Intergeneric hybridization between Pleurotus ostreatus and Schizophyllum commune by PEG-induced protoplast fusion

Intergeneric hybridization between Pleurotus ostreatus and Schizophyllum commune was studied using PEG-induced fusion. The fusion of protoplasts from auxotrophic mutant strains resulted in the formation of fusion hybrids in the frequencies of 3.6 to 7.3×10^–5. Most of these fusion hybrids were monokaryotic and sterile and no heterokaryosis occurred. Most fusants showed a significantly higher nuclear DNA content when compared to parental strains and no diploids (parent 1 genome plus parent 2 genome) were found. Some fusion hybrids revealed both parental fragments in nuclear and mitochondrial rDNA PCR profiles. AP-PCR (Arbitrarily-primed Polymerase Chain Reaction) fingerprints also indicated that most of the fusion products were recombinant hybrids.     

Characteristics of fertile somatic hybrids of G. hirsutum L. and G. trilobum generated via protoplast fusion

Fertile somatic hybrids between tetraploid upland cotton G. hirsutum L. cv. Coker 312 and wild cotton G. trilobum were generated by symmetric electrofusion. Comparisons of morphology, combined with flow cytometric, RAPD, SRAP and AFLP analyses confirmed the hybrid nature of the regenerated plants. The hybrids differed morphologically from the parent plants. Flow cytometric analysis showed that the hybrids had DNA similar in amount to the total combined DNA content of the two parents, and the use of molecular markers revealed that the hybrids contained genomic fragments from both fusion parents, further indicating the hybrid nature of the regenerated plants. The stability of the morphological features of the hybrids was examined in following generations. The hexaploid fusion plants showed strong photosynthesis and a high expression level of some photosystem-related genes. Our results suggest that novel traits may be incorporated in cotton breeding programs through the production of somatic hybrids and the backcrossing of these plants with elite cultivars.     

Nuclear and cytoplasmic genome composition of Solanum bulbocastanum (+) S. tuberosum somatic hybrids.

Somatic hybrids between the wild incongruent species Solanum bulbocastanum (2n = 2x = 24) and S. tuberosum haploids (2n = 2x = 24) have been characterized for their nuclear and cytoplasmic genome composition. Cytologic observations revealed the recovery of 8 (near-)tetraploid and 3 hexaploid somatic hybrids. Multicolor genomic in situ hybridization (GISH) analysis was carried out to study the genomic dosage of the parental species in 5 somatic hybrids with different ploidy. The GISH procedure used was effective in discriminating parental genomes in the hybrids; most chromosomes were unambiguously colored. Two (near-)tetraploid somatic hybrids showed the expected 2:2 cultivated-to-wild genomic dosage; 2 hexaploids revealed a 4:2 cultivated-to-wild genomic dosage, and 1 hexaploid had a 2:4 cultivated-to-wild genomic dosage. Characterization of hybrid cytoplasmic genomes was performed using gene-specific primers that detected polymorphisms between the fusion parents in the intergenic regions. The analysis showed that most of the somatic hybrids inherited the plastidial and mitochondrial DNA of the cultivated parent. A few hybrids, with a rearranged mitochondrial genome (showing fragments derived from both parents), were also identified. These results confirmed the potential of somatic hybridization in producing new variability for genetic studies and breeding.     

柑桔细胞电融合再生两个种间体细胞杂种

朋娜脐橙(Citrussinensis Osbeck)胚性细胞悬浮系原生质体分别与粗柠檬(C.jambhiri Lush)、枸头橙(C.aurantium)叶肉原生质体经电场诱导而融合。经培养,两组合均获得再生植株。对朋娜脐橙+粗柠檬的再生胚状体进行染色体计数,随机取样的52个胚状体中,26个为四倍体,另外26个为二倍体;对74棵再生植株进行染色体计数,由此说明都为四倍体;表明体细胞杂种在植株再生过程中具有明显的竞争优势。朋娜脐橙+枸头橙再生的14棵植株都为四倍体。对朋娜脐橙+粗柠檬部分植株进行POX同工酶和RAPD分析,表明所有检测植株都为杂种。朋娜脐橙+枸头橙再生植株经RAPD分析,表明也为杂种。     

