Serological relationships of Fraction I proteins from species in the genusNicotiana

The serological relationships of Fraction I proteins from 62 species of the genusNicotiana have been determined by qualitative double diffusion in agar gels, using antisera raised against crystalline Fraction I proteins from four species,N. glauca, N. glutinosa, N. gossei, andN. tabacum. The relationships obtained are, in most cases, similar to the relationships of the species based on morphological and cytogenetic criteria. In general, Fraction I proteins from species within the same section are serologically identical. However, serological examination of Fraction I proteins draws attention to certain species, for example,N. glauca, N. sylvestris, andN. acaulis, whose classification by traditional methods has been difficult.     

Biochemical and serological characterization of b-proteins fromNicotiana species

Summary Proteins associated with the hypersensitive response (b-proteins) were purified from variousNicotiana species and compared biochemically and serologically. The method developed to purify proteins b₁, b₂ and b₃ ofN. tabacum cv. Xanthi-nc was used to purify b-proteins present inN. sylvestris (b₀, b₁ and b₃) andN. tomentosiformis (b₂), the parental species ofN. tabacum, and b₁″ from bothN. glutinosa andN. debneyi. Ultracentrifugation and amino acid analysis of some of these proteins has shown that they are very similar and that they are all monomers in their native form (mol wt = 15 700 for b₀, b₁, b₂ and b₃; mol wt = 13 800 for b₁″). Based on their reactions to an antiserum produced against protein b₁ ofN. tabacum cv. Xanthi-nc, 3 serological groups can be recognized which are independent of the source species (I) b₀ and b₁, (II) b₁″ and b₂, (III) b₃. Thus, proteins in the same serological group but from different species are more closely related than the b-proteins in different serological groups but present in the same species. The implication of this site on the possible phylogeny of b-proteins is discussed. Serological tests confirmed the b-protein present as a constitutive component in the virus resistant interspecific hybrids ofN. glutinosa ×N. debneyi as protein b₁″.     

Identification of several chloroplast DNA genes which code for the large subunit of Nicotiana Fraction I proteins

Summary Electrofocusing of carboxymethylated, crystalline Fraction I proteins in polyacrylamide gels containing 8 M urea resolves the large subunit into three major peptides and the small subunit into one or more peptides. Electrofocusing of proteins isolated from leaves of the reciprocal, F₁, hybrids: N. glutinosa x N. tabacum, N. glauca x N. tabacum, N. glauca x N. langsdorfii and the parental species confirms that coding information for the large subunit is inherited only by the maternal line whereas both parents contribute coding information for the small subunit. The analysis shows that one or more of the three peptides of the large subunit of Fraction I proteins from different Nicotiana species differ in isoelectric point and therefore serve as phenotypic markers for chloroplast DNA genes.     

Genomic analysis in the genus Aegilops.

Summary Hybrids between different Aegilops species and Secale cereale were studied at metaphase I by means of a C-banding technique. On the basis of differences in the C-banding patterns of some of the chromosomes of these hybrids it was possible to carry out an accurate analysis of several types of Aegilops-Aegilops and Aegilops-Secale chromosome associations and, consequently, to establish intraspecific and intergeneric genome relationships. Genomes present in the majority of polyploid Aegilops species are shown to maintain similar patterns of evolutionary affinity to those reported for their proposed diploid parents although in some species there are differences indicating either that differentiations occurred during the evolution of the polyploid species or, on the contrary, that the diploid donors proposed are not the correct ones. On the other hand, differences in the relationships not only between the R genome and different Aegilops genomes but also among different homoeologous groups have been found.     

