Large intestine bacterial flora of nonhibernating and hibernating leopard frogs (Rana pipiens).

The bacteria in the large intestines of 10 northern leopard frogs (Rana pipiens) were enumerated and partially characterized. Four nonhibernating frogs were collected in the summer, four hibernating frogs were collected in the winter, and two frogs just emerged from hibernation were collected in the spring. All frogs had about 10(10) bacteria per g (wet weight) of intestinal contents and about 10(9) bacteria per g (wet weight) of mucosal scraping, although the counts from the winter frogs were slightly less than those from the other two groups of frogs. Another group of 14 summer frogs, after treatment to induce hibernation, showed a drop in bacterial counts accompanied by a change in the composition of the flora. In most frogs, Bacteroides was the dominant organism. Other bacteria repeatedly isolated at high dilutions were strict anaerobes, including butyrigenic and acetogenic helically coiled bacteria; fusobacteria; and acetogenic, small, gram-positive bacilli. These data indicate that the intestinal flora of frogs is similar to that of mammals and birds and that this flora can be maintained at temperatures close to freezing.     

Functional analysis for gut microbes of the brown tree frog (Polypedates megacephalus) in artificial hibernation

Background

Annual hibernation is an adaptation that helps many animals conserve energy during food shortage in winter. This natural cycle is also accompanied by a remodeling of the intestinal immune system, which is an aspect of host biology that is both influenced by, and can itself influence, the microbiota. In amphibians, the bacteria in the intestinal tract show a drop in bacterial counts. The proportion of pathogenic bacteria is greater in hibernating frogs than that found in nonhibernating frogs. This suggests that some intestinal gut microbes in amphibians can be maintained and may contribute to the functions in this closed ecosystem during hibernation. However, these results were derived from culture-based approaches that only covered a small portion of bacteria in the intestinal tract.

Methods

In this study, we use a more comprehensive analysis, including bacterial appearance and functional prediction, to reveal the global changes in gut microbiota during artificial hibernation via high-throughput sequencing technology.

Results

Our results suggest that artificial hibernation in the brown tree frog (Polypedates megacephalus) could reduce microbial diversity, and artificially hibernating frogs tend to harbor core operational taxonomic units that are rarely distributed among nonhibernating frogs. In addition, artificial hibernation increased significantly the relative abundance of the red-leg syndrome-related pathogenic genus Citrobacter. Furthermore, functional predictions via PICRUSt and Tax4Fun suggested that artificial hibernation has effects on metabolism, disease, signal transduction, bacterial infection, and primary immunodeficiency.

Conclusions

We infer that artificial hibernation may impose potential effects on primary immunodeficiency and increase the risk of bacterial infections in the brown tree frog.

     

The effect of elevated temperature on the toxicity of the laboratory cultured dinoflagellate Ostreopsis lenticularis (Dinophyceae)

Ostreopsis lenticularis Fukuyo 1981, is the major benthic dinoflagellate vector implicated in ciguatera fish poisoning in finfish on the southwest coast of Puerto Rico. Clonal laboratory cultures of O. lenticularis (clone 301) exposed to elevated temperatures (30-31 degrees C) for 33 and 54 days showed significant increases in the quantity of extractable toxin they produced as compared to their toxicities versus cells grown at temperatures of 25-26 degrees C. O lenticularis samples collected directly from the field following exposure to elevated temperatures for comparable periods of time also showed significant increases in extractable toxin. The increased toxicity of both field sampled and laboratory grown O. lenticularis exposed to elevated temperatures may result from the effects of elevated temperatures on their metabolism and/or the bacterial symbionts found associated with these microalgae. The number of bacteria associated with cultured O. lenticularis exposed to elevated temperatures was significantly reduced. Increased toxin recovery from O. lenticularis exposed to elevated temperatures may have resulted from the direct effect of temperature on toxin production and/or the reduction of Ostreopsis associated bacterial flora that consume toxin in the process of their growth. This reduction in the quantity of associated bacterial flora in temperature treated cultures may result in increased toxin recovery from O. lenticularis due to a reduction in the consumption of toxin by these symbiont bacteria.     

