Ions and osmolality on post‐thaw sperm motility activation of the endangered Brycon insignis (Characiformes)

The aim of this study was to evaluate the effects of osmolality and the presence of ions on the activation of post‐thaw sperm motility of Brycon insignis. Sperm was frozen under a standardized methodology for this species. In experiment 1, 11 solutions were prepared with reverse osmosis (RO) water (～0 mOsm/kg) and glucose or NaCl adjusted to an osmolality of 50, 100, 150, 200 and 250 mOsm/kg. In experiment 2, six solutions were prepared with RO and adjusted to ~100 mOsm/kg with one of the following chemicals: NaHCO₃, sodium citrate (Na₃C₆H₅O₇), NaCl, KCl, CaCl₂ or glucose (as ion‐free control). Post‐thaw sperm of both experiments was evaluated for motility rate, velocities (curvilinear = VCL, among others) and beat‐cross frequency (BCF). In experiment 1, sperm motility rate and velocities were higher (p < 0.05) when triggered in solutions at osmolalities from 0 to 200 mOsm/kg (62–80% motility; 139–167 µm/s) than that at 250 mOsm/kg (36–44% motility; 94–99 µm/s VCL). BCF was not affected by osmolality and varied from 19 to 24 Hz in all samples. In experiment 2, samples activated in NaHCO₃, citrate, NaCl and KCl solutions yielded higher motility rates (76–85%) and BCF (24–25 Hz) compared to those activated in CaCl₂ (50%; 14 Hz). Samples activated in ion‐free control solution yielded higher motility rate (87%) than those activated in NaHCO₃ and in CaCl₂. Curvilinear velocity was higher in samples activated in NaHCO₃, citrate, KCl and control solutions (144–160 µm/s) than in those activated in CaCl₂ (104 µm/s); samples activated in NaCl yielded intermediate VCL values (127 µm/s). Post‐thaw sperm achieves maximum motility rate and velocities when activated in solutions composed of sodium citrate, NaCl, KCl or glucose. Thus, post‐thaw sperm motility of B. insignis can be triggered in ionic and non‐ionic solutions at osmolality between 0 and 200 mOsm/kg. The use of solutions containing calcium, however, should be avoided.     

Use of NaCl prevents aggregation of recombinant COMP–Angiopoietin-1 in Chinese hamster ovary cells

To investigate the effect of hyperosmotic medium on production and aggregation of the variant of Angiopoietin-1 (Ang1), cartilage oligomeric matrix protein (COMP)–Ang1, in recombinant Chinese hamster ovary (CHO) cells, CHO cells were cultivated in shaking flasks. NaCl and/or sorbitol were used to raise medium osmolality in the range of 300–450 mOsm/kg. The specific productivity of COMP–Ang1, q_COMP–Ang1, increased as medium osmolality increased. At NaCl-450 mOsm/kg, the q_COMP–Ang1 was 7.7-fold higher than that at NaCl-300 mOsm/kg, while, at sorbitol-450 mOsm/kg, it was 2.9-fold higher than that at sorbitol-300 mOsm/kg. This can be attributed to the increased relative mRNA level of COMP–Ang1 at NaCl-450 mOsm/kg which was approximately 2.4-fold higher than that at sorbitol-450 mOsm/kg. Western blot analysis showed that COMP–Ang1 aggregates started to occur in the late-exponential phase of cell growth. When sorbitol was used to raise the medium osmolality, a severe aggregation of COMP–Ang1 was observed. On the other hand, when NaCl was used, the aggregation of COMP–Ang1 was drastically reduced at NaCl-400 mOsm/kg. At NaCl-450 mOsm/kg, the aggregation of COMP–Ang1 was hardly observed. This suggests that environmental conditions are critical for the aggregation of COMP–Ang1. Taken together, the use of NaCl-induced hyperosmotic medium to cell culture process turns out to be an efficient strategy for enhancing COMP–Ang1 production and reducing COMP–Ang1 aggregation.     

