Gametogenesis and Sporogony of Hepatozoon Mocassini (Apicomplexa: Adeleina: Hepatozoidae) In an Experimental Mosquito Host, Aedes Aegypti

ABSTRACT. The sexual life cycle of the hemogregarine Hepatozoon mocassini was studied in Aedes aegypti , an experimental mosquito host, using transmission electron microscopy. Gamonts were observed leaving the host snake erythrocyte as early as 30 min after mosquitoes ingested infected blood, and some gamonts had penetrated the gut epithelial cells by this time. Six hours post-feeding, gamonts were identified within cells of the abdominal fat body. Twenty-four hours post-feeding, gamonts were often entrapped within the peritrophic membrane, but were no longer observed within the gut wall. Parasites pairing up in syzygy and undergoing sexual differentiatioe were observed within fat cells at this time, and by 48 hours post-feeding, well-developed macro- and microgametocytes as well as microgametes were discernible. Developing zygotes observed 3 days post-feeding were enclosed within a panoitophorous vacuole. By day 6, multinucleate oocysts with crystalloid bodies in the cytoplasm were seen. Sporazoites developing within sporocysts appeared by day 12. Seventeen days post-feeding, mature oocysts with sporocysts containing approximately 16 sporozoites were observed upon dissection of mosquitoes. Large crystalloid bodies no longer bound by rough endopbsmic reticulum were located anterior and posterior to the sporozoite nucleus. Free sporozoites were not observed.     

Is bigger better? Water balance in the polymorphic desert harvester ant Messor pergandei

Abstract. Foraging activity of ants in xeric areas may be limited by desiccation stresses. To assess the extent of such stresses on a polymorphic ant species [Messor pergandei (Mayr), body mass range 1-12mg], we measured body water reserves, absolute rates of water loss, and cuticular permeability over the species' foraging temperature range (15–45C). Cuticular permeability of M. pergandei was typical of xeric arthropods (17μgcm^-2h^-1mmHg^-1). However, the effect of polymorphism on both absolute and relative rates of water loss was unexpected. Large workers lost water more slowly than small workers, even after adjusting for cuticular surface area. In addition, the body water reserves of large workers were larger, even after adjusting for body mass. Small workers of this ant species are therefore disproportionately prone to dehydration, yet, in spite of this, constitute a large and important component of the foraging force. To assess the practical relevance of desiccation to polymorphic ants, we developed a 'worst-case' model of desiccation-limited foraging parameters (time to complete loss of locomotor coordination in 5% of the foraging force). In this model, average actual foraging duration was substantially less than would be required to incapacitate the ants by dehydration. We discuss direct and indirect evidence suggesting that desiccation may, nevertheless, impose limitations on the foraging activity of ants.     

Ecteinascidia turbinata Extract Activates Components of Inflammatory Responses Throughout the Phylogenetic Spectrum

The tunicate Ecteinascidia turbinata contains a substance orsubstances capable of exerting a number of biological effects.Extracts of tunicate tissues have been shown to kill tumorcells in vitro and arrest tumor growth in vivo. The extractsalso suppress allograft rejection, graft-US.-host reactionsand lymphocyte proliferative responses as well as humoral responsesto immunization. By modifying the conditions, the extracts couldpotentiate antibody responses. In addition, they augment functionsof monocyte-macrophages as evidenced by in vitro phagocytosis,in vivo clearance, and cytotoxic activity against target cells.After studies in mice, we were able to demonstrate that theextracts could activate the phagocytic systems of shrimp, bluecrab, and fish (the American eel). In fish, the intraperitonealroute was superior to the intravenous route for promotion ofphagocytosis, increase in percent presentation of granulocytesand for enhancement of resistance to bacterial infection. Intrarriuscularand intraperitoneal injection led to local inflammation withaccumulation of granulocytes and macrophages.     

Hypoxic Quiescence in Alligatorweed

Propagules (stem cuttings) of alligatorweed [Alternanthera philoxeroides (Mart.) Griseb.] were subjected to various treatments of submergence, emergence, light, dark, and oxygen to relate hypoxia to the suppression of alligatorweed growth by dark submergence. In the dark, submergence completely inhibited alligatorweed growth. A nitrogen atmosphere inhibited growth from emersed propagules in the dark. The suspension of growth by dark submergence was relieved by light (40 μ einsteins/m²× s photo-synthetically active radiation), emergence (whereby air is transported to underwater nodes via the aerenchyma), or exposure to 100 mg · l^-1 of hydrogen peroxide solution renewed at 48-h intervals. Suspension of growth by a nitrogen atmosphere was relieved by inclusion of 16% oxygen in the ambient atmosphere. Dark to light transfers showed that the suspension of growth was immediately relieved if the requisite conditions were restored; this phenomenon, as described, thus appears to be hypoxic quiescence. The suppression of growth of two other amphibious species, mild smartweed (Polygonum hydropiperoides Michx.) and creeping water-primrose (Jussiaea repens L. var. glabrescens Ktze.), by dark submergence suggests that hypoxic quiescence may be a factor in the life history of amphibious species other than alligatorweed.     

