Semen from rainbow trout produced using cryopreserved spermatozoa is more suitable for cryopreservation

Oocytes from three female rainbow trout Oncorhynchus mykiss were inseminated separately with untreated or cryopreserved semen, which had been produced using either untreated (three males) or cryopreserved (three males) spermatozoa. In half of variants, the cryopreservation did not significantly affect fertilization efficiency. Regardless of whether the sperm donors were produced from cryopreserved or intact semen, insemination of oocytes with their intact sperm resulted in the same percentage of eyed embryos (94.4 and 94.3%, respectively). When eggs were inseminated with cryopreserved semen, the use of sperm from males produced with cryopreserved spermatozoa resulted in a significantly higher percentage of eyed eggs than in case of donors produced with intact sperm (89.6 and 81.7%, respectively). The production of rainbow trout using cryopreserved sperm does not appear to negatively affect reproductive abilities of male progeny and semen from donors, which were produced using cryopreserved sperm, is more suitable for cryopreservation than the semen from donors produced with intactspermatozoa.     

Development of a simple method to optimize the conditions for producing gynogenetic offspring, using albino rainbow trout, Salmo gairdneri Richardson, females as an indicator for gynogenesis

Gynogenetic offspring of rainbow trout were produced by means of UV-irradiation of the sperm from a normal male. In order to indicate the destruction of the chromosomes of the sperms, eggs of albinos were used. The gynogenetic offspring showed no pigmentation while normal progeny showed pigmentation.     

Stress reduces the quality of gametes produced by rainbow trout.

In this study we have used the rainbow trout as a model animal to study the biological consequences of stress in terms of gamete quality and quantity. Groups of 30 mature male and female rainbow trout were subjected to repeated acute stress during the 9 mo prior to spawning. Time of ovulation, fecundity, and egg size were recorded in mature females, and sperm counts were carried out on the milt from the male fish, from both the stressed and control groups. Eggs from ovulated females were fertilized with milt from males subjected to the same treatment regime. Approximately 300 eggs from each female were fertilized with a sperm dilution of 10(-3) in diluent. Subsequent development of the fertilized eggs was then monitored. There were no differences in somatic weight or length between the two groups at the end of the experiment, but exposure of rainbow trout to repeated acute stress during reproductive development resulted in a significant delay in ovulation and reduced egg size in females, significantly lower sperm counts in males, and, perhaps most importantly, significantly lower survival rates for progeny from stressed fish compared to progeny from unstressed control fish. Hence, stress reduces the quality of gametes produced by rainbow trout.     

Effects of the pathogenic haemoflagellate, <Emphasis Type="Italic">Cryptobia salmositica</Emphasis> on brood fish, <Emphasis Type="Italic">Oncorhynchus mykiss</Emphasis>

Sexually matured rainbow trout, Oncorhynchus mykiss, were experimentally infected with the pathogenic Cryptobia salmositica. Spawning female trout were more susceptible to cryptobiosis than sexually mature males. Most infected females (seven of nine) with eggs died before or shortly after spawning while all (nine) infected males survived the disease. Also, none of the uninfected females died. Males initially increased milt production and sperm concentration; however semen production declined as the disease progressed. Sperm from infected males fertilized more eggs than those from non-infected males. No differences in weight and survival were observed between progeny of infected and uninfected males.     

BKm minisatellite sequences are not sex associated but reveal DNA fingerprint polymorphisms in rainbow trout

GATA-GACA repetitive sequences first isolated from a female snake (termed BKm sequences) and associated with sex chromosomes in some species were hybridized to DNA from rainbow trout (Salmo gairdneri). Genomic DNA was studied from three groups of rainbow trout: (i) randomly selected males and females from an outbred group, (ii) androgenetic individuals from an inbred strain, and (iii) parents and offspring of an outbred strain. Three restriction enzymes (EcoRI, HaeIII, or HinfI) were used to digest the genomic DNA. The DNA was electrophoresed in agarose gels, transferred to nylon membranes, and the GATA-GACA repetitive sequence probe was hybridized to this DNA. There was no evidence of sex-associated patterns of hybridization with the enzymes used. However, the sequences reveal DNA fingerprint polymorphisms which appear to be inherited in a stable manner.     

