Light-break experiments and photoperiodic time measurement in the spider mite Tetranychus urticae

To explain photoperiodic induction of diapause in the spider mite Tetranychus urticae (Acarina: Tetranychidae) a theoretical model was developed, consisting of two components, viz. a “clock” and a photoperiodic “counter” mechanism. The clock executes photoperiodic time measurement according to hourglass kinetics; the counter accumulates the photoperiodic information contained in a number of successive $\text{light}\text{dark}$ cycles by adding up the number of “long” and “short” nights experienced by the developmental stages of the mites sensitive to the photoperiod. The influence of the circadian system on photoperiodic induction is interpreted as an inhibitory effect exerted on the expression of the photoperiodic response; this effect is encountered only in certain photoperiodic regimes, where the circadian system and the photoperiod are out of “resonance” with each other. This “hourglass timer oscillator counter model”, devised to give a theoretical explanation of photoperiodic time measurement, the summation of photoperiodic information, and the influence of the circadian system on photoperiodic induction, proved to be consistent with experimental results obtained with T. urticae in both symmetrical and asymmetrical “skeleton” photoperiods, the latter based on diel as well as non-diel $\text{light}\text{dark}$ cycles.     

Effects of cations upon chloroplast membrane subunit interactions and excitation energy distribution

When isolated chloroplasts from mature pea (Pisum sativum) leaves were treated with digitonin under “low salt” conditions, the membranes were extensively solubilized into small subunits (as evidenced by analysis with small pore ultrafilters). From this solubilized preparation, a photochemically inactive chlorophyll · protein complex (chlorophyll $\text{a}\text{b}$ ratio, 1.3) was isolated. We suggest that the detergent-derived membrane fragment from mature membranes is a structural complex within the membrane which contains the light-harvesting chlorophyll $\text{a}\text{b}$ protein and which acts as a light-harvesting antenna primarily for Photosystem II.Cations dramatically alter the structural interaction of the light-harvesting complex with the photochemically active system II complex. This interaction has been measured by determining the amount of protein-bound chlorophyll b and Photosystem II activity which can be released into dispersed subunits by digitonin treatment of chloroplast lamellae. When cations are present to cause interaction between the Photosystem II complex and the light-harvesting pigment · protein, the combined complexes pellet as a “heavy” membranous fraction during differential centrifugation of detergent treated lamellae. In the absence of cations, the two complexes dissociate and can be isolated in a “light” submembrane preparation from which the light-harvesting complex can be purified by sucrose gradient centrifugation.Cation effects on excitation energy distribution between Photosystems I and II have been monitored by following Photosystem II fluorescence changes under chloroplast incubation conditions identical to those used for detergent treatment (with the exception of chlorophyll concentration differences and omission of detergents). The cation dependency of the pigment · protein complex and Photosystem II reaction center interactions measured by detergent fractionation, and regulation of excitation energy distribution as measured by fluorescence changes, were identical. We conclude that changes in substructural organization of intact membranes, involving cation induced changes in the interaction of intramembranous subunits, are the primary factors regulating the distribution of excitation energy between Photosystems II and I.     

