Cryopreservation of chicken primordial germ cells by vitrification and slow freezing: A comparative study.

In the present study, we compare a classical slow freezing (SLF) method and an aseptic vitrification (Vitrif) technique to cryopreserve a stable primordial germ cell (PGCs) line issued from the Ardennaise chicken breed. Viability immediately after warming was close to 80% and did not differ between the two cryopreservation methods. Proliferation tended to be slower for both cryopreservation methods compared with controls, but the difference was significant only for Vitrif. No difference was found between the two methods after flow cytometry analysis of stage-specific embryonic antigen-1 expression and reverse transcription-polymerase chain reaction on several factors related to PGC phenotype. After 1 week in culture, all cryopreserved cells reached controls' main morphologic and expanding (viability/proliferation) features. However, SLF generated more unwanted cells clusters than Vitrif. After injection of the PGCs into recipient embryos, vitrified PGCs reported a clear, yet not significant, tendency to colonize the gonad at a higher rate than slow frozen PGCs. SLF in cryovials remains simple, inexpensive, and less technically demanding than Vitrif. Nevertheless, the intrinsic advantages of our aseptic Vitrif method and the present study suggest that this should be considered as safer than classical SLF for cryopreserving chicken PGCs.

Lower intracellular concentration of cryoprotectants after vitrification than after slow freezing despite exposure to higher concentration of cryoprotectant solutions.

STUDY QUESTION: What is the intracellular concentration of cryoprotectant (ICCP) in mouse zygotes during vitrification (VIT) and slow-freezing (SLF) cryopreservation procedures? SUMMARY ANSWER: Contrary to common beliefs, it was observed that the ICCP in vitrified zygotes is lower than after SLF, although the solutions used in VIT contain higher concentrations of cryoprotectants (CPs). WHAT IS KNOWN ALREADY: To reduce the likelihood of intracellular ice crystal formation, which has detrimental effects on cell organelles and membranes, VIT was introduced as an alternative to SLF to cryopreserve embryos and gametes. Combined with high cooling and warming rates, the use of high concentrations of CPs favours an intracellular environment that supports and maintains the transition from a liquid to a solid glass-like state devoid of crystals. Although the up-to-date publications are reassuring in terms of obstetric and perinatal outcomes after VIT, a fear about exposing gametes and embryos to high amounts of CPs that exceed 3-4-fold those found in SLF was central to a debate initiated by advocates of SLF procedures. STUDY DESIGN, SIZE, DURATION: Two experimental set-ups were applied. The objective of a first study was to determine the ICCP at the end of the exposure steps to the CP solutions with our VIT protocol (n = 31). The goal of the second investigation was to compare the ICCP between VIT (n = 30) and SLF (n = 30). All experiments were performed in triplicates using mouse zygotes. The study took place at the GIGA-Research Institute of the University of Liège. PARTICIPANTS/MATERIALS, SETTING, METHODS: Cell volume is modified by changes in extracellular osmolarity. Hence, we estimated the final ICCP after the incubation steps in the VIT solutions by exposing the cells to sucrose (SUC) solutions with defined molarities. The ICCP was calculated from the SUC concentration that produced no change in cell volume, i.e. when intra- and extracellular osmolarities were equivalent. Cell volume was monitored by microscopic cinematography. ICCP was compared between SLF and VIT based on the principle that a high ICCP lowers the probability of (re)crystallization during warming but increases the probability of over-swelling of the cell due to fast inflow of water. The survival rates of mouse zygotes after SLF or VIT were compared using either (i) various warming rates or (ii) various concentrations of SUC in the warming dilution medium. MAIN RESULTS AND THE ROLE OF CHANCE: The ICCP in mouse zygotes during the VIT procedure prior to plunging them in liquid nitrogen was ∼2.14 M, i.e. one-third of the concentration in the VIT solution. After SLF, the warming rate did not affect the zygote survival rate. In contrast, only 3/30 vitrified zygotes survived when warmed slowly but as many as 30/30 zygotes survived when warming was fast (>20 000°C/min). Vitrified zygotes showed significantly higher survival rates than slow-frozen zygotes when they were placed directly in the culture medium or in solutions containing low concentrations of SUC (P < 0.01). These two experiments demonstrate a lower ICCP after VIT than after SLF. LIMITATIONS, REASONS FOR CAUTION: The results should not be directly extrapolated to other stages of development or to other species due to possible differences in membrane permeability to water and CPs. WIDER IMPLICATIONS OF THE FINDINGS: The low ICCP we observed after VIT removes the concern about high ICCP after VIT, at least in murine zygotes and helps to explain the observed efficiency and lack of toxicity of VIT. STUDY FUNDING / COMPETING INTEREST(S): The study was funded by the FNRS (National Funds for Scientific Research). The authors declare that they have no competing interests.

