The hemocytes, the blood cells of Drosophila, participate in the humoral and cellular immune defense reactions against microbes and parasites [1-8]. The plasmatocytes, one class of hemocytes, are phagocytically active and play an important role in immunity and development by removing microorganisms as well as apoptotic cells. On the surface of circulating and sessile plasmatocytes, we have now identified a protein, Nimrod C1 (NimC1), which is involved in the phagocytosis of bacteria. Suppression of NimC1 expression in plasmatocytes inhibited the phagocytosis of Staphylococcus aureus. Conversely, overexpression of NimC1 in S2 cells stimulated the phagocytosis of both S. aureus and Escherichia coli. NimC1 is a 90-100 kDa single-pass transmembrane protein with ten characteristic EGF-like repeats (NIM repeats). The nimC1 gene is part of a cluster of ten related nimrod genes at 34E on chromosome 2, and similar clusters of nimrod-like genes are conserved in other insects such as Anopheles and Apis. The Nimrod proteins are related to other putative phagocytosis receptors such as Eater and Draper from D. melanogaster and CED-1 from C. elegans. Together, they form a superfamily that also includes proteins that are encoded in the human genome.
Malignant neoplasms that develop in 12 recessive-lethal, larval mutants of Drosophila melanogaster are discussed. These mutations affect the adult optic neuroblasts and ganglion-mother cells in the larval brain, the imaginal discs, and the hematopoietic organs. The malignant neoplasms exhibit fast, autonomous growth, loss of the capacity for differentiation, increased mobility and invasiveness, lethality in situ and after transplantation, and histological, fine structural, and karyotypic abnormalities. Intermediate neoplasms are also found. These combine both benign and malignant qualities. They grow in a noninvasive, compact fashion, typical of benign tumors, yet they also exhibit malignant qualities such as fast, autonomous, and lethal growth, loss of differentiation capacity, changes in cellular morphology, and lethal growth after transplantation into wild-type hosts. Thus Drosophila and vertebrate neoplasms show striking similarities.
We analyzed the heterogeneity of Drosophila hemocytes on the basis of the expression of cell-type specific antigens. The antigens characterize distinct subsets which partially overlap with those defined by morphological criteria. On the basis of the expression or the lack of expression of blood cell antigens the following hemocyte populations have been defined: crystal cells, plasmatocytes, lamellocytes and precursor cells. The expression of the antigens and thus the different cell types are developmentally regulated. The hemocytes are arranged in four main compartments: the circulating blood cells, the sessile tissue, the lymph glands and the posterior hematopoietic tissue. Each hemocyte compartment has a specific and characteristic composition of the various cell types. The described markers represent the first successful attempt to define hemocyte lineages by immunological markers in Drosophila and help to define morphologically, functionally, spatially and developmentally distinct subsets of hemocytes.
The Drosophila diptericin gene codes for a 9 kDa antibacterial peptide and is rapidly and transiently expressed in larvae and adults after bacterial challenge. It is also induced in a tumorous Drosophila blood cell line by the addition of lipopolysaccharide (LPS). The promoter of this gene contains two 17 bp repeats located closely upstream of the TATA‐box and harbouring a decameric kappa B‐related sequence. This study reports that the replacement of the two 17 bp repeats by random sequences abolishes bacteria inducibility in transgenic fly lines. In transfected tumorous blood cells, the replacement of both or either of the 17 bp motifs reduces dramatically LPS inducibility, whereas multiple copies significantly increase the level of transcriptional activation by LPS challenge. A specific DNA‐protein binding activity is evidenced in cytoplasmic and nuclear extracts of induced blood cells and fat body. It is absent in controls. It is proposed that induction of the diptericin gene mediated by the two 17 bp repeats occurs via a mechanism similar to that of mammalian NF‐kappa B.
The ultrastructure of the primordial blood cells in the first and second hematopoietic lobes of the late second and third instar larva and prepupa of Drosophila melunogaster was compared with the ultrastructure of the blood cells found freely in the larval hemolymph. Within the hematopoietic lobes two principal cell-types were detected : (i) the prohemocytes and proplasmatocytes, and (ii) different developmental stages of crystal cells., Prohemocytes are characterized by a ribsome-rich cytoplasm, showing small amounts of mitochondria, rough ER and Golgi complexes and few primary lyosomes. Prohemocytes differentiate into proplasmatocytes. When released into the hemolymph they transform further into plasmato-, podo-, and lamellocytes. This differentiation pathway is characterized by a gradual, numerical increase of cytoplasmic organelles, the development of the lysosomal system and the aquisition of the capacity for phagocytosis and melanin formation. The differentiation of a procrystal cell into a crystal cell involves a number of intermediate stages, during which the crystalline material is produced, accumulated,and crystallized. Primary and secondary lysosomes in the primordial blood cells of the hematopoietic organs as well as the free blood cells in the hemolymph were identified cytochemically with the help of the acid phosphatase test. The capacity for melanin synthesis was studied with the phenol-and polyphenol oxidase test.Work on the circulatory system of Drosophilu melanoguster has recently been reviewed by RIZKI (1). Its main components are: i. the dorsal vessel with the 'lymph glands' and the pericardial cells and ii. the hemolymph -hemocyte system. The free blood cell-types in the larval hemolymph have been studied and designated by RIZKI and his collaborators (1-5).
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