Intergeneric hybrids between Triticum crassum and Hordeum vulgare

Summary Intergeneric hybrids between Triticum crassum (2n=6x=42) and Hordeum vulgare cv. Bomi were obtained at a frequency of 15% of pollinated florets. Meiotic chromosome pairing in the hybrids was not different from that observed in a polyhaploid of T. crassum indicating negligible pairing between chromosomes of the two species and secondly that the genome of H. vulgare had no effect on intergenomic pairing in T. crassum.Contribution No. 646 Ottawa Research Station     

Triple hybridization with cultivated barley (Hordeum vulgare L.)

Summary A crossing programme for trispecific hybridization including cultivated barley (Hordeum vulgare L.) as the third parent was carried out. The primary hybrids comprised 11 interspecific combinations, each of which had either H. jubatum or H. lechleri as one of the parents. The second parent represented species closely or distantly related to H. jubatum and H. lechleri. In trispecific crosses with diploid barley, the seed set was 5.7%. Crosses with tetraploid barley were highly unsuccessful (0.2% seed set). Three lines of diploid barley were used in the crosses, i.e. Gull, Golden Promise and Vada. Generally, cv Gull had high crossability in crosses with related species in the primary hybrid. It is suggested that Gull has a genetic factor for crossability not present in cv Vada and cv Golden Promise. One accession of H. brachyantherum used in the primary hybrid had a very high crossability (seed set 54.7%) in combination with cv Vada but no viable offspring was produced. In all, two trispecific hybrids were raised, viz. (H. lechleri x H. brevisubulatum) x Gull (2n=7–30) and (H. jubatum x H. lechleri) x Gull (2n=20–22). The first combination invariably had a full complement of seven barley chromosomes plus an additional chromosome no. 7, but a varying number of chromosomes (19–22) of the wild-species hybrid. The second combination had a full set of barley chromosomes. The meiotic pairing was low in both combinations.     

Elimination and duplication of particular Hordeum vulgare chromosomes in aneuploid interspecific Hordeum hybrids

Summary Seeds formed in crosses Hordeum lechleri (6x) x H. vulgare (2x and 4x), H. arizonicum (6x) x H. v. (2x), H. parodii (6x) x H. v. (2x), and H. tetraploidum (4x) x H. v. (2x) produced plants at high or rather high frequencies through embryo rescue. Giemsa C-banding patterns were used to analyze chromosomal constitutions and chromosomal locations on the methaphase plate. Among 100 plants obtained from H. vulgare (2x) crosses, 32 plants were aneuploid with 2n=29 (1), 28 (3), 27 (13), 26 (5), 25 (4), 24 (4), or 22 (2); 50 were euploid (12 analyzed), and 18 were polyhaploid (5 analyzed). Four plants had two sectors differing in chromosome number. Two of four hybrids with H. vulgare (4x) were euploid and two were aneuploid. Parental genomes were concentrically arranged with that of H. vulgare always found closest to the metaphase centre. Many plants showed a certain level of intraplant variation in chromosome numbers. Except for one H. vulgare (4x) hybrids, this variation was restricted to peripherally located non-H. vulgare genomes. This may reflect a less firm attachment of the chromosomes from these genomes to the spindle. Interplant variation in chromosome numbers was due to the permanent elimination or, far less common, duplication of the centrally located H. vulgare chromosomes in all 34 aneuploids, and in a few also to loss/gain of non-H, vulgare chromosomes. This selective elimination of chromosomes of the centrally located genome contrasts conditions found in diploid interspecific hybrids, which eliminate the peripherally located genome. The difference is attributed to changed genomic ratios. Derivatives of various H. vulgare lines were differently distributed among euploid hybrids, aneuploids, and polyhaploids. Chromosomal constitutions of hypoploid hybrids revealed a preferential elimination of H. vulgare chromosomes 1, 5, 6, and 7, but did not support the idea that H. vulgare chromosomes should be lost in a specific order. H. vulgare SAT-chromosomes 6 and 7 showed nucleolar dominance. Aneuploidy is ascribed to the same chromosome elimination mechanism that produces haploids in cross-combinations with H. vulgare (2x). The findings have implications for the utilization of interspecific Hordeum hybrids.     