H+ transport in the evolution of photosynthesis

Extant photosynthetic organisms all appear to use transmembrane H⁺ fluxes as the coupling agent in the use of light energy in ATP synthesis. In the steady-state there is a large H⁺ free energy difference across the coupling membrane, and when this is reflected as a light-induced change in pH of the phase (cytosol or stroma) containing the enzymes of carbon assimilation, the H⁺ transport can have an informational role in activating and inactivating enzymes.The earliest organisms probably lived fermentatively (substrate-level phosphorylation) in an anaerobic environment provided with organic solutes synthesised abiotically. There are good reasons for believing that one of the earliest primary active transport systems (interconverting chemical and electrical/osmotic energy) was an H⁺ extrusion pump powered by ATP or PP_i. Its initial function was extrusion of excess H⁺ from the fermenting cells, and the support of a number of co-transport processes. The earliest energetic use of light energy is envisaged as being the energization of an alternative H⁺ extrusion pump, with bacteriorhodopsin or (bacterio-) chlorophyll as the pigment. The former type of cyclic photoredox system (Halobacterium-type) is simpler than the latter: a “pre-respiratory” chemical redox H⁺ pump may have preceded the (bacterio-) chlorophyll-based process. Any of these H⁺ pumps could spare the use of fermentative ATP in powering active H⁺ efflux and would thus have been favoured as fermentative substrates became scarce; eventually the larger generated by the light-powered H⁺ pump was used to drive the ATP-powered H⁺ pump backwards and thus generate ATP with light as the ultimate energy source.Scarcity of suitable reductants for biosynthesis as life proliferated provided a selective impetus for a non-cyclic photoredox system which could use light energy to generate a low-potential reductant at the expense of more readily available higher-potential reductants. The non-cyclic photoredox system is not possible in its simplest form (with all the redox energy coming from excitation energy of one or more photoreactions) in the bacteriorhodopsin line of evolution. Such a simple photoredox system is found in the Chlorobiaceae; even if (as seems likely) the non-cyclic photoredox process generates a (and thus, potentially, ATP), some of the ATP needed for CO₂ fixation and cell growth must be generated by a cyclic photoredox system.In the extant purple bacteria the generation of low-potential reductant involves a non-cyclic photoredox pathway which produces a reductant unable to reduce NAD⁺; the “energy gap” is spanned by “reverse electron transfer” which uses energy from a . It is not clear if this energetic requirement for the H⁺ gradient can be quantitatively satisfied from a non-cyclic photoredox H⁺ transport; it is certain that there is a major requirement for cyclic photoredox H⁺ pumping in these organisms.The photosynthetic bacteria are today restricted to reducing (low E_h) environments similar to those found in the early, anoxic earth; they are unable to use very weak reductants as donors for non-cyclic photoredox processes. As the sources of even weakly reducing donors (other than H₂O) on the primitive earth were depleted the two photoreactions scheme of extant O₂-producers evolved by modification of the bacterial photoreaction. This non-cyclic photoredox process is definitely H⁺-translocating and the role of cyclic photoredox processes in ATP generation in O₂-evolvers is smaller than in photosynthetic bacteria.In parallel with the biochemical and biophysical changes in the photosystems there was a morphological evolution, with an increasing tendency for “internalisation” of the photoredox processes (originally present in the plasma membrane, as in extant Chlorobineae) into thylakoids (as in most Rhodospirillineae, Cyanobacteria and in all eukaryotes). With a plasmalemma-located photoredox system, and the constraints of a fixed, alkaline external pH and the cytoplasmic pH of 7–8, the would be generated largely as an electrical P.D. The presence of a phase (intrathylakoid space) with a “negotiable pH” would permit the generation and use of a largely present as a pH gradient.In both cases illumination can cause an increase in cytoplasmic (stromal) pH over the dark value; this is an important aspect of the regulation of “phototrophic” and “heterotrophic” enzyme systems in the light and in the dark. However, it is argued that these differences in pH are not absolutely light-dependent unless they depend upon some more uniquely light-dependent signal, probably based on a redox component only generated in the light.     

The effect of silage additives containing formaldehyde on the fermentation of ryegrass ensiled at different dry matter levels and on the nutritive value of direct-cut silage

Ryegrass, harvested at the pre-ear emergence stage of growth, was ensiled in laboratory silos, either fresh (175 g dry matter kg^?1) or wilted to five DM levels ranging from 216–432 g DM kg^?1, with and without additive treatment. The additives used were “Sylade” containing sulphuric acid (15%) and formaldehyde (23%) applied at 4.6 l t^?1 and an “ADD-F” $\text{(85\%}\text{formic acid}\text{)}\text{formalin}$ mixture (7:3 by volume) applied at a similar rate (4.8 l t^?1). An additional treatment included application of the mixture at a constant rate related to the DM content of the ensiled crop (25 l t^?1 DM).In the untreated silages, the water-soluble carbohydrates (WSC) varied, respectively (over the DM range 175–432), from 0–32 g kg^?1 DM compared with 197-6 g kg^?1 DM for the “Sylade” treated silages and 256-50 g kg^?1 DM for the formic acid/formalin silages treated at an additive rate of 4.8 l t^?1. Corresponding ranges of protein N for the control and treatments (expressed as g kg^?1 total N) were 302–447, 624-502 and 620-505, respectively. When the formic acid/formalin additive was applied at a constant level related to the DM content of the crop, although the WSC content decreased with increasing DM (247-158 g kg^?1 DM), the protein N content (612 g kg^?1 total N) remained constant.Grass from the same field was ensiled fresh, treated with “ADD-F” at the rate of 3.4 l t^?1 fresh grass, $\text{“}\text{ADD-F}\text{”}\text{formalin}$ at the rate of 4.8 l t^?1 fresh grass and “Sylade” at the rate of 4.6 l t^?1 fresh grass. The silages were given to Suffolk-cross wether lambs in digestibility and intake trials. Digestibility coefficients of DM and energy of the silage treated with “Sylade” were significantly lower (P < 0.05) than those of the other three silages. The DM intakes of all the silages were high, ranging from 27.7 g kg^?1 live weight for the “Sylade” silage to 30.7 g kg^?1 live weight for the silage treated with $\text{“}\text{ADD-F}\text{”}\text{formalin}$. Live weight gains ranged from 200 g/day for the control silage to 267 g/day for the $\text{“}\text{ADD-F}\text{”}\text{formalin}$ silage.     

