Genetic Inactivation of European Sea Bass (Dicentrarchus labrax L.) Eggs Using UV-Irradiation: Observations and Perspectives

Androgenesis is a form of uniparental reproduction leading to progenies inheriting only the paternal set of chromosomes. It has been achieved with variable success in a number of freshwater species and can be attained by artificial fertilization of genetically inactivated eggs following exposure to gamma (γ), X-ray or UV irradiation (haploid androgenesis) and by restoration of diploidy by suppression of mitosis using a pressure or thermal shock. The conditions for the genetic inactivation of the maternal genome in the European sea bass (Dicentrarchus labrax L.) were explored using different combinations of UV irradiation levels and durations. UV treatments significantly affected embryo survival and generated a wide range of developmental abnormalities. Despite the wide range of UV doses tested (from 7.2 to 720 mJ.cm⁻²), only one dose (60 mJ.cm⁻².min⁻¹ with 1 min irradiation) resulted in a small percentage (14%) of haploid larvae at hatching in the initial trials as verified by flow cytometry. Microsatellite marker analyses of three further batches of larvae produced by using this UV treatment showed a majority of larvae with variable levels of paternal and maternal contributions and only one larva displaying pure paternal inheritance. The results are discussed also in the context of an assessment of the UV-absorbance characteristics of egg extracts in this species that revealed the presence of gadusol, a compound structurally related to mycosporine-like amino acids (MAAs) with known UV-screening properties.     

Androgenesis and homozygous gynogenesis in muskellunge (Esox masquinongy): Evaluation using flow cytometry

The purpose of this work was to study the effects of ultraviolet (UV) irradiation on denucleation of eggs and investigate the heat-shock conditions for diploidization for induction of androgenesis in muskellunge, Esox masquinongy. Several egg incubation media, including saline, Ringer's solution, and Ringer's solution supplemented with bovine serum albumin (BSA), were found suitable to maintain the egg fertility as high as in muskellunge ovarian fluid. The optimal doses of UV radiation were 660–1320 J/m², at which 100% haploid larvae were produced at a hatching rate of 22.5 ± 2.8%. UV irradiation at low doses (165–330 J/m²) generated abnormal larvae, which were morphologically identical to haploids. Using a flow cytometry method, it was found that cellular DNA content of these larvae was close to that of diploids but significantly lower in value and had a wider distribution (expressed as coefficient of variation) than that of control fish. This suggested that a low dose of UV irradiation might cause gene mutations, alteration of chromosomal conformation and fragmentation, but did not prevent maternal DNA from participating in mitotic division. Interference of maternal DNA residues could be another reason for the poor viability of androgenetic fish. A high dose of UV radiation (1980 J/m²) caused development of severely deformed embryos, indicating that UV radiation also damaged molecules in the eggs other than the denucleation. Our results suggest that classic color and allozyme markers might not be sufficient to prove a complete androgenesis. In order to optimize time and duration of shock for induced diploidization, we investigated the heat-shock conditions for inhibiting the first mitotic cleavage through induction of homozygous gynogenesis. We found that heat-shock treatment at 31°C for 9 min starting at 1.4τ₀ (a dimensionless factor describing progress in embryo development) after fertilization produced the highest percentage of diploids at hatching. Mol. Reprod. Dev. 49:10–18, 1998. © 1998 Wiley-Liss, Inc.     

Failure of interspecies androgenesis in salmonids

Androgenetic development of salmonid embryos was induced in recipient oocytes from the same or other species (intra- or interspecies androgenesis). Parameters for induced androgenesis were investigated in brown trout Salmo trutta and brook trout Salvelinus fontinalis . Reciprocal androgenetic and control crosses were conducted among fishes from three genera: Oncorhynchus (rainbow trout, O. mykiss ), Salmo (brown trout) and Salvelinus (brook trout), and within two genera: Salmo (brown trout and Atlantic salmon, S. salar ) and Salvelinus (brook trout and Arctic charr, S. alpinus ). Live hatched androgenetic progenies were obtained in all intraspecies variants, where oocytes and sperm originated from the same species. Interspecies androgenesis resulted in no viable larvae, despite the fact that most hybrid controls and intraspecies androgenetic individuals were viable. When recipient oocytes originated from other genera (interspecific intergeneric androgenesis), embryonic development ceased in early developmental stages, except for haploid controls of brook trout produced in eggs of brown trout. Survival of embryos to the eyed-egg stage was relatively high in the intrageneric androgenesis experiment. Nevertheless, none of these embryos survived to hatching. Some of the presumed Atlantic salmon individuals developing in brown trout eggs contained maternal DNA, questioning the accuracy of enucleation using irradiation. The inability to induce interspecific androgenesis among the examined salmonid species may have been the result of substantial kariotypical and developmental differences between spermatozoal donors and oocyte recipients, causing an incompatibility between maternal cytoplasmic regulatory factors and the paternal nuclear genome.     

