The mode of transmission of Tipula iridescent virus: I. Source of infection

A virus was isolated from a diseased tipulid larva and identified as Tipula iridescent virus (TIV) on the basis of the size and morphology of the virion, the production of iridescence in vitro and in infected tipulid larvae, and a serological reaction between antiserum against the virus and an isolate of TIV.A stock of Tipula oleracea was bred in the laboratory. Subjection of larvae to several stress factors did not result in any evidence for activation of a latent virus. Healthy T. oleracea larvae did not develop iridescence when confined in petri dishes with either live TIV-infected larvae or with large amounts of their feces, although these feces were found to contain infective virus by injecting extracts into healthy larvae. It appears that the concentration of virus in the feces of infected larvae is not high enough for them to serve as a source of infection. It was shown that the cadavers of TIV-infected larvae can serve as a source of infection for healthy first- and fourth-instar larvae.     

Tipula iridescent virus infection in the developmental stages of Tipula oleracea

Tipula iridescent virus (TIV) is infective to all four larval instars, pupae, and adults of both sexes of Tipula oleracea, and iridescence has been observed in infected insects at all these stages. Third- and fourth-instar larvae were more resistant to ingested TIV than first and second instars. When TIV was injected into the hemocoel, the results suggested a possible decrease in resistance from the third larval instar to the pupa. Incubation periods (times from injection of TIV to appearance of iridescence) were significantly shorter in older fourth-instar larvae than in younger fourth-instar or thirdinstar larvae, but variability in incubation period was significantly greater in younger fourth-instar larvae than in the other two stages. Many insects which were inoculated with TIV in one stage developed iridescence and died in later stages. The amounts of infective TIV in two infected adults were estimated.     

The effect of temperature upon Tipula iridescent virus infection in Tipula oleracea

The mean incubation period (time from inoculation with virus to first appearance of iridescence) was used as an indication of the rate of replication of Tipula iridescent virus (TIV) in Tipula oleracea larvae. The mean incubation period and survival time (time from inoculation with virus to death) were compared with the mean instar duration at a series of temperatures. In most stages of the insect the optimum temperature for the replication of TIV and the temperature for the shortest mean survival time coincided with the peak temperature (the temperature for the fastest development of the insect stage). The peak temperature for T. oleracea does not appear to be the same for each stage, and the optimum temperature for TIV replication appears to be closely linked to the peak temperature of the infected stage. The optimum temperature (the temperature at which most individuals survived from hatching to the adult stage) of the insect was 20°C. Tipula iridescent virus replicated in T. oleracea larvae and pupae at 3° and 27°C, which are near the temperature limits for the insect. Incubation periods and survival times in TIV-inoculated larvae incubated in the field were much longer in winter than in summer.     

A Tipula paludosa population with a high incidence of two pathogens

The incidence of lethal parasites in the larvae of a Tipula paludosa population was monitored for two seasons. The proportions of larvae infected with Tipula iridescent virus (TIV) and a tachinid insect were similar to those in previously studied populations, whereas the proportions of larvae infected with Tipula nuclear polyhedrosis virus (NPV) and a spore-forming bacterium (SFB) were higher. Conservative estimates of mortality due to these four agents were 10.7% in 1977–1978 and 7.7% in 1978–1979. The mean population density and the proportion of SFB-infected larvae were lower in 1978–1979 than in 1977–1978, while the proportion of NPV-infected larvae was higher. In 1979 the proportion of NPV-infected larvae was positively correlated with population density, which was highest in the wettest part of the study area. In both seasons the proportion of SFB-infected larvae was negatively correlated with population density. Larvae infected with the NPV or the SFB became pallid at an advanced stage of infection, but, although infected larvae were found throughout the larval period, pallid larvae were only found in the later part. It is suggested that larvae become infected in an early instar, then the infections slowly develop throughout the remainder of the larval period. Five larvae were found with mixed infections; four were infected with the SFB and NPV, while the fifth was infected with the SFB and TIV.     

