The Ultrastructure of Spores (Protozoa: Microsporida) from Lophius americanus,the Angler Fish1

ABSTRACT. Spinal and cranial ganglia of American angler fish, Lophius americanus, are often infected with microsporidia. This protozoon elicits the formation of large, spore-filled, hypertrophied host cells, cysts. Previous reports of microsporidia in European lophiids identify the parasite as Spraguea lophii, a genus which has recently been shown to be dimorphic. The spores from L. americanus are monomorphic (2.8 × 1.5 μm) and uninucleate. Each spore contains a polar tube that forms six to nine coils. Spraguea lophii differs from the microsporidium described in L. americanus in several ways. Spraguea lophii has two spore types: a large spore (4.0 × 1.25 μm) containing a diplokaryon and three to four polar tube coils and a smaller uninucleate spore (3.5 × 1.5 μm) with five to six polar tube coils. Because of these major differences, the microsporidium from L. americanus is removed from the genus Spraguea and returned to its original genus, Glugea, as a new species, G. americanus n. sp. Other ultrastructural characteristics of G. americanus are included: the posterior vacuole encloses two distinct membranous structures; one is tubular and resembles a “glomerular tuft” and the second is lamellar and composed of concentric membrane whorls, additionally, the straight or manubroid portion of the polar tube proceeds beyond the posterior vacuole before it turns anteriorly and begins to coil.     

竹亚科单枝竹属芸香竹花枝和花特征补充描述

繁殖器官在竹类植物的分类学研究中具有重要意义,研究组在广西马山县观察到竹亚科单枝竹属芸香竹正在开花,该文根据观察到的开花状况和采集到的标本解剖观察结果,对其花枝和繁殖器官特征做了详细的中文及拉丁文补充描述。经对比芸香竹与属内已知繁殖器官结构的单枝竹和小花单枝竹的繁殖器官,3个竹种有相同的繁殖器官结构特征,但在小花数目和大小等方面具有差异。繁殖器官比较表明该属竹种的繁殖器官对喀斯特地貌环境有特殊的适应性,也支持依据营养器官差异划分为3个独立竹种。     

The first report of luminescent liver tissue in fishes: Evolution and structure of bioluminescent organs in the deep‐sea naked barracudinas (Aulopiformes: Lestidiidae)

Bioluminescent organs that provide ventral camouflage are common among fishes in the meso‐bathypelagic zones of the deep sea. However, the anatomical structures that have been modified to produce light vary substantially among different groups of fishes. Although the anatomical structure and evolutionary derivation of some of these organs have been well studied, the light organs of the naked barracudinas have received little scientific attention. This study describes the anatomy and evolution of bioluminescent organs in the Lestidiidae (naked barracudinas) in the context of a new phylogeny of barracudinas and closely related alepisauroid fishes. Gross and histological examination of bioluminescent organs or homologous structures from preserved museum specimens indicate that the ventral light organ is derived from hepatopancreatic tissue and that the antorbital spot in Lestrolepis is, in fact, a second dermal light organ. In the context of the phylogeny generated from DNA‐sequence data from eight gene fragments (7 nuclear and 1 mitochondrial), a complex liver with a narrow ventral strand running along the ventral midline evolves first in the Lestidiidae. The ventral hepatopancreatic tissue later evolves into a ventral bioluminescent organ in the ancestor of Lestidium and Lestrolepis with the lineage leading to the genus Lestrolepis evolving a dermal antorbital bioluminescent organ, likely for light‐intensity matching. This is the first described hepatopancreatic bioluminescent organ in fishes. J. Morphol. 276:310–318, 2015. © 2014 Wiley Periodicals, Inc.     

Comparative SEM Studies of Lattice Organs: Putative Sensory Structures on the Carapace of Larvae from Ascothoracida and Cirripedia (Crustacea Maxillopoda Thecostraca)

Putative sensory structures, called lattice organs, were studied with scanning electron microscopy from ascothoracid or cypris larvae representing a wide range of families of the Ascothoracida and Cirripedia. These organs, situated dorsally on the carapace were, with few exceptions, always found in two anterior and three posterior pairs. The lattice organ morphology displayed by the Ascothoracida, a seta–like structure with a terminal pore, is believed to be the most plesiomorphic condition. Within the Cirripedia lattice organ morphology varied from types resembling the Ascothoracida in the Acrothoracica and the lepadomorph Capitulum mitella, to an elongate pore field with a larger terminal pore in most Thoracica and Rhizocephala. Akentrogonid Rhizocephala seem to display the most apomorphic condition. While lattice organ morphology was generally constant at the family level, cases were seen where closely related species such as Chthamalus stellatusand Chthamalus montaguishowed minor, but clear cut differences. Lattice organs in 2 + 3 pairs are argued to represent a synapomorphy for the Ascothoracida and the Cirripedia. The results confirm that the cyprid morphology at the ultrastructural level will prove to be of high value in estimating phylogeny within the Cirripedia.     

