Proceedings of the Royal Society of London Series B-Containing Papers of Abiological Character最新文献

Some computational theories of motion perception assume that the first stage en route to this perception is the local estimate of image velocity. However, this assumption is not supported by data from the primary visual cortex. Its motion sensitive cells are not selective to velocity, but rather are directionally selective and tuned to spatio-temporal frequencies. Accordingly, physiologically based theories start with filters selective to oriented spatio-temporal frequencies. This paper shows that computational and physiological theories do not necessarily conflict, because such filters may, as a population, compute velocity locally. To prove this point, we show how to combine the outputs of a class of frequency tuned filters to detect local image velocity. Furthermore, we show that the combination of filters may simulate 'Pattern' cells in the middle temporal area (MT), whereas each filter simulates primary visual cortex cells. These simulations include three properties of the primary cortex. First, the spatio-temporal frequency tuning curves of the individual filters display approximate space-time separability. Secondly, their direction-of-motion tuning curves depend on the distribution of orientations of the components of the Fourier decomposition and speed of the stimulus. Thirdly, the filters show facilitation and suppression for responses to apparent motions in the preferred and null directions, respectively. It is suggested that the MT's role is not to solve the aperture problem, but to estimate velocities from primary cortex information. The spatial integration that accounts for motion coherence may be postponed to a later cortical stage.

The hallmark of the antibody response to antigenic challenge is its remarkable specificity. In his Croonian Lecture in 1905, Ehrlich recognized it as a biological puzzle, but considered it inconceivable that animals could produce substances capable of specific recognition of toxins that the species had never encountered before. It took the largest part of the following 70 years to begin to understand the chemical base of the biological puzzle. Even more recently, the genetic base of the underlying events has been clarified. Unique genetic rearrangements of the DNA initiate the biological diversity of somatic cells; this provides an initial source of antigen recognition. The remarkable specificity is the result of an antigen-driven Darwinian selection of proliferating clones, operating on further diversity that is generated by a high rate of point mutations in specific genes. Although the complexity of the biological events underlying the process remain largely unknown, the knowledge gained so far provides insights into alternative approaches to the production of new antibodies.

Simple stimulus patterns, in this case visual, are represented by spatiotemporal Boolean functions that can be summarized in a 4 x 4 look-up table of 16 templates behind each sensory neuron. These groups of templates correspond to groups of neurons in columns behind each receptor. They abstract specific combinations of input in simple combinations and include two successive states in time. A template is like a neuron field at threshold, and responds as the field is convolved with the stimulus pattern. The same structure can be repeated in successive layers to make progressive categorization and to reject inappropriate combinations. At any level, the templates act in groups, so providing a very large number of combinations that can represent more complex stimulus patterns at deeper levels.

Two types of bipolar cell in the Geoclemys reevesii retina were studied quantitatively by means of specific cell labelling with an indoleamine derivative (5,6-dihydroxytryptamine, 5,6-DHT), a nucleic acid stain (4,6-diamidino-2-phenylindole, DAPI) and Lucifer yellow CH. Indoleamine-accumulating (IA) bipolar cells were selectively labelled with 5,6-DHT applied intraocularly. After the cells accumulated 5,6-DHT, the indoleamine fluorescence was photoconverted to diaminobenzidine products to allow observation of morphological details. Close examination of many cells (cell number; n = 120) showed that the IA bipolar cells consist of a single morphological type whose axon collaterals ramify sublaminae 1, 4 and 5 respectively. This terminal branching pattern corresponds to cells that hyperpolarize when their receptive field centres are illuminated (Weiler 1981). The density of IA bipolar cells was highest in the visual streak (4130 cells mm-2) and lowest at the peripheral margin (1970 cells mm-2). By applying a small amount of DAPI to the eye, nuclei located in the most proximal row of the outer nuclear layer were labelled selectively. By using selective intracellular dye injection into DAPI-labelled cells under fluorescence microscope (Tauchi & Masland 1984, 1985), these cells were found to have Landolt's clubs and single descending axons. Dye injections into more than fifty DAPI-labelled somata showed that they belonged exclusively to displaced bipolar cells. These comprised at least two subtypes that differ in the ramification pattern of their axon terminals within the inner plexiform layer: one was monostratified, whereas the other was bistratified. The displaced bipolar cell density was as high as 9400 cells mm-2 in the central retina, falling to 2000 cells mm-2 in the superior margin. In vitro Lucifer labelling revealed that the overall bipolar cell density in the central retina was as high as 39,300 cells mm-2. Both the conventionally located and displaced bipolar cells were included in this population. About 11% of the total bipolar cell population consisted of IA bipolar cells. Assuming that one half of the conventionally located bipolar cells are the centre-hyperpolarizing type, IA bipolar cells represent approximately 28% of the total. As displaced bipolar cells represent almost one quarter of the total bipolar population, the dislocation of their somata stands out morphologically, inviting investigation of possible functional correlates.

