The eyes of the female small white butterfly, Pieris rapae crucivora, are furnished with three classes of short-wavelength photoreceptors, with sensitivity peaks in the ultraviolet (UV) ( max ϭ 360 nm), violet (V) ( max ϭ 425 nm), and blue (B) ( max ϭ 453 nm) wavelength range. Analyzing the spectral origin of the photoreceptors, we isolated three novel mRNAs encoding opsins corresponding to shortwavelength-absorbing visual pigments. We localized the opsin mRNAs in the retinal tissue and found that each of the short-wavelengthsensitive photoreceptor classes exclusively expresses one of the opsin mRNAs. We, accordingly, termed the visual pigments PrUV, PrV, and PrB, respectively. The eyes of the male small white butterfly also use three classes of short-wavelength photoreceptors that equally uniquely express PrUV, PrV, and PrB. However, whereas the spectral sensitivities of the male photoreceptors with PrUV and PrB closely correspond to those of the female, the male photoreceptor expressing PrV has a double-peaked blue (dB) spectral sensitivity, strongly deviating from the spectral sensitivity of the female V photoreceptor. The male eyes contain a pigment that distinctly fluoresces under blue-violet as well as UV excitation light. It coexists with the dB photoreceptors and presumably acts as a spectral filter with an absorbance spectrum peaking at 416 nm. The narrow-band spectral sensitivity of the male dB photoreceptors probably evolved to improve the discrimination of the different wing colors of male and female P. rapae crucivora in the short-wavelength region of the spectrum.
The honeybee compound eye is equipped with ultraviolet, blue, and green receptors, which form the physiological basis of a trichromatic color vision system. We studied the distribution of the spectral receptors by localizing the three mRNAs encoding the opsins of the ultraviolet-, blue- and green-absorbing visual pigments. The expression patterns of the three opsin mRNAs demonstrated that three distinct types ommatidia exist, refuting the common assumption that the ommatidia composing the bee compound eye contain identical sets of spectral receptors. We found that type I ommatidia contain one ultraviolet and one blue receptor, type II ommatidia contain two ultraviolet receptors, and type III ommatidia have two blue receptors. All the three ommatidial types contain six green receptors. The ommatidia appear to be distributed rather randomly over the retina. The ratio of type I, II, and III ommatidia was about 44:46:10. Type III ommatidia appeared to be slightly more frequent (18%) in the anterior part of the ventral region of the eye. Retinal heterogeneity and ommatidial randomness, first clearly demonstrated in butterflies, seems to be a common design principle of the eyes of insects.
and III peak at 620·nm and those in type II ommatidia peak at 640·nm. The large shifts of the spectral sensitivities of the R5-8 photoreceptors with respect to the absorption spectrum of their visual pigment can be explained with the spectral filtering by pale-red (PR) and deep-red (DR) screening pigments that are concentrated in clusters of granules near the rhabdom boundary. The peak absorbance of the two spectral filters appears to be approximately 1 (PR) and 2 (DR).
In epithelia, tight junctions (TJs) create a primary barrier to the diffusion of solutes through the paracellular pathway. Although TJ-related molecules are present in the epidermis, the precise mechanisms underlying TJ functions in this tissue remain unclear. In this study, we use an ultraviolet (UV) B-irradiated murine skin model, in which the epidermal barrier function has been perturbed, to demonstrate a correlation between the expression patterns of TJ-related molecules and the epidermal permeability of TJs. Occludin remained localized in the upper epidermis, regardless of UVB irradiation (0.15 J per cm(2)). ZO-1 was localized in the upper portion of normal epidermis, and within 3-4 days of UVB irradiation, it was expressed throughout the upper epidermis and their expression coincided with epidermal thickening. Protein expression of claudin-1 and occludin did not alter until 3 and 4 days after UVB irradiation, respectively and thereafter expression remained elevated above pre-irradiation levels. An in vivo epidermal permeability assay revealed that tight junction-barrier function was perturbed by UVB irradiation, whereby biotinylated markers clearly permeated the stratum granulosum 3-5 days after irradiation. These results suggest that TJ-related molecules play important roles in epidermal barrier function in murine skin and show that changes in their expression patterns are associated with epidermal barrier perturbation after UVB irradiation. Specifically, it appears that epidermal barrier recovery is accelerated by the increased production and dense localization of occludin in the cell-cell contact region of the stratum granulosum.
Accumulating evidence shows that tight junctions (TJs) in the granular layer contribute to the epidermal barrier, suggesting that the regulation of TJ assembly in keratinocytes may provide a clue to understanding the role of barrier formation in epidermis. In this study, we investigated the behavior of TJ-related molecules in cultured human keratinocytes during keratinization induced by transfer to high-calcium medium, and the effect of RNA interference of TJ-related molecules on intercellular permeability and morphological features. The expression of TJ-related molecules and transepithelial electrical resistance were increased by transfer to high-calcium medium. In cells under the same conditions, we observed by freeze-fracture electron microscopy that TJ strands developed on the apposing cell membranes. In contrast, the transepithelial electrical resistance was clearly suppressed when the expression of claudin-1 or occludin was blocked by RNA interference. The morphological features of these knock-down cells were the same as those of MOCK cells, except for a marked decrease in the number of TJ strands. Furthermore, claudin-1 suppression inhibited occludin localization at the cell membrane, whereas suppression of occludin did not influence the localization of claudin-1. These results suggest that claudin-1 plays a crucial role in recruiting occludin to TJs, and that occludin is involved in intercellular barrier function.
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