Association of germfree mice with intestinal microfloras obtained from "normal" mice

A cultured microflora obtained from the caecum of a "normal" mouse was given to 4 groups of germfree mice and was supplied 1x, 2x, 3x and 4x respectively at 5-day intervals. Another group received a 10(-7) dilution of the caecal flora while a group associated with an 'SPF' flora served as control. The difference (measured by 8 parameters) between mice supplied with the cultured flora or with a 10(-7) dilution, both given once only, was small. Supplying the flora 3x resulted in more 'normal' mice compared with mice which received the flora once or twice. The caeca of specified-pathogen-free mice contained more bacteria per gram (microscopic bacterial count), less aerobic and anaerobic bacteria per gram (viable counts), while the yield as percentage of the microscopic bacterial count was lower as compared with the group to which a cultured flora was supplied 4 times.     

Periodic arousal from hibernation is necessary for initiation of immune responses in ground squirrels

Golden-mantled ground squirrels (Spermophilus lateralis) undergo seasonal hibernation during which core body temperature (T(b)) values are maintained 1-2 degrees C above ambient temperature. Hibernation is not continuous. Squirrels arouse at approximately 7-day intervals, during which T(b) increases to 37 degrees C for approximately 16 h; thereafter, they return to hibernation and sustain low T(b)s until the next arousal. Over the course of the hibernation season, arousals consume 60-80% of a squirrel's winter energy budget, but their functional significance is unknown and disputed. Host-defense mechanisms appear to be downregulated during the hibernation season and preclude normal immune responses. These experiments assessed immune function during hibernation and subsequent periodic arousals. The acute-phase response to bacterial lipopolysaccharide (LPS) was arrested during hibernation and fully restored on arousal to normothermia. LPS injection (ip) resulted in a 1-1.5 degrees C fever in normothermic animals that was sustained for > 8 h. LPS was without effect in hibernating squirrels, neither inducing fever nor provoking arousal, but a fever did develop several days later, when squirrels next aroused from hibernation; the duration of this arousal was increased sixfold above baseline values. Intracerebroventricular infusions of prostaglandin E(2) provoked arousal from hibernation and induced fever, suggesting that neural signaling pathways that mediate febrile responses are functional during hibernation. Periodic arousals may activate a dormant immune system, which can then combat pathogens that may have been introduced immediately before or during hibernation.     

Functional analysis for gut microbes of the brown tree frog (<Emphasis Type="Italic">Polypedates megacephalus</Emphasis>) in artificial hibernation

Background

Annual hibernation is an adaptation that helps many animals conserve energy during food shortage in winter. This natural cycle is also accompanied by a remodeling of the intestinal immune system, which is an aspect of host biology that is both influenced by, and can itself influence, the microbiota. In amphibians, the bacteria in the intestinal tract show a drop in bacterial counts. The proportion of pathogenic bacteria is greater in hibernating frogs than that found in nonhibernating frogs. This suggests that some intestinal gut microbes in amphibians can be maintained and may contribute to the functions in this closed ecosystem during hibernation. However, these results were derived from culture-based approaches that only covered a small portion of bacteria in the intestinal tract.

Methods

In this study, we use a more comprehensive analysis, including bacterial appearance and functional prediction, to reveal the global changes in gut microbiota during artificial hibernation via high-throughput sequencing technology.

Results

Our results suggest that artificial hibernation in the brown tree frog (Polypedates megacephalus) could reduce microbial diversity, and artificially hibernating frogs tend to harbor core operational taxonomic units that are rarely distributed among nonhibernating frogs. In addition, artificial hibernation increased significantly the relative abundance of the red-leg syndrome-related pathogenic genus Citrobacter. Furthermore, functional predictions via PICRUSt and Tax4Fun suggested that artificial hibernation has effects on metabolism, disease, signal transduction, bacterial infection, and primary immunodeficiency.

Conclusions

We infer that artificial hibernation may impose potential effects on primary immunodeficiency and increase the risk of bacterial infections in the brown tree frog.

