Cryopreservation of shoot primordia cultures of melon using a slow prefreezing procedure

Tissue-cultured shoot primordia of melon (Cucumis melo L. cv. prince melon) were successfully cryopreserved in liquid nitrogen (LN) using a slow prefreezing method. The highest survival and recovery were obtained with the following procedure. Three week-old shoot primordia clumps were dissected into pieces of 2-3 mm of diameter and precultured in standard medium for 3 days. They were directly soaked in CSP1 cryoprotective solution (10%w/v sucrose, 10%w/v dimethylsulfoxide and 5%w/v glycerol) and incubated at room temperature for 30 min. Samples were ice-inoculated at -8 °C and cooled at a rate of between 0.3 and 1 °C min⁻¹ with a programmable freezer to -30 °C for prefreezing. They were then plunged into LN for storage. After rapid thawing in 40 °C water, the cryoprotective solution was slowly diluted 5 fold in a dropwise manner with 3% sucrose and the shoot primordia were transferred onto regeneration medium. Under optimal conditions, more than 80% of cryopreserved shoot primordia were viable and 50 to 80% regenerated shoots after one month of reculture. Cryopreserved shoot primordia could be used both for reproducing a shoot primordia culture and for regenerating plants. This revised version was published online in June 2006 with corrections to the Cover Date.     

Genomic rearrangement in long-term shoot competent cell cultures of hexaploid wheat

Summary By use of a method for regenerating wheat plants (Triticum aestivum L.) from cells from long-term suspension culture, the chromosome complement and stability of cultured cells of cv. Mustang were examined. Massive chromosome restructuring and genomic rearrangements were detected by HCl−KOH-Giemsa banding techniques. Chromosome structural variations involved mainly heterochromatin and centromeric regions. These included B genome chromosome elimination; heterochromatin amplification; megachromosomes and extrachromosomal DNA particles; translocations and deletions; telocentric, dicentric, and multicentric chromosomes; and somatic pairing and crossing over. At least 65 break-fusion sites were identified. Most of the sites were located in the B genome chromosomes (42 sites, 64.6%); 36.9% (20 sites) were located in the A genome chromosomes; and the fewest (3 sites, 4.6%) were detected in the D genome. Most of the chromosome break-fusion is in the heterochromatin and centromeric regions. The B genome chromosomes appeared to be eliminated nonrandomly, and the stability of the genome may vary among the genotypes and depend on culture duration. We also checked chromosome number of 1-year-old shoot-competent cells. Only 20% of the cells still had 2n=42 chromosomes. Most of the cells (60%) were hyperploid. These observed variations describe the types of tissue-culture-induced variations and suggest the unsuitability of using wheat cells from long-term cultures for genetic transformation experiments.     

