Development of an efficient and reproducible regeneration system in wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

The availability of reproducible regeneration system through tissue culture is a major bottleneck in wheat improvement program. The present study has considered to develop an efficient callus induction and regeneration system using mature and immature embryos as explants in recently released agronomically superior spring wheat varieties. An efficient sterilization process was standardized using 0.1% HgCl₂ and 70% ethanol for both seeds and embryos. The maximum possible combinations of plant growth regulators (PGRs) were evaluated for their effect on different wheat regeneration processes through tissue culture starting from callus to root induction. Picloram is found as an effective auxin with 87.63–98.67% callus induction efficiency in both explants. Supplementation of CuSO₄ along with 2,4-D, zeatin in regeneration medium significantly enhanced the multiple shoot induction. The shoot development was achieved using full strength Murashige and Skoog’s (MS) medium and root induction using half MS medium without PGRs. The optimized medium and method has resulted up to 100% regeneration irrespective of the genotype used with high reproducibility. Thus, the standardized regeneration system can be used in the regeneration of healthy plants from embryos rescued from interspecies crosses, transgenic production, induced mutation breeding and recently developed genome editing techniques for the procreation of wheat plants having novel traits.     

Enhanced Trehalose Accumulation and Desiccation Survival of Entomopathogenic Nematodes Through Cold Preacclimation

Limited storage stability is a major obstacle to further expansion of the use of entomopathogenic nematodes for pest control. Progress has been made that Steinernema carpocapsae can now be stored under partial anhydrobiosis for up to 6 months at 25°C and 10 months at 5°C in a water-dispersible granular (WG) formulation. However, other species have been more difficult to store in the WG formulation due to migration of nematodes out of the granules and sensitivity of some species to desiccation directly at cold temperatures. As acclimation to cold induces trehalose accumulation (a major cryo- and desiccation protectant) in many invertebrates, it was hypothesized that cold preacclimation of entomopathogenic nematodes will enhance their survival in the WG formulation at cold temperatures. This hypothesis was tested using a temperate species Steinernema feltiae , a subtropical species S. carpocapsae , and a tropical species Steinernema riobrave possessing different thermal niche breadths and reproduction temperature optima. Cold acclimation of infective juveniles increased trehalose accumulation in all three species and the amount of trehalose accumulated was both temperature and species dependent. Trehalose content reached at its peak after 6 days at 5°C in S. feltiae (82.28 μg/mg dry weight), after 10 days at 10°C in S. carpocapsae (94.16 μg/mg dry weight) and after 6 days at 15°C in S. riobrave (47.58 μg/mg dry weight). Cold preacclimation at 5°C for 2 days enhanced desiccation survival of S. feltiae in 25% glycerol (osmotic desiccation) at both 5 and 25° and of S. carpocapsae and S. riobrave only at 5°C. Non-cold acclimated S. carpocapsae and S. riobrave were extremely sensitive to desiccation directly at 5°C in 25% glycerol, resulting in over 98% mortality within 6 days, but S. feltiae was more sensitive to desiccation at 25°C than at 5°C. Cold preacclimation increased survival of all the three species in the WG formulation at both 5 and 25°C. The survival of S. riobrave at 5°C in the WG formulation was positively correlated with the length of preacclimation period at 5°C (R 2 = 0.99) and with the amount of trehalose accumulated during cold preacclimation (R 2 = 0.81). These results support the hypothesis that cold preacclimation enhances desiccation survival of entomopathogenic nematodes at cold temperatures and the increased survival correlates well with the increased trehalose accumulation. Results also demonstrate that cold preacclimation can be used as a tool to enhance survival of nematodes in the formulations with reduced water activity.     