     

The Van't Hoff rule in studying various phases of hibernation of the squirrel Citellus undulatus Pallas. Physico-chemical route to cold adaptation

Taking into account the van't Hoff's law the rates of relative erythrocyte hemolysis in ground squirrel Citellus undulatus Pallas during different phases of hibernation were first studied by the method of acid erythrograms with some modifications. The temperature of the erythrogram registration (8 degrees C) models the body temperature in hibernation, and temperature of 35 degrees C, corresponds to the body temperature of the awakened ground squirrel. The positions of the erythrogram maxima for the ground squirrel during short-term arousal and during hibernation coincide for each temperature studied: 8 or 35 degrees C. Therefore, the increase in HCl concentration at 8 degrees C reflects an increase in the stability of erythrocyte membranes or a decrease in the rate of relative hemolysis for the ground squirrel during hibernation. Thus, the adaptive response of erythrocytes in hibernating ground squirrel is revealed. The correlation of the rates of physicochemical processes in vitro with the rates of physiological ones in vivo is shown using the ratio of the rates mentioned above for the short-term arousal and for hibernation. First the physicochemical way of cold adaptation due to the van't Hoff's law is proved.     

Ambient temperature dependence of the body temperature and of the duration of the hibernation periods in the garden dormouse, Eliomys quercinus L.

Hibernation pattern in the garden dormouse (Eliomys quercinus) was studied at TA's of 0, 4, 6.5, and 9 degrees C during 6 months in each study winter. The animals were kept in darkness without food or water. Body temperature and the mean duration of the hibernation periods were ambient temperature dependent. The comparison of hibernation at different TA's was based on three features: the mean duration of the hibernation periods during the midwinter plateau, the existence of the initial and terminal phases with the changing length of the hibernation periods, and the differences between the sexes. The TA of 4 degrees C was the optimal TA for long-term hibernation. The difference between 4 degrees C and other TA's was greater in males. The TA's of 0 and 9 degrees C were near the lower and higher TA limits for long-term hibernation. Signs of the existence of a circannual rhythm were detected in the males toward the end of the hibernation season.     

Growth of bacteria degrading naphthalene and salicylate at low temperatures

A total of 58 bacterial strains degrading naphthalene and salicylate were isolated from soil samples polluted with oil products, collected in different regions of Russia during winter and summer. The isolates were assessed for their ability to grow at low temperatures (4, 8, and 15 degrees C); bacteria growing at 4 degrees C in the presence of naphthalene or salicylate accounted for 65% and 53%, respectively, of the strains isolated. The strains differed in the temperature dependence of their growth rates. It was demonstrated that the type of expression of Nah+ phenotype at low temperatures depended on the combination of the host bacterium and the plasmid.     

Cytoplasmic microtubules of normal and tumor cells of the leopard frog. Temperature effects

The cytoplasmic microtubule complex (CMTC) was examined in monolayer cultures of normal tadpole mesonephros, primary renal adenocarcinoma, and an established cell line derived from a pronephric renal adenocarcinoma (PNKT-4B) of the leopard frog, Rana pipiens. Immunocytochemistry revealed typical arrays of microtubules extending from the cytocentrum to the cell periphery in all three cell types when cultured at 28 degrees C; similar results were obtained at 20 degrees C. However, the CMTC was disorganized in both tumor types, in contrast to the retention of a typical CMTC in normal tissue cultured at 7 degrees C. The response of PNKT-4B cells differed from that of normal tadpole mesonephros when treated with the microtubule inhibitor drug nocodazole. At 28 degrees C, PNKT-4B and tadpole mesonephros cells lost their CMTC with nocodazole treatment, and both were able to reconstitute CMTC when nocodazole was removed. Similarly, both lost CMTC organization with nocodazole and culture at 70 degrees C. However, while normal cells could effect a recovery at 7 degrees C after the removal of nocodazole, PONKT-4B cells were unable to restructure CMTC under the same conditions. Metastasis in the frog renal adenocarcinoma is temperature-dependent, with an elevated prevalence of metastasis in tumor-bearing frogs maintained at 28 degrees C. Few metastatic colonies are detected in tumor-bearing frogs maintained at a low temperature (7 degrees C). Other studies have indicated that microtubules, which are essential for cell motility, play an important role in the invasion by tumor cells of normal tissue fragments in vitro. The effects of temperature on metastasis of the Lucke renal adenocarcinoma are consistent with temperature-mediated changes in tumor-cell CMTC.     