Somatic hybridization between Lycopersicon esculentum and Lycopersicon pennellii

Summary Selection and screening methods were devised which resulted in the identification of a number of somatic hybrid callus clones following fusion of Lycopersicon esculentum protoplasts and L. pennellii suspension culture protoplasts. Visual selection for callus morphology combined with a high fusion frequency and irradiation of one parental protoplast type (¹³⁷Cs source, 1.5 Krads) resulted in selection of a callus clone population containing a high proportion of somatic hybrids. Analysis of a dimeric isozyme for the presence of a heterodimeric form was found to be satisfactory for distinguishing parental-type calli, somatic hybrid calli, and mixed calli derived from both types of unfused parental cells. No somatic hybrid calli produced shoots, although the sexual hybrid between L. esculentum and L. pennellii regenerated well under the culture conditions employed. This result suggests that the non-regenerable growth habit of the L. pennellii suspension culture was dominant in the somatic hybrid. The culture conditions described here are suitable for obtaining regenerated plants from L. esculentum mesophyll protoplasts. L. esculentum protoplast calli from fusion cultures gave rise to shoots with L. esculentum phenotype at higher frequency than calli from control unfused L. esculentum mesophyll protoplast cultures. The use of probes for species-specific organelle DNA fragments allowed identification of organelle DNA restriction fragments in digests of total DNA from small samples of individual callus clones. The callus clones analyzed either carried predominantly one parental plastid DNA type or mixtures of both types. Use of a mitochondrial DNA (mtDNA) probe which distinguishes two parental mtDNA fragments revealed that the L. pennellii-specific fragment was present in all clones examined, but the L. esculentum fragment was absent or in low proportion.     

Characterization of somatic hybrids of potato by use of RAPD markers and isozyme analysis

Electrofusion of mesophyll protoplasts from two male sterile dihaploid Solanum tuberosum genotypes. DHAK-11 and DHAK-33, was performed. Selection of putative fusion products was based on vigorous callus growth. Regeneration of rooted putative hybrid plants was scored 14 weeks after fusion. Characterization of hybrids was performed by use of morphological assessment, random amplified polymorphic DNA (RAPD), and cytological and isozyme analysis. The rate of regenerated hybrids from callus was ca 6%. Of the putative hybrids, 45% were confirmed as true hybrids. Morphological assessment of the putative hybrids revealed that tetraploid and neartetraploid hybrids were vigorous plants with intermediate characteristics between the two parental phenotypes in respect to internode length, leaf size and shape, and purple pigmentation on the abaxial side of the leaves. Near-hexaploid hybrids were slender plants with small leaves and short petioles. Selected RAPD primers showed unique marker bands for the two parental genotypes. Hybrid plants revealed the unique marker bands from both parents. A total of 53 randomly chosen decamer primers were tested and 26 primers (49%) detected polymorphism between the two dihaploid parentals. Two primers revealed that one parental marker band was missing in two aneuploid hybrids. However, of 51 putative hybrids, a double test with two independently chosen primers showed unequivocally the hybrid character of 23 plants. The ploidy level of the hybrids was analysed by chromosome numbers in root tip cells and by number of guard cell chloroplasts. A strong correlation between the chromosome number and the number of chloroplasts was obtained. The hybrid nature of all RAPD-verified hybrids was confirmed by isozyme analysis with malate dehydrogenase.     

Somatic hybrids between<Emphasis Type="Italic"> Arabidopsis thaliana</Emphasis> and cytoplasmic male-sterile radish (<Emphasis Type="Italic">Raphanus sativus</Emphasis>)

Somatic hybrids were produced by protoplast fusion between Arabidopsis thaliana ecotype Columbia and a male-sterile radish line MS-Gensuke (Raphanus sativus) with the Ogura cytoplasm. Forty-one shoots were differentiated from the regenerated calli and established as shoot cultures in vitro. About 20 of these shoots were judged to be hybrids based on growth characteristics and morphology. Molecular analyses of 11 shoots were performed, confirming the hybrid features. Of these 11 shoots, eight were established as rooted plants in the greenhouse. Polymerase chain reaction and randomly amplified polymorphic DNA analyses of the nuclear genomes of all analyzed shoots and plants confirmed that they contained hybrid DNA patterns. Their chromosome numbers also supported the hybrid nature of the plants. Investigations of the organelles in the hybrids revealed that the chloroplast (cp) genome was exclusively represented by radish cpDNA, while the mitochondrial DNA configuration showed a combination of both parental genomes as well as fragments unique to the hybrids. Hybrid plants that flowered were male-sterile independent of the presence of the Ogura CMS-gene orf138.Abbreviations CMS Cytoplasmic male sterilityCommunicated by M.R. Davey     