Theory of biological similarity revisited

A unified theory of biological similarity is proposed, based on dimensional analysis (mass M, length L, diameter D, time T) and on three postulates: (1) the constancy of body density in terrestrial mammals; (2) the elastic similarity criterion (Rashevsky and McMahon) where $\text{L ∝ D}{}^{\mathrm{<mtext>2</mtext><mtext>3</mtext>}}$; and (3) the proportionality between length (L) and time (T), which is valid for relaxation oscillators. The postulated theoretical model provides a satisfactory correlation (r = 0·9937) between the predicted reduced exponent (b) and 96 allometric exponents (b) obtained from experimental data concerning a number of morphologic and physiologic parameters in animals of different size.The reformulation of a theory of biological similarity is posited mainly for the “internal” organization of organisms, whereas a “mechanical” similarity should be applied when inertial forces are present during animal locomotion (kinematics).Since biological rhythmicity is based on relaxation oscillators (T ∝ L), while in “mechanical” similarity the pendulum ($\text{T ∝ L}{}^{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) is the paradigm of a self-sustained oscillation, these two are the limits of a continuous spectrum of similarity criteria, where the exponent of the time dimension (T) is the essential factor.The four-dimensional nature of biological space is discussed (W ∝ L⁴), and due to the postulated isometry of length (L) and time (T), periodic phenomena conform to $\text{T ∝ W}{}^{\mathrm{<mtext>1</mtext><mtext>4</mtext>}}$.     

Control of pattern duplication in the retinotectal system of Xenopus. Induction of duplication in eye fragments by secondary cuts.

Following surgical ablation of the temporal (posterior) region of the eye-bud in stage 32 Xenopus frog embryos, the surviving nasal (anterior) fragment gradually rounds up to form a functional eye and orderly retinotectal map. Large nasal fragments ($\text{N}\text{-}\text{2}\text{3}$) assemble topographically normal maps, as does the majority of nasal “half-eye” fragments; small nasal fragments ($\text{N}\text{-}\text{1}\text{3}$), and a minority of nasal half-eye fragments, give a characteristic, mirror-symmetrical duplication map, similar (but not identical) to the “double-nasal” maps which develop when two nasal half-eyes are fused to form a frank NN double-eye. Ventral fragments and temporal fragments show similar size-dependent behavior, although their characteristic duplicate maps are topographically different from those of nasal fragments and more similar to the “double-ventral” and “double-temporal” maps of VV and TT recombinant eyes. Here we show that a simple surgical transection, applied either dorsally or ventrally to large nasal ($\text{N}\text{-}\text{2}\text{3}$) fragments so as to isolate a subregion of the tissue at the dorsum or venturm of the fragment, induces full or partial duplication of the nasal type in the majority of cases. The results refute the hypothesis that special properties at the eye-bud center, by their presence or absence in the fragment, control pattern duplication, and point instead toward interactions around the circumference of the eye-bud as a crucial parameter in determining positional information in the retina.     

Bathymetric adaptations of reef-building corals at davies reef,great barrier reef,Australia. II. Light saturation curves for photosynthesis and respiration

Light saturation (P-I) curves for oxygen production and consumption were constructed in the laboratory for corals collected from depths of 1 to 45 m on the southeastern (seaward) side of Davies Reef, Great Barrier Reef, Australia. This depth range represents a gradient of from 82.6 to 2.9% of surface light, which was measured as photosynthetic photon flux density (PPFD) between 400 and 700 nm. Adaptative changes in photokinetic parameters were observed over the entire range of light intensities. The compensation intensity (I_c), I_k, the intensity at which photosynthesis was 95% light saturated (I_0.95), and the respiration rate (?R), all decreased with decreasing light intensity. The maximal rate of photosynthesis when normalized on the basis of coral chlorophyll-a content (P_ma^g) tended to decrease with decreasing irradiance but the change was not statistically significant. The $\text{P}\text{R}$ ratio ($\text{P}{}_{\mathrm{m}}{}^{\mathrm{g}}\text{?R}$), the initial slope of a light saturation curve (α), and the maximum rate of photosynthesis when normalized by coral protein content (P_mp^g), all increased with decreasing light intensity. The logarithms of the values for each variable parameter were proportional to the logarithms of the fraction of the surface PPFD (T) transmitted to the depth at which the corals grew. This enabled changes in these parameters to be accurately estimated for corals growing at any depth on the reef. Comparison of experimental data with published values for “saturating” irradiance and P_ma^g, suggests that the endosymbiotic algae within reef-building corals are photosynthetically intermediate between classical “sun” and “shade” plants.     

