Isolation of sex-specific AFLP markers in Spotted Halibut (<Emphasis Type="Italic">Verasper variegatus</Emphasis>)

Spotted Halibut (Verasper variegatus) is a commercially important marine fish species. In the present study, to isolate sex-specific markers in Spotted Halibut, we screened the genomes of Spotted Halibut by AFLP technique with 64 different primer combinations. Two primer combinations, MseI-CAG/EcoRI-ACC and MseI-CAT/EcoRI-AGG, produced a female-specific fragment in all females (n = 88) and in no males (n = 60, except 3 individuals), respectively. Both fragments were excised from the gel, cloned and characterized. The first fragment (named VevaF533) was 533 bp long, while the length of the second one (named VevaF218) was 218 bp. The two sequences showed no similarity to each other, and to the known sequences existing in the GenBank database using BLASTn. Cross-species amplification showed that the marker VevaF218 is a species-specific marker which is present in Spotted Halibut females but absent in Barfin Flounder (Verasper moseri). So this marker could be used for discriminating unambiguously between Spotted Halibut females and Barfin Flounder. Examination of the patterns of inheritance of VevaF218 in an interspecific hybrid family (V. variegatus ♂×V. moseri ♀) showed a female-specific pattern of inheritance from mother to daughter, implying that the marker VevaF218 is located on the female sex chromosome. This study provides a reliable AFLP-based genetic sexing of Spotted Halibut that could be useful for genetic mapping of the sex chromosomes and identification of sex-linked genes.     

A SCAR MOLECULAR MARKER SPECIFICALLY RELATED TO THE FEMALE GAMETOPHYTES OF SACCHARINA (LAMINARIA) JAPONICA (PHAEOPHYTA)1

PCR amplification was employed to identify female or male gametophyte associated markers in Saccharina japonica (Aresch.) C. E. Lane, C. Mayes et G. W. Saunders (=Laminaria japonica Aresch.). One pair of the primers, P5, was screened from five pairs designed based on a specific sequence (GenBank accession no. AB069714 ) of Marchantia polymorpha Y chromosome, resulting in a differential band ～500 bp in size between female and male gametophytes of Rongfu strain of S. japonica. According to the SCAR (sequence‐characterized amplified regions) strategies, one pair of primers, P51, was designed on the basis of the sequence of this band that was only present in female gametophytes. A SCAR marker, designated FRML‐494 (494‐bp Female‐Related Marker of S. japonica, GenBank accession no. EU931619 ), was developed successfully by PCR amplification using the designed P51 primer pair. The SCAR marker was verified to be present only in female gametophytes of another variety 901 of this kelp that was a hybrid between S. japonica as paternal and S. longissima (Miyabe) C. E. Lane, C. Mayes, Druehl et G. W. Saunders (=Laminaria longissima Miyabe) as maternal, suggesting that the FRML‐494 marker was specifically related to female gametophytes of the genus. This marker is the first molecular tool reported for sex identification in kelps. This study was beneficial for identifying gametophyte gender during vegetative growth and for judging whether the monogenetic sporophytes came from exclusive male or female gametophytes, as well as for further research on sex determination at the molecular level in kelps.     

Genetic linkage maps of barfin flounder (<Emphasis Type="Italic">Verasper moseri</Emphasis>) and spotted halibut (<Emphasis Type="Italic">Verasper variegatus</Emphasis>) based on AFLP and microsatellite markers

Barfin flounder (Verasper moseri) and spotted halibut (Verasper variegatus) are two economically important marine fish species for aquaculture in China, Korea and Japan. Construction of genetic linkage maps is an interesting issue for molecular marker-assisted selection (MAS) and for better understanding the genome structure. In the present study, we constructed genetic linkage maps for both fish species using AFLP and microsatellite markers based on an interspecific F₁ hybrid family (female V. moseri and male V. variegatus). The female genetic map comprised 98 markers (58 AFLP markers and 40 microsatellite markers), distributing in 27 linkage groups, and spanning 637 cM with an average resolution of 8.9 cM. Whereas the male genetic map consisted of 86 markers (48 AFLP and 38 microsatellite markers) in 24 linkage groups, covering a length of 625 cM with an average marker spacing of 10 cM. The expected genome length was 1,128 cM in female and 1,115 cM in male, and the estimated coverage of genome was 56% for both genetic maps. Moreover, five microsatellite markers were observed to be common to both genetic maps. This is the first time to report the genetic linkage maps of V. moseri and V. variegatus that could serve as the basis for genetic improvement and selective breeding, candidate genes cloning, and genome structure research.     