Aseptic vitrification of blastocysts from infertile patients, egg donors and after IVM.

During embryo vitrification, it is advisable that cooling and storage should occur in a carrier device in which there is complete separation of the embryos from liquid nitrogen to ensure asepsis. The consequence of a reduction in the cooling rate resulting from the heat-insulating barrier aseptic devices has to be counteracted by gradually increasing intracellular concentrations of cryoprotectants without inducing a toxic effect. Blastocysts originating from couples with male and/or female factor infertility (group 1) or from oocyte donors (group 2) or from in-vitro matured oocytes (group 3) were gradually exposed to increasing concentrations of dimethylsulphoxide/ethylene glycol (5/5%, 10/10% and 20/20%) before aseptic vitrification using a specially designed carrier (VitriSafe), a modification of the open hemi-straw plug device. A total of 120 aseptic vitrification/warming cycles were performed in group 1, 91 in group 2 and 22 in group 3. Survival rates before embryo transfer, ongoing pregnancy and implantation rates were as follows: for group 1, 73, 43 and 26%; for group 2, 88, 53 and 34%; and for group 3, 69, 50 and 38%, respectively. In spite of reduced cooling rates due to aseptic vitrification conditions, a three-step exposure to cryoprotectant solutions protects the embryos effectively from cryo-injuries and guaranties high survival rates.

Myostatin gene deletion prevents glucocorticoid-induced muscle atrophy.

Glucocorticoids mediate muscle atrophy in many catabolic states. Myostatin expression, a negative regulator of muscle growth, is increased by glucocorticoids and myostatin overexpression is associated with lower muscle mass. This suggests that myostatin is required for the catabolic effects of glucocorticoids. We therefore investigated whether myostatin gene disruption could prevent muscle atrophy caused by glucocorticoids. Male myostatin knockout (KO) and wild-type mice were subjected to dexamethasone treatment (1 mg/kg.d for 10 d or 5 mg/kg.d for 4 d). In wild-type mice, daily administration of low-dose dexamethasone for 10 d resulted in muscle atrophy (tibialis anterior: -15%; gastrocnemius: -13%; P < 0.01) due to 15% decrease in the muscle fiber cross-sectional area (1621 +/- 31 vs. 1918 +/- 64 microm(2), P < 0.01). In KO mice, there was no reduction of muscle mass nor fiber cross-sectional area after dexamethasone treatment. Muscle atrophy after 4 d of high-dose dexamethasone was associated with increased mRNA of enzymes involved in proteolytic pathways (atrogin-1, muscle ring finger 1, and cathepsin L) and increased chymotrypsin-like proteasomal activity. In contrast, the mRNA of these enzymes and the proteasomal activity were not significantly affected by dexamethasone in KO mice. Muscle IGF-I mRNA was paradoxically decreased in KO mice (-35%, P < 0.05); this was associated with a potentially compensatory increase of IGF-II expression in both saline and dexamethasone-treated KO mice (2-fold, P < 0.01). In conclusion, our results show that myostatin deletion prevents muscle atrophy in glucocorticoid-treated mice, by blunting the glucocorticoid-induced enhanced proteolysis, and suggest an important role of myostatin in muscle atrophy caused by glucocorticoids.

