Storage rots of taro (Colocasia esculenta) in the British Solomon Islands

Several fungicides chosen for their ability to control the pathogens previously isolated from stored corms of taro failed to prevent severe rotting. This result led to a reappraisal of the organisms involved in the initial stages of decay. Isolations made from stored corms during the first 5 days showed that Phytophthora colocasiae and Pythium splendens were the dominant fungi in the rots. Later Botryodiplodia theobromae rapidly colonized the corms to complete the decay. Attempts to reduce losses by leaving petiole bases, cormels and roots attached only succeeded in delaying infection by a few days. Corms placed in soil in well-drained pits stored relatively well up to 4 wk without impaired taste. Fungal rots were completely eliminated in corms stored in the soil but bacterial rots caused by Erwinia chrysanthemi were responsible for some decay.     

Survival of inoculum of the leaf blight fungus Phytophthora colocasiae infecting taro, Colocasia esculenta in the Solomon Islands

Phytophthora colocasiae was successfully isolated by baiting with detergent-treated taro leaf discs 8 cm diameter placed on water slurries of soil, on suspensions of macerated infected leaf lesions or on the washings from petioles of harvested plants. Taro root tips, detached or left on corms, were not susceptible to zoospores of P. colocasiae nor were detached root tips of Lupinus angustifolius. Cubes of taro corm used as baits, and agar selective for Phycomycetes which was inoculated directly with soil, both became too heavily overrun by Phythium splendens to allow detection of P. colocasiae. Investigations indicated that inoculum on lesions of detached leaves and in soil remains viable for only a few days. Petiole bases which comprise the bulk of the ‘tops’ used for vegetative propagation, lost detectable natural inoculum rapidly (2 days) if stored dry, but less rapidly (14 days) if planted immediately in the field. Artifically augmenting surface inoculum with naturally produced sporangia considerably extended the periods of detectability, probably by increasing the chances that a few propagules would survive, especially during dry storage. Incubation of inoculated tops in high humidity led to active infection and sporulation on petioles, especially on cut ends, a situation that might be paralleled under suitable moisture conditions in the field. Of several aroid species tested by artificial inoculation only Alocasia macrorrhiza was susceptible. Natural infection of this plant has not been seen, making it an unlikely alternate host of P. colocasiae under field conditions. Thus perennation between taro crops is effected by shortlived surface propagules and possibly also by mycelium within lesions on petioles. Reduction of the former and prevention of the latter might be achieved by dry storage of tops for 2 to 3 wk.     

Evolutionary origins of taro (Colocasia esculenta) in Southeast Asia

As an ancient clonal root and leaf crop, taro (Colocasia esculenta, Araceae) is highly polymorphic with uncertain genetic and geographic origins. We explored chloroplast DNA diversity in cultivated and wild taros, and closely related wild taxa, and found cultivated taro to be polyphyletic, with tropical and temperate clades that appear to originate in Southeast Asia sensu lato. A third clade was found exclusively in wild populations from Southeast Asia to Australia and Papua New Guinea. Our findings do not support the hypothesis of taro domestication in Papua New Guinea, despite archaeological evidence for early use or cultivation there, and the presence of apparently natural wild populations in the region (Australia and Papua New Guinea).     

Rapid vegetative multiplication in Colocasia esculenta (L) Schott (taro)

Initial multiplication of taro was achieved by dividing corms into pieces, each with several buds, and planting them in sterile potting mix. Surface planting and decapitation of the new primary meristem on each sucker forced additional shoot meristems to grow. Meristems of six cultivars were cultured on a modified Murashige and Skoog medium plus TDZ. In experiments with the cultivar Niue, explants cultured on modified MS medium plus 2.6 μM (0.6 mg L^-1 TDZ grew more vigorously than on media including BA. Transfer to 4.3 μM (1.0 mg L^-1 TDZ subsequently gave a 15–25 fold increase in production of plantlets per four week culture period compared to four-fold with BAP. The two stage propagation technique described in this paper is an efficient way to produce taro plants for commercial planting or the production of pathogen-tested material. This revised version was published online in June 2006 with corrections to the Cover Date.     

