Cuticle Formation in Hemicycliophora arenaria,Aphelenchus avenae and HirschmannIella gracilis

The onset of molting in all stages of Hemicycliophora arenaria was preceded by the appearance of numerous, discrete globular structures which were termed "molting bodies" because they were present in the hypodermis only during the production of the new cuticle. In all parasitic stages the molt commenced with the separation of the cuticle from the hypodermis from which the new sheath and cuticle were differentiated. Following completion of the new sheath and cuticle most of the old outer covering was apparently absorbed before ecdysis. Electronmicrographs of body wall cross sections in molting L4 male specimens revealed the final molt to be a double molt in which an additional sixth cuticle was produced. Since both a new sheath and cuticle were produced during the molt of each stage, the sheath must be considered as an integral part of the cuticle and not as a residual cuticle or the result of an incomplete additional molt. Molting in Aphelenchus avenae and Hirschmanniella gracilis was less complex and "molting bodies" were not observed. After cuticle separation the hypodermis gave rise to a new trilaminate zone, the future cortex, and (later) the matrix and striated basal layers.     

Angiostrongylus cantonensis: Scanning Electron Microscopic Observations on the Cuticle of Moulting Larvae

Angiostrongylus cantonensis is a parasitic nematode that needs to develop in different hosts in different larval stages. Freshwater snails, such as Pomacea canaliculata, are the intermediate host, and rats are the definitive host. Periodic shedding of the cuticle (moulting) is an important biological process for the survival and development of the parasite in the intermediate and definitive hosts. However, there are few studies on the cuticle alterations between different stages of this parasite. In this study, we observed the ultrastructural appearance and changes of the cuticle of the 2nd/3rd stage larvae (L2/L3) and the 3rd/4th stage larvae (L3/L4) using a scanning electron microscope. We also first divided L2/L3 into late L2 and early L3. The late L2 lacked alae, but possessed a pull-chain-like fissure. Irregular alignment of spherical particles on the cuticle were noted compared to the L3. Alae appeared in the early L3. The old cuticle turned into a thin film-like structure which adhered to the new cuticle, and spherical particles were seen regularly arranged on the surface of this structure. Regular rectangular cavities were found on the surface of L3/L4. The caudal structure of L3/L4 was much larger than that of L3, but caudal inflation, such as seen in L4, was not observed. These results are the first to reveal the ultrastructural changes of the cuticle of A. cantonensis before and after moulting of L2/L3 and L3/L4.     

Stage-specific Differences in Lectin Binding to the Surface of Anguina tritici and Meloidogyne incognita

The occurrence and distribution of several lectin binding sites on the outer surfaces of eggs, preparasitic second-stage juveniles (J2), parasitic second-stage juveniles (PJ2), females, and males of two tylenchid nematodes, Anguina tritici and Meloidogyne incognita race 3, were compared. In both species, a greater variety of lectins bound to the eggs than to other life stages; lectin binding to eggs was also more intense than it was to other life stages. Species-specific differences also occurred. More lectins bound to the amphids or amphidial secretions of M. incognita J2 than to the amphids or amphidial secretions of A. tritici J2. Lectins also bound to the amphids or amphidial secretions of adult male and female A. tritici, but binding to the cuticle occurred only at the head and tail and was not consistent in all specimens. Canavalia ensiformis and Ulex europaeus lectins bound specifically to the outer cuticle of M. incognita. Several other lectins bound nonspecifically. Oxidation of the cuticle with periodate under mild conditions, as well as pretreatment of the nematodes with lipase, markedly increased the binding of lectins to the cuticle of A. tritici J2 but not, in most cases, to M. incognita J2 or eggs of either species.     

Characterization of Sialyl and Galactosyl Residues on the Body Wall of Different Plant Parasitic Nematodes

