Interfaces between microbes and membranes of host epithelial cells in hemipteran midguts.

Certain families of plant-feeding insects in the order Hemiptera (infraorder Pentatomomorpha) have established symbiotic relationships with microbes that inhabit specific pouches (caeca) of their midgut epithelium. The placement of these caeca in a well-delineated region at the most posterior end of the midgut bordering the hindgut is conserved in these families; in situ the convoluted midgut is predictably folded so that this caecal region lies adjacent to the anterior-most region of the midgut. Depending on the hemipteran family, caeca vary in their number and configuration at a given anterior-posterior location. At the host-microbe interface, epithelial plasma membranes of midgut epithelial cells interact with nonself antigens of microbial surfaces. In the different hemipteran species examined, a continuum of interactions is observed between microbes and host membranes. Bacteria can exist as free living cells within the midgut lumen without contacting host membranes while other host cells physically interact extensively with microbial surfaces by extending numerous processes that interdigitate with microbes; and, in many instances, processes completely envelope the microbes. The host cells can embrace the foreign microbes, completely enveloping each with a single host membrane or sometimes enveloping each with the two additional host membranes of a phagosome.

Luminal membranes in the midgut of the lace bug Corythucha ciliata.

The inordinately long midgut of hemipterans is devoid of peritrophic membranes described for many other insects. These membranes separate apical microvilli of midgut cells from contents of the lumen. In hemipterans, by contrast, contents of the lumen are separated from apical surfaces of midgut epithelia by secretion of additional plasma membranes (perimicrovillar membranes) containing digestive enzymes. In the lace bug Corythucha ciliata, precursors for these perimicrovillar membranes arise in smooth endoplasmic reticula (SER) as stacked, coiled membranes and are continually expelled into the lumen along the entire length of the midgut as stacked, tubular membranes; these membranes undergo changes in form as they pass from the SER to the midgut lumen. Rather than adopting the double membrane configuration in the gut lumen that was first described for hemipteran perimicrovillar membranes, these modified perimicrovillar membranes of the Corythucha gut line apical surfaces of midgut apical lamellae and intermix with the contents of the lumen; foregut and hindgut epithelial cells are devoid of vesicles containing coiled membranes observed abundantly in midgut epithelia. Rather than achieving renewal of adult midgut epithelial cells through the divisions of regenerative cells as observed in many adult insects, prolific generation of perimicrovillar membranes apparently maintains the integrity of this lengthy hemipteran midgut epithelium.

Remodeling of the abdominal epithelial monolayer during the larva-pupa-adult transformation of Manduca.

During metamorphosis of insect epithelial monolayers, cells die, divide, and rearrange. In Drosophila undifferentiated diploid cells destined to form the adult cuticle of each abdominal segment segregate early in development from the surrounding polyploid larval epithelial cells of that segment as eight groups of diploid histoblast cells. The larval polyploid cells are programmed to die and be replaced by divisions and rearrangements of histoblast cells. By contrast, abdominal epithelial cells of Manduca larvae form a monolayer of cells representing different ploidy levels with no definitive segregation of diploid cells destined to form adult structures. These epithelial cells of mixed ploidy levels produce a thick smooth larval cuticle with sparsely distributed sensory bristles. Adult descendants of this larval monolayer produce a thinner cuticle with densely packed scale cells. The transition between these differentiated states of Manduca involves divisions of cells, changes in ploidy levels, and sorting of certain polyploid cells into circular rosette patches to minimize contacts of these polyploid cells with surrounding cells of equal or smaller size. Cells within the rosettes and some surrounding cells are destined to die and be replaced by remaining epithelial cells of uniform size and ploidy at pupa-adult apolysis.

A novel arrangement of midgut epithelium and hepatic cells implies a novel regulation of the insulin signaling pathway in long-lived millipedes.

Nutrients absorbed by the epithelial cells of the millipede midgut are channeled to a contiguous population of hepatic cells where sugars are stored as glycogen. In insects and other arthropods, however, nutrients absorbed by midgut epithelia are first passed across the epithelial basal surface to the hemolymph before storage in fat body. The inter-digitation of cellular processes at the interface of hepatic and midgut epithelial cells offers a vast surface area for exchange of nutrients. At this interface, numerous small vesicles with the dimensions of exosomes (∼30nm) may represent the mediators of nutrient exchange. Longevity and the developmental arrest of diapause are associated with reduced insulin signaling. The long lifespans for which millipedes are known may be attributable to a novel pathway with reduced insulin signaling represented by the novel arrangement of hepatic storage cells and midgut epithelial absorbing cells.