Characterization of 11 new microsatellite loci in taro (Colocasia esculenta)

Eleven new microsatellite markers were isolated from taro, Colocasia esculenta (L.) Schott, a root crop widely distributed all over the world. Forty-eight primer pairs were designed from a microsatellite-enriched genomic library, of which 11 primer pairs have polymorphisms in 30 individuals tested from a population in China, which revealed two to six alleles per locus with the observed and expected heterozygosity levels ranging from 0 to 0.733 and from 0.381 to 0.731, respectively. These new genetic markers will be useful for the study of taro germplasm management and population evolution in the future.     

PCR-based approach for mining of resistant gene analogues in taro (Colocasia esculenta)

Primers based on the conserved motifs were used to isolate nucleotide-binding sites (NBS) type sequences in taro (Colocasia esculenta). Cloning and sequencing identified three taro NBS-type sequences called resistance gene analogues (RGAs) that depicted similarity to other cloned RGA sequences. The deduced amino acid sequences of the RGAs detected the presence of conserved domains, viz. P-loop, categorising them with the NBS–leucine-rich repeat class gene family. Phylogenetic characterisation of the taro RGAs along with RGAs of other plant species grouped them with the non-toll interleukin receptor subclasses of the NBS sequences. The isolation and characterisation of taro RGAs have been reported for the first time in this study. This will provide a starting point towards characterisation of candidate resistance genes in taro and can act as a reference guide for future studies.     

Plant regeneration in vitro of South Pacific taro (Colocasia esculenta var. esculenta cv. Akalomamale,Aracea)

Summary Axillary bud expiants from South Pacific (Solomon Islands) taro, Colocasia esculenta var. esculenta cv. Akalomamale (Araceae) cultured on a modified Murashige-Skoog medium containing 1 mg NAA 1^–1 and TE formed callus and produced multiple plantlets. Explants died if NAA was present at levels lower than 0.1 mg 1^–1. BA was not required and may have been inhibitory. Plantlets developed faster and became larger following transfer to a hormone-free medium two weeks after the start of culture. Fully grown plants were established in a potting mix and are growing well in a greenhouse.Abbreviations BA benzyladenine - BM basal medium - Ca Colocasia esculenta var. antiquorum - Ce Colocasia esculenta var. esculenta - Ck cytokinin(s) - CW coconut water - HSMSM half strength Murashige Skoog macroelements - HSMS half strength Murashige and Skoog medium - IM initial medium(ia) - MS Murashige and Skoog medium - NAA naphthaleneacetic acid - SM second medium - TE taro corm extract - UCI University of California, Irvine     

Amino acid sequences of ferredoxin isoproteins from Japanese taro (Colocasia esculenta Schott)

The amino acid sequences of ferredoxins (Fd A and Fd B) from Japanese taro (Colocasia esculenta Schott) were determined. They consisted of single polypeptide chains of 98 residues, and both Fds had molecular masses of 10700 and 10500, respectively. There was a 92% homology between the sequences of the isoproteins (Fd A and Fd B). These sequences were compared with those of the closely related plant Fds and their phylogenetic tree was constructed. Two ferredoxin isoproteins from Hawaiian taro (Colocasia esculenta Schott) were also isolated and their N-terminal sequences were determined to be identical to those of Japanese taro.     

Development and characterization of polymorphic microsatellite markers in taro (Colocasia esculenta).

Microsatellite-containing sequences were isolated from enriched genomic libraries of taro (Colocasia esculenta (L.) Schott). The sequencing of 269 clones yielded 77 inserts containing repeat motifs. The majority of these (81.7%) were dinucleotide or trinucleotide repeats. The GT/CA repeat motif was the most common, accounting for 42% of all repeat types. From a total of 43 primer pairs designed, 41 produced markers within the expected size range. Sixteen (39%) were polymorphic when screened against a restricted set of taro genotypes from Southeast Asia and Oceania, with an average of 3.2 alleles detected on each locus. These markers represent a useful resource for taro germplasm management, genome mapping, and marker-assisted selection.     

