Kaikun Luo

Biological characteristics of an improved triploid crucian carp

An improved triploid crucian carp (ITCC) was produced by crossing improved tetraploids (G1×AT, ♂) with improved red crucian carp (IRCC, ♀), which were obtained by distant crossing and gynogenesis. The biological characteristics of ITCC, including the number and karyotype of chromosomes, gonadad and pituitary structures, phenotype, and growth rate are reported. ITCC possessed 150 chromosomes with the karyotype 33m+51sm+33st+33t. In the breeding season, both ovary-like and testis-like gonads of ITCC were unable to produce normal mature gametes. The ultrastructure of the pituitary of ITCC showed that most of the endocrine granules in gonadotrophic hormone (GTH) cells had not been released, providing endocrinological evidence for the sterility of ITCC. Compared with triploid crucian carp (TCC) produced by mating Japanese crucian carp with allotetraploid hybrids, ITCC not only retained the excellent traits of fast growth rate and sterility, but also acquired improved morphological characteristics, including higher body, shorter tail and smaller head.

The fertility of the hybrid lineage derived from female Megalobrama amblycephala × male Culter alburnus.

Distant hybridization can combine together the genomes of different species, which leads to changes of the offspring in phenotypes and genotypes. In this study, we successfully establish a fertile hybrid lineage by intergeneric hybridization of female blunt snout bream (BSB, Megalobrama amblycephala) × male topmouth culter (TC, Culter alburnus) and investigate some important biological traits of this lineage including the morphological traits, chromosomal number, karyotype, DNA content, gonadal development, egg and milt yield, sperm shape and density, fertilization rate and early survival rate. The results show that: (1) the diploid and triploid hybrids coexist in F1 and only diploid hybrids are found in F2, in which the diploid hybrids of F1 and F2 possess 48 chromosomes with one chromosome set of BSB and one chromosome set of TC, and the triploid hybrids of F1 possess 72 chromosomes with two chromosome sets of BSB and one chromosome set of TC. (2) All the tested males and females of the diploid F1 and F2 hybrids have the normal gonadal development and produce mature sperm and egg, respectively, which are fertilized with each other to form F2 and F3 hybrids, respectively, and finally form a diploid hybrid lineage (F1-F3). (3) The good fertility of the F1 and F2 hybrids of female BSB × male TC potentially provides reproductive base to make the hybrid lineage propagate from one generation to another. The formation of the hybrid lineage (F1-F3) also provides an ideal model to research the reproductive rules of distant hybrid progeny.

Genomic incompatibilities in the diploid and tetraploid offspring of the goldfish × common carp cross.

Significance Why is polyploidization rarer in animals than in plants? This question remains unanswered due to the absence of a suitable system in animals for studying instantaneous polyploidization and the crucial changes that immediately follow hybridization. RNA-seq analyses discover extensive chimeric genes and immediate mutations of orthologs in both diploid and tetraploid offspring of the goldfish (♀) × common carp (♂) hybrids. Overall, diploid offspring show paternal-biased expression, yet tetraploids show maternal-biased expression. Some chimeric and differentially expressed genes relate to crucial functions of normal cell cycle activities, and cancer-related pathways in 2nF1. The discovery of fast changes at the levels of chromosomes, genomic DNA, and transcriptomes suggests that allopolyploidization hinders genomic functions in vertebrates, and this conclusion may extend to all animals. Polyploidy is much rarer in animals than in plants but it is not known why. The outcome of combining two genomes in vertebrates remains unpredictable, especially because polyploidization seldom shows positive effects and more often results in lethal consequences because viable gametes fail to form during meiosis. Fortunately, the goldfish (maternal) × common carp (paternal) hybrids have reproduced successfully up to generation 22, and this hybrid lineage permits an investigation into the genomics of hybridization and tetraploidization. The first two generations of these hybrids are diploids, and subsequent generations are tetraploids. Liver transcriptomes from four generations and their progenitors reveal chimeric genes (>9%) and mutations of orthologous genes. Characterizations of 18 randomly chosen genes from genomic DNA and cDNA confirm the chimera. Some of the chimeric and differentially expressed genes relate to mutagenesis, repair, and cancer-related pathways in 2nF1. Erroneous DNA excision between homologous parental genes may drive the high percentage of chimeric genes, or even more potential mechanisms may result in this phenomenon. Meanwhile, diploid offspring show paternal-biased expression, yet tetraploids show maternal-biased expression. These discoveries reveal that fast and unstable changes are mainly deleterious at the level of transcriptomes although some offspring still survive their genomic abnormalities. In addition, the synthetic effect of genome shock might have resulted in greatly reduced viability of 2nF2 hybrid offspring. The goldfish × common carp hybrids constitute an ideal system for unveiling the consequences of intergenomic interactions in hybrid vertebrate genomes and their fertility.

