Molecular markers for sex determination in papaya (<Emphasis Type="Italic">Carica papaya</Emphasis> L.)

We have developed molecular markers tightly linked to Sex1, the gene that determines plant sex in papaya ( Carica papaya L.). Three RAPD products have been cloned and a portion of their DNA sequenced. Based on these sequences SCAR primers were synthesized. SCAR T12 and SCAR W11 produce products in hermaphrodite and male plants and only rarely in females. SCAR T1 produces a product in all papayas regardless of plant sex. SCAR T12 and SCAR W11 showed no recombination in a population of 182 F2 plants from a 'SunUp' by 'Kapoho' cross. Based on these results a PCR-based technique for rapidly and accurately determining the sex of papaya plants was developed using either W11 or T12 to detect the hermaphrodite or male allele and T1, which amplifies a product regardless of sex type, as a positive control. The sexing technique, using SCAR T12 and SCAR T1 as a positive control, was used to correctly predict hermaphrodite papaya plants in a population of seedlings with an overall accuracy of 99.2%.     

A male and hermaphrodite specific RAPD marker for papaya ( Carica papayaL.)

The random amplified polymorphic DNA (RAPD) technique was used to determine the sex of a dioecious species, Carica papaya L., with three sex types, male, female and hermaphrodite. A 450 bp marker fragment, named PSDM(Papaya Sex Determination Marker), exists in all male and hermaphrodite plants but not in the female plants so far analyzed. The DNA sequence of PSDM exhibited no significant similarity to previously reported sequences. A sequence-characterized amplified region (SCAR) marker, SCARps, was developed from PSDM to determine the sex of papaya. Southern hybridization, using PSDM as a probe, showed that PSDM exists in the male and hermaphrodite genomes, but not in the female genome. This result strongly suggests that PSDM is located on the chromosome region that is specific to the male and the hermaphrodite. SCARps is a suitable marker for the precise and rapid diagnosis of sex in papaya. Received: 1 February 2001 / Accepted: 22 May 2001     

Identification of DNA markers linked to the male sex in dioecious hemp (Cannabis sativa L.)

 A 400-bp RAPD marker generated by a primer of random decamer sequence has been found associated with the male sex phenotype in 14 dioecious cultivars and accessions of hemp (Cannabis sativa L.). The primer OPA8 generates a set of bands, most of which polymorphic among all the individual plants tested, and 1 of which, named OPA8₄₀₀, present in all male plants and absent in female plants. A screening of 167 plants belonging to different genotypes for the association of the OPA8₄₀₀ marker with the sex phenotype revealed that only in 3 cases was the 400-bp band was present in plants phenotypically female; on the contrary, in male plants the band was never missing, while in monoecious plants it was never present. Despite this sex-specific association, the sequences corresponding to OPA8₄₀₀ were present in both staminate and carpellate plants, as revealed by Southern blotting and hybridization with the cloned RAPD band. The RAPD marker was sequenced, and specific primers were constructed. These primers generated, on the same genotypes used for RAPD analysis, a SCAR marker 390 bp in length and male-specific. This SCAR is suitable for a precise, early and rapid identification of male plants during breeding programs of dioecious and monoecious hemp. Received: 16 January 1998 / Accepted: 30 April 1998     

Gender in plants: sex chromosomes are emerging from the fog

Although most plants have flowers with both male and female sex organs, there are several thousands of plant species where male or female flowers form on different individuals. Surprisingly, the presence of well-established sex chromosomes in these dioecious plants is rare. The best-described example is white campion, for which large sex chromosomes have been identified and mapped partially. A recent study presented a comprehensive genetic and physical mapping of the genome of dioecious papaya. It revealed a short male specific region on the Y chromosome (MSY) that does not recombine with the X chromosome, providing strong evidence that the sex chromosomes originated from a regular pair of autosomes. The primitive papaya Y chromosome thus represents an early event in sex chromosome evolution. In this article, we review the current status of plant sex-chromosome research and discuss the advantages of different dioecious models.     

Identification of sex in hop (Humulus lupulus) using molecular markers.

The rapid identification of sex in the dioecious hop (Humulus lupulus) is important for the breeding of this cultivated plant because only unfertilized flowers of the female plants are used as an ingredient in the production of beer. It is thought that a sex-chromosome mechanism controls the development of male or female plants. We have compared pools of male and female plants derived from a hop cross to identify molecular markers associated with the Y or male-specific chromosome. Of 900 functional RAPD primers, 32 revealed fragments specific for male plants that were absent in female plants of this cross. Subsequently, the 32 positive primers were tested on unrelated male and female plants. Three of these 32 primers were specific for the Y chromosome in all lines. The Y-specific product derived from one of these primers (OPJ9) was of low copy in hybridization experiments and predominantly present in male plants. Primers developed from the DNA sequence of this product provide a marker for rapid sex identification in crosses of hop by means of PCR.     