Comparative study of symmetric and asymmetric somatic hybridization between common wheat andHaynaldia villosa

Symmetric and asymmetric protoplast fusion between long term cell suspension-derived protoplasts ofTriticum aestivum (cv. Jinan 177) and protoplasts ofHaynaldia villosa prepared from one-year-old embryogeneric calli was performed by PEG method. In asymmetric fusion, donor calli were treated with gamma ray at a dose of 40, 60, 80 Gy (1.3 Gy/min) respectively and then used to isolate protoplasts. Results of morphological, cytological, biochemical (isozyme) and 5S rDNA spacer sequence analysis revealed that we obtained somatic hybrid lines at high frequency from both symmetric and asymmetric fusion. Hybrid plants were recovered from symmetric and low dose γ-fusion combinations. GISH (genomicin situ hybridization) analysis proved exactly the existence of both parental chromosomes and the common occurrence of several kinds of translocation between them in the hybrid clones regenerated from symmetric and asymmetric fusion. And the elimination of donor DNA in hybrid clones regenerated from asymmetric fusion combinations was found to increase with the increasing gamma doses. It is concluded that transference and recombination of nuclear DNA can be achieved effectively by symmetric and asymmetric fusion, hybrids with small fragment translocation which are valuable in plant breeding can be obtained directly by asymmetric fusion.     

Comparative study of symmetric and asymmetric somatic hybridization between common wheat andHaynaldia villosa

Symmetric and asymmetric protoplast fusion between long term cell suspension-derived protoplasts ofTriticum aestivum (cv. Jinan 177) and protoplasts ofHaynaldia villosa prepared from one-year-old embryogeneric calli was performed by PEG method. In asymmetric fusion, donor calli were treated with gamma ray at a dose of 40, 60, 80 Gy (1.3 Gy/min) respectively and then used to isolate protoplasts. Results of morphological, cytological, biochemical (isozyme) and 5S rDNA spacer sequence analysis revealed that we obtained somatic hybrid lines at high frequency from both symmetric and asymmetric fusion. Hybrid plants were recovered from symmetric and low dose γ-fusion combinations. GISH (genomicin situ hybridization) analysis proved exactly the existence of both parental chromosomes and the common occurrence of several kinds of translocation between them in the hybrid clones regenerated from symmetric and asymmetric fusion. And the elimination of donor DNA in hybrid clones regenerated from asymmetric fusion combinations was found to increase with the increasing gamma doses. It is concluded that transference and recombination of nuclear DNA can be achieved effectively by symmetric and asymmetric fusion, hybrids with small fragment translocation which are valuable in plant breeding can be obtained directly by asymmetric fusion.     

Identification of Hybrids of Painted and Milky Storks Using FTA Card-Collected Blood, Molecular Markers, and Morphologies

Suspicious hybrids of painted storks and milky storks were found in a Malaysian zoo. Blood of these birds was sampled on FTA cards for DNA fingerprinting. Of 44 optimized primers, 6 produced diagnostic markers that could identify hybrids. The markers were based on simple, direct PCR-generated multilocus banding patterns that provided two sets of genetic data, one for each of the two stork species and another for the hybrids. It also revealed that large DNA fragments (3,000 bp) could be amplified from blood collected on FTA cards. When the results of each individual bird’s DNA fingerprint were compared with plumage characters, the hybrids were found to express a range of intermediate phenotypic traits of the pure breeds with no dominant plumage characteristic from either parental species.     

苜蓿红豆草属间体细胞杂种的分子生物学鉴定

通过原生质体融合和培养获得苜蓿红豆草属间体细胞杂种植株。采用一种简便方法从杂种组织再生植株叶片、红豆草羟脯氨酸抗性系再生植株叶片和苜蓿根癌农杆菌702转化系愈伤组织提取DNA用于RAPD和Southern杂交分析。随机引物扩增结果显示两种亲本的RAPD多态具有明显差异。在所用20种随机引物中,6种产生较多的DNA片段。杂种组织具有两种亲本特有的DNA片段,但倾向于排除红豆草亲本的染色体,表明该杂种为非对称杂种,两种亲本染色体之间可能发生了重组。由于红豆草DNA的介入,杂种组织表现出较强的分化能力。分别利用RAPD扩增得到的OPA141000bp红豆草羟脯氨酸抗性系特异产物和OPA141600bp苜蓿根癌农杆菌702转化系特异产物为探针进行Southern分子杂交,证明杂种组织同时具有这两种DNA片段的同源序列。     