Induced androgenesis in acipenserids may be obtained by ultraviolet radiation

The results are presented on haploid androgenesis in Siberian sturgeon and sterlet induced by UV irradiation of ovicells. During irradiation, the cells in Ringer solution were rotated around a UV lamp. The efficiency of genetic inactivation of ovicells was estimated by the following parameters: manifestation of Hertwig effect, the fraction of embryos demonstrating haploid syndrome at final developmental stages, by arrest of embryonic development in hybrids Siberian sturgeon × great sturgeon, and by absence of maternal alleles of microsatellite loci in embryos. The dose-effect curve suggests that, during UV irradiation of ovicells of Siberian sturgeon, the complete genetic inactivation is attained at exposition of 120 s, while that in sterlet is 90 or 105 s. The results show a principal possibility of inactivation of ovicells by UV irradiation and use of such cells for producing androgenetic progeny of acipenserids.     

UV irradiation of polar cells of Drosophila melanogaster eggs. II. Estimation of the number of polar cells at the origin of the germinal line

Polar cap cells of Drosophila eggs were irradiated with UV doses ranging from 750 to 1200 erg/mm². One of the important observations relates to the incidence of sterility among the surviving males and its dependence on the dose of UV irradiation. Histological examination of the sterile males showed that such males have agametic testes.     

Effects of inhibitors on repair of DNA in normal human and xeroderma pigmentosum cells after exposure to x-rays and ultraviolet irradiation

Experiments were carried out to obtain direct evidence for the hypothesis that in human cells the repair of UV-damaged DNA is initiated by an incision step, and that this step is defective in cells from patients having Xeroderma pigmentosum (XP). The alkaline sucrose gradient centrifugation technique was used to detect breaks in the DNA.A decreased sedimentation velocity of the DNA was found after exposure of normal and XP cells to high doses of UV (5000 erg/mm²). Breaks were induced in the DNA by the UV irradiation without the action of an enzyme. After exposure of both types of cell to UV doses of 100–500 erg/mm², breaks that might occur by enzymic incision were not observed, possibly because of immediate rejoining.After single-strand breaks had been induced by X-rays, rejoining did not occur at temperatures lower than 22°. Rejoining was inhibited by KCN, 2,4-dinitrophenol, EDTA, iodoacetate and crystal violet. Actinomycin D, acriflavine and phleomycin, also tested as potential inhibitors of the repair process, induced breaks or conformational changes in the DNA of unirradiated normal and XP cells.Application to UV-exposed cells of conditions that inhibit the rejoining of breaks did not cause accumulation of breaks in the DNA. The results suggest a coordinated and sequential performance of the steps in the repair of each UV lesion by repair enzymes which may act as a complex.     

Quantitative trait loci x maternal cytoplasmic environment interaction for development rate in Oncorhynchus mykiss

Effects of maternal cytoplasmic environment (MCE) on development rate in rainbow trout were evaluated within a quantitative trait loci (QTL) analysis framework. Previous research had identified QTL for development rate in doubled haploid (DH) progeny produced from a cross between the Oregon State University (OSU) and the Swanson (SW) River rainbow trout clonal lines. In this study, progeny for QTL mapping were produced from a cross between the OSU and Clearwater (CW) River clonal lines. Doubled haploids were produced from the OSU x CW F1 by androgenesis using eggs from different females (or MCEs); with androgenesis, the maternal nuclear genome was destroyed by irradiation and diploidy was restored by blocking the first embryonic cleavage by heat shock. All embryos were incubated at the same temperature and development rate quantified as time to hatch. Using a linkage map constructed primarily with AFLP markers, QTL mapping was performed, including MCE covariates and QTL x MCE effects in models for testing. The major QTL for development rate in the OSU x SW cross overlaps with the major QTL found in this OSU x CW cross; effects at this locus were the same across MCEs. Both MCE and QTL x MCE effects contribute to variability in development rate, but QTL x MCE were minor and detected only at small-effect QTL.     

