Compensatory response of a legume root-nodule system to nodule herbivory by Sitona hispidulus

A laboratory study was conducted to examine the hypothesis that herbivory of nitrogen-fixing root nodules on legumes causes an exact compensatory response in nodule growth. Plants of Medicago sativa (L.) were grown hydroponically in clear plastic growth pouches so that the number and biomass of root nodules could be estimated nondestructively before, and 10 and 18 days after, partial denodulation. For treatments, plants were subjected to 23% denodulation by first-instar larvae of Sitona hispidulus (F.) (a common herbivore of Medicago and Trifolium) or 50% nodule pruning; additional plants were left untreated. Results indicated that nodule herbivory and nodule pruning caused an overcompensatory response in number of nodules. This was also true for number of nodule units (an indirect measure of nodule biomass) per plant at 10 days after denodulation but had changed to an exact compensatory response by day 18. An inverse relationship between change in number of nodule units and initial number of nodules indicated that compensatory nodulation was regulated by a feedback mechanism. Shoot and root biomasses were not affected by denodulation in this study.     

Effects of host age on embryogenesis and encapsulation of the parasite Bathyplectes curculionis in the alfalfa weevil

First- through fourth-instar larvae of Hypera postica were fixed at 12- to 24-hr intervals after parasitization by Bathyplectes curculionis and sectioned histologically. Sections revealed that host age had little effect on time required for embryogenesis and hatching of parasites. B. curculionis completed larval development and emerged from all host instars ca. 11 days after parasitization at 22.2°C. Parasite eggs were fully encapsulated in just 3.3% of the first-instar H. postica compared with 50.0% in the third instar. Much larger hemocyte capsules were formed in later instars as well.     

Compensatory growth response of the legume, Medicago sativa, to defoliation and denodulation

A laboratory study was conducted to determine the effects of defoliation and denodulation on compensatory growth of Medicago sativa (L.). Plants grown hydroponically in clear plastic growth pouches were subjected to 0 and 50% nodule pruning, and 0, 25, 50, and 75% defoliation by clipping trifoliate leaves. An additional experiment was conducted to determine if clipping leaves simulated herbivory by Hypera postica (Gyllenhal) larvae. Previously, we determined that nodule pruning accurately simulated herbivory by Sitona hispidulus (L.) larvae (Quinn & Hall, 1992). Results indicated that denodulation stimulated nodule growth and caused exact compensation in standing and total number of nodules per plant within 15 days and in standing nodule biomass within 22 days of treatment. Denodulation caused a significant reduction (13%) in final shoot biomass, but did not affect significantly final root biomass. Percentage of change in number of trifoliate leaves per plant increased with the level of defoliation. Within 22 days of treatment, total number of trifoliate leaves per plant was similar to controls. However, final standing shoot biomasses were significantly less that controls, indicating undercompensatory growth. Shoot biomasses of the 25-, 50-, and 75%-defoliated plants were 18, 20, and 36% lower than controls, respectively. Nodule biomass per plant was reduced by 24 and 32% in 50- and 75%-defoliated plants, respectively, but was not affected significantly by 25% defoliation. Root biomass was affected by all levels of defoliation. Clipping trifoliate leaves accurately simulated defoliation by H. postica larvae. Our results indicated that partial defoliation affected shoot, root, and nodule biomass of M. sativa, but that partial denodulation only affected shoot biomass.     

Ecology of black beetle,Heteronychus arator (Coleoptera: Scarabaeidae) — influence of temperature on feeding,growth, and survival of the larvae

Abstract

The influence Of temperature on the growth and survival of first-instar larvae of black beetle feeding in soil was examined. Similarly the consumption, utilisation, growth, and survival of second- and third-instar larvae feeding on carrot were investigated using gravimetric methods. Soil temperatures in the range 20–25° c were found to be necessary for optimum growth of all instars. First-instar larval growth increased exponentially over the temperature range 10–20°c. Third-instar larvae were tolerant of higher temperatures than second-instar larvae. The temperatures for optimum levels of consumption and utilisation of carrot varied between the instars.     