Enhanced specific antibody productivity of hybridomas resulting from hyperosmotic stress is cell line-specific

Hybridomas with non-growth-associated antibody production are thought to exhibit enhanced specific monoclonal antibody productivity (q _MAb) when subjected to hyperosmotic stress. Two hybridoma cell lines exhibiting non-growth-associated antibody production, S3H5/2bA2 and DB9G8 hybridomas, are cultivated in a batch mode using hyperosmolar media resulting from sodium chloride addition. Their response to hyperosmotic stress regarding q _MAb is quite different, though they show similar depression of cell growth in hyperosmolar media. The q _MAb of S3H5/2bA2 cells in a hyperosmolar medium (396 mOsm/kg, 10% fetal bovine serum (FBS)) is enhanced by approximately 180% when compared with that in a standard medium (283 mOsm/kg, 10% FBS), while q _MAb of DB9G8 cells in the same hyperosmolar medium is enhanced by only 10%. Thus, the enhanced q _MAb of hybridomas exhibiting non-growth-associated antibody production resulting from hyperosmotic stress is cell line-specific.     

Na+ channel activity in cultured renal (A6) epithelium: Regulation by solution osmolarity

Summary Solution osmolarity is known to affect Na⁺ transport rates across tight epithelia but this variable has been relatively ignored in studies of cultured renal epithelia. Using electrophysiological methods to study A6 epithelial monolayers, we observed a marked effect of solution tonicity on amiloride-sensitive Na⁺ currents (I _sc).I _sc for tissues bathed in symmetrical hyposmotic (170 mOsm), isosmotic (200 mOsm), and hyperosmotic (230 or 290 mOsm) NaCl Ringer's solutions averaged 25±2, 9±2, 3±0.4, and 0.6±0.5 A/cm², respectively. Similar results were obtained following changes in the serosal tonicity; mucosal changes did not significantly affectI _sc. The changes inI _sc were slow and reached steady-state within 30 min. Current fluctuation analysis measurements indicated that single-channel currents and Na⁺ channel blocker kinetics were similar for isosmotic and hyposmotic conditions. However, the number of conducting Na⁺ channels was approximately threefold higher for tissues bathed in hyposmotic solutions. No channel activity was detected during hyperosmotic conditions. The results suggest that Na⁺ channels in A6 epithelia are highly sensitive to relatively small changes in serosal solution tonicity. Consequently, osmotic effects may partly account for the large variability in Na⁺ transport rates for A6 epithelia reported in the literature.     

A novel running wheel apparatus to monitor locomotor rhythms in land crabs

The spatial distribution of cephalopods is influenced by salinity and temperature. In marine osmoconformers, one reason for different spatial distributions maybe the putative distinct capacity to regulate tissue hydration. Adult Octopus vulgaris (n?=?6) and O. insularis (n?=?6) were obtained by divers from sites along the southern and northeastern Brazilian coasts, respectively. In the laboratory, octopuses were acclimated to full-strength seawater (salinity 34), for 5–10 days. They were then anesthetized (10 min in 4 °C seawater), a portion of the second right arm was removed, and cut into three portions. Tissues were placed in control isosmotic saline (osmolality 1072 mOsm/kg H₂O). Fragments were weighed and transferred to either isosmotic, hyposmotic (50%), or hyperosmotic (150%) salines, and their weight was observed for 120 min. Tissue from both species maintained their hydration/weight following the hyposmotic shock, but differed in their response to the hyperosmotic challenge, where hydration remained unchanged in O. insularis, but was significantly reduced in O. vulgaris. This result could partially explain why O. insularis is more abundant than O. vulgaris throughout the shallow reefs and tide pools in the warmer and salty tropical waters of the northeastern Brazilian coast.     

Effect of salt and volume loading on the circulation in the leech,Hirudo medicinalis L.

Summary The effects of increased fluid volume in the closed vascular system on circulation were studied in the leech (Hirudo medicinalis) by intravascular pressure recordings and blood flow measurements.Significant increases in blood volume were achieved by crop loading with hyposmotic (72 mOsmol·kg^–1 H₂O) or hyperosmotic (300 mOsmol·kg^–1 H₂O) salt solutions or by infusion of isosmotic saline (200 mOsmol·kg^–1) into the vascular system.During the high-pressure (HIP) phase, which maintains the rear-to-front circulation, systolic blood pressure in the heart was not affected. An increase in systolic pressure in the heart was observed during the low-pressure (LOP) phase, which supplies the segmental circulation. Heart rate was not changed by crop loading with hyposmotic saline or by vascular infusion. Heart rate decreased after crop loading with hyperosmotic saline. Blood flow rate in the dorsal vessel was increased by crop loading with hyposmotic saline, but not after crop loading with hyperosmotic saline. In all cases the diameter of the dorsal vessel was not affected. A possible mechanism controlling blood pressure and blood flow in the vascular system is discussed.Abbreviations HIP-phase high-pressure phase - LOP-phase low-pressure phase - CNS central nervous system     