The plant parasitic nematodes Helicotylenchus multicinctus, Meloidogyne javanica, Tylenchulus semipenetrans, and Xiphinema index, differing in their host specificity and parasitic habits, were analyzed as to their cuticle surface sialyl, galaclosyl, and/or N-acetylgalactosaminyl residues. The procedure involved the selective oxidation of sialic acid and galactose/N-acetylgal-actosamine residues using periodate and galactose oxidase, respectively, to form reactive aldehyde groups. These functional groups were coupled directly with a new hydrazide-containing compound, the fluorescent reagent lissamine rhodamine-β-alanine hydrazide, or they were utilized to introduce DPN-groups to the nematode cuticle. The distribution of the DNP-tagged glycoconjugates was visualized by treating the nematodes with rabbit anti-DNP antibody and staining with fluorescein isothiocyanate (FITC)-labeled goat antirabbit IgG. Sialo residues were observed along the entire outer body wall of the first three aforementioned nematodes, but there were some differences in reaction among the various life stages within the species. In X. index, sialo residues were sited in the tail and head areas, mainly on the lips, oral opening, amphid apertures and stylet. Galactose oxidase treatments revealed galactose on N-acytylgalactosamine residues on T. sentipenetrans and X. index, but there were no indications that their presence was dependent on the developmental stage. Trypsin, pronase, and neuraminidase pretreatment completely abolished the fluorescence in T. semipenetrans but did not alter the sialo residue binding reaction in H. multicinctus or M. javanica, indicating possible differences in the outer body wall saccharide structure and composition between these nematodes. The existence and nature of sugar residues on the cuticle surface of nematodes could contribute to an understanding of the specific recognition by phytophagous nematodes of their host, and perhaps also of the virus transmission mechanism in those nematodes which serve as vectors.     

Cuticle Ultrastructure of Hemicycliophora arenaria,Aphelenchus avenae,Hirschmanniella gracilis and Hirschmanniella belli

Ultrathin sections of all parasitic stages of Hemicycliophora arenaria revealed two major divisions in the body covering. The outermost was a seven-layered sheath and the innermost a five-layered cuticle comprising three zones; an outer trilaminate cortex, a fibrillar matrix and a striated basal layer. The body covering of the nonparasitic males also exhibited two major divisions: the outer, a relatively thin four-layered sheath and the inner, a six-layered cuticle consisting of three zones; an outer trilaminate cortex, a two-layered matrix and a striated basal layer. The cuticles of all stages of Aphelenchus avenae were similar, consisting of five layers divisible into three zones; an outer trilaminate cortex, a fibrillar matrix and a striated basal layer. Hirschmanniella gracilis and H. belli cuticles were also similar in all stages examined, consisting of six layers divisible into three zones; an outer trilaminate cortex, a two-layered matrix and a striated basal layer.     

Structure and development of Austramphilina elongata Johnston, 1931 (Cestodaria: Amphilinidea)

The life cycle and structure of the larva of Austramphilina elongata using light-microscopy, scanning and transmission electron microscopy are described. Eggs are round and non-operculate. Larvae hatch in freshwater and penetrate through the cuticle of juvenile crayfish, Cherax destructor, and of freshwater shrimps, Paratya australiensis and Atya (= Atyoida) sp., shedding their ciliated epidermis. In the last two hosts, development to the infective stage does not occur. In crayfish, larvae grow and reach the infective stage. Turtles, Chelodina longicollis, become infected by eating infected crayfish. Larvae penetrate through the oesophageal wall of the turtle and migrate toward the coelom, where maturation occurs. The free-swimming larva has a syncytial epidermis which covers most of the body except for the posterior region bearing the hooks. It is loosely attached to a thin underlying tegument, which is connected to ‘insunk’ nucleated cell bodies. It forms a thick surface layer in the posterior region. There are three flame cells on each side of the body and two postero-lateral excretory pores. There are no lateral flames. The weir apparatus of the flame cell has the structure typical of parasitic platyhelminths. The smaller capillaries have a smooth surface, that of the terminal ducts is covered by numerous microvilli. Three types of penetration glands open anteriorly. There are five pairs of hooks; one median ‘normal’, two submedian halberd-shaped, and two lateral serrate. Hook are not lost, they are arranged around the gonopore of the adult. Frontal glands opening into the proboscis were found in the anterior part of the body in all stages examined. Infective stages in crayfish have developing reproductive organs and ducts. The tegument of the adult has many microvilli.     

Ultrastructural Variation of Cuticular Layers in Cephalobinae (Nemata: Rhabditida)

The ultrastructure of the body wall cuticle in Acrobeles complexus, Cervidellus alutus, and Zeldia punctata was studied as a step toward understanding biological diversity within Cephalobinae, and to discover new characters for phylogeny-based classification of the suborder. In each species the cuticle consists of cortical, median, and basal layers. The cortical layer includes an external trilaminate and internal granular zone; the basal layer is striated. In Z. punctata the median layer is electron-lucent, vacuolar, and penetrates the cortical layer; it also includes periodically dense columns that apparently correspond to punctuations visible with light microscopy. In contrast, the median layer of the body wall cuticle in A. complexus and C. alutus is bisected by a zone that undulates parallel to the nematode surface and with periodicity corresponding to annuli. Phylogenetic analysis, using derived cuticle patterns of Cephalobinae, requires an understanding of ecological pressures that could result in convergent evolution of cuticle characters.     

