Triploidy Induction in the Pacific White Shrimp Litopenaeus vannamei: An Assessment of Induction Agents and Parameters, Embryo Viability, and Early Larval Survival

In this study, we trialed 6-dimethylaminopurine (6-DMAP) chemical shocks to induce meiosis I or meiosis II Pacific White shrimp, Litopenaeus vannamei, triploids for the first time, and cold temperature shocks to induce meiosis II L. vannamei triploids as done previously. Inductions were performed on 37 spawnings in total with experiments being progressively designed in a factorial manner to allow optimization of induction parameters. Treatment with a 200-μm 6-DMAP final concentration at 1?min post-spawning detection for a 6 to 8?min duration resulted in the most consistent induction of chemically induced meiosis I triploids while treatment at 7?min 30?s post-spawning detection for a 10-min duration resulted in the most consistent induction of chemically induced meiosis II triploids. A cold temperature shock of 11.7°C to 13.25°C (final treatment temperature; spawning water temperature 28.5°C) applied at 8?min post-spawning detection for a 4 to 10?min duration resulted in the most consistent induction of cold-temperature-induced meiosis II triploids. 6-DMAP shocks resulted in meiosis I induction rates from 29% to 100% in unhatched embryos and 50% in nauplii, and meiosis II induction rates from 65% to 100% in unhatched embryos and 52% to 100% in nauplii. Cold shocks resulted in induction rates from 5% to 100% in unhatched embryos and nauplii. Confocal microscopy analysis of embryos revealed that there are major developmental abnormalities in a large proportion of later stage triploid L. vannamei embryos compared to their diploid sibling controls. Despite this, however, some triploid embryos did appear normal and both shock agents induced small numbers of viable triploid L. vannamei nauplii which were successfully reared to protozoeal stage 3 as confirmed by flow cytometry. Triploids beyond this life-history stage were not observed in the present study as confirmed by flow cytometry at mysis stages. This study adds to our knowledge base of triploid induction in L. vannamei and further highlights the inherent difficulties with triploid embryonic and larval viability in this species.     

Triploidy induction in the Caspian salmon, Salmo trutta caspius, by heat shock

Induction of triploidy was attempted in the Caspian salmon, Salmo trutta caspius, using heat shocks. The optimal temperature level (26, 28 and 30°C), initiation time [5, 10, 20 and 40 min post-fertilization (PF)] and duration of thermal shock (5, 10 and 20 min) required for effective induction of triploidy were investigated. Incidence of triploid fry was determined by surface and volume measurements of erythrocytes as well as from flow-cytometric analysis of some blood samples. Survival from fertilization to swim-up, triploid rates and triploid yields were in the range of 0–70%, 0–97% and 0–57%, respectively. The highest triploid yield was obtained with a shock treatment at 26°C for 10 min duration initiated 40 min PF.     

Delayed meiosis and polar body release in eggs of triploid Pacific oysters, Crassostrea gigas, in relation to tetraploid production

The dynamics of polar body release are important for creating polyploid shellfish. For producing triploids, these dynamics concern meiosis in diploid eggs and are well understood. For creating tetraploids, eggs from triploids are employed and the dynamics, variation, and environmental influences upon polar body release are less studied. We investigated the effects of several agents on the timing of 50% first polar body (PB1) release in eggs of triploids. PB1 release is generally slower in triploid eggs than diploid ones at 26 degrees C. Lowering the temperature (from 26 to 19 degrees C) had a marked effect on timing of 50% PB1 in both diploid and triploid eggs. While lower temperature merely slowed development in diploid eggs, it nearly halted it in triploid eggs. At any temperature, the variability in 50% PB1 release was much higher in triploid eggs than diploid ones; this variation occurred both within eggs from individual females and among eggs from different females. The amount of time eggs remain in seawater between the time they are stripped and fertilized (or time of hydration) also affected rate of meiosis. In triploid eggs, the average time necessary for the expulsion of 50% PB1 was 23 min post-fertilization (PF) for 75 min of hydration versus 29 min PF for 35 min. However, increasing the time of hydration had no effect on the variability in the timing among females. Serotonin also had no effect on the dynamics of polar body release in triploids. Variability among triploid females in timing of meiosis cannot be improved with any treatments we tried. Consequently we recommend that treatments of triploid eggs to produce tetraploids incorporate a single female at a time.     