The titres of lectins in the haemolymph of Lacanobia oleracea and the effects of parasitism by the ectoparasitoid wasp Eulophus pennicornis

Serum from larvae of Lacanobia oleracea L. (Lepidoptera; Noctuidae) parasitized by Eulophus pennicornis (Hymenoptera; Eulophidae) and from normal non‐parasitized larvae is capable of agglutinating rabbit, sheep, calf, goat, chicken, horse and human erythrocytes, but not yeast. Studies with a range of inhibitory carbohydrates showed that serum lectins(s) had specificity for sugars containing galactose and for rhamnose, and for the glycosubstances fetuin and asialofetuin. Lectin activity is heat‐labile and is not dependent on calcium. Parasitism by E. pennicornis caused an increase in the agglutination titre of the serum from larvae of L. oleracea but not an increase in specific activity (titre per mg protein per ml). However, when venom from the venom gland of female wasps was injected into L. oleracea larvae, both the agglutinating activity and the specific activity of the larval serum increased. The possible causes of this increase are discussed. It is suggested that venom contains antigenic components which, when injected into the haemocoel of the L. oleracea larva, may be increasing lectin synthesis and/or release into the serum.     

Parasitism of Lacanobia oleracea (Lepidoptera,noctuidae) by the ectoparasitic wasp Eulophus pennicornis,results in the appearance of a 27 kDa parasitism-specific protein in host plasma

Little is known about the effects of ectoparasitoids and their secretions on the plasma protein profiles of their insect hosts. To address this deficit, a study has been made of the interactions between an ectoparasitic wasp, Eulophus pennicornis, and its host, the tomato moth, Lacanobia oleracea. In particular, the quantitative and qualitative effects of parasitism or the experimental injection of wasp venom on host plasma proteins were investigated. Results demonstrated that both treatments caused an initial increase in L. oleracea total plasma protein concentration up to day 5 of treatment, but whereas the protein concentration remained high in the experimentally envenomated group, a decrease towards day 8 occurred in parasitized insects. Parasitism was also associated with the appearance of a protein with an estimated molecular weight of 27 kDa. This protein first appeared on day 3 after parasitization and its levels subsequently increased. The protein was not detected in any of the unparasitized larvae (including all the various control groups) or in experimentally envenomated L. oleracea larvae. In addition, the appearance of this protein was not a non-specific result of nutritional deprivation, nor was it a general injury, stress, or infection induced protein. Its appearance was strictly associated with parasitism of L. oleracea by E. pennicornis and thus, it may be described as a parasitism-specific protein (PSP). The PSP has been partially purified using whole gel elution. Gel filtration and SDS PAGE indicated that it has a native molecular weight of 27 kDa and that it does not appear to aggregate to produce higher molecular weight molecules, nor dissociate into lower molecular weight subunits held together by disulphide or covalent bonds. The precise site of synthesis of the 27 kDa PSP is not yet known but some evidence leads us to speculate that it may be synthesised by the feeding E. pennicornis larvae and introduced into their host. This possibility is discussed in relation to previous work detailing the effects of parasitism on L. oleracea haemocyte morphology, function and viability, and the effects of endoparasitoids on host plasma proteins.     

Transmission of a baculovirus in populations of Oryctes rhinoceros

The transmission of the baculovirus of Oryctes rhinoceros, previously called Rhabdionvirus oryctes, was studied. O. rhinoceros adults became infected with the virus when kept in a mixture of sawdust and ground-up virus-killed larvae or together with other virus-infected adults. In the field, mated females were more frequently infected than unmated females. Adults developing from larvae that had survived exposure to various dosages of the virus were not infected. No virus infections occurred in larvae hatching from eggs surface-contaminated with the virus. Larvae hatching from eggs laid by virus-infected females very rarely were infected.In the O. rhinoceros population the virus is transmitted most frequently during mating, possibly when the uninfected partner contacts virus material excreted by the infected partner. The virus can be transmitted in a similar way when infected and healthy beetles feed together in palm trees. Beetles visiting larval breeding sites containing freshly virus-killed larvae can become infected. Virus-infected beetles can pass the infection to healthy larvae when visiting a breeding site.     

