Modulation of integrin activity is vital for morphogenesis.

Cells can vary their adhesive properties by modulating the affinity of integrin receptors. The activation and inactivation of integrins by inside-out mechanisms acting on the cytoplasmic domains of the integrin subunits has been demonstrated in platelets, lymphocytes, and keratinocytes. We show that in the embryo, normal morphogenesis requires the alpha subunit cytoplasmic domain to control integrin adhesion at the right times and places. PS2 integrin (alphaPS2betaPS) adhesion is normally restricted to the muscle termini, where it is required for attaching the muscles to the ends of other muscles and to specialized epidermal cells. Replacing the wild-type alphaPS2 with mutant forms containing cytoplasmic domain deletions results in the rescue of the majority of defects associated with the absence of the alphaPS2 subunit, however, the mutant PS2 integrins are excessively active. Muscles containing these mutant integrins make extra muscle attachments at aberrant positions on the muscle surface, disrupting the muscle pattern and causing embryonic lethality. A gain- of-function phenotype is not observed in the visceral mesoderm, showing that regulation of integrin activity is tissue-specific. These results suggest that the alphaPS2 subunit cytoplasmic domain is required for inside-out regulation of integrin affinity, as has been seen with the integrin alphaIIbbeta3.

Cellularization in locust embryos occurs before blastoderm formation.

In Drosophila intracellular gradients establish the pattern of segmentation by controlling gene expression during a critical syncytial stage, prior to cellularization. To investigate whether a similar mechanism may be exploited by other insects, we examined the timing of cellularization with respect to blastoderm formation in an insect with extreme short-germ development, the African desert locust, Schistocerca gregaria. Using light and electron microscopic techniques, we show that the islands of cytoplasm surrounding cleavage nuclei are largely isolated from their neighbours, allowing cleavage to proceed asynchronously. Within a short time of their arrival at the surface and prior to blastoderm formation, nuclei become surrounded by complete cell membranes that block the free uptake of dye (10,000 kDa) from the yolk. Our results imply that the formation of the blastoderm disc involves the aggregation of cells at the posterior pole of the egg and not the migration of nuclei within a syncytial cytoplasm. These findings suggest that the primary cleavage syncytium does not play the same role in patterning the locust embryo as it does in Drosophila. However, we do identify a syncytial nuclear layer that underlies the forming blastoderm and remains in continuity with the yolk.

Specificity of PS integrin function during embryogenesis resides in the alpha subunit extracellular domain.

We tested the ability of different integrin alpha subunits to substitute for each other during embryonic development. Two alpha subunits, which form heterodimers with the same betaPS subunit, are expressed in complementary tissues in the Drosophila embryo, with alphaPS1 expressed in the epidermis and endoderm, and alphaPS2 expressed in the mesoderm. As a result the two integrin heterodimers are present on opposite surfaces at sites of interaction between the mesoderm and the other cell layers where they are required for normal development. Using the GAL4 system, we are able to rescue fully the embryonic lethality of an alphaPS2 null mutation with a UAS-alphaPS2 transgene, but only partially with a UAS-alphaPS1 gene, due to partial rescue of both muscle and midgut phenotypes. Similarly we are able to rescue the embryonic/first instar larval lethality of an alphaPS1 null mutation gene with UAS-alphaPS1, but only partially with UAS-alphaPS2. Each UAS-alpha gene, when it contains the cytoplasmic domain from the other alpha subunit, maintains an equivalent ability to rescue its own mutation and cannot fully rescue a mutation in the other alpha. We conclude that the two alpha subunits are not equivalent and have distinct functions which reside in the extracellular domains.

Mammalian CD2 is an effective heterologous marker of the cell surface in Drosophila.