Abortive second meiosis detected in cytochalasin-treated eggs in androgenetic diploid Corbicula fluminea

The hermaphroditic diploid clam Corbicula fluminea reproduces by androgenesis. In the control (androgenetic development), all maternal chromosomes and maternal centrosomes at the meiotic poles were extruded as two first polar bodies and subsequently second meiosis did not occur. In eggs treated with cytochalasin D (CD) to inhibit the polar body extrusion, the second meiosis was abortive. After the first meiosis, two centrosomes at the spindle poles remained in the cytoplasm because of the effect of CD. The chromosomes divided into two groups at anaphase-I as observed in the control eggs. Two centrosomes divided into four just after the first meiosis but did not separate completely. The microtubules from the centrosomes were rather short. So at the second meiosis, two monoasters or tetrapolar spindles were formed. The fluorescence signal from microtubules of the monoaster or tetrapolar spindle was weak compared with the spindle at the first meiosis. The maternal chromosomes on the monoaster or tetrapolar spindle did not move, and became large female pronuclei. The pronuclei became the metaphase chromosomes on the spindle for the first cleavage. The present study suggests that second meiosis regulating factors may be abortive in androgenetic diploid C. fluminea.     

Serum-free microcarrier based production of replication deficient Influenza vaccine candidate virus lacking NS1 using Vero cells

Background

Androgenesis (all-male inheritance) is generally induced by means of irradiating the eggs to inactivate the maternal genome, followed by fertilization with normal sperm. In fish, the conventional technique for induced androgenesis has been applied for rapid fixation to traits, recovery of cryopreserved genotypes, sex-control, etc. A new method of androgenesis that eliminates the need to irradiate the egg was proposed using the loach, Misgurnus anguillicaudatus (a teleost fish).

Results

When the eggs of wild-type females were fertilized with sperm of albino or orange phenotype males and cold-shocked at 0 to 3°C for 60 min duration just after fertilization, generally more than 30% (with a peak of 100%) of the hatched progeny were androgenotes. While a few of them were the normal diploid, most of them turned out to be abnormal haploid. All-male inheritance was verified by the expression of the recessive color trait (albino or orange) and microsatellite genotypes comprising only paternally derived alleles. Nuclear behavior after the cold-shock treatment was traced by microscopic observation of DAPI (4'6-diamidino-2-phenylindole)-stained samples and hematoxylin-eosin stained histological sections, and the extrusion of egg (maternal) nucleus was observed in eggs treated in the optimum timing.

Conclusion

In this paper, we demonstrate that cold-shock treatment (at 0 and 3°C) of loach eggs for 60 min just after fertilization successfully induces androgenetic haploid development. The most likely mechanism of cold-shock induced androgenesis is an elimination of the egg nucleus together along with the second polar body and subsequent development of a decondensed sperm nucleus or male pronucleus.     

Repair Replication and Degradation of Bromouracil-Substituted DNA in Mammalian Cells after Irradiation with Ultraviolet Light

Ultraviolet (UV) light irradiation of HeLa cells in which bromouracil (BU) is substituted for thymine in one strand of the DNA, elicits a number of responses that occur predominantly in the BU strand. A small amount of degradation of both strands occurs, but the BU strand is degraded to a greater extent than the normal strand. Large UV doses (1000 erg/mm²) induce degradation of about 1.7% of the DNA within 6 hr of irradiation of unsubstituted cells; in BU-substituted cells under these conditions about 1.9% of the normal strand is degraded but 17.5% of the BU strand. After irradiation fresh bases are inserted into the BU strands at infrequent intervals throughout the DNA and this is presumed to represent repair of UV damage in the BU strands. After 1000 erg/mm² the majority (70%) of the thymidine incorporated enters the BU strand. Inhibitors of normal DNA synthesis, hydroxyurea and arabinosyl cytosine, do not appear to inhibit the repair of DNA. The increased sensitivity of mammalian cells that contain BU to irradiation may consequently be due to damage of the BU strand. A specific interference between BU and repair of DNA which leads to large amounts of DNA degradation in bacteria, does not seem to be important in the sensitization of mammalian cells with BU.     