PHYLOGENETIC INFERENCE OF NUPTIAL TRAIT EVOLUTION IN THE CONTEXT OF ASYMMETRICAL INTROGRESSION IN NORTH AMERICAN DARTERS (TELEOSTEI)

Introgressive hybridization and incomplete lineage sorting complicate the inference of phylogeny, and available species‐tree methods do not simultaneously account for these processes. Both hybridization and ancestral polymorphism have been invoked to explain divergent phylogenies inferred from different datasets for Stigmacerca, a clade of 11 North American darter species. Species of Stigmacerca are characterized by a mating system involving parental care with males guarding nesting territories and fertilized eggs. Males of four species of Stigmacerca develop egg‐mimic nuptial structures on their second dorsal fins during the breeding season. Previous phylogenies suggest contrasting scenarios for the evolution of this nuptial trait. Using a combination of coalescent‐based methods, we analyzed a dataset comprising a mitochondrial gene and 15 nuclear loci to estimate relationships and simultaneously test for introgressive hybridization. Our analyses identified several instances of interspecific gene flow involving both cytoplamsmic haplotypes and nuclear alleles. The new phylogeny was used to infer a single origin and recent loss of egg‐mimic structures in Stigmacerca and led to the discovery of a phylogenetically distinct species. Our results highlight the limited strategies available to account for introgressive hybridization in the inference of species relationships and the likely effects of this process on reconstructing trait evolution.     

Lymphomyeloid organs of the Antarctic fish Trematomus nicolai and Chionodraco hamatus (Teleostei: Notothenioidea): a comparative histological study

Lymphomyeloid organs of two common species of Antarctic fish, Trematomus nicolai and Chionodraco hamatus, were studied with the aim of analysing some morphological aspects of these organs in relation to adaptation to low environmental temperature. The thymuses of T. nicolai and C. hamatus were flattened, incompletely lobated, with numerous Hassall-like bodies, which were mainly located in the central part of the organ in C. hamatus. In T. nicolai, thymocytes, erythroid and reticular epithelial cells filled the organ. In C. hamatus, the thymocytes intermingled with reticular epithelial cells were often close to groups of melano-macrophages. In both species, the thymus did not show distinct compartmentalisation; however, the thymocytes had significantly different sizes in the outer and inner portions of the thymus. The head kidney of both species was completely filled by haematopoietic tissue, highly vascularised and mainly lymphopoietic in T. nicolai, while both erythropoietic and lymphopoietic in C. hamatus. The spleen appeared mainly erythropoietic in T. nicolai and mainly lymphopoietic in C. hamatus. Solitary melano-macrophages in T. nicolai were close to numerous small vascular ellipsoids where erythroid and lymphoid cells were intermingled without the formation of red and white pulp areas. In C. hamatus, large lymphoid areas were organised around the capillaries. The possible adaptation of lymphoid organs to the low temperature of polar water is discussed. Accepted: 8 November 1999     

The Luminescent Systems of Pony Fishes

The anatomy of bioluminescent organs and mode of light production in 18 species of pony fish have been investigated using fresh and preserved material. The luminescent systems are similarly arranged in all. Basically, the system consists of a light organ located at the distal end of the esophagus, and a series of abdominal accessory structures positioned in tandem for controlling light intensity and for directing and dispersing the light. Light is produced by numerous symbiotic luminous bacteria in the light organ. A simple classification of the luminescent systems is proposed. The light organs of Leiognathus elongatus and L. rivulatus show marked sexual dimorphism. The bacteria present in the light organs of many pony fishes are easily culturable, but not those from L. elongatus. Electron micrographs of the light organs of L. elongatus and L. rivulatus show the presence of numerous rod-shaped bacteria measuring approximately 0.8 µ x 2.4 µ and 0.8 µ x 7.3 µ, respectively. It is concluded that the light organ of L. elongatus contains another example of a type of non-culturable luminous bacteria that have been found elsewhere. Such bacteria appear to require from the host some special factor for growth and luminescence.     

