Early beak development in Argonauta Nodosa and Octopus Vulgaris (Cephalopoda: Incirrata) paralarvae suggests adaptation to different feeding mechanisms

Morphological and morphometric development of the beak of Argonauta nodosa (oceanic species) and Octopus vulgaris (neritic species) paralarvae were analyzed in order to verify whether or not they are determined by distinct life strategies and habitats. Measurements were taken from the upper jaw (UJ) and lower jaw (LJ), compared by the t test to identify-specific differences, and correlated with mantle length (ML) by multiple linear regression to determine overall and relative influences on growth. The jaws of both species were fragile, lightly colored, presented dentition and a slit (division) in the LJ rostrum, and showed considerable variation in general aspect. The hood and lateral walls (UJ) and crest and wings (LJ) showed the highest correlation with paralarval size (ML), and were more developed in A. nodosa than in O. vulgaris of similar size. The rostrum of O. vulgaris seems to be less functional than that of A. nodosa. The presence of beak characteristics from ancestral cephalopod species in the jaws of early paralarvae, namely teeth and a slit in the LJ rostrum, and also the inability of small-sized  A. nodosa paralarvae to close the jaws and bite off a piece of prey, seem to be related to the performance of external pre-digestion and suction of body fluids of prey, a specialized feeding mode.     

Beak development of early squid paralarvae (Cephalopoda: Teuthoidea) may reflect an adaptation to a specialized feeding mode

Morphological and morphometric development of the upper jaw (UJ) and lower jaw (LJ) and arm crown of Chiroteuthis cf. veranyi, Liocranchia reinhardti (oceanic species), and Doryteuthis opalescens (neritic species) paralarvae were analyzed in order to verify whether or not they are determined by developmental modes. Jaw measurements were taken, correlated with mantle length (ML) by multiple linear regression to determine relative influences on growth, and compared between species by ANOVA to identify differences. Development was expected to be similar between oceanic species, but was morphologically similar between L. reinhardti and D. opalescens, and morphometrically similar between the latter and C. cf. veranyi. UJ and LJ measurements with highest correlation with ML are larger in L. reinhardti, indicating greater beak development in this species. Rostrum robustness is higher in L. reinhardti, intermediate in D. opalescens, and lower in C. cf. veranyi, hinting at the respective prey type. Teeth (LJ) and slit, characteristics of ancestral cephalopods, are present, disappearing completely and partially on the largest specimens of L. reinhardti and D. opalescens, respectively, and remaining in all sizes of C. cf. veranyi. The results suggest that their presence in early paralarvae reflects an adaptation to sucking the pre-digested internal fluids of prey.     

Endocardial surface and atrial morphological changes during development and aging

Light, scanning, and transmission electron microscopic observations related to morphological changes of the right atrium as well as the atrial endocardium during development (15th embryonic day and 1 day old) and aging (560 days old) in the Syrian hamster were described and correlated. From the fetus to the adult, the atrial endocardium differentiates in parallel with, or in response to, the subjacent proliferating myocytes in the atrial wall and the trabeculae. Simultaneously, the atrium compartmentalizes grossly into a main chamber and an appendicular region. There is a progressive differentiation from a rudimentary, open chamber with primitive mural ridges in the fetal atria to a distinct, separate, atrial main chamber and appendage with a dense network of trabeculae in the adult. The fetal and neonatal endocardial, endothelial cells are convex with a central nuclear bulging and attenuated cytoplasmic extensions; the adult endocardium shows a squamous endothelium. Two cell surface specializations were observed in all age groups: microvilli and blebs or cytoplasmic protrusions. The general atrial morphology and surface endocardial changes were correlated with growth and the role of the endocardial endothelium as a barrier which controls metabolic exchanges, including the transport of atrial natriuretic factor, between the myocytes and the blood. This endothelial function appears to be essential in the fetal and neonatal age groups since no blood vessels are detected in these groups.     

Distribution of common octopus and common squid paralarvae in a wind-driven upwelling area (Ria of Vigo, northwestern Spain)

The variation of paralarval abundance in a region subjectedto wind-driven upwelling (Ria of Vigo, northwestern Spain) wasstudied. Research cruises were undertaken during the favourableupwelling season (May to October) in 2000 and 2001. Each cruiseincluded biological and hydrographic sampling and consistedof five stations in waters located to the east and west of theCies Islands. A total of 221 paralarvae of Octopodidae and Loliginidaewere collected over the 12-month study period. During 2000,higher abundance of paralarvae was observed in July, Septemberand October for Loligo vulgaris and Octopus vulgaris. In 2001,abundance of both species was higher in May and also in Septemberfor O. vulgaris. The mantle length of the paralarvae variedfrom 1.25 to 2.25 mm and from 1.00 to 4.90 mm within the O.vulgaris and L. vulgaris individuals, respectively. The presence/absenceof upwelling modulates the abundance and spatial distributionof loliginid and octopod paralarvae. The relationship betweenthe distribution and movement of these paralarvae in the Riaof Vigo seems to follow the circulation system defined for thisarea; when the upwelling extends its influence inside the Ria,the paralarvae are transported to the inner part in a west—eastdirection.     