Vertebrate freezing survival: Regulation of the multicatalytic proteinase complex and controls on protein degradation

The wood frog, Rana sylvatica, survives weeks of whole body freezing during winter hibernation, expressing numerous metabolic adaptations that deal not only with freezing but with its consequences including organ ischemia and cellular dehydration. The present study analyzes the 20s multicatalytic proteinase (MCP) complex from skeletal muscle to determine how protein degradation is managed in the ischemic frozen state. MCP was partially purified and assayed fluorometrically using three AMC-labeled substrates to compare multiple states: control (5 degrees C acclimated), 24 h frozen at -2.5 degrees C, 4 or 8 h thawed at 5 degrees C, 8 h anoxia, and 40% dehydration. MCP from frozen frogs showed significantly different K(m) and V(max) values compared with controls; e.g., K(m) Z-LLE-AMC increased by 45% during freezing and 52% under anoxia whereas V(max) decreased by 40%. After thawing, K(m) was restored and V(max) rose by 2.2-fold. Incubations promoting protein kinase or phosphatase action on MCP showed that phosphatase treatment strongly increased V(max) implicating reversible phosphorylation in MCP regulation during freeze-thaw. Western blotting showed a 36% decrease in MCP protein in muscle from frozen frogs. The 20s MCP preferentially degrades oxidatively-damaged proteins and evidence of impaired function during freezing came from a 1.4-fold increase in protein carbonyl content in muscle and liver during freezing. Ubiquitin and ubiquitin conjugate levels were unchanged in muscle but changed markedly in liver during freeze-thaw.     

Effect of winter high temperatures on reproduction and circannual rhythms in hibernating ground squirrels

We tested whether prevention of hibernation in ground squirrels by midwinter exposure to high ambient temperatures influenced timing of the spring phase of reproductive maturation and the phase and period of subsequent circannual rhythms of reproduction and body mass. Exposing hibernating adult male Spermophilus lateralis to 30 degrees C for 6 weeks beginning December 4 advanced the timing of testicular recrudescence by 4-5 weeks, compared to controls left at 4 degrees C. Males exposed to 30 degrees C for 6 weeks beginning at the average time of spontaneous end of hibernation (January 15) reached reproductive maturation at a time intermediate to those of controls and of the December 4 experimental group. However, neither the date of the subsequent fall's body mass peak, the date of the next year's reproductive maturation, nor the periods of circannual rhythms of body mass and reproduction differed among groups. Premature interruption of hibernation appears to allow early expression of reproduction, but does not affect the underlying timing mechanism.     

Survival of surface ripening cultures during storage and monitoring their development on cheese

AIMS: To study the survival of bacteria isolated from the surface of smear cheese and monitor their development during cheese ripening. METHODS AND RESULTS: The storage of five potential bacterial surface-ripening cheese cultures, Brevibacterium aurantiacum, Corynebacterium casei, Corynebacterium variable, Microbacterium gubbeenense and Staphylococcus saprophyticus, in maximum recovery diluent (MRD), containing 0.85% w/v or 5% w/v NaCl, at 21 or 4 degrees C for 40 days, was investigated. All five strains studied survived well with a maximum decrease of c. 2.5 log(10) CFU ml(-1) after storage for 40 days at 4 degrees C in 0.85% or 5% w/v NaCl. Survival, especially of C. variable, was less at 21 degrees C. The development of defined ripening cultures containing C. casei and Debaryomyces hansenii on two farmhouse cheeses was also evaluated. Using pulsed-field gel electrophoresis (PFGE) for the bacteria and mitochondrial DNA restriction fragment length polymorphism (mtDNA-RFLP) for the yeast, it was shown that the ripening cultures could be re-isolated in high numbers, 10(8) CFU cm(-2) for C. casei and 10(6) CFU cm(-2) for D. hansenii, from the cheese surface after 2.5 weeks of ripening. CONCLUSIONS: Ripening strains of surface ripening cultures can be stored in MRD containing 5% w/v salt at 4 degrees C for at least 40 days. Such cultures are recovered in high numbers from the cheese during ripening. SIGNIFICANCE AND IMPACT OF STUDY: This study has provided a low-cost and efficient way to store bacteria that could be used as ripening cultures for smear cheese. Such cultures can be recovered in high numbers from the cheese surface during ripening.     