A Horsehair Worm,Gordius sp. (Nematomorpha: Gordiida), Passed in a Canine Feces

Nematomorpha, horsehair or Gordian worms, include about 300 freshwater species in 22 genera (Gordiida) and 5 marine species in 1 marine genus (Nectonema). They are parasitic in arthropods during their juvenile stage. In the present study, the used gordian worm was found in the feces of a dog (5-month old, male) in July 2014. Following the worm analysis using light and scanning electron microscopes, the morphological classification was re-evaluated with molecular analysis. The worm was determined to be a male worm having a bi-lobed tail and had male gonads in cross sections. It was identified as Gordius sp. (Nematomorpha: Gordiidae) based on the characteristic morphologies of cross sections and areole on the cuticle. DNA analysis on 18S rRNA partial sequence arrangements was also carried out, and the gordiid worm was assumed to be close to the genus Gordius based on a phylogenic tree analysis.     

Ultrastructure of Gonionchus australis (Xyalidae,Nematoda)

Observations are reported on the ultrastructure of the buccal cavity, body cuticle, spermatids, spermatozoa, male genitalia, and caudal glands of Gonionchus australis. The buccal cuticle is a continuation of the pharyngeal cuticle. Anteriorly it is secreted by arcade tissue and overlaps the mouth rim; laterally it forms longitudinal tooth ridges. The non-annulated cephalic cuticle differs sharply from the remainder of the body wall cuticle. The cortical and basal zones become much thinner, while a largely structureless, lucent median zone expands to fill the bulk of the lips and lip flaps. Spermatids possess fibrous bodies, multimembrane organelles, mitochondria, and compact chromatin. The spermatozoa of G. australis resemble those of most other nematodes by the absence of the nuclear envelope and presence of fibrous bodies, mitochondria, and compact chromafin. The ejaculatory duct possesses microvilli. Two ejaculatory glands lie beside the duct. Two neurons are located within each spicule and each part of the paired gubernaculum. Caudal gland nuclei are large, with dispersed chromatin. The ducts of all three caudal glands are filled with secretory vesicles.     

The life cycle of Anguina agrostis: Development in host plant

Bird A.F. and Stynes B.A. 1981. The life cycle of Anguina agrostis: Development in the host plant. Internationaljournal for Parasitology11: 431–440. The growth and development of the infective second stage “dauer” larvae (DL₂) of Anguina agrostis into adults have been followed under field conditions in rye grass (Lolium rigidum). Three moults were observed to occur during the parasitic phase of development. From the third (second parasitic) moult onwards, there was much more variability in the size of the female nematodes than in the males and sexual dimorphism became very pronounced. The transition from the DL₂ to the second stage parasitic larva (PL₂) is marked by the disappearance of the numerous lipid storage granules which are characteristic of the DL₂, and the development in the PL₂ of an intestine which becomes more pronounced in each succeeding stage, particularly in the adult female. Anguina agrostis is unusual among parasitic nematodes in that the DL₂ has the thickest cuticle of all stages, including adults. The L₄ and adult males have thicker cuticles than the females at the same stages of development. Moulting appears to involve resorption of the innermost basal zone of the shed cuticle as well as morphological and chemical changes to the epicuticle.     

Changes in Esophageal Gland Activity During the Life Cycle of Nacobbus aberrans (Nemata: Pratylenchidae)

Electron and light microscopy were used to study the dorsal gland (DG) and the two subventral glands (SvG) of seven developmental phases of Nacobbus aberrans: pre-parasitic second-stage juveniles (J2), parasitic J2, third- (J3) and fourth- (J4) stages, migratory females, young sedentary females, and mature sedentary females. In each developmental phase the level of esophageal gland activity, was estimated by the abundance of organelles associated with secretory pathways, including endoplasmic reticulum, ribosomes, Golgi, multivesicular bodies, and secretory granules. All esophageal glands were metabolically active in all J2 examined, although only in parasitic J2 were there numerous secretory granules in the esophageal gland extensions and ampullae. No evidence of secretory activity was observed in the esophageal glands of the coiled and relatively inactive J3 and J4, nor in migratory females; these stages apparently do not feed. Observations suggest that reserves stored by J2 sustain three ecdyses and the migratory female''s search for a feeding site and induction of a syncytium. Feeding activity is resumed in young and mature sedentary females, in which the DG is highly active and enlarged. The SvG are metabolically active, but with little synthesis of secretory granules, suggesting that in sedentary females the SvG may have physiological roles other than digestion.     