Polytene chromosomes of Oxytricha: Biochemical and morphological changes during macronuclear development in a ciliated protozoan

After conjugation in the ciliated protozoan, Oxytricha, polytene chromosomes are formed during the development of a macronucleus from a micronucleus. Here we report a microscopic study of these chromosomes and an analysis of their DNA. The polytene chromosomes of Oxytricha bear a strong morphological resemblance to the polytene chromosomes of the Dipteran salivary gland. The nucleus of a developing macronuclear anlage contains 120±2 polytene chromosomes and each chromosome has an average of 81 bands; a total of about 10,000 bands per nucleus. At a later stage in development, the number of bands per chromosome is reduced by a factor of four, presumably due to fusion of adjacent bands. The polytene chromosomes then break up into their constituent bands, each of which is encased in a vesicle. There are about 2,700 vesicles per nucleus. — During the growth of polytene chromosomes, there is a change in the relative proportion of sequences in the DNA. The DNA from polytene nuclei has a buoyant density of 1.695 g/cc, significantly lighter than the density of the original micronuclear DNA (1.698 g/cc to 1.702 g/cc). We interpret this buoyant density change to be the result of differential replication of DNA sequences during polytene chromosome growth. A second change in DNA composition occurs after the polytene stage of development, shown by a shift in buoyant density to 1.701 g/cc in the DNA of the mature macronucleus. During this second process, the molecular weight of the DNA is reduced from greater than 50×10⁶ daltons to about 2×10⁶ daltons.This paper is No. VI in the series, DNA of Ciliated Protozoa.     

Functional design of tentacles in squid: linking sarcomere ultrastructure to gross morphological dynamics

This paper offers a quantitative analysis of tentacle extension in squid that integrates several levels of structural organization. The muscular stalks of the two tentacles of squid are rapidly elongated by 70 per cent of resting length during prey capture. A typical duration of the extension is 30 ms in Loligo pealei (with a contracted tentacle length of 93 mm and a strike distance of about 37 mm). In a successful strike, the terminal clubs hit the prey and attach to it via arrays of suckers.A forward dynamics model is proposed for the extension of the tentacular stalk and the forward motion of the terminal club. The stalk is modelled as a longitudinal array of thin muscular discs with extensor muscle fibres oriented parallel to the disc planes. As a disc contracts radially, it lengthens because its volume is constant. The equations of motion for the linked system of discs were formulated and solved numerically. The inputs of the model are the dimensions of the tentacle, passive and active muscle properties such as Hill''s force–velocity relationship, myofilament lengths and activation of the muscle fibres. The model predicts the changing geometry of the tentacle, the pressure and stress distribution inside the tentacle and the velocity and kinetic energy distribution of the stalk and club. These predictions are in agreement with kinematic observations from high-speed films of prey capture. The model demonstrates also that the unusually short myosin filaments (reported range 0.5–0.9 micrometre) that characterize the extensor muscles are necessary for the observed extension performance. Myosin filament lengths typical for vertebrate sarcomeres (1.58 micrometre) would lead to a significant reduction in performance. In addition, the model predicts that, to maximize peak velocity of the terminal club, the myosin filaments should be longer at the base and shorter at the tip of the stalk (0.97 micrometre at the base and 0.50 micrometre at the tip for the tentacle size above). This results from differences in dynamic loading along the stalk. Finally, the model allows exploration of the effects of changes in the dimensions and mass of the tentacle and intrinsic speed of the myofilaments on the optimum myosin filament lengths.     

Limb,tooth, beak: Three modes of development and evolutionary innovation of form

The standard model of evolutionary change of form, deriving from Darwin’s theory via the Modern Synthesis, assumes a gradualistic reshaping of anatomical structures, with major changes only occurring by many cycles of natural selection for marginal adaptive advantage. This model, with its assertion that a single mechanism underlies both micro- and macroevolutionary change, contains an implicit notion of development which is only applicable in some cases. Here we compare the embryological processes that shape the vertebrate limb bud, the mammalian tooth and the avian beak. The implied notion of development in the standard evolutionary picture is met only in the case of the vertebrate limb, a single-primordium organ with morphostatic shaping, in which cells rearrange in response to signalling centres which are essentially unchanged by cell movement. In the case of the tooth, a single-primordium organ with morphodynamic shaping in which the strengths and relationships between signalling centres is influenced by the cell and tissue movements they induce, and the beak, in which the final form is influenced by the collision and rearrangement of multiple tissue primordia, abrupt appearance of qualitatively different forms (i.e. morphological novelties) can occur with small changes in system parameters induced by a genetic change, or by an environmental factor whose effects can be subsequently canalized genetically. Bringing developmental mechanisms and, specifically, the material properties of tissues as excitable media into the evolutionary picture, demonstrates that gradualistic change for incremental adaptive advantage is only one of the possible modes of morphological evolution.     