Supercooling ability in two populations of the land snail Helix pomatia (Gastropoda: Helicidae) and ice-nucleating activity of gut bacteria

The land snail Helix pomatia (Gastropoda: Helicidae) is widely distributed in Northern and Central Europe where it may experience subzero temperatures during winter months. Its supercooling ability was studied in two populations of H. pomatia. One population originated from Southern Sweden (Gotaland) and the other from Central France (Auvergne). In the experimental design, they were acclimated, over 2 weeks, to artificial winter conditions (hibernation, T=5 degrees C). The Swedish snails showed a rather limited supercooling ability (temperature of crystallization, T(c)=-6.4+/-0.8 degrees C), significantly greater, however, than the supercooling capacity of the population from France (T(c)=-4.6+/-1.4 degrees C). In artificial spring conditions (3 months of hibernation followed by a progressive acclimation, over 2 weeks, to activity at T=20 degrees C), both populations exhibited a similar high T(c) (-2.0+/-1.0 degrees C). The lower T(c) of hibernating Swedish snails could be due to a greater loss of body water, accompanied by a higher concentration of solutes in the hemolymph. In both populations, the variation in hemolymph osmolality measured between hibernating (250-270 mOsm kg(-1)) and active (165-215 mOsm kg(-1)) snails may be explained by the variation in body water mass and did not suggest the production of colligative cryoprotectants. Moreover, the three bacterial strains, Buttiauxella sp., Kluyvera sp., and Tatumella sp. (Enterobacteriaceae) which were isolated from fed snails, but absent in starved snails, did not show any ice-nucleating activity at temperatures higher than -9 degrees C. Only the strain Kluyvera sp. initiated nucleation at -9 degrees C. This strain, therefore, is a weak, also termed a Type III or Class C ice-nucleating active bacterium, but with no influence on the supercooling ability of individual snails. In summary, fluctuations in body water mass of hibernating snail populations, triggering changes in osmolyte concentration, rather than the presence of endogenous ice-nucleating-active bacteria, accounts for fluctuations in their T(c).     

Aerobic capacity of frog skeletal muscle during hibernation

Frogs submerged at 3 degrees C in hypoxic water (Po2=60 mmHg) depress their metabolic rate to 25% of that seen in control animals with access to air. The hypometabolic state of the skeletal muscle in such cold-submerged frogs is thought to be the most important contributor to the overall metabolic depression. The aim of this study was to determine whether the aerobic capacity of frog skeletal muscle became altered during 1-4 mo of hibernation to match the reduction in adenosine triphosphate (ATP) demand. To this end, the activities of key mitochondrial enzymes were measured in the skeletal muscle and in isolated mitochondria of frogs at different stages during hibernation. We also measured the activity of lactate dehydrogenase (LDH) as an indicator of glycolytic capacity. The activities of cytochrome c oxidase, citrate synthase, and LDH were significantly lower in frog skeletal muscle after 4 mo of hibernation compared with control conditions. The reduction in skeletal muscle aerobic capacity is apparently due to changes in the intrinsic properties of the mitochondria. Overall, these results indicate an important reorganisation of ATP-producing pathways during long-term metabolic depression to match the lowered ATP demand.     