AFLP-Based Genetic Linkage Maps of the Pacific Oyster <Emphasis Type="Italic">Crassostrea gigas</Emphasis> Thunberg

Amplified fragment length polymorphisms (AFLPs) were used for genome mapping in the Pacific oyster Crassostrea gigas Thunberg. Seventeen selected primer combinations produced 1106 peaks, of which 384 (34.7%) were polymorphic in a backcross family. Among the polymorphic markers, 349 were segregating through either the female or the male parent. Chi-square analysis indicated that 255 (73.1%) of the markers segregated in a Mendelian ratio, and 94 (26.9%) showed significant (P < 0.05) segregation distortion. Separate genetic linkage maps were constructed for the female and male parents. The female framework map consisted of 119 markers in 11 linkage groups, spanning 1030.7 cM, with an average interval of 9.5 cM per marker. The male map contained 96 markers in 10 linkage groups, covering 758.4 cM, with 8.8 cM per marker. The estimated genome length of the Pacific oyster was 1258 cM for the female and 933 cM for the male, and the observed coverage was 82.0% for the female map and 81.3% for the male map. Most distorted markers were deficient for homozygotes and closely linked to each other on the genetic map, suggesting the presence of major recessive deleterious genes in the Pacific oyster.     

菠菜性别相关的ISSR标记

菠菜为雌雄异株植物,用CTAB法提取其雌、雄株成株幼嫩叶片DNA,分别构建雌、雄株DNA池,以之为模板,用已优化的ISSR体系扩增,在74条ISSR引物中,I62扩增出一条约1 200 bp雌性连锁标记,回收纯化该特异扩增片段,将其连接于pUCm-T载体,转化进大肠杆菌JM109菌株,并检测及测序。回收克隆和测序后发现该片段全长1 176 bp,富含AT,AT占57.0%。根据测序结果设计1对25 bp的特异引物将这个雌性连锁的ISSR标记转化为稳定性和特异性更好的SCAR标记。该特异引物对随机选取的雌雄菠菜单株进行PCR扩增,在雌株中均有1 176 bp的特异条带,而雄株中均无。此特异条带的获得为菠菜性别相关基因的克隆奠定基础。     

Identification of two markers linked to the sex locus in dioecious <Emphasis Type="Italic">Asparagus officinalis</Emphasis> plants

One hundred decamer primers of random-amplified polymorphic DNA were tested on dioecious Asparagus officinalis plants to identify sex-linked molecular markers. One primer (S368) produced two markers (S368-928 and S368-1178) in female plants. These two DNA markers were identified in 30 male and female plants, respectively, and a S368-928 marker was proved to be linked to the female sex locus. The female-linked S368-928 marker was sequenced and specific primers were synthesized to generate a 928 bp marker of sequence characterized amplified regions (SCAR) in female plants, SCAR₉₂₈. SCAR₉₂₈ could be used to correctly screen homozygous mm female plants of A. officinalis. However, results of Southern blot analysis suggest that the hybridization pattern of S368-928 was presented in both sex plants. This text was submitted by the authors in English.     

An ISSR‐based Approach for the Molecular Detection and Diagnosis of Dwarf Bunt of Wheat,Caused by Tilletia controversa Kühn

Dwarf bunt of wheat, caused by Tilletia controversa Kühn, is an important international quarantine disease in many countries. The objective of this investigation was to develop a diagnostic molecular marker generated from intersimple sequence repeat (ISSR) for rapid identification of T. controversa. A total of 60 primers were tested by ISSR to detect DNA polymorphisms between T. controversa and related species. The primer ISSR818 generated a polymorphic pattern displaying a 952‐ bp DNA fragment specific for T. controversa. The marker was converted into a sequence characterized amplified region (SCAR), and specific primers (TCKSF2/TCKSR2) were designed for use in a PCR detection assay. Its detection limit was 1 ng of DNA, which could be yielded by 1.1 μg of teliospores in a 25‐ μl PCR. Conclusively, a method to distinguish T. controversa from similar pathogenic fungi has been successfully developed based on the use of a SCAR marker.     

