<Emphasis Type="Italic">Vibrio parahaemolyticus</Emphasis> and<Emphasis Type="Italic">Vibrio alginolyticus</Emphasis>: Short generation-time marine bacteria

The growth rates of 30 different strains ofVibrio parahaemolyticus andVibrio alginolyticus at 37°C was determined. Each species consists of two major groups, one having a short generation time (12–14 min) and one with a longer generation time (20–25 min). The diversity in generation times of different strains belonging to the same species is discussed. The effect of temperature, salt, and nutrient concentrations on the growth rate of oneV. alginolyticus strain (NCMB 1803) was studied. The most striking is the effect of the temperature; at 39°C the generation time is 10–11 min, while at 21°C it is 60 min. The heat of activation for growth calculating from such data is 22,580 kcal/mole/hr⁻¹. The ecological significance of these results is discussed.     

Effect of temperature,salts, pH and other factors on the development of peritrichous flagella in Vibrio alginolyticus

The development of peritrichous flagella and, consequently, swarming of Vibrio alginolyticus depend on a complex relationship between temperature, salt concentrations and pH. At temperatures above 28°C V. alginolyticus did not develop peritrichous flagella unless certain minimal concentrations of NaCl are present: the higher the temperature, the higher the NaCl concentrations required for peritrichous flagella synthesis. This requirement for NaCl at high temperatures is much more pronounced at pH 9 than at pH 6. High temperatures and low concentrations of NaCl also inhibited swarming of cells already armed with peritrichous flagella. Other cations, such as Li⁺, K⁺ and Mg²⁺, replaced NaCl only at temperatures below 28°C.     

The growth of four species of Azolla as affected by temperature

The growth of 22 strains of Azolla pinnata R. Br., 3 strains of A. filiculoides Lam. and one strain each of A. mexicana Presl and A. caroliniana Willd. was tested separately in liquid culture media kept in controlled, artificial light (30 klux) growth cabinets. Three temperature levels were used: 33°C (37/29°C day/night), 29°C (33/25°C) and 22°C (26/18°C)/ Photoperiod was 12 h a day.For most A. pinnata strains (except three) and an A. mexicana strain the maximum weekly relative growth rate was higher at 33°C than at 22°C, but not for A. filiculoides and A. caroliniana. The highest value of maximum relative growth rate corresponded to 1.9 doubling days and in most strains this occurred in the first week. As the plants grew, the growth rate slowed down more severely at higher temperatures. The maximum biomass was higher at 22°C than at 33°C in all strains. At 22°C, it took 30–50 days to attain maximum biomass and the highest value was 14 g N m^?2 or 320 g dry m^?2 by A. caroliniana, followed by 12 g N m^?2 or 290 g dry wt. m^?2 by one strain of A. filiculoides. At 29°C, the maximum biomass was attained in 20–35 days. The highest value was 6.3 g N m^?2 or 154 g dry wt. m^?2 by A. caroliniana. At 33°C, most A. pinnata strains gave a maximum biomass of less than 4 g N m^?2 after 13–23 days, while some strains grew up to 30 days, resulting in a higher maximum biomass. The highest maximum biomass at 33°C was 5.5 g N m^?2 or 140 g m^?2 dry wt. by A. pinnata from Cheng Mai while the maximum biomass of A. filiculoides and A. caroliniana was much less. Azolla filiculoides requires lower temperature than other species for its growth. Azolla pinnata has the best tolerance to high temperatures among the four species. Azolla mexicana could not be discriminated from A. pinnata in its response to temperature. Azolla caroliniana may keep an intermediate position between A. filiculoides and A. pinnata in temperature response.The formation of ammonia in the medium was examined and it occurred mostly under stationary growth conditions, but, at 33°C, some strains of A. pinnata and A. mexicana released or formed ammonia at 0.3–0.8 μg N ml^?1 per week during their initial exponential growth stage.     