Induction of tetraploidy in garden cress: morphological and cytological changes

Plant Cell, Tissue and Organ Culture (PCTOC) - Garden cress (Lepidium sativum L., Brassicaceae) is one of the most popular leafy vegetables which is widely used, and has also various medicinal...     

Biochemical and morphological changes accompanying light organ development in the firefly, Photuris pennsylvanica

The larval light organs of the firefly, Photuris pennsylvanica, regress and are replaced by the adult lantern during metamorphosis. Larval and adult light organs are present and capable of periodic light emission during the latter stages of pupation and the early adult. The whole pupa emits a continuous, low level, glow throughout pupation.During pupation levels of luciferase and luciferin, the enzyme and substrate required in the light reaction, were found to remain constant in the posterior half of the pupa and to show an initial increase followed by a decrease in the anterior half. Levels of luciferase and luciferin in anterior halves were not affected by ablation of the larval light organs. The ratio of luciferase to luciferin concentrations changed from less than 1, in larval and pupal stages, to greater than 1, in the adult. Changes in the concentration and the localization of luciferase and luciferin were correlated with observed light organ development.     

Physiological and morphological changes in autolyzingAspergillus nidulans cultures

Physiological and morphological changes in carbon-limited autolyzing cultures of Aspergillus nidulans were described. The carbon starvation arrested conidiation while the formation of filamentous and "yeast-like" hyphal fragments with profoundly altered metabolism enabled the fungus to survive the nutritional stress. The morphological and physiological stress responses, which maintained the cellular integrity of surviving hyphal fragments at the expense of autolyzing cells, were highly concerted and regulated. Moreover, sublethal concentrations of the protein synthesis inhibitor cycloheximide or the mitochondrial uncoupler 2,4-dinitrophenol completely blocked the autolysis. In accordance with the propositions of the free-radical theory of ageing reactive oxygen species accumulated in the surviving fragments with a concomitant increase in the specific superoxide dismutase activity and a continuous decrease in cell viability. Glutathione was degraded extensively in carbon-starving cells due to the action of gamma-glutamyltranspeptidase, which resulted in a glutathione-glutathione disulfide redox imbalance during autolysis.     

Effect of flooding on tomato cultivars: The relationship between proline accumulation and other morphological and physiological changes

Flooding of the root system of tomato plants ( Lycopersicon esculentum ) caused cessation of leaf elongation, leaf epinasty, formation of adventitious roots, and increase in diffusive resistance associated with the wilting of leaves at the first stage of the stress. Upon development of adventitious roots, the wilted leaves regained their turgor and the diffusive resistance slowly decreased at a rate slower than that at which water potential increased. In the course of flooding, proline accumulated but after 11 days dropped back to the control level. The extent of proline accumulation in various tomato cultivars was positively correlated with the extent to which their leaf water potential dropped, but was not correlated with the changes in their diffusive resistance. Cultivars which accumulated the highest proline levels were those which showed the most severe injury, with only one cultivar as an exception. However, only in the cultivars producing high levels of proline was the return of leaf turgor followed by resumption of leaf elongation. In cv. 'Hosen', which was severely injured by the stress, but accumulated a low level of proline, leaf elongation was not resumed. The results suggest that proline accumulation is an indicator of the cultivar's sensitivity to dehydration associated with the flooding stress, and confirm the notion that proline may play a role in the post-stress recovery process.     

Sex reversal in pairs of Lythrypnus dalli: behavioral and morphological changes

In Lythrypnus dalli, the bluebanded goby, reproductive success is primarily determined by functional sex, and functional sex is determined largely by rank in the dominance hierarchy. In most natural social groups of L. dalli, one male is at the apex of the hierarchy, and 1 to 7 females are lower in rank. When a male exits the group, a female ascends to the top of the hierarchy and becomes a male. We have examined this process in a simplified environment--a pair of females--that allows us to identify behavior associated with the formation of a dominance relationship and any other phenotypic changes associated with dominance, sex change or both. We found that pairs of L. dalli females quickly and readily form stable dominance relationships, with the dominant fish changing sex into a male. This dominant animal also rapidly increases in body size and length of its dorsal fin. In summary, dominant L. dalli females change sex in this simplified environment, providing excellent opportunities to examine the early behavioral and morphological changes associated with dominance and sex change.     