Laboratory rearing of Lytopylus rufipes (Hymenoptera: Braconidae: Agathidinae), a parasitoid wasp of the oriental fruit moth,Grapholita molesta (Lepidoptera: Tortricidae), using apple and a commercially available diet

Lytopylus rufipes (Nees) (Hymenoptera: Braconidae: Agathidinae) is a potential natural enemy of the oriental fruit moth, Grapholita molesta (Busck) (Lepidoptera: Tortricidae), but there is no established method to rear this wasp continuously. In the laboratory, female wasps can produce both female and male progenies without mating (deuterotokous), but host-infested plants are necessary to trigger oviposition behavior. In this study, immature apples were used because they keep well. Grapholita molesta larvae were transferred to immature apples, and then exposed to L. rufipes females. After parasitization, these apples were transferred to blocks of artificial diet (Silkmate 2M) for further rearing. Using this transitional diet system, L. rufipes females develop in 25.1?±?1.8 (mean?±?SD) days from egg to adult, but male wasps require only 23.8?±?1.0 days. Furthermore, the longevity of female wasps was 12.2?±?7.3 (mean?±?SD) days, and the parasitism rate was 26.4 (95% Cl: 22.2–30.6). Female wasps can attack host larvae in all instars, but parasitism of first-instar larvae is more successful. Therefore, first-instar larvae of G. molesta are recommended for establishing a L. rufipes colony under laboratory conditions. This system decreases the requirement for plant material and maintains continuous production of L. rufipes.

     

Biology of Heilipodus ventralis (Coleoptera: Curculionidae), an Argentine Weevil for Biological Control of Snakeweeds (Gutierrezia spp.) in the United States

The Argentine root-boring weevil Heilipodus ventralis (Hustache) is a candidate for biological control of the perennial snakeweeds Gutierrezia sarothrae (Pursh) Britton and Rusby and G. microcephala (DeCandolle) A. Gray, poisonous native weeds of rangelands of the southwestern United States. In Argentina, the weevil occurs in semiarid regions from Tucumán south to Chubut, which are climatically similar to broad areas of the southwestern United States. Laboratory-reared females lived ca. 112 days and laid ca. 117 eggs. The eggs hatched in ca. 15 days. The larvae had eight instars; they required ca. 151 days and pupae ca. 27 days to develop. Adult weevils emerged from the taproots in early summer, fed on the leaves and terminals, and oviposited mostly in the crown near the soil line. The feeding of one or more pairs of caged adults killed medium-sized plants. The larvae tunneled downward to the taproot where they pupated. They overwintered in the taproots of these perennial host plants and pupated in the spring. A generation required 1 year but some individuals probably required two growing seasons. At Peninsula Valdés, Chubut, H. ventralis preferred Gutierrezia solbrigii Cabrera to Grindelia chiloensis (Corn.) Cabrera by a ratio of 1.9 to 1.0. In the field there, crowns of large Gu. solbrigii (average 60 cm canopy diameter) contained an average 5.0 larvae per plant, those of small plants (23 cm diameter) contained 1.1 larvae, and plants smaller than 10 cm rarely contained larvae. No insect parasitoids or predators were found attacking any stage. H. ventralis probably evolved on xerophytic, temperate Astereae, from ancestors of the genus Heilipus that fed on species of ancient, hygrophytic, tropical plant families.     

Leaf age and larval performance of the leaf beetle Paropsis atomaria

ABSTRACT.