Effects of temperature change on the innate cellular and humoral immune responses of orange-spotted grouper Epinephelus coioides and its susceptibility to Vibrio alginolyticus

Orange-spotted grouper Epinephelus coioides held at 27 °C were then further cultured at 19, 27 (control), and 35 °C, and were examined for innate cellular and humoral responses after 3–96 h. The total leucocyte count, respiratory burst, and phagocytic activity significantly decreased 3, 48, and 96 h after fish were transferred to 19 and 35 °C. Both the alternative complement pathway (ACH₅₀) and the lysozyme activity significantly decreased at 3–96 h after fish were transferred to 19 and 35 °C. In another experiment, groupers reared at 27 °C at 34‰ salinity were injected with Vibrio alginolyticus grown in tryptic soy broth (TSB) at a dose of 2.3 × 10⁹ colony-forming units (cfu) fish^?1, and then further reared in water temperatures of 19, 27 (control), and 35 °C. The cumulative mortalities of V. alginolyticus-injected fish held in 19 and 35 °C were significantly higher than that of injected fish held in 27 °C. Resistance had decreased after 12 h for the challenged grouper held at 35 °C. All injected fish held in 19 °C had died after 72 h. It was concluded that at 12 h after transfer of grouper from 27 to 19 and 35 °C, immunity was suppressed and resistance against V. alginolyticus had decreased.     

The effect of light and temperature on the growth and photosynthesis of Gracilariopsis chorda (Gracilariales, Rhodophtya) from geographically separated locations of Japan

The effect of light and temperature on the growth and photosynthesis of the Japanese agarophyte, Gracilariopsis chorda (Gracilariaceae, Rhodophyta), was determined to better understand its physiology so that we could identify candidates for mass cultivation. Above the photosynthetic active radiation of 66 μmol photons m^?2 s^?1, photosynthetic rates saturated for all strains that were collected from six different locations (Hokkaido, Chiba, Tokushima, Saga, Kagoshima, and Okinawa); furthermore, either photosynthesis or growth was observed at all temperature treatments examined in our study (4–32 °C for photosynthesis, 16–32 °C for growth experiments). We identified a temperature range for optimal photosynthesis and growth, which occurred within 20.1–29.1 °C and roughly correlated with the water temperatures of the collection locations and strongly suggests that this species tolerates a wide variety of water temperature. In particular, the Kagoshima strain had the widest range of optimal temperatures (20.8–29.1 °C), whereas the Saga strain had the narrowest range (23.1–27.3 °C). It is important to note that all the optimal temperature ranges overlapped among the strains; therefore, no definitive distinction can be determined. The broad tolerance to temperatures commonly observed from northern to southern Japan suggests that the cultivation of this species should succeed during spring to summer in the majority of the coastal regions in Japan.     

The ATP-dependent generation of membrane potential by sub-bacterial vesicles from the marine bacterium,Vibrio alginolyticus

Addition of ATP leads to the accumulation of the permeant anion PCB⁻ by sub-bacterial vesicles from Vibrio alginolyticus. This accumulation is caused by Δψ generation by ATPase, the effect being inhibited by CCCP, gramicidin D and DCCD. Δψ values may be increased by incubation of sub-bacterial vesicles at room temperature and with the protein fraction isolated according to Beechey et al. [(1975) Biochem. J. 148, 533–537] from another portion of the sub-bacterial vesicles. Δψ generation is observable only in the presence of Mg²⁺ at high concentrations (optimum ≈ 30 mM). Proceeding from experimental data we assume that Mg²⁺ reduces passive H⁺ conductivity of the vesicle membranes. Thus, a Δψ-generating ATPase has been shown for the first time in V. alginolyticus membranes.     

Loop‐mediated isothermal amplification method for rapid detection of Vibrio alginolyticus,the causative agent of vibriosis in mariculture fish

Aims: The purpose of this study was to develop a loop‐mediated isothermal amplification (LAMP) method for the rapid, sensitive and simple detection of Vibrio alginolyticus in mariculture fish. Methods and Results: LAMP primers were designed by targeting the gyrB gene. With Bst DNA polymerase, the target DNA can be clearly amplified for 60 min at 64°C in a simple water bath. The detection sensitivity of the LAMP assay for the detection of V. alginolyticus is about 3·7 × 10² CFU ml^?1 (3·7 CFU per reaction). LAMP products could be judged with agar gel or naked eye after the addition of SYBR Green I. There were no cross‐reactions with other bacterial strains indicating a high specificity of the LAMP. The LAMP method was applied to detect V. alginolyticus‐infected fish tissues effectively. Conclusions: The LAMP established in this study is a simple, sensitive, specific, inexpensive and rapid protocol for the detection of V. alginolyticus. Significance and Impact of the Study: This LAMP method provides an important diagnostic tool for the detection of V. alginolyticus infection both in the laboratory and field.     