Hypothermic storage of sheep embryos with antifreeze proteins: development in vitro and in vivo

Antifreeze proteins (AFPs) non-colligatively lower the freezing point of aqueous solutions, block membrane ion channels and thereby confer a degree of protection during cooling. Ovine embryos following prolonged hypothermic storage were used to determine 1) the type and concentration of a group of AFPs that can confer hypothermic tolerance, 2) the storage temperature, 3) the cooling rate, and 4) the in vitro and in vivo viability. In Experiment 1, Grade 1 and 2 embryos produced following superovulation were either cultured fresh (control) or stored at 4 degrees C for 4 d in media containing protein from 1 of 3 sources: Winter Flounder (WF; AFP Type 1); Ocean Pout (OP; AFP Type 3) at a concentration of 1 or 10 mg/ml; or bovine serum albumen (BSA) at 4 mg/ml in phosphate buffered saline (PBS). Following 72 h of culture, the viability rates were not different between controls (18 21 ); BSA (9 15 ); WF at 1 mg/ml (14 15 ); WF at 10 mg/ml (13 15 ) or OP at I mg/n-d (15 21 ), but were decreased (P < 0.05) in embryos stored in OP at 1 0 mg/ml (I 1 20 ). Pooled data showed higher (P < 0.05) viability rates for WF (27 30 ) than for OP (26 41 ) or BSA (9 15 ). There was no effect of protein source on hatching rates, but mean hatched diameters of embryos were lower (P < 0.05) following storage in BSA. In Experiment 2, Grade I to 3 embryos were either cultured fresh or stored for 4 d at 0 degrees or 4 degrees C in 4 mg/n-d BSA or 1 mg/ml WF. Embryos stored in WF at 4 degrees C (WF/4 degrees C) had comparable hatching rates (8 12 ) to that of controls (10 10 ), but embryos in the other treatments (WF 0 degrees C, 5 11 , BSA 4 degrees C, 6 11 and BSA 0 degrees C, 3 10 ) had significantly lower hatching rates (P < 0.01) compared with controls. Hatched diameters were comparable between controls and embryos stored in WF 4 degrees C, but embryos stored in WF 0 degrees C and BSA at both temperatures had smaller diameters (P < 0.05). In Experiment 3, Grade 1 to 3 embryos were either transferred fresh or were stored for 4 d at 4 degrees C in 4 mg/ml BSA or 1 mg/ml WF at different cooling rates (T1, BSA > 2 degrees C/min; T2, WF > 2 degrees C/min and T3, WF < 1 degrees C/min) prior to transfer. There were no differences in the number of ewes pregnant (T1, 10 1 1; T2, 6 10 and T3, 8 10 ) or in the number of viable fetuses recovered per treatment (T1, 14 25 ; T2, 10 1 4 and T3, 15 2 1) to indicate a negative effect of cooling rate or protein on embryo survival. In conclusion, ovine embryos can be stored in WF or BSA at 4 degrees C for 4 d, yielding similar pregnancy and embryo survival rates as fresh embryos following transfer to recipient ewes.     

Selective utilization of 2-thioribothymidine- and ribothymidine-containing tRNAs by the protein synthetic systems of Thermus thermophilus HB 8 depending on the environmental temperature

An extreme thermophile, Thermus thermophilus HB 8, contains two types of tRNAs, T- and S2T-containing tRNAs. Their relative content changes depend on the growth temperature of the bacterial cells (1-3). To elucidate the reason why the extreme thermophile possesses the two types of tRNAs, an attempt was made to clarify how these tRNAs are utilized in in vivo protein synthetic systems of the bacteria cultured at different temperatures. First, a method was developed to isolate active polysomes from the thermophile cells cultured at 55 degrees C, 65 degrees C, and 77 degrees C. Then, tRNAs were separated from the polysomes and the T- and S2T-contents of the tRNAs were determined by HPLC. The relative content of S2T-tRNAs in the polysomes from 77 degrees C cells was much higher than that in bulk tRNAs from whole cells cultured at the same temperature, but the situation was reversed in 50 degrees C cells. These results clearly show that the protein synthetic systems of the thermophile have some selection mechanism to utilize either T- or S2T-containing tRNAs preferentially depending on the environmental temperature.     