Temporal Formation and Immunolocalization of an Endospore Surface Epitope During Pasteuria penetrans Sporogenesis

The synthesis and localization of an endospore surface epitope associated with the development of Pasteuria penetrans was determined using a monoclonal antibody (MAb) as a probe. Nematodes, uninfected or infected with P. penetrans, were harvested at 12, 16, 24, and 38 days after inoculation (DAI) and then examined to determine the developmental stage of the bacterium. Vegetative growth of P. penetrans was observed only in infected nematodes harvested at 12 and 16 DAI, whereas cells at different stages of sporulation and mature endospores were observed at 24 and 38 DAI. ELISA and immunoblot analysis revealed that the adhesin-associated epitope was first detected at 24 DAI, and increased in the later stages of sporogenesis. These results indicate that the synthesis of adhesin-related proteins occurred at a certain developmental stage relative to the sporulation process, and was associated with endospore maturation. Immunofluorescence microscopy indicated that the distribution of the epitope is nearly uniform on the periphery of each spore, as defined by parasporal fibers. Immunocytochemistry at the ultrastructural level indicated a distribution of the epitope over the parasporal fibers. The epitope also was detected over other structures such as sporangium and exosporium during the sporogenesis process, but it was not observed over the cortex, inner-spore coat, outer-spore coat, or protoplasm. The appearance of the adhesin epitope first at stage III of sporogenesis and its presence on the parasporal fibers are consistent with an adhesin-related role in the attachment of the mature endospore to the cuticle of the nematode host.     

In vitro Cultivation of the Entomogenous Nematode Filipjevimermis leipsandra

The mermithid nematode, Filipjevimermis leipsandra, was successfully cultivated to the preadult stage in Schneider''s Drosophila medium supplemented with 20% fetal bovine serum. Upon transfer to a solid substrate the preadults continued to develop into ovipositing adult females. Four molts were observed. The first molt occurred in the egg. The second occurred after 6-8 days in culture during which the very thin cuticle was shed completely. The third molt occurred after 18-20 days in culture; the cuticle was retained by the third-stage nematode. This stage was considered comparable to the preadult stage that emerges from host larva, Diabrotica spp. The fourth molt occurred within 12 days after the preadult was transferred from the liquid medium to a solid substrate. Adult females began ovipositing viable eggs 1-3 days after the final molt.     

Using FAME Analysis to Compare, Differentiate, and Identify Multiple Nematode Species

We have adapted the Sherlock^® Microbial Identification system for identification of plant parasitic nematodes based on their fatty acid profiles. Fatty acid profiles of 12 separate plant parasitic nematode species have been determined using this system. Additionally, separate profiles have been developed for Rotylenchulus reniformis and Meloidogyne incognita based on their host plant, four species and three races within the Meloidogyne genus, and three life stages of Heterodera glycines. Statistically, 85% of these profiles can be delimited from one another; the specific comparisons between the cyst and vermiform stages of H. glycines, M. hapla and M. arenaria, and M. arenaria and M. javanica cannot be segregated using canonical analysis. By incorporating each of these fatty acid profiles into the Sherlock^® Analysis Software, 20 library entries were created. While there was some similarity among profiles, all entries correctly identified the proper organism to genus, species, race, life stage, and host at greater than 86% accuracy. The remaining 14% were correctly identified to genus, although species and race may not be correct due to the underlying variables of host or life stage. These results are promising and indicate that this library could be used for diagnostics labs to increase response time.     

Two Simple Methods for the Collection of Individual Life Stages of Reniform Nematode,Rotylenchulus reniformis

The sedentary semi-endoparasitic nematode Rotylenchulus reniformis, the reniform nematode, is a serious pest of cotton and soybean in the United States. In recent years, interest in the molecular biology of the interaction between R. reniformis and its plant hosts has increased; however, the unusual life cycle of R. reniformis presents a unique set of challenges to researchers who wish to study the developmental expression of a particular nematode gene or evaluate life stage–specific effects of a specific treatment such as RNA-interference or a potential nematicide. In this report, we describe a simple method to collect R. reniformis juvenile and vermiform adult life stages under in vitro conditions and a second method to collect viable parasitic sedentary females from host plant roots. Rotylenchulus reniformis eggs were hatched over a Baermann funnel and the resultant second-stage juveniles incubated in petri plates containing sterile water at 30°C. Nematode development was monitored through the appearance of fourth-stage juveniles and specific time-points at which each developmental stage predominated were determined. Viable parasitic sedentary females were collected from infected roots using a second method that combined blending, sieving, and sucrose flotation. Rotylenchulus reniformis life stages collected with these methods can be used for nucleic acid or protein extraction or other experimental purposes that rely on life stage–specific data.     

