Ultrastructure of the mouthparts of adult sweetpotato whitefly,Bemisia tabaci Gennadius (Homoptera: Aleyrodidae)

The fine structure of the mouthparts of the whitefly, Bemisia tabaci Gennadius (Homoptera: Aleyrodidae), was examined by scanning and transmission electron microscopy. Adult whitefly mouthparts are similar to those of other homopterans, especially aphids, being composed of the labrum, the labium, and the stylets. The stylet bundle is the feeding organ of the whitefly and is composed of 2 mandibular stylets and 2 maxillary stylets. Mandibular stylets, which are located on the outer aspect of the stylet bundle, each contain 2 dendrites. The tips of the mandibular stylets are curved inward, and there are barb-like ridges on the lateral aspects, which probably function in piercing and cutting plant tissues and in anchoring the stylets in the tissues. The maxillary stylets are not innervated and are interlocked to form 2 separate compartments, the food canal and salivary canal. At the distal end of the interlocked maxillary stylets, there is a small depression, which may allow for mixing of the salivary canal and food canal components. Movement of the B. tabaci stylets during feeding is discussed in comparison with other homopterans.     

Morphological description of the mouthparts of the Asian citrus psyllid, Diaphorina citri Kuwayama (Hemiptera: Psyllidae)

Scanning (SEM) and transmission (TEM) electron microscopy were used to elucidate the morphology of the rostrum, as well as the mandibular and maxillary stylets of the psyllid Diaphorina citri, vector of phloem-inhabiting bacteria associated with citrus huanglongbing (HLB) disease. D. citri has a cone-shaped rostrum that extends behind the pair of prothoracic coxae. The stylet bundle comprises a pair of mandibular (Md) and maxillary (Mx) stylets with a mean length of 513.3 μm; when retracted, their proximal portions form a loop and are stored in the crumena (Cr). Serial cross-sections of the rostrum revealed that the mandibles are always projected in front of the maxillary stylets. The two maxillary stylets form the food and salivary canals, with diameters of 0.9 μm and 0.4 μm respectively. These two canals merge at the end of the stylets forming a common duct with a length of 4.3 μm and a mean diameter of 0.9 μm. The acrostyle, a distinct anatomical structure present in the common duct of aphid maxillary stylets, was not observed by TEM in the ultrathin cross-sections of the common duct (CD) of D. citri. This study provides new information on D. citri mouthparts that may help to understand the feeding behaviour of this important vector of HLB-associated bacteria.     

Opening mechanism of the mouth of the hematophagous hemipteran, Triatoma infestans

A morphological study of the tips of the stylets in an haematophagous hemipteran has been performed with a scanning microscope in order to determine both the relative positions of the mouthparts during a meal, and the means by which the ‘functional mouth’ can open. If the stylets of Triatoma are examined following severance of the labium, differences in the morphology and relative position of the two maxillary tips are observed. When, prior to a meal, the insect explores the medium with its mouthparts, the tips of its maxillary stylet are united. By contrast, when the bug is pumping food the left stylet is retracted relative to the right stylet and its tip is bent outwards.We have studied the mechanics of the system which allows the tip of the left maxillary to rock, resulting in the opening of the alimentary canal. Finally, we have re-examined the stylet movements of dissected animals in the light of these new morphological findings.     

Secretory products of the Malpighian tubules of Cicadellidae (Hemiptera,Membracoidea): an ultrastructural study

The middle segment of the Malpighian tubules (MT), specialized for secretion of proteins and lipids, was investigated by transmission electron microscopy in nymphs and adults of nine cicadellid species (Hemiptera, Cicadellidae). In addition, the external cuticle coated with secretory products of the MT was studied by scanning electron microscopy. The ultimate secretory product found in adult cicadellids, both in the MT and on the cuticle, were intricately structured particles known as brochosomes (BS). These showed significant differences in size, shape and internal structure among species studied. Common features of all BS were a bounding outer membrane and regular cell-like depressions on the surface. Nascent BS develop in numerous Golgi regions as secretory vesicles individually enclosed in larger vacuoles. Definitive structure of BS is acquired during the peculiar post-Golgian maturation. Two basic patterns of the secretion in the MT during ontogenesis were recognized. In Cicadella viridis (L.), Bathysmatophorus reuteri J. Shlb., Graphocraerus ventralis (Fall.) and Doratura impudica Horv. BS are produced and applied onto the cuticle in both adults and nymphs. In contrast, in young nymphs of Vilbasteana oculata (Ldb.), Populicerus nitidissimus (H.-S.), Oncopsis flavicollis (L.) and Ulopa reticulata (F.) the MT are involved in production of various secretions other than BS. The secretory cells in these species undergo a change switching to BS production in the last nymphal instar, so that the BS are applied onto the cuticle for the first time only in freshly molted adults. The secretory patterns differ among subfamilies. The observed diversity of products suggests that the protective water- or feces-repellent function proposed for BS cannot completely explain the adaptive significance of the secretory specialization of the MT in cicadellids.     