Complex interspecific hybridization in barley (Hordeum vulgare L.) and the possible occurrence of apomixis

Summary Several complex hybrids were produced from the combination [(Hordeum lechleri, 6x xH. procerum, 6 x) × H. vulgare, 2 x]. Crosses with six diploid barley lines resulted in triple hybrids, most of which had a full complement of barley chromosomes (no. 1–7), but were mixoploid with respect to alien chromosomes (19–22). In one combination, chromosome no. 7 was duplicated. Meiosis in triple hybrids showed low, but variable pairing (1.3–5.5 chiasmata per cell). The syndesis probably did not include the barley chromosomes. Direct back-crosses to di- and tetraploid barley lines were unsuccessful. Chromosome doubling of the triple hybrid based on cv Pallas resulted in a plant with 2n = 53–56, which had an increased fertility. Backcrosses to one di- and one tetraploid barley line resulted in offspring. The cross made with the tetraploid line (Haisa II), produced a 28-chromosomic plant in which the male parental genome was absent. We suspect that this plant may have arisen through parthenogenetic development of a reduced female gamete. The other cross with a diploid line (9208/9) resulted in plant with 2n = 51–53. The most likely explanation for this second plant is that an unreduced gamete from the amphiploid was fertilized by a normal gamete from the backcross parent, and during early embryo development, some chromosomes were eliminated.     

Analysis of the effect of rye chromosomes 4R, 6R and telomeric heterochromatin on 7R on homologous chromosome pairing in pentaploid hybrids (AABBR,AABBD)

Summary Meiotic pairing in Triticum turgidum cv. Ma (4x) with a mean chiasmata frequency of 27.16 per cell was compared with chiasmata frequencies in its hybrids with several triticale strains, Chinese Spring wheat and its addition lines for Imperial rye chromosomes 4R and 6R. In hybrids between Ma and x Triticosecale cv. Rosner the chiasmata frequency was marginally reduced by an average of 1.25%, by 8.8% in hybrids with x Triticosecale cv. DRIRA HH and by 6.7% with DRIRA EE (lacking 90% telomeric heterochromatin from chromosome arm 7RL). In pentaploid hybrids between Ma and T. aestivum cv. Chinese Spring the reduction was an average of 10.30%, while addition lines with rye chromosome 6R reduced chiasmata frequencies by an average of 7.4% and rye addition line for 4R showed the greatest depression in chiasmata frequency in hybrids by a 25.04% reduction. An interchange difference involving long chromosome segments was observed between Ma and Rosner.Contribution No. 819 Ottawa Research Station     

Primary callus as source of totipotent barley (Hordeum vulgare L.) protoplasts

Summary Primary callus of barley (Hordeum vulgare L.) derived from scutella (cv. Dissa) and anthers (cv. Igri) was used for protoplast isolation and plant regeneration. The protoplasts were embedded in agarose and cultured with nurse cells. The plating efficiency varied from 0.1% to 0.7%. Shoots regenerated from the developing callus. Plantlets were transferred to soil and cultivated in the greenhouse three to five months after protoplast isolation. All plants were normal in morphology, and most of them flowered and set seeds.     

Chromosome elimination in Hordeum vulgare x H. bulbosum hybrids

Summary The hybrid progeny from a stable amphidiploid of H. vulgare x H. bulbosum involving the cultivar Vada and an unstable amphidiploid involving the cultivar Emir were studied. The genotypes examined contained two genomes from Vada or one from Vada and one from Emir, with one or two genomes from H. bulbosum. Comparisons between the chromosome numbers in root-tips and anthers revealed that there was no chromosome elimination in most plants, whether there was one or two Vada genomes present. The one plant in which chromosome elimination was positively identified had Emir as opposed to Vada cytoplasm. It also had a high incidence of degraded or fragmented chromosomes in the PMCs. Differences in stability between a 27 chromosome plant and other hypotetraploids suggest that Vada contains both elimination genes and elimination suppressor genes. Upon selfing, again irrespective of the number of Vada genomes present, circa triploid hybrids gave rise to diploid H. vulgare offspring while hypotetraploids produced hybrid-like plants. These included diploids, triploids and tetraploids. There was evidence that suggested that H. vulgare as well as H. bulbosum chromosomes had been eliminated.     

Molecular mapping of a new gene Rrs4 CI 11549 for resistance to barley scald (Rhynchosporium secalis)

Doubled haploid (DH) progeny from a cross between the scald susceptible barley (Hordeum vulgare L.) cultivar Ingrid and the resistant accession CI 11549 (Nigrinudum) was evaluated for resistance in the pathogen Rhynchosporium secalis (Oudem) J.J. Davis. Two linked and incompletely dominant loci confer resistance CI 11549 against isolate 4004. One is an allele at the complex Rrs1 locus on chromosome 3H close to the centromere; the other is located 22 cM distally on the long arm. The latter locus is designated Rrs4. In BC₃-lines into Ingrid from CI 2222 (another Nigrinudum) resistance seems governed by one locus close to the telomeric region of chromosome 7H, probably allelic to Rrs2. In neither case did we find any trace of the recessive gene rh8 reported to be present in Nigrinudum. Various resistance donors of Ethiopian origin designated as Nigrinudum, Jet or Abyssinian were identical to a great extent with respect to markers, but differed in resistance to different isolates of scald or in barley yellow dwarf virus (BYDV) resistance. The implications for their use as differentials in scald tests and screening of germplasm collections are discussed.     

