Topology of the caudal fat body of the tumor-w mutant of Drosophila melanogaster

Hereditary melanotic tumors in the tumor^w strain of Drosophila melanogaster are known to involve encapsulation of the caudal fat body by the larval hemocytes. The encapsulated masses are subsequently melanized. The present study shows that the chain of events preceding encapsulation includes disintegration of the basement membrane of the caudal fat body and the appearance of particulate materials between and around the dissociating fat cells.     

Developmental analysis of a temperature-sensitive melanotic tumor mutant inDrosophila melanogaster

Summary A sex-linked, temperature-sensitive melanotic tumor mutation inDrosophila melanogaster, tu (1) Sz ^ts, was mapped at 34.3±and localized to bands 10A10-11 of the polytene chromosomes. At 26°Ctu-Sz ^ts larvae develop melanotic tumors whereas 18°C is non-permissive for tumor formation. Tumorigenesis at 26°C involves the encapsulation of abnormal caudal fat body regions by precociously differentiated hemocytes. Low temperature blocks the development of the abnormal adipose cells and the overlying aberrant tissue surfaces but does not inhibit precocious differentiation of the hemocytes to the lamellocytic form. This phenotypic difference at the two temperatures indicates that lamellocyte encapsulation to form melanotic tumors is directed against abnormal tissue surfaces. On the basis of these observations and an earlier study (Rizki and Rizki 1979) we propose that hereditary melanotic tumors inD. melanogaster are a calss of autoimmune disorders in which affected tissue surfaces arouse the body's cellmediated defense response.     

Hemocyte responses to implanted tissues inDrosophila melanogaster larvae

Summary At 26° C temperature-sensitivetu(1) Sz ^ts larvae ofDrosophila melanogaster develop melanotic tumors consisting of aberrant caudal adipose tissue encapsulated by precociously differentiated hemocytes (lamellocytes). Whentu-Sz ^ts larvae are grown at 18° C, lamellocytes are present but the caudal fat body surfaces remain normal and melanotic tumors do not develop (Rizki and Rizki, preceding paper). In this paper we demonstrate that the lamellocytes intu-Sz ^ts larvae at 18° C encapsulate implants of mechanically-damaged fat bodies and adipose cells devoid of basement membrane, while leaving host fat bodies or implanted fat bodies with intact basement membrane unencapsulated. Therefore, low temperature blocks melanotic tumor formation by normalizing the surfaces of the prospective tumor-forming sites intu-Sz ^ts.The discriminatory ability oftu-Sz ^ts lamellocytes was examined by challenging them with undamaged heterospecific tissues. Tissues from sibling species ofD. melanogaster were not encapsulated whereas tissues fromDrosophila species outside theD. melanogaster species subgroup were. Ultrastructural examination of encapsulated heterospecific tissues showed intact basement membrane, so we propose that distinction between self and not self by lamellocytes depends upon the molecular architecture of the basement membrane. In similar series of experiments usingD. virilis donor tissues inOre-R wild type larval hosts, fat bodies remained unencapsulated and imaginal disks metamorphosed. These studies suggest that continued presence of lamellocytes in the larval host is a prerequisite for encapsulation.     

Leptopilina heterotoma and L. boulardi: strategies to avoid cellular defense responses of Drosophila melanogaster

Eggs of three strains of the cynipid parasitoid Leptopilina heterotoma and a Tunisian strain (G317) of L. boulardi are not encapsulated by hemocytes of Drosophila melanogaster hosts, but the eggs of a Congolese strain (L104) of L. boulardi are encapsulated. To determine the reason for the difference in host response against the parasitoid eggs, lamellocytes (hemocytes that encapsulate foreign objects and form capsules around endogenous tissues in melanotic tumor mutants) were examined in host larvae parasitized by the five Leptopilina strains. Parasitization by the three L. heterotoma strains affected the morphology of host lamellocytes and suppressed endogenous melanotic capsule formation in melanotic tumor hosts. L104 did not alter the morphology of host lamellocytes nor block tumor formation in melanotic tumor mutant hosts. The morphology of some lamellocytes was affected by G317 parasitization but host lamellocytes were still capable of forming melanotic tumors and encapsulating dead supernumerary parasitoid larvae. Therefore, the eggs of strains affecting lamellocyte morphology are protected from encapsulation by the host's blood cells. L. heterotoma eggs float freely in the host hemocoel but L. boulardi eggs are attached to host tissue surfaces. Lamellocytes cannot infiltrate the attachment site so the capsule around the L104 egg remains incomplete. The wasp larva uses this gap in the capsule as an escape hatch for emergence.     