Environmental correlates of internal coloration in frogs vary throughout space and lineages

Internal organs of ectotherms have melanin‐containing cells that confer different degrees of coloration to them. Previous experimental studies analyzed their developmental origin, role in immunity, and hormonal regulation. For example, melanin increases with ultraviolet radiation (UV) and temperature in frogs and fish. However, little is known about how environmental variables influence the amount of coloration on organs among amphibian species over a large spatial extent. Here, we tested how climatic variables (temperature, UV, and photoperiod) influence the coloration of internal organs of anurans. We recorded the level of melanin pigmentation using four categories on 12 internal organs and structures of 388 specimens from 43 species belonging to six anuran families. Then, we tested which climatic variables had the highest covariation with the pigmentation on each organ after controlling for spatial autocorrelation in climatic variables and phylogenetic signal in organ coloration using the extended version of the RLQ ordination. Coloration in all organs was correlated with the phylogeny. However, the coloration of different organs was affected by different variables. Specifically, the coloration of the heart, kidneys, and rectum of hylids, Rhinella schneideri, some Leptodactylus, and Proceratophrys strongly covaried with temperature and photoperiod, whereas that of the testicle, lumbar parietal peritoneum, lungs, and mesenterium of Leiuperinae, Hylodidae, Adenomera, and most Leptodactylus had highest covariation with UV‐B and temperature. Our results support the notion that melanin pigmentation on the surface of organs of amphibians has an adaptive function conferred by the protective functions of the pigment. But most importantly, internal melanin seems to respond differently to climatic variables depending on the lineage and locality in which species occur.     

Special cutaneous receptor organs of fish. IV. Ampullary organs of the nonelectric catfish, Kryptopterus

Ampullary organs of the transparent catfish, Kryptopterus bicirrhus, are present in large numbers on the head and in a regular pattern of lines on the body and fins. The organs lie in the epidermis, and have a pore that opens to the surface. Flattened cells form a roof and walls. On the floor of the organ there are a “sensory hillock,” composed of spherical receptor cells and columnar supporting cells, and a “secretory hillock” composed of columnar secretory cells. The receptor cells are nonciliated and have only afferent innervation. The organ cavity is filled with jelly. The organs are compared with ampullary organs of the weakly electric fish Eigenmannia, ampullae of Lorenzini of Raja, and small pit organs of Amiurus. Structural characteristics of the ampullary organs of Kryptopterus make them especially suitable for electrophysiological studies.     

Structure of the green lacewing tympanal organ (Chrysopa carnea,neuroptera)

Small swellings near the base of the radial vein in each fore wing of the green lacewing, Chrysopa carnea, resemble typical insect tympanal organs, but some important differences are apparent. The swellings are bounded dorsally and laterally by thick cuticle and ventrally by thin, membranous cuticle. The ventral membrane is formed by a single, thin sheet of exocuticle with flattened hypodermis internally, but lacks the tracheal component that forms part of the tympanum in the typical insect tympanal organ. The portion of the membrane beneath each swelling is rippled while proximally it is smooth. In contrast to typical insect tympanal organs, the swellings in C. carnea are largely fluid-filled since an unexpanded trachea runs through each organ. A distal and a proximal chordotonal organ composed of typical chordotonal sensory units are associated with each swelling. The distal organ contains from five to seven units while the proximal organ is composed of from 18 to 20 units. Each sensory unit is composed of three readily identifiable cells. Distally, an attachment cell unites with the membrane and is contiguous with the scolopale cell, which surrounds the dendrite of the bipolar neuron. On the basis of the morphological evidence, one would not expect these swellings to function as sound receptors. However, the results of physiological and behavioral experiments, presented elsewhere, show that these organs are receptors for ultrasound.     

Plant meristems: <Emphasis Type="Italic">CLAVATA3/ESR</Emphasis>-related signaling in the shoot apical meristem and the root apical meristem

The plant meristems, shoot apical meristem (SAM) and root apical meristem (RAM), are unique structures made up of a self-renewing population of undifferentiated pluripotent stem cells. The SAM produces all aerial parts of postembryonic organs, and the RAM promotes the continuous growth of roots. Even though the structures of the SAM and RAM differ, the signaling components required for stem cell maintenance seem to be relatively conserved. Both meristems utilize cell-to-cell communication to maintain proper meristematic activities and meristem organization and to coordinate new organ formation. In SAM, an essential regulatory mechanism for meristem organization is a regulatory loop between WUSCHEL (WUS) and CLAVATA (CLV), which functions in a non-cell-autonomous manner. This intercellular signaling network coordinates the development of the organization center, organ boundaries and distant organs. The CLAVATA3/ESR (CLE)-related genes produce signal peptides, which act non-cell-autonomously in the meristem regulation in SAM. In RAM, it has been suggested that a similar mechanism can regulate meristem maintenance, but these functions are largely unknown. Here, we overview the WUS–CLV signaling network for stem cell maintenance in SAM and a related mechanism in RAM maintenance. We also discuss conservation of the regulatory system for stem cells in various plant species. S. Sawa is the recipient of the BSJ Award for Young Scientist, 2007.     