Polyoxometalate/laccase-mediated oxidative polymerization of catechol for textile dyeing

The synergistic effect between polyoxometalates (POMs), namely K₅[SiW₁₁V^VO₄₀]·11H₂O and H₅[PMo₁₀V^V ₂O₄₀]·13H₂O and laccase from ascomycete Myceliophthora thermophila has been employed for the first time in oxidative polymerization of catechol. Such a laccase-mediator system allowed the formation of a relatively high molecular weight polycatechol as confirmed by size exclusion chromatography and electrospray ionization mass spectrometry (ESI-MS) (3990 Da when using K₅[SiW₁₁V^VO₄₀]·11H₂O and 3600 Da with H₅[PMo₁₀V^V ₂O₄₀]·13H₂O). The synthesized polymers were applied as dyes for the dyeing of flax fabrics. The color intensity of flax fabrics colored with polymer solutions was evaluated by diffuse reflectance spectrophotometry via k/s measurements (+10% of fixation ratio). A new synthetic process allowed a dyeing polymer, provided upon flax coloration, better color fixation and color resistance when compared to that obtained by conventional synthesis with laccase solely or with addition of organic mediator (1-hydroxybenzotriazole).     

Sexual and seasonal variations in osmoregulation and ionoregulation in the estuarine crab Chasmagnathus granulatus (Crustacea, Decapoda)

The estuarine crab Chasmagnathus granulatus (Crustacea, Decapoda, Brachyura) inhabits salt marshes along the South Atlantic coast from Rio de Janeiro (Brazil) to Patagonia (Argentina). In the present study, salinity tolerance (0-45‰; 16-1325 mOsm/kg H₂O) and hemolymph osmotic and ionic (Na⁺, Cl⁻, and K⁺) regulation in both female and male C. granulatus were analyzed in summer and winter. Results showed that both female and male C. granulatus are euryhaline. Mortality was only observed in extremely low salinity (0‰; 16 mOsm/kg H₂O) for both sexes. For females, the LT₅₀ at 0‰ salinity was similar in summer (20.1 h) and winter (17.4 h). Males were more tolerant to salinity than females in both seasons, and mortality was observed only in summer (LT₅₀ = 50.9 h). Results from freshly collected crabs or long-term (16-day) osmotic and ionic regulation experiments in the laboratory showed that male C. granulatus is a better hyper-osmoregulator than female in summer and winter. However, a hypo-osmoregulatory ability was only observed in females experimentally subjected to salinity 40‰ (1176 ± 11 mOsm/kg H₂O) in both seasons. In both sexes, hyper-osmotic regulation was achieved by hyper-regulating hemolymph Na⁺, Cl⁻, and K⁺ concentration. In females, hypo-osmotic regulation was achieved by hypo-regulating hemolymph Na⁺ and Cl⁻ concentration. Long-term (16-day) osmotic and ionic regulations in different salinities were similar in males or females collected and tested in summer and winter. Despite this lack of a seasonal effect on hemolymph osmoregulatory and ionoregulatory patterns in males or females, a marked seasonal difference in the dynamics of these processes was observed for both sexes. In the first 2 days after hypo-osmotic shock (20‰→5‰; 636→185 mOsm/kg H₂O), variations in female osmolality and ion (Na⁺ and Cl⁻) concentration were larger and faster in winter than in summer, while in males the opposite was observed. Furthermore, a seasonal effect on the crab response to hyper-osmotic shock (20‰→40‰; 636→1176 mOsm/kg H₂O) was only observed in males. A new osmolality and ion (Na⁺ and Cl⁻) concentration steady state was faster achieved in winter than in summer. Regarding sexual differences, females showed a better capacity to hypo-regulate the hemolymph osmolality and Na⁺ concentration than males, even after a sudden increase in salinity (hyper-osmotic shock) in both seasons. On the other hand, males showed a better capacity to hyper-regulate the hemolymph osmolality and Na⁺ concentration than females, even after a sudden decrease in salinity (hypo-osmotic shock), especially in winter. Taken together, results reported in the present study suggest the need to consider both sex and collection season as important factors in future osmotic and ionic regulation studies in estuarine crabs.     

