Non-random gametoclonal variation in rice regenerants from callus subcultured for a prolonged period under high osmotic stress

Gametoclonal variations were investigated in rice plants regenerated from anther-derived callus after subculture for two different periods (4–6 and 20 weeks) in medium with two levels (292 and 438 mM) of mannitol. A high osmotic stress by mannitol in subculture medium contributed to the maintenance of high regeneration ability. The frequency of diploid regenerants (R₀ plants) increased and that of haploids decreased from callus subcultured for the longer period in medium with the higher concentration of mannitol. R₁ regenerant lines displayed variations in all six agronomical traits studied at the frequencies of 63% and 88% after subculture for 4–6 weeks and 20 weeks, respectively. High homozygosity was suggested in most of the R₁ lines for these traits by the similar levels of variance to those in the control variety. A principal component analysis showed a skewed distribution of variants towards dwarfness and less panicle weight in the regenerants from callus subcultured for 20 weeks with 438 mM mannitol. Two short culmn variants were shown to be due to single or double recessive mutations. The results suggested that prolonged subculture under high osmotic stress causes non-random selection of homozygous gametoclonal variations in rice anther culture. This revised version was published online in August 2006 with corrections to the Cover Date.     

A comparison of somaclonal variation in rice plants derived and not derived from protoplasts

To clarify the effect of the type of in vitro culture on the generation of somaclonal variation, protoplast-derived rice plants were compared with rice plants derived from suspension culture or primary calli (not derived from protoplasts). Regenerated plants showing polyploid-like phenotypes appeared at a higher frequency (33–70%) in plants derived from protoplasts than in those not derived from protoplasts (3–6%). In the first progeny (R₁) generation of all regenerated plants, 120 of 368 lines (33%) segregated plants with mutated characters such as albino, dwarf and sterile. In quantitative traits, 62 (21%) and 144 (50%) of 290 Rj lines showed shorter culm and lower seed-fertility, respectively, compared with the control line derived from the selfed seeds of the original cultivar. The frequency of the mutant-possessing R₁ lines among lines derived from protoplasts was not significantly different from those not derived from protoplasts. These results indicate that isolation and culture of protoplasts does not enhance genetic changes other than cytogenetical changes.     

Somaclonal variation of regenerated plants in chili pepper (Capsicum annuum L.)

The morphological and genetic variations in somaclones of chili pepper (Capsicumannuum L.) derived from tissue culture were evaluated. Cotyledonary node explants of cultivars, Shishitou and Takanotsume, were cultured on Murashige and Skoog (MS) medium supplemented with benzyladenine (BA)5 mg/l for shoots regeneration and regenerated shoots were rooted on MS medium supplemented with naphthalene acetic acid(NAA) 0.1 mg/l and indol-3-butyric acid(IBA) 0.05 mg/l. The regenerated plants(R₀) were selfed to obtain seeds for next generation (R₁ lines). Qualitative characters were studied in R₀generation and both qualitative and quantitative characters were studied in R₁ generation. In R₀ generation, variations were noticed in plant growth habit, stem color, flower color and color of unripe fruits, and expression of anthocyanin in unripe fruits. Comparison among the R₁ lines and their parents were made for morphological and agronomic characters. Significant variation among R₁ lines and differences between R₁ lines and their parents were observed. Genetic variations among three somaclones were revealed by random amplified polymorphic DNA (RAPD) analysis. Variation, such as early flowering and increase of yield components, is an indication of the response to selection for any specific character. Occurrence of productive variants among somaclones of established cultivars, like Shishitou and Takanotsume, indicates the possibility of their improvement through somaclonal variation. This revised version was published online in July 2006 with corrections to the Cover Date.     