Ectopic expression of neutral proteins, such as beta-galactosidase, in developing embryos has been an invaluable tool for studies of gene expression and embryonic development. However, expression of beta-galactosidase does not reveal the shape of the cells containing it. We have examined the suitability of rat CD2, a small transmembrane protein of the immunoglobulin superfamily, as a marker of cell morphology in Drosophila. We selected the regulatory sequences of the Drosophila mesoderm-specific gene twist to express CD2 and prepared a chimeric gene, twi-CD2. Embryos containing twi-CD2 faithfully express CD2 in the same pattern as Twist. Expression of CD2 on the surface of cells reveals the shape of cells when stained with existing monoclonal antibodies. We have also constructed a CD2 gene that can be used with the GAL4 system and show that CD2 can be expressed on the surface of epithelial cells and along the length of axons.

Blood gases, pH and hematology of montane and lowland coot embryos.

Blood gases, air cell-blood gas differences, blood pH, and hematology were compared in embryonic coots (Fulica americana peruviana) at 4150 m and sea level in Peru. Neither arterialized nor venous O2 tensions differed significantly between montane and lowland groups but blood CO2 tensions of the two groups differed significantly. The air cell PO2-arterialized blood PO2 difference of montane eggs was less than half the value in lowland eggs. Both arterialized and venous CO2 tensions differed substantially between montane and lowland groups. Despite these differences, plasma pH at both altitudes was statistically indistinguishable, due in part to variation in plasma [HCO3-]. Hematocrits of montane embryos were significantly higher than that of their lowland counterparts.

Integrins and morphogenesis.

The Drosophila position specific (PS) integrins consist of two cell surface heterodimers, PS1 (alpha PS1 beta PS) and PS2 (alpha OS2 beta PS), which are expressed on complementary sides of attachments between cell layers and are essential for these attachments. Current evidence suggests that the PS integrins bind to components of the extracellular matrix, similar to the majority of vertebrate integrins, but specific Drosophila ligands have not yet been identified. In the embryo PS1 is found on the surface of the epidermis and endoderm, while PS2 is restricted to the mesoderm. The integrins are concentrated at the sites where the somatic muscles attach to the epidermis and at the interface between the visceral mesoderm and the endoderm. In myospheroid mutant embryos, which lack the beta PS subunit, the adhesion between the mesoderm and the other cell layers fails. The PS integrins are also required for the adhesion of the dorsal to the ventral surface of the wing during metamorphosis. PS1 is expressed on the basal surface of the dorsal cells and PS2 is expressed on the ventral cells. Loss of PS integrin function in the wing results in balloon shaped wings because of the failure of the two surfaces of the wing blade to adhere to each other. These and other aspects of the phenotypes of mutations in the genes encoding the PS integrins indicate that integrins play an important role in the adhesion of different cell layers to each other and thus an essential role in the morphogenesis of the organism. The use of extracellular matrix receptors in this role may aid in keeping the different cell layers distinct.

Metabolic effects of cyanate on mice at sea level and in chronic hypobaric hypoxia.

In order to evaluate the toxic effects of Sodium Cyanate (NaOCN), it was orally administered to growing mice at sea level (SL-CN) and to mice chronically exposed to intermittent hypobaric hypoxia (IHH-CN). The effects on body weight, in-vivo O2 consumption (VO2) and the respiratory function of liver mitochondria were evaluated. At sea level, the animals on cyanate lost weight in contrast with the controls that gained weight. When exposed to IHH, the controls lost weight and the animals on cyanate regained weight. After 2 months observation the weights of the IHH-CN and IHH-C were similar. The VO2 after one month of treatment was similar in the SL-C and in the SL-CN but it was lower in the IHH-CN when compared with IHH-C. The substrate-stimulated respiration of isolated liver mitochondria (ST4) was not affected by NaOCN, but the ADP-stimulated respiration (ST3) was reduced. The ratio ST3/ST4 (RCR) was also lower. These changes were present in both SL and in IHH and were much larger after three months of treatment. The toxic effects of chronic administration of NaOCN are discussed.