A variant mitochondrial DNA arrangement specific toPetunia stable sterile somatic hybrids

We have characterized two related regions of twoPetunia mitochondrial genomes in order to understand how plant mt genomes from a cytoplasmic male sterile (cms) line and a fertile line diverge from one another. Restriction maps of these regions indicate that a sequence arrangement shared by the two genomes adjoins sequences which are not shared at the corresponding locations in the two genomes. A point where the mt genomes from the cms line and the fertile lines diverge from each other was identified and mapped. Previously we had observed that somatic hybrids constructed from the cms and the fertile line contained mt genomes carrying new combinations of parental mtDNA restriction fragments (3). Using the restriction maps of the two related mtDNA regions, a mtDNA arrangement unique to the cms parent could be shown to be present in all 17 stable sterile somatic hybrids tested and none of the 24 stable fertile somatic hybrids tested. This data does not exclude the possibility that additional, as yet unidentified, mtDNA arrangements unique to the cms parent might also be found exclusively in sterile somatic hybrids. Whether or not the sterile parental mtDNA arrangement reported here is functionally related to cms, it apparently segregates with cms in somatic hybrids.     

Production of intertribal somatic hybrids between Brassica napus L. and Lesquerella fendleri (Gray) Wats

Intertribal Brassica napus (+) Lesquerella fendleri hybrids have been produced by polyethylene glycol-induced fusions of B. napus hypocotyl and L. fendleri mesophyll protoplasts. Two series of experiments were performed. In the first, symmetric fusion experiments, protoplasts from the two materials were fused without any pretreatments. In the second, asymmetric fusion experiments, X-ray irradiation at doses of 180 and 200 Gy were used to limit the transfer of the L. fendleri genome to the hybrids. X-ray irradiation of L. fendleri mesophyll protoplasts did not suppress the proliferation rate and callus formation of the fusion products but did significantly decrease growth and differentiation of non-fused L. fendleri protoplasts. In total, 128 regenerated plants were identified as intertribal somatic hybrids on the basis of morphological criteria. Nuclear DNA analysis performed on 80 plants, using species specific sequences, demonstrated that 33 plants from the symmetric fusions and 43 plants from the asymmetric fusions were hybrids. Chloroplast and mitochondrial DNA analysis revealed a biased segregation that favoured B. napus organelles in the hybrids from the symmetric fusion experiments. The bias was even stronger in the hybrids from the asymmetric fusion experiments where no hybrids with L. fendleri organelles were found. X-ray irradiation of L. fendleri protoplasts increased the possibility of obtaining mature somatic hybrid plants with improved fertility. Five plants from the symmetric and 24 plants from the asymmetric fusion experiments were established in the greenhouse. From the symmetric fusions 2 plants could be fertilised and set seeds after cross-pollination with B. napus. From the asymmetric fusions 9 plants could be selfed as well as fertilised when backcrossed with B. napus. Chromosome analysis was performed on all of the plants but 1 that were transferred to the greenhouse. Three plants from the symmetric fusions contained 50 chromosomes, which corresponded to the sum of the parental genomes. From the asymmetric fusions, 11 hybrids contained 38 chromosomes. Among the other asymmetric hybrids, plants with 50 chromosomes and with chromosome numbers higher than the sum of the parental chromosomes were found. When different root squashes of the same plant were analysed, a total of 6 plants were found that had different chromosome numbers.     

Analysis of chloroplast and mitochondrial segregation in three different combinations of somatic hybrids produced within Brassicaceae

