The heterotrimeric protein Go is required for the formation of heart epithelium in Drosophila.

The gene encoding the alpha subunit of the Drosophila Go protein is expressed early in embryogenesis in the precursor cells of the heart tube, of the visceral muscles, and of the nervous system. This early expression coincides with the onset of the mesenchymal-epithelial transition to which are subjected the cardial cells and the precursor cells of the visceral musculature. This gene constitutes an appropriate marker to follow this transition. In addition, a detailed analysis of its expression suggests that the cardioblasts originate from two subpopulations of cells in each parasegment of the dorsal mesoderm that might depend on the wingless and hedgehog signaling pathways for both their determination and specification. In the nervous system, the expression of Goalpha shortly precedes the beginning of axonogenesis. Mutants produced in the Goalpha gene harbor abnormalities in the three tissues in which the gene is expressed. In particular, the heart does not form properly and interruptions in the heart epithelium are repeatedly observed, henceforth the brokenheart (bkh) name. Furthermore, in the bkh mutant embryos, the epithelial polarity of cardial cells was not acquired (or maintained) in various places of the cardiac tube. We predict that bkh might be involved in vesicular traffic of membrane proteins that is responsible for the acquisition of polarity.

Towards the molecular biology of cell adhesion in Drosophila.

The characterization of extracellular matrix molecules and their putative receptors is rapidly evolving in Drosophila. Where corresponding vertebrate and Drosophila extracellular proteins have been identified they are very similar with respect to their structural properties, suggesting a high degree of conservation during evolution. By contrast, indications for components homologous to vertebrate cell-cell adhesion molecules are still very sparse. Studies on the regulation of the Drosophila genes encoding cell adhesion molecules that are involved in general basic functions during morphogenesis, together with a knowledge of the function of the genes responsible for pattern formation, should lead towards a more complete understanding of the organism's developmental program.

The multienzyme complex containing nine aminoacyl-tRNA synthetases is ubiquitous from Drosophila to mammals.

In all mammalian cells studied so far, a multienzyme complex containing the nine aminoacyl-tRNA synthetases specific for the amino acids Glu, Pro, Ile, Leu, Met, Gln, Lys, Arg and Asp was characterized. The complexes purified from various sources display very similar polypeptide compositions; they are composed of 11 polypeptides with molecular masses ranging from 18 to 150 kDa. By contrast, the corresponding enzymes from prokaryotes and lower eukaryotes behave as free enzymes. In order to test for the ubiquity of the multisynthetase complex in all metazoan species, we have searched for a similar complex in Drosophila. We have purified to homogeneity, from Schneider cells, a high molecular weight complex comprising the same nine synthetase activities. Its polypeptide composition resembles that of the complexes isolated from mammalian sources. By using the Western blotting procedure, some of the constituent polypeptides of the Drosophila complex were assigned to specific aminoacyl-tRNA synthetases. These findings support the proposal according to which the multisynthetase complex is an idiosyncratic feature of all higher eukaryotic cells.

Plasma membranes from rat intestinal epithelial cells at different stages of maturation. I. Preparation and characterization of plasma membrane subfractions originating from crypt cells and from villous cells.

To determine the mechanism of the maturation of the brush border membrane in intestinal epithelial cells, purification of the plasma membrane from undifferentiated rat crypt cells and of the basal-lateral membrane from villous cells has been performed. The method is based on density perturbation of the mitochondria to selectively disrupt their association with the membrane. With both cell populations, two membrane subfractions displaying the same respective density on sucrose gradient have been obtained with an overall yield of 15--20% and a 10-fold enrichment of the plasma membrane markers 5'-nucleotidase and (Na+ + K+)-dependent, ouabain-sensitive ATPase chosen to follow their purification. The four fractions were constituted by sheets and apparently closed vesicles of various sizes. Each fraction was characterized by a distinct protein composition and different levels of enzyme activities. The cells, used for the preparation of the membranes, were isolated as a villus to crypt gradient. This separation and that of the membranes, led to the conclusion that the (Na+ + K+)-dependent ATPase is localized principally in the plasma membrane of all cells whatever their state of maturation, while 5'-nucleotidase is predominantly located in the basal-lateral membrane of the villous cells and may serve as a specific marker for the purification of this membrane. Finally it has been shown that aminopeptidase, dissacharidases and alkaline phosphatase do not appear simultaneously in the maturation process of the cells, alkaline phosphatase being absent from the crypt cells and aminopeptidase being the first to be synthesized. This enzyme seems to appear in the crypt cells membrane before being integrated into the mature brush border membrane.