Effects of Ultraviolet and X-Ray Radiation on in vitro Cultivated Cells of Haplopappus gracilis

A cell strain of Haplopappus gracills was used for investigations of the effects of UV (2537 A) and X-ray irradiation. Mitotic inhibition and killing after UV exposure were studied. A survival curve of UV treated and then plated cells is presented. The LD₅₀ seems to be about 2000 erg. mm^?2 under the experimental conditions used. All types of chromosome aberrations are induced by UV irradiation, but the frequency is relatively low at doses which do not completely inhibit cell division. A mutant strain of chromosome type is isolated after UV treatment and then plating. Mitotic inhibition and killing after X-ray treatment were studied. A survival curve is presented and the LD₅₀ under the culture conditions used seems to be about 2000 R. The frequency of chromosome aberrations induced by X-rays is highly increased by aeration during X-ray treatment which indicates that some degree of cell anoxia exists in a cell suspension. There arr indications that chromosome aherrations may not cause growth inhibition to such an extent as is usually believed.     

Paternal chromosome incorporation into the zygote nucleus is controlled by maternal haploid in Drosophila

maternal haploid (mh) is a strict maternal effect mutation that causes the production of haploid gynogenetic embryos (eggs are fertilized but only maternal chromosomes participate in development). We conducted a cytological analysis of fertilization and early development in mh eggs to elucidate the mechanism of paternal chromosome elimination. In mh eggs, as in wild-type eggs, male and female pronuclei migrate and appose, the first mitotic spindle forms, and both parental sets of chromosomes congress on the metaphase plate. In contrast to control eggs, mh paternal sister chromatids fail to separate in anaphase of the first division. As a consequence the paternal chromatin stretches and forms a bridge in telophase. During the first three embryonic divisions, damaged paternal chromosomes are progressively eliminated from the spindles that organize around maternal chromosomes. A majority of mh embryos do not survive the deleterious presence of aneuploid nuclei and rapidly arrest their development. The rest of mh embryos develop as haploid gynogenetic embryos and die before hatching. The mh phenotype is highly reminiscent of the early developmental defects observed in eggs fertilized by ms(3)K81 mutant males and in eggs produced in incompatible crosses of Drosophila harboring the endosymbiont bacteria Wolbachia.     

A search for radioresistance in experimental populations of Drosophila with radiation histories

Human lymphocytes in the G₀ stage were irradiated with UV light and X-rays. A 2-fold increase in the yield of dicentrics was observed in comparison with the yield for X-rays alone. This synergistic effect was constant irrespective of the variation in the UV dose between 50 and 100 erg/mm².The individual chromosomes participated in interchange aberrations as expected from a random distribution per mitotic chromosome length unit. This observation is in contrast with the recent finding that X-ray-induced chromosome-type breakage is preferentially located on chromosomes with relatively large amounts of R-bands. Thus, the present data indicate that the additional breakage points, due to the synergism, had a different distribution between chromosomes from those induced by X-irradiation alone. Mechanisms that could account for the synergistic reaction are discussed.     

Effects of ultraviolet radiation on carotenoid-containing and albino strains of Neurospora crassa

To determine the influence of carotenoids on UV sensitivity of Neurospora crassa conidia, the dose-response curves of 3 albino strains were compared to that of the wild type. In a control experiment the genetic background effects were eliminated by irradiating the wild type in which carotenoid synthesis had been inhibited by β-ionone, and comparing the dose-response curve to that of untreated wild type. All strains used had similar γ-ray survival curves and nuclei per conidium which precluded differences in UV sensitivity due to morphological differences.The albinos and β-ionone-treated strains showed a greater sensitivity (mean LD50 4.35·10³ erg/mm²) to UV irradiation than the wild type (LD50 7.30·10³ erg/mm²).     