Polyamine Synthesis by the Mermithid Nematode Romanomermis culicivorax

The polyamine and amino acid composition of the mermithid nematode, Romanomermis culicivorax, and its host, Aedes aegypti, was determined. Putrescine, spermidine, spermine, cadaverine and two acetylated spermidine derivatives were present in parasitic juveniles, newly-emerged post-parasites, and eggs of R. culicivorax. Whole insect homogenates of fourth-instar A. aegypti contained the same array of polyamines, except that the putrescine:spermidine ratio was the inverse of that in parasitic R. culicivorax. Polyamines and amino acids were in greater concentrations in the nematode eggs than in other developmental stages investigated. Both the host and nematode possess the biosynthetic capacity for polyamine biosynthesis, as evidenced by measurable activities of ornithine decarboxylase in the host''s tissues and the nematode''s free-living stages.     

Effect of Temperature on Development and Survival of the Mermithid Filipjevimermis leipsandra

The development and survival of egg, juvenile (parasitic), preovipositing, and ovipositing stages of the parasitic mermithid Filipjevimermis leipsandra were determined at eight temperatures. Infection of the host, Diabrotica balteata, peaked at 30 C and fell off sharply at warmer or cooler temperatures. No development, oviposition, or infection occurred at < 20 C. Fecundity was highest at 25 C, and 50% of the eggs were laid in the first 4-7 days of oviposition.     

Atomic Force Microscopy of Plant-Parasitic Nematodes

A simple method for atomic force microscopy (AFM) of nematode cuticle was developed to visualize the external topography of Helicotylenchus lobus, Meloidogyne javanica, M. incognita, and Xiphinema diversicaudatum. Endospores of two isolates of the nematode parasite, Pasteuria penetrans, adhering to M. incognita and X. diversicaudatum were also visualized and measured by this technique. Scanning procedures were applied to specimens killed and dehydrated in air or dehydrated and stored in glycerol. Atomic force microscopy scanning of nematodes in constant height mode yielded replicated high-resolution images of the cuticle showing anatomical details such as annulations and lateral fields. Submicrometer scale images allowed the identification of planar regions for further higher resolution scans.     

The MIXTA-like Transcription factor MYB16 is a major regulator of cuticle formation in vegetative organs

Cuticle secreted on the surface of the epidermis of aerial organs protects plants from the external environment. We recently found that Arabidopsis MIXTA-like R2R3-MYB family members MYB16 and MYB106 regulate cuticle formation in reproductive organs and trichomes. However, the artificial miRNA (amiRNA)-mediated knockdown plants showed no clear phenotypic abnormality in vegetative tissues. In this study, we used RNA interference (RNAi) targeting MYB16 to produce plants with reduced expression of both MYB16 and MYB106. The rosette leaves of RNAi plants showed more severe permeable cuticle phenotypes than the myb106 mutants expressing the MYB16 amiRNA in the previous study. The RNAi plants also showed reduced expression of cuticle biosynthesis genes LACERATA and ECERIFERUM1. By contrast, expression of a gain-of-function MYB16 construct induced over-accumulation of waxy substances on leaves. These results suggest that MYB16 functions as a major regulator of cuticle formation in vegetative organs, in addition to its effect in reproductive organs and trichomes.     

Cuticle Ultrastructure of Criconemella curvata and Criconemella sphaerocephala (Nemata: Criconematidae)

Cuticle ultrastructure of Criconemella curvata and C. sphaerocephala females is presented; males were available only in the second species. Ultrathin sections revealed three major zones: cortical, median, and basal. The cortical zone in the females consists of an external and internal layer. In C. curvata the external layer is trilaminate and at each annule it is covered by a multilayered cap. In C. sphaerocephala the trilaminate layer is lacking and the external cortical layer includes an osmophilic coating. In both species the internal layer consists of alternate striated and unstriated sublayers. The median zone is fibrous with a central lacuna and the zone is interrupted between the annules. The basal zone of the cuticle is striated and narrower between each annule. The cuticle of the C. sphaerocephala male is typical of Tylenchida, except under both lateral fields; the striated layer becomes forked at the first incisure and the innermost two prongs of the fork overlap each other, resulting in a continuous striated band.