Photoaffinity labeling of membrane-bound porcine aminopeptidase N.

To investigate the possible role of aminopeptidase N (alpha-aminoacyl-peptide hydrolase (microsomal), EC 3.4.11.2) in the transport of amino acids from oligopeptides, the modified amino acids Phe(N3) and Phe(N3, I) and the tetrapeptides Phe(N3) or Phe(N3, I)-L-or-DAla-Gly-Gly have been synthesized. The azido-amino acids were radioactively labeled by tritium or 125I before their coupling with the tripeptides. Their utilization as photoaffinity labels for aminopeptidase N has been studied. The modification imposed at the N-terminal residue of the tetrapeptides has not impaired their hydrolysis by porcine aminopeptidase N (same kinetic parameters as unmodified peptides). In addition, evidence is presented for a specific and reversible interaction in the dark of the azido-derivatives at the substrate recognition site of the enzyme. Upon photolysis, irreversible inactivation of aminopeptidase N and covalent attachment of Phe(N3, I) have been demonstrated. Soluble and membrane-bound aminopeptidases are both labeled to the same extent indicating that the free azido-amino acid preferentially reacts with the external part of the enzyme. Although the linkage of the azido-derivative is not strictly restricted to the region of the active site, the values obtained strongly suggest that 1 mol probe has been covalently attached per mol monomer of inhibited aminopeptidase.

The transduction signalling protein Go during embryonic development of Drosophila melanogaster.

G proteins are heterotrimeric proteins that play a key role in signalling transduction conveying signals from cell surface receptors to intracellular effector proteins. In particulate preparations from Drosophila melanogaster embryos, only one substrate of 39,000-40,000 molecular weight could be ADP-ribosylated with pertussis toxin. This substrate reacted in immunoblotting and immunoprecipitation experiments with a polyclonal antibody directed against the carboxy-terminal sequence of the alpha subunit of the mammalian Go protein. The Drosophila Go alpha protein was present at all stages of embryonic development; however, its expression markedly increased after 10 h embryogenesis, a period of time during which there is an active development of axonal tracts. Immunolocalization on whole mount embryos has indicated that this protein is principally localized in the CNS and is mainly restricted to the neuropil without any labelling of the cell bodies. In contrast, all the axon tracts of the CNS appeared to be highly labelled. The distribution of the Go alpha protein was also examined in several neurogenic mutants. The Go alpha protein expression was not altered in any of them but the pattern of labelling was disorganized as was the neuronal network. These results suggest a possible role for the Go protein during axonogenesis.

A new approach to monoclonal antibody production. In vitro immunization with antigens on nitrocellulose using Drosophila myosin heavy chain as an example.

A methodology of broad applicability is described for the production of monoclonal antibodies to antigens with interesting developmental properties using Drosophila myosin heavy chain to exemplify the procedure. The technique consists of two parts. (1) Identification of the antigen with any tool which allows its detection on a Western blot. In the present case, this was achieved by monospecific polyclonal antibodies, prepared as described by Smith and Fisher (J. Cell Biol. (1984) 99, 20), which usefully define the characteristic properties of the antigen. (2) In vitro immunization of splenocytes with antigen on nitrocellulose whose position on Western blots was detected using monospecific polyclonal antibodies, followed by generation of monoclonal antibodies. A total of 19 hybridomas were selected by immunohistochemistry screening and at least six of them were directed against antigens possessing the specific characteristic properties of myosin heavy chain.

Adsorption and activation of pancreatic lipase at interfaces.