Dissemination of the biocontrol agent Vairimorpha necatrix by the spined soldier bug, Podisus maculiventris

The ability of the spined soldier bug, Podisus maculiventris (Say) (Heteroptera: Pentatomidae), to disseminate infective forms of two lepidopteran pathogens, Vairimorpha necatrix (Kramer) (Microspora: Microsporidia) and Lacanobia oleracea granulovirus (LoGV) was investigated. Individual female P. maculiventris that had fed on Lacanobia oleracea L. (Lepidoptera: Noctuidae) larvae, infected with V. necatrix, excreted approximately 6 × 10⁸V. necatrix spores during the subsequent 7 days. Excreted spores were fed to L. oleracea larvae, causing 100% mortality, indicating that the spores remained viable after passing through the gut of the predator. Podisus maculiventris that had fed on V. necatrix or LoGV‐infected larvae were allowed to defecate on the foliage of tomato plants, prior to the infestation of the plants with L. oleracea or Spodoptera littoralis (Boisduval) (Lepidoptera: Noctuidae) larvae. This proved to be an effective way of infecting the pest larvae with the pathogens, particularly when five predatory bugs were used per plant. After 20 days, the number of S. littoralis and L. oleracea surviving on the plants was reduced by 75% and 61%, respectively. Female P. maculiventris maintained on V. necatrix‐infected prey showed reduced egg production and longevity, whilst those fed on LoGV‐infected prey showed only reduced egg production. The potential for P. maculiventris to disseminate insect pathogens is discussed in the context of improved biological control of lepidopteran pests.     

Waterborne toxoplasmosis - Recent developments

Humans become infected with Toxoplasma gondii mainly by ingesting uncooked meat containing viable tissue cysts or by ingesting food or water contaminated with oocysts from the feces of infected cats. Circumstantial evidence suggests that oocyst-induced infections in humans are clinically more severe than tissue cyst-acquired infections. Until recently, waterborne transmission of T. gondii was considered uncommon, but a large human outbreak linked to contamination of a municipal water reservoir in Canada by wild felids and the widespread infection of marine mammals in the USA provided reasons to question this view. The present paper examines the possible importance of T. gondii transmission by water.     

A microsporidium,Nosema pilicornis sp. n., of the purslane sawfly,Schizocerella pilicornis

A new microsporidian species, Nosema pilicornis, which infects the purslane sawfly, Schizocerella pilicornis, is described. This microsporidium infects most body tissues of the host. N. pilicornis was compared to other microsporidian species infecting Hymenoptera and to a group of similar microsporidia infecting Lepidoptera. N. pilicornis could be distinguished from all other microsporidian species on the basis of host range and ultrastructural characteristics of the spore. Spores were oval, containing 11 to 12 polar filament coils, and the polar filament had an angle of tilt of about 80°. N. pilicornis infected lepidopteran larvae, but only when heavy spore dosages were fed to early larval instars. S. pilicornis is a good but sporadic biological control agent of common purslane, Portulaca oleracea, a pernicious weed of vegetable, ornamental, and orchard crops. N. pilicornis, which is transovarially transmitted and causes high mortality in infected larvae, affects the performance of S. pilicornis as a biological control agent.     

A recombinant immunosuppressive protein from Pimpla hypochondriaca (rVPr1) increases the susceptibility of Lacanobia oleracea and Mamestra brassicae larvae to Bacillus thuringiensis

The precise mechanisms underlying Bacillus thuringiensis-mediated killing of pest insects are not clear. In some cases, death may be due to septicaemia caused by Bt and/or gut bacteria gaining access to the insect haemocoel. Since insects protect themselves from microbes using an array of cellular and humoral immune defences, we aimed to determine if a recombinant immunosuppressive wasp venom protein (rVPr1) could increase the susceptibility of two pest Lepidoptera (Lacanobia oleracea and Mamestra brassicae) to Bt. Bio-assays indicated that injection of 6 μl of rVPr1 into the haemocoel of both larvae caused similar levels of mortality (less than 38%). On the other hand, the LD_30-40 of Bt for M. brassicae larvae was approximately 20 times higher than that for L. oleracea larvae. Furthermore, in bio-assays where larvae were injected with rVPr1, then fed Bt, a significant reduction in survival of larvae for both species occurred compared to each treatment on its own (P < 0.001); and for L. oleracea larvae, this effect was more than additive. The results are discussed within the context of insect immunity and protection against Bt.     