Development of male-specific SCAR marker in date palm (Phoenix dactylifera L.)

Genetics of control mechanisms that underlies sex differentiation in date palm is not known. Sex of the plants becomes known only at the time of first flowering, which takes around 5 years. In comparison, molecular diagnosis (if available/feasible) promises quick and reliable identification of sex types very early when plantlets are growing in seedbeds. To develop such an assay, genomic DNA from 45 individual plants (25 female and 20 male) belonging to different varieties of date palm was subjected to PCR amplification using 100 random amplified polymorphic DNA (RAPD) and 104 intersimple sequence repeat (ISSR) primers. Initially, two bulk genomic DNA samples (each made by pooling DNA from ten male and female plants, separately) were used. A primer showing sex-specific band in bulked samples was further used for amplification of the genomic DNA of the individual samples of that bulk. Only one RAPD primer, OPA-02, amplified a fragment of ~1.0 kb in all the individual samples of male genotypes, whereas this fragment was absent in all the female genotypes. This male-specific fragment was cloned and sequenced (GenBank accession no. JN123357), and a sequence-characterized amplified region (SCAR) primer pair was designed that amplified a 406-bp fragment in both female and male genotypes and a unique fragment of 354 bp in only male genotypes. The SCAR marker was further validated using 25 female and ten male date palm plants belonging to different varieties collected from different locations.     

A male-specific SCAR marker in Calamus simplicifolius, a dioecious rattan species endemic to China

A male-specific SCAR marker (CsMale1) was developed in the dioecious rattan species Calamus simplicifolius. The marker was 509 bp in size and had a GC content of 50.1%. The sequence contained two open reading frames, indicating that CsMale1 represented probably a coding genome region. No highly similar sequence was found within the GenBank database. The SCAR marker could be used for precise and quick identification of plant sex types in C. simplicifolius, especially at very early developmental stages.     

Identification of a male-specific AFLP marker in a functionally dioecious fig,<Emphasis Type="Italic"> Ficus fulva</Emphasis> Reinw. ex Bl. (Moraceae)

A male-specific amplified fragment length polymorphism (AFLP) marker was identified in the functionally dioecious fig species, Ficus fulva. A total of 89 polymorphic fragments from three primer combinations were produced, of which one (246 bp) was present in all males (n=23) and absent in all females (n=24) of two populations. This strong association suggests a tight chromosomal linkage between the AFLP marker and the sex-controlling locus. Further analysis indicated that the marker segregated in open-pollinated progenies from natural populations in a 1:1 ratio (n=156), implying that males are the heterogametic sex. Chromosome preparations showed no evidence for morphologically distinct sex chromosomes. The low frequencies of associated markers argue against a morphologically cryptic non-recombining sex chromosome. The sex-locus is therefore likely to be autosomal. The male-specific AFLP marker was sequenced and converted into a sequence characterised amplified region (SCAR) marker. This SCAR marker produced a fragment of equal size in males and females, suggesting that sequence divergence between male- and female-specific chromosomal regions is low.Publication 3311 NIOO-KNAW Netherlands Institute of Ecology     

Microsatellite (GATA)n reveals sex-specific differences in Papaya

Papaya, an economically important fruit plant, is polygamous in nature. The sex of dioecious papaya plants can be deduced only after they attain reproductive maturity (6–8 months). Normally, 50% of the population in a field is composed of unfruitful male plants and almost 45% of these have to be uprooted at the flowering stage. This unnecessary cultivation of unwanted males leads to wastage of resources, which can be avoided if the sex of the plant is determined at juvenile stage. Morphological and cytological studies conducted so far have failed to differentiate between the various sex forms of papaya. Its dioecious nature, occasional sex-reversal of male flowers and the absence of a heteromorphic pair of sex chromosomes make papaya an interesting system to study sex determination at the molecular level. In the present study, highly informative microsatellite and minisatellite probes were employed to identify sex-specific differences in papaya. Among these, only the microsatellite probe (GATA)₄ demonstrated sex-specific differences in all the cultivars analysed. The diagnostic potential of this microsatellite marker was exploited to sex papaya plants at the seedling stage. This study also indicates that the genetic material of the X and Y chromosomes of papaya is diverging in a sex-specific manner and hence they are in the process of differentiation. Received: 26 February 1999 / Accepted: 25 March 1999     

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.     

