Brain function in antarctic fish: Activity of central vestibular neurons in relation to head rotation and eye movement

Summary Recordings were made from central vestibular neurons responding to horizontal head rotation in antarctic fish,Pagothenia borchgrevinki, at a temperature close to 0 °C. The spontaneous activity of these units varied between 0 and 56 Imp/s with a mean value of 20. Almost all units responded to horizontal rotation with a maximum firing rate that was approximately in phase with head velocity, either towards the recording side (type I units) or away from the recording side (type II), with no alteration of firing pattern during saccadic eye movements. The mean gain of these units was 2.6 Imp/s//s at 0.35 Hz which is higher than that reported for central vestibular neurons in other fish.     

Temperature compensation in myotomal muscle: Antarctic versus temperate fish

Synopsis Contraction time of an isolated white muscle from the temperate water Girella tricuspidata is proportional to temperature and inversely proportional to fish size. Between ambient (14°C) and 8° C muscle from all sizes of fish is similary affected by temperature; the lower the temperature the more the contraction time is slowed. Below 8° C muscle from large fish is affected more than is muscle from small fish. Contraction time of white muscle in the antarctic notothenioid Pagothenia borchgrevinki is about twice as fast as that of Girella tricuspidata at temperatures between 2–12°C, but at normal body temperature, contraction time of muscle from Girella tricuspidata (14°C) is about twice as fast as that of Pagothenia borchgrevinki (–1.9°C).     

Effect of preoptic lesions on behavioral thermoregulation of green sunfish,Lepomis cyanellus,and of goldfish,Carassius auratus

Summary Sunfish (Lepomis cyanellus) and goldfish (Carassius auratus) acclimated to 5°, 15° and 25 °C were placed individually in a horizontal temperature gradient from 2° to 30 °C where the fish could swim freely. They spent large proportions of time (70%) at temperatures near their acclimation temperature and avoided the extremes. By behavioral selection, internal body temperature was maintained relatively constant. After bilateral medial and lateral preoptic lesions, fish spent random amounts of time at all temperatures available in the gradient and did not maintain a stable body temperature.Support from grants NSF PCM 76-15861 and HEW PHS GM 7143 is acknowledged.     

Effect of temperature on rate of photosynthesis in Antarctic phytoplankton

Summary The rate of photosynthesis of marine antarctic phytoplankton (western Scotia Sea and Bransfield Strait) was determined as a function of temperature, from ambient (-0.8°C to 1.0°C) to 28°C. Photosynthetic rates, based on radiocarbon incorporation during half-day incubations, were increased by as much as 2x with temperatures up to 7°C; at higher temperatures the rates decreased rapidly, so that at 28°C the rates were only 3% of that at ambient temperatures. In antarctic surface waters during the austral summer the rate of photosynthesis by phytoplankton thus is limited by thermodynamic effects on metabolic reactions, in spite of high nutrient concentrations and saturating light levels. The observed rates were in agreement with thermodynamic models of the dependence of phytoplankton growth rate on temperature.     

Qualitative assessment of hydrolytic activities in antarctic microfungi grown at different temperatures on solid media

Microfungi from Antarctica were grown at 10 °C, 21 °C, 28 °C and 37 °C on a series of plates each containing a single carbon source and designed to indicate the secretion of particular hydrolytic enzymes. Colony radius and hydrolytic activity were measured and a relative activity index (RA) established. In general, effective hydrolysis occurred at mesophilic temperatures. Some enzymes, especially of Trichoderma spp. and Penicillium spp. showed maximum activity at 10 °C, indicating adaptation to the colder temperatures of the antarctic environment.     

Changes in gill morphology of Oreochromis mossambicus subjected to heat stress

Synopsis The cichlid fish, Oreochromis mossambicus, was acclimated to 25°C for a 14 day period and then subjected to elevated temperatures of 30, 35, 40 and 45° C. Gill epithelia was progressively damaged from 30–40° C; gills from fish tested at 45°C showed less damage than those tested at 40°C. This is presumably due to the shorter exposure (survival) time at 45°C. Shrinkage of the secondary lamellae and the collapse of pillar cells supports the hypothesis that hypoxia at elevated temperatures is partially a function of changes in gill morphology.     