• 1 Larval performance of the leaf beetle Paropsis atomaria Oliver was determined for larvae raised on both new and mature leaves of Eucalyptus blakelyi Maiden. Larvae were transferred to mature leaves at different ages; control larvae stayed on new leaves through all instars.
• 2 Only larvae reared on new leaves through the third instar survived to pupate on mature leaves; developmental time was prolonged by 20% and pupal weight was reduced by 50% in these larvae compared with larvae reared entirely on new leaves. Almost all larvae died when transferred to mature leaves as first, second or third instars.
• 3 Low survival and slow development on mature leaves was mainly due to failure by larvae to feed. Larvae palpated leaves and could discriminate among leaf ages immediately, without biting into the leaf tissue.
• 4 New leaves had higher concentrations of oil and tannins than old leaves, while there were no significant differences in nitrogen concentrations in the two types of leaves. Mature leaves were more than 3 times tougher than new leaves, in terms of g mm^?2 of penetrometer force.
• 5 In drought years E. blakelyi may not produce sufficient new leaves to supply specialist herbivores with their preferred food resource. We infer that drought years reduce P. atomaria larval performance significantly, and influence the population dynamics of the insect.

     

Competitiveness of indigenous populations of Bradyrhizobium japonicum serocluster 123 as determined using a root-tip marking procedure in growth pouches

Soil Bradyrhizobium populations limit nodule occupancy of soybean by symbiotically-superior inoculant strains throughout much of the American midwest. In this study, the competitiveness of indigenous populations of B. japonicum serocluster 123 from Waukegan and Webster soils was evaluated in growth pouches using a root-tip marking procedure. The native rhizobia were from soils incubated 0–8 h in soybean root exudate (SRE) or plant nutrient solution (PNS) prior to inoculation. Populations of serocluster 123 strains in soil and nodule occupancy by these strains were assessed using fluorescent antibodies prepared against B. japonicum USDA 123. There were no significant differences in populations that came from SRE or PNS incubated soils: both populations increased in number over the incubation period. Nodule occupancy by both populations in growth pouches was similar to that previously encountered in field studies with these two soils. With the Waukegan soil, the serocluster 123 population dominated nodulation forming 69 and 62% of taproot nodules above and below the root tip mark, respectively. However, for the more alkaline Webster soil, serocluster 123 strains were much less competitive, producing only 9 and 13%, respectively, of the nodules formed above and below the root tip mark. In growth pouches, soil populations of bradyrhizobia from the Webster soil produced significantly more nodules than those from the Waukegan soil, but both strains and a pure culture of USDA 110 had a similar distribution of nodules.     

Predation capacity of two predatory laelapid mites on soil-dwelling thrips stages

The life cycle of the Western Flower Thrips, Frankliniella occidentalis (Pergande) (Thysanoptera: Thripidae), one of the most important glasshouse pests, includes a soil passage composed of three instars that deserve more attention in terms of biocontrol strategies. It has been repeatedly reported that two polyphagous predatory mites, Stratiolaelaps miles (Berlese) and Hypoaspis (Geolaelaps) aculeifer (Canestrini) (Acari: Laelapidae), also prey on these thrips stages, in addition to several other soil inhabiting prey species. However, the potential thrips consumption rates have never been quantified for these predatory mites. Therefore, an arena experiment was carried out to investigate the potential predation rates of the two mites on second instar larvae, prepupae, and pupae of F. occidentalis. In addition, the fecundity on the thrips diet was assessed and compared to oviposition rate on a nematode prey. All thrips instars were accepted as prey by each mite species. Females of H. aculeifer preyed on 3.5 (± 0.5) thrips instars and laid 2.5 (± 0.87) eggs per day, whereas females of S. miles preyed on 1.64 (± 0.3) thrips and laid 0.8 (± 0.53) eggs. Males of both species killed 0.6 (± 0.3) thrips per day. The fitness of the two predatory mites on F. occidentalis as prey and their suitability as biocontrol agents are elucidated. Reasons for reduced thrips control in the soil environment, in contrast to the results obtained in arena assays are discussed.     

