Somatic cells derived from haploid larvae are feasible as donors for nuclear transplant in zebrafish. Preliminary results.

Summary Somatic cells derived from zebrafish haploid larval (both androgenetic and gynogenetic) cultures were used as donors for nuclear transplant into non-enucleated oocytes. Nuclei were transplanted either before or simultaneously with oocyte activation in the central region and in the incipient animal pole, respectively. Against expected results, 20% of transplanted embryos during oocyte activation using cells of gynogenetic origin reached the 100% epiboly stage, even two survived for up to 5 days, whereas no development was observed when cells from androgenetic origin were used. Results derived from this work open a novel possibility of studying somatic cell reprogramming and imprinting phenomena in zebrafish.

Ultraviolet radiation and handling medium osmolarity affect chimaerism success in zebrafish.

The effects of a predefined ultraviolet radiation dose (0.529 mW/cm2 for 30s) together with two different micromanipulation medium osmolarities (30 mOsm/kg vs 300 mOsm/kg) were tested on embryo survival at different developmental stages and on the somatic (skin) and germ-line chimaerism rates. Somatic (13%, 6/47 adults) and germ-line chimaerism (50% pigmented F1 larvae) were detected only in the UV-treated recipient embryos micromanipulated in a 300 mOsm/kg medium. From the results obtained, we concluded that the conditions cited above were the most suitable to improve somatic and germ-line chimaerism rates in zebrafish.

Definition of fusion medium and electric parameters for efficient zygote electrofusion in the Pacific oyster (Crassostrea gigas).

Cell electrofusion has been widely used in the induction of tetraploidy in mammals, but little attention has been paid in molluscs. This work pursued the establishment of fusion medium (ionic vs. non-ionic) and electric parameters in the electrofusion of Pacific oyster zygotes (prior to the completion of the first mitotic division), minimizing all deleterious effects possible to D-larval stage. The tested combinations of electric field intensity (Vcm(-1)) and number of square DC pulses applied (for 50 micros each) were (Voltage x N degrees pulses): 400 x 1, 400 x 2, 400 x 3 and 600 x 1, 600 x 2, 600 x 3. When pulses were applied for first time, it was determined that an ionic fusion medium (microfiltered seawater) offered better conditions than the non-ionic fusion media previously used (0.6 M sucrose or 0.6 M mannitol) in terms of embryo survival and lysis rates. In this fusion medium, two different combinations of electric parameters (3 square DC pulses of 400 Vcm(-1) for 50 micros each at 26 degrees C and 1 square DC pulse of 600 Vcm(-1) for 50 micros at 26 degrees C) offered the best technical results of fusion (57 and 79% respectively) and survival until D-larva (44 and 41% respectively). In conclusion, these electric parameters could be established, using seawater as electrofusion medium, for further approaches to evaluate individual ploidy and survival beyond spat.

Ultraviolet radiation dose to be applied in recipient zebrafish embryos for germ-line chimaerism is strain dependent.

Germ-line chimaerism is a powerful technique that has proved to be useful to produce viable gametes when transplanted blastomeres colonize the germinal ridges in recipient embryos and obtaining offspring from such transplanted cells. In fish, ionizing radiations were commonly used for embryo penalization to cancelling the cell participation of recipient embryos in development and in gamete production. The ultraviolet (UV) radiation when compared with other radiation types is cheaper, easier and no special installations are required for its use. So, the aim of this work was to establish the optimal UV radiation dose to be applied in zebrafish embryos at mid-blastula transition stage of development, in order to use them as penalized recipient embryos in futures chimaerism assays. A UV germicide lamp was used as radiation source (0.529 mW/cm(2)). Four exposure levels and three exposure times of UV radiation were tested. The survival rates obtained with the non-dechorionated embryos without lid group suggested that it could be the optimal exposure level to achieve the objective proposed. With the obtained results, we concluded that this UV radiation dose for 60 and 30 s are optimal parameters to penalize recipient wild and gold strain zebrafish embryos, respectively in chimaerism assays, but without involving their survival and apparently normal development.

Micromanipulation medium osmolarity compromises zebrafish (Danio rerio) embryo and cell survival in chimaerism experiments.

In zebrafish chimaerism experiments, the cell injection can involve intra-embryonic cell lyses by osmolar effects. Moreover, the donor cells can be injured during manipulation due to osmolar changes into the transplant pipette. Therefore, the present study aimed to assess the effects of manipulation medium osmolarity on embryonic survival and donor cell viability.In Experiment I, 0.1 microl to 0.15 microl approximately of an isosmolar solution (300 mOsm) was injected into recipient embryos, which were kept at 300 (E1) or 30 mOsm (E2). Survival at day 1 was significantly higher in the E2 group than in E1 (E1: 68% vs E2: 81%, p < 0.05), but after 5 days embryo survival in the E1 group was slightly higher. In Experiment II, donor cells from zebrafish embryos were exposed (or not) to a possible osmolarity change (inner pipette medium: 300 mOsm vs external medium: 30 or 300 mOsm) using two different micropipette outer diameters, 40-50 and 60-70 microm. Cell mechanical damage was detected in the 40-50 microm pipette (p < 0.05), but not by the handling medium osmolarity. Results recommend the use of a 300 mOsm manipulation medium and bore-sized pipettes adjusted as closely as possible to the donor cell size.

Definition of three somatic adult cell nuclear transplant methods in zebrafish (Danio rerio): before, during and after egg activation by sperm fertilization.