Adaptability of carp neutrophilic granulocytes to environmental temperatures: spontaneous cytotoxic activity and cell-adherent activity

This study observed the adaptability of carp neutrophilic granulocytes possessing spontaneous cytotoxic activity to different environmental temperatures. To study the adaptability of neutrophilic granulocytes, two different temperatures (25° C and 10° C) were selected, both for rearing and forin vitroassays, in which the cytotoxicity and the adherent rate against K562 target cells were measured. The cytotoxicity and adherent rate of neutrophilic granulocytes from carp kept at 25° C for 30 days were higher when assayed at 25° C than when assayed at 10° C. On the other hand, in carp acclimated from 25° C to 10° C, the cytotoxicities and adherent rates, when assayed at 25° C, decreased with increasing acclimation times, eventually becoming smaller than the values obtained when assayed at 10° C. After the fish kept at 10° C for a long period were re-acclimated to 25° C, these activities assayed at 25° C again became higher than the activities assayed at 10° C. These results indicated that carp neutrophilic granulocytes adapt their cytotoxic activity and adherent activity to different environmental temperatures. A change in cellular composition in the head kidney was also observed in carp kept at different environmental temperatures. The percentage of neutrophilic granulocytes became higher and lymphocytes became lower in carp that were kept at 10° C for a long period compared with carp that were kept at 25° C for a long period.     

Use of a minifluviarium to study responses of young Sarotherodon niloticus (L) to hydrogen-ion concentrations and temperature

The reactions of O+ Sarotherodon niloticus (L) to varying pH and temperature were studied in the laboratory using a minifluviarium. S. niloticus was found to tolerate pH — values as low as 5.0 without any marked effect. At values between 3.0 and 5.0 the fish lost orientation and showed signs of hyperactivity. Below 3.0, they died shortly after removal from the test — yard.Thermal behavior was tested for values ranging between 30° and 43 °C. Young S. niloticus were observed to prefer temperatures between 30° and 36 °C and avoid higher temperatures. Temperatures above 41 °C were lethal. Larger fish (6.0 to 8.0 cm.) showed more tolerance to increasing temperatures, however, when pH was considered, there was no significant difference between the sizes studied (P > 0.05).     

Thermal stability of myosin rod from various species

The radius of gyration and fraction helix as a function of temperature have been determined for myosin rod from four different species: rabbit, frog, scallop, and antarctic fish. Measurements from sodium dodecyl sulfate gel electrophoresis indicate that all particles have the same molecular weight (approximately 130K). All fragments are nearly 100% alpha-helical at low temperatures (0-5 degrees C). The melting profiles for each are qualitatively similar in shape, but their midpoints are shifted along the temperature axis in the following order: antarctic fish (Tm = 33 degrees C), scallop (Tm = 39 degrees C), frog (Tm = 45 degrees C), and rabbit (Tm = 49 degrees C). Corresponding radius of gyration vs temperature profiles for each species are shifted to lower temperatures (approximately 5-8 degrees C) with respect to the optical rotation melting curves. From plots of radius of gyration vs fraction helix, we find a marked drop in the radius of gyration (from 43 to approximately 34 nm) with less than a 5% decrease in fraction helix for rabbit, frog, and antarctic fish rods, whereas the radius of gyration of scallop rod never exceeds 34 nm. Results indicate hinging of the myosin rod of each species. The thermal stabilities of the myosin rods shift in parallel with the working temperature of their respective muscles.     

Temperature preferences and tolerances of three fish species inhabiting hyperthermal ponds on mangrove islands

The fish species Cyprinidon artifrons, Floridichthys carpio, and Gambusia yucatana inhabit shallow mangrove ponds off the coast of Belize. Portions of these ponds experience a diurnal temperature change from 26 °C at night to 40 °C and above during midday. Repeated field observations indicate Cyprinidon prefer the warmer (and much larger) portions of the ponds whereas the other two species stay in the cooler areas.The hypothesis that temperature is serving as a cue for partitioning within the ponds was supported by laboratory thermal gradient tests in which Cyprinidon preferred temperatures clearly higher than the other two species.The critical thermal maximum (CTM) was determined for the three species using members that had been acclimated to either a daily cycling temperature similar to that for the ponds, or to the mean of the 24-hour cycle (30 °C). Cyprinidon acclimated to the cycling temperature had a CTM of 45.5 °C, which apparently sets a new record for fish CTM. Acclimation to a constant 30 °C lowered the CTM to 43.7 °C. Floridichthys and Gambusia acclimated to the cycled temperature had CTMs of 43.9 and 43.3 °C respectively, and 42.5 and 42.6 °C for those acclimated to 30 °C.All three species appear to have the ability to tolerate the high temperatures throughout the ponds but only Cyprinidon utilize the whole pond during the day. This may help to explain the large populations of Cyprinodon found in these mangrove ponds compared to the other species.     