Some but not All Tetrahymena Species Destroy Monolayer Cultures of Cells from a Wide Range of Tissues and Species

The activities of Tetrahymena corlissi, Tetrahymena thermophila, and Tetrahymena canadensis were studied in coculture with cell lines of insects, fish, amphibians, and mammals. These ciliates remained viable regardless of the animal cell line partner. All three species could engulf animal cells in suspension. However, if the animal cells were monolayer cultures, the monolayers were obliterated by T. corlissi and T. thermophila. Both fibroblast and epithelial monolayers were destroyed but the destruction of human cell monolayers was done more effectively by T. thermophila. By contrast, T. canadensis was unable to destroy any monolayer. At 4 °C T. thermophila and T. corlissi did not carryout phagocytosis and did not destroy monolayers, whereas T. canadensis was able to carryout phagocytosis but still could not destroy monolayers. Therefore, monolayer destruction appeared to require phagocytosis, but by itself this was insufficient. In addition, the ciliates expressed a unique swimming behavior. Tetrahymena corlissi and T. thermophila swam vigorously and repeatedly into the monolayer, which seemed to loosen or dislodge cells, whereas T. canadensis swam above the monolayer. Therefore, differences in swimming behavior might explain why T. corlissi has been reported to be a pathogen but T. canadensis has not.     

Comparison of sperm quality and DNA integrity in mouse sperm exposed to various cooling velocities and osmotic stress

The first objective was to compare sperm quality following conventional manual sperm freezing (cryovials held 1, 2, 3, and 4 cm, respectively, above liquid nitrogen (LN₂) for 10 min, resulting in cooling velocities of approximately −14.9, −10.1, −6.6, and −5.1 °C/min, respectively), and cooling velocities of −5, −20, −40, and −100 °C/min in a programmed automated freezer, for sperm recovered from CD-1, B6129SF1, and C57BL/6NCrlBR mice. Furthermore, using these strains, as well as 129S/SvPaslco, and DBA/2NCrlBR mice, the second objective was to determine the effects on DNA integrity of sperm exposed to hyposmotic (1 mOsm/L) and hyperosmotic (2400 mOsm/L) solutions, compared to an isosmotic control (300 mOsm/L). For freezing above LN₂ or in an automated freezer, 2 cm above LN₂ and −100 °C/min, respectively, were optimal (P < 0.05-0.01), with no significant differences between these two approaches for post-thaw progressive motility, DNA integrity, and in vitro rates of fertilization and blastocyst formation. Both manual and automated freezing techniques increased post-thaw sperm DNA fragmentation (P < 0.01); the DNA integrity of post-thaw sperm was significantly affected by cooling velocity and strain background. Relative to isosmotic controls, a hyposmotic solution was more deleterious (P < 0.05-0.01) to sperm DNA integrity than a hyperosmotic solution for CD-1, B6129SF1, C57BL/6, and DBA mice (there were strain-dependent differences). In conclusion, optimization of freezing distance and cooling velocity (manual and automated freezing, respectively) were significant factors for efficient cryopreservation and re-derivation of mice from frozen-thawed sperm. Additionally, osmotically-driven volume changes in mouse sperm increased DNA fragmentation, with susceptibility affected by background strain.     

The effect of fertilizer‐N on the inter‐specific competition among three wheat aphids under elevated CO2

Increasing atmospheric carbon dioxide (ab. CO₂) and fertilizer‐nitrogen (ab. N) applications may have marked direct effects on the plant growth of agricultural crops, and in turn affect the higher trophic level of insect herbivores. In this study, the effects of elevated CO₂ (i.e., 650 µl/L vs. ambient 400 µl/L) and fertilizer‐N (0, 50, 100, 200 kg/ha) on the population abundances and the inter‐specific competition among three co‐occurring species of wheat aphids, Sitobion avenae, Rhopalosiphum padi and Schizaphis graminum, were studied. The grain weight per ear and the 1,000‐grain weight were generally increased when grown under elevated CO₂ and showed a significant effect at the 100 kg/ha (grain weight per ear) and 0, 50 and 100 kg/ha (1,000‐grain weight) N. These two yield indexes increased with increasing fertilizer‐N levels within reasonable limits and reached a maximum at 100 kg/ha. Elevated CO₂ combined with fertilizer‐N levels formed complex indirect effects on the three wheat aphids through the wheat crops they fed on. Elevated CO₂ significantly decreased the niche overlap index (ab. NOI) between S. avenae and R. padi under 0 and 100 kg/ha and that between R. padi and S. graminum under 0 kg/ha, while significantly increased the three NOIs under 50 kg/ha and that between R. padi and S. graminum under 100 and 200 kg/ha. S. avenae and R. padi had the larger population and stronger competition in low‐N condition (0 and 50 kg/ha), which was harmful to wheat yield and quality when combined with its own poor nutrition. Overall, the 100 kg/ha N level was the best option based on the aphid population, competition and wheat yields. Therefore, the balanced relationship formed among fertilizers, plants and insects under 100 kg/ha N was vital for the interactive ecosystem.     