Effects of light,temperature and salinity on the growth rate of harmful marine diatoms,Chaetoceros convolutus and C. concavicornis that kill netpen salmon

Chaetoceros convolutus and C. concavicornis have been implicated in the death of salmon in netpens in the Pacific Northwest by damaging the salmon's gills. To better understand how environmental factors affect the distribution of these two species, the interacting effects of light, temperature and salinity on growth rate were examined by growing these species under a range of temperatures (4–18 °C), light (10–175 μmol photon m⁻² s⁻¹) and salinities (10–30‰). For C. convolutus, the growth rate showed a hyperbolic relationship with irradiance at 8, 14 and 18 °C and light saturation occurred at 9, 14 and 20 μmol photon m^t s⁻¹ respectively. At 4 °C for C. convolutus and 8 °C for C. concavicornis, cells grew at μ_max, even at the lowest irradiances tested (10 μmol photon m⁻² s⁻¹). For C. convolutus, the amount of light required to saturate growth rate increased with temperature in an approximately linear fashion. The Q₁₀ was 1.88, calculated by averaging over both species. C. concavicornis was the more euryhaline species growing at salinities as low as 17.5‰, while C. convolutus grew only at 25‰ and above.     

Short-term effects of temperature upon the growth of intertidal fucales

The growth rate of five species of intertidal Fucales (Pelvetia canaliculata (L.) Dec. et Thur., Fucus spiralis L., Fucus vesiculosus L., Fucus serratus L., Ascophyllum nodosum (L.) Le Jolis) was measured at temperatures from 2.5 to 35 °C. An increase in temperature immediately causes a high growth rate, and during the first hour it increases linearly with temperature; at 35 °C it is 20 times the control at 7 °C. This acceleration of growth is based mainly on stored photosynthate. After the first few hours the growth rate decreases rapidly, particularly at the highest temperatures. After 2–3 weeks a temperature optimum below 17.5 °C is indicated. High temperatures, 30–35 °C, were lethal to all species, with a survival time corresponding to their vertical zonation in the natural habitat.     

Effects of temperature and irradiance on quantum yield of PSII photochemistry and xanthophyll cycle in a tropical and a temperate species

The effect of a wide range of temperatures (?15 and 60°C) in darkness or under strong irradiation [1,600 μmol(photon) m^?2 s^?1] on quantum yield of photosystem II photochemistry and xanthophyll cycle pigments was investigated in a tropical fruit crop (Musa sp.) and a temperate spring flowering plant (Allium ursinum L.). In darkness within the nonlethal thermal window of A. ursinum (from ?6.7 to 47.7°C; 54.5 K) and of Musa sp. (from ?2.2°C to 49.5°C; 51.7 K) maximal quantum yield of PSII photochemistry (F_v/F_m) was fairly unaffected by temperature over more than 40 K. At low temperature F_v/F_m started to drop with ice nucleation but significantly only with initial frost injuries (temperature at 10% frost damage; LT₁₀). The critical high temperature threshold for PSII (T_c) was 43.8°C in A. ursinum and 44.7°C in Musa sp. Under strong irradiation, exposure to temperatures exceeding the growth ones but being still nonlethal caused photoinhibition in both species. Severity of photoinhibition increased with increasing distance to the growth temperature range. ΔF/F_m′ revealed distinctly different optimum temperature ranges: 27–36°C for Musa sp. and 18–27°C for A. ursinum exceeding maximum growth temperature by 2–7 K. In both species only at temperatures > 30°C zeaxanthin increased and violaxanthin decreased significantly. At nonlethal low temperature relative amounts of xanthophylls remained unchanged. At temperatures > 40°C β-carotene increased significantly in both species. In Musa sp. lutein and neoxanthin were significantly increased at 45°C, in A. ursinum lutein remained unchanged, neoxanthin levels decreased in the supraoptimal temperature range. In darkness, F_v/F_m was highly temperature-insensitive in both species. Under strong irradiation, whenever growth temperature was exceeded, photoinhibition occurred with xanthophylls being changed only under supraoptimal temperature conditions as an antiradical defence mechanism.     