Membrane controls of epithelial phosphate transport

Phosphate homeostasis involves efficient intestinal absorption of dietary phosphate and sensitive renal conservation of filtered phosphate. Phosphate transport occurs by similar mechanisms across the intestinal and renal epithelium. This includes secondary active uptake across the brush-border membrane, movement of phosphate across the cytosol or into the metabolic phosphate pool, and finally the passive exit from the basolateral membrane. Active transport across the brush-border membrane involves cotransport of phosphate with sodium, which moves down its electrochemical gradient. As this process is the rate-limiting step, it is thought to be the controlling event in intestinal and renal absorption. The interaction of phosphate, sodium, and hydrogen ions with the recognition proteins involved with sodium-dependent phosphate transport is complex and not fully understood. Furthermore, the lipid bilayer structure may play a significant role in controlling the sequence of events in the movement across the brush-border membrane. Transfer of phosphate through the cytosol and exit across the basolateral membrane is less well understood, although the latter transmembrane flux is thought to be carrier mediated. Intestinal phosphate absorption is determined principally by plasma calcium and phosphate concentrations (1,25(OH)2 D3) and dietary availability of phosphate (intrinsic adaptation). On the other hand, renal conservation is determined by the available calcium (PTH), phosphate (intrinsic adaptation), and acid-base balance (hydrogen ions). These controls alter sodium-dependent phosphate cotransport across the brush-border membrane of the epithelial cell. The chemical alterations of the brush-border membrane and the metabolic events leading to changes in the brush-border membrane are not understood. The use of isolated, purified membranes and innovations of current techniques will enhance our understanding of these events and allow us to explain the mechanisms controlling epithelial phosphate absorption.     

Contributions to the Life Cycle of Peneroplis planatus (Fichtel and Moll) Montfort

Direct observations of schizonts and agamonts releasing megalospheres clarified the asexual phase of the life cycle of Peneroplis planatus and made it most probable that this species has a paratrimorphic life cycle. Specimens with maximum lengths between 837 and 3,503 μm released about 500 to 1,500 megalospheric juveniles, which possessed two chambers (proloculi and flexostyles) prior to emergence from the parental shell. The presence of gamonts was not shown and was only implied by the occurrence of the agamonts. Since agamonts and schizonts have been found from December to May and since asexual reproduction occurs in spring in Elat, sexual reproduction probably occurs at another time of year (June to December). More detailed studies of this species need to be conducted throughout the year to improve our knowledge of the life cycle of this species.     

The Control of Vascular Branching in Coleus 1. The Side Bundle

Xylary branching at the proximal end of a differentiating sidebundle was modified by surgical alteration of the surroundingleaf traces and manipulation of their auxin fluxes. Incisionsthrough one corner trace, with the other pre-existing traceintact, resulting in xylem differentiation in the branch ofthe newly formed side bundle toward only the severed trace.Application of IAA to the cut trace allowed xylem branchingof the new strand in both directions. With sufficient auxinimbalance created by increasing the concentration of the appliedIAA, the new xylem strand branched away from the higher auxinsource. Auxin relations were thus able to regulate the courseof differentiation of vascular strands, but their role in regulatingbranching patterns in intact plants may be questioned. Xylembranched exclusively toward an incised trace only when the auxinflux of the incised trace was virtually eliminated. Phloem andprocambium of the differentiating strand were unaffected bythis treatment. Coleus, vascular differentiation, vascular anatomy, vascular branching, vascular patterns, auxin, auxin balance, node     

Origins of diverse feeding ecologies within Conus, a genus of venomous marine gastropods

Specialized predators on polychaetes, fishes, hemichordates or other molluscs, members of the predominantly tropical gastropod genus Conus diversified rapidly during the Miocene to constitute the most species-rich modern marine genus. We used DNA sequence data from mitochondrial and nuclear loci of 76 Conus species to generate species-level phylogenetic hypotheses for this genus and then mapped known diets onto the phylogenies to elucidate the origins and evolutionary histories of different feeding specializations. The results indicate that dramatically new feeding modes arose only a few times, that the most derived feeding modes likely arose in the Miocene, and that much of the known diversity of Conus that was generated during Miocene radiations has survived to the present.