Evolution of the Portulaca oleracea L. aggregate in Egypt on molecular and phenotypic levels revealed by morphology,inter-simple sequence repeat (ISSR) and 18S rDNA gene sequence markers

Molecular markers including inter simple sequence repeats (ISSR) and 18S rDNA gene sequence markers were combined with a detailed morphological analysis to seek characters that discriminate four taxa of Portulaca oleracea s.l. These taxa were identified as the microspecies Portulaca nitida, Portulaca oleracea, Portulaca rausii and Portulaca granulatostellulata. Morphological characters did not provide a clear distinction among the four taxa of P. oleracea s.l. It was found that mixed populations of the taxa occur in several locations and morphological similarities between the microspecies were detected. ISSR analysis indicates that gene flow among populations of different taxa was high and most of the genetic variation (61.9%) occurs within population. These results are inconsistent with the general characteristics of P. oleracea as a self- or 5% cross-pollinated species. A close relationship between P. oleracea, P. rausii and P. granulatostellulata was supported by ISSR and 18S rDNA gene sequence. The ISSR and 18s data support the specific status of P. nitida as a recently evolved taxon. We conclude that P. oleracea exists as a polymorphic species and is not divisible into microspecies based on seed surface as the primary morphological trait, and inter simple sequence repeats (ISSR) and 18S rDNA gene sequence markers. We suggest that the taxa do not merit specific rank as morphological characters and absence of a breeding barrier fail to separate the different populations when they become sympatric.     

The snowdrop lectin Galanthus nivalis agglutinin (GNA) and a fusion protein ButaIT/GNA have a differential affect on a pest noctuid Lacanobia oleracea and the ectoparasitoid Eulophus pennicornis

Fusion proteins have considerable potential as novel insect control agents because they enable the oral delivery of insecticidal peptides to the haemolymph of pests. Transport is achieved via fusion of the toxin to a carrier protein Galanthus nivalis agglutinin (GNA) that, after ingestion, binds to and crosses the insect gut epithelia. A fusion protein comprising a toxin from the South Indian red scorpion (Mesobuthus tamulus) that is fused to a GNA polypeptide (ButaIT/GNA) has a detrimental effect on the development of tomato moth Lacanobia oleracea (L.) (Lepidoptera: Noctuidae) larvae. The present study examines the effects of ButaIT/GNA and GNA, delivered orally or by injection, on the development of L. oleracea larvae, and the subsequent effects on the gregarious ectoparasitoid Eulophus pennicornis (Nees) (Hymenoptera: Eulophidae) developing on ButaIT/GNA‐ and GNA‐treated hosts. The fusion protein, but not GNA, reduces the growth of fifth stadium L. oleracea larvae. The development of E. pennicornis is not affected by the presence of ButaIT/GNA in hosts that ingest the protein, although it is affected when hosts are injected with the protein. This difference is considered to be a result of higher levels of fusion protein being present when the fusion protein is injected. Intact ButaIT/GNA is detected by immunoassay in the haemolymph of L. oleracea larvae after ingestion of the fusion protein. More unexpectedly, negative effects are observed for the growth of E. pennicornis larvae developing on hosts that have either ingested, or been injected with GNA.     

Isolation and characterization of a granulosis virus from the tomato moth,Lacanobia oleracea,and its potential as a control agent

A disease causing death in Lacanobia oleracea (Lepidoptera: Noctuidae) occurring in glasshouses in Scotland was shown to be caused by a granulosis virus (GV). Structural properties of the virus were examined by electron microscopy, immunodiffusion, polyacrylamide gel electrophoresis, and restriction endonuclease analysis and compared with an isolate of GV from L. oleracea obtained from France. The two isolates were structurally very similar but could be distinguished by analysis of EcoRI digests of their DNAs. Bioassays of the virus gave LD₅₀ values from 10^4.3 capsules for second-instar larvae to 10^6.6 capsules for fifth-instar larvae. The French isolate was bioassayed in third-instar larvae and was not found to differ significantlyfrom the Scottish isolate. Two small glasshouse trials using the virus to control artificial infestations of L. oleracea indicated that high-volume sprays of virus at 10⁸ to 10⁹ capsules/ml achieved good control. An alternative strategy using much smaller amounts of virus to control the insect is discussed.     