Mottled coloration in a rainbow trout is associated with mosaicism for albinism

Within a group of rainbow trout at a commercial farm, a single individual was noted for its mottled yellow and dark skin pigmentation. This female fish was reared to sexual maturity and sublots of its eggs were crossed to rainbow trout males from golden, albino, and wild-type (dark-pigmented) strains. Development in other eggs was activated to produce diploid gynogenetic offspring. Coloration within each progeny group was scored at 10 weeks following initiation of feeding. Mottled coloration was observed in none of the progeny at this time. The phenotypes observed (palomino, albino, and/or wild type) and their proportions within progeny groups indicated that the mottled female was originally heterozygous for albinism. The fish apparently became mosaic for this trait following mutation of the wild-type allele at the albinism locus within a cell(s) early in embryonic development. Curiously, at approximately 6 months after initiation of feeding, mottled coloration became apparent in 2 fish from among 25 progeny of the cross to the golden male. No change in phenotype was noted at this time in 9 gynogenetic progeny nor in 68 progeny from the cross to the albino male. Apparently additional mutations and/or other genetic and regulatory processes affecting coloration came into play during juvenile development of these latter two fish.     

Diploid gynogenesis induced by hydrostatic pressure in rainbow trout, Salmo gairdneri Richardson

Diploid gynogenetic fry of rainbow trout, Salmo gairdneri , were produced by treating eggs activated by UV-irradiated sperm with hydrostatic pressure. Treatments for l0 min at 40 min after activation with 55 000 kPa (8000 psi) pressure resulted in high hatching rates and yields of heterozygous diploid gynogenomes of up to 81%. Attempts to produce homo-zygous diploid gynogenomes by the suppression of the first mitotic division ofthe eggs failed. Ether treatment alone did not induce diploid gynogenesis.     

Clonal Atlantic salmon × brown trout hybrids produced by gynogenesis

Clonal full-sib progeny groups of Atlantic salmon Salmo salar × brown trout Salmo trutta hybrids were produced by gynogenesis. Eggs obtained from two 3-year-old Atlantic salmon (female) × brown trout (male) F₁ hybrids were activated with UV-irradiated rainbow trout Oncorhynchus mykiss sperm. Fecundity, percentage egg activation and percentage survival to completion of yolk-sac absorption were similar for the two females, and averaged 800 eggs kg⁻¹, 90 and 65%, respectively. Flow cytometric and protein electrophoretic analyses confirmed the progeny to be diploid hybrids. Isogenicity within progeny groups and to the maternal parent was indicated by identical DNA fingerprint patterns detected with multilocus oligonucleotide probes–GATA₍₅₎ and ACTG_(n). Isogenicity was also observed in the gynogenetic progeny of a third female spawned the following year. It appeared that a large portion of the oocytes in females of this hybrid underwent a premeiotic chromosome doubling, or possibly a complete suppression of meiosis. The result was ovulation of diploid eggs, each possessing a full set of both Atlantic salmon and brown trout chromosomes identical to those in the maternal somatic cells. Lines of clonal hybrids could therefore be perpetuated by gynogenesis and would have potential both as experimental animals and in commercial aquaculture.     

Production of androgenetic diploid rainbow trout

Haploid androgenesis was induced in rainbow trout (Salmo gairdneri) when eggs were irradiated with 60Co gamma radiation prior to fertilization. Diploidy was restored to the androgenetic haploid zygotes by suppression of first cleavage division using hydrostatic pressure. Peak survival in the androgenetic diploid lots (32.5-38.9 percent of control) occurred when a pressure shock of 9000 pounds per square inch lasting from one to three minutes was applied to the eggs 345 minutes post-fertilization. Chromosomal analysis confirmed diploidy in the androgenetic individuals and suggested that YY rainbow trout are viable to at least the "eyed stage" of development. Inheritance patterns at two loci confirmed all-paternal inheritance. The relatively high yields of completely homozygous androgenetic rainbow trout and the potential for the use of androgenesis in the production of inbred lines and in genetic studies indicate that androgenesis may become a valuable tool in fish research and breeding.     