Early taproot development of a xeric shrub (<Emphasis Type="Italic">Larrea tridentata</Emphasis>) is optimized within a narrow range of soil moisture

Effects of watering amount and frequency on root biomass accumulation and taproot elongation were examined 16–17 days post-germination in seedlings of Larrea tridentata, a dominant shrub in North American hot deserts. Two experimental variables manipulated in a full factorial design greenhouse study were (i) number of “triggering” days: consecutive days (2, 3, 4 or 5) at the start of the experiment on which seedlings received 10 mm of water per day; and (ii) “post-trigger” watering frequency: 5 mm of water either daily or every other day. We hypothesized that taproot elongation would increase with greater numbers of triggering days, whereas higher post-trigger watering frequency would enhance root biomass development. Increasing the number of triggering days from two to four promoted taproot extension without affecting root biomass, and higher watering frequency in the post-trigger phase generally increased root biomass, as expected. Contrary to expectations, root biomass and taproot length were significantly reduced when daily watering followed five consecutive triggering days. Taproot length correlated with root biomass, but irrigation regime also had a biomass-independent effect: with either two or five triggering days, taproots were shorter than expected based on root biomass. Thus, both too little and too much water stymied taproot extension. In natural settings, the adverse response of taproots to too little or too much water could reduce seedling survivorship and restrict establishment to a narrow range of environmental conditions.     

The comparative susceptibilities of Pieris brassicae and P. rapae to a granulosis virus from P. brassicae

A comparison was made of the dosage-mortality responses of larvae of Pieris brassicae and P. rapae to infection by P. brassicae granulosis virus (GV). Bioassays with first, second, third, and fourth-instar larvae of both species revealed a marked difference in susceptibility between instars and between species. Median lethal dosages (LD₅₀s) for P. rapae larvae ranged from five capsules for the first instar to 662 capsules for the fourth instar. With P. brassicae, this range extended from 66 capsules to 2.3 × 10⁷ capsules. The time-mortality responses of the two species were similar when fed virus dosages equivalent to an LD₉₀. Median lethal times (LT₅₀s) ranged from 5 days for first-instar larvae to 7–8 days for fourth-instar larvae. A comparison between a long-established laboratory stock of P. brassicae and a stock recently acquired from the field showed no significant difference in their susceptibility to GV. The implications of the pronounced species differences in susceptibility to GV infection are discussed in relation to the potential field control of P. rapae and P. brassicae.     

Typha productivity in a Texas pond: Implications for energy and nutrient dynamics in freshwater wetlands

Above-and below-ground biomass of Typha angustifolia L. was sampled monthly for 18 months from a small Texas pond. Maximum above-ground biomass was 2559±284 g AFDW (ash-free dry weight) m⁻² in 1983 and 2895±217 g AFDW m⁻² in 1984. Peak below-ground biomass for these 2 years was 2506±278 g AFDW m⁻² and 2314±226 g AFDW m^t-2, respectively. Stepwise multiple linear regression analyses revealed that mean above-ground biomass accrual was related to duration of growing season, cumulative precipitation, cumulative degree days and/or cumulative pan evaporation. The same was not true for below-ground biomass increases. Analysis of covariance revealed that the rates of above-ground biomass production were not significantly different (F test, p < 0.05) between the 1983 and 1984 growing seasons. Below-ground biomass turnover times for 1983 and 1984 were 2.47 and 1.21 years, respectively.     

Effects of near‐bed turbulence on the suspension and settlement of freshwater dreissenid mussel larvae

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Etiolated Growth as Measure of Non-structural Biomass in Lucerne Taproots

Enzymatic hydrolysis of starch in lucerne (Medicago sativa L.)taproots is the conventional method used to determine the quantityof carbohydrates allocated to regrowth. Etiolated growth froma taproot could be used to quantify total root biomass allocatedto regrowth. This study compared concentrations of non-structuralcarbohydrates, as measured by -amylase hydrolysis of starchto glucose, to concentrations of non-structural biomass, asmeasured by etiolated growth from lucerne taproots placed inan incubator and plants in situ. The concentration of starchfrom enzymatically assayed taproots was 325 g kg^-1 expressedas glucose equivalents. Etiolated growth and weight loss byrespiration from plants grown in the incubator accounted for524 g of actual biomass per kg of root. There was 46·2g kg^-1 of N, 3·1 of P, and 33·1 of K in the etiolatedgrowth. An 88% increase in etiolated growth dry weight was observedfrom plants in situ compared to taproots placed in the incubator.Accurate quantification on non-structural biomass should notbe limited to sampling just the taproot, but must included theentire root system. Compared to determining non-structural carbohydratesby enzymatic hydrolysis of starch, the procedure used in determiningnon-structural biomass by etiolate growth gave results in unitsrelative to the plant. The use of etiolate growth also providedinformation on mineral nutrient partitioning from root to shoots,was less technically demanding, and could be applied to theentire root system.Copyright 1993, 1999 Academic Press Medicago sativa, root carbohydrates, etiolated growth, taproot     