How selfing and intra- and interspecific crossing influence seed set, morphology and ploidy level in Euphrasia: An experimental study of species occurring in the Alps of Switzerland

Annual alpine species rely on selfing rather than on cross-pollination for successful reproduction. However, insect visits may occasionally cause cross-pollination not only within but also between closely related species. The aim of this study was to investigate four species of Euphrasia for their efficiency in spontaneous selfing and their success in intra- and interspecific crossing. We used the seed sets that followed spontaneous selfing and artificial cross- and selfpollination to measure the breeding success. We compared the morphological characters of species and hybrids and determined their ploidy level using flow cytometry. We verified the hybridogenous origin of plants resulting from interspecific crosses using RAPD banding patterns. While spontaneous seed set was high in the two small-flowered species, seed set in the large-flowered species was small and affected by external circumstances. We obtained F1 and F2 hybrids from interspecific crosses of two diploid species and detected polyploid individuals in both generations.     

Analysis of metaphase I chromosome association in species of the genus Aegilops

Summary Metaphase-I chromosome associations in every diploid and polyploid species of the genus Aegilops were studied using C-banding in order to analyse the cytogenetic behaviour of the whole complement as well as of specific genomes in different polyploid species. Differences were observed in the frequency of associations per cell among different species of the same ploidic level and even between species sharing the same genomic constitution. Differences were also found between different genomes within the same polyploid species and between the same genome when present in several diploid and polyploid species. Several factors proposed as having an influence on the frequency of metaphase-I associations, such as chromosome morphology, C-heterochromatin content, genetic control and genome interactions, are discussed. Most of the polyploid Aegilops species showed a diploid-like behaviour at metaphase I although multivalents involving homoeologous associations were occasionally observed in Ae. biuncialis, Ae. juvenalis and Ae. crassa(6x); therefore, the Aegilops diploidising genetic system is not equally effective in all polyploid species.     

Interspecific hybrid plant formation by electrofusion in Nicotiana

Summary We obtained complete hybrid plants by electrofusion of mesophyll protoplasts from Nicotiana glauca and N. langsdorffii. Electrofocusing analysis of Fraction I proteins isolated from the leaves of these plants confirmed their hybridity. Cytological analysis indicated that the chromosome number (2n) of these plants is between 60 to 66, suggesting that they are the products of triple fusion. All plants were fertile and set viable seeds after self pollination. As we did not use an AC field for electrofusion, the present results indicate that an AC field is not essential for obtaining hybrid plants with electrofusion.     

Nontranslation of foreign genetic information for fraction 1 protein under circumstances favorable for direct transfer ofNicotiana gossei isolated chloroplasts intoN. Tabacum protoplasts

Summary The nuclei and cytoplasm ofN. gossei andN. tabacum are compatible to the extent that reciprocal, interspecific F₁ hybrids can be produced by conventional breeding techniques. Conditions were established in which manyN. gossei isolated chloroplasts could be seen by phase and fluorescence microscopy to adhere to 40% of the population of protoplasts obtained from white tissue of variegatedN. tabacum plants and to remain attached after washing the protoplasts. Chloroplasts also could be seen to enter the interior of the protoplasts. After treating albino protoplasts withN. gossei chloroplasts, the protoplasts were subjected to further conditions whereby 65 calluses containing shoots developed. TwentyN. tabacum protoplasts not treated with foreign chloroplasts also produced calluses with shoots to serve as a control. All calluses developed chlorophyll irrespective of whether or not the albino protoplasts had been treated with isolatedN. gossei chloroplasts. The Fraction 1 protein ofN. tabacum has a different electrophoretic mobility from the protein ofN. gossei or anN. gossei xN. tabacum F₁ hybrid. The Fraction 1 protein large subunit is coded by chloroplast DNA, whereas the small subunit is coded by nuclear DNA. Fraction 1 protein was isolated from the variegated shoots of the 65 calluses obtained after treating albino protoplasts with foreign chloroplasts. Immunoelectrophoresis demonstrated the protein from each callus to have a mobility identical toN. tabacum protein. Therefore, under circumstances highly favorable for the direct transfer ofN. gossei isolated chloroplasts (and possibly nuclei also) intoN. tabacum protoplasts, no evidence was obtained to suggest that genetic information contained in the isolated foreign organelles was being translated into the polypeptides of either the large or small subunits of Fraction 1 protein contained in newly differentiated leaves derived from the protoplasts. Supported by Research Grant PCM-75-07368 from the National Science Foundation.     