Anterior alimentary canal of the pear Psylla,Psylla pyricola foerster (Homoptera,Psyllidae)

Scanning and light microscopy investigations of the anterior alimentary canal of the pear psylla, Psylla pyricola Foerster (Homoptera: Psyllidae), revealed the morphology of the labium and stylets, as well as the presence of sensory structures and a valve in the precibarium. The labium consists of three telescoping segments with an internal labial groove, which surrounds and supports the stylet bundle. Also a part of the labial groove is the internal labial clamp. The stylet bundle is comprised of paired styliform mandibles and maxillae, which interlock to form the food and salivary canals. The stylet bundle proximal to the labium forms a large loop within a membranous crumena. When fully retracted the coiled stylets are under tension. Stylet extension generates increasing tension so that when retracted the stylets readily recoil within the crumena. Penetration of leaf tissues by the stylet bundle is dependent on the interaction between stylet muscles, opening and closing of the labial clamp, the barbed stylet tips, and the ventral position of the labium. Proximal to the crumena the paired stylets separate and diverge at the entrance of the precibarium, which is formed by the interlocking of the epi-and hypopharynges. There are 18 sensory structures in the precibarium, as well as a precibarial valve. These structures appear to be homologous to similar structures observed previously in aphids and leafhoppers. The morphology and the location of the precibarial sensilla suggest that, like the precibarial sensory organs of aphids and leafhoppers, they are gustatory and probably mediate acceptance or rejection of plant fluids, thus playing a major role in locating tissues for feeding.     

Fine structure and sensory apparatus of the mouthparts of the pear psyllid,Cacopsylla chinensis (Yang et Li) (Hemiptera: Psyllidae)

The pear psyllid, Cacopsylla chinensis (Yang et Li) (Hemiptera: Psyllidae), is one of the most significant economic pests of pear in China, causing direct damage through feeding by the highly specialized piercing–sucking mouthparts. The ultrastructural morphology and sensory apparatus of the mouthparts of the adult were examined using scanning and transmission electron microscopy. The piercing–sucking mouthparts of C. chinensis are composed of a three-segmented labium with a deep groove in the anterior side, a stylet fascicle consisting of two mandibular and two maxillary stylets, and a pyramid-shaped labrum. Proximal to the labium, the stylet fascicle forms a large loop within a membranous crumena. Mandibles, with more than ten teeth on the external convex region, can be seen on the distal extremity. Smooth maxillary stylets are interlocked to form a larger food canal and a smaller salivary canal. One dendritic canal housing 2 dendrites is also found in each mandible. Two types of sensilla trichodea, four types of sensilla basiconica, single as well as groups of sensilla campaniformia, and oval flattened sensilla occur in different locations on the labium, whereas a kind of sensilla basiconica is at the junction of the labrum and anteclypeus. Sensilla trichodea and sensilla campaniformia, always present with denticles, are present on the middle labial segment. Three types of sensilla basiconica, two types of sensilla trichodea and two oval flattened sensilla are located on the distal labial segment. The mouthpart morphology and abundance of sensilla located on the labium in C. chinensis are illustrated, along with a brief discussion of their taxonomic and putative functional significance.     

