Sustainable Production of Bioactive Compounds From Persea indica

In this work we have investigated the accumulation of ryanoids in different plant parts (leaves, stems roots) of aeroponically grown Persea indica cloned trees (one year old cloned individuals) and a selected mature wild tree. We have tested the insect antifeedant (against Spodoptera littoralis, Myzus persicae and Rhopalosiphum padi) and nematicidal (against Meloidogyne javanica) effects of ethanolic extracts from these different plant parts. The HPLC-MS analysis of P. indica extracts showed that the mature tree (wild) leaves had 2 times more chemical diversity than the stems. The aeroponic plants showed lower differences in chemical diversity between leaves and stems, with the lowest diversity found in the roots. The ryanodane epiryanodol (1) was present in all the plant parts, with the mature stems (wild) having the highest amount. The aeroponic stems also accumulated ryanoids including 1, cinnzeylanol 2 and cinnzeylanone 4. The insect Spodoptera littoralis was strongly affected by the stem extracts while the leaf ones were moderately active. Based on the predicted vs. the real antifeedant values we conclude that the ryanoid content (1 or a combination of 2, 4 and 1) explained the antifeedant effects of the stem extracts while addition-al components contributed to the activity of the leaf ones. Therefore, careful individual selection of P. indica seedlings should be carried out prior to proceed with its aeroponic cultivation in or-der to obtain ryanodane-rich stem or leaf extracts with strong antifeedant effects on S. littoralis.

First Report of Meloidogyne javanica on Globe Artichoke in Florida, USA

Globe artichoke (Cynara cardunculus var. scolymus L.) is native to the Mediterranean region and cultivated worldwide for its edible flower buds and the medicinal value of its leaves (Pignone and Sonnante 2004). In 2019, artichokes were planted on 29 km2 predominantly in California, with a yield of over 100 million kg (USDA 2020). It has been grown as a specialty crop in Florida since 2017 (Agehara 2017a). Meloidogyne spp. (root-knot nematodes/RKNs) can lead to yield losses to artichoke (Greco et al. 2005). In June 2020, artichokes (cv. Imperial Star) with stunting, wilting, and galled-root symptoms were observed in a research field with sandy soil located at the University of Florida Gulf Coast Research and Education Center (UF/GCREC), Wimauma, Florida. The goal of this report was to identify the RKN species collected from two symptomatic artichoke roots. Morphological measurements (mean, standard deviation and range) of 15 second-stage juveniles (J2s) included body length = 409.1 ± 31.6 (360.3 - 471.3) µm, body width = 15.4 ± 1.6 (12.4 - 18.8) µm, and stylet length = 14.7 ± 0.7 (13.9 -16.1) µm. Perineal patterns of five matured females had a high dorsal arch and double lateral lines. Morphological characteristics of the RKN cultures were consistent with the description of M. javanica (Eisenback and Triantaphyllou 1991). DNA was extracted respectively from two RKN females isolated from the diseased artichoke roots. The nematode species was confirmed with primers Fjav/Rjav and resulted in ≈ 670 bp fragment (Zijlstra et al. 2000). The COXII region of mtDNA was amplified by C2F3/1108 (Powers and Harris 1993), and the sequencing results were submitted to the NCBI with GeneBank Accession No. MZ397905. The molecular sequences had 100% identity with M. javanica in COXII (MK033440 and MK033439). The pathogenicity test was conducted in the greenhouse at UF/GCREC from May to August 2021 (temperature = 26.7 ± 4.1°C, relative humidity = 83.9 ± 14.6 %). Each of the ten 6.5-in-diameter plastic pots containing 3.8-L pasteurized soil was seeded with one artichoke seed. Five pots were inoculated with 5000 eggs of the field RKN cultures 4-week after planting, and five pots served as the untreated control. Two months after inoculation, galled symptoms were only observed in inoculated plants with an average gall index (Bridge and Page 1980) of 6.2 ± 2.2; 99,240 ± 72,250 eggs were extracted from each root system, and the nematode reproduction factor was 19.9 ± 14.4. Meloidogyne spp. has been reported on artichoke in Europe, Asia, and South America (Greco et al. 2005). This is the first report of RKN on artichoke in the United States. Meloidogyne javanica caused severe root gall symptoms and visible aboveground damage in the form of chlorosis, stunting, and wilting of artichoke planted at the UF/GCREC research farm. Meloidogyne javanica is the predominant RKN species at the UF/GCREC research farm and one of the most common RKNs in Florida (Gu and Desaeger 2021). Artichoke is a new crop in Florida, and RKNs is likely to be one of the main soilborne problems for its production in the state. Its long growing season (October - May) (Agehara 2017b) allows for high nematode reproduction rates. Several new growers have already reported RKN as a problem in their fields. For artichoke to become a commodity in Florida, managing RKNs will be critical. This report provides new information on the risk that RKNs pose to artichoke, a newly established specialty crop in Florida.