The heat shock response of an antarctic alga is evident at 5°C

A subtidal seaweed collected in antarctic waters, Plocamium cartilagineum (L. Dix.), displayed induction of mRNAs encoding the 70 kDa heat shock protein (HSP70) and the ubiquitin polyprotein (UBI) when incubated at 5°C. Maximal induction of HSP70 mRNA was observed when the alga was incubated at 10°C for 1 h. Incubations at higher temperatures or for longer periods reduced the amount of HSP70 mRNA detected. Incubations at 20°C or greater resulted in cell death. These data indicate that dispite the unusually low temperature of induction, this macrophyte exhibits a heat shock response similar to that of other organisms at temperatures 5 to 10°C above usual growth conditions.     

Temperature influence on cohort parameters and demographic characteristics of the two cowpea coreids Clavigralla tomentosicollis and C. shadabi

Age-specific life tables of two important pests of cowpea, Vigna unguiculata (L.) Walp., the pod sucking bugs Clavigralla tomentosicollis Stål and C. shadabi Dolling (Heteroptera: Coreidae), were obtained from observations carried out at different temperatures. A biophysical model was found satisfactory to describe the temperature-response of developmental and mortality rates of egg and nymphal stages, with a peak developmental rate around 34°C in both species. The variability in development times was small and the experimental data did not permit any conclusion with regard to the Erlang probability density function. Survival of eggs and nymphs remained high between 20° and 30°C for both species. At temperatures above 34°C, C. tomentosicollis survivorship and fecundity was higher than that of C. shadabi, which in turn laid more eggs at temperatures between 20° and 30°C. Maximum fecundity is estimated to be at 29°C for C. tomentosicollis (99 eggs/female) and 26°C for C. shadabi (261 eggs/female). At 30°C, the intrinsic rate of increase reached a maximum in both species, 0.152 per day for C. tomentosicollis and 0.145 per day for C. shadabi, and remained high for C. tomentosicollis until 36°C. C. tomentosicollis performed significantly better on pigeonpea, Cajanus cajan Millsp., than on cowpea at higher temperatures.     

Effect of Calcium and Zinc on the Activity and Thermostability of Superoxide Dismutase

The effect of calcium and zinc ions on superoxide dismutase (SOD) from four plant species (Taxus baccata, Pinus sylvestris, Medicago rigidula, and Zea mays) was followed at three temperatures: optimal (20 °C), increased (50 °C), and high, inhibiting temperature (70 – 80 °C). At 20 and 50 °C in vitro added calcium increases SOD activity, but the degree was different for the plants investigated. The effect of zinc ions at the same temperatures varied in the investigated plants from activation to inhibition. An inhibiting effect of high temperature on SOD activity was diminished in the presence of calcium or zinc ions. It was shown that calcium and zinc ions can increase activity and thermostabilize different SOD isoforms.     

Characterization of proteases produced by newly isolated and identified proteolytic microorganisms from fermented fish (Budu)

Eight different strains ofBacillus were isolated from fermented fish (Budu) and their proteolytic enzyme activities were determined after 18 h cultivation at room temperature (35° C). Four isolates possessed high protease activities. Optimum pH for these enzymes was between 7.0 and 8.0 and the optimal temperature was 55° C. The proteases retained 40% of their original activity after 20 min at 55° C but lost all activity at 65° C. Three of the four isolates were identified asBacillus subtilis, the fourth asBacillus licheniformis.     

Neurochemical Changes in Cerebellum of Goldfish Exposed to Various Temperatures

Acclimation of goldfish at 35°C increased the cerebellar content of aspartate, glutamate, and taurine and [³H]glutamate uptake. Acclimation at 4°C increased the levels of glutamine, serine, and alanine and glutamine synthetase (GS) activity. Adenosine content increased in cerebellum of fish acclimated to warm temperature. K⁺-evoked release of endogenous and exogenous glutamate from cerebellar slices increased in fish acclimated at 35°C compared to 4°C. The basal level of cyclic adenosine 3:5-monophosphate (cAMP) in perfused cerebellar slices in fish acclimated at 35°C was much higher than in fish acclimated at 5° and 22°C. It is concluded that variations of environmental temperature produces large neurochemical changes in goldfish cerebellum.     

The growth of Epidermophyton floccosum and E. stockdaleae at different temperatures

The ability of 17 strains of genus Epidermophyton (15 strains belonging to Epidermophyton floccosum, one to E. floccosum var. nigricans and one to E. stockdaleae) to grow at different temperatures (4 °C, 25 °C, 28 °C, 31 °C, 34 °C, 37 °C and 40 °C) was stated.The strains were inoculated on Sabouraud Dextrose Agar and regularly controled over a period of 14 days when the plates were incubated at 25 °C, 28 °C, 31 °C, 34 °C, 37 °C and 40 °C, and over a period of 70 days when the temperature was 4 °C. The optimal growth of E. floccosum was observed at 28 °C and 31 °C, and no signs of growth were recorded neither at 4 °C nor at 40 °C. The optimal development of E. stockdaleae was observed at 25 °C and 28 °C. This species grew from 4 °C to 31 °C.     