Induction of callus from axillary buds of taro (Colocasia esculenta var. esculenta,Araceae) and subsequent plantlet regeneration

Summary Axillary buds of taro (Colocasia esculenta var. esculenta, Araceae) cultured on half strength Murashige-Skoog medium (HMS) containing taro extract (HMSTE) and 2, 4, 5-trichlorophenoxyacetic acid produce a compact, hard, slow growing callus which is not very active morphogenetically and produces only a few plantlets. When cultured on HMSTE plus 5 mg 1^–1 each of naphthaleneacetic acid and benzyl adenine (HMSNB) the buds produce a fast growing, friable and morphogenetically active callus. Meristematic regions form on the friable callus after 30 days on HMSNB. If transferred to HMSTE at this point the callus gives rise to plantlets. Addition of taro extract to the media is required for the culture of buds, induction of callus and plantlet regeneration.Abbreviations BA benzyl adenine - BNA b-naphthoxyacetic acid - CW coconut water (liquid endosperm) - DW dry weight - FW fresh weight - HMS half strength Murashige-Skoog medium - HMSCW HMSTE plus 100 ml CW 1^–1 - HMSNB HMSTE plus 5 mg 1^–1 each NAA and BA - HMSTE HMS plus 25 ml taro extract 1^–1 - HMSTR HMSTE plus 2 mg 2,4,5-T 1^–1 - MNA methyl-1-naphthaleneacetate - NAA naphthaleneacetic acid - OCPAA ortho-chlorophenoxyacetic acid - TE taro extract - 2,4,5-T 2,4,5-trichlorophenoxyacetic acid     

Cryopreservation of shoot-tips by droplet vitrification applicable to all taro (Colocasia esculenta var. esculenta) accessions

The application of the droplet vitrification cryopreservation technique to taro accessions from a range of Asia Pacific countries is presented. The optimum protocol involves excision of about 0.8 mm shoot-tips from in vitro plants, 20–40 min PVS2 exposure at 0°C followed by rapid plunge into liquid nitrogen. Thawing was done at room temperature (25°C) and shoot-tips inoculated on MS medium with 0.1 M sucrose regenerated into plantlets 4–6 weeks later. This new droplet vitrification protocol improved the mean post-thaw regeneration rates to 73–100% from 21–30% obtained with the previous cryo-vial vitrification protocol.     

芋侧球茎发生发育的形态学机理

观察了魁芋和多子芋腋芽、侧球茎发生发育的形态学变化规律,分析了主球茎顶芽和不同发育期腋芽中蛋白质的组成。结果表明,魁芋每一叶轮上腋芽数目为１;多子芋为３或３个以上,其中一个体积较大。魁芋侧球茎发育初期伸长的速度大于增粗,首先形成圆柱型,然后顶端膨大形成体积很小的侧球茎。多子芽腋芽伸的同时茎部明显变粗,首先形成圆锥型,然后发育成品种特有的形状。根据发育进程将腋芽发育分成ＡＢ１－ＡＢ９个时期,将主球茎     

Genetic diversity of taro, Colocasia esculenta (L.) Schott, in Southeast Asia and the Pacific