Segmental pairs of giant insect cells discharge presumptive immune proteins at each larval molt.

A pair of massive secretory cells exists within each thoracic and the nine abdominal segments of Manduca larvae. Each of these cells is nestled between the dorsal integument and underlying muscles. Contents of large vacuoles in these cells are abruptly discharged at each molt and have always been considered to contribute to shedding and/or formation of cuticle. Peanut agglutinin is a specific lectin label for these secretory vacuoles; vacuoles label intensely immediately before each molt as vacuoles attain their maximal size. Contents of vacuoles are restored after each molt and throughout most of each intermolt. During the molt cycle these cells secrete contents of their vacuoles into the interior hemocoel rather than onto the exterior cuticle. Vacuoles discharge via a distinctive mechanism involving partitioning of contents into numerous vesicles that move to the cell surface. Dermal secretory cells were dissected from larvae before and after the 4th-5th instar molt. Proteins from pre-molt and post-molt secretory cells were separated by two-dimensional electrophoresis to establish which proteins are discharged at the molt. While secreted proteins are novel, all have presumptive roles in immune responses. Dermal secretory cells may represent a new, unsuspected component of the innate immune system that release their proteins during the vulnerable molting period of an insect's life.

Regenerative cells and the architecture of beetle midgut epithelia.

The architectural ground plan of beetle and other insect midguts is represented by a monolayer of epithelial cells arranged in a cylindrical configuration. Proliferation and differentiation of regenerative cells maintain the integrity of this monolayer in the face of continual losses of individual cells through cytoplasmic budding and/or expulsion of entire epithelial cells. Peritrophic membranes have conventionally been considered universal features of insect midguts that function to protect vulnerable microvillar surfaces of the midgut epithelium from abrasion by ingested food; however, peritrophic membranes were found in only a small fraction of the adult beetle species examined in this study. In adult beetles, midgut epithelial cells are continually replaced by cells recruited from populations of mitotic regenerative cells that are interspersed among the differentiated epithelial monolayer. To remain contiguous with the other cells in the midgut monolayer, some of these proliferating populations have adopted evaginated configurations of cells that extend for varying distances from the basal surface of the monolayer. These configurations are referred to as regenerative crypts or pouches and consist of progenitor cells and stem cells. The presence, the relative densities, and the relative lengths of these regenerative pouches vary considerably among families of beetles. Placement of longitudinal muscles of the midgut relative to the proximodistal axes of these regenerative pouches also varies among species of beetles. The presence, the size, and the density of regenerative cell populations are related to 1) feeding habits of adult beetles, 2) presence of peritrophic membranes, and 3) expulsion of entire midgut epithelial cells or fragments of these epithelial cells into midgut lumens.

Cell renewal in adjoining intestinal and tracheal epithelia of Manduca.

Cell renewal continuously replaces dead or dying cells in organs such as human and insect intestinal (midgut) epithelia; in insects, control of self-renewal determines insects' responses to any of the myriad pathogens and parasites of medical and agricultural importance that enter and cross their midgut epithelia. Regenerative cells occur in the midgut epithelia of many, if not all, insects and are probably derived from a distinctive population of stem cells. The control of proliferation and differentiation of these midgut regenerative cells is assumed to be regulated by an environment of adjacent cells that is referred to as a regenerative cell niche. An antibody to fasciclin II marks cell surfaces of tracheal regenerative cells associated with rapidly growing midgut epithelia. Tracheal regenerative cells and their neighboring midgut regenerative cells proliferate and differentiate in concert during the coordinated growth of the midgut and its associated muscles, nerves and tracheal cells.

Stem cells of the beetle midgut epithelium.