Ontogeny of squid mantle function: changes in the mechanics of escape-jet locomotion in the oval squid,Sepioteuthis lessoniana lesson, 1830

In Sepioteuthis lessoniana, the oval squid, ontogenetic changes in the kinematics of the mantle during escape-jet locomotion imply a decline in the relative mass flux of the escape jet and may affect the peak weight-specific thrust of the escape jet. To examine the relationship between ontogenetic changes in the kinematics of the mantle and the thrust generated during the escape jet, we simultaneously measured the peak thrust and the kinematics of the mantle of squid tethered to a force transducer. We tested an ontogenetic series of S. lessoniana that ranged in size from 5 to 40 mm dorsal mantle length (DML). In newly hatched squids, thrust peaked 40 ms after the start of the escape jet and reached a maximum of between 0.10 mN and 0.80 mN. In the largest animals, thrust peaked 70 ms after the start of the escape jet and reached a maximum of between 18 mN and 110 mN. Peak thrust was normalized by the wet weight of the squid and also by the cross-sectional area of the circumferential muscle that provides power for the escape jet. The weight-specific peak thrust of the escape jet averaged 0.36 in newly hatched squid and increased significantly to an average of 1.5 in the largest squids measured (P < 0.01). The thrust per unit area of circumferential muscle averaged 0.25 mN/mm(2) in hatchlings and increased significantly to an average of 1.4 mN/mm(2) in the largest animals tested (P < 0.01). The impulse of the escape jet was also lowest in newly hatched individuals (1.3 mN. s) and increased significantly to 1000 mN. s in the largest squids measured (P < 0.01). These ontogenetic changes in the mechanics of the escape jet suggest (1) that propulsion efficiency of the exhalant phase of the jet is highest in hatchlings, and (2) that the mechanics of the circumferential muscles of the mantle change during growth.     

Muscle development in squid: Ultrastructural differentiation of a specialized muscle fiber type

The ultrastructural differentiation of two muscle fiber types of the squid Sepioteuthis lessoniana was correlated with development of prey-capture behavior. Transmission electron microscopy was used to document the differentiation of the fast-contracting cross-striated muscle cells of the tentacles and the obliquely striated muscle cells of the arms of specimens sampled at one week intervals from hatching to 5 weeks. By using high-speed video recordings, the ultrastructural differentiation was correlated with changes in prey-capture behavior that occur during development and growth. The ultrastructural analysis focused on the muscle cells of the transverse muscle of the tentacles and the transverse muscle of the arms. For the first 2 weeks after hatching, the tentacle transverse muscle fibers do not show the adult ultrastructure and are indistinguishable from the obliquely striated fibers of the transverse muscle of the arms. Transverse striation of the tentacle muscle cells appears at approximately three weeks and adult ultrastructure is present by 4–5 weeks after hatching. The high-speed video recordings show correlated behavioral changes. During the first 2–3 weeks after hatching, the animals use a different prey-capture mode from the adults; they jet forward and capture the prey with splayed arms and tentacles rather than employing the rapid tentacular strike. © 1996 Wiley-Liss, Inc.     

Aggregata andresi n. sp. (Apicomplexa: Aggregatidae) from the ommastrephid squid Martialia hyadesi in the SW Atlantic Ocean and some general remarks on Aggregata spp. in cephalopod hosts

A new species of coccidian, Aggregata andresi, is described from the digestive tract of the flying squid Martialia hyadesi, an ommastrephid squid that lives in cold subantarctic waters in the Southwest Atlantic. Gamogonic and sporogonic stages were observed in the digestive tract of 96.5% studied hosts. Oöcysts were ovoid to subspheroid in shape, 170–590 µm in length and 200–530 µm in width. Each oöcyst contained approximately 45,000 sporocysts. Sporocysts measured 9.5–10 µm in length and 8–8.5 µm in width. The surface of the sporocyst wall was smooth and the cyst wall thick. Each sporocyst contained three sporozoites measuring 16–20 µm in length and 2–2.5 µm width. A. andresi is the second species of Aggregata to be reported from a nerito-oceanic cephalopod host.     

DNA fragmentation and morphological changes in apoptotic human lymphocytes

Cell suspensions enriched in cells at various stages of apoptosis were obtained by separation of irradiated human peripheral blood lymphocytes on density gradients at different post-irradiation times. The state of DNA fragmentation in the cells was determined by comet assay and pulsed field gel electrophoresis. The morphologically distinguishable features of apoptosis such as chromatin condensation and cell shrinkage correlated with discrete stages of DNA fragmentation. It was found that >/=50 kbp fragmentation of DNA occurs already in cells of normal density whereas the subsequent DNA fragmentation onto fragments <50 kbp occurs in parallel with cell shrinkage and simultaneous increase in cell density.The observed stages of DNA fragmentation seem to be separated in time that could allow in case of abortive apoptosis formation of chromosomal aberrations.