Zebrafish somatic nuclear transplant has only been attempted using preactivated eggs. In this work, three methods to carry out the nuclear transplant using adult cells before, during and after the egg activation/fertilization were developed in zebrafish with the aim to be used in reprogramming studies. The donor nucleus from somatic adult cells was inserted: (method A) in the central region of the egg and subsequently fertilized; (method B) in the incipient animal pole at the same time that the egg was fertilized; and (method C) in the completely defined animal pole after fertilization. Larval and adult specimens were obtained using the three methods. Technical aspects related to temperature conditions, media required, egg activation/fertilization, post-ovulatory time of the transplant, egg aging, place of the donor nucleus injection in each methodology are presented. In conclusion, the technical approach developed in this work can be used in reprogramming studies.

Effects on cell viability of three zebrafish testicular cell or tissue cryopreservation methods.

In this work, three cryopreservation procedures were tested in order to obtain efficiently viable testicular cells after cryopreservation. Testicular cells of Wild type zebrafish males were frozen using an equilibrium protocol and testicular tissue fragments were cryopreserved with equilibrium freezing and vitrification procedures. Results showed that vitrification was significantly more efficient than freezing in terms of final cell survival (cell freezing: 14.4%, tissue freezing: 77.4%-85.5%, tissue vitrification: 94%). It must be noted that, in live cells, the presence of pseudopodia was frequently observed, which indicated their spermatogonial nature. Based on these results, the authors suggest that vitrification, with the subsequent elimination of connective tissue after warming, offers the best combination to rescue live testicular cells as a genetic conservation procedure in zebrafish.

Can vitrified zebrafish blastomeres be used to obtain germ-line chimaeras?

Blastomere cryopreservation plays an important role in maintaining the genetic diversity for valuable fish species. Recently, an original procedure for blastomere vitrification in zebrafish (Danio rerio) was developed in our lab. In the present work, blastomeres from the wild strain embryos, previously vitrified-thawed by this procedure, were injected into embryos from the gold strain in order to assess their ability to colonise the germ-line of recipient embryos. The blastomere survival rate at thawing (higher than 90 percent) as well as the whole number of recovered blastomeres per donor embryo (around 20 percent), were in the ranges previously reported for this vitrification technique. Despite this, only 2 adult chimaeric specimens were finally obtained from a total of 47 injected embryos. Signals of chimaerism were not detected at any stage of development of the chimaeric embryos (somatic chimaerism) or in adulthood (somatic and germ-line chimaerism). In relation to this, difficulties during blastomere insertion are thought to be responsible for the poor results obtained, their aspects being discussed in detail in this work. More improvements to overcome such technical difficulties are needed and, until then, blastomere vitrification may only be of interest for germplasm cryobanking.

Vitrification of zebrafish embryo blastomeres in microvolumes.

Cryopreservation of fish embryos may play an important role in biodiversity preservation and in aquaculture, but it is very difficult. In addition, the cryopreservation of fish embryo blastomeres makes conservation strategies feasible when they are used in germ-line chimaerism, including interspecific chimaerism. Fish embryo blastomere cryopreservation has been achieved by equilibrium procedures, but to our knowledge, no data on vitrification procedures are available. In the present work, zebrafish embryo blastomeres were successfully vitrified in microvolumes: a number of 0.25 microl drops, sufficient to contain all the blastomeres of an embryo at blastula stage (from 1000-cell stage to oblong stage), were placed over a 2.5 cm loop of nylon filament. In this procedure, where intracellular cryoprotectant permeation is not required, blastomeres were exposed to cryoprotectants for a maximum of 25 sec prior vitrification. The assayed cryoprotectants (ethylene glycol, propylene glycol, dimethyl sulphoxide, glycerol and methanol) are all frequently used in fish embryo and blastomere cryopreservation. Methanol was finally rejected because of the excessive concentration required for the vitrification (15M). All other cryoprotectants were prepared (individually) at 5 M in Hanks' buffered salt solution (sigma) plus 20% FBS (vitrification solutions: vs). After direct thawing in Hanks' buffered salt solution plus 20% FBS, acceptable survival rates were obtained with ethylene glycol: 82.8%, propylene glycol: 87.7%, dimethyl sulphoxide: 93.4%, and glycerol: 73.9% (p < 0.05). Dimethyl sulphoxide showed the highest blastomere survival rate and allowed the rescue of as much as 20% of the total blastomeres from each zebrafish blastula embryo.

Vitrification of caudal fin explants from zebrafish adult specimens.

No data on vitrification of tissue samples are available in fishes. Three vitrification solutions were compared: V1: 20% ethylene glycol and 20% dimethyl sulphoxide; V2: 25% propylene glycol and 20% dimethyl sulphoxide, and; V3: 20% propylene glycol and 13% methanol, all three prepared in Hanks' buffered salt solution plus 20 percent FBS, following the same one step vitrification procedure developed in mammals. Caudal fin tissue pieces were vitrified into 0.25 ml plastic straws in 30s and stored in liquid nitrogen for 3 days minimum, warmed (10s in nitrogen vapour and 5s in a 25 degree C water bath) and cultured (L-15 plus 20% FBS at 28.5 degree C). At the third day of culture, both attachment and outgrowing rates were recorded. V3 led to the worst results (8% of attachment rate). V1 and V2 allow higher attachment rates (V1: 63% vs V2: 50%. P < 0.05) but not significantly different outgrowing rates (83% to 94%). Vitrification of caudal fin pieces is advantageous in fish biodiversity conservation, particularly in the wild, due to the simplicity of procedure and equipment.