Identification of Meloidogyne Species on the Basis of Head Shape and,Stylet Morphology of the Male

Head shape and stylet morphology of males of 90 populations of M. arenaria, M. hapla, M. incognita, and M. javanica from geographic regions of the world were compared by light microscopy (LM). In addition, stylets of one population each of M. arenaria, M. incognita, and M. javanica and three different chromosomal forms of M. hapla race A and two of race B were excised and examined with a scanning electron microscope (SEM). Differences among species occurred in both head and stylet morphology. Head morphology differed in size and shape of the head cap, annulation of the head region, and width of the head region relative to the first body annule. Differences in stylets occurred in size and shape of the cone, shaft, and knobs. All populations of M. hapla, except one, had similar head morphology, but stylet morphology was different between cytological races A and B. Populations of M. javanica varied with respect to the presence of head annulations. Head shape and stylet morphology of males are recommended as additional characters useful in the identification of root-knot nematodes.     

Asian citrus psyllid stylet morphology and applicability to the model for inter-instar stylet replacement in the potato psyllid

In Hemiptera, presumptive stylets for each consecutive postembryonic instar are manufactured prior to ecdysis to replace the ecdysial stylets discarded with the exuviae. With the discovery that the bacterium “Candidatus” Liberibacter solanacearum accesses the tissues involved in the stylet replacement process of the potato psyllid, a hypothesis was formed that the bacterium could adhere to the stylets of freshly emerged instars and hence gain access to the host plant when feeding is resumed. Although unproven, it was imperative that a model for stylet replacement be built. Stylet morphology and the stylet replacement process of the Asian citrus psyllid (ACP), vector of “C.” L. asiaticus, causal pathogen of citrus greening disease, are comparable to the potato psyllid model system. Morphology consists of a basal terminus with its tab-shaped auricle, a base, shaft, and an apical terminus. Each of the four auricles act as a platform for the replacement apparatus, which is compacted into a tight aggregate of cells, the ‘end-cap’. As modeled, on apolysis of larval instar hypodermis, the aggregate ‘deconstructs’ and expands into a snail shell-shaped tube, the ‘atrium’, that houses the presumptive stylet as it is synthesized. Completed stylets then despool from the atrium and are fitted into their functional positions as the next instar emerges from its exuviae.     

On the pronymphal stage in the migratory locust (Locusta migratoria, Orthoptera, Acrididae)

The structure of the integument, somatic and visceral muscles, midgut, and Malpighian tubules were investigated at the late stages of the embryonic and early postembryonic development of the migratory locust, Locusta migratoria, to assess the organization of its pronymphal stage. In its morphogenetic features, the vermiform locust larva sometimes called the pronymph corresponds to the first nymphal instar covered with the second embryonic cuticle which has not been shed. Since the first-instar locust nymphs before and after the shedding of this embryonic cuticle differ significantly in many morphological characters, two consecutive phases of this nymphal instar can be distinguished: the first phase existing from the moment of development of the third embryonic cuticle to the shedding of the second one; the second phase existing from the shedding of the second embryonic cuticle to the formation of the cuticle of the second nymphal instar. Since the pronymphal stage should precede the nymph stage, it may be concluded that the pronymph of the locust is fully embryonized and covered with the second embryonic cuticle, which is also typical of other insects with hemimetabolous development (Konopová and Zrzavý, 2005). Therefore, it would be erroneous to refer to the vermiform first-instar nymph as the pronymph, because the two stages are separated by molting and formation of a new cuticle.     

Morphology of the mouthparts of the spittlebug Philagra albinotata Uhler (Hemiptera: Cercopoidea: Aphrophoridae)

Mouthparts associated with feeding behavior and feeding habits are important sensory and feeding structures in insects. To obtain a better understanding of feeding in Cercopoidea, the morphology of mouthparts of the spittlebug, Philagra albinotata Uhler was examined using scanning electron microscopy. The mouthparts of P. albinotata are of the typical piercing–sucking type found in Hemiptera, comprising a cone-shaped labrum, a tube-like, three-segmented labium with a deep groove on the anterior side, and a stylet fascicle consisting of two mandibular and two maxillary stylets. The mandibles consist of a dorsal smooth region and a ventral serrate region near the apical half of the external convex region, and bear five nodules or teeth on the dorsal external convex region on the distal extremity; these are regarded as unique features that distinguish spittlebugs from other groups of Hemiptera. The externally smooth maxillary stylets, interlocked to form a larger food canal and a smaller salivary canal, are asymmetrical only in the internal position of longitudinal carinae and grooves. One dendritic canal is found in each maxilla and one in each mandible. Two types of sensilla trichodea, three types of sensilla basiconica and groups of multi-peg structures occur in different locations on the labium, specifically the labial tip with two lateral lobes divided into anterior sensory fields with ten small peg sensilla arranged in a 5 + 4 + 1 pattern and one big peg sensillum, and posterior sensory fields with four sensilla trichodea. Compared with those of previously studied Auchenorrhyncha, the mouthparts of P. albinotata may be distinguished by the shape of the mandibles, the multi-peg structures and a tooth between the salivary canal and the food canal on the extreme end of the stylets. The mouthpart morphology is illustrated using scanning electron micrographs, and the taxonomic and putative functional significance of the different structures is briefly discussed.     