Genetic variation in 14 Porphyra lines using restriction site amplified polymorphism (RSAP)

Restriction site amplified polymorphism (RSAP) is a molecular marker technique which just requires a simple polymerase chain reaction to amplify fragments around restriction sites. The RSAP analytic system was set up and applied to Porphyra genetic variation analysis in this study for the first time. Fourteen Porphyra lines were screened by the RSAP analytic system with 30 primer combinations, 12 of which produced stable and reproducible amplification patterns in three repeated experiments. The 12 primer combinations produced 408 amplified fragments, 402 of which (98.53%) were polymorphic, with an average of 33.5 polymorphic fragments for each primer combination, ranging in size from 50 to 500 bp. The 408 fragments were scored one by one and then used to develop a dendrogram of the 14 Porphyra lines with unweighted pair-group method arithmetic average. The genetic distance among these Porphyra lines ranged from 0.10 to 0.50. These Porphyra lines were divided into two major groups at the 0.71 similarity level: one group contained only Porphyra haitanensis lines and the other group contained Porphyra yezoensis lines. In addition, some specific RSAP markers were acquired from each Porphyra line apart from P. yezoensis Yqd-2-1, and five of them were sequenced. One of the specific markers, R1/R3-8₁₁₉ from P. yezoensis Y-9101, was successfully converted into sequence characterized amplification region marker. The result suggested that TRAP was a simple, stable, polymorphic, and reproducible molecular marker technique for the classification and resource protection of Porphyra lines.     

ISSR marker-assisted selection of male and female plants in a promising dioecious crop: jojoba (Simmondsia chinensis)

Simmondsia chinensis (Link) Schneider, a multipurpose and monogeneric dioecious shrub from arid zones, has emerged as a cash crop all over the globe. Its seed propagation poses severe problems due to its male-biased population: the male:female ratio is 5:1. Investigations have been carried out to generate a sex-specific Inter-simple sequence repeat (ISSR) marker for the early detection of male and female plants. Of the 42 primers analysed with a bulk sample of pooled male DNA and a bulk sample of pooled female DNA, only one primer, UBC-807, produced a unique ~1,200 base-pair fragment in the male DNA. To validate this observation, this primer was re-tested with individual male and female samples from eight cultivars. A similar unique ~1,200 bp fragment was present in the male individuals of all eight cultivars and completely absent in the female individuals tested. This is the first report of the use of ISSR markers to ascertain sex in physiologically mature S. chinensis plants.     

A second‐generation genetic linkage map for bighead carp (Aristichthys nobilis) based on microsatellite markers

Bighead carp (Aristichthys nobilis) is an important aquaculture fish worldwide. Genetic linkage maps for the species were previously reported, but map resolution remained to be improved. In this study, a second‐generation genetic linkage map was constructed for bighead carp through a pseudo‐testcross strategy using interspecific hybrids between bighead carp and silver carp. Of the 754 microsatellites genotyped in two interspecific mapping families (with 77 progenies for each family), 659 markers were assigned to 24 linkage groups, which were equal to the chromosome numbers of the haploid genome. The consensus map spanned 1917.3 cM covering 92.8% of the estimated bighead carp genome with an average marker interval of 2.9 cM. The length of linkage groups ranged from 52.2 to 133.5 cM with an average of 79.9 cM. The number of markers per linkage group varied from 11 to 55 with an average of 27.5 per linkage group. Normality tests on interval distances of the map showed a non‐normal marker distribution; however, significant correlation was found between the length of linkage group and the number of markers below the 0.01 significance level (two‐tailed). The length of the female map was 1.12 times that of the male map, and the average recombination ratio of female to male was 1.10:1. Visual inspection showed that distorted markers gathered in some linkage groups and in certain regions of the male and female maps. This well‐defined genetic linkage map will provide a basic framework for further genome mapping of quantitative traits, comparative mapping and marker‐assisted breeding in bighead carp.     