Agronomic and morphological characterization of Agrobacterium-transformed Bt rice plants

The agronomic and morphological characteristics of Agrobacterium-transformed rice plants carrying the synthetic cry1Ab or cry1Ac gene were investigated. Tremendous variations in plant height, seed fertility, grain size and other traits were seen in 80 T₁ lines, derived from 80 T₀ plants of 9 rice varieties. On average, about 33% T₁ lines had either morphological or agronomic variant plants. Most of the variations in T₁ plants had no significant correlation with transgene insertion and were proved heritable to their progenies. Genetic analysis in T₃ or T₄ generations showed some simple mutations such as chlorophyll deficiency and stunted plants were independent of transgene insertion and seemed to be controlled by a pair of single genes. However, in two independent transgenic progenies of Xiushui 11, all plants homozygous for transgenes showed dwarfism while all hemizygous and null segregants had normal plant heights. Two advanced homozygous Bt lines, KMD1 and KMD2, were developed from these two progenies. Comparison of the agronomic traits of KMD1 and KMD2 with their parent displayed marked differences among them in terms of seedling growth, tillering ability, yield components and yield potential. The genetic variation observed was generally not linked to the transgene locus and was ascribed to somaclonal variation, but other causes might also exist in particular cases. The results are discussed in the context of choosing appropriate transformation methodology for rice breeding programs. This revised version was published online in August 2006 with corrections to the Cover Date.     

The influence of auxin type on the array of somaclonal variants generated from somatic embryogenesis of eggplant, Solanum melongena L.

Somaclonal variation is a possible source of variation in plant breeding. To apply this approach to eggplant breeding, somaclonal variations were observed among plants regenerated through somatic embryogenesis induced by 1-naphthaleneacetic acid (NAA) or 2,4-dichlorophenoxyacetic acid (2,4-D). Variations including leaf shape, plant height, flower number per cluster, fruit shape, anther number per flower and pollen fertility were compared among ? 300 plants (R₀). Although these variations were confirmed among plants regenerated using both auxins, the frequencies of somaclonal variations in leaf shape, plant height, fruit shape and pollen fertility in the NAA experiment were higher than those in the 2,4-D experiment. Variations in flower number and anther number were also confirmed among plants from both experiments, although no significant differences in their frequency were observed. Subsequently, the inheritance of variations (leaf shape, fruit shape, and flower number) observed in R₀ was investigated from generation to generation (R₁). Variations in leaf shape and fruit shape were inherited while those in flower number were not. From these results we concluded that, although a high frequency of somaclonal variations were observed among plants from both methods, embryogenesis with NAA was more efficient than 2,4-D in eggplant.     

Effect of Mutagenic Treatments on Somaclonal Variation in Wheat (Triticum aestivum L.)

Different wheat genotypes were treated with gamma-rays, sodium azide (SA) and EMS before tissue culture and immature embryos from M₁ plants or plants shortly after exposure to gamma-rays were used to initiate callus culture. Thousands of plants were regenerated and used to investigate the effect of mutagenic treatments on the regenerated plants and somaclonal variation in the M₃R₂ and M₂R₂ generations. The results showed that mutagen-induced damage in terms of reduction in plant height, fertility and spike length were not outstanding in the regenerated plants as compared with the untreated control. In the M₃R₂ generation, only SA treatment had significantly higher frequencies of somaclonal variations than the control. Increases in the variation frequencies were observed when explant embryos were irradiated with 2.5 and 5 gy gamma-rays and the highest frequency appeared when embryos were exposed to 5 gy gamma-rays on the 5th day after anthesis. Increased variation spectra also resulted from mutagenic treatments and most of the variants recovered were unsuitable for plant improvement.     

Genetic variability in plants regenerated from in vitro culture of sunflower (Helianthus annum L.)

In vitro regenerated sunflower (Helianthus annuus L.) plants (R₁) were self-fertilized and the R₂ generation was evaluated for qualitative traits. A broad range of phenotypic variation was observed and mutation frequencies were calculated. Some in vitro induced variant phenotypes were similar to known spontaneous or induced mutations in sunflower, while others were new. Chlorophyll and carotenoid deficiencies, chimaerical variegation, fasciated stem and capitulum, abnormal shoot development, and other morphological variations, were noted. Substitution of anthers with petaloid structures in a disk-floret mutant indicates a possible homeotic mutation induced by in vitro tissue culture.     

