Dynamics of the cytoskeleton in Amoeba proteus

Fluorescein-labeled muscle actin was microinjected into Amoeba proteus and followed during intracellular redistribution by means of the image-intensification technique. The fully polymerization-competent protein becomes part of the endogenous actomyosin system undergoing dynamic changes over time periods of several hours. Single-frame analysis of long-term sequences enabled the direct demonstration of both the contractile activities and morphological transformations of microfilaments in normally locomoting, immobilized and phagocytozing specimens. In normally locomoting cells the filament layer undergoes continuous changes in spatial distribution depending on the actual pattern of cytoplasmic streaming and cell shape. The highest degree of differentiation is always maintained in the intermediate region between the front and the uroid, thus indicating this segment of the cortex to be the most important site in generating motive force for pseudopodium formation and ameboid movement. In immobilized cells contracted by the application of ruthenium red or relaxed by different anesthetics, the filament layer forms a continuous thick sheath beneath the cell surface or becomes completely disintegrated. In phagocytozing cells the local polymerization of actin at the tip of pseudopodia forming the food-cup and around the nascent phagosome points to a significant participation of the actomyosin system in the process of capturing and constricting prey organisms. Although our results provide clear evidence for the overall importance of motive force generation according to the hydraulic pressure theory, some motile phenomena exist in Amoeba proteus that cannot exclusively be explained by this mechanism.     

Echoortung bei der Fledermaus Chilonycteris rubiginosa

Zusammenfassung Chilonycteris rubiginosa erzeugt in allen Orientierungsituationen dreiteilige Ortungslaute. Im Anfangsteil steigt die Frequenz um etwa 1–2 kHz an. Der folgende Mittelteil hat eine konstante Frequenz von etwa 57 bis 57,6 kHz. Im Endteil fällt die Frequenz um etwa 8 kHz ab. Die Laute werden in Folgen von Lautgruppen ausgesendet.CR erzeugt pro Flügelschlag eine Lautgruppe. Im freien Flug zeigt CR Gruppen mit 2 Lauten von etwa 17–23 msec Dauer. Landende Fledermäuse senden in der Annäherungsphase Gruppen mit einer zunehmenden Zahl immer kürzerer Laute und in der Schlußphase eine längere Gruppe mit vielen kurzen Lauten.Fliegende Tiere senken die Frequenz des konstantfrequenten Mittelteils immer um etwa den Betrag der durch die Fluggeschwindigkeit bedingten Dopplereffekte ab, so daß die von den Tieren gehörte Echofrequenz nahezu konstant in Höhe der vor dem Flug ausgesendeten Frequenz gehalten wird.CR zeigt Kopf- und Ohrbewegungen. Die Ohrbewegungen stehen in Beziehung zur Lautaussendung.

---

Echolocation by the bat Chilonycteris rubiginosa

Summary Chilonycteris rubiginosa (CR) produces tripartite ultrasonic sounds in all orientation situations. During the first part the frequency rises by 1–2 kHz. The following middle part has a constant frequency of about 57–57,6 kHz. In the terminal part the frequency decreases by about 8 kHz. The sounds are emitted as a sequence of groups of sounds.In flight they produce per wingbeat one group of sounds at a repetition rate of 10–11 Hz. In free flight CR emits groups of 2 sounds of about 17–23 msec duration. During the approach landing bats emit groups consisting of an increasing number of sounds of decreasing duration. During the terminal phase the group is longer in duration and consists of many short sounds.Flying CR lower the frequency of the middle part by an amount which compensates for Doppler shifts caused by the flight velocity. The frequency heard by the bats is, thus, always kept constant and equal to a frequency which is about 100–150 Hz above the medium frequency emitted before the flight. CR shows head and ear movements. The ear movements are correlated to the sound emission.