Haploidy from Hordeum interspecific crosses

Summary Hordeum arizonicum (2n=42) and H. lechleri (2n=42) were crossed with both H. bulbosum (2n=14 or 28) and H. vulgare (2n=14 or 28) and progeny plants were obtained through embryoculture. Crosses of arizonicum with diploid bulbosum invariably resulted in haploids (2n=21) of arizonicum, whereas arizonicum by tetraploid bulbosum or diploid vulgare crosses produced both hybrids and haploids of arizonicum. The lechleri by diploid bulbosum or diploid vulgare crosses resulted in haploids of lechleri, while lechleri by tetraploid bulbosum resulted in well differentiated embryos which failed to germinate.Hybrid embryos derived from the haploid producing crosses exhibit chromosome variability, suggesting that chromosome elimination leads to haploid formation.The results also indicate that the ratio of the parental genomes in the zygote is a critical factor which determines the chromosome elimination or stability in any cross combination. Furthermore, both arizonicum and lechleri appear to be of similar genetic strength in eliminating bulbosum and vulgare chromosomes. The possibility of stability factors in overcoming elimination and manipulation towards elimination are discussed.     

Haploidy from Hordeum interspecific crosses

Summary Interspecific crosses of Hordeum parodii (2n = 42) with H. bulbosum (2n = 14 or 28) and H. vulgare (2n = 14;, and of H. proaerum (2n = 42) with H. bulboswn, H. vulgare and H. parodii were made. Crosses between parodii and diploid bulbosum resulted in haploids (2n = 21) of parodii, whilst the crosses of parodii by tetraploid bulbosum or diploid vulgare gave hybrid progeny. The procerum by diploid bulbosum cross invariably produced haploids (2n = 21) of procerum, whereas procerum by tetraploid bulbosum or diploid vulgare crosses resulted in both hybrids and haploids of procerum. The cross between procerum and parodii gave hybrid progeny which did not reach maturity.Cytological observations on two-week-old embryos obtained from reciprocal crosses revealed chromosome variability (not less than 21 in any cell) in haploid producing crosses. This shows that chromosome elimination leads to haploid formation irrespective of which species was used as female parent.The results indicate that the ratio of the parental genomes in the zygote determines whether predominantly haploids or hybrids will be produced in any cross combination. Furthermore, procerum appears to be not only more efficient in eliminating bulbosum chromosomes in comparison with parodii, but also capable of eliminating vulgare chromosomes. The possibility of stability factors in overcoming chromosome elimination, a hierarchy of chromosome elimination and the general existence of genome balance for chromosome stability in interspecific crosses, are discussed.     

Somatic embryogenesis,plant regeneration and somaclonal variation in barley

In vitro culture of immature embryo and young leaf tissues was carried out with five cultivars of barley, Hordeum vulgare. Two cultivars (Albacete and Porthos) responded poorly from both types of explants, while the three others (Dissa, Golden Promise and Ingrid) produced a high frequency of embryogenic callus from these explants (25–60%). For Dissa and Ingrid, young leaf explants were slightly better than immature embryo explants for embryogenic callus induction, while immature embryo cultures of Golden Promise responded better than young leaf explants. Thus, there appears to be a significant genotype × explant interaction in the initiation of embryogenic callus in barley.Some phenotypic variants were detected among the regenerated plants of Golden Promise and Ingrid, most originating by epigenetic changes. Only in one case was the variant phenotype heritable, probably due to a mutation in the chloroplast DNA. Mitotic alteractions were not detected. Consequently, somaclonal variation did not appear to be a very frequent event in plants regenerated from 1- to 6- month-old cultures of barley.     

Plant regeneration and variants from calli derived from immature embryos of diploid barley (Hordeum vulgare L.) and H. vulgare L. x H. bulbosum L. crosses

Summary Plant regeneration from calli was carried out at two locations using several parental genotypes and environments. Selfed immature diploid (VV) barley (Hordeum vulgare) embryos and immature haploid (V) or hybrid (VB) embryos from crosses between H. vulgare and H. bulbosum were used as explants. Golden Promise, Emir and CB 7432 were the best cultivars for plant regeneration, and 15°C tended to be more suitable for plant development than higher temperatures. A total of 844 regenerants were obtained, and over 200 fertile progenies were screened agronomically. Apart from the occurrence of polyploidy and albinism, three variants were identified. One showed maternal inheritance for yellow leaf striping while the other two were controlled by single recessive genes. One of these possessed increased resistance to scald (Rhynchosporium secalis) compared with the donor parent cv Triumph, and one resembled a chlorina mutant.     