Evidence for the Formation of the Male Gynogenetic Fish

The females and unexpected males of gynogenetic red crucian carps (GRCC) with the 1:1 sex ratio were found in the progeny of the distant crossing of red crucian carp (RCC; ♀, 2n = 100) × blunt snout bream (BSB; ♂, 2n = 48). The females and males of GRCC were fertile, and they mated each other to generate the red crucian carps (GRCC1) and another variational gray crucian carps (GGCC). The GRCC and their offspring were proved to be diploids (2n = 100) with one to three microchromosomes by examining the chromosomal metaphases. The evidences for the male’s genetic effect in GRCC were provided by means of fluorescence in situ hybridization, Sox-HMG DNA markers, and microsatellite DNA markers. The genotypic variances of GRCC resulted in their phenotypic variances which were quite different from their maternal parent. It was concluded that the formation of the male gynogenetic fish in GRCC resulted from the genetic leakage of the paternal fish in the form of the microchromosomes including the paternal male-determining gene. After being activated by the sperm of BSB, which was inactivated and finally degraded but left the microchromosomes, the egg of RCC, in which the 50 chromosomes were spontaneously doubled to 100 chromosomes, developed into the diploid male gynogenetic fish. The formation of the bisexual GRCC and their progeny indicated that the distant hybridization could generate the bisexual diploid gynogenetic fish with genetic variation derived from the paternal fish, which is of great significance in both fish genetic breeding and evolutionary biology.

Novel genetic markers derived from the DNA fragments of Sox genes.

With the pair of degenerate primers designed against the conserved regions of HMG-box of Sox gene family, DNA fragments of different sizes were obtained by amplifying the whole genome DNA samples of many animals, including natural fish, artificial hybrid fish, Aves, reptiles, amphibians and hexapods. Each sample was identified by the specific DNA-band pattern formed by the DNA fragments with defined number and size which marked the samples genetic characteristics. In addition, 50 DNA fragments from 22 kinds of animals were sequenced and comparatively analyzed so as to study their genetic relationships, especially that between artificial hybrids and their original parents. Based on the specific DNA-band pattern and the specific DNA sequence obtained in tissue DNA sample, we established the novel genetic DNA markers derived from the DNA fragments of Sox genes. The present results proved that the novel DNA markers provided fast and accurate markers for different animal phylogenetic branches and that these convenient markers can also distinguish closely related species and hybrids using a single gene family tool.

Formation and biological characterization of three new types of improved crucian carp

The improved tetraploids (G1×AT) were obtained by distant crossing and gynogenesis and the high-body individuals accounted for 2% among G1×AT. After mating with each other, the high-body individuals produced three kinds of bisexual fertile diploid fishes: high-body red crucian carp, high-body fork-like-tails goldfish and gray common carp. The high-body red crucian carp mating with each other formed three types of improved crucian carp (ICC) including improved red crucian carp (IRCC), improved color crucian carp (ICCC) and improved gray crucian carp (IGCC). The phenotypes, chromosome numbers, gonadal structure and fertility of the three kinds of ICC and their offspring were observed. All the three kinds of ICC possessed some improved phenotypes such as higher body, smaller head and shorter tail. The ratios of the body height to body length of IRCC, ICCC and IGCC were 0.54, 0.51 and 0.54, respectively. All of them were obviously higher than that of red crucian carp 0.41 (P<0.01). Three kinds of ICC had the same chromosome number as red crucian carp with 100 chromosomes. All the ICC possessed normal gonads producing mature eggs or sperm, which was important for the production of an improved diploid population. Compared with red crucian carp, all the ICC had stronger fertility such as higher gametes production, higher fertilization rate and higher hatchery rate. Three types of improved diploid fish population were generated from the three kinds of ICC by self-crossing, respectively. The ICC can serve as ornamental fish and edible fish. They are also ideal parents to produce triploids by mating with tetraploids. The new ICC plays an important role in biological evolution and fish genetic breeding.