The genetic diversity of 255 taro (Colocasia esculenta) accessions from Vietnam, Thailand, Malaysia, Indonesia, the Philippines, Papua New Guinea and Vanuatu was studied using AFLPs. Three AFLP primer combinations generated a total of 465 scorable amplification products. The 255 accessions were grouped according to their country of origin, to their ploidy level (diploid or triploid) and to their habitat—cultivated or wild. Gene diversity within these groups and the genetic distance between these groups were computed. Dendrograms were constructed using UPGMA cluster analysis. In each country, the gene diversity within the groups of wild genotypes was the highest compared to the diploid and triploid cultivars groups. The highest gene diversity was observed for the wild group from Thailand (0.19), the lowest for the diploid cultivars group from Thailand (0.007). In Malaysia there was hardly any difference between the gene diversity of the cultivars and wild groups, 0.07 and 0.08, respectively. The genetic distances between the diploid cultivars groups ranges from 0.02 to 0.10, with the distance between the diploid accessions from Thailand and Malaysia being the highest. The genetic distances between the wild groups range from 0.05 to 0.07. First, a dendrogram was constructed with only the diploids cultivars from all countries. The accessions formed clusters largely according to the country from which they originated. Two major groups of clusters were revealed, one group assembling accessions from Asian countries and the other assembling accessions from the Pacific. Surprisingly, the group of diploid cultivars from Thailand clustered among the Pacific countries. Secondly, a dendrogram was constructed with diploid cultivated, triploid cultivated and wild accessions. Again the division of the accessions into an Asian and a Pacific gene pool is obvious. The presence of two gene pools for cultivated diploid taro has major implications for the breeding and conservation of germplasm.     

Storage losses of taro corms in the British Solomon Islands Protectorate

In two storage trials, corms of taro (Colocasia esculenta) decayed and became unfit for human consumption after 1 to 2 weeks. There were three fairly distinct types of rot: A dry rot caused by Fusarium solani, a spongy black rot caused by Botryodiplodia theobromae, and a Sclerotium rot caused by S. rolfsii. Although it was found that, under humid conditions, all three fungi could penetrate and rot undamaged corms most natural infection is thought to occur through wounds. None of the pathogens rotted corms at low humidity.     

芋(Colocasia esculenta)的民族植物学

应用民族植物学的基本原理和方法,选择中国云南和山东为试点,兼顾其他省区,开展芋[Colocasia esculenta(L.)Schott]的民族植物学研究.结果表明:在云南传统栽种芋的菜园和农地被高附加值的经济作物所代替,芋在不同民族家庭中的地位也从传统作为主食变成蔬菜或杂粮;在山东已形成芋的产业化、标准化生产的格局,芋在汉族农家经济中的地位得到提升.在云南分布有芋的野生近缘种、半栽培种、栽培品种,种质资源丰富;在山东未发现芋的野生类型,以旱芋类型的多子芋栽培品种为主.由于经济的发展和主流文化的影响,民间对芋的植物崇拜及植物崇拜文化丢失的速度大大加剧.在古朴的传统食芋文化中,蕴含着丰富的关于芋植物资源利用和保护的传统知识和朴素的科学内涵,需要进行深入的挖掘和探讨.     

Production of resistant starch from taro (Colocasia esculenta L. Schott) corm and determination of its effects on health by in vitro methods

The aim of the study was the production of resistant starch from taro (Colocasia esculenta L. Schott) corm and determination of its effects on health by in vitro methods. Starch was isolated from taro corms with 98% purity, and 10.4±0.5% amylose content. By application of heating, autoclaving, enzymatic debranching, retrogradation, and drying processes to taro starch for two times, resistant starch (RS) content was increased 16 fold (35.1±1.9%, dry basis). The expected glycemic index (eGI) of taro starch and taro resistant starch was determined as 60.6±0.5 and 51.9±0.9, respectively and the decrease in the glycemic index of taro resistant starch was found as statistically significant (P<0.05). The in vitro binding of bile acids by taro starch and taro resistant starch relative to cholesterol decreasing drug cholestyramine were 5.2±0.2% and 7.6±1.7%, respectively.     