Differences in the susceptibility of five herbivore species and developmental stages to tomato resistance induced by methyl jasmonate treatment

We compared the susceptibility of five herbivores to tomato resistance induced by methyl jasmonate (MeJA) treatment. We tested for lethal effects against five herbivores (Spodoptera litura, Mamestra brassicae, Frankliniella occidentalis, Tetranychus urticae, and Henosepilachna vigintioctopunctata) at various MeJA concentrations. The mortality of all five herbivores increased significantly with increasing MeJA concentration. The 25 % lethal concentration was 0.03 μM for both first-instar larvae of S. litura and third-instar larvae of M. brassicae, 0.51 μM for third-instar larvae of S. litura, 0.76 μM for adult T. urticae, 2.4 μM for first-instar larvae of F. occidentalis, and 5.7 μM for first-instar larvae of H. vigintioctopunctata. Thus, the degree of susceptibility to MeJA-induced resistance of tomato was first-instar larvae of S. litura = third-instar larvae of M. brassicae > third-instar larvae of S. litura ≈ adult T. urticae > first-instar larvae of F. occidentalis > first-instar larvae of H. vigintioctopunctata. Mortality of first-instar larvae of M. brassicae was >90 % at all concentrations. Mortality of fourth-instar larvae of H. vigintioctopunctata (<7 %) was similar to that of the control at all MeJA concentrations. We also detected statistically significant weight loss of the surviving lepidopteran larvae, increased larval duration of F. occidentalis and H. vigintioctopunctata, and reduced egg production by T. urticae grown on MeJA-treated tomato, suggesting that the MeJA-induced resistance can control these herbivores, but effectiveness is different on different species and growth stage. Feeding by both M. brassicae and H. vigintioctopunctata larvae activated JA-inducible genes in tomato.     

Anti-juvenile hormone activity of azacoprostane depends on inhibition of molting

Administration of the anti-ecdysteroid azasteroid 25-azacoprostane (AZCP) to larvae of the tobacco hornworm, Manduca sexta, often inhibits molting without curtailing growth. As a result, AZCP-treated larvae may attain weights 2–3 times greater than normal during the first four instars. This may explain the paradoxical anti-juvenoid activity of AZCP evident in the precocious metamorphosis of AZCP-treated fourth-instar larvae, which was noted only after those larvae attained unusually large weights over 2 g. The weight interval of 2–3 g has been previously identified as a critical threshold for initiation of metamorphosis by normal final (fifth) instar larvae. The premature attainment of this weight threshold by AZCP-treated fourth-instar larvae probably activates the same premetamorphic sequence of events that normally occurs in the fifth instar at this threshold, including activation of potent endogenous anti-juvenoids. Anti-juvenoid activity limited to the penultimate instar is likely to be a general feature of compounds that block molting without inhibiting growth. © 1997 Wiley-Liss, Inc.     

Prey selection and baculovirus dissemination by carabid predators of Lepidoptera

Abstract.