Photoautotrophic shoot and root development for triploid melon

The aim of this investigation was to establish environmental factors which promote growth and photosynthesis of melon (Cucumis melo L.) shoot buds, in vitro, and determine if photoautotrophic shoots had superior root forming ability in photoautotrophic environments. Buds from the triploid melon clone ‘(L-14×B)×L-14’ were observed for 21 days after transfer from a multiplication MS medium with 3% sucrose and 10 μM benzyladenine (BA) to a shoot development medium with 1 μM BA at three levels of sucrose in the medium (0, 1 and 3%), and light (50, 100 and 150 PPF) and CO₂ (500, 1000 and 1500 ppm) in the culture chamber. More shoot buds were observed with 3% sucrose in the medium. Increased light and CO₂ had a positive interaction with shoot proliferation. Fresh and dry weights were greatest at 3% sucrose, 150 PPF light and 1500 ppm CO₂. Shoot buds grew more slowly in sugar-free medium, but fresh and dry weight still doubled over 21 days of culture. Net photosynthetic rates (NPR) of buds were negative after four days in treatment conditions, but became positive after transfer to fresh, sugar-free medium. Two triploid genotypes of melon were (1) grown in vitro with sugar (photomixotrophic) and without sugar (photoautotrophic), (2) rooted in sugar-free media, both in a laboratory controlled environment chamber (in vitro) and a greenhouse acclimatization unit (ex vitro), and (3) compared for subsequent nursery growth in the greenhouse unit. The genotype ‘(L-14×B)×L-14’ produced more shoots than ‘(L-14×B)×Mainstream’ in both photomixotrophic or photoautotrophic conditions. ‘(L-14×B)×L-14’ rooted as well from either photoautotrophic and photomixotrophic shoots but ‘(L-14×B)×Mainstream’ rooted less frequently from photoautotrophic shoots. Seventy-six percent of the shoots in the laboratory controlled environment chamber were able to root photoautotrophically, whereas 47% of the shoots in the greenhouse acclimatization unit were rooted. Between 77% and 88% of plantlets from all treatment combinations survived transfer to the nursery. After growth in the nursery, the sizes of plants (fresh weight, dry weight, leaf area) were the same for either genotype, from either photoautotrophic or photomixotrophic shoots. Nursery plants that had been rooted in the laboratory controlled environment chamber were larger than those rooted in the acclimatization greenhouse chamber. This revised version was published online in June 2006 with corrections to the Cover Date.     

Boron and salinity effects on grafted and non-grafted melon plants

Production of melon (Cucumis melo) may be limited by excesses of boron and salinity, and it was hypothesized that melon grafted onto Cucurbita rootstock would be more tolerant to excessive boron concentrations than non-grafted plants. The objectives of this study were (i) to determine the effects of salinity and excessive boron concentrations in irrigation water on growth and yields of grafted and non-grafted melon plants; and (ii) to study the interaction between the effects of salinity and boron on the uptake of macroelements and boron by grafted and non-grafted melon plants. The plants were grown in pots of Perlite in a greenhouse. The combined effects of boron and salinity on growth and yield were investigated for five boron concentrations, ranging from 0.2 to 10 mg L^{− 1}, and two salinity levels, electrical conductivity (EC) 1.8 and 4.6 dS m^{− 1}, in the irrigation water. With low salinity the boron concentrations in old leaves of non-grafted and grafted plants ranged from 249 to 2827 and from 171 to 1651 mg kg^{− 1} dry weight, respectively; with high salinity the corresponding concentrations ranged from 192 to 2221 and from 200 to 1263 mg kg^{− 1} dry weight, respectively. These results indicate that the grafted plants accumulated less boron than the non-grafted plants when they were exposed to similar boron concentrations, and that both plant types absorbed less boron when irrigated with the more saline irrigation water. It is suggested that: (i) the Cucurbita rootstock excluded some boron and that this, in turn, decreased the boron concentration in the grafted plants; and (ii) the low boron uptake under high-salinity irrigation was mainly a result of reduced transpiration of the plants. Significant negative linear regressions were found between fruit yield and leaf boron concentration for grafted plants, under both low and high salinity levels, and for non-grafted plants under low salinity. The fruit yield of the grafted plants was less affected by boron accumulation in the leaves than that of non-grafted plants. Increasing the water salinity decreased the sensitivity of both plant types to increases in leaf boron concentration, which indicates that the effects of boron and salinity on melon plants were not additive.     

Role of leaf glandular trichomes of melon plants in deterrence of Aphis gossypii Glover