Association of isozyme genotypes with agronomic and seed composition traits in soybean

Summary Two crosses between Glycine max (L.) Merr. and G. soja Sieb. & Zucc. parents were used to study the association between isozyme marker loci and agronomic and seed composition traits in soybean. The parents possessed different alleles at six isozyme loci for Cross 1 (A80-244036 × PI 326581) and at eight isozyme loci for Cross 2 (A81-157007 × PI 342618A). A total of 480 BC₂F_4:6 lines from the two crosses was evaluated for 13 traits in two environments. Lines were grouped in locus classes from 0 to 5 according to the number of loci homozygous for the G. soja alleles that they possessed. Within each locus class, each isozyme genotype was represented by five random lines.Selection for G. max alleles at the isozyme loci was not effective in recovering the recurrent parent phenotype in either cross. In cross 1, however, BC₂F₄-derived lines in the 0- or 1- locus class more closely resembled the G. max parent than lines in the 4- or 5- locus classes for most of the agronomic and seed composition traits evaluated. Significant associations were found between particular isozyme genotypes and every trait analyzed. The estimated effect of genes linked to the Pgm1 locus was a delay in maturity of 6.0±3.4 days. In cross 1, the Idh2 locus was associated with a significant effect on linolenic acid content. The percentage of variation accounted for by the models of estimation varied according to the heritability of the trait. The R² was high (up to 78%) for maturity, lodging, and vining, and low (up to 21%) for seed yield. Most of the variation was associated with the BC₂F₁ family from which the lines were derived. There was little evidence that digenic epistasis was an important source of variation.Journal Paper No. J-13505 of the Iowa Agric. Home Econ. Exp. Stn., Ames, IA, Project 2475.     

High frequency regeneration and heritable somaclonal variation in Brassica juncea

Summary Multiple shoot formation in cotyledonary callus of Indian mustard (Brassica juncea cv. Prakash) was induced on modified MS media supplemented with high cytokinin (kinetin or zeatin) and low IAA concentrations. Complete plants were obtained on prolonged incubation of shoots on the same medium. 6-Benzyladenine alone or in combination with IAA or NAA did not support plantlet regeneration. A total of 71 plants were transferred to greenhouse. The seed, however, could be collected from 37 plants only. The seed was sown in the field to evaluate the material for somaclonal variation in R₁ generation. Data were recorded for yield, plant height, number of primary branches, siliqua number, 1,000 seed weight and oil content. Somaclonal lines showed tremendous amount of variation for all the characters studied. A number of plants in this generation showed significantly higher yield and/or other improved agriculturally important characteristics as compared to the control. A line with dwarf plant type was also identified. A number of plants were selected from this generation and carried forward to R₂ generation. Most of these lines bred true in R₂ generation. The material seems to be very promising for future breeding programmes.     

In vitro Culture of Cucumis sativus

The variability of morphological traits in 1800 individuals of R₂ generation of Cucumis sativus was studied. R₂ generation was obtained from 60 R₁ planes which regenerated from leaf explants of a highly inbred Line of cv. Borszczagowski. All the plants of R₁ population were phenotypically identical with the initial variety; some (8,3 %) of the R₂ progeny, however, exhibited segregations. Variability was manifested in the following traits: 1. type of growth (dwarf and bushy), 2, male sterility, 3, mosaic type leaves, 4, xantha type chlorophyll change. In R₃ generation, only one new phenotype (yellow fruit flesh) has been found. The traits mentioned above were frequently accompanied by lower viability and fertility of R₂ plants. The latter was connected with disturbances in microsporogenesis and lover pollen germination ability. Genic instability of one trait is described.     