High cell density production of <Emphasis Type="Italic">Deinococcus radiodurans</Emphasis> under optimized conditions

Deinococcus radiodurans is a bacterium being investigated for mechanisms of extreme radiation resistance and for bioremediation of environmental radioactive waste sites. In both fundamental and applied research settings, methods for large-scale production of D. radiodurans are needed. In this study, a systematic investigation was carried out to optimize D. radiodurans production at the 20-L fermentor scale. In defined medium, the phosphate buffer typically used was found to be inhibitory to D. radiodurans growth, and caused cell aggregation. Substitution of HEPES and MOPS buffers for phosphate buffer improved D. radiodurans growth characteristics. Several antifoaming agents were investigated to support large-scale production with submerged aeration, and the defoamer KFO 673 was chosen based on its ability to prevent foaming without affecting D. radiodurans growth. The conventional undefined rich medium tryptone/glucose/yeast extract (TGY) maximally supported D. radiodurans growth to an OD₆₀₀ of 10. Using a ‘design of experiments’ approach, we found glucose, Mg and Mn to be critical in supporting high-density growth of D. radiodurans. The optimal pH and temperature for D. radiodurans growth in large-scale preparations were 7.0 and 37°C, respectively. Growth was carried out in a 20-L fermentor using the newly developed media under the optimal conditions. With addition of 10 g/L glucose, 0.5 g/L MgSO₄ · 7H₂O, 5 μM MnCl₂ into TGY media, an OD₆₀₀ of 40 was achieved.     

Effects of anisosmotic medium on cell volume,transmembrane potential and intracellular K+ activity in mouse hepatocytes

Summary Mouse hepatocytes in primary monolayer culture (4 hr) were exposed for 10 min at 37°C to anisosmotic medium of altered NaCl concentration. Hepatocytes maintained constant relative cell volume (experimental volume/control volume) as a function of external medium relative osmolality (control mOsm/experimental mOsm), ranging from 0.8 to 1.5. In contrast, the relative cell volume fit a predicted Boyle-Van't Hoff plot when the experiment was done at 4°C. Mouse liver slices were used for electrophysiologic studies, in which hepatocyte transmembrane potential (V _m ) and intracellular K⁺ activity (a _K ⁱ ) were recorded continuously by open-tip and liquid ion-exchanger ion-sensitive glass microelectrodes, respectively. Liver slices were superfused with control and then with anisosmotic medium of altered NaCl concentration.V _m increased (hyperpolarized) with hypoosmotic medium and decreased (depolarized) with hyperosmotic medium, and ln [10(experimentalV _m /controlV _m )] was a linear function of relative osmolality (control mOsm/experimental mOsm) in the range 0.8–1.5. Thea _K ⁱ did not change when medium osmolality was decreased 40–70 mOsm from control of 280 mOsm. Similar hypoosmotic stress in the presence of either 60mm K⁺ or 1mm quinine HCl or at 27°C resulted in no change inV _m compared with a 20-mV increase inV _m without the added agents or at 37°C. We conclude that mouse hepatocytes maintain their volume anda _K ⁱ in response to anisosmotic medium; however,V _m behaves as an osmometer under these conditions. Also, increases inV _m by hypoosmotic stress were abolished by conditions or agents that inhibit K⁺ conductance.     