Pathology caused by a viral toxin in the parasitoid Apanteles militaris

The toxin extracted from the hemolymph of larvae of the armyworm, Pseudaletia uniquncta, infected with the synergistic strain of a granulosis virus, adversely affects the embryonic and larval stages of the parasitoid Apanteles militaris. The initial effect of the toxin is the cessation of parasitoid growth. On the second day, the tissues begin to recede from the cuticle, but the parasitoid usually survives for several days even after 50% or more of its tissues have receded. Eventually it dies. In a dead larva, the basement membrane, which has separated from the lysed epidermal cells, encloses the remnant of the parasitoid. In the necrocytosis of the affected parasitoid, the tissues become atrophied, the organs lose their organization and cellular integrity, and the caudal vesicle, in many instances, becomes separated from the hindgut.     

Histopathology of the European chafer,Amphimallon majalis,infected with Bacillus popilliae

Third-instar larvae of the European chafer were challenged orally or by injection with spore suspensions of Bacillus popilliae. The pathogenesis was investigated by histological examination of larvae sacrificed at various exposure times. Spores germinated in the center of hemocytic capsules when injected and probably in the lumen of the anterior intestine when ingested. Following preliminary multiplication inside the basement membrane of the midgut, vegetative cells penetrated and continued to multiply in the hemolymph. Whether larvae were infected by ingestion or injection, the bacilli concentrated in connective tissue sheaths or in close association with hemocytes for sporulation.     

Melanotic mutants in Drosophila: pathways and phenotypes

Mutations in >30 genes that regulate different pathways and developmental processes are reported to cause a melanotic phenotype in larvae. The observed melanotic masses were generally linked to the hemocyte-mediated immune response. To investigate whether all black masses are associated with the cellular immune response, we characterized melanotic masses from mutants in 14 genes. We found that the melanotic masses can be subdivided into melanotic nodules engaging the hemocyte-mediated encapsulation and into melanizations that are not encapsulated by hemocytes. With rare exception, the encapsulation is carried out by lamellocytes. Encapsulated nodules are found in the hemocoel or in association with the lymph gland, while melanizations are located in the gut, salivary gland, and tracheae. In cactus mutants we found an additional kind of melanized mass containing various tissues. The development of these tissue agglomerates is dependent on the function of the dorsal gene. Our results show that the phenotype of each mutant not only reflects its connection to a particular genetic pathway but also points to the tissue-specific role of the individual gene.     

Pathology of Spiroplasma floricola in Galleria mellonella larvae

Spiroplasma floricola strain 23-6, originally isolated from tulip tree flowers, was injected into larvae of the greater wax moth. Histopathology and cytopathology of disease larvae were studied by histochemical, fluorescent antibody, and electron microscopical methods. The gut was empty, polysaccharides in fat and muscle tissue were reduced, the fat body was broken down, and phospholipids were depleted in larvae 4 days after injection. Fluorescein conjugated S. floricola antibody was adsorbed onto hemocytes, sarcolemma, gut epithelial membrane, and the cortex of the ventral ganglia. By electron microscopy, spiroplasmas were found in hemocoel, hemocytes, pericardial cells, connective tissues, basement membranes, epidermal cells of the cuticle, the neural lamella, and the peripheral glial cells of the ventral nerve cord, and on midgut and epidermal membranes. It is postulated that the cytopathological effects induced in the body of the insect released nutritional elements that allow extensive reproduction of S. floricola.     

Basement Membrane and Cell Integrity of Self-Tissues in Maintaining Drosophila Immunological Tolerance

The mechanism underlying immune system recognition of different types of pathogens has been extensively studied over the past few decades; however, the mechanism by which healthy self-tissue evades an attack by its own immune system is less well-understood. Here, we established an autoimmune model of melanotic mass formation in Drosophila by genetically disrupting the basement membrane. We found that the basement membrane endows otherwise susceptible target tissues with self-tolerance that prevents autoimmunity, and further demonstrated that laminin is a key component for both structural maintenance and the self-tolerance checkpoint function of the basement membrane. Moreover, we found that cell integrity, as determined by cell-cell interaction and apicobasal polarity, functions as a second discrete checkpoint. Target tissues became vulnerable to blood cell encapsulation and subsequent melanization only after loss of both the basement membrane and cell integrity.     

Cell interactions in the differentiation of a melanotic tumor in Drosophila.

