Drosophila IKK-related kinase regulates nonapoptotic function of caspases via degradation of IAPs.

Caspase activation has been extensively studied in the context of apoptosis. However, caspases also control other cellular functions, although the mechanisms regulating caspases in nonapoptotic contexts remain obscure. Drosophila IAP1 (DIAP1) is an endogenous caspase inhibitor that is crucial for regulating cell death during development. Here we describe Drosophila IKK-related kinase (DmIKKvarepsilon) as a regulator of caspase activation in a nonapoptotic context. We show that DmIKKvarepsilon promotes degradation of DIAP1 through direct phosphorylation. Knockdown of DmIKKvarepsilon in the proneural clusters of the wing imaginal disc, in which nonapoptotic caspase activity is required for proper sensory organ precursor (SOP) development, stabilizes endogenous DIAP1 and affects Drosophila SOP development. Our results demonstrate that DmIKKvarepsilon is a determinant of DIAP1 protein levels and that it establishes the threshold of activity required for the execution of nonapoptotic caspase functions.

A pheromone receptor mediates 11-cis-vaccenyl acetate-induced responses in Drosophila.

Insect pheromones elicit stereotypic behaviors that are critical for survival and reproduction. Defining the relevant molecular mechanisms mediating pheromone signaling is an important step to manipulate pheromone-induced behaviors in pathogenic or agriculturally important pests. The only volatile pheromone identified in Drosophila is 11-cis-vaccenyl acetate (VA), a male-specific lipid that mediates aggregation behavior. VA activates a few dozen olfactory neurons located in T1 sensilla on the antenna of both male and female flies. Here, we identify a neuronal receptor required for VA sensitivity. We identified two mutants lacking functional T1 sensilla and show that the expression of the VA receptor is dramatically reduced or eliminated. Importantly, we show misexpression of this receptor in non-T1 neurons, normally insensitive to VA, confers pheromone sensitivity at physiologic concentrations. Sensitivity of T1 neurons to VA requires LUSH, an extracellular odorant-binding protein (OBP76a) present in the sensillum lymph bathing trichoid olfactory neuron dendrites. Here, we show LUSH are also required in non-T1 neurons misexpressing the receptor to respond to VA. These data provide new insight into the molecular components and neuronal basis of volatile pheromone perception.

Antennal deformities of chironomid larvae and their use in biomonitoring of heavy metal pollutants in the river Damodar of West Bengal, India.

Analyses of sediment and water indicate the presence of heavy metal pollutants like lead, zinc, copper, mercury and cadmium of the river Damodar of India. These metals are responsible for causing morphological deformities of antennae and other parts of chironomid larvae. Percentage of deformity correlated positively with the concentrations of Pb in water and sediment (r > 0.6) at the confluence point. A new severity index, SISS((antenna)) has been proposed here to assess deformity at the family or subfamily level.

WAY-100635, an antagonist of 5-HT(1A) receptor, causes malformations of the CNS in ascidian embryos.

Serotonin (5-HT) is a neurotransmitter which is supposed to play a key role during development. In the last few years 5-HT receptors have been cloned in many animal species, and there is evidence that different 5-HT receptors are also present in ascidians. Ascidians and vertebrates are both members of the phylum Chordata and both have a dorsal tubular central nervous system. Embryos of the ascidian Phallusia mammillata have been treated with WAY-100635, a potent and selective 5-HT(1A) receptor antagonist. The larvae developed from treated embryos showed a dramatic reduction of their anterior sensory vesicles and the pigment of two sensory organs, the ocellus and the otolith. Immunofluorescence experiments with an anti beta-tubulin monoclonal antibody specific for the neural system showed that the anterior neural system of treated animals was radically altered by the action of the drug in a dose-dependent way. These results suggest that 5-HT plays a role in the development of the neural system in ascidians and its action is mediated by receptors similar to the members of the 5-HT(1A) receptor subtype of mammals.

Phylogeny and its clinical significance.

The creation of the universe, the origin of life, and the rise of the one celled organism to man are reviewed. The embryologic development of man recapitulates the entire phylogenesis. The evolution of the sense organs (ear and nose) and food and airway passages is discussed in detail. Finally, observations are made regarding phylogenetic development and its relation to human congenital malformations and other pathologic processes.

Projection of sensory neurons from a homeotic mutant appendage, Antennapedia, in Drosophila melanogaster.

Central projections of sensory neurons from homeotic mutant appendages (Antennapedia) of Drosophila melanogaster were compared with those of wild-type antennae and wild-type legs by means of degeneration and cobalt backfilling methods. Sensory axons originating from wild-type thoracic legs terminate within the ventral ipsilateral half of the corresponding neuropile segment and do not project to the brain. Sensory fibers from the third antennal segment (AIII) of wild-type animals project into the ipsilateral antennal glomerulus (AG) and to a lesser extent into the contralateral AG, whereas those from the second antennal segment terminate principally within the ipsilateral posterior antennal center. The sensory terminals of femur, tibia, and tarsi of the homeotic leg show a distribution very similar to that of the homologous wild-type antennal segment AIII, differing to a minor degree only in the size and precise localization of terminals within the antennal glomeruli. No degenerating axons were evident in ultrastructural examination of neck connectives after removal of homeotic legs. It is thus very improbable that any sensory fibers of the homeotic leg project to normal leg projection areas in the thoracico-abdominal ganglion. Several alternative explanations are offered for the apparent retention of antennal specificity by axons from the transformed appendage.

Development in genetic mosaics of aristapedia, a homoeotic mutant of Drosophila melanogaster.

Development of the homoeotic mutation, aristapedia (ss(a)), was investigated by means of genetic mosaics. The wild-type alleles of aristapedia and the bristle markers yellow, singed, and forked were removed from cells at different times in development by X-ray induced somatic crossing-over. The phenotype of the resulting clones was examined in order to ascertain whether it was leg or antenna. The y sn f; ss(a) clones showed a leg phenotype if induced before the mid-third instar, but showed an antennal phenotype if induced after this time. Late non-expression of ss(a) may be due either to an influence of surrounding ss(+) tissues on the small ss(a) clones, or to a persistence of the effect of ss(+) for one or two cell generations after it is removed from a cell line.