Involvement of Pteridines in the Body Coloration of the Isopod Armadillidium vulgare

The pteridine content was measured as a function of age in Armadillidium vulgare, and the fine structure of the pteridine-containing granules in the integument was examined in relation to pteridine content. Yellow chromatophores are an essential component of the cream-markings, which are a defining feature of the female A. vulgare. Four kinds of pteridines in the integument including a yellow pigment (sepiapterin) were determined by HPLC. The body color of the red phenotype of A. vulgare varies from dark red to yellowish red and was formerly thought to be due to the quality and quantity of ommochrome pigment. Our analysis of the pteridine content in the integument of this phenotype revealed a significant change in sepiapterin content per body weight with age. Sepiapterin content per body weight decreased gradually with age, while that of biopterin tended to increase with age. Ultrastructural observations of the pigment granules in the yellow chromatophores revealed a corresponding change in the fine structure of pigment granules. In the older adults, some of the electron-dense fibrous materials in the pteridine-containing granules was concentrically arranged, and in the younger adults, most of pteridine-containing granules were electron-lucent. The role of pteridine quality in determining the structure of pteridine-containing granules is discussed.     

The morphology and evolution of the ventral gill arch skeleton in batoid fishes (Chondrichthyes: Batoidea)

The ventral gill arch skeleton was examined in some representatives of batoid fishes. The homology of the components was elucidated by comparing similarities and differences among the components of the ventral gill arches in chondrichthyans, and attempts were made to justify the homology by giving causal mechanisms of chondrogenesis associated with the ventral gill arch skeleton. The ceratohyal is present in some batoid fishes, and its functional replacement, the pseudohyal, seems incomplete in most groups of batoid fishes, except in stingrays. The medial fusion of the pseudohyal with successive ceratobranchials occurs to varying degrees among stingray groups. The ankylosis between the last two ceratobranchials occurs uniquely in stingrays, and it serves as part of the insertion of the last pair of coracobranchialis muscles. The basihyal is possibly independently lost in electric rays, the stingray genus Urotrygon (except U. daviesi) and pelagic myiiobatoid stingrays. The first hypobranchial is oriented anteriorly or anteromedially, and it varies in shape and size among batoid fishes. It is represented by rami projecting posterolaterally from the basihyal in sawfishes, guitarfishes and skates. It consists of a small piece of cartilage which extends anteromedially from the medial end of the first ccratobranchial in electric rays. It is a large cartilaginous plate in most of stingrays. It is absent in pelagic myliobatoid stingrays. The remaining hypobranchial cartilages also vary in shape and size among batoid fishes. Torpedo and possibly the Jurassic Belemnobalis and Spathobatis possess the generalized or typical chondrichthyan ventral gill arch structure in which the hypobranchials form a Σ-shaped pattern. In the electric ray Hypnos and narkinidid and narcinidid electric rays, the hypobranchial components are oriented longitudinally along the mid-portion of the ventral gill arches. They form a single cartilaginous plate in the narkinidid electric rays, Narcine and Diplobatis. In guitarfishes and skates, the second hypobranchial is unspecialized, and in skates, it does not have a direct contact with the second ceratobranchial. In both groups, the third and fourth hypobranchials are composed of a small cartilage which forms a passage for the afferent branches of the ventral aorta and serve as part of the insertion of the coracobranchialis muscle. In sawfishes and stingrays, the hypobranchials appear to be included in the medial plate. In sawfishes, the second and third components separately chondrify in adults, but the fourth component appears to be fused with the middle medial plate. In stingrays, a large medial plate appears to include the second through to the last hypobranchial and most of the basibranchial copulae. The medial plate probably develops independently in sawfishes and stingrays. Because the last basibranchial copula appears to be a composite of one to two hypobranchials and at least two basibranchial copulae, the medial plate may be formed by several developmental processes of chondrogenesis. More detailed comparative anatomical and developmental studies are needed to unveil morphogenesis and patternings of the ventral gill arch skeleton in batoid fishes.     

A systematic review of the snakes allied to Amphiesma pryeri (Boulenger) (Squamata: Golubridae) in the Ryukyu Archipelago, Japan

External characters, hemipenial morphology, karyotype, and reproductive mode were examined for the three subspecies of the endemic Ryukyu natricine, Amphiesma pryeri . Results revealed that populations of the Yaeyama Group, currently regarded as comprising a subspecies, A. p. ishigakiense , have several unique features such as the brownish ground colour of head, termination of sulcus spermaticus in the crotch between apical lobes of the hemipenis, terminal location of centromeres in the largest microchromosome pair, and the viviparous mode of reproduction. In the other populations, ground colour of head is black or dark greyish tan; sulcus spermaticus terminates near the tip of the left lobe of the hemipenis; the largest microchromosome pair is metacentric; and the reproductive mode is oviparous. Of these, however, the Miyakojima population, which currendy consists solely of the subspecies, A. p. concelarum , differs from the nominotypical subspecies from the central Ryukyus in having only 94–102 subcaudal scales and telocentric W chromosome; A. p. pryeri has 112–130 subcaudal scales and submetacentric W chromosomes. These strongly suggest that the two subspecies have also substantially diverged from each other, constituting distinct evolutionary lineages. We thus accord full-species status to each of pryeri, concelarum and ishigakiense , and revise their definitions on the basis of the present results. A dichotomous key to the Japanese species and subspecies of Amphiesma is provided.     

The Protoplasmic Connection in Volvox

SYNOPSIS. Electron-microscopic observations were performed on 2 species of Volvox , one similar to V. globator , the other to V. aureus. The former has distinct protoplasmic connections in the adult coenobium and specific structures, named "medial bodies," in the connections just at the intersection with the middle lamella. The medial body is disk shaped, about 800 mμ in diameter, and is composed of 3 parts, 2 dense outer layers and an intermediate less dense zone. In the latter species, the connection and medial body were not seen. On the other hand, it was commonly seen in both of them that in younger, dividing gonidia neighboring protoplasts were connected with each other by protoplasmic bridges. The bridges are undoubtedly formed due to incomplete cell separation in the division of a gonidium. The structural difference in the adult coen***bium between the 2 species emerges just after inversion of the coenobium. In the globator type the medial body appears just after inversion, and the connection remains unruptured all thru life. In the aureus type, it seems that the connections are withdrawn or degenerate immediately after inversion. It is discussed whether protoplasmic continuity is really maintained by the connection or not in the freeswimming coenobium of Volvox.     

Centripetal Disposition of Bundle Sheath Chloroplasts During the Leaf Development of Eleusine coracana

Distribution of chloroplasts in bundle sheath cells was examinedby light and electron microscopy during the leaf developmentof finger millet (Eleusine coracana Gaertn.), an NAD malic enzymetype C₄ plant with centripetal arrangement of bundle sheathchloroplasts. Young chloroplasts are almost evenly distributedalong the cell walls in bundle sheath cells of folded immatureleaves. In elongating leaves and above the elongation zone thebundle sheath chloroplasts tend to lie along the radial wallsand the walls adjacent to the vascular bundle. They furthermigrate near to the vascular bundle and finally establish acentripetal arrangement. Mitochondria, microbodies and nucleusmigrate along with the chloroplasts. Etioplasts and other organellesare centripetally located in the bundle sheath cells of etiolatedseedlings grown in the dark. Bundle sheath chloroplast, C₄ plant, chloroplast, chloroplast orientation, Eleusine coracana, finger millet