Maintenance of fertility in cryopreserved Indian gerbil (Tatera indica) spermatozoa

This study is the first attempt at sperm cryopreservation, as well as a further examination of frozen sperm fertility by the hamster test, applied to the maintenance of an Indian gerbil (Tatera indica) colony, which is a newly developing experimental animal.The osmotic tolerance of the spermatozoa was initially investigated by subjection to hypertonicity, up to 620 mOsm/kg, for 5 min at room temperature prior to freezing. Although the percentage of total motile sperm was not affected, that of progressive motile spermatozoa began to drop at 400 mOsm/kg, and a significant decrease was observed at 620 mOsm/kg (p < 0.01). According to these results, the osmolality of the solutions for the freezing experiment, in which 6–22% raffinose was present, was fixed at approximately 400 mOsm/kg. Sperm, suspended in a plastic straw, were frozen in liquid nitrogen vapor for 5 min, followed by immersion in liquid nitrogen. Motile sperm were recovered from all freezing conditions, and high survival was obtained when sperm were frozen in the presence of 14% and 18% raffinose, with a normalized motility higher than 40%. Fertility of cryopreserved Indian gerbil sperm was examined by the zona-free hamster test. Thawed sperm adhered to 88% of the zona-free hamster oocyte surface, and some oocytes were penetrated and exhibited swollen sperm heads or male pronuclei, which we used to define fertilization. Although the fertilization rate of cryopreserved sperm to zona-free hamster eggs was significantly lower than that of fresh sperm (6% vs. 30%, p < 0.01), we demonstrated that thawed Indian gerbil spermatozoa have the ability to maintain their fertility.     

Influence of hyperosmolar basal media on hybridoma cell growth and antibody production

To investigate the influence of hyperosmolar basal media on hybridoma response, S3H5/γ2bA2 and DB9G8 hybridomas were cultivated in a batch mode using hyperosmolar basal media resulting from additional sodium chloride supplementation. The basal media used in this study were IMDM, DMEM, and RPMI 1640, all of which are widely used for hybridoma cell culture. In IMDM, two hybridomas showed different responses to hyperosmotic stress regarding specific MAb productivity (q _MAb), though they showed similar depression of cell growth in hyperosmolar media. Unlike S3H5/γ2bA2 hybridoma, the q _MAb of DB9G8 hybridoma was not enhanced significantly around 390 mOsm kg^?1. The variation of basal media influenced DB9G8 hybridoma response to hyperosmotic stress regarding q _MAb. In IMDM, the q _MAb of DB9G8 hybridoma was increased by more than 200% when the osmolality increased from 281 to 440 mOsm/kg. However, in RPMI 1640 and DMEM, similar amplitude of osmolality increase resulted in less than 100% increase in q _MAb. The variation of basal media also influenced the cell growth in hyperosmolar medium. Both hybridomas were more tolerant against hyperosmotic stress in DMEM than in IMDM, which was found to be due to the high osmolality of standard DMEM. The osmolalities of standard IMDM and DMEM used for inocula preparation were 281 and 316 mOsm kg^?1, respectively. Thus, when the cells were cultivated at 440 mOsm kg^?1, the cells in IMDM experienced higher osmotic shock than in DMEM. By using the inoculum prepared at 317 mOsm kg^?1 in IMDM, S3H5/γ2bA2 cell growth at 440 mOsm kg^?1 in IMDM was comparable to that in DMEM. Taken together, the results obtained from this study show that the selection of basal media is an important factor for MAb production by employing hyperosmotic stress.     

Structures and luminescent sensors of mixed‐counterions based salen‐type lanthanide coordination polymers

Reactions of N,N′‐bis (salicylidene)‐1,2‐cyclohexanediamine (H₂L) with mixed lanthanide counterions of LnCl₃·6H₂O and Ln (NO₃)₃·6H₂O afford six H₂L lanthanide coordination polymers, e.g. {[Pr(H₂L)₂(NO₃)₂Cl]·2CH₂Cl₂}_n ( 1 ); {[Ln(H₂L)_1.5(NO₃)₃]₂·5CHCl₃·mCH₃OH}_n [Ln = Sm ( 2 ), Eu ( 3 ), Gd ( 4 ), Tb ( 5 ) and Yb ( 6 ); m = 1 ( 2 – 5 ); m = 0 ( 6 )]. X‐ray crystallographic analysis reveals that complex 1 exhibits three‐dimensional diamondoid topologic structure and complexes 2 – 6 are of two‐dimensional structure. Luminescent spectra show that complexes 1 and 6 have characteristic near‐infrared (NIR) emission of praseodymium (III) and ytterbium (III) ions and complexes 2 – 5 emit luminescence in the visible region. Complexes 3 and 6 reveal sensitive luminescence responses to formaldehyde.     