At the completion of metamorphosis, adult insect cells have traditionally been assumed to halt cell divisions and terminally differentiate. While this model of differentiation holds for adult ectodermal epithelia that secrete cuticular specializations of exoskeletons, adult endodermal epithelia are populated by discrete three-dimensional aggregates of stem cells that continue to divide and differentiate after adult emergence. Aggregates of these presumptive adult stem cells are scattered throughout larval and pupal midgut monolayers. At the beginning of adult development (pupal-adult apolysis), the number of cells within each aggregate begins to increase rapidly. Dividing cells form three-dimensional, coherent populations that project as regenerative pouches of stem cells into the hemocoel surrounding the midgut. Stem cell pouches are regularly spaced throughout endodermal monolayers, having adopted a spacing pattern suggesting that each incipient pouch inhibits the formation of a similar pouch within a certain radius of itself-a process referred to as lateral inhibition. At completion of adult development (pupal-adult ecdysis), a distinct basal-luminal polarity has been established within each regenerative pouch. Dividing stem cells occupying the basal region are arranged in three-dimensional aggregates. As these are displaced toward the lumen, they transform into two-dimensional monolayers of differentiated epithelial cells whose apical surfaces are covered by microvilli. This organization of stem cell pouches in insect midguts closely parallels that of regenerative crypts in mammalian intestines.

Multiple alpha subunits of integrin are involved in cell-mediated responses of the Manduca immune system.

The cell-mediated responses of the insect innate immune system-phagocytosis, nodulation, encapsulation-involve multiple cell adhesion molecules of hemocyte surfaces. A hemocyte-specific (HS) integrin and a member of the immunoglobulin (Ig) superfamily (neuroglian) are involved in the encapsulation response of hemocytes in Manduca sexta. In addition, two new integrin alpha (alpha) subunits have been found on these hemocytes. The alpha2 subunit is mainly expressed in epidermis and Malphigian tubules, whereas the alpha3 subunit is primarily expressed on hemocytes and fat body cells. Of the three known alpha subunits, the alpha1 subunit found in HS integrin is the predominant subunit of hemocytes. Cell adhesion assays indicate that alpha2 belongs to the integrin family with RGD-binding motifs, confirming the phylogenetic analysis of alpha subunits based on the amino-acid sequence alignment of different alpha subunits. Double-stranded RNAs (dsRNAs) targeting each of these three integrin alpha subunits not only specifically decreased transcript expression of each alpha subunit in hemocytes, but also abolished the cell-mediated encapsulation response of hemocytes to foreign surfaces. The individual alpha subunits of M. sexta integrins, like their integrin counterparts in mammalian immune systems, have critical, individual roles in cell-substrate and cell-cell interactions during immune responses.

An integrin-tetraspanin interaction required for cellular innate immune responses of an insect, Manduca sexta.

In their encounters with foreign intruders, the cells of the insect innate immune system, like those of the mammalian immune system, exhibit both humoral and cell-mediated responses. Some intruders can be dispatched by the humoral immune system alone, but many must be phagocytosed by individual hemocytes or encapsulated by interacting hemocytes. Surface proteins of hemocytes control the abrupt transition of hemocytes from resting, nonadherent cells to activated, adherent cells during these cell-mediated responses. Two of these surface proteins, an integrin and a tetraspanin, interact during this adhesive transition. As demonstrated with a hemocyte adhesion assay and a surface plasmon resonance assay, the large extracellular loop of tetraspanin D76 binds to a hemocyte-specific integrin of Manduca sexta. The interaction between the large extracellular loop domain and hemocyte-specific integrin is interrupted not only by a monoclonal antibody (MS13) that binds to a domain of beta-integrin known to be a ligand-binding site for cell adhesion but also by double-stranded beta-integrin RNA. Transfected S2 cells expressing tetraspanin mediate adhesion of hemocytes. A monoclonal antibody to tetraspanin D76 perturbs the cell-mediated immune response of encapsulation. These studies involving antibody blocking, RNA interference, and binding assays imply a trans interaction of integrin and tetraspanin on hemocyte surfaces.

Neuroglian on hemocyte surfaces is involved in homophilic and heterophilic interactions of the innate immune system of Manduca sexta.