Control of respiration in proteoliposomes containing cytochrome aa3 II. Inhibition by carbon monoxide and azide

1. Carbon monoxide (CO) acts competitively towards oxygen when the latter is taken up in respiration by cytochrome aa₃-containing proteoliposomes, both in the presence of p-trifluoromethoxy carbonyl cyanide phenylhydrazone and valinomycin (deenergized state) and in their absence (energized state). At high levels of CO, the double reciprocal plots ($\text{1}\text{v}$ vs. $\text{1}\text{[}\text{O}{}_2\text{]}$) in the energized and deenergized states are parallel, i.e. energization acts “anti-competitively” towards oxygen, and the “respiratory control ratio” decreases as the oxygen concentration decreases.2. Azide acts non-competitively towards cytochrome c when the latter is oxidized by cytochrome aa₃-containing proteoliposomes both in the energized and deenergized (plus p-trifluoromethoxy carbonyl cyanide phenylhydrazone and valinomycin) conditions. At low azide concentrations the apparent K_i for azide is unaffected by energization, but at high azide levels the K_i increases in energized liposomes, i.e. the “respiratory control ratio” decreases as the azide concentration increases.3. It is concluded that the inhibitor experiments are consistent with but do not prove the concept that the oxidase molecules in a single vesicle are responding to a single “energization state” or set of electrochemical gradients. This and other models are discussed.     

A simple, rapid, and precise method for calculating the steroid hormone-receptor complex concentration in the presence of saturating levels of hormone by using "differential dissociation" techniques.

The steroid hormone-receptor complex concentrations measured by “differential dissociation” techniques have to be corrected to obtain the true concentrations of receptor binding sites (B_s). For the calculation of B_s, the parameters kn (product of the equilibrium association constant and the concentration of binding sites of the “nonspecific” component) and f (fraction of the nonspecific binding measured in the experimental estimates of bound ligand by a given technique), previously proposed by Blondeau and Robel (J. P. Blondeau and P. Robel, 1975, Eur. J. Biochem.55, 375–384) are important. A new parameter of interest, ? [$\text{?}\text{=}\text{knf}\text{(kn + 1)}$], is discussed. The measurement of this parameter ? for three “differential dissociation” techniques allows the comparison of their efficiency and their reliability under various conditions for hormone receptor measurement in cytosol. Charcoal and hydroxylapatite methods are more efficient than the Sephadex G-25 filtration method. It is demonstrated that the “isotopic dilution” correction generally used for the estimation of the background of a given technique may be incorrect whatever the method of correction. A new method, the “double concentration measurement,” is developed. This method is simple, rapid, and precise. It requires two receptor binding measurements at two different saturating concentrations of ligand. This method allows the measurement of the estradiol receptor binding activity from calf uterine cytosol, with an error of less than 5% in samples containing the receptor either free or previously complexed with radioactive hormone, even in the presence of very high concentrations (≤0.5 μm) of radioactive steroid.     

Unmasking the mitochondrial K/H exchanger: tetraethylammonium-induced K+-loss.

Mitochondria respiring in media containing 80 mM tetraethylammonium ions lose all of their endogenous K⁺ within 7 minutes. K⁺-loss is associated with uptake of tetraethylammonium ions. K⁺ efflux under these conditions is energy-dependent and electroneutral. It is concluded that tetraethylammonium uptake unmasks the endogenous $\text{K}\text{H}$ exchanger. Considered in relation to the chemiosmotic theory, these results support the existence of a “carrier-brake” mechanism which modulates $\text{K}\text{H}$ exchange to maintain volume homeostasis $\text{in vivo}$.     

A dielectric theory of "multi-stratified shell" model with its application to a lymphoma cell

A theory of complex dielectric constant ($\text{ε}{}^1$) for the suspension of “multi-stratified” spherical particles is presented. Based on Maxwell's theory of interfacial polarization, we derive a general expression which correlates $\text{ε}{}^1$ with the electrical and geometrical parameters of each stratum. It can be shown that such a “multi-stratified” system in general should give rise to multiple dielectric dispersions, the number of which corresponds to the number of interfaces lying between the successive shell phases. The conditions for a full number of different “unit” dispersions to occur are also discussed. As an example, a special case of the “double-shell” model consisting of a spherical core and three layers of concentric phases is solved numerically by using a set of parameter values pertinent to a lymphoma cell. In light of the characteristic behavior of $\text{ε}{}^1$ thus revealed, we propose a scheme of procedure that applies to the determination of electrical parameters associated with the specific “double-shell” model.     