Vitellogenic cycles in laboratory-maintained females of the leopard frog, Rana pipiens

As a part of studies on the reproduction of laboratory maintained frogs, wild-caught Rana pipiens were ovulated and maintained at 22-27 degrees C for up to 18 months. Vitellogenic oocytes were periodically staged and counted, and a "maturity index" was calculated to assess the progress of the vitellogenic cycle. The initial cycle was similar to that of wild frogs except that the first oocytes to reach stage 5 (mature eggs) usually began to degenerate before later starting oocytes became mature. In addition, a second cycle began before the first was completed. After more than 1 year at room temperature, abnormal cycles were common. Ovaries of such animals contained very few mature eggs. Many of their oocytes were in early stages of vitellogenesis or, if pigmented, had begun to degenerate. These deficiencies were partially corrected in females placed in 4 degrees C for 4-6 weeks. The average number of mature eggs increased 15-fold and ovary weights more than doubled. Oviduct weights almost doubled. Although the rates of cooling, photoperiod, and nutritional status could be important influences, the results imply that cold treatment alone increases estrogen secretion. We suggest that low estrogen secretion may account for the reproductive deficiencies seen in R. pipiens cultured at room temperature.     

Increased heat loss affects hibernation in golden-mantled ground squirrels

During hibernation at ambient temperatures (T(a)) above 0 degrees C, rodents typically maintain body temperature (T(b)) approximately 1 degrees C above T(a), reduce metabolic rate, and suspend or substantially reduce many physiological functions. We tested the extent to which the presence of an insulative pelage affects hibernation. T(b) was recorded telemetrically in golden-mantled ground squirrels (Spermophilus lateralis) housed at a T(a) of 5 degrees C; food intake and body mass were measured at regular intervals throughout the hibernation season and after the terminal arousal. Animals were subjected to complete removal of the dorsal fur or a control procedure after they had been in hibernation for 3-4 wk. Shaved squirrels continued to hibernate with little or no change in minimum T(b), bout duration, duration of periodic normothermic bouts, and food intake during normothermia. Rates of rewarming from torpor were, however, significantly slower in shaved squirrels, and rates of body mass loss were significantly higher, indicating increased depletion of white adipose energy stores. An insulative pelage evidently conserves energy over the course of the hibernation season by decreasing body heat loss and reducing energy expenditure during periodic arousals from torpor and subsequent intervals of normothermia. This prolongs the hibernation season by several weeks, thereby eliminating the debilitating consequences associated with premature emergence from hibernation.     

Control of Listeria monocytogenes in a biofilm by competitive-exclusion microorganisms

Biofilms from drains in food processing facilities with a recent history of no detectable Listeria monocytogenes in floor drains were cultured for microorganisms producing antilisterial metabolites. A total of 413 microbial isolates were obtained from 12 drain biofilm samples and were assayed at 15 and 37 degrees C for activities that were bactericidal or inhibitory to L. monocytogenes, by two agar plate assays. Twenty-one of 257 bacterial isolates and 3 of 156 yeast isolates had antilisterial activity. All 24 isolates which produced metabolites inhibitory to L. monocytogenes were assayed for antilisterial activity in coinoculated broth cultures containing tryptic soy broth with yeast extract (TSB-YE). A five-strain mixture of 10(3) CFU of L. monocytogenes/ml and 10(5) CFU of the candidate competitive-exclusion microorganism/ml was combined in TSB-YE and incubated at 37 degrees C for 24 h, 15 degrees C for 14 days, 8 degrees C for 21 days, and 4 degrees C for 28 days. Substantial inhibition of L. monocytogenes growth (4 to 5 log CFU/ml) was observed for nine bacterial isolates at 37 degrees C, two at 15 and 8 degrees C, and three at 4 degrees C. The inhibitory isolates were identified as Enterococcus durans (six isolates), Lactococcus lactis subsp. lactis (two isolates), and Lactobacillus plantarum (one isolate). The anti-L. monocytogenes activity of these isolates was evaluated in biofilms of L. monocytogenes on stainless steel coupons at 37, 15, 8, and 4 degrees C. Results revealed that two isolates (E. durans strain 152 and L. lactis subsp. lactis strain C-1-92) were highly inhibitory to L. monocytogenes (growth inhibition of >5 log(10) CFU of L. monocytogenes/cm(2)). These two bacterial isolates appear to be excellent competitive-exclusion candidates to control L. monocytogenes in biofilms at environmental temperatures of 4 to 37 degrees C.