The cellular events in the formation of melanotic tumors in the tu-W mutant larva of Drosophila melanogaster are described. The first step is the differentiation of spherical hemocytes to flattened cells, the lamellocyte variants. Subsequently, the surface of the caudal fat body undergoes changes to which the hemocytes respond by forming cellular capsules. The hemocytes utilize two mechanisms in this process: (1) phagocytosis of small particulate materials escaping from the adipose cells, (2) adhesion to form a multilayered wall of lamellocytes. Differentiating hemocytes in the vicinity of the tumor-forming site extrude membrane-bound vesicles that tend to adhere to the hemocyte surfaces. These vesicles are trapped between the lamellocytes as they pile in layers to form the capsule wall. It is suggested that the vesicles play a role in lamellocyte-to-lamellocyte adhesion during the initial stages of hemocyte aggregation at the tumor-forming site.     

Apoptosis in Hemocytes Induces a Shift in Effector Mechanisms in the Drosophila Immune System and Leads to a Pro-Inflammatory State

Apart from their role in cellular immunity via phagocytosis and encapsulation, Drosophila hemocytes release soluble factors such as antimicrobial peptides, and cytokines to induce humoral responses. In addition, they participate in coagulation and wounding, and in development. To assess their role during infection with entomopathogenic nematodes, we depleted plasmatocytes and crystal cells, the two classes of hemocytes present in naïve larvae by expressing proapoptotic proteins in order to produce hemocyte-free (Hml-apo, originally called Hemo^less) larvae. Surprisingly, we found that Hml-apo larvae are still resistant to nematode infections. When further elucidating the immune status of Hml-apo larvae, we observe a shift in immune effector pathways including massive lamellocyte differentiation and induction of Toll- as well as repression of imd signaling. This leads to a pro-inflammatory state, characterized by the appearance of melanotic nodules in the hemolymph and to strong developmental defects including pupal lethality and leg defects in escapers. Further analysis suggests that most of the phenotypes we observe in Hml-apo larvae are alleviated by administration of antibiotics and by changing the food source indicating that they are mediated through the microbiota. Biochemical evidence identifies nitric oxide as a key phylogenetically conserved regulator in this process. Finally we show that the nitric oxide donor L-arginine similarly modifies the response against an early stage of tumor development in fly larvae.     

Cell Interactions in the Differentiation of a Melanotic Tumor in Drosophila

The cellular events in the formation of melanotic tumors in the tu-W mutant larva of Drosophila melanogaster are described. The first step is the differentiation of spherical hemocytes to flattened cells, the lamellocyte variants. Subsequently, the surface of the caudal fat body undergoes changes to which the hemocytes respond by forming cellular capsules. The hemocytes utilize two mechanisms in this process: (1) phagocytosis of small participate materials escaping from the adipose cells, (2) adhesion to form a multilayered wall of lamellocytes.
Differentiating hemocytes in the vicinity of the tumor-forming site extrude membrane-bound vesicles that tend to adhere to the hemocyte surfaces. These vesicles are trapped between the lamellocytes as they pile in layers to form the capsule wall. It is suggested that the vesicles play a role in lamellocyte-to-lamellocyte adhesion during the initial stages of hemocyte aggregation at the tumorforming site.     

Cellular immune response of brown soft scale Coccus hesperidum L. (Hemiptera: Coccidae) to eggs of Metaphycus luteolus Timberlake (Hymenoptera: Encyrtidae)

The parasitic wasp, Metaphycus luteolus Timberlake, is an endoparasitoid of various soft scale insects including brown soft scale, Coccus hesperidum L. Development of this parasitoid in scale hosts is hindered by encapsulation. In the present study, using transmission and scanning electron microscopy, we show that hemocytes are responsible for encapsulation, which is mediated by the direct deposition of cells and melanin on the surface of M. luteolus eggs. By 12 h post-oviposition, scale hemocytes, presumably granulocytes, aggregate, spread and directly lyse on the surface of parasitoid eggs. This process continues for at least 1 day and results in the gradual formation of a capsule. Two to three days post-oviposition, a melanized capsule is well formed and signs of chemical deposition are evident by examination of the outer surface of the capsule. These results demonstrate that soft scale insects are fully capable of melanotic encapsulation of foreign material mediated by hemocytes.     

Drosophila Immunity: Analysis of Larval Hemocytes by P-Element-Mediated Enhancer Trap

Our aim was to identify new genes involved in the cellular aspects of defense mechanisms of Drosophila, as well as in melanotic tumor formation processes that are linked to blood cell disregulation. We have screened 1341 enhancer detector fly lines for expression of the lacZ reporter gene in larval hemocytes at the end of the third instar. We have selected 21 lines in which we observed a reproducible lacZ expression in blood cells. These lines were classified according to the subsets of hemocytes in which lacZ was expressed, and we identified five lines that can be used as lamellocyte markers. Three lines were selected for further analysis. The first exhibited strong lacZ expression in all lamellocytes. The second expressed lacZ in plasmatocytes and lamellocytes, and exhibited a melanotic tumor phenotype in larvae homozygous for the insertion. A third line showed a striking insertion-linked phenotype of melanized lymph glands (the hematopoietic organ), which resulted in the total absence of circulating hemocytes in the mutant larvae. We anticipate that this mutation, which we named domino, will prove a useful tool in the analysis of the role of hemocytes during the various aspects of immune response and melanotic tumor formation.     