Tubular bodies in dendritic outer segments projecting to second embryonic cuticle from anlagen of contact chemoreceptors in Locusta migratoria L. (Orthoptera : Acrididae) and Periplaneta americana (L.) (Dictyoptera : Blattidae)

Bundles of dendritic outer segments project to the 2nd embryonic cuticle from anlagen of contact chemoreceptors in the antennae of 9-day embryos (80–85% stage) of Locusta migratoria L. (Orthopteroidea) and in the maxillary palps of 24-day embryos (80% stage) of Periplaneta americana (L.) (Blattodea). The dendrite sheaths fuse with irregular nodular thickenings in the 2nd embryonic cuticle in Locusta; in Periplaneta the sheaths are joined to it by filaments. In both species one of the dendritic outer segments shows a dilation within which a tubular body is contained. This tubular body is located in Locusta at the nodular thickening where the dendrite sheath is connected to the 2nd embryonic cuticle. In Periplaneta, the tubular body was observed near the junction between the dendrite sheath and the cuticle in most cases, but at some distance to the cuticle in others. The occurrence of a tubular body is discussed with reference to mechanoreceptive capacities of the sensory cells and to the phylogeny of the 2nd embryonic cuticle.     

Bemisia tabaci （Hemiptera： Aleyrodidae） nymphal feeding in cotton （Gossypium hirsutum） leaves

We used brightfield electron microscopy （BEM）, differential interference contrast microscopy （DICM）, scanning electron microscopy （SEM）, transmission electron microscopy （TEM）, and confocal laser scanning microscopy （CLSM） to investigate the stylet pathways of Bemisia tabaci during nymphal feeding behavior in cotton leaves beginning with penetration of the abaxial leaf surface and ending with stylets in sieve tubes in phloem tissues. Most nymphal stylets within salivary sheaths penetrating leaf tissues made complex turns and developed more than one salivary sheath branch before ending in sieve tubes. The external morphology of the salivary sheaths and their routes between and through leaf cells are described during the present study. Results showed the presence of the stylet within the sieve tubes. B. tabaci nymphs may remove stylets and feed in different sieve tubes. Ten short movies showing the progression of the stylet penetrations from adaxial surface to the sieve tubes are attached to Figures 8-15. The report and movies can be viewed from the internet. Download the movies to a local drive in your computer first for fast upload. The movies are posted on the website http：//www.ars.usda.gov/Services/docs.htm？docid=14629. The movies can be used as a teaching aid in biology classes.     

Assessing the validity of stylets as ageing tools in Octopus pallidus

A method to age octopus was determined through the quantification of growth increments within the stylet structure (highly reduced internal shells). To validate the periodicity of the increments, stylets were analysed from known-age laboratory-raised Octopus pallidus. The animals, which ranged from 3 to 8 months old, were exposed either to a simulated natural or to constant temperature regime. Transverse stylet sections were embedded in thermo-plastic cement and ground until a thin section was achieved. A pre-hatch region and first post-hatch increment was identified in the stylet microstructure. The number of increments, across all ages and temperature treatments, was in remarkably close agreement to age (number of days), clearly demonstrating that stylet increments are deposited daily throughout the lifecycle of O. pallidus. Morphometric analyses of the stylet indicated that increments were laid down regularly during stylet growth and that stylets grew in concert with body size, further supporting daily periodicity. This study successfully validates daily increments in stylets and thus demonstrate a method to age octopus, therefore, potentially having critical implications for future octopus research and the effective management of stocks worldwide.     