Kazachstania psychrophila sp. nov., a novel psychrophilic yeast isolated from vacuum-packed beef

Five novel ascosporogenous yeast strains (H382, H396, H409, H433^T and H441) were found through a survey of vacuum-packed beef microbiota. Sequence analysis of ITS domain and LSU rRNA genes showed that the new strains represent a distinct lineage within the genus Kazachstania, closely related to Kazachstania lodderae (97.0 % identity) and Kazachstania ichnusensis (96.1 % identity). The main difference of strains H382, H396, H409, H433^T and H441 to strains of known Kazachstania species is the maximum growth temperature, which is below 20 °C for the new strains, whereas related species grow at 25 °C. Furthermore, the strains differed from known Kazachstania species in assimilation and fermentation patterns of carbon sources. Based on these characteristics, the five strains are considered to represent a novel species of the genus Kazachstania for which the name Kazachstania psychrophila sp. nov. is proposed. The type strain is H433^T (DSM 26230^T=CBS 12689^T). The Mycobank number of the type strain is MB 803980.     

Seed germination at different temperatures and seedling emergence at different depths of Rhamnus spp

Rhamnus alaternus and R. ludovici-salvatoris, two Mediterranean shrubs with different geographic distributions, have shown important differences in seedling recruitment capacity. The objectives of this work were to determine the ability of these species to germinate seeds under different temperature ranges, as well as the capacity of seedlings to emerge from different burial depths, in order to better understand their regeneration processes. Two different experiments were performed. In the first one, seed germination was studied in Petri dishes and in the dark at different temperature regimes: a) 5–15°C, b) 10–20°C and c) 15–25°C (12h/12h). In the second experiment, seedling emergence capacity from different burial depths (0.5, 2 and 5 cm) was tested. R. ludovici-salvatoris showed a significantly higher final germination rates, a lower dormancy period, and average time response at 10–20°C than at other temperature ranges, although differences were much greater when seeds were subjected to the 5–15°C temperature regime. By contrast, R. alaternus did not show significant differences between treatments (5–15°C and 10–20°C) in germination behavior. Seedling emergence of both species was lower and slower when seeds were buried at 5 cm. However, R. ludovici-salvatoris always showed a lower seedling emergence capacity than R. alaternus at any burial depth. The low ability of R. ludovici-salvatoris to germinate seeds and emerge between 5–15°C, even from shallow depths, is discussed in relation to its low regeneration capacity and declining geographic distribution.     

Inhibition of pathogenic Vibrio by the microalgae Isochrysis galbana

Vibrio alginolyticus, Vibrio campbellii, and Vibrio harveyi were inhibited by Isochrysis galbana in batch cultures. I. galbana reduced the V. alginolyticus, V. campbellii, and V. harveyi counts to undetectable levels in 2, 4, and 7 days (<0.01 Vibrio spp. mL^?1), respectively, remaining so until the end of the experiment on day 15. Other heterotrophic bacteria reached counts of 10⁶ CFU mL^?1 on ZoBell medium at the end of the experiment. Vibrio parahaemolyticus was not inhibited by I. galbana. In all mixed I. galbana and Vibrio spp. cultures, the algal density increased from 3.5 to 4.0?×?10⁷ cells mL^?1, higher than that in I. galbana cultures alone, indicating a lack of an inhibitory effect on microalgae in the mixed cultures. The predominant fatty acids (>82 %) of I. galbana during the stationary growth phase were estearidonic (24.3 %), oleic (15.7 %), myristic (13.8 %), docosahexaenoic (11.0 %), palmitic (10.3 %), and α-linolenic (7.2 %) acids. These results demonstrate that I. galbana synthesizes antibacterial fatty acids that inhibit the growth of pathogenic bacteria such as V. alginolyticus, V. campbellii, and V. harveyi.     