Prophenoloxidase binds to the surface of hemocytes and is involved in hemocyte melanization in Manduca sexta

In insects, melanotic encapsulation is an important innate immune response against large pathogens or parasites, and phenoloxidase (PO) is a key enzyme in this process. Activation of prophenoloxidase (proPO) to PO is mediated by a serine proteinase cascade. PO has a tendency to adhere to foreign surfaces including hemocyte surfaces. In this study, we showed that in the naïve larvae of the tobacco hornworm Manduca sexta, hemolymph proPO bound to the surface of granulocytes and spherule cells but not to oenocytoids, and about 10% hemocytes had proPO on their surfaces. When larvae were injected with water (injury) or microsphere beads (immune-challenge), hemolymph proPO was activated, and the number of hemocytes with surface proPO/PO increased at 12 h post-injection, but dropped to the normal level at 24 h. Hemocyte surface proPO can be activated in vitro, leading to melanization of these hemocytes. The number of melanized hemocytes from the larvae injected with water or microsphere beads significantly increased. We also showed that neither hemocytes nor cell-free plasma alone triggered melanization of immulectin-2-coated agarose beads in vitro. However, agarose beads were effectively melanized by isolated hemocytes in the presence of cell-free plasma. Our results suggest that activation of hemocyte surface proPO may initiate melanization, leading to the systemic melanization of hemocyte capsules.     

Edin Expression in the Fat Body Is Required in the Defense Against Parasitic Wasps in Drosophila melanogaster

The cellular immune response against parasitoid wasps in Drosophila involves the activation, mobilization, proliferation and differentiation of different blood cell types. Here, we have assessed the role of Edin (elevated during infection) in the immune response against the parasitoid wasp Leptopilina boulardi in Drosophila melanogaster larvae. The expression of edin was induced within hours after a wasp infection in larval fat bodies. Using tissue-specific RNAi, we show that Edin is an important determinant of the encapsulation response. Although edin expression in the fat body was required for the larvae to mount a normal encapsulation response, it was dispensable in hemocytes. Edin expression in the fat body was not required for lamellocyte differentiation, but it was needed for the increase in plasmatocyte numbers and for the release of sessile hemocytes into the hemolymph. We conclude that edin expression in the fat body affects the outcome of a wasp infection by regulating the increase of plasmatocyte numbers and the mobilization of sessile hemocytes in Drosophila larvae.     

Factors affecting the ability of the wasp parasite Pseudeucoila bochei to inhibit tumourigenesis in Drosophila melanogaster.

The cellular immune reaction of Drosophila melanogaster larvae which results in encapsulation of internal metazoan parasites is similar to the autoimmune reaction made by certain tumourmutant stocks against abnormally developing host tissues. The wasp parasite Pseudeucoila bochei is capable of actively inhibiting the haemocytic encapsulation reaction of host larvae, and this activity can also inhibit the haemocytic response made by the bw tu mutant flies against abnormal fat body tissue. The ability of the parasite to suppress tumourigenesis is dependent on the age of the host at the time of infection, and on the amount of previous oviposition of the parasite. The earlier during host development parasitisation occurs the more tumour formation is inhibited. partially spent females are less able to inhibit tumours than are newly emerged parasites and unspent parasites of the same age. In some parasitised individuals the tumour response is incomplete and consists of small pigment particles instead of the large melanotic growths characteristic of the strain. The autoimmune response made against “alien” host tissues is specific and does not interfere with the successful development of the parasite.     

Quantification of cytotoxic hemocytes of Mytilus edulis using a cytotoxicity assay in agar

When a thin layer of agar containing a mixture of erythrocytes and Mytilus hemocytes is prepared on slides, the occurrence of plaques of lysed target cells can be observed around a limited number of hemocytes. These hemocytes remain completely intact cells and are viable as evidenced by their ability to phagocytose target cells and/or to form pseudopods. The number of hemocytes releasing cytotoxic molecules has been shown to vary greatly between different animals. The same holds true for the total number of circulating hemocytes, although no correlation exists between the number of hemocytes in the circulation and the percentage of cytotoxic blood cells.