     

Regeneration from intact and sectioned immature embryos of barley (Hordeum vulgare L.): the scutellum exhibits an apico-basal gradient of embryogenic capacity

Immature zygotic embryos from spring barley cv. Dissa were used to induce somatic embryogenenesis. Up to 158 germinated somatic embryos could be recovered per plated zygotic embryo. Critical factors for obtaining a high yield of regenerants were the size of the explant, the level of 2,4-D used for callus induction and the careful division of callus at each subculture. Use of microsections of immature embryos as explants revealed a pronounced gradient of callus formation and embryogenic response across the scutellum. Sections from the scutellar tissue at the coleoptilar end of the embryo gave the most callus and were highly embryogenic. The regeneration response of sectioned explants was comparable to that recovered from intact embryos of similar size.     

The role of vanadium in green plants

Cells of Chlorella pyrenoidosa, derived from vanadium free agar slants, respond with great sensitivity to microamounts of vanadium, added as NH₄VO₃ to autotrophic liquid cultures. Between 0.01 and 1 g V per litre nutrient medium (2·10^-10-2·10^-8g-at/l), the algae respond with a continuous increase in dry weight. At higher V-concentrations, further enhancement in biomass is accompanied by a additional increase in chlorophyll content. Maximum V-effect on both parameters was found to be at 500g V/l (10^-5 g-at/l). Dry weight as well as chlorophyll content of Chlorella are decreased by concentrations above 25 mg V/l; 100 mg V/l (2·10^-3 g-at/l) stop growth and cause death of the cells. The toxic threshold for the V-content in the algae was determined to be at 150–200 g V/g (3–4·10^-6 g-at/g) dry weight.Two different pH-optima for a positive vanadium action on dry weight and chlorophyll biosynthesis were established, the first at pH 7, the other in the range pH 7.5–8. Two sites of vanadium action in green algae are discussed.Part I: Arch. Microbiol. 105, 77–82 (1975)     

Fledermäuse im Windkanal

Zusammenfassung In einem Windkanal wurde für eine Myotis lucifugus die Abhängigkeit der Fluggeschwindigkeit (v_F) und der Geschwindigkeit über Grund (v_G) von der Windgeschwindigkeit (v_W) bestimmt. Die Fledermaus flog bei Windstille mit einer mittleren v_F von etwa 4,5 m/sec. Bei zunehmenden Gegenwinden erhöhte sie v_F und verringerte v_G, um bei v_W=7,7 m/sec für kurze Zeit stationären Flug (v_G=0) zu erreichen. Die Flügelschlagfrequenz lag bei Gegenwinden von 0–7,7 m/sec zwischen 10–11/sec. Bei zunehmenden Rückenwinden wurde der Flug immer mehr dem Rüttelflug ähnlich und die Flügelschlagfrequenz stieg bis 16/sec an. Die v_G blieb nahezu konstant in einem Bereich zwischen 4,5–5 m/sec. Bei Myotis lucifugus, Chilonycteris rubiginosa, Carollia perspillicata und Rhinolophus ferrum-equinum wurde die Flügelstellung während der Lautaussendung ermittelt. Alle Arten erzeugten entweder einen Einzellaut oder eine Gruppe von Lauten pro Flügelschlag.

---

Bats in the wind tunnel

Summary In an experimental wind tunnel air speed (v_F) and ground speed (v_G) of a Myotis lucifugus were measured as a function of wind speed (v_W). The bat had a v_F of about 4,5 m/sec in still air. With head winds it increased v_F and lowered v_G to reach stationary flight (v_G=0) at a v_W of 7,7 m/sec. The rate of wing motion remained at about 10–11/sec at head winds from 0–7,7 m/sec. With tail winds the bat changed to a semi-hovering flight with wing beat frequencies rising to about 16/sec and v_F dropping to almost zero at 4–5 m/sec tailwinds. The v_G remained nearly constant between about 4,5–5 m/sec. (Figs. 2 and 3). The wing positions during which orientation sounds were emitted were determined for Myotis lucifugus (Fig. 4), Chilonycteris rubiginosa, Carollia perspillicata and Rhinolophus ferrum-equinum (Fig. 5). All bats emitted either one single sound or a group of sounds per wing beat.