External characteristics of the leaf epidermis and their effects on behaviour of Aphis gossypii Glover were evaluated in two Cucumis melo L. genotypes, ‘Bola de Oro’ (aphid susceptible) and TGR‐1551 (aphid resistant) in order to explore their role in the early rejection of TGR‐1551 by this aphid. No differential effects of epicuticular waxes on aphid behaviour were observed. The type, distribution and number of trichomes on melon leaves were also studied. Pubescence in melon, measured as the number of non‐glandular trichomes per cm², was not sufficient to prevent aphid settling. However, there was a high density of type I glandular trichomes on leaves of the aphid‐resistant genotype. According to microscopic observations and stain testing, these trichomes store and secrete phenols and flavonoids. Free‐choice tests were conducted to determine the effect of these glandular trichomes on A. gossypii preference, revealing that aphids reject leaf disks of TGR‐1551 from the onset of the experiment. Additional experiments after removal of leaf type I glandular trichome exudates showed that A. gossypii preferred washed TGR‐1551 leaf disks over unwashed disks, while this effect was not observed in experiments using washed and unwashed ‘Bola de Oro’ leaf disks. These results suggest that a high density of glandular trichomes and chemicals secreted by them deter A. gossypii and disturb aphid settling on TGR‐1551.     

Effect of genotype on callus induction,shoot regeneration,and phenotypic stability of regenerated plants in the greenhouse of Primula ssp.

Genotypic differences between six genotypes of Primula vulgaris could be observed in callus induction rate, type of callus, root formation during the callus phase, and shoot regeneration rate. The shoot regeneration rate ranged from zero to 11.6 shoots per explant. There was no correlation between callus induction rate and shoot regeneration rate. Callus consistency and colour were an indicator of the organogenetic capacity of callus. An experiment with different periods of treatment with 4.0 mg l 2,4-dichlorophenoxyacetic acid and 2.0 mg l21 thidiazuron revealed that the shoot regeneration rate varied tremendously between genotypes. In two genotypes a period of 8 weeks on medium with plant growth regulators was sufficient to induce shoot regeneration. In three other genotypes a longer induction period was not able to overcome low regeneration capacity. However an increase in shoot regeneration rate was observed after 16iV32 weeks of induction. Phenotypic stability was also strongly dependent on genotype. In three genotypes the majority of regenerated plants looked normal and were diploid. Aberrations like abnormal growth habit, crinkly leaves, deviation of flower colour or lack of pollen formation occurred in only one genotype at a very low frequency (1.5 genotypes between 12.5 and 18.1 regenerants was tetraploid.     

Analysis of genetic stability of plants regenerated from suspension cultures and protoplasts of meadow fescue (Festuca pratensis Huds.)

A cytological and molecular analysis was performed to assess the genetic uniformity and true-to-type character of plants regenerated from 20 week-old embryogenic suspension cultures of meadow fescue (Festuca pratensis Huds.), and compared to protoplastderived plants obtained from the same cell suspension. Cytological variation was not observed in a representative sample of plants regenerated directly from the embryogenic suspensions and from protoplasts isolated therefrom. Similarly, no restriction fragment length polymorphisms (RFLPs) were detected in the mitochondrial, plastid and nuclear genomes in the plants analyzed. Randomly amplified polymorphic DNA markers (RAPDs) have been used to characterise molecularly a set of mature meadow fescue plants regenerated from these in vitro cultures. RAPD markers using 18 different short oligonucleotide primers of arbitrary nucleotide sequence in combination with polymerase chain reaction (PCR) allowed the detection of pre-existing polymorphisms in the donor genotypes, but failed to reveal newly generated variation in the protoplast-derived plants compared to their equivalent suspensionculture regenerated materials.The genetic stability of meadow fescue plants regenerated from suspension cultures and protoplasts isolated therefrom and its implications on gene transfer technology for this species are discussed.Abbreviations PCR polymerase chain reaction - RAPD random amplified polymorphic DNA - RFLP restriction fragment length polymorphism.     