A chromosome-specific sequence common to the B genome of polyploid wheat and Aegilops searsii

A low-copy, non-coding chromosome-specific DNA sequence, isolated from common wheat, was physically mapped to the distal 19% region of the long arm of chromosome 3B (3BL) of common wheat. This sequence, designated WPG118, was then characterized by Southern hybridization, PCR amplification and sequence comparison using a large collection of polyploid wheats and diploid Triticum and Aegilops species. The data show that the sequence exists in all polyploid wheats containing the B genome and absent from those containing the G genome. At the diploid level, it exists only in Ae. searsii, a diploid species of section Sitopsis, and not in other diploids including Ae. speltoides, the closest extant relative to the donor of the B genome of polyploid wheat. This finding may support the hypothesis that the B-genome of polyploid wheat is of a polyphyletic origin, i.e. it is a recombined genome derived from two or more diploid Aegilops species.     

Reduced meiotic fitness in hybrids with heterozygosity for heterochromatin in the speciating<Emphasis Type="Italic">Mus terricolor</Emphasis> complex

Mus terricolor I, II and III are the three chromosomal species which differ in stable autosomal short-arm heterochromatin variations established in homozygous condition. Analysis of meiosis in the laboratory-generated F₁ male hybrids from crosses (both ways) betweenM. terricolor I and II and betweenM. terricolor I and III shows high frequencies of pairing abnormalities at pachytene. The backcross (N3 generation) male hybrids betweenM. terricolor I and II have meiotic abnormalities as in the F₁male hybrids, though to a lesser extent. They show difference in pairing abnormalities in the different karyotypic forms; the backcross hybrids heterozygous for the heterochromatic short arms have more anomalies compared to the homokaryotypic hybrids. This suggests a negative influence of the heterochromatin heterozygosity in meiotic pairing. The results indicate a role for heterochromatin variations in the development of a reproductive barrier in the speciatingM. terricolor complex.     

Interspecific hybridization between the cultivated potato Solanum tuberosum subspecies tuberosum L. and the wild species S. circaeifolium subsp. circaeifolium Bitter exhibiting resistance to Phytophthora infestans (Mont.) de Bary and Globodera pallida (Stone) Behrens

Summary Somatic fusions between the cultivated potato Solanum tuberosum and the wild species S. circaeifolium subsp. circaeifolium Bitter were produced in order to incorporate desirable traits into the potato gene pool. Selection of the putative hybrids was based on a difference in callus morphology between the hybrids and their parents, with the hybrids showing typical purple-colored cells in otherwise green calli. In all, 17 individual calli regenerated to plants. Of the nine plants that could be transferred to the greenhouse, eight showed a hybrid and one a parental morphology. Restriction fragment length polymorphism (RFLP) analysis confirmed the hybrid character in the former group. Chloroplast counts in stomatal guard cells and flow cytometric determination of nuclear DNA content showed that four hybrid plants were tetraploid (4x), one was mixoploid (5x–8x), and the others were polyploid (6x; 8x). Three out of four tetraploid hybrids were found to be fully resistant to Phytophthora infestans, and all four hybrids were resistant to Globodera pallida pathotypes Pa2 and Pa3. It was further observed that the type and amount of steroidal glycoalkaloids varied among the tubers of the parents and the hybrids. Using the hybrids as female parents in crosses with S. tuberosum, viable seeds could be obtained. This demonstrates the potential of these hybrids in practical plant breeding.     