Towards development of Al-toxicity tolerant lines in indica rice by exploiting somaclonal variation

Somaclonal variations, induced in vitro, were used to enhance tolerance to aluminium (Al) toxicity in rice. Tolerant plants were developed through in vitro screening of embryogenic calli. The calli were derived from mature seed embryos and cultured on medium stressed with different concentrations of Al₂(SO₄)₃⋅18H₂O. Seed germination, callus induction, plantlet regeneration and callus health declined with increased concentration of Al. At higher Al concentrations, callus health deteriorated drastically with partial to total necrosis. Plantlet regeneration varied largely among varieties and treatments. The variety IR72 produced maximum plantlets among all genotypes tested. An amount of 60 ppm or more Al was highly toxic, which greatly reduced plantlet regeneration from callus. R₀ plantlets were grown under glasshouse. Based on the appearance of bronzing symptoms on leaves, the tolerant R₁ plants were selected. R₁ and R₂ lines derived from putative tolerant somaclones, were evaluated in fiberglass tanks filled with Al-toxic soil. R₃ population was evaluated in the field. A few lines derived from IR72 showed high yield and good plant type. The progenies at R₃ showed normal root growth under stressed environment in sand culture. The study revealed that in vitro screening would be an appropriate alternative to conventional breeding in evolving Al-tolerant lines as observed in case of other abiotic stresses. The technique was useful in creating de novo synthesized Al-tolerance character in rice.     

Salt-tolerance in Brassica juncea L. I. In vitro selection,agronomic evaluation and genetic stability

Summary In vitro selection of salt tolerant plants of Brassica juncea L. (Indian mustard) cv. Prakash has been accomplished by screening highly morphogenic cotyledon explant cultures on high NaCl media. Out of a total of 2,620 cotyledons cultured on high salt medium, 3 survived, showed sustained growth and regenerated shoots. They were multiplied by axillary bud culture on NaCl free medium. The salt-selected shoots retained salt tolerance following 3 month of growth and multiplication on control medium. While two of these somaclones flowered and set seeds, third one grew slowly, had abnormal leaf morphology and was sterile. The seed of the two fertile plants were sown in the field to raise R₁ segregating generation. Data were recorded for field, other agronomic components and oil content. The somaclonal lines, both selected salt-tolerant and non-selected, showed tremendous amount of variation for all the characters studied. One of the two tolerant somaclones invariably showed reduced height, longer reproductive phase and higher 1000 seed weight. Based on the agronomic performance of R₁ plants of these somaclones, some plants were selected and their progeny were evaluated for agronomic performance under standard field conditions and salt-tolerance in the greenhouse using sand pot culture method. Most of the lines bred true for their specific characteristics. In the greenhouse, selected salt-tolerant somaclones (SR-2 and SR-3) performed better for plant growth, yield and other agronomic traits at higher salt treatments, indicating thereby that salt-tolerance trait selected in vitro was expressed in the whole plants and is genetically stable and transmitted onto the progeny. The two tolerant lines, however, differed in their salt-tolerance during vegetative and reproductive phases as indicated by their salt-tolerance and stress susceptibility indices. The mechanism of salt-tolerance is not clear and needs to be further investigated.     

In vitro screening and field evaluation of tissue-culture-regenerated sorghum (Sorghum bicolor (L.) Moench) for soil stress tolerance

Summary Sorghum bicolor (L.) Moench is generally quite sensitive to salt and acid (high aluminium) soil stresses, but quite tolerant of drought stress. As with any stress phenomenon, intra-specific variability exists within the genus. In vitro cell selection and somaclonal variation offer an alternative to traditional breeding methodology for generating improved breeding lines for hybrid development. A field selection protocol was developed for the three soil stresses and inter-stress evaluations were conducted in an effort to find multiple, stress-tolerant genotypes. The acid soil-drought stress, super-tolerant selections were located by the R₇ generation when exposed to a combined aluminium-drought stress field environment and when the regeneration population (number of regenerated lines from one callus source) was maintained at 15,000 plants or higher. A variant frequency of 0.1 to 0.2% for stress tolerance and acceptable agronomic traits among the surviving somaclones, provided an adequate number of phenotypes with desirable agronomic characteristics and a high level of soil stress tolerance. Subsequent research verified that the stress-tolerant regenerants had superior acid soil and drought stress tolerance to that of the donor parents, that their yield capabilities under stress were superior to their parents, and that their stress tolerance attributes were transferred in hybrid combinations. In vitro selection was not effective in increasing the number of field stress survivors. In fact, superior germplasms were developed from non-stressed callus or salt-stressed callus. In vitro selection reduced regeneration frequency and subsequent survival of plants under field stress. In vitro-stressed regenerants should be subjected only to non-stressed environments to maintain population numbers for field selection and thereafter should be subjected to stress environments during later (R₅₊) generations. The optimal strategy for the exploitation of somaclonal variation may be through short-term cell culture (< 12 months) with no attempt at in vitro selection.     