Convenient genotyping of six myostatin mutations causing double-muscling in cattle using a multiplex oligonucleotide ligation assay.

We herein describe a procedure that allows for simultaneous genotyping of six loss-of-function mutations in the bovine myostatin gene associated with the double-muscling phenotype. The proposed method relies on a multiplex oligonucleotide ligation assay and detection of the fluorescently labelled products using automatic sequencers.

[Positional clonage and characterization of the bovine myostatin gene]. / Clonage positionnel et caractérisation du gène de la myostatine bovine.

The double-muscled condition has been intensively selected for in the Belgian Blue cattle breed, where segregation studies have demonstrated the monogenic, autosomal and recessive determinism. This has been confirmed by genetic linkage which located the gene to the centromeric tip of chromosome 2. Our positional cloning strategy, and the discovery of a positional candidate in the mouse, led us to the identification of the causative gene now referred to as the Myostatin gene, since its product downregulates skeletal muscle mass. Disruptive mutations of the gene in cattle have been shown to be responsible for the muscular hypertrophy found in eight european beef breeds. A 15 Kilobases genomic region, including the myostatin gene, has been sequenced and compared in cattle and mice. The murine gene has undergone a complex genetic engineering in order to test different allelic variants in vivo after gene targeting transgenesis.

High-resolution, human-bovine comparative mapping based on a closed YAC contig spanning the bovine mh locus.

A closed YAC contig spanning the mh locus was assembled by STS content mapping with seven microsatellite markers, eight genes or EST, and nine STS corresponding to YAC ends. The contig comprises 27 YACs, has an average depth of 4.3 YACs, and spans an estimated 1.2 Mb. A linkage map was constructed based on five of the microsatellite markers anchored to the contig and shown to span 7 cM, yielding a ratio of 160 kb/1 cM for the corresponding chromosome region. Comparative mapping data indicate that the constructed contig spans an evolutionary breakpoint connecting two chromosome segments that are syntenic but not adjacent in the human. Consolidation of human gene order by means of whole genome radiation hybrids and its comparison with the bovine order as inferred from the contig confirm conservation of gene order within segments.

Molecular definition of an allelic series of mutations disrupting the myostatin function and causing double-muscling in cattle.

We have determined the entire myostatin coding sequence for 32 double-muscled cattle sampled from ten European cattle breeds. Seven DNA sequence polymorphisms were identified, of which five would be predicted to disrupt the function of the protein, one is a conservative amino acid substitution, and one a silent DNA sequence variant. Four additional DNA sequence polymorphisms were identified in myostatin intronic sequences. In all but two breeds, all double-muscled animals were either homozygous or compound heterozygotes for one of the five loss-of-function mutations. The absence of obvious loss-of-function mutations in the coding sequence of the two remaining breeds points either towards additional mutations in unexplored segments of the gene, or towards locus heterogeneity of double-muscling.

A deletion in the bovine myostatin gene causes the double-muscled phenotype in cattle.

An exceptional muscle development commonly referred to as 'double-muscled' (Fig. 1) has been seen in several cattle breeds and has attracted considerable attention from beef producers. Double-muscled animals are characterized by an increase in muscle mass of about 20%, due to general skeletal-muscle hyperplasia-that is, an increase in the number of muscle fibers rather than in their individual diameter. Although the hereditary nature of the double-muscled condition was recognized early on, the precise mode of inheritance has remained controversial; monogenic (domainant and recessive), oligogenic and polygenic models have been proposed. In the Belgian Blue cattle breed (BBCB), segregation analysis performed both in experimental crosses and in the outbred population suggested an autosomal recessive inheritance. This was confirmed when the muscular hypertrophy (mh) locus was mapped 3.1 cM from microsatellite TGLA44 on the centromeric end of bovine chromosome 2 (ref. 5). We used a positional candidate approach to demonstrate that a mutation in bovine MSTN, which encodes myostatin, a member of the TGF beta superfamily, is responsible for the double-muscled phenotype. We report an 11-bp deletion in the coding sequence for the bioactive carboxy-terminal domain of the protein causing the muscular hypertrophy observed in Belgian Blue cattle.