Protein synthesis patterns following stage-specific heat shock in early Drosophila embryos

Summary Very short heat shocks are administered to carefully staged early embryos of Drosophila melanogaster, and the effects on protein synthesis pattern investigated. A shock as short as 2 min will induce the heat shock response (reduction of normal protein synthesis, increased synthesis of the heat shock proteins) in syncytial blastoderm or later stages. Thus the initial events of the heat shock response must occur within 2 min, and not reverse upon rapid return to 22° C. A low level of synthesis of the 70 kDa heat shock protein is sometimes visible in unshocked animals, but may be induced by the labeling procedure. Survival following a short shock is not strictly correlated with a high level of heat shock response. Pre-blastoderm embryos do not produce significant heat shock protein, but survive a 2 min 43°C heat shock better than do heat shock response competent blastoderm embryos. The protein synthesis pattern prior to the blastoderm stage is very stable, possibly enhancing survival following a short shock. Shocks of 3 min or longer are more detrimental to pre-blastoderm embryos than to later stages, confirming the role of the heat shock response in survival following a longer shock. Stage-specific developmental defects (phenocopies) may be induced by heat shock at the blastoderm or later stages. Induction of these defects may require disruption of the normal protein synthesis pattern. Use of very short heat shocks to induce the heat shock response will be valuable in identifying the precise time at which a specific defect can be induced.     

Tetraploid Induction by Inhibiting Mitosis I with Heat Shock, Cold Shock, and Nocodazole in the Hard Clam Mercenaria mercenaria (Linnaeus, 1758)

Tetraploid induction by inhibiting mitosis I with heat shock (32, 35, and 38°C), cold shock (1, 4, and 7°C), and nocodazole (0.02 to 1.6 mg/L) was investigated in the hard clam Mercenaria mercenaria. All treatments were applied to fertilized eggs about 5 min before the first cell division at 22 to 23°C, and lasted for 10, 15, and 20 min. Three replicates were produced for each treatment with different parents. The ploidy of resultant larvae and juveniles was determined with flow cytometry. Heat shock of 35 and 38°C was effective in inhibiting mitosis I, producing 54% to 89% tetraploid larvae. Heat shock of 32°C accelerated embryonic development without inhibiting mitosis or producing tetraploids. In all heat-shock groups, the survival to D-stage larvae was lower than in controls, suggesting that heat-shock treatments and tetraploidy were detrimental to larval development. At the juvenile stage, survivors from heat-shock groups contained no tetraploids. Cold shocks suspended the first cell division during the treatment, but produced no tetraploids in the 4°C and 7°C treatment groups. Cold shock of 1°C produced 31% tetraploid larvae in one replicate, with none surviving to juvenile stage. Nocodazole inhibited mitosis I at concentrations of 0.04 mg/L or higher, but did not produce tetraploids. This study indicates that heat shock is most effective in inducing tetraploids through mitosis I inhibition, although none of the induced tetraploids survived to juvenile stage.     

The induction of triploidy in Oreochromis aureus by heat shock

Summary Triploid fish were obtained using heat-shock treatment. The optimal conditions for the heat shock (39.5±0.2°C for 3.5–4 min) as well as the exact zygote age (3 min) at which this heat shock was applied were studied. Results showed that this treatment gives rise to 100% of triploid fish with a satisfactory survival rate of 61% beyond the yolk sac resorption. The genital papillae of this triploid fish were underdeveloped in comparison to normal diploid fish. However, no morphological or growth-rate differences between diploid and triploid fish could be observed up to the age of 6 months. Triploidy was assessed by the karyotyping of embryo cells or adult PHA-stimulated lymphocytes, or by erythrocyte measurements. The occurrence of a heat-shock sensitive event at the zygotic age of 6 min is discussed.     

咖啡因加热休克诱导皱纹盘鲍多倍体的研究

报道了用咖啡因加热休克抑制受精卵的第一极体的释放诱导皱纹盘鲍（Ｈａｌｉｏｔｉｓ ｄｉｓｃｕｓ ｈａｎｎａｉ Ｉｎｏ）多倍体的研究结果。皱纹盘鲍的卵在２１℃海水中受精,受精后１０分钟开始处理,药物浓度分别为２．５ｍｍｏｌ／Ｌ、５ｍｍｏｌ／Ｌ、１０ｍｍｏｌ／Ｌ,热休克温度分别为２４℃、２６℃、２８℃,处理的持续时间为１０分钟至３０分钟,共分５个时间段。结果表明,药物浓度５ｍｍｏｌ／Ｌ和１０ｍｍｏｌ／Ｌ     

Shock-induced triploidy and its effect on growth and gonad development of the European catfish, Silurus glanis L.