Inheritance of resistance to Fusarium wilt and yield traits in pigeonpea

Fusarium wilt is the main pigeonpea production constraint in Malawi. The purpose of the study was to understand the nature and mechanism of inheritance of F. wilt resistance, yield and secondary traits in pigeonpea. 48 crosses were generated in a 12 lines × 4 testers mating scheme. Some F₁ plants were selfed for segregation analysis for inheritance pattern of resistance, while others were evaluated for resistance, yield and secondary traits. There were significant variations among F₁ plants for F. wilt, days to 50 % flowering, seed/pod, and number of secondary branches. Specific combining ability (SCA) effects were predominant for F. wilt, days to 50 % flowering and number of secondary branches. The general combining ability (GCA) effects, mainly due to maternal genotypes, were preponderant for yield and other secondary traits. The significance of GCA and SCA effects suggested that variations were due to additive gene action in both the testers and parental lines arising from their interactions, and the dominance effects due to interactions of the parental lines. The χ² analysis suggested dominant patterns of inheritance for wilt in most of the F₂ populations. The segregation ratios of 3:1, 15:1, and 9:7 suggested the involvement of single or two independent/complementary dominant genes in the test donors. Involvement of a few genes governing wilt resistance suggested the ease of breeding for this trait. Pedigree breeding method would be recommended for incorporating various traits in pigeonpea.     

Somatic Embryogenesis in Maize and Comparison of Genetic Variability Induced by Gamma Radiation and Tissue Culture Techniques

Sixteen inbred lines and one hybrid of manse were tested for their capability of somatic embryogenesis, and fully developed plants could be regenerated, from ten inbred, lines. The highest frequency of plant regeneration was expressed in the inbred line CHI 31, and when this line was crossed with a recalcitrant, non-regenerating line, the F₁ and BC hybrids were regenerable. The results of reciprocal crosses demonstrated that dominant nuclear genes and cytoplasmic factors are primarily responsible for the heritable determination of embryogenic callus proliferation and in vitro regeneration of maize plants. Somaclonal and radiation-induced variability was studied in maize to assess their nature and potential contribution to plant breeding., The inbred line CHI 31 possessing a high in vitro capacity of somatic embryo formation was used as experiments.] material. CHI 31 plants were selfed and twelve-day old zygotic embryos irradiated with ⁶⁰Co gamma radiation in situ. Mature caryopses were harvested and assigned as M₁ material. In another series, immature zygotic embryos (size 1.2—1.5 mm) were cultured in vitro on N-6 medium supplemented with 2,4-D (2.5 μM), and somatic embryos regenerated into plants; these were transplanted into soil and self-pollinated. Regenerants from non-irradiated cultures were grown as R₁ generation, while regenerants from irradiated explants were considered as M₁R₁ generation. The genetic variability was evaluated in the M₂, R₂ and M₂R₂ generations, respectively, and compared with a non-treated seed control. Irradiation induced a variety of chlorophyll and morphological variants segregating in the M; generation; however, the frequency of deviant types obtained in the R: generation (somaclonal variation) was significantly exceeding the one derived from the M₂ populations. The combination of expert irradiation and in vitro regeneration was most effective for the manifestation of chlorophyll and morphological o if types in the M₂R₂ generation, and increased drastically the frequency of early flowering variants. Differences in the segregation patterns of mutant phenotypes amonsister somaclones in the R₃ and M₃R₃ generations indicate a different genetic basis, of plants originating from the same explant. This phenomenon suggests a mutational sectoring of the callus during culture. Radiation induced and somaclonal variation exerted a similar spectrum of chlorophyll and morphological deviants.     