The “acrostyle”: A newly described anatomical structure in aphid stylets

The recent demonstration that a plant virus could be retained on protein receptors located exclusively in a small area inside the common duct at the tip of aphid maxillary stylets indicated the possible existence of a distinct anatomical structure at this level. Since no distinct feature within the common duct of any aphid species has ever been reported in the literature, we first carefully re-examined the distal extremity of the maxillary stylets of Acyrthosiphon pisum using transmission- and scanning-electron microscopy. Here, we describe an area of the cuticle surface displaying a different structure that is limited to a “band” paving the bottom of the common duct in each opposing maxillary stylet. This band starts at the very distal extremity, adopts a “comma-like” shape as it continues up towards the salivary canal, reducing in width and disappearing before actually reaching it. Investigations on several aphid species led to the conclusion that this anatomical feature—which we have tentatively named the “acrostyle”—is highly conserved among aphids. We then produced an antibody recognizing a consensus peptide located in the middle of the RR-2 motif of cuticular proteins from A. pisum and showed that this motif is accessible specifically within the acrostyle, indicating a higher concentration of cuticular proteins. While it is clear that at least some viruses can use the acrostyle to interact with their aphid vectors to ensure plant-to-plant transmission, the role of this new “organ” in aphid biology is unknown and calls for further investigation in the near future.     

The sensory systems and feeding behavior of leafhoppers. I. The aster leafhopper,Macrosteles fascifrons stål (homoptera,cicadellidae)

The ultrastructure of the sensilla, and other structures, within the stylets and precibarium of Macrosteles fascifrons were examined by transmission and scanning electron microscopy. Precibarium is a new term, defined here, for the canal that precedes the cibarium inside the leafhopper head. Within the precibarium are found 20 chemosensilla and a previously undescribed structure, the precibarial valve. Twelve mechanosensilla, three in each stylet, are found within the maxillary and mandibular stylets. The relationship between all of these structures and feeding by the insect is detailed in a feeding mechanism hypothesis. It is concluded that leafhoppers (and probably all homopterans) utilize the precibarial chemosensilla alone for gustatory discrimination, the stylet sensilla for proprioception, and the precibarial valve for regulation of fluid uptake and compartmentalization of the sensilla.     

Estimating potential stylet penetration of southern green stink bug – a mathematical modeling approach

Southern green stink bugs, Nezara viridula (L.) (Hemiptera: Pentatomidae), and related species are significant pests of cotton, Gossypium hirsutum L. (Malvaceae), in the USA Cotton Belt. Using their stylets, adults introduce pathogens of cotton into cotton bolls, and preliminary data indicate nymphs can also ingest these pathogens. However, data are lacking regarding stylet penetration potential of N. viridula nymphs, and records of stylet penetration by adults are typically determined after damage has occurred. In this study, rostral segments of all developmental stages of N. viridula were measured to estimate potential stylet penetration depth using a novel mathematical model. Overall mean stylet penetration estimates for all stages ranged from 135.3 μm for first instars to 2 389.3 μm for adult females. Potential stylet penetration significantly increased as the insect progressed through nymphal stages. Penetration was also significantly affected by insect posture while feeding. Overall minimum and maximum observed lengths of rostrum ranged from 835.3 μm (first instars) to 7 088.2 μm (adult females), and mean rostral lengths were significantly different between all stages. This report establishes conservative baselines of potential stylet penetration depths by all nymphal stages and both adult sexes of N. viridula. Additionally, the model presented here can be used to estimate potential stylet penetration for other Hemiptera and closely related insects with similar modes of feeding. In conjunction with crop phenology data, accurate estimates of potential stylet penetration will allow more proactive approaches to pest management in a wide range of high‐value cash crops affected worldwide by N. viridula.     

Morphological Comparison of Head Shape and Stylet Morphology of Second-stage Juveniles of Meloidogyne Species

Head shape and stylet morphology of second-stage juveniles of one population each of M. incognita, M. javanica, M. arenaria, and M. hapla were compared by light microscopy. Excised stylets of each species were also compared by scanning electron microscopy (SEM). Differences in head morphology were observed only between M. hapla and the other three species. In SEM, differences in stylet size, shape, and relative distance of the dorsal esophageal gland orifice to the base of the stylet were evident. Differences in stylet morphology between M. incognita and M. javanica could not he detected by light microscopy, but M. arenaria and M. hapla could be distinguished from each other and from the other two species. Head shape and styler morphology of second-stage juveniles are considered useful taxonomic characters.     