The first step of the lipase-catalyzed hydrolysis of insoluble long chain triglycerides is the adsorption of the enzyme to the interface. This adsorption, which is spontaneous when the interface is hydrophobic, is hindered by bile salts. Under these conditions, a small protein cofactor designated colipase adsorbs first and then anchors lipase at the interface. Interfacial adsorption enhances lipase activity, due, at least in part, to an acceleration of the rate-limiting deacylation step of the reaction. In this respect, lipase appears to be a most interesting model of an enzyme being activated by the presence of a lipid. The 3 steps of the heterogeneous catalysis induced by lipase, interfacial adsorption, interfacial activation and catalysis proper are under the control, respectively, of a serine hydroxyl group, a carboxyl and a histidine imidazole.

Effect of taurodeoxycholate, colipase and temperature on the interfacial inactivation of porcine pancreatic lipase.

Beside their inhibitory effect upon lipase adsorption, bile salts at low concentration (around 0.2 mM) have repeatedly been shown to enhance lipolysis slightly. From the data reported in this paper, this activation has been attributed to a stabilization of the adsorbed lipase brought about by low concentrations of bile salts. This hypothesis relies on the following observations. (a) For a given temperature, the activation by bile salts depends on the substrate. It is maximum for trihexanoin (trihexanoylglycerol) and does not exist for tripropionin (tripropionylglycerol). (b) In the absence of bile salts, the optimal activities are obtained for different temperatures depending on the substrate. (c) For a given substrate, the activation by a low concentration of bile salts depends on the temperature. It increases when the temperature is raised (up to 35-40 degrees C) and completely disappears at a sufficiently low temperature (around 10 degrees C). (d) This temperature effect does not seem to be due to a modification of the physical parameters of the interface as measured by the interfacial tension. (r) Colipase, like bile salts, increases the lipase activity on short-chain triglycerides but only at high temperature when lipase denaturation occurs. It has no influence upon the activity when the temperature is sufficiently low (around 10 degrees C).

Mechanism of pancreatic lipase action. 2. Catalytic properties of modified lipases.

Reaction of lipase with diethyl pyrocarbonate results in the modification of three histidine residues. One is highly reactive, although without affecting the activity, while the two others react more slowly with a concomitant loss of activity on both dissolved and emulsified substrates. As previously shown, lipase can also be modified either by reaction of five carboxyl groups with carbodiimide (5N-lipase) or by esterification of one serine residue with diethyl p-nitrophenyl phosphate (DP-lipase). In the three cases, the activity on emulsified substrates is abolished. The modification of histidine residues results also in a loss of activity on dissolved substrates, suggesting that the essential histidine is at (or close to) the active site. The ability of lipase to be adsorbed on siliconized glass beads is not impaired in this reaction. By contrast, 5N-lipase is still able to hydrolyze dissolved monomeric substrates and to adsorb on siliconized glass beands. Therefore, the essential carboxyl group is assumed to play an important role in the interfacial activation. Finally, since DP-lipase is still fully active on dissolved p-nitrophenyl acetate, the serine residue, which has been previously suggested to be the acylable one, is more likely implicated in the recognition and the binding to interfaces, as confirmed by the inability of DP-lipase to be adsorbed on siliconized glass beads.

Pancreatic lipase and colipase: an example of heterogeneous biocatalysis.

The hydrolytic reactions catalyzed by pancreatic lipase represent a good example of heterogeneous catalysis. The particularity of this enzyme is provided by its preferential action on emulsified substrates. The first step of catalysis resides in a reversible adsorption of the enzyme to the oil-water interface. In fact, the formation of this adsorption complex is an obligatory step for the enzyme to display its full activity. Two principal but not necessarily exclusive hypotheses have been proposed to explain the observed interfacial activation: Either the interface confers new properties on the substrate which allow its subsequent hydrolysis, or the enzyme itself is modified by adsorption at the interface. Different approaches have recently been developed to clarify this point further. The results obtained by chemical modifications of lipase are consistent with the following hypothesis. The active site preexists in solution and becomes fully functional only by interaction of the interface with an additional site on the enzyme molecule which can be tentatively called the "interfacial activation site." Finally, a protein of low molecular weight, colipase, seems necessary for lipase to express its activity under physiological conditions. This protein enters specific interactions with bile salts micelles and is responsible for the reversal of the inhibition of lipolysis brought about by these detergents.