Relationship between somaclonal variation and type of culture in cucumber

Highly inbred B line of cucumber was used to compare the effect of four types of in vitro culture on somaclonal variation. The plants were regenerated from the following types of culture: twelve- and eighteen-month-old liquid culture of meristematic clumps (LMC₁₂₍₁₈₎), ten-month-old embryogenic cytokinin-dependent suspension (CDS), eighteen-month-old embryogenic cytokinin-dependent suspension in medium with modified NH⁺ ₄/NO₃ ^- ratio (CDS 1.7), twelve-month-old embryogenic auxin-dependent suspension (ADS), thirty six-month-old embryogenic auxin-dependent suspension in medium with modified NH⁺ ₄/NO₃ ^- ratio (ADS 1.7) and recurrent leaf callus regeneration (RLC) – repeated 5 times. The differences in the incidence of the following properties were observed: the ploidy of R₀ plants, the segregation of new morphological traits in R₁ and the germination ability of R₁ seeds. R₁ families with the segregation of new phenotypes were most numerous in CDS (62.5%) and LMC₁₈ (57.9%), next in CDS1.7 (35.7%), while the smallest number was found in LMC₁₂ (11.1%) and RLC (3.4%).Tetraploid and mixoploid plants occurred in ADS1.7 and ADS (100%) whereas CDS and RLC were observed to contain only tetraploids, respectively 33.3% and 55.2%. There were no changes of ploidy after LMC₁₂, LMC₁₈ and CDS1.7. Among new phenotypes there were such that have not been described so far in cucumber: ginkgolike leaf (gll), yellow-green chlorophyll mutants (y-gc), serrate margin of corolla in male and female flowers (smc). This revised version was published online in August 2006 with corrections to the Cover Date.     

Improved frost tolerance and winter survival in winter barley (<Emphasis Type="Italic">Hordeum vulgare</Emphasis> L.) by <Emphasis Type="Italic">in vitro</Emphasis> selection of proline overaccumulating lines

Embryogenic calli derived from anther cultures of the two-rowed winter barley cultivar Igri were plated on solid L3 medium containing the proline analogue hydroxyproline (Hyp), 10–20 mmol l^–1. Exposure to Hyp caused severe degeneration of most of the calli. Hyp resistant calli, distinguishable by their lighter colour and higher growth rate, and control calli not exposed to Hyp were plated on L3 regeneration medium. From 22,500 anthers exposed to Hyp 46 Hyp resistant regenerates were obtained, which were transferred to soil. After cultivation for 5–10 weeks at normal growth conditions they were cold hardened at 2 C under short day conditions together with control regenerates. Frost tolerance assays with segments of fully grown leaves of unhardened and cold hardened plants revealed that Hyp resistant regenerants were significantly more frost tolerant than the control regenerants. Improved frost tolerance was found also in the progenies R₁ to R₉, and genotypic segregation in the R₁ generation in a 1:2:1 ratio was indicated. Increased proline content was observed in the R₂ generation and in subsequent generations and was significantly (P 0.001) correlated with increased frost tolerance in the Hyp lines. Comparative studies of R₉ progenies from homozygous R₂ plants with the wild type Igri under field conditions in winter at three locations in Europe as well as crossing experiments confirmed the heritable improvement of frost tolerance and winter survival, respectively, in the Hyp lines. The results support the hypothesis that proline accumulation in cold acclimated winter barley plants is causally related to the acquisition of frost tolerance. Moreover, the described biotechnological procedure may be applicable in breeding programs for improved winter hardiness and possibly also for other stress tolerances.     