Fine structure of the mouthparts of Diostrombus politus and Proutista moesta (Hemiptera: Derbidae)

Insect mouthparts are important sensory and feeding structures, morphological studies of this organ can provide additional data for phylogenetic studies. The planthopper superfamily Fulgoroidea is among the dominant groups of phytophagous insects, however, the mouthparts ultrastructure of this superfamily remains unsatisfactorily studied. This study investigates the ultrastructure of the mouthparts of two species in the family Derbidae (Hemiptera: Fulgoroidea), Diostrombus politus Uhler and Proutista moesta (Westwood), using a scanning electron microscope. The results show that these two derbids are of a typical piercing-sucking type found in Hemiptera. They consist of a cone-shaped labrum, a three-segmented labium and a stylet fascicle with two interlocked maxillary stylets incompletely wrapped by two mandibular stylets. The arrangement of the sensilla on the labial tip differ slightly between the two derbid species, and the subapical labial sensilla are likely different among genera in the family Derbidae.     

Electrical penetration graphic waveforms in relation to the actual positions of the stylet tips of Nilaparvata lugens in rice tissue

The stylet penetration behavior of Nilaparvata lugens (Hemiptera: Delphacidae) in rice plants (Oryza sativa) was evaluated through the use of an electrical penetration graph (EPG). To accomplish this, we classified the EPG signals into seven different waveforms, np, N1, N2, N3, N4-a, N4-b, and N5, according to their shapes, amplitudes, and frequencies. The N4-b waveform was always preceded by N3 and N4-a, in that order. Continuous honeydew excretion only occurred during the N4-b period, and the honeydew deposited on a filter paper containing ninhydrin reagent during the N4-b period was stained violet. The tips of the stylets that were severed in the N3, N4-a, and N4-b periods were in the phloem region of rice. Moreover, the flow of plant sap after stylectomy only occurred during the N4-b period. Finally, sucrose was the only carbohydrate component identified when HPLC analysis of the plant sap was conducted. On the other hand, honeydew excretion hardly occurred during the N5 period and the tips of the stylets that were severed during the N5 period were located in the xylem region of rice. Based on the location of the stylets and honeydew excretion, the EPG waveforms for the stylet penetration behaviors of N. lugens were assigned to the following groups; np: non-penetration of stylets, N1: penetration initiation, N2: salivation and stylet movement, N3: an extracellular activity near the phloem region, N4-a: an intracellular activity in phloem region, N4-b: phloem sap ingestion, and N5: activity in the xylem region.     

Plant penetration activities by the flatid planthopper Metcalfa pruinosa (Hemiptera: Fulgoroidea): an electrical penetration graph‐histology analysis

The citrus flatid planthopper, Metcalfa pruinosa Say (Hemiptera: Flatidae), is a very polyphagous native insect in North America and currently a serious pest in Europe and South Korea. To understand the feeding behaviour of M. pruinosa, stylet penetration behaviour of M. pruinosa was investigated with an electrical penetration graph (EPG) system. This study reports seven EPG waveforms related to M. pruinosa feeding behaviour: np (no stylet penetration), Mp1 (initiation of stylet penetration), Mp2 (stylet movement and salivation), Mp4 (phloem feeding), Mp4‐H (honeydew excretion), Mp5 (xylem feeding) and Mp6 (unknown). To determine respective feeding behaviour related to the Mp4 and Mp5 waveforms, stylets were cut with a laser beam, and the location of the stylet tip within plant tissue was examined. We found plant sap was exuded from the severed stylets only when the Mp4 waveform was observed, suggesting phloem sap ingestion. The stylet tip was located in the xylem region, indicating xylem‐feeding activity, when the Mp5 waveform was observed. The analysis of 24 different EPG parameters suggests that M. pruinosa stylets reached the vascular bundle of a plant within ca. 5 min and spend ca. 70% of the time feeding on xylem and phloem feeding. This is the first study that reports seven distinctive EPG waveforms with respect to the feeding behaviour of M. pruinosa which could help determine host specificity and host plant susceptibility.