Organization of the vomeronasal organ in a plethodontid salamander

Salamanders in the family Plethodontidae show a unique behavior (nose-tapping) and have unique structures (nasolabial grooves) that may be used specifically to convey chemicals to the vomeronasal organ. The nasal structure of Plethodon cinereus was studied to determine if there is enhanced development of the vomeronasal organ compared with other salamander families that would correlate with use of these unique features. The vomeronasal organ in salamanders is found in a ventrolateral diverticulum of each main olfactory organ. P. cinereus has a more anteriorly placed vomeronasal organ within the diverticulum, and the posterior limit of each nasolabial groove is adjacent to the anterior limit of the vomeronasal organs. This suggests that the grooves deliver chemicals preferentially to the vomeronasal organs instead of to the main olfactory organs. In addition, the vomeronasal sensory epithelium is thickest anteriorly and is at its thinnest at about the level corresponding to the location of the vomeronasal organ in other salamander families. These adaptations suggest a specific mechanism of odorant delivery to the vomeronasal organ in plethodontid salamanders not found in other salamander families.     

STEWARTIOTHECA GEN. N. AND THE NATURE AND ORIGIN OF COMPLEX PERMINERALIZED MEDULLOSAN POLLEN ORGANS

Stewartiotheca gen. n. is a bell-shaped, unisynangiate pollen organ with eccentric radial symmetry and a single series of about 80 pollen sacs. Infoldings that vary in depth occur circumferentially and extend from the periphery to a point off center. This position also marks the location of a sclerenchyma column (proximally) and a sclerenchyma-lined, conical hollow (distally) that opens onto the distal face of the organ. Plates of ground parenchyma extend inward from the outer covering of the organ at locations of infoldings, while similar plates with sclerenchyma strands occur between these locations. Pre-pollen of Monoletes type was released through distal longitudinal slitlike openings of the pollen sac faces toward the sclerenchymatous ground tissue plates. Vascular bundles entering the organ undergo repeated dichotomies, and lead to numerous bundles both in the cover (one per sac for those sacs that abut directly on cover tissue) and internally (one per pair of pollen sacs that lie opposite one another across the location of an infolding). The most complex permineralized medullosan pollen organs Sullitheca, Stewartiotheca, and Dolerotheca are considered to have evolved from a similar type of cup-shaped organ with a single ring of pollen sacs, broadly open distally, and with a central hollow. Circumferential infoldings of one organ of this type were involved in the origin of both Stewartiotheca and Sullitheca, while four similar organs, each showing infoldings non-circumferentially, fused to produce the Dolerotheca type organ (exemplified by D. formosa), a compound synangium.     

Central nervous system and sense organs, with special reference to photoreceptor-like sensory elements, in Polygordius appendiculatus (Annelida), an interstitial polychaete with uncertain phylogenetic affinities

Abstract. The phylogenetic position of Polygordius is still pending; relationships with either Opheliidae or with Saccocirrus are the most favored hypotheses. The present study of Polygordius appendiculatus was designed to look for morphological characters supporting either of these two hypotheses. The homology of the anterior appendages, and the structure of the central nervous system and nuchal organ all required clarification; we also examined whether photoreceptor‐like sense organs exist in adults. From their innervation pattern, it is likely that the anterior appendages represent palps. They lack structures typical of palps in Canalipalpata, such as musculature and coelomic cavities, which would be expected in the case of a saccocirrid relationship. Thirteen photoreceptor‐like sense organs were found in front of the brain, the only structures resembling photoreceptors in adults of P. appendiculatus. These multicellular sense organs comprise a supportive cell and several sensory cells enclosing an extracellular cavity. There are three different types of sensory cells: one rhabdomeric and two ciliary. These sensory cells are combined differently into three forms of sense organ: the most frequent uses all three types of sensory cells, the second possesses one rhabdomeric and one ciliary cell type, and the third has two types of ciliary sensory cells. Whereas similar sensory cells are frequently found in various polychaetes, their combination in one sensory organ is unique to Polygordius and is considered to represent an autapomorphy. The nuchal organs exhibit features typical of polychaetes; there are no specific features in common with Saccocirrus. Instead, the covering structures show obvious similarities to Opheliidae, as can also be found in the central nervous system. Altogether, the current observations do not contradict a relationship with opheliids but provide no evidence of a relationship with Saccocirrus as has been found in certain molecular analyses, and thus currently leave the phylogenetic position of Polygordius unresolved.     