Change in the solubility of crystalline Fraction I proteins correlated with change in the composition of the small subunit

Fraction I protein crystals were obtained by a simple methodfrom four additional species in addition to seven species ofNicotiana previously reported and from Solanum melongena. Crystalswere obtained neither from several other genera of the Solanacealnor from N. debneyi, but ¹⁴C protein from the latter co-crystallizedwith N. tabacum Fraction I protein. Co-crystallization did notoccur with ¹⁴C proteins from species of Tagetes, Allium, Beta,Brassica and Hyocyamus whose Fraction I proteins were evidentlytoo different in their quaternary structures to occupy the samecrystal lattice with N. tabacum protein. Fraction I proteinsfrom N. gossei and N. excelsior differed in solubility as afunction of the NaCl concentration. The two proteins were alikein the isoelectric point of the three primary peptides composingthe large subunit, but differed in the isoelectric point ofone out of four primary peptides of the small subunit; thisdifference was also consistent with a difference in trypticpeptide fingerprints. Proteins from N. tabacum and N. glaucadiffered both in the composition of their large and small subunitsbut did not differ in solubility. However, by changing the compositionof the small subunit without changing the large subunit, thesolubility of each protein was changed. The change in smallsubunit composition could be achieved by isolating proteinsfrom the reciprocal F₁ hybrids of N. tabacum ? N. glauca wherethe maternal inheritance regulates the composition of the largesubunit, whereas both maternal and paternal genes regulate thecomposition of the small subunit. ¹Present address: Department of Physiology, Hyogo College ofMedicine, Nishinomiya, Hyogo, Japan. (Received March 20, 1974; )     

Rare symmetric and asymmetric Nicotiana tabacum (+) N. megalosiphon somatic hybrids recovered by selection for nuclear-encoded resistance genes and in the absence of genome inactivation

Following protoplast fusion between Nicotiana tabacum (dhfr) and N. megalosiphon (nptII) somatic hybrids were selected on the basis of dual resistance to kanamycin and methotrexate. Despite strong selection for parental nuclear-encoded resistances, only nine N. tabacum (+) N. megalosiphon somatic hybrids were obtained. A preferential loss of the parental N. tabacum nuclear and organelle genome was apparent in some plants in spite of the lack of genomic inactivation by the irradiation or chemical treatment of the parental protoplasts. Only six of the nine hybrids recovered possessed both parental profiles of nuclear RFLPs and isoenzymes. The remaining three hybrids were highly asymmetric with two being identical to N. megalosiphon except for minor morphological differences and rearranged or recombined mitochondrial DNAs (mtDNA), while the other one was distinguishable only by the presence of a rearranged or recombined mtDNA, and was therefore possibly a cybrid. Overall, eight somatic hybrids possessed rearranged or recombined mtDNAs and chloroplast inheritance was non-random since eight possessed N. megalosiphon-type chloroplasts and only one had N. tabacum chloroplasts. In contrast, using the same selection approach, numerous morphologically similar symmetric somatic hybrids with nuclear RFLPs and isozymes of both the parental species were recovered from control fusions between N. tabacum and the more closely related N. sylvestris. In spite of the low frequency of recovery of symmetric N. tabacum (+) N. megalosiphon hybrids in this study, one of these hybrids displayed a significant degree of self-fertility allowing for back-crosses to transfer N. megalosiphon disease-resistance traits to N. tabacum. Plant Research Centre Contribution No. 1579     

Somatic hybridization between potato and Nicotiana plumbaginifolia

Summary Electrofusion was carried out between mesophyll protoplasts from the transformed diploid S. tuberosum clone 413 (2n=2x=24) which contains various genetic markers (hormone autotrophy, opine synthesis, kanamycin resistance, -glucuronidase activity) and mesophyll protoplasts of a diploid wild-type clone of N. plumbaginifolia (2n=2x=20). Hybrid calli were obtained after continuous culture on selection medium containing kanamycin. Parental chromosome numbers, determined at 2 months after fusion, revealed hybrid-specific differences between the individual calli. On the basis of these differences three categories of hybrids were distinguished. Category I hybrids contained between 8 and 24 potato chromosomes and more than 20 N. plumbaginifolia chromosomes; category II hybrids had between 1 and 20 N. plumbaginifolia chromosomes and more than 24 potato chromosomes; category III hybrids contained diploid or subdiploid numbers of chromosomes from both parents. The hybrids were evenly distributed over the three categories. After a 1-year culture of 24 representative hybrid callus lines on selection medium the karyotype of 10 hybrids remained stable, whereas 8 hybrids showed polyploidization of the genome of one parent, together with no or minor changes of the chromosome numbers of the other parent. Six hybrids showed slight changes in the hybrid karyotype. The elimination of chromosomes of a particular parent was not correlated to their metaphase location. The processes of spontaneous biparental chromosome elimination leading to the production of asymmetric hybrids of different categories are discussed.     