Effect of chromosome-doubling agents on somaclonal variation in the progeny of doubled haploids of maize

This study was carried out to determine whether the treatment of anther-culture-derived haploid callus of maize (Zea mays) with chromosome-doubling agents, such as colchicine or the herbicides pronamide and amiprophos-methyl (APM), induces higher than normal levels of somaclonal variation. A total of 79 R₁ families produced by diploid regenerated plants resulting from chromosome-doubling treatments were evaluated in the field in comparison with the three parental inbreds. Four qualitative variant phenotypes — male sterility, chlorophyll deficiency, earless plants, and short plants with narrow leaves and thin stalks —– were observed. The last phenotype (narrow leaves and thin stalks) was also found in the inbreds FR16 and H99 grown from seed, so it may not be directly related to the tissue-culture conditions or the anti-microtubule-agent treatments. The frequency of R₁ families segregating for the other three mutations was 3.8%, which is no higher than the somaclonal variation frequencies observed previously in tissue-culture-derived maize plants. Observations of three quantitative traits—–days to anthesis, days to silk emergence, and plant height—– also failed to detect any extra variation that could be related to the treatments with anti-microtubule agents. These studies indicate that the anti-microtubule agents APM, pronamide and colchicine can be used to induce chromosome doubling of anther-culture-derived callus to produce a high proportion of doubled haploid plants without causing increased rates of mutation (somaclonal variation).     

Mapping QTLs for salt tolerance in an introgression line population between Japonica cultivars in rice

QTL analysis of physiological traits related to salt tolerance was carried out using 117 BC₃F₅ lines derived from a cross between “Ilpumbyeo” as a recurrent parent and “Moroberekan” as a donor parent. The 117 introgression lines with the parents were evaluated for five traits; dry weight, fresh weight, leaf area, seedling height, and survival rate under control and salinity conditions (55 mM) at the seedling stage. To identify QTLs related to salt tolerance, 125 SSR markers showing polymorphisms between the parents were genotyped for the 117 BC₃F₅ lines. A total of eight QTLs were detected on chromosomes 1, 6, and 7. These include two QTLs on chromosomes 6 and 7 for reduction rate of dry weight (R² = 10.2∼13.6%), three QTLs on chromosomes 1, 6, and 7 for reduction rate of fresh weight (R² = 10.9∼13.9 %), two QTLs on chromosomes 1 and 7 for reduction rate of leaf area (R² = 12.1%), and one QTL on chromosome 7 for reduction rate of seedling height (R² = 10.5%). The Moroberekan alleles contributed the positive effect at these eight QTL loci. Although the parents, Ilpumbyeo and Moroberekan, were not salt tolerant as the salt tolerant check variety, Pokkali, some lines displayed a similar level of tolerance as Pokkali. The effect of the QTL on chromosome 7 was further confirmed by evaluating four lines containing the target QTL for fresh and dry weight, turgid weight, and relative water content (RWC). Significant differences between each line and Ilpumbyeo were detected for dry and fresh weight, and RWC values, and these results seem to indicate the beneficial effect of the Moroberekam alleles for salt tolerance. A set of introgression lines are being developed containing only few chromosomal segments from Moroberekan in the Ilpumbyeo background. These would be useful in developing salt tolerant lines in the breeding program.     

Induction and selection of mutations for resistance against bacterial leaf blight in rice

Summary Dry seed lots of a rice cultivar, Harebare, susceptible for bacterial leaf blight (BLB), were exposed to thermal neutrons with and without pre-treatment of seed for boron-enrichment, and to gamma-rays. M₁ plants of each of the treatments were grown and their seeds were separately harvested. M₂ populations were raised in rice fields of a farmer in a region where BLB is epidemic every year, and M₂ and control plants which expressed resistant reactions to BLB were selected. M₃ and control lines as plant progenies of the selected M₂ plants were raised in the same rice fields as in M₂ generation in order to investigate their BLB resistance and other agronomically important traits. Variances for disease severity of M₂ populations were significantly larger than those of the control population. whereas their means were not singificantly different from that of the control population, suggesting induction of mutations toward both resistance and susceptibility to BLB. Mean disease severity values of the M₃ lines from selected M₂ plants were significantly smaller than those of the control lines, indicating gains of selection in M₂ for quantitative resistance against BLB. Thermal neutrons, especially with boron-enrichment pre-treatment were effective to induce mutations for resistance against BLB. Some M₃ mutant lines with quantitatively enhanced resistance against BLB were not modified in other agronomic traits from those of the original cultivar. Significance of the induced quantitative resistance in breeding programmes for BLB resistance is discussed.