Genetic relationships among emu populations in Japanese farms based on mitochondrial and microsatellite DNA polymorphisms.

Emus (Dromaius novaehollandiae) are expected to become a novel poultry species for producing eggs, meat, and oil. In our previous studies, Japanese emu populations were predicted to have reduced genetic diversity through inbreeding. For a sustainable emu industry in Japan, it is necessary to understand the current genetic structure and relationships in dispersed farms. In this study, we investigated the genetic structure and relationships of six Japanese emu farms based on mitochondrial DNA and microsatellite polymorphisms. We analyzed the DNA sequences of the mitochondrial D-loop region in 157 individuals and detected four haplotypes with four nucleotide substitution sites (Hap-a, Hap-b, Hap-c, and Hap-d). Analysis of molecular variance revealed that 43.6% of total variance was "among population," and the FST value was 0.436 with significant genetic differentiation (P < 0.001). In microsatellite analysis, the expected (HE ) and observed (HO ) heterozygosities were 0.53-0.64 and 0.44-0.59, respectively. Phylogenetic trees and STRUCTURE analysis revealed that the six Japanese farmed emu populations could be divided into four genetically differentiated groups. Therefore, we identified genetic resources that may be useful in extending the genetic diversity of Japanese farms and are predicted to contribute to the conservation and reconstruction of populations.

Gender-Difference in Hair Length as Revealed by Crispr-Based Production of Long-Haired Mice with Dysfunctional FGF5 Mutations.

Fibroblast growth factor 5 (FGF5) is an important molecule required for the transition from anagen to catagen phase of the mammalian hair cycle. We previously reported that Syrian hamsters harboring a 1-bp deletion in the Fgf5 gene exhibit excessive hair growth in males. Herein, we generated Fgf5 mutant mice using genome editing via oviductal nucleic acid delivery (GONAD)/improved GONAD (i-GONAD), an in vivo genome editing system used to target early embryos present in the oviductal lumen, to study gender differences in hair length in mutant mice. The two lines (Fgf5go-malc), one with a 2-bp deletion (c.552_553del) and the other with a 1-bp insertion (c.552_553insA) in exon 3 of Fgf5, were successfully established. Each mutation was predicted to disrupt a part of the FGF domain through frameshift mutation (p.Glu184ValfsX128 or p.Glu184ArgfsX128). Fgf5go-malc1 mice had heterogeneously distributed longer hairs than wild-type mice (C57BL/6J). Notably, this change was more evident in males than in females (p < 0.0001). Immunohistochemical analysis revealed the presence of FGF5 protein in the dermal papilla and outer root sheath of the hair follicles from C57BL/6J and Fgf5go-malc1 mice. Histological analysis revealed that the prolonged anagen phase might be the cause of accelerated hair growth in Fgf5go-malc1 mice.

Carcass traits and fat quality of breeding emu (Dromaius novaehollandiae) in Northern Japan.

Characterization of carcass traits and fat quality is important to effectively produce and genetically improve emus. We investigated carcass traits in 309 emus. The meat production of female emus showed a significantly higher value than that of males (P < 0.01). The fat weight of male (9.232 ± 3.156 kg) was larger than that of the female (7.772 ± 2.697 kg). The fat yield (fat weight per kg of body weight) was strongly correlated to body weight (r = 0.79 and r = 0.75 in male and female, respectively). The fat melting points of females and males were 19.19 ± 3.39°C and 19.39 ± 3.39°C, respectively, without significant difference. Since the fat melting point did not correlate to body and fat weights, we predicted that it was an independent trait from body growth and was highly influenced by genetic elements. Percentages of palmitic, stearic, oleic, linoleic, and α-linolenic acids were 22.27 ± 3.50%, 9.37 ± 1.90%, 54.11 ± 5.17%, 13.54 ± 7.80% and 0.71 ± 0.59%, respectively. Among them, linoleic acid contents showed a wide individual difference (range 0.3-19.9%). The oleic/stearic acid ratio showed a negative correlation to the fat melting point. These results suggest that the fat melting point is a good indicator of C18:1/C18:0 ratio in emu fat.