Purification and Some Properties of a Protease from the Sarcocarp of Musk Melon Fruit

A protease has been purified from sarcocarp of musk melon, Cucumis melo ssp. melo var. reticulatus Naud. Earl’s Favourite. The protease was mostly present in the placenta part of the fruit and next in the inside mesocarp. The molecular mass of the enzyme was estimated to be about 62kDa on SDS-PAGE. The enzyme had a carbohydrate moiety. The optimum pH of the enzyme was 11 at 35°C using casein as a substrate. The enzyme was stable between pH 6 and 11. The enzyme was strongly inhibited by diisopropyl fluorophosphate, but was not inhibited by EDTA or cysteine protease inhibitors. From the digestion of Ala-Ala-Pro-X-pNA (X = Phe, Leu, Val, Ala, Gly, Lys, Glu, Pro, and diaminopropionic acid (Dap) substrates the specificity of the protease was found to be approximately broad, but the preferential cleavage sites were C-terminal sites of hydrophobic or acidic amino acid residues at P, position. It was proved that the enzymatic properties of musk melon protease are similar to those of cucumisin [EC 3.4.21.25]. The enzyme was not inhibited by typical proteinous inhibitors such as STI or ovomucoid. Therefore, this enzyme seems to be a useful protease for the food industries.     

Genotype and medium affect shoot regeneration of melon

The effects of basal media, growth regulators and gelling agents on the morphogenetic response of eleven Cucumis melo L. var. reticulatus and inodorus genotypes were examined. Regeneration was achieved from cultured cotyledons of all genotypes and the morphogenic response was affected by the genetic background. Among the combination of factors tested, MS basal medium supplemented with 2.8 M 6-benzyladenine (BA) and 1.0 M abscisic acid (ABA) solidified with agar gave the highest frequency of shoot regeneration.Abbreviations ABA abscisic acid - BA 6-benzyladenine - TDZ thidiazuron     

Plastome data analysis of Cucumis melo subsp.agrestis

It is of interest to refine the taxonomic status of C. melo ssp. agrestis using its plastome data. The chloroplast size and GC% was found to be 1,56,016 bp and 36.92% respectively in Cucumis melo subsp. agrestis. The plastome of C. melo subsp. agrestis comprises of two inverted repeat (IR) regions of 25,797 bp each. It consisted of 133 genes with 88 protein-coding genes, 8 rRNA genes and 37 tRNA genes. Analysis of the C. melo ssp. agrestis plastome data will help breeders to improve the yield the crop.     

Shoot regeneration in long-term callus cultures derived from mature flowering plants of Cyclamen persicum Mill.

Summary In long-term callus cultures of Cyclamen persicum Mill. two types of tissue could be distinguished. One type featured a brown suberised outer layer and was poorly organogenic. The other type was yellowish in appearance and gave rise to many shoot buds. Both types co-existed on the same callus, the former prevailing. Selection for organogenic tissue resulted in cultures yielding approximately three times more petioles than random subcultures. Callus-derived shoots could be rooted and established in the greenhouse. The method allowed for the production of thousands of plants but the regenerants often showed deviant phenotypes and genotypes.Abbreviations BA 6-benzylaminopurine - BMP basal medium propagation - BMR basal medium rooting - DAPI 4,6-diamino-2-phenylindole - KIBA potassium salt of indole-3-butyric acid - kinetin 6-furfurylaminopurine - MS Murashige and Skoog - NAA 1-naphthaleneacetic acid     

Selection of somaclonal variants with low-temperature germinability in melon (Cucumis melo L.)

Summary Plants were regenerated from adventitious buds and somatic embryos (R₀) of melon (Cucumis melo L.), the cultivar Andes. Somaclonal variants of melon with low temperature germinability were selected from the progenies (R₁) of R₀ plants. Among 5,618 R₁ seeds harvested from 23 R₀ plants that were regenerated from adventitious buds 4 seeds germinated after 5 days of culture at 15 °C (selection rate; 0.07%). However, among 374 R₂ seeds harvested from 2 R₁ plants no seed germinated after 7 days of culture at 14 °C. Among 9,181 R₁ seeds harvested from 50 R₀ plants regenerated from somatic embryos 110 seeds germinated after 5 days of culture at 15 °C (selection rate; 1.20%). Among 3,717 R₂ seeds harvested from 17 R₁ plants 113 seeds germinated after 7 days of culture at 14 °C (selection rate; 3.04%). R₃ seeds were collected from these R₂ plants following self-pollination. Forty-five of the 47 lines (R₃) originated from 10 R₀ plants showed higher germination rates than that of the original cultivar. Selected lines with low-temperature germinability showed greater fruit growth rate than the original cultivar during the middle stage when they were cultivated in a greenhouse under low-temperature conditions. Of fruits harvested from 31 lines, 15 lines showed greater fruit volume than the original cultivar.     