A genetic test of the mechanism of Wolbachia-induced cytoplasmic incompatibility in Drosophila

Cytoplasmic bacteria of the genus Wolbachia are best known as the cause of cytoplasmic incompatibility (CI): many uninfected eggs fertilized by Wolbachia-modified sperm from infected males die as embryos. In contrast, eggs of infected females rescue modified sperm and develop normally. Although Wolbachia cause CI in at least five insect orders, the mechanism of CI remains poorly understood. Here I test whether the target of Wolbachia-induced sperm modification is the male pronucleus (e.g., DNA or pronuclear proteins) or some extranuclear factor from the sperm required for embryonic development (e.g., the paternal centrosome). I distinguish between these hypotheses by crossing gynogenetic Drosophila melanogaster females to infected males. Gynogenetic females produce diploid eggs whose normal development requires no male pronucleus but still depends on extranuclear paternal factors. I show that when gynogenetic females are crossed to infected males, uniparental progeny with maternally derived chromosomes result. This finding shows that Wolbachia impair the male pronucleus but no extranuclear component of the sperm.     

Androgenesis in rainbow trout using cryopreserved spermatozoa: the effect of processing and biological factors

In addition to producing homozygous lines for biomedical and genomic research and monosex stocks for commercial purposes, androgenesis is the biotechnology considered most promising and reliable for recovering complete nuclear genome information from cryopreserved fish cells. That is because procedures of cryopreserving spermatozoa, contrary to procedures for oocytes or entire eggs, are being well developed. Application of androgenesis in genome banking programs addresses the needs of both the aquaculture industry (safeguard for valuable strains and lines) and natural resource conservation (in vitro protection of endangered species or populations). The present study was focused on successful production of an androgenetic rainbow trout stock using cryopreserved spermatozoa. Our report constitutes the first time a full factorial analysis of processing and biological factors affecting androgenesis efficacy has been presented. Also for the first time, the survival of androgenetic individuals during 2 years of life was recorded. Remarkably high survival rates were observed in one of the two experiments-up to 42.5 +/- 2.8% of hatched larvae, 22.5 +/- 0.1% of swim-up larvae and 10.5% of androgenetic alevins 0.4 g. Mortality rates in androgenetic groups were high especially during the first 6 months. In all, 114 androgenetic individuals (0.9%) survived 2 years. Cryopreservation of spermatozoa generally did not affect androgenesis efficiency significantly, however, this effect was significantly dependent on the method of ploidization shock and on the duration of treatment. Significant interactions were revealed between the irradiation dose and the magnitude of pressure applied, and between the treatment of sperm and duration of pressure shock. Individual variability of spermatozoa donors significantly affected androgenesis efficiency regardless of their genetic (outbred or inbred) origin. Genetic source of the oocytes, contrary to spermatozoa, proved to be an important factor. Following findings of other researchers that androgenesis using cryopreserved spermatozoa is possible, we demonstrated that viable stock could be successfully established from cryopreserved nuclear genome information. Complex statistical analysis of previously developed procedures resulted in information-rich data regarding factorial interactions helpful for developing protocols in genome-restoration programs.     

Genome incompatibility between rainbow trout (<Emphasis Type="Italic">Oncorhynchus mykiss</Emphasis>) and sea trout (<Emphasis Type="Italic">Salmo trutta</Emphasis>) and induction of the interspecies gynogenesis

Rainbow trout (Oncorhynchus mykiss Walbaum) and sea trout (Salmo trutta Linnaeus, 1758) show large karyotypic differences and their hybrid offspring is not viable due to unstable karyotype and chromosome fragmentation. However, gametes from these two species were used to induce gynogenetic development. Rainbow trout eggs activated by UV-irradiated sea trout sperm were subjected to high hydrostatic pressure (HHP) shock to prevent release of the 2nd polar body (early shock) or to inhibit the first cleavage (late shock) in order to produce diploid meiotic gynogenotes and gynogenetic doubled haploids (DHs), respectively. Cytogenetic analysis proved fish that development was induced by the sea trout spermatozoa were rainbow trout. In turn, molecular examination confirmed homozygosity of the gynogenetic DHs. Presumed appearance of the recessive alleles resulted in lower survival of the gynogenetic DH larvae (~25%) when compared to survival of the heterozygous (meiotic) gynogenotes (c. 50%). Our results proved that genomic incompatibilities between studied trout species result in the hybrid unviability. However, artificial gynogenesis including activation of rainbow trout eggs with UV-irradiated sea trout spermatozoa was successfully induced. As both species are unable to cross, application of the UV-irradiated sea trout spermatozoa to activate rainbow trout development assures only maternal inheritance with no contamination by the residues of the paternal chromosomes.     