Effects of post-ovulatory aging on centromeric cohesin protection in murine MII oocytes.

Purpose: Post-ovulatory aging causes a high frequency of aneuploidy during meiosis II in mouse oocytes, irrespective of maternal age. In this study, we evaluated the effects of post-ovulatory oocyte aging on the protection of chromosomal cohesion involved in aneuploidy and verified the relationship between PP2A or SGO2 expression and the phosphorylation level of REC8 in oocytes. Methods: Murine ovulated oocytes were incubated for 6 or 12 h in vitro after collection and denoted as the aged group. The oocytes examined immediately after collection were used as the control group. Immunofluorescent staining was used to detect the localization of PP2A, SGO2, BUB1, AURORA B, and MAD2 in the chromosomal centromere. Immunoblotting was used to quantify the expression of proteins describe above and REC8 in the oocytes. Results: PP2A expression involved in the de-phosphorylation of REC8 decreased over time in oocytes, suggesting a deficiency in PP2A in centromeres. This indicated an increase in the level of phosphorylated REC8, which destabilizes centromeric cohesion in oocytes. In contrast, SGO2 expression was significantly high in aged oocytes. Conclusions: The findings show that post-ovulatory aging destabilizes the centromeric cohesin protection in oocytes and can cause aneuploidy, which is often observed in aged oocytes during meiosis II.

Development of 49 novel microsatellite markers from Next-generation sequencing data and a robust method for parentage tests in the emu (Dromaius novaehollandiae).

The emu is a useful and new breed of poultry, but their genetic improvement has not advanced yet due to their very recent domestication. Pedigree information is difficult to record because of their complex reproduction system (polyandry). To identify parent-offspring relationships in the emu, parentage test based on polymorphic DNA markers have to be developed. In this study, we isolated more than 25,000 microsatellite (simple sequence repeat, SSR) regions from Next-generation sequencing data via the QDD pipeline and developed 49 SSR markers with polymorphism in the Japanese farmed emu. The dinucleotide motifs, (AC)n, (AT)n and (AG)n, were the most frequently detected and were found on 10,167 (38.55%), 8,114 (30.76%) and 4,796 (18.18%) contigs, respectively. Forty-nine novel SSR markers were characterized in 20 individuals and showed NA ranged from 2 to 12, with an average of 4.2. HE/HO ranged from 0.389/0.071 to 0.702/1.000 with an average of 0.601/0.515. PIC value ranged from 0.059 to 0.886 with an average of 0.528, and 17 of 49 markers showed a higher polymorphism than 0.500. Thirty-four individuals were genotyped using 12 markers, and CERVUS simulations based on genotype showed that parents of all offspring were identified with 0.9995-1.0 probability. Thus, 49 novel SSR markers and a robust method for parentage test for the Japanese emu were developed.

Mitochondrial DNA variations in Japanese farmed emu populations.

The emu (Dromaius novaehollandiae) is a new poultry. In this study, we investigated the haplotype composition of mitochondrial DNA among emu populations farmed in Japan. We sequenced the D-loop region in 109 individuals, and detected four substitution sites and three haplotypes (Hap-a, -b, and -c). Hap-a was the most frequently observed haplotype in the Japanese populations. Although Hap-c was a rare haplotype in not only Japanese but also Australian populations, it was detected with high frequency in the Japanese farmed population. The AMOVA indicated that 9% of total variance was "among population". The FST value was 0.087 and genetic differentiation was significant (P<0.01). These results may contribute to conserving the genetic resources available for the Japanese emu industry.

Development and characterization of ten novel microsatellite loci for the emu (Dromaius novaehollandiae) and genetic diversity of Japanese farm populations.