Neuroglian, a member of the L1 family of cell adhesion molecules (L1-CAMs), is expressed on surfaces of granular cells and a subset of large plasmatocytes of Manduca sexta that act as foci for hemocyte aggregation during the innate immune response. Neuroglian expressed on surfaces of transfected Sf9 cells induced their homophilic aggregation, with the aggregation being abolished in the presence of recombinant immunoglobulin (Ig) domains of neuroglian. Neuroglian and its Ig domains also can interact with hemocyte-specific integrin (HS integrin) as demonstrated with an enzyme-linked immunoassay and a surface plasmon resonance (SPR) assay. Neuroglian double-stranded (ds) RNA not only depresses expression of neuroglian in hemocytes but also depresses the cell-mediated encapsulation response of these hemocytes to foreign surfaces. After injection of a monoclonal antibody (MAb 3B11) into M. sexta larvae that recognizes the Ig domains of neuroglian, the cell-mediated encapsulation response of hemocytes was likewise inhibited. The Ig domains of neuroglian are involved in both homophilic and heterophilic interactions, and subsets of these six different Ig domains may affect different functions of neuroglian.

Neuroglian-positive plasmatocytes of Manduca sexta and the initiation of hemocyte attachment to foreign surfaces.

Observations of hemocyte aggregation on abiotic surfaces suggested that certain plasmatocytes from larvae of Manduca sexta act as foci for hemocyte aggregation. To establish how these particular plasmatocytes form initial attachments to foreign surfaces, they were cultured separately from other selected populations of hemocytes. While all circulating plasmatocytes immunolabel with anti-beta-integrin monoclonal antibody (MAb), only these larger plasmatocytes immunolabel with a MAb to the adhesion protein neuroglian. Neuroglian-negative plasmatocytes and granular cells that have been magnetically segregated from the majority of granular cells adhere to each other but fail to adhere to foreign substrata; by contrast, neuroglian-positive plasmatocytes that segregate with most granular cells adhere firmly to a substratum. Hemocytes form stable aggregates around the large, neuroglian-positive plasmatocytes. However, if neuroglian-positive plasmatocytes are separated from most granular cells, attachment of these plasmatocytes to foreign surfaces is suppressed.

Clustering of adhesion receptors following exposure of insect blood cells to foreign surfaces.

Cell-mediated immune responses of insects involve interactions of two main classes of blood cells (hemocytes) known as granular cells and plasmatocytes. In response to a foreign surface, these hemocytes suddenly transform from circulating, non-adherent cells to cells that interact and adhere to each other and the foreign surface. This report presents evidence that during this adhesive transformation the extracellular matrix (ECM) proteins lacunin and a ligand for peanut agglutinin (PNA) lectin are released by granular cells and bind to surfaces of both granular cells and plasmatocytes. ECM protein co-localizes on cell surfaces with the adhesive receptors integrin and neuroglian, a member of the immunoglobulin superfamily. The ECM protein(s) secreted by granular cells are hypothesized to interact with adhesion receptors such as neuroglian and integrin by cross linking and clustering them on hemocyte surfaces. This clustering of receptors is known to enhance the adhesiveness (avidity) of interacting mammalian immune cells. The formation of ring-shaped clusters of these adhesion receptors on surfaces of insect immune cells represents an evolutionary antecedent of the mammalian immunological synapse.

A hemocyte-specific integrin required for hemocytic encapsulation in the tobacco hornworm, Manduca sexta.

Upon encountering an object recognized as foreign, insect hemocytes aggregate in multiple layers on the surfaces of the object in a process known as encapsulation. For encapsulation to occur, hemocytes must switch from their usual nonadherent state to an adherent state, presumably by regulating the activity of adhesion proteins. Although detailed knowledge exists regarding the adhesion receptors for cells of the mammalian immune system, comparable information on adhesion molecules of insect hemocytes and their function in immune responses is extremely limited. We report here the identification of an integrin present exclusively on the surface of hemocytes in the tobacco hornworm, Manduca sexta. Monoclonal antibodies MS13 and MS34, which bind to plasmatocytes and block encapsulation, were used for immunoaffinity chromatography to isolate their corresponding hemocyte antigen, which was revealed to be the same integrin beta subunit. A cDNA for this M. sexta integrin beta1 was cloned and characterized. Integrin-beta1 mRNA was detected by Northern analysis in hemocytes and not in other tissues tested. MS13 and MS34 were demonstrated to bind to a recombinant fragment of integrin beta1 consisting of the I-like domain, consistent with their blocking of a ligand-binding site and subsequent disruption of plasmatocyte adhesion. Injection of double stranded integrin-beta1 RNA into larvae resulted in decreased integrin beta1 expression in plasmatocytes and significantly suppressed encapsulation. These results indicate that activation of ligand-binding by the hemocyte-specific integrin plays a key role in stimulating plasmatocyte adhesion leading to encapsulation.

