased gradually after heat exposures above 39°C, unlike the electron transport to nitrite as a terminal acceptor, which was stimulated by heating of intact chloroplast suspensions in the temperature range from 33 to 40°C. The heating at higher temperatures inhibited nitrite photoreduction. It is concluded that the heating of phototrophic cells at sublethal temperatures stimulates the mobilization of inorganic nitrogen and thereby facilitates the repair of thermally induced injuries of proteinaceous cell structures. The stimulation of nitrate reductase activity in vivo at the temperature range 37–40°C provides an evidence for the increase in the availability of reductants in the cytosolic compartment of the leaf cell.     

Nitrogen excretion in Streptocephalus Dichotomus Baird (Crustacea: Anostraca)

Summary The total nitrogen excreted by Streptocephalus dichotomus is 1.5177 mg/g/day for males and 1.3875 mg/g/day for females at 30°C.The main excretory product of S. dichotomus is ammonia (75.3%). The rate of excretion of ammonia increased with increase in temperature up to 30°C and at 33°C it decreased.Analyses of covariance revealed that the F ratios are not significant in the case of rate of total nitrogen excretion between the two sexes at 30°C and in the case of rate of ammonia excretion between the two sexes or when comparison is made within the sexes at the different temperatures between 20° and 30°C.This work formed part of the thesis submitted to the University of Madras for the award of the Degree of Doctor of Philosophy in 1970.     

The effect of high temperature and fallow period on infection of mung bean and cashew roots by the vesicular-arbuscular mycorrhizal fungus Glomus intraradices

The experiments described were designed to investigate the way in which high temperatures (30°C and above) affected the survival and infectivity of spores of Glomus intraradices formulated as the commercial inoculum NutriLink^TM. Infection of mung bean (Vigna radiata) occurred most rapidly at 30°C compared with either 22° or 38°C, although the final percentage of the root length infected (6 weeks) was similar at all three temperatures. Early rapid infection led to greater plant growth of this species at 30°. In cashew (Anacardium occidentale) no infection occurred at 38°C and this was associated with low plant growth, compared with the other temperatures at which infection reached 40–60% after 4 months. In both species differences in root temperature were associated with marked differences in the morphology and growth of the root systems, with poor root growth at 38°C. Spores of G. intraradices retained infectivity with respect to mung bean for up to 6 weeks in moist fallow soil, although maximum infectivity was observed in soil without a fallow period. The effects of temperature on germination of spores buried in filter paper sandwiches in soil were consistent with the data for infection and growth. Germination was most rapid and reached the highest percentage at 3 weeks at 30°C. Lowest germination was attained at 38°C. We conclude that G. intraradices can retain its infectivity in moist soil at high temperatures, but that the extent to which the plants become infected and hence their response, depends not only on this but also on host factors such as root growth.     

Ecophysiological studies on Spirulina platensis Effect of temperature,light intensity and nitrate concentration on growth and ultrastructure

The ultrastructure of the cyanobacterium Spirulina platensis was studied in relation to temperature, light intensity and nitrate concentration. The organism was able to grow in media supplied with nitrate in concentrations up to 250mm. High nitrate concentrations increased the yield and growth rate at temperatures above 35°C. Occurrence, distribution and abundance of cyanophycin granules, polyglucan granules, cylindrical bodies, carboxysomes and mesosomes varied widely in relation to the factors studied. At low temperatures (up to 17°C) cyanophycin was the abundant organelle, especially at high nitrate concentrations, whereas in the temperature range 17–20°C polyglucan was found in large quantities particularly at low nitrate concentrations. Special attention was paid to the cylindrical bodies, the ultrastructure of which was dependent on temperature. Three types of ultrastructure were distinguished each with several possible shapes.     

Temperature-sensitive photosynthesis-deficient mutants of the cyanobacteriumAnabœna variabilis impaired in nitrogen assimilation

Temperature-sensitive (Ts) mutants ofAnabœna variabilis exhibited differences in the rates of oxygen evolution at 28 and 40°C. They were unable to perform photosynthesis and nitrogen fixation at 40°C beyond a period of 3 d in a nitrogen-deficient medium. However, the addition of combined nitrogen sources enhanced the growth of all the Ts mutants at both temperatures. Studies on nitrate uptake ty Ts mutants revealed the existence of a low affinity system, whereK _m values were found to be lower than 1 mmol/L. The activity of nitrate reductase gradually increased with time at 28°C with the exception of Ts-161 where the activity decreased with time at 40°C. The rate of ammonia uptake byA. variabilis and its Ts mutants greatly differed and the results suggest the existence of a single phase of uptake. The activity of glutamate-ammonia ligase (GAL) of the parent and Ts mutants was slightly higher in cells from nitrogen-deficient medium when compared to nitrate grown cells at 28°C. At 40°C, the GAL activity decreased after 3 d. The inability of the Ts mutants to grow at 40°C appears to be due to an impairment in nitrogen asimilation.     