Gas-liquid Chromatographic Determination of Furamethrin

Quantitative gas-liquid chromatographic methods for the determination of 5-propargyl-2-furylmethyl dl-cis, trans-chrysanthemate, furamethrin, have been developed. The base line before the furamethrin peak of GLC drifted on the column with 2% silicone XE-60 coated on 60 ~ 80 mesh, acid-washed and DMCS-treated Chromosorb W (Method B), which suggested partial decomposition of furamethrin, however, a fine chromatogram was obtained when sodium borate was added to the column supporter (Method A). By utilizing an adequate internal standard, furamethrin was determined with the standard deviation of about 0.8% by Method B as well as Method A, the values being substantially equal to those obtained by the TLC-UV method previously reported. In addition, the trans and cis isomers in technical products of furamethrin were separated from each other on a 5% silicone DC QF-1 column and the results obtained by analyzing the mixtures indicate that the ratio can be accurately determined by their area ratio.     

甘肃省甜瓜黄萎病的病原鉴定

【背景】2013年11月在甘肃省兰州市皋兰县的日光温室秋冬茬甜瓜种植棚发现黄萎症状的甜瓜植株,病株率约为1%。【目的】明确甜瓜黄萎病的病原。【方法】采用组织分离法进行病原菌分离;通过科赫氏法则(Koch’s法则)明确分出病菌的致病性;采用形态学和分子生物学方法对病原菌进行种类鉴定。【结果】分离得到轮枝菌属真菌8株,轮枝菌属真菌的病株分出率达100%;2个代表性菌株GLTG-2和GLTG-5(显微特征相似但菌落形态和生长速率不同),在温度18-24℃及昼/夜光周期为11.5 h/12.5 h的试验条件下,人工接种可引起甜瓜苗矮化、枯萎;接种后40 d,枯死株率分别为70%和40%;BLASTn分析结果显示,菌株GLTG-2的rDNA-ITS序列与Verticillium dahliae菌株MRHf7的序列相似性达99.78%,菌株GLTG-5的rDNA-ITS序列与V.dahliae菌株MRHf7和Vd414的序列相似性达100.00%。【结论】引起甜瓜黄萎病的病原菌被鉴定为大丽轮枝菌(V. dahliae),这是大丽轮枝菌引起甜瓜黄萎病在我国和亚洲地区的首次报道。     

Cucumber mosaic virus movement protein affects sugar metabolism and transport in tobacco and melon plants

In addition to its influence on plasmodesmal function, tobacco mosaic virus movement protein (TMV‐MP) causes an alteration in carbon metabolism in source leaves and in resource partitioning among the various plant organs. The present study was aimed at characterizing the influence of cucumber mosaic virus (CMV)‐MP on carbohydrate metabolism and transport in both tobacco and melon plants. Transgenic tobacco plants expressing the CMV‐MP had reduced levels of soluble sugars and starch in their source leaves and a significantly reduced root‐to‐shoot ratio in comparison with control plants. A novel virus‐vector system was employed to express the CMV‐coat protein (CP), the CMV‐MP or the TMV‐MP in melon plants. This set of experiments indicated that the viral MPs cause a significant elevation in the proportion of sucrose in the phloem sap collected from petioles of source leaves, whereas this sugar was at very low levels or even absent from the sap of control melon plants. The mode by which the CMV‐MP exerts its effect on phloem‐sap sugar composition is discussed in terms of possible alterations in the mechanism of phloem loading.     