Phenotypic Characterization and Molecular Mapping of Recessive Resistance To Meloidogyne Javanica in Cucumber, Cucumis Sativus

The Javanese root-knot nematode (JRKN, Meloidogyne javanica) is a serious pest of cucumber (Cucumis sativus) grown in tropical and subtropical regions. The recessive mj resistance gene first identified in the wild cucumber (C. sativus var. hardwickii), is the only known source of resistance to JRKN within the C. sativus gene pool. Despite its potential utility as a nematode management tool, the mj trait has yet to be fully characterized or widely incorporated into commercial cucumber lines. In this study, we mapped the mj resistance locus to a 148-kb interval on cucumber chromosome 1 by phenotyping a recombinant inbred line (RIL) and targeted backcross populations. The genomic interval is predicted to contain 36 candidate genes, including several known to be directly related to plant defense against pathogens. We also conducted histological comparisons of nematode development in mj resistant and susceptible lines, providing evidence that the mechanism of action for this gene may be different from that of known RKN resistance genes. These results provide a set of tightly linked markers that can assist breeding programs seeking to incorporate mj resistance into new cucumber varieties. The candidate genes will also provide a starting point for further research into the mechanisms of action that underlay the mj-regulated JRKN resistance.

Molecular Characterization and Pathogenicity of Trichoderma Isolates to Meloidogyne javanica

Nematodes are considered a serious problem for agriculture. Nematodes of the Meloidogyne genus can attack a wide range of plants, needing different management methods to decrease its population. Fungi from the Trichoderma genus has been related to have potential as biological control agents. However, before an organism is used as biological control agent, first it is necessary to prospect, characterize and test its potential as biocontrol agent, so the objective of this work was to characterize and test fungi isolates of the Trichoderma genus to control M. javanica. We obtained forty isolate to carry out this experiment. We extracted the DNA of each isolate to discover which species we were testing, by doing a PCR and sequencing. We tested in vitro their parasitism effect using ELISA plate. Also, we extracted their filtrate to see if their metabolites have potential to reduce nematode population by showing a high mortality or inhibiting hatching. The results confirmed the high potential of the fungi of Trichoderma genus as a biological agent to control Meloidogyne javanica.

Relative Efficacy of Some Products Against Meloidogyne Javanica (Treub) Chitwood on Tomato Under Greenhouse Conditions

A pot experiment was conducted to compare the efficacy of some products i.e., Stanes Bio Nematon®, Soft Guard®, Paecilomyces lilacinus, Trichoderma longibranchiatum, camel and goat manures against Meloidogyne javanica on tomato under greenhouse conditions. Based on nematode reproduction, indices of galls and egg masses, the six materials were grouped into four classes from the relatively highest efficacy of control (goat manure) to the relatively low efficacy of control (P. lilacinus). Bangladesh J. Bot. 50(3): 709-712, 2021 (September)

Bio-fertilizers’ protocol for controlling root knot nematode Meloidogyne javanica infecting peanut fields

Background Plant parasitic nematodes create serious threat to crop production. In Egypt root knot nematode, Meloidogyne spp. has been considered to be a limiting factor in the production of most crops of which the Peanut (Arachis hypogaea L.) is an important legume and oil crop. Therefore, management of root knot nematodes Meloidogyne spp. is an obligatory challenge. Microbial organisms are extensively used as eco-friendly tools for controlling plant parasitic nematodes as alternative to chemical nematicides. The effectiveness of the commercial bacterial bio-fertilizers NPK containing Bacillus polymyxa, B. circulance, B. megaterium, Pseudomans spp.; the nitrogen fixative bacteria Azotobacter chroocoocum and the bacterial isolate NRC211 were evaluated against the root knot nematode, Meloidogyne javanica infecting peanut plants under field conditions. Identification of the bacterial isolate was made through PCR amplification and sequencing of 16S rDNA gene. Results Sequencing of 16S rDNA gene revealed that the bacterial isolate NRC211 had 100% similarity with Bacillus wiedmannii strain FSL W8-0169 16S ribosomal RNA. This Bacillus was recorded for the first time under accession number LC626774 on GenBank data base as B. wiedmannii NRC211. Recorded data revealed that all the tested treatments whether single or combined in soil naturally infested with M. javanica, resulted in variable significant reduction in the nematode reproductive parameters with a considerable increase in crop production and oil content of peanut plant. These results were improved by increasing the frequency of application of the bio-agents. In this respect the repeated combined treatment of A. chroococcum and B. wiedmannii NRC211 treatment overwhelmed all other treatments in decreasing nematode reproductive parameters with percentage reductions of 94.8, 79.0 and 80.1% in M. javanica juveniles in soil, galls and egg masses, respectively. This was associated with slight increase in peanut oil content than the untreated control. The repeated combined treatment of NPK plus A. chroococcum produced the highest increase 608.7%, and 72.7% in crop production and plant growth parameters, respectively than the control. While, the oil content in this treatment was increased up to 47.4 g/kg. Conclusion It was concluded that B. wiedmanni NRC211 is an eco-friendly bio agent that can be applied with other commercial microbial bio-fertilizers in bio-integrating programs for controlling M. javanica infecting peanut plants.