Role of proneural genes in the formation of the larval olfactory organ of <Emphasis Type="Italic">Drosophila</Emphasis>

In this paper, we address the role of proneural genes in the formation of the dorsal organ in the Drosophila larva. This organ is an intricate compound comprising the multineuronal dome—the exclusive larval olfactory organ—and a number of mostly gustatory sensilla. We first determine the numbers of neurons and of the different types of accessory cells in the dorsal organ. From these data, we conclude that the dorsal organ derives from 14 sensory organ precursor cells. Seven of them appear to give rise to the dome, which therefore may be composed of seven fused sensilla, whereas the other precursors produce the remaining sensilla of the dorsal organ. By a loss-of-function approach, we then analyze the role of atonal, amos, and the achaete-scute complex (AS-C), which in the adult are the exclusive proneural genes required for chemosensory organ specification. We show that atonal and amos are necessary and sufficient in a complementary way for four and three of the sensory organ precursors of the dome, respectively. AS-C, on the other hand, is implicated in specifying the non-olfactory sensilla, partially in cooperation with atonal and/or amos. Similar links for these proneural genes with olfactory and gustatory function have been established in the adult fly. However, such conserved gene function is not trivial, given that adult and larval chemosensory organs are anatomically very different and that the development of adult olfactory sensilla involves cell recruitment, which is unlikely to play a role in dome formation. N. Grillenzoni and V. de Vaux contributed equally to this work.     

Structural evidence why males of Panorpa liui offer prey rather than salivary mass as their nuptial gift

Ma, N. and Hua, B. 2010. Structural evidence why males of Panorpa liui offer prey rather than salivary mass as their nuptial gift. —Acta Zoologica (Stockholm) 92 : 398–403. The scorpionflies are considered as ideal model animals for the study of mating systems in insects. The males generally offer both prey and salivary mass as nuptial gifts to the females during copulation. Our field observations show that Panorpa liui is peculiar because the males offer only prey rather than salivary secretions as nuptial gift. Through anatomical and histological examinations, the salivary glands of P. liui were found to be devoid of sexual dimorphism in Panorpa for the first time. Both the male and female P. liui bear simple salivary glands, which are only composed of a common duct and two short sac‐like glands. This is the first attempt to explore the relationship between the salivary glands and the mating tactics from the structural aspect in Panorpa, speculating that the simple structure of the male salivary glands in P. liui might be responsible for its failing to produce salivary mass as a nuptial gift during copulation. Compared with Boreidae, Meropidae, Bittacidae and Panorpidae, we presume that the absence of sexual dimorphism of the salivary glands might represent a plesiomorphy in P. liui. The origin and evolutionary process of the nuptial gift behaviour are tentatively speculated in Panorpa.     

Evolution of sensory structures in basal metazoa

Cnidaria have traditionally been viewed as the most basal animalswith complex, organ-like multicellular structures dedicatedto sensory perception. However, sponges also have a surprisingrange of the genes required for sensory and neural functionsin Bilateria. Here, we: (1) discuss "sense organ" regulatorygenes, including; sine oculis, Brain 3, and eyes absent, thatare expressed in cnidarian sense organs; (2) assess the sensoryfeatures of the planula, polyp, and medusa life-history stagesof Cnidaria; and (3) discuss physiological and molecular datathat suggest sensory and "neural" processes in sponges. We thendevelop arguments explaining the shared aspects of developmentalregulation across sense organs and between sense organs andother structures. We focus on explanations involving divergentevolution from a common ancestral condition. In Bilateria, distinctsense-organ types share components of developmental-gene regulation.These regulators are also present in basal metazoans, suggestingevolution of multiple bilaterian organs from fewer antecedentsensory structures in a metazoan ancestor. More broadly, wehypothesize that developmental genetic similarities betweensense organs and appendages may reflect descent from closelyassociated structures, or a composite organ, in the common ancestorof Cnidaria and Bilateria, and we argue that such similaritiesbetween bilaterian sense organs and kidneys may derive froma multifunctional aggregations of choanocyte-like cells in ametazoan ancestor. We hope these speculative arguments presentedhere will stimulate further discussion of these and relatedquestions.