• 1 The interaction between coleopteran predators and baculovirus-infected larvae was studied in the laboratory and the field in order to assess the potential role of predators in the dissemination of a nucleopolyhedrovirus (NPV).
• 2 Preference tests using three carabid species, Harpalus rufipes De Geer, Pterostichus melanarius Illiger and Agonum dorsale Pont, showed no evidence of discrimination between healthy and diseased larvae of the cabbage moth Mamestra brassicae L. (Lepidoptera: Noctuidae) as prey items.
• 3 Virus infectivity was maintained after passage through the predator's gut. NPV mortality ranged from 97% to 20% when test larvae were exposed to faeces collected immediately after and 15 days post-infected meal respectively.
• 4 The potential for transfer of inoculum in the environment was estimated in the laboratory by soil bioassay. Carabids continuously passed infective virus to the soil for at least 15 days after feeding on infected larvae.
• 5 Field experiments showed that carabids which had previously fed on diseased larvae transferred sufficient virus to the soil to cause low levels of mortality in larval populations of the cabbage moth at different instars.

     

Bacterivory by deposit-feeding mayfly larvae (Stenonema spp.)

SUMMARY.

• 1 The importance of bacteria in the diet of deposit-feeding mayflies (Stenonema spp.) from the Ogeecnee River, a sixth order low-gradient blackwater river in Georgia, U.S.A., was determined. Stenonema are abundant and productive on snags in biackwater rivers in the southeastern Coastal Plain of the U.S.A. Bacteria are abundant in the seston in this river, and are a potentially important food source.
• 2 Naturally occurring seston was fed to Stenonema larvae after bacterial DNA in the seston was labelled with methyl-[³H]thymidine. Larval respiration measurements and growth rate estimations were used to compare the amount of bacterial carbon assimilated and retained in larval tissue to the carbon requirements of the larvae.
• 3 Stenonema larvae incorporated 8.7×10⁷±1.3×10⁷ bacteria larva^?1 h^?1 This was equivalent to 93±6% of their daily growth, and 47±3% of their total daily carbon needs. Larger larvae incorporated more bacterial biomass, but mass specific incorporation was not related to size. Ingestion of bacteria while eating seston accumulated on snags appears to be an important component of the diet of Stenonema larvae in these rivers.

     

Impacts of cattle on amphibian larvae and the aquatic environment

• 1 Agricultural practices such as cattle farming may have direct or indirect negative effects on larval amphibians by decreasing water quality through deposition of nitrogenous waste, causing eutrophication, and grazing shoreline vegetation that contributes to detrital cover and food.
• 2 We sampled amphibian larvae on the Cumberland Plateau, Tennessee, U.S.A., twice per week, water quality twice per month and algal and detrital biomass once per month at seven wetlands (three cattle‐access and four non‐access) from March to August 2005 and 2006.
• 3 In general, species richness and diversity of amphibian larvae were greater in wetlands without cattle. Mean relative abundance of green frog (Rana clamitans) and American bullfrog (Rana catesbeiana) tadpoles was greater in non‐access wetlands. Body size of some ranid larvae was larger in cattle‐access wetlands but this trend did not exist for juveniles or adults. Dissolved oxygen was lower, while specific conductivity and turbidity were higher in cattle‐access wetlands. Mean biomass of detritus was lower in cattle‐access wetlands compared to non‐access wetlands; no differences were detected in algal biomass.
• 4 Given the negative impacts of cattle on water quality, detrital biomass, larval amphibian species richness and relative abundance of some amphibian species, we recommend that farmers consider excluding these livestock from aquatic environments.

     

Dosage-mortality and time-mortality studies of a granulosis virus in a laboratory strain of the codling moth,Laspeyresia pomonella

Different doses of a granulosis virus were administered to first- and fifth-instar larvae of the codling moth Laspeyresia pomonella. Virus was very pathogenic for both larval instars. The LD₅₀ values for first- and fifth-instar larvae were 5 and 49 capsules/larva, respectively. However, fifth-instar larvae were much more variable in their response to virus than first-instar larvae. Using probit methods it was calculated that 1 capsule could cause death in about 25% of both larval instars but 1578 capsules were required to cause 70% mortality of fifth-instar larvae as compared to 12 capsules for first-instar larvae. This is the first report of a decided difference in variability of response to virus by two larval instars of the same species. A bimodal response by both larval instars was observed in time-mortality studies. Apparently, about 20% of the larvae were very resistant to virus infections.