Genetic variation in sympatric populations of diploid and polyploid brine shrimp (Artemia parthenogenetica)

We examined genetic variation in sympatric diploid and polyploid brine shrimp Artemia parthenogenetica from each of three populations (China, Italy and Spain). Italian and Spanish tetraploids are closely related (I=0.964). Diploids and tetraploids within each of the two European populations are also closely related (mean I=0.905). Most alleles found in diploids also exist in sympatric polyploids. In contrast, the asexual Artemia (2N, 4N and 5N) in our study share few alleles with their close sexual relative, A. tunisiana (mean I=0.002). These results, as well as the work of other authors, strongly suggest that at least the tetraploid Artemia in our study have an autopolyploid origin.Clonal diversity of polyploid Artemia can be very high at least in some population. Both diploids and polyploids had low clonal diversities in the populations dominated by polyploids and high clonal diversities in the population dominated by diploids.The most common genotypes of sympatric diploid and polyploid Artemia frequently differed. Some alleles occurred only in diploids, while others were restricted to polyploids. These results suggest that polyploidy in Artemia has led to genetic divergence from diploid progenitors, and that ploidy-level variation must also be considered in developing an understanding of spatial and temporal allozyme polymorphism in asexual populations.     

Sulle Cause Determinanti La Formazione Di Tumori in Ibridi Di Nicotiana

Abstract

Cause of tumor formation in NICOTIANA hybrids. Further serological studies. — Additional researches have been carried out about genetical tumors in genus Nicotiana. By means of serological procedure the affinity among pairs of species that give rise to tumorous and non-tumorous hybrids has been tested, considering also their phyletic interrelation. Using ion exchange chromatography a qualitative analysis of the total proteins of tumorous and non-tumorous tissue of hybrids and of normal leaves taken from hybrids and their parental species was carried out. Serological analysis of affinity between the species tested gave following results:

1) higher serological affinity was found between species belonging to the same subgenus than between species belonging to different subgenera.

2) serological affinity between pairs of species giving rise to tumorous hybrids is higher than the affinity observed between other pairs of species that give rise to normal hybrids in spite of the same sistematic position. The same serological responses were obtained studying many species of Nicotiana with the single apparent exception of N. langsdorffii. The results of chromatographical analysis have revealed a high constancy of protein composition of the normal and tumorous tissue of hybrids. This conferms the genetical uniformity of the whole plant.     

Fertile somatic hybrids between transgenicNicotiana tabacum and transgenicN. debneyi selected by dual-antibiotic resistance

Summary A simple, yet effective selection system was used to produce fertile somatic hybrids betweenNicotiana tabacum andN. debneyi. This approach utilized transgenic antibiotic-resistantN. tabacum andN. Debneyi as donor plants for mesophyll protoplast fusions. Thirteen somatic hybrid plants were regenerated from calli capable of growth on medium containing both antibiotics. The majority of the hybrids displayed a range of leaf and floral morphologies and growth habits that were intermediate to those of the parental species, and had chromosome numbers varying from amphidiploid (2n = 96) to hypoaneuploid (2n = 60). Isoenzyme and RFLP analysis demonstrated the presence and expression of nuclear genes from both parents in all of the hybrids. Most plants are fully fertile. Thus, these plants differ from the malesterile tobacco cybrids and alloplasmic lines produced by transferring theN. debneyi cytoplasm to tobacco. A nonrandom pattern of cytoplasmic segregation in the fusion products occurred with a bias towards the presence ofN. debneyi cp and mtDNA. Evidence for the presence of rearranged or recombinant cp and mtDNA in some of the hybrids was obtained. The somatic hybrids were successfully backcrossed to theN. tabacum parent and are now being tested for immunity to black root rot, a trait specific toN. debneyi, but not existent in theN. tabacum parental line.     

