How do bees learn and recognize visual patterns?

The basic task of perceptual systems is the recognition and localization of objects. The central nervous system has to solve these problems on the basis of the excitation patterns of sensory nerves, in spite of the fact that these provide only ambiguous information about objects. Two processing principles seem to be fundamental for an efficient formation of object representations: the extraction of characteristic features and the ability to assess similarities between different objects. This article reviews investigations in which different training paradigms were applied in order to explore the honeybee's capacities to learn and recognize visual patterns. One aim of these experiments is to assess whether insects use similar processing mechanisms as vertebrates, for instance human beings. By comparing the computational performance of perceptual systems in animals with different evolutionary history we can hope to learn more about the operation of basic rules in nervous systems. “The messages which the brain receives have not the least similarity with the stimuli. They consist in pulses of given intensities and frequencies, characteristic for the transmitting nerve-fiber, which ends at a definite place of the cortex. ... From this information it produces the image of the world by a process which can metaphorically be called a consummate piece of combinatorial mathematics: it sorts out of the maze of indifferent and varying signals, invariant shapes and relations which form the world of ordinary experience.” Max Born (1949) Received: 4 October 1997 / Accepted in revised form: 26 August 1998     

Expression of liver phenotypes in cultured mouse hepatoma cells: synthesis and secretion of serum albumin

A permanent cell line, designated Hepa, has been isolated from a mouse hepatoma, BW 7756. The cell line synthesizes and secretes albumin at rates appreciably higher than previously reported hepatomas adapted to in vitro conditions. Monospecific antimouse serum albumin was produced in rabbits, and mouse serum albumin secreted by the hepatoma cells was identified by double diffusion, immunoelectrophoresis, and radioimmunodiffusion. A quantitative immunoassay was used to measure albumin secretion and to study the effects of culture conditions on albumin secretion. A subclonal analysis was performed to study the homogeneity and stability of cloned hepatoma lines in respect to albumin secretion. Different secretion rates were observed during the culture cycle. Significant clonal variation in respect to albumin secretion was found among ten subclones.The significance of clonal variation is discussed in relation to the study of epigenetic control of albumin expression in somatic hybrid cells.     

Localization of beta-glycerophosphatase and Mg++-activated adenosine triphosphatase in a moss haustorium,and the relation of these enzymes to the cell wall labyrinth

Summary Acid phosphatase and ATPase were localized in the bryophyte haustorium and in the surrounding paternal tissue of the gametophyte. Only cells with wall labyrinths are the sites of intense enzyme activity.The reaction products of both enzymes were found to occur in cell organelles, the plasma membrane and particularly in wall inclusions that are supposedly proteinaceous in nature.The intensity of the reaction is proportional to the state of differentiation of the labyrinth. The highest enzyme activity was encountered in the epidermal cells which are furnished with the most elaborate wall labyrinths. Somewhat lower was the activity in the other labyrinth cells with filiform ingrowths.These findings stress the role of the epidermis as an absorptive epithelium, and also show clearly that the enzyme activity associated with the plasma surface is in no reciprocal ratio to the degree of amplification of the surface area.     

UeberPsittacella Brehmii undmodesta Rosenb

Ohne Zusammenfassung     

Eine Beobachtung über die Wanderung vonArenicola marina L. (Polychaeta sedentaria)

Zusammenfassung Am 7. 1. 1954 wurden am Südstrand des Ellenbogens bei List a. Sylt in einem hochgelegenen Strandgürtel zahlreiche lebendeArenicola angetroffen, die hier durch das Morgenhochwasser angespült waren. Der Fund ist allem Anschein nach damit zu erklären, daß dieArenicola-Besiedlung der hochgelegenen Wattflächen, die meist aus kleineren und mittelgroßen Tieren besteht, auf der Wanderung nach tieferen Wohnplätzen begriffen war. Die unmittelbare Ursache waren der plötzliche Temperaturabfall und der durch Ostwindwetterlage abgesunkene Wasserstand des Januaranfangs. Es wird vermutet, daß die beschriebene Erscheinung Ausdruck eines regelmäßigen Verhaltens ist, das sich normalerweise über einen längeren Zeitraum bei Eintritt der kalten Jahreszeit erstreckt, das sich aber 1953/54 wegen des ungewöhnlich milden Wetters verzögert hat und erst Anfang Januar durch die schnell sinkenden Temperaturen ausgelöst wurde.(Mit 1 Abbildung und 2 Tabellen im Text)     

Anatomie und biologie des diplopoden strongylosoma pallipes oliv.

Ohne Zusammenfassung     

Collective Cell Migration in Embryogenesis Follows the Laws of Wetting

Collective cell migration is a fundamental process during embryogenesis and its initial occurrence, called epiboly, is an excellent in vivo model to study the physical processes involved in collective cell movements that are key to understanding organ formation, cancer invasion, and wound healing. In zebrafish, epiboly starts with a cluster of cells at one pole of the spherical embryo. These cells are actively spreading in a continuous movement toward its other pole until they fully cover the yolk. Inspired by the physics of wetting, we determine the contact angle between the cells and the yolk during epiboly. By choosing a wetting approach, the relevant scale for this investigation is the tissue level, which is in contrast to other recent work. Similar to the case of a liquid drop on a surface, one observes three interfaces that carry mechanical tension. Assuming that interfacial force balance holds during the quasi-static spreading process, we employ the physics of wetting to predict the temporal change of the contact angle. Although the experimental values vary dramatically, the model allows us to rescale all measured contact-angle dynamics onto a single master curve explaining the collective cell movement. Thus, we describe the fundamental and complex developmental mechanism at the onset of embryogenesis by only three main parameters: the offset tension strength, α, that gives the strength of interfacial tension compared to other force-generating mechanisms; the tension ratio, δ, between the different interfaces; and the rate of tension variation, λ, which determines the timescale of the whole process.     

LiDAR‐derived canopy structure supports the more‐individuals hypothesis for arthropod diversity in temperate forests

Despite considerable progress in the ability to measure the complex 3‐D structure of forests with the improvement of remote‐sensing techniques, our mechanistic understanding of how biodiversity is linked to canopy structure is still limited. Here we tested whether the increase in arthropod abundance and richness in beech forest canopies with increasing canopy complexity supports the more‐individuals hypothesis or the habitat‐heterogeneity hypothesis. We used fogging to collect arthropod samples from 80 standardized plots from canopies of single‐ to multi‐layered mature montane European beech stands. Tree height and an independent measure of vertical heterogeneity – the vertical distribution ratio – on each arthropod sampling plot were derived from high‐resolution full‐waveform airborne laser scanning data. Mixed‐model path analysis based on almost 20 000 specimens of 762 species from 11 orders provided support for the more‐individuals hypothesis, with higher arthropod abundance but not higher species richness in stands with a more equal vertical distribution of plant biomass. By contrast, we found no support for the habitat‐heterogeneity hypothesis. The increase in the number of individuals with increasing vertical distribution of biomass might be caused either by increasing leaf area, as indicated by higher space filling and productivity in multi‐layered stands, or by higher persistence of arthropod populations owing to better shelter, reduced competition and more refuges under harsh conditions, or by both. High‐resolution airborne laser scanning, with its ability to penetrate dense canopies under leaf‐on conditions, has proved suitable for measuring vertical structures as a predictor for canopy diversity. Expanding combinations of remote‐sensing and canopy‐biodiversity data opens many avenues for improving our understanding of the link between diversity and forest structures.