Rapid diagnosis of the invasive species,Frankliniella occidentalis (Pergande): a species‐specific COI marker

The western flower thrips, Frankliniella occidentalis (Pergande) (Thysanoptera: Thripidae), is an invasive species and currently occurs in only a few areas in China. An easy, accurate and developmental‐stage independent method to identify F. occidentalis would be a valuable tool to facilitate pest management decision making and, more importantly, to provide an early warning so actions can be taken to prevent its introduction into non‐infested areas. Morphological identification of thrips adults and, to a lesser extent, of second‐stage larvae is the main method currently available to identify F. occidentalis. Molecular identification, however, can be easily carried out by a non‐thrips‐specialist with a little training. In this study, DNA sequence data [within the mitochondrial cytochrome oxidase I gene (COI)] and polymerase chain reaction (PCR) were utilized to develop a molecular diagnostic marker for F. occidentalis. A primer set and PCR cycling parameters were designed for the amplification of a single marker fragment (340 bp) of F. occidentalis COI mtDNA. Specificity tests performed on 28 thrips species, efficacy tests performed on five immature developmental stages as well as on male and female adults and tests on primer sensitivity all demonstrated the diagnostic utility of this marker. Furthermore, the primer set was tested on seventeen F. occidentalis populations from different countries and invaded areas in China and proved to be applicable for all geographic populations. It was used successfully to clarify the distribution of F. occidentalis in the Beijing metro area. These results suggested that this diagnostic PCR assay provides a quick, simple and reliable molecular technique for the identification of F. occidentalis.     

Isolation of Female-Specific AFLP Markers and Molecular Identification of Genetic Sex in Half-Smooth Tongue Sole (<Emphasis Type="Italic">Cynoglossus semilaevis</Emphasis>)

The sex-specific molecular marker is a useful gene resource for studying sex- determining mechanisms and controlling fish sex. Artificially produced male and female half-smooth tongue sole (Cynoglossus semilaevis) were used to screen sex-specific amplified fragment length polymorphism (AFLPs) molecular markers. The phenotypic sex of 28 tongue soles was determined by histological sectioning of gonads. The AFLP analysis of 15 females and 13 males via 64 primer combinations produced a total of 4681 scorable bands, of which 42.11% and 43.39% of bands were polymorphic in females and males, respectively. Seven female-specific AFLP markers were identified and designated as CseF382, CseF575, CseF783, CseF464, CseF136, CseF618, and CseF305, respectively. One female-specific AFLP marker (CseF382) was amplified, recovered from the gels, cloned, and sequenced (accession no. DQ487760). This female-specific AFLP marker was converted into a single-locus polymerase-chain reaction (PCR) marker of a sequence-characterized amplified region (SCAR). A simple PCR method of using the specific primers was developed for identifying genetic sex of half-smooth tongue sole. PCR products demonstrated that the initial 15 females produced the female-specific band of about 350 bp, but the initial 13 male individuals failed to produce the band. We also investigated the applicability of the PCR primers in other tongue sole individuals. The same female-specific fragment of about 350 bp was found in the additional 59 female individuals, but not in the additional 58 male individuals. This AFLP-based molecular sexing technique may have great application potential in elucidation of sex determination mechanisms and sex control in half-smooth tongue sole.     

Using RAD‐seq to develop sex‐linked markers in a haplodiplontic alga

For many taxa, including isomorphic haplodiplontic macroalgae, determining sex and ploidy is challenging, thereby limiting the scope of some population demographic and genetic studies. Here, we used double‐digest restriction site‐associated DNA sequencing (ddRAD‐seq) to identify sex‐linked molecular markers in the widespread red alga Agarophyton vermiculophyllum. In the ddRAD‐seq library, we included 10 female gametophytes, 10 male gametophytes, and 16 tetrasporophytes from one native and one non‐native site (N = 40 gametophytes and N = 32 tetrasporophytes total). We identified seven putatively female‐linked and 19 putatively male‐linked sequences. Four female‐ and eight male‐linked markers amplified in all three life cycle stages. Using one female‐ and one male‐linked marker that were sex‐specific, we developed a duplex PCR and tested the efficacy of this assay on a subset of thalli sampled at two sites in the non‐native range. We confirmed ploidy based on the visual observation of reproductive structures and previous microsatellite genotyping at 10 polymorphic loci. For 32 vegetative thalli, we were able to assign sex and confirm ploidy in these previously genotyped thalli. These markers will be integral to ongoing studies of A. vermiculophyllum invasion. We discuss the utility of RAD‐seq over other approaches previously used, such as RAPDs (random amplified polymorphic DNA), for future work designing sex‐linked markers in other haplodiplontic macroalgae for which genomes are lacking.     