Development of nested multiplex polymerase chain reaction (PCR) assay for the detection of Toxocara canis, Toxocara cati and Ascaris suum contamination in meat and organ meats

Ascarid Larva Migrans Syndrome (ascarid LMS) is a clinical syndrome in humans, caused by the migration of animal roundworm larvae such as Toxocara canis, Toxocara cati and Ascaris suum. Humans may acquire infection by ingesting embryonated eggs, or infective larvae of these parasites in contaminated meat and organ meats. To detect these pathogenic contaminations, a novel nested multiplex PCR system was developed. Our novel nested multiplex PCR assay showed specific amplification of T. canis, T. cati and Ascaris spp. Detection limit of the nested multiplex PCR was tested with serial dilution of T. canis, T. cati or A. suum genomic DNA (gDNA) from 100?pg to 100 ag and found to be 10?fg, 1?fg and 100?fg, respectively. When larvae were spiked into chicken liver tissue, DNA of T. canis and A. suum was detected from the liver spiked with a single larva, while the assay required at least 2 larvae of T. cati. Moreover, the ascarid DNA was detected from the liver of mice infected with 100 and 300 eggs of T. canis, T. cati or A. suum. This nested multiplex PCR assay could be useful for the detection of contamination with ascarid larvae in meat and organ meats.     

The effect of sodium butyrate on Tipula iridescent virus synthesis in insect suspension cell cultures

The effect of sodium butyrate on Tipula iridescent virus (TIV) synthesis in suspension-cultured cells of Estigmene acrea was investigated. Sodium butyrate reduces viral-induced cell fusion but this is reversible with the removal of butyrate. At 7 mM sodium butyrate, TIV replicates in cells within 8 hr, but does not replicate in this time with 10–20 mm butyrate in the cell medium; cells so treated contain large vesicles with inoculum. Upon removal of the inhibitor, TIV replication appears normal, but large inoculum vesicles can still be found in the cytoplasm, and many infected cells have highly condensed chromatin in their nuclei. Sodium butyrate causes a lag of at least 2 hr in viral DNA synthesis as detected by [³H]thymidine incorporation into viroplasmic centres and at 7 mm butyrate viral DNA synthesis is reduced by 50–60%. In comparison, butyrate at 7 and 10 mm concentration does not inhibit host DNA synthesis, but at 15 and 20 mm, nuclear DNA synthesis is markedly reduced.     

Experiments on the transmission of Babesia divergens to cattle by the tick Ixodes ricinus

A modification of the method of rearing Ixodes ricinus gave a successful method of producing and reliably rearing adequate numbers of this tick for experimental work.Experiments on transmission of Babesia divergens by I. ricinus showed that infections could be initiated only in the adult stage of the tick. Whilst all stages of the F₁ generation of an infected female could transmit infection, larvae and nymphs could not acquire it. Infection persisted throughout the F₁ generation and sometimes up to the F₂ larval stage even when the ticks were maintained on hosts not susceptible to B. divergens. Both parasitaemic and premune carrier hosts were infective to ticks. A single infected adult or nymph could transmit infection.     

A laboratory evaluation of the pathogenicity of Bacillus popilliae var. rhopaea, the agent of milky disease in Rhopaea verreauxi (Coleoptera: Scarabaeidae)

Two methods of infection, i.e., feeding known numbers of spores and rearing larvae in contaminated peat, were used to bioassay the susceptibility of Rhopaea verreauxi to Bacillus popilliae var. rhopaea at 23°C. The susceptibility of the three larval instars was similar as measured by the ID₅₀ and IC₅₀ values. However, within an instar, newly molted larvae were less susceptible than mature larvae when infected by the contaminated peat method. It is suggested that this was due to reduced food intake. The range of ID₅₀ values for all bioassays with R. verreauxi larvae were 1.1 × 10⁷ to 4.0 × 10⁷ spores per larva, and IC₅₀ values were 3.4 × 10⁶ to 5.0 × 10⁷ spores per g of contaminated peat. The slope of the probit line was always low (0.6 to 1.8) except for young first-instar larvae infected by contaminated peat when the slope was 4.0. Disease per se did not affect food intake, though intake was reduced at high doses of contaminated peat. Young larvae often died without developing symptoms but, with increasing age, infected larvae were more likely to develop symptoms. Bioassays with Othnonius batesi and Rhopaea morbillosa indicated a much lower susceptibility per os than for R. verreauxi. It is concluded that the potential for using B. popilliae var. rhopaea to control R. verreauxi is high, but the bacillus is unlikely to be of value in control of O. batesi or R. morbillosa.     