Effect of Neem and Selected Fungicides on Viability and Virulence of the Entomopathogenic Nematode Steinernema feltiae

Entomopathogenic nematodes are often used in conjunction with other pest management tactics and the lack of compatibility information is a major impediment in further expansion of their use. We evaluated the effects of different formulations of neem and selected fungicides commonly used in greenhouses on Steinernema feltiae which is used for the control of fungus gnats. Neem as pure oil at the field recommended concentrations (5- 10 mL L -1 ) had no effect on the viability and virulence of S. feltiae up to 120 h incubation. However the neem formulation, Nimbecidine and neem oil when mixed with a bactericidal soap (commonly used as a surfactant with neem oil) caused 13- 25% mortality of S. feltiae. This toxic effect was entirely due to the soap that alone caused about 24% mortality. Neither neem oil, Nimbecidine or soap had any effect on nematode virulence. The fungicide cinnamaldehyde (Cinnamate) was highly toxic, resulting in 100% nematode mortality after 4 h of incubation, followed by hydrogen dioxide/peroxyacetic acid mixture (ZeroTol) that caused 100% mortality after 120 h of incubation. Another fungicide, azoxystrobin (Abound) caused no nematode mortality. This investigation concludes that neem and the fungicide azoxystrobin (Abound) can be safely tank mixed at the field recommended concentrations with the infective juveniles of S. feltiae for application, but cinnamaldehyde (Cinnamate) and hydrogen dioxide/peroxyacetic mixture (ZeroTol), are incompatible. Also the surfactants that are usually recommended as 'tank-mix' applications can be toxic to the nematodes and should therefore be evaluated for compatibility prior to use.     

Assessing the Potential of Entomopathogenic Nematodes to Control the Grape Root Borer Vitacea polistiformis (Lepidoptera: Sesiidae) Through Laboratory and Greenhouse Bioassays

Seventeen entomopathogenic nematode species and strains were evaluated for virulence to the grape root borer, Vitacea polistiformis (Harris) in laboratory and greenhouse bioassays. Heterohabditis bacteriophora strain GPS11 and H. zealandica strain X1 produced a larval mortality rate of over 85% of larvae embedded in the root cambium in laboratory bioassays. The nematode species H. marelata and H. bacteriophora strain Oswego produced mortality rates of over 75%. Of the Steinernema species tested, S. carpocapsae strain 'All' performed the best with a mortality rate of 69%. All other nematode species and strains tested, with the exception of S. bicornutum , produced some degree of larval mortality. In the greenhouse bioassays, 93% control was achieved with H. zealandica strain X1 applied at 4 ×109 infective juveniles (IJs) acre1 -1 (9.88 ×10 9 IJs ha -1 ). H. bacteriophora strain GPS11 successfully reproduced in grape root borer larvae. The numbers of IJs produced within infected larvae were related to larval size. The survival rate of neonate larvae on grape root sections was 61%, which thus provides a means to rear the neonate larvae for bioassays.     

Latent infection: a low temperature survival strategy in steinernematid nematodes

1. Entomopathogenic nematodes penetrate and kill Galleria mellonella within 48 h at optimal temperatures.

2. Low temperature induces infection latency, preventing host death until optimal conditions resume.

3. Infected Galleria survived 25 days at 5°C. On transfer to 25°C, 100% and 12.5% of Steinernema carpocapsae and Steinernema riobravis infected larvae died within 72 h.

4. Infective juvenile penetration decreased with decreasing temperature; declining from 49.7 and 49.3 nematodes/host at 25°C to 6.3 and 0.25 nematodes/host at 5°C for S. carpocapsae and S. riobravis, respectively.

5. Latent infection occurs, albeit infrequently, due to low host penetration at low temperature.

Effectiveness of a Hot Water Drench for the Control of Foliar Nematodes Aphelenchoides fragariae in Floriculture