Ploidy levels of plants regenerated from mixed ploidy maize callus cultures

Summary Haploid and diploid anther-derivedZea mays callus lines were treated with the antimicrotubule herbicide pronamide to produce mixed ploidy callus as determined by flow cytometry. The ploidy levels of the plants regenerated from the callus were determined by counting the leaf epidermal guard cell chloroplast numbers. The proportion of diploid regenerated plants was somewhat lower than the proportion of diploid cells of the callus. The diploid plants regenerated somewhat faster than the haploids. The proportion of tetraploids regenerated from the pronamide treated diploid callus, which originated by spontaneous chromosome doubling, was much lower than the proportion of cells indicating that tetraploid cells survive or regenerate plants at a lower frequency than diploid cells.     

Resistance in melon to Monosporascus cannonballus and M. eutypoides: Fungal pathogens associated with Monosporascus root rot and vine decline

The fungal species Monosporascus cannonballus and M. eutypoides have been described as the causal agents of Monosporascus root rot and vine decline disease (MRRVD), which mainly affects melon and watermelon crops. Resistance to M. cannonballus has been reported in some melon cultivars (ssp. melo). Moreover, melon ssp. agrestis accessions have proven to be better resistance sources. This is the case of the Korean accession ‘Pat 81’, highly resistant under field and artificial inoculation. The objective of the work here presented was the evaluation of the resistance to MRRVD of different accessions representing the variability of Cucumis melo ssp. agrestis, against both, M. cannonballus and M. eutypoides, in a multiyear assay under different infection conditions. In general, M. eutypoides was less aggressive than M. cannonballus in the different environmental conditions. There was a strong influence of temperature on MRRVD, with more severe symptoms with higher temperatures and with variable effect of infection on plant development depending on the fungal species considered. Resistance to MRRVD has been confirmed in ‘Pat 81’ and in its derived F1 with a susceptible Piel de Sapo melon. Among the new germplasm explored, African accessions (both wild agrestis and exotic cultivated acidulus) showed good performance in artificial inoculation assays and in field conditions. These sources do not present compatibility problems with commercial melons, so they can be introduced in backcrossing programs. The accession assayed of the wild relative Cucumis metuliferus, also resistant to Fusarium wilt and to root-knot nematode, was highly resistant to MRRVD. The interest of this accession mainly relies in its advantages as a rootstock for melon.     

Seed coat structure and oxygen availability control lowtemperature germination of melon (Cucumis melo) seeds

The involvement of the seed coat in low-temperature germination of melon seeds was examined in two accessions differing in their ability to germinate at 14°C: Noy Yizre'el (a cold-sensitive cultivar) and Persia 202 (a cold-tolerant breeding line). Decoating resulted in full germination of Noy Yizre'el at 14°C, but splitting the coat increased germination only partially. Thus, the inhibition of Noy Yizre'el germination at 14°C is not due to physical constraint on radicle protrusion. At 25°C, seeds of both accessions submerged in water or agar germinated fully as long as the hilum aperture remained uncovered. Submerging the whole seed, or covering the hilum with lanolin, strongly depressed germination of Noy Yizre'el but not of Persia 202. Accessions differed in germination response to decreasing O₂ concentration, with Noy Yizre'el showing higher sensitivity to hypoxia. These differences were correlated with differences in seed coat structure as well as in embryo sensitivity to hypoxia. Intercellular spaces in the outer layer of the seed coat were evident in the more tolerant Persia 202, while in the sensitive Noy Yizre'el this layer was completely sealed. Sensitivity to hypoxia increased at 15°C as compared with 25°C, the increase being greater in Noy Yizre'el. It is proposed that the seed coat-imposed dormancy at low temperature in Noy Yizre'el is the combined result of more restricted oxygen diffusion through the seed coat and a greater embryo sensitivity to hypoxia, rather than to physical constraints of radicle break-through or impairment of imbibition.