Optimization of cultural conditions for the production of antifungal chitinase by Streptomyces sporovirgulis

Actinomycetes were screened from soil in the centre of Poland on chitin medium. Amongst 30 isolated strains one with high activity of chitinase was selected. It was identified as Streptomyces sporovirgulis. Chitinase activity was detected from the second day of cultivation, then increased gradually and reached maximum after 4 days. The maximum chitinase production was observed at pH 8.0 and 25–30°C in the medium with sodium caseinate and asparagine as carbon and nitrogen sources and with shrimp shell waste as inducer of enzyme. Chitinase of S. sporovirgulis was purified from a culture medium by fractionation with ammonium sulphate as well as by chitin affinity chromatography. The molecular weight of the enzyme was 27 kDa. The optimum temperature and pH for the chitinase were 40°C and pH 8.0. The enzyme activity was characterised by high stability at the temperatures between 35 and 40°C after 240 min of preincubation. The activity of the enzyme was strongly inhibited in the presence of Pb²⁺, Hg²⁺ and stabilized by the ions Mg²⁺. Purified chitinase from S. sporovirgulis inhibited growth of fungal phytopathogen Alternaria alternata. Additionally, the crude chitinase inhibited the growth of potential phytopathogens such as Penicillium purpurogenum and Penillium sp.     

The thermophilic bacteria hydrolyzing agar: Characterization of thermostable agarase

Three strains of anaerobic thermophilic bacteria capable of growing on agarose as a source of energy and carbon were isolated from hot springs near Lake Baikal (Barguzin National Park) and the caldera Uzon (Kamchatka). Cells of all the three strains were spore bacilli with peritrichous flagellation. These isolates grew at a temperature of 55–60°C and pH 6.5–7.0 and fermented a wide range of organic substrates. Analysis of the 16S rRNA sequences allowed us to ascribe the strains B5 and K14 to the genus Thermoanaerobacter and the strain K67 to the genus Caldoanaerobacter. According to the results of DNA-DNA hybridization, B5 was determined as belonging to the species Thermoanaerobacter wiegelii. Agarase was isolated by preparative PAGE and subsequent gel chromatography from the culture liquid of strain B5 grown on the medium containing 0.5% agarose and 0.3% galactose. The molecular weight of this enzyme amounted to 67 kDa and pI, to 4.2. The T. wiegelii B5 agarase was active in the pH range of 3.5 to 7.0 (optimum, 5.2) and temperature range of 50 to 80°C (optimum, 70°C). The preincubation of this enzyme at 90° C for 60 min did not reduce the agarase activity. This activity increased in the presence of metal ions; the maximal effect was observed in the presence of 5 mM Mg²⁺ and 25 mM Co²⁺.     

Field evaluations of systemic fungicides and derivatives of dithiocarbamic acid for the control of clubroot

Strains of Botrytis cinerea and Mucor mucedo germinated and grew over the range 0.25^°C. There were differences in germination rates and growth rates between strains of B. cinerea at any given temperature. Five of the benomyl-resistant strains germinated and grew more slowly than any of the other benomyl-resistant or benomyl-sensitive strains of B. cinerea tested. Strains of Rhizopus stolonifer and R. sexualis germinated and grew between 5 and 25^°C, and although some spores germinated at 2^°C, subsequent growth of the germ tubes and growth from a mycelial inoculum did not occur. Neither species germinated or grew at o^°C. The effect of temperature on mycelial growth in vitro was consistent with the ability of the strains of the four species to infect strawberry fruits.     

Effects of temperature on growth of Vallisneria americana in a sub-tropical estuarine environment

The submersed aquatic vegetation (SAV) species Vallisneria americana Michx. (tape grass) is a valuable resource in the Caloosahatchee estuary and in many other aquatic systems. Given the variable nature of freshwater inflows and environmental conditions in the Caloosahatchee, it is necessary to understand how tape grass will respond to high and low salinity conditions at different light and temperature levels. Specifically, quantitative information is needed as input to modeling tools that can be applied to predict growth and survival of tape grass under a range of environmental conditions present in the estuary. We determined growth rates for small and medium sized tape grass plants obtained from the Caloosahatchee estuary, southwest coastal Florida, USA in freshwater (0.5 psu) under high (331 μE m^?2 s^?1) and low light (42 μE m^?2 s^?1) and at 10 psu under high light conditions. We ran six treatments at five temperatures spanning 13–32 °C for 8–9 weeks. The optimum temperature for growth was roughly 28 °C, with a minimum threshold temperature of 13 °C and a maximum threshold temperature of 38 °C. Plants grew fastest in freshwater, at high light and temperatures greater than 20 °C. The slowest growth rates were observed at 13 °C regardless of salinity, light or plant size. Our results suggest that tape grass growth is strongly influenced by water temperature and that additional stressors such as low light and elevated salinity can reduce the range of temperature tolerance, especially at colder water temperatures.     