Summary Mitochondrial and chloroplast DNA were characterized in three different combinations of somatic hybrids produced between different species within Brassicaceae. The fusions were made between B. campestris and B. oleracea, B. napus and B. nigra and between B. napus and Eruca sativa. The combinations represent interspecific hybridizations, but the phylogenetic distance between the species used in each instance is different. Whereas the B. campestris (+) B. oleracea and the B. napus (+)B. nigra hybrids are both examples of intrageneric hybrids, B. campestris is more closely related to B. oleracea than B. napus is to B. nigra. The fusion of B. napus and E. sativa represents an intergeneric hybridization. Since hybrids were produced with reproducible and uniform fusion and culture methods, a comparison of chloroplast and mitochondrial segregation and mitochondrial DNA (mt-DNA) rearrangements could be made between the combinations. The segregation of both chloroplasts and mitochondria was biased in the B. napus (+)B. nigra and the B. napus (+)E. sativa combination. The nonrandom segregation of chloroplasts and mitochondria could be due to the different ploidy levels of the fusion partners and/or reflect differences in organelle replication rate. Furthermore, segregation of mitochondria was correlated to the differences in phylogenetic distance between the species used in the fusions. However, mitochondrial segregation, in contrast to chloroplast segregation, could in all combinations also have been affected by the cell type used as protoplast source in the fusions. All different chloroplast types could be established within each combination. Hybrids containing chloroplast from one parent together with mitochondria from the other parent were found in two of the combinations, although the majority of the hybrids had mt-DNA that was altered compared to the parental species. The rearranged mt-DNA found in most hybrids was an effect of the heteroplasmic state following protoplast fusion rather than of the tissue culture methods, since no mt-DNA rearrangements were found in B. napus plants regenerated from protoplast culture. The mtDNA restriction patterns of the hybrids with rearranged mt-DNA indicated that specific regions of the mt-DNA were involved in the rearrangements following protoplast fusion.     

Horizontal Transfer of Genetic Material among Saccharomyces Yeasts

The genus Saccharomyces consists of several species divided into the sensu stricto and the sensu lato groups. The genomes of these species differ in the number and organization of nuclear chromosomes and in the size and organization of mitochondrial DNA (mtDNA). In the present experiments we examined whether these yeasts can exchange DNA and thereby create novel combinations of genetic material. Several putative haploid, heterothallic yeast strains were isolated from different Saccharomyces species. All of these strains secreted an a- or alpha-like pheromone recognized by S. cerevisiae tester strains. When interspecific crosses were performed by mass mating between these strains, hybrid zygotes were often detected. In general, the less related the two parental species were, the fewer hybrids they gave. For some crosses, viable hybrids could be obtained by selection on minimal medium and their nuclear chromosomes and mtDNA were examined. Often the frequency of viable hybrids was very low. Sometimes putative hybrids could not be propagated at all. In the case of sensu stricto yeasts, stable viable hybrids were obtained. These contained both parental sets of chromosomes but mtDNA from only one parent. In the case of sensu lato hybrids, during genetic stabilization one set of the parental chromosomes was partially or completely lost and the stable mtDNA originated from the same parent as the majority of the nuclear chromosomes. Apparently, the interspecific hybrid genome was genetically more or less stable when the genetic material originated from phylogenetically relatively closely related parents; both sets of nuclear genetic material could be transmitted and preserved in the progeny. In the case of more distantly related parents, only one parental set, and perhaps some fragments of the other one, could be found in genetically stabilized hybrid lines. The results obtained indicate that Saccharomyces yeasts have a potential to exchange genetic material. If Saccharomyces isolates could mate freely in nature, horizontal transfer of genetic material could have occurred during the evolution of modern yeast species.     

Morphological characteristics and chloroplast DNA distribution in different cytoplasmic parasexual hybrids of Nicotiana tabacum

Summary Protoplast fusion makes possible the fusion of two different cytoplasms, allowing genetical analysis of cytoplasmic factors. Two varieties of Nicotiana tabacum differing by their cytoplasms have been used. Techne, the first variety, obtained by an interspecific cross between N. debneyi (female) and N. tabacum (male) is characterized by the nuclear tabacum genome inside the debneyi cytoplasm. Techne plants present abnormal flowers with cytoplasmic male sterility (cytoplasmic marker) and sessile leave (nuclear marker). Techne leaf protoplasts were fused with leaf protoplasts of N. tabacum var. Samsun (or Xanthi). The last variety is characterized by petiolated leaves and normal flowers, because it possesses the nuclear tabacum genome associated with the tabacum cytoplasm. The nuclear marker (leaf shape) and the cytoplasmic one (flower shape inducing male sterility or fertility) have been used to distinguish among the whole regenerated plants the somatic nuclear hybrids and the cytoplasmic hybrids (cybrids) displaying the nuclear phenotype of one of the two parents associated with a modified flower type, intermediate between the parental ones.The chloroplastic (cp) DNA contained in each parent has been specifically identified by using EcoRI restriction nuclease and gel electrophoresis. EcoRI fragment patterns of cp DNA isolated from the first progeny of the regenerated cytoplasmic hybrids revealed that only one of the two parental cp DNAs is present in all cases; neither mixture of both parental cp DNAs nor recombinant cp DNA molecules were observed. This indicates that a specific elimination of one or the other parental cp DNAs occurs after the initial mixing of the cytoplasms. The study of the association of the modified flower type with the cp DNA isolated from the corresponding plant showed that cp DNA seems independent from the mechanism of cytoplasmic male sterility in tobacco.     