Embryonic origins of the two main classes of hemocytes--granular cells and plasmatocytes--in Manduca sexta.

Cell-mediated responses of the moth immune system involve the interaction of two main classes of hemocytes-granular cells and plasmatocytes. During embryogenesis, granular cells arise much earlier than plasmatocytes, and the presence of granular cells is closely coupled with the formation of basal laminae that line the hemocoel occupied by hemocytes. Although epithelial cells contribute the large extracellular matrix protein lacunin to embryonic matrices before granular cells begin contributing this protein to basal laminae, the spatial pattern of lacunin expression in early embryos parallels the later distribution of granular cells over surfaces of basal laminae. Plasmatocytes arise late in embryogenesis, after the cessation of the major morphogenetic movements and the establishment of intact basal laminae. Granular cells are intimately involved with remodeling of basal laminae, and disruptions in the structure of basal laminae can trigger an autoimmune response of granular cells and plasmatocytes. By arising after basal laminae have been molded and remodeled by granular cells, plasmatocytes presumably do not encounter the cues that trigger their aggregation and an autoimmune response.

Hematopoietic organs of Manduca sexta and hemocyte lineages.

Cells of the moth immune system are derived from organs that loosely envelop the four wing imaginal discs. The immune response in these insects is believed to depend on the activities of two main classes of hemocytes: plasmatocytes and granular cells. The fates of cells that arise from these hematopoietic organs have been followed by immunolabeling with plasmatocyte-specific and granular-cell-specific antibodies. Cells within each hematopoietic organ differ in their coherence and in their expression of two plasmatocyte-specific surface proteins, integrin and neuroglian. Within an organ there is no overlap in the expression of these two surface proteins; neuroglian is found on the surfaces of the coherent cells while integrin is expressed on cells that are losing coherence, rounding up, and dispersing. A granular-cell-specific marker for the protein lacunin labels the basal lamina that delimits each organ but only a small number of granular cells that lie on or near the periphery of the hematopoietic organ. When organs are cultured in the absence of hemolymph, all cells derived from hematopoietic organs turn out to immunolabel with the plasmatocyte-specific antibody MS13. The circulating plasmatocytes derived from hematopoietic organs have higher ploidy levels than the granular cells and represent a separate lineage of hemocytes.

Expression patterns of odorant-binding proteins in antennae of the moth Manduca sexta.

Monoclonal antibodies (MAbs) were generated to six recombinant proteins (odorant-binding proteins; OBPs) of Manduca sexta. The specificity of each MAb was demonstrated by labeling six immunoblots, each of which contained samples of all six recombinant OBPs. The expression patterns of the six OBPs could be grouped into three classes: (1) one (GOBP1) was expressed in sensilla located throughout each annulus; (2) two (ABPX and ABP2) were expressed in the long sensilla trichoidea bordering a zone that was arranged as an arch on the periphery of each annulus; (3) three (PBP2, PBP3, and GOBP2) were expressed in shorter sensilla occupying a wedge-shaped mid-annular zone of each annulus. In female antennae, sensilla expressing these OBPs were intermixed, and the distinct zonation observed in the male antenna was absent. In males, PBP2 was co-expressed in exactly the same cells of the mid-annular zone as those expressing PBP3 and most of the same cells expressing GOBP2, although its expression overlapped with no or only a few sensilla expressing OBPs of class 1 (GOBP1) or class 2 (ABPX, ABP2). This overlap of expression or lack of overlap between PBP2 and the other OBPs for male antennae was mirrored in female antennae. In view of the restricted spatial expression of OBPs within an annulus and the diversity of possible dimeric combinations of OBPs that arises from the co-expression of multiple OBPs in a given sensillum, OBPs could contribute to the specificity of the olfactory responses of insects.