Chromosome rearrangements and survival of androgenetic rainbow trout (Oncorhynchus mykiss)

The purpose of this work was to quantify the impact of spontaneous and X-radiation-induced chromosome rearrangements on survival rate of androgenetic rainbow trout (Oncorhynchus mykiss). Various doses of X irradiation (50, 150, 250, 350 Gy) were used for inactivation of nuclear DNA in oocytes. After the irradiation, eggs were inseminated with normal sperm from 4 males derived from a strain characterized by Robertsonian rearrangements and length polymorphism of the Y chromosome. The haploid zygotes were exposed to a high hydrostatic pressure (7000 psi) to duplicate the paternal DNA. Neither Robertsonian chromosome polymorphism nor the Y chromosome morphology impaired the viability of the androgenetic embryos and alevins. Moreover, survival of eyed embryos of the androgenetic rainbow trout increased significantly with increasing doses of oocyte X irradiation. After 6 months of rearing, only specimens from the 250 and 350 Gy variants survived. The number of fingerlings with remnants of the maternal genome in the forms of chromosome fragments was higher in the 250 Gy group. Intraindividual variation of chromosome fragment number was observed, and some individuals exhibited haploid/diploid mosaicism and body malformations. Individuals irradiated with less than 250 Gy died, presumably because of the conflict between intact paternally derived chromosomes and the residues of maternal genome in the form of chromosome fragments.     

Mutation in a sex-determining gene in rainbow trout: detection and genetic analysis

In rainbow trout (Oncorhynchus mykiss), the acknowledged sex-determining system is genetic sex determination (GSD) with female homogamety (female symbolXX-male symbolXY). Subsequently, mitotic gynogens are all expected to be females. Unexpected maleness was fortuitously observed in a mitotic gynogenetic family of rainbow trout (13 males out of 27). An equal ratio of males and females suggested the possible segregation of some Mendelian sex-influencing factor. In order to perform a comprehensive analysis of the inheritance and expression of the factor involved, the transmission of maleness was studied across the next three generations, using both conventional and/or meiotic and mitotic gynogenetic offspring. On the whole, males as well as intersexes were observed in crosses between two expected carrier parents, and in gynogenetic offspring of expected carrier females, but not in crosses between one expected carrier parent and one normal XX control. Sex ratios in the different crosses often fitted Mendelian proportions, but not always. Both excess and lack of maleness were observed. The simplest hypothesis consistent with most results is a one-locus model, assuming the existence of a mutation (termed mal) of a sex-determining gene, which is able to override the primary XX mechanism of sex determination and to induce the development of testicular tissue in the gonads of expected XX individuals. The one-locus model requires that the mal mutation usually, but not systematically, behave as a recessive mutation and have a limited penetrance, that is, heterozygous (mal/+) may be sex reversed, homozygous (mal/mal) may remain female, and carrier individuals may undergo partial masculinization alone (many intersexes were recorded). Inconsistency in sex ratios among offspring of parents expected to respond the same way was recorded, indicating that other modifier loci may also be involved. Finally, the occurrence of both males and females in clonal progenies showed that epigenetic factors also likely influence the expression of maleness. The effects of the mal mutation are compared to similar mutations recently described in other fish species. The nature and location of the mal gene (carried by heterochromosomes or an autosomal pair) is briefly discussed in view of the knowledge recently acquired on the subject.     

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.     

Diploid clone produces unreduced diploid gametes but tetraploid clone generates reduced diploid gametes in the Misgurnus loach

Most individuals of the loach Misgurnus anguillicaudatus reproduce bisexually, but cryptic clonal lineages reproduce by natural gynogenesis of unreduced diploid eggs that are genetically identical to maternal somatic cells. Triploid progeny often occur by the accidental incorporation of a sperm nucleus into diploid eggs. Sex reversal from a genetic female to a physiological male is easily induced in this species by androgen treatment and through environmental influences. Here, we produced clonal tetraploid individuals by two methods: 1) fertilization of diploid eggs from a clonal diploid female with diploid sperm of a hormonally sex-reversed clonal diploid male and 2) artificial inhibition of the release of the second polar body in eggs of clonal diploid females just after initiation of gynogenetic development. There is no genetic difference between the clonal diploid and tetraploid individuals except for the number of chromosome sets or genomes. Clonal tetraploid males never produced unreduced tetraploid sperm, only diploid sperm that were genetically identical to those of a clonal diploid. Likewise, clonal tetraploid females did not form unreduced tetraploid eggs, just diploid eggs. However, the eggs' genotypes were identical to those of the original clone, and almost all the eggs initiated natural gynogenesis. Thus, gametogenesis of the clonal tetraploid loach is controlled by the presence of two chromosome sets to pair, thereby preserving the normal meiotic process, i.e., the formation of bivalents and subsequently two successive divisions.     