In vitro and in situ studies on nitrate disappearance in water-sediment systems of the Camargue (southern France)

Results of in vitro and in situ experiments on nitrate disappearance from water-sediment systems in the Camargue are described.In the in vitro experiments two factors were studied: temperature and organic matter. After a first addition of KNO₃ to these sediments, the concentration of organic matter exerted a strong influence on the disappearance rate of nitrate at 25 °C and 15 °C but not at 2 °C. After a second addition of nitrate at 25 °C and 15 °C the denitrification rate increased by approximately 10%, probably because the activity of the bacterial population had increased.Experiments in situ in freshwater temporary marshes showed that nitrate disappeared at approximately twice the rate at similar temperature in vitro.After the first addition of nitrate in the in vitro experiments the concentration of nitrite in the water above the sediment reached about 10% of the concentration of total dissolved inorganic nitrogen at 2 °C and 15 °C. These high concentrations were not found after the first addition at 25 °C or after the second addition of nitrate at 25 °C and 15 °C. In the in situ experiments, however, high concentrations of nitrite were found.     

Growth regulation in Neurospora crassa effects of nutrients and of temperature

Summary Mycelia of Neurospora crassa growing with quite different rates at a given temperature (30°C) are obtained by changing the composition of the culture medium: for instance a duplication time of 220 min is found when cultures are growing in Vogel's minimal medium supplemented with glycerol and one of 80 min when cultures are growing in Vogel's minimal medium supplemented with sucrose and casein hydrolysate. The kinetics of shifth-down and shift-up transitions of growth between culture conditions supporting different rates of growth are described. Temperatures above 40°C and below 20°C severely restrict growth in Vogel's minimal medium supplemented with sucrose. The Arrhenius plot of the constant of the rate of growth suggests that an inactivation process occurs at low temperatures: the molecular basis for such a process is discussed.Abbreviations used A₄₅₀ absorbance at 450 mm     

Nitrate reductase and glutamine synthetase activities,nitrate and ammonia assimilation,in the unicellular alga Cyanidium caldarium

Nitrogen-limited continuous cultures of Cyanidium caldarium contained induced levels of glutamine synthetase and nitrate reductase when either nitrate or ammonia was the sole nitrogen source. Nitrate reductase occurred in a catalytically active form. In the presence of excess ammonia, glutamine synthetase and nitrate reductase were repressed, the latter enzyme completely. In the presence of excess nitrate, intermediate levels of glutamine synthetase activity occurred. Nitrate reductase was derepressed but occurred up to 60% in a catalytically inactive form.Cell suspensions of C. caldarium from nitrate- or ammonialimited cultures assimilated either ammonia or nitrate immediately when provided with these nutrients. In these types of cells, as well as in cells grown with excess nitrate, the rate of ammonia assimilation was 2.5-fold higher than the rate of nitrate assimilation. It is proposed that the reduced rate at which nitrate was assimilated as compared to ammonia might be due to regulatory mechanisms which operate at the level of nitrate reductase activity.     

Microhabitat segregation and physiological differences in co-occurring tiger beetle species,Cicindela oregona and Cicindela tranquebarica

Summary The daily movements of two co-occurring tiger beetle species were monitored in conjunction with changes in microclimate along streams in Northeast Arizona. Cicindela oregona and C. tranquebarica temporarily segregated across areas of beach exhibiting different microclimates. C. oregona progressively moved from the dry upper beach to the wet stream edge as beach temperatures increased and humidity decreased. The actively foraged throughout the day in this moist habitat at air temperatures between 25 and 38°C. C. tranquebarica remained on the dry, upper portions of the beach and shuttled between sun and shade at air temperatures above 35°C. Only when stream edge temperatures exceeded 30°C was tranquebarica found in this subhabitat. Both species exhibited physiological tolerances in the laboratory that were consistent with their microhabitat preferences in the field. Although both species had similar high lethal temperatures (47–48°C) in saturated air, oregona died at lower temperatures (39–43°C) than tranquebarica (46–47°C) under dry (0% RH) conditions. C. oregona was considerably more active than tranquebarica at body temperatures below 30°C and exhibited higher levels of active metabolism between 25 and 40°C. In addition, C. tranquebarica exhibited significantly lower water loss rates than oregona at 30, 35 and 40°C.     