Evidence of Different Ploidy Eggs Produced by Diploid F2 Hybrids of Carassius auratus (♀) × Cyprinus carpio (♂)

Based on the presence of three types of eggs with different diameters 0.13, 0.17 and 0.2 cm, we made two crosses: F2 (♀) × diploid red crucian carp (♂), and F2 (♀) × F10 tetraploid (♂). The ploidy levels of the progeny of the two crosses were examined by chromosome counting and DNA content measurement by flow cytometer. In the offspring of the former cross, tetraploids, trip-loids, and diploid were obtained. In the progeny of the latter cross, tetraploids and triploids were observed. The production of the different ploidy level fish in the progeny of the two crosses provided a further evidence that F2 might generate triploid, diploid and haploid eggs. The presence of the male tetraploid found in F2 (♀) × diploid red crucian carp (♂) suggested that the genotype of XXXY probably existed in the tetraploid progeny. The gonadal structures of the tetraploids and triploids indicated that both female and male tetraploids were fertile and the triploids were sterile. We concluded that the formations of different ploidy level eggs from F2 were contributed by endoreduplication and fusion of germ cells.

Evidence for the evolutionary origin of goldfish derived from the distant crossing of red crucian carp × common carp.

BackgroundDistant hybridization can generate transgressive hybrid phenotypes that lead to the formation of new populations or species with increased genetic variation. In this study, we produced an experimental hybrid goldfish (EG) by distant crossing of red crucian carp (Carassius auratus) × common carp (Cyprinus carpio) followed by gynogenesis.ResultsWe evaluated the phenotype, ploidy level, gonadal structure, and 5S rDNA of the EG. Diploid EG possessed a high level of genetic variation, which was stably inherited. In particular, the EG combined transgressive phenotypes, including a forked tail and shortened caudal peduncle, traits that are present in common goldfish. The EG and common goldfish share a number of morphological and genetic similarities.ConclusionsUsing the EG, we provide new evidence that goldfish originated from hybridization of red crucian carp × common carp.

Cell fusion as the formation mechanism of unreduced gametes in the gynogenetic diploid hybrid fish

The gynogenetic diploid hybrid clone line (GDH) derived from red crucian carp (♀ RCC) × common carp (♂ CC) possesses the unusual reproductive trait of producing unreduced diploid eggs. To identify the mechanism underlying this phenomenon, we examined the structure, in vivo developmental process and in vitro dynamic development of the GDH gonad. In summary, compared with RCC and CC, GDH showed certain special straits. First, a high frequency (84.7%) of germ cell fusion occurred in gonadal tissue culture in vitro as observed by time-lapse microscopy. Second, microstructural and ultrastructural observation showed numerous binucleated and multinucleated germ cells in the gonad, providing evidence of germ cell fusion in vivo. By contrast, in the diploid RCC and CC ovaries, neither cell fusion nor multinucleated cells were observed during the development of gonads. Third, the ovary of GDH remained at stage I for 10 months, whereas those of RCC and CC remained at that stage for 2 months, indicating that the GDH germ cells underwent abnormal development before meiosis. This report is the first to demonstrate that cell fusion facilitates the formation of unreduced gametes in vertebrates, which is a valuable finding for both evolutionary biology and reproductive biology.

Different expression patterns of sperm motility-related genes in testis of diploid and tetraploid cyprinid fish†.

Abstract Sperm motility is an important standard to measure the fertility of male. In our previous study, we found that the diploid spermatozoa from allotetraploid hybrid (4nAT) had longer durations of rapid and slow progressive motility than haploid spermatozoa from common carp (COC). In this study, to explore sperm motility-related molecular mechanisms, we compared the testis tissues transcriptomes from 2-year-old male COC and 4nAT. The RNA-seq data revealed that 2985 genes were differentially expressed between COC and 4nAT, including 2216 upregulated and 769 downregulated genes in 4nAT. Some differentially expressed genes, such as tubulin genes, dynein, axonemal, heavy chain(dnah) genes, mitogen-activated protein kinase(mapk) genes, tektin 4, FOX transcription factors, proteasome genes, and ubiquitin carboxyl-terminal hydrolase(uchl) genes, are involved in the regulation of cell division, flagellar and ciliary motility, gene transcription, cytoskeleton, energy metabolism, and the ubiquitin-proteasome system, suggesting that these genes were related to sperm motility of the 4nAT. We confirmed the differential expression of 12 such genes in 4nAT by quantitative PCR. By western blotting, we also confirmed increased expression of Uchl3 in 4nAT testis. In addition, we identified 1915 and 2551 predicted long noncoding RNA (lncRNA) transcripts from testis tissue transcriptomes of COC and 4nAT, respectively. Of these, 1575 lncRNAs were specifically expressed in 4nAT and 939 were specifically expressed in COC. This study provides insights into the transcriptome profile of testis tissues from diploid and tetraploid, which are useful for research on regulatorymechanisms behind sperm motility in male polyploidy. Summary Sentence Clues of variations in tetraploid testis are characterized by comparative transcriptome analysis between tetraploid hybrid and common carp.