Meiotic analyses ofCucumis hybrids and an evolutionary evaluation of the genusCucumis (Cucurbitaceae)

Meiosis in seven interspecificCucumis hybrids has been analysed i.a. inC. metuliferus ×C. zeyheri, where the parents belong to different sections. In the triploid hybrids a remarkably high number of trivalents has been found. Additional data from literature on geographical distribution, cucurbitacins, flavonoid patterns, isozymes, C-banding, genome size, DNA amount and chloroplast DNA are used to discuss species relationships and evolution. The African cross-compatible group is divided into theMyriocarpus subgroup with the diploid speciesC. africanus, C. myriocarpus subsp.leptodermis and subsp.myriocarpus, and theAnguria subgroup withC. anguria, C. dipsaceus, C. ficifolius, C. prophetarum, C. zeyheri and all polyploids (exceptC. heptadactylus). It is argued that the Asian subg.Melo with x = 7 is derived from the African subg.Cucumis with x = 12; the latter contains all the polyploid species and has the most common basic chromosome number of theCucurbitaceae. This phylogenetic advance is interpreted with concepts of the quantum model of evolution.     

The genome specific grain proteins and the phylogenetic interrelation between Triticum L., Elytrigia Desf., Elymus L. and Agropyron Gaertn

Summary Immunochemical protein studies show that nongliadins of the ethanol-soluble fraction (EF) provide the best biochemical information on genome interrelations in cereals. After electrophoresis (pH 3.2) these genome specific proteins are shown to fall within the category of -prolamines and albumins where inhibitors against -amylases are to be found. Although these genome specific proteins of the EF exhibit identical serological properties, they may differ in electrophoretic mobility. They may very well be controlled by different chromosomes within a certain, characteristic genome. Electrophoretic analyses will thus likely reveal interrelations between individual chromosomes or even chromosome segments while the precipitation spectrum of the EF will function as a marker of the whole genomes or at least of the major part of their genetic material. This advantage of the immunological technique has been explored in a study of the phylogenetic relations between different genomes belonging to Triticum L., Elytrigia Desf., Elymus L. and Agropyron Gaertn. Serological markers for the main genomes of Triticum were checked against species and genomes of the other three genera.More than 80 species belonging to these three genera were proved to be immunologically distinctive from the wheat genomes. Antigens produced against diploid Elytrigia species were not only checked with other species belonging to Elytrigia but also to Elymus and Agropyron. This inventory of interrelationships confirmed previous knowledge and also added some new information on the phylogeny of the polyploid representatives of Elytrigia and Elymus.     

Somatic hybridization of sexually incompatible petunias: Petunia parodii,Petunia parviflora

Summary Somatic hybrid plants were regenerated following the fusion of leaf mesophyll protoplasts of P. parodii with those isolated from a nuclear-albino mutant of P. parviflora. Attempts at sexual hybridization of these two species repeatedly failed thus confirming their previously established cross-incompatibility. Selection of somatic hybrid plants was possible since protoplasts of P. parodii would not develop beyond the cell colony stage, whilst those of the somatic hybrid and albino P. parviflora produced calluses. Green somatic hybrid calluses were visible against a background of albino cells/calluses, and upon transfer to regeneration media gave rise to shoots. Shoots and the resultant flowering plants were confirmed as somatic hybrids based on their growth habit, floral pigmentation and morphology, leaf hair structure, chromosome number and Fraction 1 protein profiles. The relevance of such hybrid material for the development of new, and extensively modified cultivars, is discussed.