Activation of an Aquareovirus,Chum Salmon Reovirus (CSV), by the Ciliates Tetrahymena thermophila and T. canadensis

For the first time, ciliates have been found to activate rather than inactivate a virus, chum salmon reovirus (CSV). Activation was seen as an increase in viral titre upon incubation of CSV at 22 °C with Tetrahymena canadenesis and two strains of T. thermophila: wild type (B1975) and a temperature conditional mutant for phagocytosis (NP1). The titre increase was not likely due to replication because CSV had no visible effects on the ciliates and no vertebrate virus has ever been shown unequivocally to replicate in ciliates. When incubated with B1975 and NP1 at 30 °C, CSV was activated only by B1975. Therefore, activation required CSV internalization because at 30 °C only B1975 exhibited phagocytosis. CSV replicated in fish cells at 18 to 26 °C but not at 30 °C. Collectively, these observations point to CSV activation being distinct from replication. Activation is attributed to the CSV capsid being modified in the ciliate phagosomal‐lysosomal system and released in a more infectious form. When allowed to swim in CSV‐infected fish cell cultures, collected, washed, and transferred to uninfected cultures, T. canadensis caused a CSV infection. Overall the results suggest that ciliates could have roles in the environmental dissemination of some fish viral diseases.     

Effect of Temperature and Osmolarity on Growth of Crithidia fasciculata,C. hutneri,C. luciliae thermophila,and Herpetomonas samuelpessoai1

Crithidia fasciculata (Anopheles, Culex, and Nöller strains), C. hutneri, C. luciliae thermophila, and Herpetomonas samuelpessoai were grown in a defined medium with different values of osmolarity at different temperatures. C. fasciculata (all strains) grew best between 300 to 500 mOsm; H. samuelpessoai, 400–500 mOsm; and C. hutneri and C. luciliae thermophila, 500–800 mOsm. At higher temperatures better growth was obtained at the upper osmolarities.     

Water and solute regulation in Procephalothrix spiralis Coe and Clitellio arenarius (Müller) III. Long-term acclimation to diluted seawaters and effect of putative neuroendocrine structures

When acutely transferred to diluted seawater (SW), Procephalothrix spiralis and Clitellio arenarius regulate water content (g H₂O/g solute free dry wt = s.f.d.w.) via loss of Na and Cl (µmoles/g.s.f.d.w.). The present study extends these observations to a greater range of salinities and determines the effects of long-term, stepwise acclimation to diluted seawaters. Final exposure to a given experimental seawater (70, 50, 30, 15%) was 48 hours. Osmolality (mOsm/kg H₂O) and Na, K, and Cl ion concentrations (mEq/l) were determined in total tissue water and in the extracellular fluid of C. arenarius. Extracellular volume was determined as the ¹⁴C-polyethylene glycol space. Both species behaved as hyperosmotic conformers in diluted seawaters. However, reduction of the osmotic gradient between worm and medium occurred in P. spiralis, but not C. arenarius, in 30 and 15% SW. In both species, osmolality and Na, Cl, and K concentrations in total tissue water decreased with increased dilution of the SW. Water content increased with dilution of the medium but was lower than that which would be predicted based on approximation of the van't Hoff relation. This indicated the occurrence of regulatory volume decrease (RVD). In P. spiralis, in 70 or 50% SW, RVD was accompanied by loss of Na and Cl contents. However, in 30 or 15% SW, Na and Cl contents increased and in worms in 15% SW K content decreased. The latter movements of Na, Cl and K are indicative of cellular hysteresis and were associated with decreased viability, indicating the lower limits of regulatory ability in this species. In comparison, RVD in C. arenarius occurred in all diluted seawaters and was accompanied by loss of Na and Cl contents. In C. arenarius, evidence for reduced viability was absent. Removal of the supra- and subesophageal ganglia of C. arenarius resulted in retention of water, Na and Cl (g H₂O or µmoles/g s.f.d.w.) in worms acclimated to 70% SW. Removal of the cerebral ganglia and cephalic glands of P. spiralis did not significantly influence regulation of water content.