Effectiveness of a hot water drench for the control of Aphelenchoides fragariae infesting hosta (Hosta sp.) and ferns (Matteuccia pensylvanica) was studied. Drenching with hot water at 70 °C and 90 °C in October reduced (P < 0.05) A. fragariae in the soil but not in the leaves relative to the control (25 °C) 300 days after treatment (DAT). Plants drenched with 90 °C water had lower numbers of nematode-infected leaves per plant than those treated with 25 °C and 70 °C water (P < 0.05). Hot water treatments had no adverse effect on the growth parameters of hosta. Boiling water (100 °C) applied once a month for 3 consecutive months (April, May, June) consistently reduced the number of infected leaves and the severity of infection relative to the control 150 DAT in hosta but not in ferns (P < 0.05). Boiling water (100 °C) caused a 67% reduction in A. fragariae population in hosta leaves, 50% in fern fronds, and 61% to 98% in the soil over the control 150 DAT. A boiling water drench had no effect on the fern growth but caused 49% and 22% reduction in the number and size of hosta leaves, respectively, over the control in 2002. We conclude that 90 °C water soil drench in the autumn or early spring could prove effective in managing foliar nematodes on hosta in nurseries and landscapes.     

Susceptibility of North American Native and Non-native Slugs (Mollusca: Gastropoda) to Phasmarhabditis hermaphrodita (Nematoda: Rhabditidae)

Phasmarhabditis hermaphrodita caused significant mortality of the two native species, Deroceras laeve and Leidyula floridana, and of one introduced species D. reticulatum, but not of the other three introduced species, Arion hortensis, A. subfuscus and Limax maximus. Even the juvenile stages of A. subfuscus and L. maximus showed no mortality in nematode treatments. However, treatments with nematodes resulted in rapid and strong feeding inhibition in all six species. Surviving slugs resumed feeding when fresh food was provided. This study expands the host range of P. hermaphrodita to include a new family Vaginulidae and demonstrates the inability of P. hermaphrodita to cause mortality of A. hortensis, A. subfuscus and L. maximus. These three species use feeding suspension as an evasive behavior to escape nematode infection.     

Characterization of the First Molluscicidal Lipopolysaccharide from Moraxella osloensis

Moraxella osloensis is a bacterium that is mutualistically associated with Phasmarhabditis hermaphrodita, a nematode that has potential for the biocontrol of mollusk pests, especially the slug Deroceras reticulatum. We discovered that purified M. osloensis lipopolysaccharide (LPS) possesses a lethal toxicity to D. reticulatum when administered by injection but no contact or oral toxicity to this slug. The toxicity of the LPS resides in the lipid A moiety. M. osloensis LPS was semiquantitated at 6 × 10⁷ endotoxin units per mg. The LPS is a rough-type LPS with an estimated molecular weight of 5,300. Coinjection of galactosamine with the LPS increased the LPS's toxicity to the slug two- to four-fold. The galactosamine-induced sensitization of the slug to the LPS was reversed completely by uridine.     

Pathogenicity of Moraxella osloensis, a bacterium associated with the nematode Phasmarhabditis hermaphrodita, to the slug Deroceras reticulatum.

Moraxella osloensis, a gram-negative bacterium, is associated with Phasmarhabditis hermaphrodita, a nematode parasite of slugs. This bacterium-feeding nematode has potential for the biological control of slugs, especially the grey garden slug, Deroceras reticulatum. Infective juveniles of P. hermaphrodita invade the shell cavity of the slug, develop into self-fertilizing hermaphrodites, and produce progeny, resulting in host death. However, the role of the associated bacterium in the pathogenicity of the nematode to the slug is unknown. We discovered that M. osloensis alone is pathogenic to D. reticulatum after injection into the shell cavity or hemocoel of the slug. The bacteria from 60-h cultures were more pathogenic than the bacteria from 40-h cultures, as indicated by the higher and more rapid mortality of the slugs injected with the former. Coinjection of penicillin and streptomycin with the 60-h bacterial culture reduced its pathogenicity to the slug. Further work suggested that the reduction and loss of pathogenicity of the aged infective juveniles of P. hermaphrodita to D. reticulatum result from the loss of M. osloensis from the aged nematodes. Also, axenic J1/J2 nematodes were nonpathogenic after injection into the shell cavity. Therefore, we conclude that the bacterium is the sole killing agent of D. reticulatum in the nematode-bacterium complex and that P. hermaphrodita acts only as a vector to transport the bacterium into the shell cavity of the slug. The identification of the toxic metabolites produced by M. osloensis is being pursued.