Male-specific DNA in the dioecious species Atriplex garrettii (Chenopodiaceae)

The mechanism of sex determination in dioecious species of the genus Atriplex (Chenopodiaceae) has not been determined. This paper reports the discovery of a male-specific DNA fragment in the diploid dioecious species A. garrettii. DNA samples extracted individually from ten male and ten female plants were bulked by sex. Random amplified polymorphic DNA (RAPD) fragments were generated in the two bulks in order to identify markers that were polymorphic between male and female plants. A total of 158 decamer primers were tested. A 2075 base-pair (bp) male-specific DNA fragment generated with the OPAF-14 primer was identified. The fragment was cloned and partially sequenced and 24-mer primers that exclusively amplified this fragment were constructed. When 124 male plants, 126 female plants, and one hermaphroditic plant were tested individually, the male-specific 2075-bp DNA fragment was present in the hermaphrodite and all but one of the male plants, and was absent in all female plants. A smaller DNA fragment (~1800 bp) that was homologous to the 2075-bp fragment was amplified from the single male plant that lacked the 2075-bp fragment. Cytogenetic analysis revealed no apparent heteromorphic sex chromosomes. These observations suggest that sex determination in A. garrettii is genetic, with no evidence of heteromorphic sex chromosomes.     

Identification of Random Amplified Polymorphic DNA Markers Linked to Sex Determination in Calamus simplicifolius C. F. Wei

The random amplified polymorphic DNA (RAPD) molecular marker technique was used to determine the sex of Calamus simplicifolius C. F. Wei In the present study, DNA samples were extracted individually from 10 male and 10 female plants. After a total of 1 040 decamer primers had been tested, an approximate 500-bp male-specific DNA fragment was generated with the S1443 primer. It is feasible to identify sex at the early stages of plant life, which is beneficial for improving breeding programs of this dioecious species. In addition, we have obtained a proper RAPD protocol that is useful for other species of rattan.     

Identification of Random Amplified Polymorphic DNA Markers Linked to Sex Determination in Calamus simplicifolius C. F. Wei.

The random amplified polymorphic DNA （RAPD） molecular marker technique was used to determine the sex of Calamus simplicifolius C. F. Wei In the present study, DNA samples were extracted individually from 10 male and 10 female plants. After a total of 1 040 decamer primers had been tested, an approximate 500-bp male-specific DNA fragment was generated with the S 1443 primer. It is feasible to identify sex at the early stages of plant life, which is beneficial for improving breeding programs of this dioecious species. In addition, we have obtained a proper RAPD protocol that is useful for other species of rattan.     

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.     

Ovine-specific Y-chromosome RAPD–SCAR marker for embryo sexing

An accurate, sensitive, and quick (approximately 3 h) method for determining the sex of ovine embryos was developed using polymerase chain reaction (PCR) primers derived from an ovine-specific Y-chromosome random amplified polymorphic DNA marker ( UcdO43 ). The accuracy and sensitivity of the assay were first tested using genomic DNA from 10 males and 10 females of five different sheep breeds, and then tested using serial dilutions of male-in-female DNA. The assay was 100% accurate in confirming the sex of the individuals and the ovine male-specific fragment was detected in dilutions containing as little as 10 pg of male DNA in 50 ng of female DNA. The assay was also confirmed to be specific for the ovine Y-chromosome as bovine, caprine, porcine, murine, and human DNA did not amplify. The ovine embryo sexing method is a duplex PCR system that also includes ZFY/ZFX primers. ZFY/ZFX provide an internal positive control for amplification as well as a means to confirm the results obtained with the UcdO43 primers. All embryo sexing results (36/36) from our method were in agreement with the ZFY/ZFX assay results. However, while our method requires an internal control to detect PCR failure, it has the advantages of not requiring nested PCR or restriction endonuclease digestion of the PCR product, and concerns about cross-species contamination are eliminated.     

Discovery of the human homolog of sex-determining region (SRY) gene in dioecious plants

Sex determination in the early developmental stages of dioecious crops is economically-beneficial. During this study, a human homology of SRY gene was successfully identified in dioecious crops. SRY gene sequences of date palm and jojoba were submitted to GenBank under the accession numbers KC577225 and MK991776, respectively. This is the first report regarding the novel sex-determination methodology of four dioecious plants (jojoba, date palm, papaya, and pistachios). SRY sex gene was found in all the tested dioecious plant and human samples. This novel approach is simple and of significant importance for breeders. It facilitates the unambiguous selection of jojoba and date palm female plants at an early age and reduces the plantation cost of cultivating non-productive male plants. This is a rapid sex-determination technique for dioecious plants and mammals at an early stage. This technique specifically targets the SRY sequence that has been comprehensively investigated in humans. The kit development for the SRY-based sex determination of various crops is in progress.     