The emu (Dromaius novaehollandiae) is a useful poultry animal farmed for fat, meat, and eggs. Genetic structure and relationships among farmed emu populations in Japan are unknown and the number of microsatellite markers for genetic analysis of the emu is insufficient. In this study, we isolated 16 microsatellites from the emu genome and developed ten new microsatellite markers. These microsatellite markers were used to characterize three farm emu populations in Japan. The number of alleles ranged from 3 to 13 and the expected (HE) and observed heterozygosity (HO) of these microsatellite loci was 0.187-0.802 and 0.179-0.647, respectively. The polymorphic information content ranged from 0.176 to 0.786. Positive inbreeding coefficient (FIS) values were detected in all tested populations, and they ranged from 0.027 to 0.540. These results suggest that farm populations of the emu in Japan resulted from inbreeding. The fixation index (FST) values ranged from 0.026 to 0.061, and phylogenetic trees and population structure analysis confirmed no definitive genetic differentiation among the three populations. Therefore, these populations are at a relatively low level of genetic differentiation at present. The microsatellite markers developed in our study can be utilized for genetic analysis and preservation of genetic resources in the emu.

Destabilization of spindle assembly checkpoint causes aneuploidy during meiosis II in murine post-ovulatory aged oocytes.

Mammalian oocyte quality degrades over time after ovulation in vitro, which can cause fatal defects such as chromosomal aneuploidy. As various oocyte manipulations employed in assisted reproductive technology are time consuming, post-ovulatory aging is a serious problem to overcome in reproductive medicine or ova research. In this study, we investigated the effects of postovulatory aging on the incidence of chromosome aneuploidy during meiosis II, with a focus on the expression of functional proteins from the spindle assembly checkpoint (SAC). Chromosome analysis was used to assess the rate of aneuploidy in in vitro aged oocytes, or in early embryos derived from aged oocytes. Immunofluorescent staining was used to detect the localization of MAD2, which is a SAC signal that monitors the correct segregation of sister chromatids. Immunoblotting was used to quantify cohesin subunits, which are adhesion factors connecting sister chromatids at the metaphase II (MII) centromere. It was shown that post-ovulatory oocyte aging inhibits MAD2 localization to the sister kinetochore. Furthermore, oocyte aging prevented cohesin subunits from being maintained or degraded at the appropriate time. These data suggest that the destabilization of SAC signaling causes sister chromatid segregation errors in MII oocytes, and consequently increases the incidence of aneuploidy in early embryos. Our findings have provided distinct evidence that the post-ovulatory aging of oocytes might also be a risk factor for aneuploidy, irrespective of maternal age.

A 1-bp deletion in Fgf5 causes male-dominant long hair in the Syrian hamster.

Hair length in mammals is generally regulated by the hair cycle, and its disruption leads to abnormal hair morphogenesis in several species. FGF5, one of the hair cycle regulators, has a role in inducing catagen, and that mutation causes abnormal hair length in both sexes in humans, mice, dogs, and cats. Male-dominant long-haired coat (MALC) is an inbred strain of Syrian hamster exhibiting spontaneous long hair in males. After castration, MALC exhibited significantly shorter hair than the control individuals, but testosterone administration to castrated MALC showed reversion to the original phenotype. Moreover, flutamide administration led to MALC phenotype repression. Histological analysis revealed that hair follicle regression was shown in the wild-type 4 weeks after depilation, but that of MALC remained in the anagen phase. We detected a c.546delG of Fgf5 in MALC (Fgf5malc) that might lead to truncation resulting from a frame shift in FGF5 (p.Arg184GlyfsX6). Additionally, homozygous Fgf5malc was only detected in long-haired (Slc:Syrian×MALC)F2 and (J-2-Nn×MALC)F2 progenies, and all homozygous wild and heterozygous Fgf5malc individuals showed normal hair length. Thus, Fgf5malc leads to male-dominant long hair via a prolonged anagen phase which is affected by testosterone in hamsters. To our knowledge, this report is the first to present the sexual dimorphism of hair length caused by the Fgf5 mutation.

Asymmetrical allocation of mitochondrial DNA to blastomeres during the first two cleavages in mouse embryos.