Characterization of inhibitory mechanism and antifungal activity between group-1 and group-2 phytocystatins from taro (Colocasia esculenta)

Tarocystatin from Colocasia esculenta, a group-2 phytocystatin, is a defense protein against phytopathogenic nematodes and fungi. It is composed of a highly conserved N-terminal region, which is homological to group-1 cystatin, and a repetitive peptide at the C-terminus. The purified recombinant proteins of tarocystatin, such as full-length (FL), N-terminus (Nt) and C-terminus (Ct) peptides, were produced and their inhibitory activities against papain as well as their antifungal effects were investigated. Kinetic analysis revealed that FL peptide exhibited mixed type inhibition (K(ia) = 0.098 microM and K(ib) = 0.252 microM) and Nt peptide showed competitive inhibition (K(i) = 0.057 microM), whereas Ct peptide possessed weak papain activation properties. A shift in the inhibitory pattern from competitive inhibition of Nt peptide alone to mixed type inhibition of FL peptide implied that the Ct peptide has an regulatory effect on the function of FL peptide. Based on the inhibitory kinetics of FL (group-2) and Nt (group-1) peptides on papain activity, an inhibitory mechanism of group-2 phytocystatins and a regulatory mechanism of extended Ct peptide have each been proposed. By contrast, the antifungal activity of Nt peptide appeared to be greater than that of FL peptide, and the Ct peptide showed no effect on antifungal activity, indicating that the antifungal effect is not related to proteinase inhibitory activity. The results are valid for most phytocystatins with respect to the inhibitory mechanism against cysteine proteinase.     

Analysis of genetic diversity in Phytophthora colocasiae causing leaf blight of taro (Colocasia esculenta) using AFLP and RAPD markers

The oomycetous fungus Phytophthora colocasiae that causes taro leaf blight is one of the most devastating diseases of taro and is widely distributed in India. Molecular and cultural techniques were employed for assessing and exploiting the genetic variability among isolates of P. colocasiae obtained from different geographical regions of India. Analysis of the 5.8-ITS region revealed detectable intraspecific variation among isolates. Ten random amplified polymorphic DNA (RAPD) and eight amplified fragment length polymorphism (AFLP) primers produced 198 and 510 reproducible fragments, respectively. AFLP produced 100 % polymorphism, whereas RAPD showed 93.5 % polymorphism. The average value of the number of observed alleles, the number of effective alleles, mean Nei’s genetic diversity, and Shannon’s information index were 2.00–1.94, 1.53–1.36, 0.31–0.24, and 0.47–0.40, respectively, for two DNA markers used. Analysis of molecular variance (AMOVA) for both markers produced similar results with the majority (85 %, AFLP; 89 %, RAPD) of the diversity present within population of P. colocasiae. Dendrograms based on two molecular data using the unweighted pair group method with arithmetic mean (UPGMA) was incongruent and classified the P. colocasiae isolates into one and two major clusters. Cophenetic correlation coefficient between dendrogram and original similarity matrix were significant for RAPD (r?=?0.904) and AFLP (r?=?0.825). The results of this study displayed a high level of genetic variation among the isolates irrespective of the geographical origin. The possible mechanisms and implications of this genetic variation are discussed.     

Callus Growth and Plantlet Regeneration in Taro, Colocasia esculenta var. esculenta (L) Schott (Araceae)

Explants of taro cultivars belonging to Colocasia esculentavar. esculenta have been nearly impossible to culture untilrecently. Here, we describe a method which induces callus formationfrom bud explants of Colocasia esculenta var. esculenta cv.Akalomamale, brings about shoot and root production, and leadsto plantlet regeneration. The medium used is half-strength Murashige-Skoog(HMS) solution containing 25 ml taro tuber extract (TE), 2 mg2, 4, 5-trichlorophenoxyacetic acid and 200 mg glutamine 1^–1.TE is an important requirement for bud explants and callus tissues.Root induction on callus-derived shoots (i.e. plantlet formation)occurs on HMS containing only 25 ml TE and 100 ml coconut water1^–1. Taro, Colocasia esculenta var. esculenta (L) Schott (Araceae), coconut water, micropropagation, plantlet regeneration, root formation, taro extract, tissue culture