Gene segregation in induced tetraploid rainbow trout: genetic evidence of preferential pairing of homologous chromosomes

Gene segregation at six protein loci was analysed in progeny from tetraploid males and females obtained by suppression of first mitosis. The triploid full-sib families from five tetraploid males and the diploid gynogenetic lines from four tetraploid females were examined. The proportions of heterozygous gametes (0.83 on the average) were significantly higher than expected from tetrasomic inheritance (0.667) at all the loci studied. This was explained by preferential pairing of homologous chromosomes. The proportions of heterozygous gametes were significantly different between loci, but the variations were not correlated with the gene--centromere distances. Our results showed that, at least for one locus, the homozygous gametes mainly resulted from pairing of homologous chromosomes rather than from pairing of homologous chromosomes, quadrivalent formation, and chromatin exchanges between homologous chromosomes.     

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.     

Induction of diploid androgenetic and mitotic gynogenetic Nile tilapia (Oreochromis niloticus L.)

Androgenesis is a potentially valuable technique for recovering fish from gene banks composed of cryopreserved sperm, developing inbred lines, and analyzing patterns of inheritance. The procedure for producing diploid organisms whose nuclear DNA is wholly of paternal origin is dependent on: (1) the denucleation of host eggs, and (2) the inhibition of the first mitotic division in order to double the haploid sperm chromosome complement following fertilization of host eggs. Denucleation of tilapia (Oreochromis niloticus L.) eggs was carried out using UV irradiation. Treatment durations of 5–8 min (total dose of 450–720 J/m²) produced acceptable yields of viable denucleated eggs [22.9±1.6% (±SE) of controls] as estimated by the survival of haploid androgenetic tilapia to 48 h post-fertilization. Successful mitotic inhibition was accomplished using a heat-shock of 42.5 °C for 3–4 min, applied at 2.5-min intervals from 22.5 to 30 min post-fertilization (mpf). The mean survival of androgenetic diploid fish to yolk-sac absorption for treatment groups varied from 0.4% to 5.3%, relative to the controls. Differences in the suceptibility of eggs from different females to UV irradiation were a significant factor in the overall yield of androgenetic diploids. Paternal effects did not significantly influence the androgenetic yield, suggesting that individual males would not be selected against. For comparative purposes mitotic gynogenetic mitogyne diploids were produced from UV-irradiated sperm. Mean survival to yolk-sac absorption varied from 0.5% to 10.64%, relative to controls. Similar optima for androgenetic and gynogenetic induction were found in the period 25–27.5 mpf (minutes post-fertilization). Induction treatments would appear to be operating on the same developmental events in both these techniques, and the results suggest that the UV irradiations used do relatively little damage to the eggs beyond nuclear inactivation. The results indicate that the production of androgenetic O. niloticus is possible on a consistent basis and that the application of this technique may be useful in quantitative and conservation genetics.     

Dispermic androgenesis in sturgeons with the help of cryopreserved sperm: production of androgenetic hybrids between Siberian and Russian sturgeons

Dispermic androgenesis was used to produce, for the first time, an androgenetic progeny of the Siberian sturgeon (Acipenser baerii) and the androgenetic nuclear cytoplasmic hybrids (Siberian sturgeon, A. baerii x Russian sturgeon, A. gueldenstaedtii) using cryopreserved sperm. Microsatellite DNA analysis confirmed exclusively paternal inheritance in the androgenetic progeny of Siberian sturgeon. Heterozygotes for certain microsatellite loci were detected among the androgenetic hybrids, thereby confirming a dispermic nature of androgenesis. According to the data of comparative morphological analysis, the obtained androgenetic hybrid, by the age of 15 months old, was completely identical to the paternal species. Both a female and a male were detected in the androgenetic sturgeon progenies, which is of interest for producing bisexual progenies via androgenesis. The data of this study confirm the feasibility of dispermic androgenesis using cryopreserved sperm to preserve and recover the gene pools of endangered sturgeon species.