The Drosophila Chmp1 protein determines wing cell fate through regulation of epidermal growth factor receptor signaling.

Background: Receptor down-regulation by the multivesicular body (MVB) pathway is critical for many cellular signaling events. MVB generation is mediated by the highly conserved ESCRT (0, I, II, and III) protein complexes. Chmp1 is an ESCRT-III component and a putative tumor suppressor in humans.

Insect wing membrane topography is determined by the dorsal wing epithelium.

The Drosophila wing consists of a transparent wing membrane supported by a network of wing veins. Previously, we have shown that the wing membrane cuticle is not flat but is organized into ridges that are the equivalent of one wing epithelial cell in width and multiple cells in length. These cuticle ridges have an anteroposterior orientation in the anterior wing and a proximodistal orientation in the posterior wing.

Low-cost multispectral vegetation imaging system for detecting leaking CO₂ gas.

As a component of a multisensor approach to monitoring carbon sequestration sites for possible leaks of the CO₂ gas from underground reservoirs, a low-cost multispectral imaging system has been developed for indirect detection of gas leaks through observations of the resulting stress in overlying vegetation. The imager employs front-end optics designed to provide a full 50° field of view with a small, low-cost CMOS detector, while still maintaining quasi-collimated light through the angle-dependent interference filters used to define the spectral bands. Red and near-infrared vegetation reflectances are used to compute the normalized difference vegetation index (NDVI) and spatial and temporal patterns are analyzed statistically to identify regions of anomalous stress, which are then flagged for closer inspection with in-situ CO₂ sensors.

Cuticle refraction microscopy: a rapid and simple method for imaging Drosophila wing topography, an alternative readout of wing planar cell polarity.

The polarity of hairs on the adult Drosophila wing provides information about the planar cell polarity (PCP) signaling events that occur during pupal wing development. We have recently shown that PCP signaling also determines the orientation of cuticle ridges that traverse the surface of the adult wing membrane; a feature we call the wing membrane topography. Although hair polarity is uniform across the wild-type wing, ridge orientation differs between the anterior and posterior wing.

Two frizzled planar cell polarity signals in the Drosophila wing are differentially organized by the Fat/Dachsous pathway.

The regular array of distally pointing hairs on the mature Drosophila wing is evidence for the fine control of Planar Cell Polarity (PCP) during wing development. Normal wing PCP requires both the Frizzled (Fz) PCP pathway and the Fat/Dachsous (Ft/Ds) pathway, although the functional relationship between these pathways remains under debate. There is strong evidence that the Fz PCP pathway signals twice during wing development, and we have previously presented a Bidirectional-Biphasic Fz PCP signaling model which proposes that the Early and Late Fz PCP signals are in different directions and employ different isoforms of the Prickle protein.

The Frizzled Planar Cell Polarity signaling pathway controls Drosophila wing topography.

The Drosophila wing is a primary model system for studying the genetic control of epithelial Planar Cell Polarity (PCP). Each wing epithelial cell produces a distally pointing hair under the control of the Frizzled (Fz) PCP signaling pathway. Here, we show that Fz PCP signaling also controls the formation and orientation of ridges on the adult wing membrane.