Upper temperature limits for growth and diazotrophy in the thermophilic cyanobacterium HTF Chlorogloeopsis

The effect of temperature and oxygen on diazotrophic growth of the thermophilic cyanobacterium HTF (High Temperature Form) Chlorogloeopsis was investigated using cells grown in light-limited continuous culture at a dilution rate of 0.02 h^-1. Diazotrophy was more sensitive to elevated temperatures than growth with combined nitrogen. The maximum temperature for growth of cultures gassed with CO₂-enriched air was more than 55 °C but less than 60 °C with N₂ as the sole nitrogen source, but between 60°C and 65°C when nitrate was present in the medium. The effect of temperature on nitrogenase activity, photosynthesis and respiration in the dark was determined using cells grown at 55°C. Maximal rates of all three processes were observed at 55°C and rates at 60°C during shortterm incubations were not less than 75% of the maximum. However, nitrogenase activity at 60°C was unstable and decayed at a rate of 2.2 h^-1 under air and at 0.3 h^-1 under argon. Photosynthesis and respiration were more stable at 60°C than anoxic nitrogen fixation. The upper temperature limits for diazotrophic growth thus seem to be set by the stability of nitrogenase.Abbreviations chl chlorophyll a - DCMU N-(3,4-dichlorophenyl) N,N-dimethylurea - Taps N-tris(hydroxymethyl)methyl-3-aminopropanesulfonic acid     

Effects of thermal regime on energy and nitrogen budgets of an early juvenile Arctic charr, Salvelinus alpinus, from Lake Inari

The feed intake, growth, oxygen consumption and ammonia excretion of juvenile Arctic charr were measured over period of four weeks at different temperatures which were either constant (11.0, 14.4, 17.7 °C) or fluctuated daily (14.3 ± 1 °C). Maximum feed intake was estimated to occur at 14.3 °C, while oxygen consumption and nitrogen excretion were highest at the highest temperature, and growth rate was estimated to be highest at 13.9 °C. Feed conversion efficiency was estimated to be highest at 13.2 °C, where over 62.7% of ingested energy was allocated to growth. Metabolic rate accounted for 16–30% of ingested energy and nitrogen excretion was under 3% of ingested energy. The nitrogen budget was under similar thermal influences to the energy budget. Thermal fluctuation increased metabolic rate, but not feed intake, leading to a reduction in feed conversion efficiency under fluctuating temperature conditions.     

Effect of temperature variations on growth,reproduction, amino acid synthesis,fat and sugar content in ulva fasciata delile plants

This work deals with the effect of temperature variations on growth, reproduction, amino acid synthesis, fat and sugar content in Ulva fasciata in habiting the littoral region of the Mediterranean shore bordering Alexandria.Higher temperatures above 30°C have lethal effects on some parts of the algal fronds while the other parts are rather resistant. The latter are scattered groups of cells, which usually regenerate new plants when carried even to distant parts due to detrimental action of waves and currents. They serve a good means for vegetative propagation and spread better than zooids, which probably perish under such severe and violent conditions.The rate of growth of Ulva indicated by the increase in dry weight and total nitrogen, increases at rising temperature till the latter becomes limiting.Higher temperatures favour the growth and development of sporophytic phases, known by their deep green colouration, while temperatures below 20°C favour the production of gametophytes, identified by their yellowish green colour. This might explain why most of the algal crops of Ulva fasciata produced from parental stock (3 crops per year i.e. annually), are sporophytes.Moderate temperatures were favourable for growth, reproduction and the various metabolic processes. Amino acids and sugar contents increase with the rise of temperature, reaching their maximum around 25°C, while fat content increases at still lower temperatures.     

Nutritional requirements of keratinophilic fungi and dermatophytes for conidial germination

Germination of spores of Chrysosporium crassitunicatum, Nannizzia fulva (+), Nannizzia fulva (–) and Trichophyton equinum was studied in the presence of various carbon and nitrogen sources. Effect of different temperatures on spore germination was also determined. Maximum spore germination within 24 hours was recorded when glucose was used as a carbon source for all the test fungi. Except sodium nitrate all the inorganic nitrogen sources enhanced the spore germination at 0.05% concentration. Most of the organic nitrogen sources used were found to be stimulatory for the spore germination of test fungi. Optimum temperature i.e. 28 °C supported maximum spore germination of all the test fungi within 24 hours. C. Crassitunicatum, N. fulva(+), N. fulva(–) could germinate upto 35 °C but beyond that no spore germination was noticed in these fungi. T. equinum could germinate at a higher temperature of 40 °C but the percentage of germination was very low.     

