Trois Especes Nouvelles d'Ophryoglenes: O. gelifera n. sp., O. mucosa n. sp., O. multimicronucleata n. sp. (Cilies Holotriches Peniculiens)

SYNOPSIS. A previous study with P. de Puytorac on O. bacterocaryon(3) has shown the methods of studying this Ciliate and has specified the general and buccal morphology, the morphogenesis, and the biology of vegetative individuals (theront, trophont, tomont, tomites) of this species. Three species we are describing now offer numerous common features with O. bacterocaryon. We consider them as the proper characters of genus Ophryoglena and we only insist on the specific particularities of O. gelifera, O. mucosa and O. multimicronucleata. O. gelifera is a large Ophryoglene differing from the others by a slightly asymetric, curved, spindle-shaped theront; the ellipsoidal tomont secretes abundant and clear jelly. The theront possesses one thick spindle-shaped macronucleus, one voluminous spherical micronucleus, fitting with the macronucleus. Its somatic infraciliature is dense, its buccal infraciliature is characteristic, especially in the shape of peniculus P1. This species cannot be mistaken for O. pectans Mugard(2) although it is rather near it. O. mucosa is a very small Ophryoglene. The theront has one thick elliptical macronucleus, one small micronucleus; the buccal orifice is not kidney-shaped, but quite pointed in front; there is no tragus; the somatic infraciliature is not close; the peniculus P1 is characteristic. The tomont is ellipsoidal and surrounded by a thick mucous gangue. The tomites are not close together. O. mucosa is very different from O. gelifera and O. pectans Mugard(2). O. multimicronucleata. Near to O. polymicrocaryon Mugard(2), this Ophryoglene differs from it by the small size of all its vegetative elements and especially by its nuclear-apparatus. The latter includes numerous (5 to 6) bulky spherical micronuclei and one macronucleus looking like blackpudding which can be compared to that of O. singularis Canella and Trinchas(1). The theront is spindle-shaped and of a dark-grey colour. The spherical tomont secretes a mucous gangue which is not very thick. Besides, the somatic infraciliature and buccal in fraciliature of the theront (peniculus P1 especially) make O. multi micronucleata quite distinct from O. polymicrocaryon Mugard(2).     

Genetic evidence for `leaky' cohorts in the semivoltine stonefly Peltoperla tarteri (Plecoptera: Peltoperlidae)

1. Genetic techniques are being used increasingly to address questions about dispersal and gene flow of freshwater invertebrates. However, population genetic structure can be affected by factors other than dispersal. Many stream insects have long life cycles that result in the simultaneous existence of multiple cohorts throughout the larval development period. If larval development is fixed, successive cohorts may be reproductively isolated and, as a result, genetically distinct. In such cases, significant levels of genetic differentiation between cohorts could confound estimates of dispersal based on population genetic structure.
2.  Peltoperla tarteri is a stonefly that can be abundant in Appalachian headwater streams. Although P. tarteri is univoltine at the type locality (Big Paint Hollow, WV, U.S.A.), the study populations in southwestern Virginia, U.S.A., were semivoltine. This semivoltine life cycle results in the simultaneous existence of multiple cohorts with the potential for significant genetic differentiation among them.
3. Levels of genetic differentiation among P. tarteri cohorts were analysed with mitochondrial DNA (mtDNA) sequence data from the non-coding origin of replication or `control' region from 93 individuals from two successive cohorts (collected in 1998 and 1999).
4. Analysis of molecular variance ( AMOVA ) indicated no genetic differentiation among cohorts ( F _ST=0.0), and gene flow among cohorts was very high ( Nm =∞).
5. High levels of gene flow among cohorts suggest that larval development of P. tarteri is not fixed. Gene flow among cohorts most likely occurs as a result of a cohort split in which some individuals complete development in one or three years instead of two.     

Conversion of Intrasporal Trehalose into Reducing Sugars During Germination of Nosema algerae (Protista: Microspora) Spores: A Quantitative Study

ABSTRACT. Carbohydrates were extracted from dormant, stimulated and germinated spores of Nosema algerae . Concentrations of total sugars were measured by the Anthrone test. Non-reducing sugars were quantified by NaOH hydrolysis followed by the Anthrone reaction, and reducing sugars by the Nelson's test. Glucose was measured by the o -toluidine test and a glucose oxidase assay. The concentrations of trehalose in the cytoplasm of the dormant, ungerminated spore was estimated to be in excess of 1.0 M. Trehalose decreased by 70% during the five-minute course of germination. All of the lost trehalose was converted to reducing sugar of which 70–78% was glucose. The osmotic potential increase caused by catabolism of trehalose appears to be sufficient for germination.     

Structural Alteration of the Plasma Membrane in Spores of the Microsporidium Nosema algerae on Germination1

The fine structure of the plasma membrane in spores of the microsporidium Nosema algerae, a pathogen of mosquitoes, was examined in the resting condition and after the spores were stimulated to germinate in vitro. Slow penetration of resin caused collapse of the germinated spores. Thin sections of germinated spores showed peculiar membrane infoldings that were never found in ungerminated samples. Analogous germination-dependent configurations of the plasma membrane were observed in freeze-fractured preparations of spores either fixed and impregnated with glycerol prior to freezing, or rapidly frozen with liquid propane while in the process of germination. In every case, the replicas presented germinated spores with indentations in the protoplasmic face of the plasma membrane, and apparently complementary blunt spines on the external face, that were absent in ungerminated spores. It suggests that these alterations of the plasma membrane result from a structural adjustment to a spontaneous contraction of the spore case after germination. We discuss this interpretation with regard to conflicting views on the nature of such morphological features.