A recent report showed higher oxygen consumption, adenosine triphosphate (ATP) production and mitochondrial localisation in trophectoderm cells than in the inner cell mass of mouse blastocysts. We hypothesised that this phenomenon was due to the asymmetrical distribution of mitochondria in the blastomeres during the earlier stages. Oocytes, 2-cell embryos and 4-cell embryos were analysed to determine the volume, ATP content and mitochondrial DNA (mtDNA) copy number in the whole egg and individual blastomeres. Significant differences were detected in the volumes of cytoplasm and ATP contents between blastomeres from the 2-cell and 4-cell embryos. Moreover, whilst remaining stable in whole embryos, mtDNA copy number differed between blastomeres, indicating that mitochondria in oocytes are unevenly delivered into the daughter blastomeres during the first two cleavages. Although their volume and ATP content were not correlated, there was a significant correlation between volume and mtDNA copy number in 2- and 4-cell blastomeres. These results indicate that the number of mitochondria delivered to blastomeres during early cleavage is not precisely equal, suggesting that the allocation of mitochondria into daughter blastomeres is affected by uneven cytoplasmic distribution during cytokinesis in the oocyte and mother blastomeres.

Characterization of mitochondrial replication and transcription control during rat early development in vivo and in vitro.

In vitro culture (IVC), used in assisted reproductive technologies, is a major environmental stress on the embryo. To evaluate the effect of IVC on mitochondrial transcription and the control of mtDNA replication, we measured the mtDNA copy number and relative amount of mRNA for mitochondrial-related genes in individual rat oocytes, zygotes and embryos using real-time PCR. The average mtDNA copy number was 147 600 (+/-3000) in metaphase II oocytes. The mtDNA copy number was stable throughout in vivo early development and IVC induced an increase in mtDNA copy number from the 8-cell stage onwards. Gapd mRNA levels vary during early development and IVC did not change the patterns of these housekeeping gene transcripts. Polrmt mRNA levels did not vary during early development up to the morula stage but increased at the blastocyst stage. IVC induced the up-regulation of Polrmt mRNA, one of the key genes regulating mtDNA transcription and replication, at the blastocyst stage. An increase in mt-Nd4 mRNA preceded the blastocyst-related event observed in nuclear-encoded Gapd and Polrmt, suggesting that the expression of mitochondrial encoded genes is controlled differently from nuclear encoded genes. We conclude that the IVC system can perturb mitochondrial transcription and the control of mtDNA replication in rat embryos. This perturbation of mtDNA regulation may be responsible for the abnormal physiology, metabolism and viability of in vitro-derived embryos.

Susceptibility of mink (Mustera vision)-derived cells to replication by human immunodeficiency virus type 1.

In vivo studies for understanding viral transmission and replication, host immune responses, and pathogenesis of human immunodeficiency virus type 1 (HIV-1) infection would greatly benefit from the establishment of a small-animal model. In this study, we explored the potential of American mink (Mustera vison) as a susceptible host. We found that primary cells and cell lines derived from this species efficiently supported trans-activation of the HIV-1 long terminal repeat by Tat. Accordingly, the cysteine residue at position 261, which has been shown to be important for interaction of the human cyclin T1 with the HIV-1 regulatory protein Tat, is conserved in the mink homologue. No species-specific defect in Rev function could be detected in mink cells. In addition, primary splenocytes, fibroblasts, and the Mv.1.Lu cell line from American mink supported early as well as late HIV-1 gene expression following infection with vesicular stomatitis G protein-pseudotyped HIV-1 viruses, at levels comparable to those seen with permissive human cells. Furthermore, the mink Mv.1.Lu cell line stably expressing human CD4 and CCR5 receptors supported a spreading HIV-1 infection with few, if any, deficiencies compared to findings in human cell lines. This indicates the potential of HIV-1 to replicate in these cells once the blockade at the stage of virus entry has been removed. These results clearly show that cells from American mink generally pose no functional intracellular block to HIV-1 replication, and collectively they raise the possibility that this animal species could be engineered to support HIV-1 infection, providing a useful small-animal model for evaluating de novo infection by HIV-1.