Acclimation of barley to changes in light intensity: photosynthetic electron transport activity and components

Barley seedlings (Hordeum vulgare L. Boone) were grown at 20°C with 16 h/8 h light/dark cycle of either high (H) intensity (500 mole m^-2 s^-1) or low (L) intensity (55 mole m^-2 s^-1) white light. Plants were transferred from high to low (H L) and low to high (L H) light intensity at various times from 4 to 8 d after leaf emergence from the soil. Primary leaves were harvested at the beginning of the photoperiod. Thylakoid membranes were isolated from 3 cm apical segments and assayed for photosynthetic electron transport, Photosystem II (PS II) atrazine-binding sites (Q_B), cytochrome f(Cytf) and the P-700 reaction center of Photosystem I (PS I). Whole chain, PS I and PS II electron transport activities were higher in H than in L controls. Q_B and Cytf were elevated in H plants compared with L plants. The acclimation of H L plants to low light occurred slowly over a period of 7 days and resulted in decreased whole chain and PS II electron transport with variable effects on PS I activity. The decrease in electron transport of H L plants was associated with a decrease in both Q_B and Cytf. In L H plants, acclimation to high light occurred slowly over a period of 7 days with increased whole chain, PS I and PS II activities. The increase in L H electron transport was associated with increased levels of Q_B and Cytf. In contrast to the light intensity effects on Q_B levels, the P-700 content was similar in both control and transferred plants. Therefore, PS II/PS I ratios were dependent on light environment.Abbreviations Asc ascorbate - BQ 2,5-dimethyl-p-benzoquinone - DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DCIP 2,6-dichlorophenolindophenol - H control plants grown under high light intensity - H L plants transferred from high to low light intensity - L low control plants grown under low light intensity - L H plants transferred from low to high light intensity - MV methyl viologen - P-700 photoreaction center of Photosystem I - Q_B atrazine binding site - TMPD N,N,N,N-tetramethyl-p-phenylenediamine Cooperative investigations of the United States Department of Agriculture, Agricultural Research Service, and the North Carolina Agricultural Research Service, Raleigh, NC. Paper No. 11990 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, NC 27695-7643, USA.     

Ibf-1 (Iodine binding factor), a highly variable marker system in the Triticeae

Summary Isoelectric focusing of extracts from the endosperm of mature grains of hexaploid wheat and related species was used to study the genetic control of Iodine binding factor (IBF). Ten IBF bands were present in Chinese Spring (CS) and analysis of the nullisomictetrasomic and ditelosomic lines of CS showed nine of them to be controlled by genes on the long arms of the homoeologous group 5 chromosomes. Five alleles were detected at Ibf-A1 locus, four at Ibf-B1 and four at Ibf-D1 among a sample of 46 wheat genotypes. Homoeoloci were found on chromosome 5R of Secale cereale, 5E of Agropyron elongatum, 5U of Aegilops umbellulata, 5Agⁱ of Agropyron intermedium, 5S¹ and 4S¹ of Aegilops sharonensis and 4H of Hordeum vulgare.     

Encoding genes for endosperm proteins in Hordeum chilense

Summary The endosperm proteins encoded by the genome Hch in Hordeum chilense, Tritordeum (amphiploid Hordeum chilense x Triticum turgidum), common wheat-H. chilense addition lines, and the segregating plants resulting from the cross Tritordeum x T. turgidum, were fractionated by three electrophoretical techniques: SDS-PAGE, A-PAGE, and bidimensional PAGE. Prolamin subunits with a high molecular weight (HMW) were well visualized by SDS-PAGE, the A-PAGE technique permitted good resolution for many hordeins and gliadins, and two-dimensional electrophoresis allowed new sets of bands coded by gene complexes from H. chilense chromosomes to be distinguished. The loci Hor-Hch1 (up to 11 subunits belonging to the -, — and -hordeins), Glu-Hch1 (one HMW prolamin subunit), Hor-Hch2 (one -hordein), and Hor-Hch3 (up to four -hordeins) were located on the H. chilense chromosomes 1Hch, 5Hch, and 7Hch.     