Production and analysis of asymmetric hybrid plants between monocotyledon (Oryza sativa L.) and dicotyledon (Daucus carota L.)

Asymmetric hybrid plants were obtained from fused protoplasts of a monocotyledon (Oryza sativa L.) and a dicotyledon (Daucus carota L.). X-ray-irradiated protoplasts isolated from a cytoplasmic malesterile (cms) carrot suspension culture were fused with iodoacetoamide-treated protoplasts isolated from a 5-methyltryptophan (5MT)-resistant rice suspension culture by electrofusion. The complementary recovered cells divided and formed colonies, which were then cultivated on regeneration medium supplemented with 25mg/l 5MT to eliminate any escaped carrot cells. Somatic hybrids were regenerated from 5 of the 5MT-resistant colonies. The morphologies of most of the regenerated plants closely resembled that of the parental carrot plants. A cytological analysis of callus cultures induced from these plants indicated that most of the cells possessed 20–22 chromosomes and were resistant to 5MT. An isozyme analysis revealed that several regenerated plants had the peroxidase isozyme patterns of both parents. A Southern hybridization analysis with non-radioactively labelled DNA fragments of the rgp1 gene showed that regenerated plants had hybridizing bands from both rice and carrot. Chloroplast (cp) and mitochondrial (mt) DNAs were also analyzed by Southern hybridization by using several probes. CpDNA patterns of the regenerated plants were indistinguishable from those of the carrot parent. However 1 of the regenerated plants had a novel band pattern of mtDNA that was not detected in either of the parents, indicating a possible recombination of mitochondrial genomes.     

Protoplast fusion in the yeast, Schwanniomyces alluvius

Summary This first application of the technique of protoplast fusion to Schwanniomyces suggests that it is possible to overcome the genetic isolation of this genus imposed by its inability to undergo conventional intraspecific mating. The stability, increased ploidy, and cell volumes of such fusion hybrids over the parental strains indicate the possibility of construction of polyploid strains suitable for use in industry.Nuclear fusion (karyogamy) appears to occur in intraspecific hybrids as evidenced by isolation of recombinants after mitotic segregation of parental auxotrophic genetic markers.Intergeneric hybrids formed from Schw. alluvius and Saccharomyces spp. were unstable and spontaneously segregated into original auxotrophic parent cultures. Genetic diversity between these genera may be too great to allow stable co-existance of the two genomes within a single nucleus. Nuclear fusion in such cases could not be confirmed.     

Mixing of maize and wheat genomic DNA by somatic hybridization in regenerated sterile maize plants

Intergeneric somatic hybridization was performed between albino maize (Zea mays L.) protoplasts and mesophyll protoplasts of wheat (Triticum aestivum L.) by polyethylene glycol (PEG) treatments. None of the parental protoplasts were able to produce green plants without fusion. The maize cells regenerated only rudimentary albino plantlets of limited viability, and the wheat mesophyll protoplasts were unable to divide. PEG-mediated fusion treatments resulted in hybrid cells with mixed cytoplasm. Six months after fusion green embryogenic calli were selected as putative hybrids. The first-regenerates were discovered as aborted embryos. Regeneration of intact, green, maize-like plants needed 6 months of further subcultures on hormone-free medium. These plants were sterile, although had both male and female flowers. The cytological analysis of cells from callus tissues and root tips revealed 56 chromosomes, but intact wheat chromosomes were not observed. Using total DNA from hybrid plants, three RAPD primer combinations produced bands resembling the wheat profile. Genomic in situ hybridization (GISH) using total wheat DNA as a probe revealed the presence of wheat DNA islands in the maize chromosomal background. The increased viability and the restored green color were the most-significant new traits as compared to the original maize parent. Other intermediate morphological traits of plants with hybrid origin were not found.