芦笋雌性特异性片段的克隆和分析(简报)

芦笋(Asparagus officinalis L.)又名石刁柏、龙须菜,系雌雄异株宿根性植物,是重要的经济作物之一。芦笋的性染色体为一对同形的L5染色体,雌性的性染色体为XX,雄性的性染色体为XY。性别决定的多态性是由位于一对L5性染色体上的一个显性基因M决定的[1-3],雌株基因型为隐性纯合子mm,雄株为显性纯合子MM(又称超雄株)或杂合子Mm。在生产上,由于雄株比雌株高产25%以上[4],并具有极强的抗病性和生命力,故雄株特别是超雄株则倍受生产者的青睐,但芦笋雌雄鉴定只有等到种植的第二年待植株开花时才能进行,这就严重影响了芦笋的有目的种植和经济效…     

Identification of a RAPD marker linked to sex determination in Pistacia vera using bulked segregant analysis

The Random Amplified Polymorphic DNA (RAPD) technique was used to amplify DNA segments, with the objective of finding markers linked to sex determination in the dioecious species, Pistacia vera. Progenies from two female parents pollinated by a common male parent were studied. Two bulks of DNA were made in each cross, one from males and one from females, by pooling an equal weight of fresh leaves from each individual contributing to the bulk prior to DNA extraction. DNA was extracted from each bulked sample and from each of the contributing individuals. DNA was also extracted from 14 cultivars of P. vera and from 94 open-pollinated, fewweeks-old P. vera seedlings of unknown sex. Seven hundred different decamer oligonucleotide primers were used to perform DNA amplification, with 1 of these (OPO08) producing a 945 bp amplification band that was present only in the bulked female samples and absent in the bulked male samples of the two crosses. The relationship between band presence and female sex expression was conserved in every individual obtained from the two crosses and in the 14 cultivars unrelated to the crosses. We propose that this band is tightly linked to the gene(s) that control sex determination in pistachio. The OPO08₉₄₅ RAPD marker could be used in a breeding program to screen the gender of pistachio plants long before they reach reproductive maturity, resulting in considerable savings of time and economic resources. In order to verify that assumption we screened 94 additional seedlings with the OPO08 primer and obtained results consistent with a 11 male:female ratio.     

Identification of sex in Simmondsia chinensis (Jojoba) using RAPD markers

Simmondsia chinensis (Link) Schneider, a multipurpose dioecious shrub of arid zones, has emerged as a cash crop. It is being cultivated for its seeds which store liquid wax whose properties are similar to spermaceti (Sperm whale oil), a substitute for petro products and precious high-priced lubricants. Jojoba is a slow-growing desert shrub having a male biased (5:1; male:female ratio) population. Since there is no method available to determine the sex at the seedling stage, current investigations have been carried out to generate a sex-specific random amplified polymorphic DNA (RAPD) marker in jojoba which is based on the PCR amplification of random locations in the genome of plant. Of the 72 primers tested, only one random decamer primer, OPG-5, produced a unique ∼1,400 base pairs fragment in male DNA. To validate this observation, this primer was re-tested with the individuals of male and female samples of four cultivars. The unique ∼1,400 bp fragment was present in male individuals of all the four cultivars and completely absent in respective female individuals tested. To the best of our knowledge, this is the first report to ascertain the sex of jojoba plants at an early stage of development of the taxon.     

CHARACTERIZATION OF GENETIC MARKERS LINKED TO SEX DETERMINATION IN THE HAPLOID‐DIPLOID RED ALGA GRACILARIA CHILENSIS1

Bulk segregant analysis, random amplified polymorphic DNA (RAPD), and sequence characterized amplified region (SCAR) methods were used to identify sex‐linked molecular markers in the haploid‐diploid rhodophyte Gracilaria chilensis C. J. Bird, McLachlan et E. C. Oliveira. One hundred and eighty 10 bp primers were tested on three bulks of DNA: haploid males, haploid females, and diploid tetrasporophytes. Three RAPD primers (OPD15, OPG16, and OPN20) produced male‐specific bands; and one RAPD primer (OPD12), a female‐specific band. The sequences of the cloned putative sex‐specific PCR fragments were used to design specific primers for the female marker SCAR‐D12‐386 and the male marker SCAR‐G16‐486. Both SCAR markers gave unequivocal band patterns that allowed sex and phase to be determined in G. chilensis. Thus, all the females presented only the female band, and all the males only the male band, while all the tetrasporophytes amplified both male and female bands. Despite this sex‐specific association, we were able to amplify SCAR‐D12‐386 and SCAR‐G16‐486 in both sexes at low melting temperature. The differences between male and female sequences were of 8%–9% nucleotide divergence for SCAR‐D12‐386 and SCAR‐G16‐486, respectively. SCAR‐D12‐386 and SCAR‐G16‐486 could represent degenerated or diverged sequences located in the nonrecombining region of incipient sex chromosomes or heteromorphic sex chromosomes with sequence differences at the DNA level such that PCR primers amplify only one allele and not the other in highly specific PCR conditions. Seven gametic progenies composed of 19 males, 19 females, and the seven parental tetrasporophytes were analyzed. In all of them, the two SCAR markers segregated perfectly with sexual phenotypes.