Localised corrosion induced by a marine vibrio

The corrision of mild steel in media with and without bacterial cultures was assessed using potentiostatic and potentiodynamic techniques and the production of biofilm on the metal surface was studied by scanning electron microscopy.Metal in a solution consisting of the inorganic components of Postgate's medium C was not passivated, but a passive surface was indiced by the addition of lactate, citrate, or phosphate. The breakdown potential (E_b of the passivated metal was most anodic for phosphate. No significant change in the electrochemical behaviour of the steel was seen when the formulation of Postgate's medium C was completed by the addition of yeast extract, but chloride, added to allow the growth of Vibrio alginolyticus, caused a reduction in the E_b value.Vibrio alginolyticus reduced the E_b value in Postgate's medium C from −0·37 to −0·43V, indicating its corrosive capacity. This value was reduced still further, to −0·60V, when sulphate-reducing bacteria were also present.Scanning electron microscopy showed the presence of colonies of V. alginolyticus on the metal surface. When cleaned, it was apparent that intense pitting had occurred beneath these colonies.It is suggested that V. alginolyticus may promote chemical or SRB-induced corrosion by removing a passive film from the metal, allowing aggressive species such as sulphides to affect the surface.     

Response of Antarctic, temperate, and tropical microalgae to temperature stress

The global temperature increase has significant implications on the survival of microalgae which form the basis of all aquatic food webs. The aim of this study was to compare the response of similar taxa of microalgae from the Antarctic (Chlamydomonas UMACC 229, Chlorella UMACC 237, and Navicula glaciei UMACC 231), temperate (Chlamydomonas augustae UMACC 247, Chlorella vulgaris UMACC 248, and Navicula incerta UMACC 249), and tropical (C. augustae UMACC 246, C. vulgaris UMACC 001, and Amphiprora UMACC 239) regions to changing temperature. The Antarctic, temperate, and tropical strains were grown over specific temperature ranges of 4 °C to 30 °C, 4 °C to 32 °C, and 13 °C to 38 °C, respectively. The three Antarctic strains survived at temperatures much higher than their ambient regime. In comparison, the tropical strains are already growing at their upper temperature limits. The three Chlorella strains from different regions are eurythermal, with a large overlap on tolerance ranging from 4 °C to 38 °C. The specific growth rate (μ) of the Antarctic Navicula decreased (<0.34 day^?1) at temperatures above 4 °C, showing it to be sensitive to temperature increase. If further warming of Earth occurs, N. glaciei UMACC 231 is likely to have the most deleterious consequences than the other two Antarctic microalgae studied. The percentage of polyunsaturated fatty acids (PUFA) decreased with increasing temperature in the Antarctic Navicula. As temperature increases, the growth and nutritional value of this commonly occurring diatom in the Antarctic may decrease, with consequences for the aquatic food web. Of the three Chlamydomonas strains, only the Antarctic strain produced predominantly PUFA, especially 16:3 (48.4–57.2 % total fatty acids).     

Thermal limits for the establishment and growth of populations of the invasive apple snail <Emphasis Type="Italic">Pomacea canaliculata</Emphasis>

Pomacea canaliculata is a South American freshwater snail considered as one of the world’s worst invasive alien species. A temperature of around 25 °C has usually been considered to be optimal for rearing P. canaliculata. Nevertheless, snails have not been reared under a wide range of temperatures to reveal the optimum for performance in terms of population increase. We investigated the effect of temperature on growth, survival and reproduction, estimating demographic parameters for P. canaliculata in the wide range of temperatures at which these snails are active (15–35 °C). No reproductive activity was evidenced for the snails reared at 15 °C, probably explained by the small sizes attained at this temperature. Temperatures above 25 °C did not promote a significant acceleration in growth so higher temperatures will not result in a reduction in time to reach maturity. In fact, snails from 25 and 30 °C began reproduction at the same age. We report here for the first time a detrimental effect of high temperatures that provoked a significant decrease in the contribution of snails to the next generation: the viability of eggs from the snails reared at 30 °C was very low and the snails exposed to a constant water temperature of 35 °C were unable to produce eggs. Our findings reveal a new environmental constraint that could be a determinant of the range limits of this species in invaded regions, especially during the coming decades, anticipating the scenario predicted from global warming.