Population genetic structure of striped mullet, Mugil cephalus, along the coast of China, inferred by AFLP fingerprinting

The striped mullet, Mugil cephalus, is an economically important species for both aquaculture and commercial fisheries in China. In this study, the amplified fragment length polymorphism (AFLP) technique was employed to analyze population genetic diversity and genetic distance between different populations with the aim of elucidating the population structure and gene flow of M. cephalus along the coast of China. A total of 230 fragments with 150–500 bp were identified from 118 individuals by five AFLP primer combinations. The polymorphic loci within populations varied from 46.52% to 64.78%, with an average of 53.91%, and the average heterozygosity from 0.1829 to 0.2282, with an average of 0.2074. The UPGMA phenograms of 118 individuals were constructed based on Dice similarity coefficients and four clusters were recognized. AMOVA analysis revealed that 60.7% of genetic variations were within populations and 39.3% between populations. The estimated genetic distance (φ_ST) value over all polymorphic loci across the six populations was 0.393 (p < 0.0010), indicating a strong population structuring. The pairwise φ_ST value ranged from 0.1112 to 0.5358, with an average of 0.3693. The population pairwise gene flows (average N_m = 0.73) are low. In addition, the result of the Mantel test showed that there was a significant correlation between geographic and genetic distances (r = 0.5434, p = 0.0050). It was speculated that there exist at least four distinct geographic populational subdivisions of M. cephalus along the Chinese coast. This research has provided new molecular data which will aid our understanding of the genetic structure of this species.     

Identification of genetic markers for Korean native cattle (Hanwoo) by RAPD analysis

In order to develop the specific genetic marker for Korean native cattle (Hanwoo), randomly amplified polymorphic DNA (RAPD) analysis of 6 different cattle breeds was attempted by using 38 decamer primers. In comparison of RAPD patterns, two distinctive DNA bands specific for Hanwoo were detected. One was 296 bp of DNA fragment found to be specific only for female Hanwoo when primer GTCCACACGG was employed. In individual analysis of this RAPD marker was observed only in female individuals with the possibility of 85.3%. The other was 521 bp of RAPD marker amplified using TCGGCGATAG and AGCCAGCGAA primers, which showed 83.0% of genetic frequency in 85 male and 68 female individuals tested. Nucleotide sequencing of these genetic markers revealed that 296 bp marker has a short microsatellite-like sequence, ACCACCACAC, and a tandem repeat sequence of microsatellite GAAAAATG in the determined sequence. Two distinctive tandem repeats of microsatellite sequences, AAC and GAAGA, were also appeared in 521 bp DNA marker. In BLAST search, any gene having high homology with these markers was not found     

Identification of a Novel 1033‐Nucleotide Deletion Polymorphism in the Prophage Region of ‘Candidatus Liberibacter asiaticus’: Potential Applications for Bacterial Epidemiology

The prophage/phage region in the genome of ‘Candidatus Liberibacter asiaticus’, an alpha‐proteobacterium associated with citrus Huanglongbing, included many valuable loci for genetic diversity studies. Previously, a mosaic genomic region (CLIBASIA_05640 to CLIBASIA_05650) was characterized, and this revealed inter‐ and intracontinental variations of ‘Ca. L. asiaticus’. In this study, 267 ‘Ca. L. asiaticus’ isolates collected from eight provinces in China were analysed with a primer set flanking the same mosaic region plus downstream sequence. While most amplicon sizes ranged from 1400 to 2000 bp, an amplicon of 550 bp (S550) was found in 14 samples collected from south‐western China. Sequence analyses showed that S550 was the result of a 1033 bp deletion which included the previously known mosaic region. The genetic nature of the deletion event remains unknown. The regional restriction of S550 suggests that the ‘Ca. L. asiaticus’ population from south‐western China is different from those in eastern China. The small and easy‐to‐detect S550 amplicon could serve as a molecular marker for ‘Ca. L. asiaticus’ epidemiology.     