Membrane currents were recorded in voltage-clamped oocytes of Xenopus laevis in response to voltage steps. We describe results obtained in oocytes obtained from one donor frog, which showed an unusually large outward current upon depolarization. Measurements of reversal potentials of tail currents in solutions of different K+ concentration indicated that this current is carried largely by K+ ions. It was strongly reduced by extracellular application of tetraethylammonium, though not by Ba2+ or 4-aminopyridine. Removal of surrounding follicular cells did not reduce the K+ current, indicating that it arises across the oocyte membrane proper. Activation of the K+ conductance was first detected with depolarization to about -12 mV, increased with a limiting voltage sensitivity of 3 mV for an e-fold change in current, and was half-maximally activated at about +10 mV. The current rose following a single exponential timecourse after depolarization, with a time constant that shortened from about 400 ms at -10 mV to about 15 ms at +80 mV. During prolonged depolarization the current inactivated with a time constant of about 4 s, which did not alter greatly with potential. The K+ current was independent of Ca2+, as it was not altered by addition of 10 mM Mn2+ to the bathing medium, or by intracellular injection of EGTA. Noise analysis of K+ current fluctuations indicated that the current is carried by channels with a unitary conductance of about 20 ps and a mean open lifetime of about 300 ms (at room temperature and potential of +10 to +20 mV).

Injection of inositol 1,4,5-trisphosphate (Ins(1,4,5)P3) into the animal pole of Xenopus oocytes induced membrane depolarization due to the internal mobilization of calcium, which activates a chloride conductance. Repetitive injections of Ins(1,4,5)P3 results in desensitization probably as a result of depletion of the internal store of calcium. Desensitization was restricted to the region surrounding the site of injection. Injection of Ins(1,4,5)P3 at one position induced desensitization, which failed to spread to a neighbouring region (ca. 200 microns away). Even when sufficient Ins(1,4,5)P3 was injected to induce calcium oscillations, there was still no evidence for the effects of Ins(1,4,5)P3 spreading to neighbouring regions. The fact that periodic calcium transients could also be established by the repetitive injection of small amounts of Ins(1,4,5)P3 suggests that calcium oscillations may also be localized. It is concluded that the Ins(1,4,5)P3-sensitive store of calcium comprises separate local compartments that can be activated independently of each other.

The effect, on the evolution of resistance, of alternating two unrelated insecticides in space or in time (or both) is studied. Transient polymorphism is shown to occur under certain conditions of mating, selection and migration. In some situations, the transient polymorphism can show a sharp decline before the alleles recover to fixation. Alternating a single insecticide in space, and in space and time, is also considered. Neither alternation in space nor in time shows any advantage with regard to delaying the onset of resistance. The most promising mode is to alternate the presence and absence of a single insecticide in both space and time, especially if it is applied at the larval stage and if some form of biological control is used in the regions where no insecticide is applied.

It is well established that exposure of oxyhaemoglobin to ionizing radiation results in remarkably selective electron addition to the (FeO2) unit, giving a novel species, (FeO2)-, in which the extra electron is largely localized on iron and dioxygen. This work has now been extended to haemoglobin (Hb.) Iwate. The haemoglobin M. Iwate used is a mutant haemoglobin having only Fe(III) alpha-chains by oxy beta-chains (alpha 2 Met beta 2 oxy). The haem iron atoms in the alpha-chains are coordinated in the fifth site by a proximal tyrosine in place of histidine. This unit is a high-spin Fe(III) with axial symmetry and prominent electron spin resonance (ESR) features in the g = 6 and g = 2 regions. On exposure to 60Co gamma-rays at 77 K, efficient electron addition occurred at both types of iron centre, giving Fe(II) and (FeO2)- units. The former was monitored by the decrease of the g = 6 feature for Fe(III) and the latter by the growth of g-features at 2.254 (gx), 2.149 (gy) and 1.967 (gz). These values are close to those for the FeO2- centre formed in the beta-chains of normal oxyhaemoglobin. On annealing above 77 K, two changes occurred: first there was a small but clear increase in gx and gy, followed by a marked reduction in gx and gy giving g-values close to those for the centre formed directly in the alpha-chains of the normal protein. Finally, this intermediate species gave a centre having gx = 2.310, gy = 2.180 and gz = 1.935. These values are typical of low-spin Fe(III) haemoglobin and are assigned to the protonated complex, Fe(III)O2H. Ultimately at ca. room temperature, this was converted into the high-spin, met-form, with a gain in the g = 6 feature. These results established that the beta-chain centre in Hb. Iwate behave in the same way as isolated beta-chains. They also confirm that electron addition to the oxy-units is facile, even in the presence of Fe(III) units in each tetramer. The results also confirm that electron capture to give (FeO2)- units is not followed by internal electron-transfer to give Fe(II) from the Fe(III) centres in the alpha-chains.

We present a diffusion-competition model to describe the interaction between the externally introduced grey squirrel and the indigenous red squirrel in Britain. We estimate the model parameters from field data. Solution of the model predicts waves of grey squirrel invasion with speed of invasion typical of that observed in the field. Numerical solution of the model on a two-dimensional domain gives population distributions qualitatively similar to those observed. We suggest that competition alone could account for the observed displacement of the red squirrel by the grey in large regions of Britain. The solutions are qualitatively similar to those for a single species spreading in the absence of competition. The quantitative difference is because competition slows down the speed of advance of the invading species.

A polyclonal, monospecific antiserum raised against a nicotinic acetylcholine receptor protein affinity-purified from insect nervous tissue, was employed to demonstrate the localization of antigenic sites in the neuropile of the terminal (sixth) abdominal ganglion of the cockroach Periplaneta americana. In agreement with previously published autoradiographic mapping of specific [125I]alpha-bungarotoxin binding sites, specific areas of the central neuropile of this ganglion were densely stained, but not the cercal afferent axons. No staining was detected corresponding to the dense, peripheral, partly non-specific binding of alpha-bungarotoxin seen in autoradiographs of the same tissue. Certain peripherally located neuronal cell bodies, including the cell body of giant interneuron 2, contained intracellularly located antigenic sites.