Microsatellite mapping of the bovine roan locus: a major determinant of White Heifer disease.

In the Belgian Blue Cattle breed, coat color variation is mainly under the influence of a single autosomal locus, the roan locus, characterized by a pair of codominant alleles: r+ (black) and R (white). Heterozygous r+R animals have intermingled black and white hairs, yielding the "blue" phenotype typical of the breed. Major interest for the roan locus stems from its pleiotropic effect on fertility, owing to the critical role of the R allele in the determinism of White Heifer Disease. We describe the linkage mapping of the roan locus to bovine Chromosome (Chr) 5, in the interval between microsatellite markers BPI and AGLA293, with an associated lodscore of 11.2. Moreover, we map a candidate gene, the Steel locus coding for the mast cell growth factor, to bovine Chr 5.

The mh gene causing double-muscling in cattle maps to bovine Chromosome 2.

While the hereditary nature of the "double-muscling" phenotype (a generalized muscular hypertrophy documented in several cattle breeds) is well established, its precise segregation mode has remained controversial. Both monogenic models (autosomal dominant or recessive) and oligogenic models have been proposed. Using a panel of 213 bovine microsatellite markers, and an experimental pedigree obtained by backing "double-muscled (Belgian Blue) x conventional (Friesian)"1 dams to double-muscle sire, we have mapped a locus on bovine Chromosome (CHr) 2 that accounts for all the phenotypic variance in the backcross generation. This locus, referred to as mh (muscular hypertrophy), has been positioned with respects to a map composed of seven Chr 2-specific microsatellites, at 2 cM from the closet marker. This result confirms the validity in the Belgian Blue population of the monogenic model involving an autosomal mh locus, characterized by a wild-type "+" and a recessive "mh" allele, causing the double-muscling phenotype in the homozygous condition. The linkage relationship between the mh locus and the Chr 2 markers was confirmed in three informative pedigrees collected from the general Belgian Blue Cattle population, reinforcing the notice of genetic homogeneity of the double-muscling trait in this breed. This work paves the way towards marker-assisted selection for or against the double muscling trait, and towards positional cloning of the corresponding gene.

Transgenic mice harboring Aujeszky's disease virus gD gene.

Plasmid pMLP10 gp50.5 (gD) (Eloit et al., 1990) provided the sequence to integrate. The construct has been injected into the male pronucleus of one-cell mouse embryos (CBA/C5B1). A total of 1,567 microinjected embryos were transferred into the oviduct of pseudopregnant females (Hogan et al., 1986). PCR revealed that 3 out of 10 mice were born with an integrated construct; among them, 2 mice have integrated the construct in their gonads because 20 out of 107 (18.7%) of their offspring were also transgenic. This low percentage could be explained by germline mosaicism and/or differential mortality between transgenic and non-transgenic embryos.

[Genome diagnosis in domestic animals]. / Diagnostics génomiques chez les animaux domestiques.

Different contributions to the development and applications of genomic diagnosis methods in domestic animals are reported. DNA fingerprints were used to solve parentage disputes in different species, and to reveal leucochimerism in bovine dizygotic twins. In cattle, an embryo sexing method and a freemartinism diagnosis assay were also developed. The search for molecular markers of the MH (muscular hypertrophy) and R (rouan) bovine genes is described. Prion protein gene polymorphisms are investigated in the framework of a research on the genetics of bovine spongiform encephalopathies. The mutation responsible for the autosomal recessive lethal condition BLAD (bovine leucocyte adhesion deficiency) in Holstein cattle is found in our country, and the carries can be detected by a molecular method. The mutation responsible for the halothane sensitivity in pig can also be detected, what is done to control efficiently the introgression of the stress resistance allele in a Piétrain strain.