The second meiosis occurs in cytochalasin D-treated eggs of Corbicula leana even though it is not observed in control androgenetic eggs because the maternal chromosomes and centrosomes are extruded at first meiosis

The hermaphroditic freshwater clam Corbicula leana reproduces by androgenesis. In the control (androgenetic development), all maternal chromosomes and maternal centrosomes at the meiotic poles were extruded as the two first polar bodies, and subsequently, second meiosis did not occur. But, in C. leana eggs treated with cytochalasin D (CD) to inhibit polar body extrusion, the second meiosis occurred. At metaphase-I, the spindle showed the typical bipolar structure and two spheroid centrosomes were located at its poles. All the maternal chromosomes were divided at anaphase-I, but they were not extruded as polar bodies due to the effects of CD. After completion of first meiosis, the maternal centrosomes split into four. At the second meiosis, twin or tetrapolar spindles were formed and two groups of maternal chromosomes divided into four sets of chromosomes. After the second meiosis, the spindle disassociated and the four maternal centrosomes disappeared. Four groups of maternal chromosomes transformed into the four female pronuclei. Male and female pronuclei became metaphase chromosomes of the first mitosis. The present study clearly indicates that typical meiosis systems still proceed in androgenetic triploid C. leana. We conclude that the androgenetic form may have arisen from the meiotic form.     

UV irradiation of pig metaphase chromosomes: maturation-promoting factor degradation, nuclear cytology and cell cycle progression

Experiments were designed to test two hypotheses. The first was that irradiation of pig metaphase chromosomes would block the normal sequence of cytological and molecular events associated with activation; the second postulated that damaged DNA would prevent eggs from progressing through the first mitotic cleavage cycle. The experimental protocol involved selectively irradiating the metaphase II plate of pig oocytes with highly focused 254 nm ultraviolet (UV) light, followed by activation using standard electroactivation procedures. The following assessments were made of different groups of eggs: (i) nuclear membrane reassembly; (ii) chromosomal cytology; (iii) changes in maturation-promoting factor kinase (MPF kinase) activity at 1 h intervals after activation; and (iv) mitotic progression of eggs containing damaged chromosomal fragments. UV irradiation neither prevented the reassembly of nuclear membranes required for pronuclear formation nor interfered with the normal pattern of MPF kinase degradation after egg activation. UV irradiation did induce a wide range of chromatin defects, including condensation and dispersal of DNA fragments which, in turn, resulted in the formation of micronuclei in the treated eggs and embryos. The presence of damaged DNA retarded, but did not inhibit, progression through the first mitotic cycle. No evidence was obtained that the subsequent mitotic cycle was adversely affected by the presence of UV-damaged DNA. Overall, these results indicate that early cleavage divisions in pig eggs are not blocked by the presence of damaged, hypercondensed chromatin. In this respect, pig eggs are similar to Xenopus eggs, but are different from bovine eggs. On the basis of these findings it is suggested that focused UV irradiation offers a simple and rapid technique for the non-invasive enucleation of pig oocytes provided that the residual hypercondensed chromatin does not affect later developmental stages.     