Genome specific,highly repeated sequences of Hordeum vulgare: cloning,sequencing and squash dot test

Summary Highly repeated sequences of nuclear DNA from barley Hordeum vulgare (L.) variety Erfa were cloned. Several clones containing barley specific repeated DNA were analysed by sequence analysis and Southern blot hybridization. The investigated repeats differ from each other in their length, sequence and redundancy. Their length ranges from 36 bp to about 180 bp. The repeats are AT-rich and differ widely in their redundancy within the barley genome. Southern analysis showed that the repeats belong to different repetition complexes. The possibility for utilizing these clones as probes for simple and fast genome analysis is demonstrated in squash dot experiments.     

Improvement of isolated microspore culture of wheat (Triticum aestivum L.) through ovary co-culture

Embryogenesis from isolated microspore cultures of wheat was improved by ovary co-culture when compared to a completely defined medium. This indicates that essential factor(s) in addition to PAA or its analogs may be supplied by the ovaries. Isolated microspores cocultured with 20 ovaries of wheat on the top of semi-solid MMS3 induction medium for 21–30 days gave the best response. Both the number and quality of the embryos was significantly increased. The maximum frequencies of dividing microspores and of embryogenesis were 94% and 2.4%, respectively. Up to 2583 embryos were formed per 100 anthers of cv Chris and between 18% and 43% of the larger embryos regenerated into green plants upon transfer. Genotype differences for both induction and embryogenesis phases were reduced using ovary co-culture. However, there was still a strong genotype influence on plant regeneration with cv Chris, with the F1 of Chris × Sinton displaying the highest frequencies. These results are important with respect to enhancing haploidy applications in wheat biotechnology and plant breeding.Abbreviations PAA Phenylacetic acid - MMS modified MS medium - MS Murashige and Skoog's medium 1962 - FHG Hunter's FHG medium 1988     

Sources and inheritance of resistance to leaf curl virus in Lycopersicon

Summary One hundred and twenty-two varieties, lines and wild accessions of Lycopersicon were screened under three different regimes during the autumn/winter season of 1982–83 and 1983–84 for resistance to tomato leaf curl virus (TLCV). L. hirsutum f. glabratum (B6013) and L. hirsutum f. typicum (A1904) proved to be highly resistant to TLCV in all three environments. Various accessions of L. peruvianum were also highly resistant. L. pimpinellifolium (A1921) exhibited no TLCV symptoms within 90 days. Of the cultivated varieties, Acc 99 exhibited the minimim score for susceptibility; AC 142, Collection No. 2, Kalyanpur Angurlata and HS 101 had a low rating for virus incidence. The inheritance of resistance was studied in the interspecific crosses between a TLCV resistant line of L. pimpinellifolium (A1921) and five (HS 101, HS 102, HS 110, Pusa Ruby and Punjab Chhuhara) susceptible cultivars of L. esculentum. Parents, F₁, F₂ and backcross progenies were artificially inoculated with local strains of TLCV using vector the viruliferious whitefly, Bemisia tabaci (Genn.). Data indicated that the resistance of L. pimpinellifolium (A 1921) is monogenic and incompletely dominant over susceptibility.     

Carotenoid pigments in a red strain of Rhizobium from Lotononis bainesii Baker

The carotenoid pigments of a Rhizobium strain isolated from Lotononis bainesii were found to be diglucosyl-4,4-diapocarotene-4,4-dioate and glucosyl-4,4-diapocarotene-4-oate-4-oic acid.5th publication in the series Carotenoids of Rhizobia [4th publication: Helv. chim. Acta 62: 2551–2557 (1979)]     

In vitro propagation and chromosome doubling of a Triticum crassum x Hordeum vulgare intergeneric hybrid

Summary In vitro culture of inflorescence tissue of a Triticum crassum (6x) x Hordeum vulgare cv. Bomi (2x) intergeneric hybrid resulted in the proliferation of totipotent callus from which plants were regenerated. Regeneration was also achieved from immature inflorescence callus of T. crassum but not from H. vulgare. T. crassum x H. vulgare regenerates had a somatic chromosome number of 28, identical to that of the original hybrid. Four chimeric plants with a partially doubled chromosome number were obtained by in vitro colchicine treatment of hybrid callus prior to induction of plant regeneration. All T. crassum regenerates had 35 chromosomes rather than the expected number of 42. Meiotic analysis of a 35-chromosome plant revealed an extremely abnormal meiosis which might be attributable to a complete disturbance in meiotic control system(s) including that of meiotic pairing.Dedicated to Professor Georg Melchers on the occasion of his 75th birthday.Contribution No. 624 Ottawa Research Station, Research Branch, Agriculture Canada, Ottawa, Ont. K1A OC6 (Canada)