Triloidy was induced in European catfish, Silurus glanis L., by cold-shocking eggs at 4°C for 30 and 40 min respectively, starting 5 min after fertilization. The hatching success of cold-shocked eggs was 25–30%. Cold shocks longer than 1 h caused total mortality. The triploid character of the cold-shocked European catfish was proved by karyological and red blood cell size analyses. The gonads of the triploid fish were significantly smaller than those of the diploids, while the growth rate values of the triploids were significantly higher than those of the diploids.     

Combined cold, acid, ethanol shocks in Oenococcus oeni: Effects on membrane fluidity and cell viability

The effects of combined cold, acid and ethanol on the membrane physical state and on the survival of Oenococcus oeni were investigated. Membrane fluidity was monitored on intact whole O. oeni cells subjected to single and combined cold, acid and ethanol shocks by using fluorescence anisotropy with 1,6-diphenyl-1,3,5-hexatriene (DPH) as a probe. Results showed that cold shocks (14 and 8 °C) strongly rigidified plasma membrane but did not affect cell survival. In contrast, ethanol shocks (10-14% v/v) induced instantaneous membrane fluidisation followed by rigidification and resulted in low viability. Acid shocks (pH 4.0 and pH 3.0) exerted a rigidifying effect on membrane without affecting cell viability. Whatever the shock orders, combined cold (14 °C) and ethanol (14% v/v) shocks resulted in strong membrane rigidification. Interestingly, O. oeni survived combined cold and ethanol shocks more efficiently than single ethanol shock. Membrane rigidification was induced by ethanol-and-acid (10% v/v - pH 3.5) shock and correlated with total cell death. In contrast, O. oeni recovered its viability when subjected to cold (8 °C)-then-ethanol-and-acid shock which strongly rigidified the membrane. Our results suggested a positive short-term effect of combined cold, acid and ethanol shocks on membrane fluidity and viability of O. oeni.     

Morphogenesis after heat shock during the cell cycle ofLymnaea: A new interpretation

Summary The effect of a heat shock (37.0–38.0°C, 10 min) during the third and fourth cleavage cycles ofLymnaea was investigated. The sensitivity with respect to the duration of the cell cycle and morphogenesis appeared to be periodic. The cycle extension curve has three maxima: at the beginning of the cycle, at the G₂-phase, and at prometaphase. With regard to morphogenesis, the eggs become sensitive shortly before cleavage, when cleavage cannot be delayed any more.In eggs treated at the morphogenetically sensitive stages, mitotic abnormalities caused by an incomplete separation of the chromosomes during treatment were observed. Some cells were lethally affected, and the division chronology was abnormal in some embryos.It is concluded that heat shock disturbs a process relevant to the cell cycle. If applied before metaphase, an extension of the cell cycle permits a complete recovery and morphogenesis remains unaffected. If applied at metaphase or later, cell division is not delayed, but mitosis is seriously disturbed. This irreversible damage is the cause of abnormal morphogenesis. The type of malformation depends on the prospective significance of the affected blastomeres.     

Polyploidy induced by hydrostatic pressure in rainbow trout, Salmo gairdneri Richardson

Triploid rainbow trout were produced by hydrostatic pressure applied to eggs 40 min after fertilization. Treatment for 10 min with or without exposure to 2% ether produced high hatching rates. Nuclear measurements from serial section of 40-day-old fry and from blood smears of 5-month-old juveniles showed that the proportion of triploid individuals was 80–90%. Ether treatment alone did not induce triploidy. Attempts to produce tetraploids by hydrostatic pressure treatment of eggs at 8 h after fertilization failed. Parallel results were also obtained with heat shock.     

Use of grayling sperm (Thymallus thymallus) as a marker for the production of gynogenetic rainbow trout (Salmo gairdneri)

Summary Experiments were conducted to estimate the viability of diploid and induced triploid hybrids between the rainbow trout female and the grayling male. Both are unable to hatch, even so the triploid dies later than the diploid. Insemination of rainbow trout eggs by UV irradiated sperm of grayling results in gynogenetic rainbow trouts when viability is restored by heat shocks inhibiting the second division of egg meiosis.     