Sensory processing in the vestibular nuclei during active head movements

Many secondary vestibular neurons are sensitive to head on trunk rotation during reflex-induced and voluntary head movements. During passive whole body rotation the interaction of head on trunk signals related to the vestibulo-collic reflex with vestibular signals increases the rotational gain of many secondary vestibular neurons, including many that project to the spinal cord. In some units, the sensitivity to head on trunk and vestibular input is matched and the resulting interaction produces an output that is related to the trunk velocity in space. In other units the head on trunk inputs are stronger and the resulting interaction produces an output that is larger during the reflex. During voluntary head movements, inputs related to head on trunk movement combine destructively with vestibular signals, and often cancel the sensory reafferent consequences of self-generated movements. Cancellation of sensory vestibular signals was observed in all of the antidromically identified secondary vestibulospinal units, even though many of these units were not significantly affected by reflexive head on trunk movements. The results imply that the inputs to vestibular neurons related to head on trunk rotation during reflexive and voluntary movements arise from different sources. We suggest that the relative strength of reflexive head on trunk input to different vestibular neurons might reflect the different functional roles they have in controlling the posture of the neck and body.     

Developmental rates of heterozygous and homozygous rainbow trout reared at three temperatures

The hatching distributions of rainbow trout (Salmo gairdneri) with different genotypes at eight loci are compared in two experiments with the same strain. Embryos were incubated at temperatures colder (5 and 8°C) and warmer (12°C) than normally experienced by these fish (9.5°C). At hatching, embryos were separated into five hatching groups representing the chronological order of hatching. There is no significant correlation between multilocus heterozygosity and hatching time at any temperature in either experiment. Fish in the middle of the hatching distribution had the highest average heterozygosity. In both experiments, heterozygotes at the majority of loci examined tended to hatch relatively later within the hatching distribution at 12°C than at both 5 and 8°C. Fish with different genotypes atPgm2 andCk1 showed significant differences in hatching time that were consistent between experiments.Ck1 heterozygotes hatched sooner than homozygotes at 8°C but later at 12°C.Pgm2 heterozygotes hatched later than homozygotes at all temperatures and significantly later in four of five cases. At the other loci examined, however, the relative hatching distributions of fish with particular genotypes were not significantly different or repeatable between experiments.This research was supported by National Science Foundation Grant BSR-8300039 awarded to Dr. Fred W. Allendorf. Moira M. Ferguson was supported by a postgraduate scholarship from the Natural Sciences and Engineering Research Council of Canada.     

Growth, survival, and starvation resistance of Colorado squawfish larvae

Synopsis Growth and survival of Colorado squawfish, Ptychocheilus lucius, larvae under fluctuating 18, 22, and 26° C (5° C diel fluctuations) and constant 18, 22, 26° C, and 30° C temperature conditions and ration size corresponding to 12.5, 28,64,142, 320 brine shrimp nauplii fish^–1 day^–1 determined from laboratory experiments. Growth was optimal at 31° C and high at temperatures of 26° C to 30° C, at the highest food abundance. Lowest growth was under lowest food rations and highest temperatures. Growth of Colorado squawfish larvae declined substantially at temperatures < 22° C. Neither growth nor survival was significantly different between fluctuating or constant regimes. Survival of Colorado squawfish larvae was highest (95%) at 26.2° C and 235 nauplii fish^–1 day^–1 and high at temperatures of 20 to 30° C with food abundance > 180 nauplii fish^–1 day^–1. Survival was lowest when food abundance was low and temperature was high. Highest mortality occurred more than 20 days after experiments began and mortalities occurred sooner in higher than lower temperatures. Colorado squawfish larvae denied food for 5, 10, or 15 d after first feeding could have begun (6 d), had survival greater than 87 % which was equivalent to continuously fed controls. Survival of fish denied food for 17.5 d after feeding could have begun declined from 84% before feeding to 57% after feeding. Point of no return was estimated between 17.5 and 20 d. Colorado squawfish have relatively high starvation resistance. Low, stable flows that simulate natural hydrographs may enhance growth, survival, and recruitment of early life stages of Colorado squawfish by increasing water temperature and food abundance in regulated rivers of the Colorado River basin.