<Emphasis Type="Italic">Brachionus calyciflorus</Emphasis> is a Species Complex: Mating Behavior and Genetic Differentiation Among Four Geographically Isolated Strains

Four geographic strains of B. calyciflorus are investigated regarding their genetic similarity and ability to cross-mate. DNA sequence analysis of the mitochondrial cox1 gene (694 bp) and the nuclear ribosomal ITS region (735 bp) showed that the Florida and Georgia strains were very similar to each other (0.3% sequence divergence for the 1429 bp) and different from the Texas and Australia strains (~7% and 9% sequence divergence for the 1429 bp, respectively). Consistent with this genetic relatedness, cross-copulation occurred only between the Florida and Georgia strains. Thus, B. calyciflorus is a complex of cryptic species. While the Florida, Texas and Australia strains were reproductively isolated from one another, most combinations of cross-strain mating tests showed intense and prolonged male circling behavior following male–female encounters. This suggests that precopulatory male circling and copulation are two separate behaviors that may be controlled by different female chemicals and male coronal receptors. In some cross-strain mating tests, females regularly retracted their corona when circled by a male, indicating that they can recognize ‘foreign’ males and actively interfere with copulation.     

The complete mitochondrial genome analysis of the tiger (<Emphasis Type="Italic">Panthera tigris</Emphasis>)

The complete mitochondrial genomes of five tiger samples from three subspecies (P. t. sumatrae, P. t. altica, and P. t. tigris) were successfully obtained by using 26 specifically designed Panthera-specific primer sets. The genome organization and gene arrangement of the five tiger samples were similar to each other; however polymorphic tandem repeat sequences were observed in the control region (CR). This led to a difference in the genome lengths obtained from these five samples with an average size of 16,994 bp for the five tiger mitochondrial genomes. The nucleotide base composition was on average as follows: A, 31.8%; T, 27.0%; C, 26.6%; G, 14.6% and exhibited compositional asymmetry. Most of tiger mitochondrial genome characteristics are similar to those of other common vertebrate species; however, some distinctive features were observed in the CR. First, the repetitive sequence 2 (RS 2) contained two repeat units of 80 bp and the first 15 bp of what would be the third repeat motif. The repetitive sequence 3 (RS 3) contained 47–50 repeat motifs of a shorter 8 bp (ACGTAYAC)_n. Second, length heteroplasmy polycystosine (poly-C) stretches was observed at the end of the HV I locus in all tiger samples.     

Using RAD‐seq to recognize sex‐specific markers and sex chromosome systems

Next‐generation sequencing methods have initiated a revolution in molecular ecology and evolution (Tautz et al. 2010 ). Among the most impressive of these sequencing innovations is restriction site‐associated DNA sequencing or RAD‐seq (Baird et al. 2008 ; Andrews et al. 2016 ). RAD‐seq uses the Illumina sequencing platform to sequence fragments of DNA cut by a specific restriction enzyme and can generate tens of thousands of molecular genetic markers for analysis. One of the many uses of RAD‐seq data has been to identify sex‐specific genetic markers, markers found in one sex but not the other (Baxter et al. 2011 ; Gamble & Zarkower 2014 ). Sex‐specific markers are a powerful tool for biologists. At their most basic, they can be used to identify the sex of an individual via PCR. This is useful in cases where a species lacks obvious sexual dimorphism at some or all life history stages. For example, such tests have been important for studying sex differences in life history (Sheldon 1998 ; Mossman & Waser 1999 ), the management and breeding of endangered species (Taberlet et al. 1993 ; Griffiths & Tiwari 1995 ; Robertson et al. 2006 ) and sexing embryonic material (Hacker et al. 1995 ; Smith et al. 1999 ). Furthermore, sex‐specific markers allow recognition of the sex chromosome system in cases where standard cytogenetic methods fail (Charlesworth & Mank 2010 ; Gamble & Zarkower 2014 ). Thus, species with male‐specific markers have male heterogamety (XY) while species with female‐specific markers have female heterogamety (ZW). In this issue, Fowler & Buonaccorsi ( 2016 ) illustrate the ease by which RAD‐seq data can generate sex‐specific genetic markers in rockfish (Sebastes). Moreover, by examining RAD‐seq data from two closely related rockfish species, Sebastes chrysomelas and Sebastes carnatus (Fig.  1 ), Fowler & Buonaccorsi ( 2016 ) uncover shared sex‐specific markers and a conserved sex chromosome system.