Mating behavior of the cabbage beetle, Colaphellus bowringi (Coleoptera: Chrysomelidae)

Abstract  Circadian mating rhythms, mating frequency, mating duration, and the effect of mating duration on fecundity and fertility in the cabbage beetle, Colaphellus bowringi were investigated in the laboratory. Mating occurred throughout the 24-h cycle but the majority of copulations occurred in the photophase with two apparent peaks, one at 8:00 and another at 16:00. Mating frequency observations for 10 consecutive days indicated that pre-mating period of C. bowringi was about 4 days, and pairs mated an average of 5 times per day and an average of 40 times during the first 10 days. There was a negative correlation between mating frequency and mating duration during the consecutive mating. The mean duration of the first copulation (136.24 ± 4.62 min) was significantly longer than those of the second (57.87 ± 2.03 min), third (53.05 ± 2.05 min) and fourth copulation (30.86 ± 2.98 min). Fecundity showed a slight increase with increasing mating duration but no significant difference among treatments. However, fertility was significantly influenced by the mating duration in this species. Mating of 20-min duration did not produce viable eggs. The mean percentage of fertile eggs with completed mating duration (204.43 ± 18.96 min, 56.75% fertile eggs) was significantly higher than those with 60 min (39.55%) and 30 min (17.91%) mating duration, suggesting that the longer mating duration might be associated with transfer of more sperm that are used to increase the fertility of eggs.     

Experiments inducing prospective polar body nuclei to participate in embryogenesis of the sawfly Athalia rosae (Hymenoptera)

Summary Mature eggs dissected from ovaries of unmated females of Athalia rosae (Hymenoptera: Tenthredinidae), if placed on a filter-paper soaked with distilled water, are activated and develop to haploid males. Occasionally, however, diploid females develop from these artificially activated eggs. Treatment of mature unfertilized eggs dissected from diploid females with ice-cold temperatures immediately before activation and with a high temperature (36° C) upon and immediately after activation resulted in the production of diploid males, diploid females, triploid females and gynandromorphs at high frequency. The same treatment of mature unfertilized eggs dissected from triploid females resulted in the production of only triploid survivors. These results, together with the results on the segregation of a marker mutation, yellow fatbody (yfb), appear to indicate that meiotic divisions were complete in the treated eggs, and that all four nuclei became potentially capable of participating in development with or without automictic fusion.Studies on the sawfly, Athalia rosae (Insecta, Hymenoptera, Tenthredinidae), part V     

Heat shock protein responses in thermally stressed bay scallops, Argopecten irradians, and sea scallops, Placopecten magellanicus

The effects of thermal stress on the induction of heat shock proteins (HSPs) were examined in northern bay scallops, Argopecten irradians irradians, a relatively heat tolerant estuarine species, and sea scallops, Placopecten magellanicus, a species residing in cooler, deeper water. Polyclonal antibodies used in this work for analysis of inducible HSP70 and HSP40 only recognized proteins of 72 and 40 kDa respectively from the mantles of both scallop species. Additionally, HSP quantification using the antibody to HSP70 was equally effective by either immunoprobing of western blots or ELISA, demonstrating that either approach could be successfully employed for analysis of thermal response in scallops. Sea scallop HSP70 and HSP40 did not change when animals were heat-shocked for 3 h by raising the temperature from 10 °C to 20 °C; however, a 24 h treatment of the same magnitude elicited a significant response. Conversely, bay scallops displayed rapid and prolonged HSP70 and HSP40 responses during the recovery period following a 3 h heat shock from 20 °C to 30 °C. Temperature reduction from 20 °C to 3 °C for 3 h also caused significant HSP70 and HSP40 increases in bay scallops; this represents the first time cold shock was shown to induce HSP synthesis in bivalve mollusks. The onset of the HSP40 response was more rapid than for HSP70, occurring at the end of the cold shock itself prior to transfer to a recovery temperature. Both proteins responded maximally during recovery at control temperature. HSP responses of sea and bay scallops to thermal stress may be related to their habitat in the natural environment and they suggest a differential capacity for adaptation to temperature change. This is an important consideration in assessing the response of these scallops to different culture conditions.     