High efficiency of meiotic gynogenesis in sea lamprey Petromyzon marinus

Induction of androgenesis and gynogenesis by applying a pressure (PS) or heat shock (HS) to double the haploid chromosomal set results in progenies possessing only chromosomes from a single parent. This has never been accomplished in representatives of Agnatha. The objective of this study was to induce gynogenesis and androgenesis in sea lamprey Petromyzon marinus. For gynogenesis experiments, ultraviolet (UV)-irradiated sperm was used to activate sea lamprey eggs and HS or PS were applied to inhibit the second meiotic division and consequently induce diploidy in the embryos. The UV irradiation of immobilized sperm was performed for 1 min at 1,719 J m(-2). HS of 35+/-1 degrees C for 2 min and PS of 9,000 psi for 4 min were applied at different times after egg activation (8, 12, 20, and 24 min or 8, 16, and 24 min for HS or PS, respectively). Regardless of the induction time of the HS, survivals at pre-hatching stage were similar. In contrast, PS applied 8 min after activation appears to increase survival rate of pre-hatched embryos in comparison to 16 and 24 min after activation. In control groups, without shock treatment (no diploidization), there were no survivors. All deformed, gynogenetic embryos were confirmed to be haploids and died prior to burying themselves in the sand. We confirmed by flow cytometry that progenies produced using both shock methods surviving to the next stage, burying in the substrate, were diploid gynogenetic. For the androgenesis experiments, UV-irradiated eggs (1,719 J m(-2) for 1 min) were fertilized with non-treated sperm and HS was applied to restore diploidy of the eggs. Several attempts have been made to optimize the parameters used. HS of 35+/-1 degrees C was applied 110, 140, 170, 200, and 230 min after activation for 2 min. Low yields of androgens were obtained and all animals died within a week after hatching. These techniques will allow to establish meiotic gynogenetic lines of sea lamprey for determining sex differentiation in this species and to analyze its hormonal and environmental regulation.     

Induction of meiotic gynogenesis in Atlantic cod,Gadus morhua (L.)

Gynogenesis is one of several chromosome‐manipulating techniques used in fish. In gynogenesis the male does not contribute to the genetic material of the offspring, and the sperm cells act only as stimulators in order for the egg to start development. This technique has several applications, both in aquaculture and in biological research: gynogenetic fish may be used as a step in the production of all‐female populations, the production of isogenetic‐ and inbred lines, revealing of the sex determination mechanism, construction of genetic maps, and testing of environmental vs genetic control of different traits. The aim of this study was to develop a simple protocol for production of gynogenetic cod (Gadus morhua L.) for further use in aquaculture research. Various milt dilutions and UV‐irradiation doses were tested, in order to inactivate the sperm without destroying its ability to induce egg development. This was followed by pressure treatment of the eggs shortly after ‘fertilization’ to suppress the completion of meiosis II, and thereby restoring diploidy. A dose of 9000 erg mm^?2, followed by a 5‐min pressure treatment (58.6 MPa) 180 min‐degrees after fertilization gave 100% gynogenetic larvae. Histologically, sexual differentiated fish were all females, possibly confirming female homogamety in Atlantic cod. No particular signs of reduced growth, survival or enhanced deformity rates were observed after the fish had reached the juvenile phase. Mortality was, however, high during the egg and larval stages. This protocol has made capable the production of gynogenetic cod juveniles in significant amounts using relatively simple means; the next step will be to elaborate on the technique in order to produce mitotic gynogenetic (double haploid) individuals, which are 100% homozygous.     

Pathways to doubled haploidy: chromosome doubling during androgenesis

Production of doubled haploid (DH) plants through androgenesis induction is a promising and convenient alternative to conventional selfing techniques for the generation of pure lines for breeding programs. This process comprises two main steps: induction of androgenesis and duplication of the haploid genome. Such duplication is sometimes indirectly induced by the treatments used to promote androgenic development. But usually, an additional step of direct chromosome doubling must be included in the protocol. Duplication of the haploid genome of androgenic individuals has been thought to occur through three mechanisms: endoreduplication, nuclear fusion and c-mitosis. In this review we will revise and analyze the evidences supporting each of the proposed mechanisms and their relevance during androgenesis induction, embryo/callus development and plant regeneration. Special attention will be devoted to nuclear fusion, whose evidences are accumulating in the last years.     

A study of beating frequency of a single myocardial cell : II. Ultraviolet micro-irradiation of the nucleus and of the cytoplasm

Single rat myocardial cells were irradiated with the UV micro-irradiation technique over a nuclear or cytoplasmic area of 5 μm of diameter. The contractile response was studied immediately after the irradiation. After 10³ ergs mm⁻² of UV light (254 nm), 4% and 21% of the cells irradiated in the nucleus and the cytoplasm, respectively, showed a temporary increase of the beating rhythm. Moreover, cytoplasmic regions rich in mitochondria were more excitable than other cytoplasmic regions. The ultrastructure and the survival of these cells 24 h after the irradiation did not differ from the control cells. The change of the contractile response according to the localization of the irradiation indicates that the main target organelles are mitochondria; the role of the membrane is not excluded when higher doses of irradiation are considered.