Biosynthesis of Quinoline by a Stick Insect.

The Peruvian stick insect Oreophoetes peruana is the only known animal source for unsubstituted quinoline in nature. When disturbed, these insects discharge a defensive secretion containing quinoline. Analysis of samples obtained from l-[2',4',5',6,'7'-2H5]tryptophan-fed stick insects demonstrated that the insects convert it to [5,6,7,8-2H4]quinoline by removing the 2'-CH moiety in the indole ring of tryptophan. Analogous experiments using l-[1'-15N]tryptophan and l-[1'-15N,15NH2]tryptophan showed that the indole-N atom is retained while the α-amino group is eliminated during the biosynthesis. Mass spectra recorded from quinoline derived from [2-13C1]tryptophan-fed insects indicated that the α-carbon atom of tryptophan is incorporated as the C-2 atom of the quinoline ring.

Biological bifocal lenses with image separation.

Almost all animal eyes follow a few, relatively well-understood functional plans. Only rarely do researchers discover an eye that diverges fundamentally from known types. The principal eye E2 of sunburst diving beetle (Thermonectus marmoratus) larvae clearly falls into the rarer category. On the basis of two different tests, we here report that it has truly bifocal lenses, something that has been previously suggested only for certain trilobites. Our evidence comes from (1) the relative contrast in images of a square wave grating and (2) the refraction of a narrow laser beam projected through the lens. T. marmoratus larvae have two retinas at different depths behind the lens, and these are situated so that each can receive its own focused image. This is consistent with a novel eye organization that possibly comprises "two eyes in one." Moreover, we find that in contrast to most commercial bifocal lenses, the lens of E2 exhibits asymmetry, which results in separation of the images both dorsoventrally and rostrocaudally within the layered retina. Visual contrast might thus be improved over conventional bifocal lenses because the unfocused version of one image is shifted away from the focused version of the other, an organization which could potentially be exploited in optical engineering.

Eye and optic lobe metamorphosis in the sunburst diving beetle, Thermonectus marmoratus (Coleoptera: Dytiscidae).

Nearly nothing is known about the transition that visual brain regions undergo during metamorphosis, except for Drosophila in which larval eyes and the underlying neural structure are strongly reduced. We have studied the larvae of the sunburst diving beetle, Thermonectus marmoratus (Coleoptera: Dytiscidae), which are sophisticated visually oriented predators characterized by six elaborate stemmata on each side of the head and an associated large optic lobe. We used general neurohistological staining and 3D reconstruction to determine how the eyes and optic lobe of T. marmoratus change morphologically during metamorphosis. We find that in third (last) instar larvae, the adult neuropils are already forming de novo dorsally and slightly anteriorly to the larval neuropils, while the latter rapidly degenerate. Larval eyes are eventually reduced to distinct areas with dark pigmentation. This complete reorganization, which may be an evolutionarily conserved trait in holometabolous insects, occurs despite the considerable costs that must apply to such a visually complex animal. Our findings are consistent with the concept that stemmata are homologous to the most posterior ommatidia of hemimetabolous insects, an idea also recently supported by molecular data.

Scanning behavior by larvae of the predacious diving beetle, Thermonectus marmoratus (Coleoptera: Dytiscidae) enlarges visual field prior to prey capture.

Larvae of the predaceous diving beetle Thermonectus marmoratus bear six stemmata on each side of their head, two of which form relatively long tubes with linear retinas at their proximal ends. The physical organization of these eyes results in extremely narrow visual fields that extend only laterally in the horizontal body plane. There are other examples of animals possessing eyes with predominantly linear retinas, or with linear arrangements of specific receptor types. In these animals, the eyes, or parts of the eyes, are movable and perform scanning movements to increase the visual field. Based on anatomical data and observations of relatively transparent, immobilized young larvae, we report here that T. marmoratus larvae are incapable of moving their eyes or any part of their eyes within the head capsule. However, they do perform a series of bodily dorso-ventral pivots prior to prey capture, behaviorally extending the vertical visual field from 2 degrees to up to 50 degrees. Frame-by-frame analysis shows that such behavior is performed within a characteristic distance to the prey. These data provide first insights into the function of the very peculiar anatomical eye organization of T. marmoratus larvae.

Twenty-eight retinas but only twelve eyes: an anatomical analysis of the larval visual system of the diving beetle Thermonectus marmoratus (Coleoptera: Dytiscidae).

The larvae of the sunburst diving beetle, Thermonectus marmoratus (Coleoptera: Dytiscidae), are highly efficient visually guided predators. Their visual system consists of a cluster of six stemmata and one eye patch on each side of the head capsule. Histological investigations show that the organization of individual stemmata differs strongly from any eye that has previously been described. Based on general morphology, ultrastructural data, and the presence of actin-rich areas that are typical for rhabdoms, we find that each eye is characterized by several retinas. The most dorsal eye on each side is relatively long and tubular, and we have identified three spatially distinct areas with retinula cells: 1) a band of two rows of rhabdoms along the medial side of the eye tube; 2) a flattened cone-shaped region towards the bottom of the tube that is formed by the rhabdoms of retinula cells that are oriented perpendicular to the light path; and 3) two horizontal rows of long rhabdoms parallel to the light path at the base of the tube. A second large eye is organized similarly but lacks the medial band. The remaining four eyes are nearly spherical and each has two distinct retinas. The 12 eyes hence account for a total of 26 retinas, and two further retinas are present in eye patches lacking lenses. Our anatomical findings suggest that this is an example of a visual system in which specific visual tasks are distributed among the eyes, and which relies on a variety of highly specialized retinas.