Characterization of the heat shock response inEnterococcus faecalis

We have characterized the general properties of the heat shock response of the Gram-positive hardy bacteriumEnterococcus faecalis. The heat resistance (60°C or 62.5°C, 30 min) of log phase cells ofE. faecalis grown at 37°C was enhanced by exposing cells to a prior heat shock at 45°C or 50°C for 30 min. These conditioning temperatures also induced ethanol (22%, v/v) tolerance. The onset of thermotolerance was accompanied by the synthesis of a number of heat shock proteins. The most prominent bands had molecular weights in the range of 48 to 94kDa. By Western blot analysis two of them were found to be immunologically related to the well known DnaK (72 kDa) and GroEL (63 kDa) heat shock proteins ofEscherichia coli. Four other proteins showing little or no variations after exposure to heat are related to DnaJ, GrpE and Lon (La)E. coli proteins and to theBacillus subtilis ⁴³ factor. Ethanol (2% or 4%, v/v) treatments elicited a similar response although there was a weaker induction of heat shock proteins than with heat shock.     

How to overwinter and be a founder: egg-retention phenotypes and mating status in Drosophila melanogaster

In temperate regions, Drosophila melanogaster has perennial overwintering populations. These populations present seasonal variations, under the influence of developmental temperature, for several genetically determined physiological traits. The capacity of virgin females to control ovulation is one of these characteristics. Phenotypes able to postpone egg-laying in the absence of insemination are favored under low temperature development and are numerous in Autumn generations. Moreover, a shift between Autumn and the following Spring has often been observed in favor of these phenotypes. The aim of the present study is to determine the characteristics and situations which confer an advantage on long as compared with short-retention phenotypes, during this non-reproductive period. Several traits were studied: resistance to cold shocks, resistance to long cold periods, developmental duration and viability, longevity and starvation resistance. Long-retention phenotypes (LL) had a longer life expectancy than short-retention phenotypes (ss) under virgin or mated status and greater resistance to starvation, by avoiding waste material (eggs). At 14 °C, flies that had mated once survived for several months on normal substrate with live spermatozoa, and flies on deficient medium (without proteins) survived for more than 3 months varying with phenotype. Flies with the best chance of overwintering are the long-retention phenotypes and some hybrids. The most favorable situation for population restoration is when flies are inseminated once in Autumn rather than when they remain virgin until Spring, because males die sooner than females.     

Sex control and ploidy manipulations in yellow perch (Perca flavescens) and walleye (Stizostedion vitreum)

In both yellow perch ( Perca flavescens ) and walleye ( Stizostedion vitreum ), females grow significantly faster and reach a larger ultimate size than males. In addition, reproductive development in both of these species can have a significant negative impact on somatic growth and fillet yield. Accordingly, methods for producing monosex female populations and for inducing sterility, have important potential applications for both commercial fish culture and fisheries management. Of the several available methods for producing monosex female populations in fishes (such as yellow perch and walleye) in which females are homogametic, the preferred method (described herein) may be to treat juveniles with androgens to induce phenotypic sex inversion of genetic females, and to subsequently use sperm from these females to fertilize normal eggs. Initial efforts at inducing sterility focused on the direct use of either heat or hydrostatic pressure shocks to produce triploid yellow perch and walleye. The gonadal development of triploid yellow perch and walleye of both sexes is retarded compared to that of diploids, and triploid yellow perch can have higher fillet yields than diploids. The direct use of heat and pressure shocks to induce triploidy in yellow perch, however, has negative effects on growth that are independent of ploidy status. One way to circumvent this problem is to produce triploids by crossing fertile tetraploids with diploids. To date, methods of producing viable tetraploids (beyond the larval stage) have been developed for yellow perch but not for walleye.     

Induction of Tetraploid Gynogenesis in the European Sea Bass (Dicentrarchus labrax L.)

A preliminary study on tetraploid gynogenetic induction in the European sea bass was performed by pressure-blocking the second polar body release and the first cleavage in eggs fertilized with ultraviolet-irradiated sperm. Fertilization of eggs with genetically inactivated sperm produced only haploid development that terminated around hatching. Pressure treatments (8.500 psi for 2 min) applied at 6 and 65 min after fertilization (a.f.) produced variable levels (7–95%) of tetraploid larvae at hatching. A small proportion of mosaics (3.8n/4.2n) was also recorded.