A common pathway for metabolism of 4-hydroxybenzylglucosinolate in Pieris and Anthocaris (Lepidoptera: Pieridae)

Caterpillars of Pieris rapae L. (Lepidoptera: Pieridae) convert 4-hydroxybenzylglucosinolate (sinalbin) in brassicaceous plants into 4-hydroxybenzylcyanide sulfate (HBC sulfate), with 4-hydroxybenzylcyanide (HBC) as intermediate. This apparently serves as a detoxification, because alternative formation of a mustard oil is avoided. We confirmed the capacity of P. rapae to convert the intermediate HBC into HBC sulfate. Four additional Pieridae – Anthocaris cardamines L., Pieris virginiensis Harris, Pieris napi oleracea Edwards and Pieris brassicae L., likewise excreted HBC sulfate after ingesting leaves with topically added HBC or leaves naturally containing sinalbin and myrosinase, but not after ingesting control leaves devoid of HBC and sinalbin. We confirmed the capacity of the most distantly related pierid species (A. cardamines) for converting ingested (topically added) sinalbin into HBC sulfate. Larvae of two non-pierid Brassicaceae-feeding insects, the oligophagous sawfly Athalia rosae L. (Hymenoptera: Tenthrenidae) and the polyphagous moth Spodoptera frugiperda (Smith) (Lepidoptera: Noctuidae), did not excrete HBC sulfate after ingesting sinalbin-containing leaves or topically added HBC.     

Molecular identification and larval morphological description of Contracaecum pelagicum (Nematoda: Anisakidae) from the anchovy Engraulis anchoita (Engraulidae) and fish-eating birds from the Argentine North Patagonian Sea

Anisakids use invertebrates as paratenic and/or intermediate hosts as a basic feature of larval transmission. The third-stage larva usually develops in invertebrates which are prey items of finfish paratenic hosts. Contracaecum larvae molt twice inside the egg and hatch as free third-stage larvae ensheathed in the second-stage larval cuticle. Copepods act as paratenic or obligatory hosts, usually ingesting these free L3 larvae, and fish act as intermediate/paratenic or metaparatenic hosts preying on infected copepods. Fish-eating birds acquire L3 larvae by ingesting infected fish where they develop into the fourth-stage larvae and adults. Objectives of this work were to establish the specific correspondence between Contracaecum pelagicum L3 larvae parasitizing the anchovy Engraulis anchoita, and the adults parasitizing the Magellanic penguin Spheniscus magellanicus and the Imperial shag Phalacrocorax atriceps through the use of molecular markers; and, to evaluate the anisakid L3 larval recruitment and infection caused by ingestion of anchovy by S. magellanicus. Sixteen specimens of Contracaecum L3 larvae were analyzed from E. anchoita from Bahía Engaño, Chubut, eight adult nematodes from S. magellanicus and six adult specimens from P. atriceps both from the Valdés Peninsula, Chubut. All nematodes were sequenced for three genes: mitochondrial cytochrome oxidase 2 (mtDNA cox2), mitochondrial ribosomal RNA (rrnS), and the internal transcribed spacers (ITS-1 and ITS-2) of the nuclear ribosomal DNA region. Phylogenetic analyses were performed by using Maximum Parsimony (MP) analysis by PAUP. In addition, studies under SEM and LM were carried out on L3 larvae. All L3 individuals from E. anchoita, adults from S. magellanicus, and P. atriceps clustered in the same clade, well supported in the MP tree inferred from the mtDNA cox2, and rrnS gene sequences analyses. Further, the sequence alignments of L3 larvae and adults of C. pelagicum here obtained at the ITS-1 and ITS-2 regions of the rDNA matched the sequences of C. pelagicum previously deposited by us in GenBank. Nematode recruitment (R_o) was equal to 33.07 (7.20–91.14) L3 larvae for C. pelagicum in each penguin's meal of anchovy. The MP tree topologies obtained from mtDNA cox2 and rrnS genes demonstrated that specimens of Contracaecum L3 larvae from E. anchoita and C. pelagicum from S. magellanicus as well as from P. atriceps constitute a unique clade, well-distinct and supported from all the others formed by the Contracaecum spp. sequenced so far for these genes. Molecular markers are considered to be an effective tool to elucidate larval transmission. The Contracaecum L3 larval recruitment value showed that many worms fail to establish in the bird digestive tract, probably because they are below a critical size. Further work is needed to elucidate other factors (e.g., physiological, immunological) that control nematode populations in the penguin digestive tract.