Studies on Aspergilli XVI. Effect of pH,temperature, and carbon and nitrogen interaction

Summary The effect of pH, temperature, and carbon and nitrogen interaction on the growth and sporulation ofAspergillus nidulans (Eidam)Wint.,A. rugulosus Thom &Raper,A. variecolor (Berk. &Br.)Thom &Raper andA. quadrilineatus was studied. All the moulds could grow on a wide range of pH (2.0 to 12.0) but the growth was poor on too acid and too alkaline media. Best growth ofA. rugulosus, A. quadrilineatus, andA. violaceus was seen at pH 6.5 and that ofA. nidulans andA. variecolor at pH 7.0. In general maximum production of perithecia was recorded between pH 6.0 and 8.0.All the above species ofAspergillus under study could grow between a temperature range of 10° C–48° C, but the growth was poor at 10° C and 48° C. The present moulds showed good growth at 20° C, 25°C, and 30° C. At 40° CA. nidulans andA. rugulosus showed moderate growth while the rest of the Aspergilli attained good growth. Temperatures between 20° C–30° C favoured excellent perithecial production.In general, little improvement in growth was noted on media containing good carbon and nitrogen sources. Malic acid was found to be useless when supplied singly. But, poor growth was recorded when supplied in combination with amino acids, amide, and peptone. This was due to the fact that these N sources also supplied carbon for their metabolism.     

Effect of temperature on vegetative growth among isolates of Metarhizium anisopliae and M. flavoviride

Effects of temperature on vegetative growth on a semi-synthetic medium of 22 isolates of Metarhizium anisopliae and 14 isolates of M. flavoviride were determined. The majority of isolates of both species grew between 11 and 32°C; several isolates grew at 8 and 37 °C. None of the isolates grew at 40 °C. Relative growth rate, calculated from the maximum growth rate for each isolate, was significantly affected by temperature and isolate, with significant isolate * temperature interactions. The maximum absolute growth rates among the isolates ranged from 2.5 mm to 5.9 mm/day. Optimal temperatures were generally between 25 and 32 °C with several isolates exhibiting optimal growth at temperatures as high as 32 °C. Overall, relative growth rates were greater in isolates of M. anisopliae than M. flavoviride at temperatures of 25 °C or lower; conversely mean relative growth rates were greater in M. flavoviride than M. anisopliae at temperatures higher than 25 °C. However, the two most cold tolerant isolates at 8 °C were M. flavoviride and the three most heat tolerant at 35 °C were M. anisopliae. Since temperature growth responses varied considerably between isolates, strain selection according to thermal tolerance may be warranted when choosing a strain for development as a microbial control agent.This revised version was published online in October 2005 with corrections to the Cover Date.     

Production of extracellular inulinase in high-cell-density fed-batch cultures of Kluyveromyces marxianus

The production of extracellular inulinase (\-1,2-d-fructan fructanohydrolase, EC 3.2.1.7) was studied in fed-batch cultures of the yeast Kluyveromyces marxianus CBS 6556 at 30 and at 40° C. At both temperatures, the final biomass concentration exceeded 100 g·l^–1 and more than 2 g enzyme. L^–1 of culture supernatant was produced. The biomass yield on O₂ at 40° C was substantially lower than at 30°C. Nevertheless, at 40° C a growth rate of 0.20 h^–1 could be maintained for a longer period than at 30° C. The unexpected higher O₂-transfer rate at 40°C is probably due to a lower viscosity of the culture broth. The 40°C fermentation took only 33 h as compared to 42 h at 30° C. These results indicate that K. marxianus is a promising host for the extracellular production of heterologous proteins under the control of the inulinase promoter.     

Effects of incubation temperature on growth and development of embryos ofAlligator mississippiensis

Summary Eggs ofAlligator mississippiensis were incubated at 30 °C and 33 °C throughout incubation up to hatching. Every four days several eggs were opened and the albumen, yolk and extra-embryonic fluids removed and weighed. The embryo was removed and fixed prior to being staged, weighted and measured for various morphometric criteria. Development at 33 °C was accelerated compared with 30 °C in terms of yolk and albumen utilization and embryo growth. Significant losses in yolk mass did not occur until stage 22 at 33 °C but occurred at stage 18 at 30 °C. Different patterns in growth were observed in embryos at the two temperatures at similar morphological stages: between stages 18 and 22 embryos at 33 °C were smaller (in mass and length) compared with embryos at 30 °C despite being morphologically similar. The differences in growth and physiology between embryos at 30 °C (females) and 33 °C (males) were dependent on incubation temperature but not sex. Incubation at 33 °C accelerated both growth and development inAlligator; initially morphogenesis was accelerated by the higher temperature but later, growth rate was accelerated.