A theoretical model of the red cell survival followed by means of random and cohort labeling

The usual method of approximating the experimental curves of erythrocyte survival by combining the exponential and normal distribution is rather arbitrary. For the method of cohort labeling the authors introduce a function expressing the number of labeled erythrocytes in the blood: $\text{F}\text{(}\text{t}\text{)}\text{exp}\text{?}\text{at}\text{?}\text{b}\text{λ+1}\text{t}{}^{\mathrm{\lambda +1}}$ the death probability function (Bergner,1962) belonging to it having the form μ(t) = a + bt^λ The advantage of this function consists in its simplicity and generality, which enables it to include both the “random” and “determined” components of erythrocyte destruction as special cases, without tying oneself to this traditional interpretation of the mechanism of erythrocyte elimination however. The suitability of the function F(t) in the form given here is demonstrated by means of a comparison with the experimental data available for several species of mammals.Problems of mathematical correction of perturbing factors in the methods of cohort and random labeling are further discussed in the paper. It is, for example, an erroneous prolongation of the erythrocyte life span in the latter method, due to neglecting the exponential component of the elimination, and the perturbing influence of the gradual incorporation of the labeled material into erythrocytes, which is responsible for the increasing initial part of the curve in the former method. Only the method of cohort labeling of erythrocytes of the same age can yield the desired more detailed information on the course of elimination of the red cells from the population; the further methodical improvement should be directed to a more thorough analysis of the perturbing factors connected with this method.     

Characterization of the stimulatory effect of T4 gene 45 protein and the gene 4462 protein complex on DNA synthesis by T4 DNA polymerase

On a variety of single-stranded DNA templates, the overall rate of in vitro DNA synthesis catalyzed by the bacteriophage T4 DNA polymerase is increased about fourfold by addition of the T4 gene $\text{44}\text{62}$ and 45 proteins. Several different methods suggest that this stimulation reflects an increase in the average DNA polymerase “sticking distance”, or processivity, from 800 to about 3000 nucleotides per initiation event. Both the $\text{44}\text{62}$ protein complex and the 45 protein must be present to obtain this effect, and either ATP or dATP hydrolysis is required. Rapid-mixing experiments indicate that the polymerase stimulation is maximized within a few seconds after addition of these “polymerase accessory proteins.”     

The invisible copper of cytochrome c oxidase. pH and ATP dependence of its midpoint potential and its role in the oxygen reaction.

Formation of the CO compound has been studied in intact mitochondria, submitochondrial particles and isolated cytochrome oxidase. The reaction requires the prior reduction of both cytochrome a₃ and one other single-electron acceptor. It is inferred that the second acceptor is the “invisible” copper which is undetectable by both optical and spin resonance spectroscopy. The overall process can be viewed as two single electron steps plus a ligand binding reaction. At high concentrations of CO, when titrations are performed at oxidation-reduction potentials significantly above the midpoints of either cytochrome a₃ or “invisible” copper, appearance of the CO compound follows a strict n = 2 (2-electron) relationship. Its midpoint potential is also dependent on the prevailing concentration of CO and is increased by approx. 30 mV for each tenfold increase in the level of CO. At redox potentials approaching the midpoints of cytochrome a₃ or “invisible” copper, significant deviations from n = 2 behavior are apparent which are readily detectable experimentally using low CO concentrations.A mathematical analysis of this model is presented and the oxidation-reduction properties of the CO compound are utilized to determine the midpoint potential of the “invisible” copper. This value is estimated to be 340 ± 10 mV at pH 7.8, independent of pH and the prevailing $\text{sol}\text{[ATP]}\text{[ADP]}\text{× [}\text{P}{}_1\text{]}$ ratio.By analogy with the observations on CO binding, the primary intermediate in the oxidase reaction with oxygen is concluded to be a bridged a₃²⁺-O₂-Cu¹⁺ complex. The initial reduction of molecular oxygen can then proceed via a thermodynamically favorable two-electron step to form a bridged peroxide intermediate. Subsequent reduction to water may later occur by way of two single-electron steps or one two-electron step.     

The enzyme "aldehyde oxidase" is an iminium oxidase. Reaction with nicotine delta 1'(5') iminium ion.

The second of the two reaction steps involved in the metabolic transformation of (?)-nicotine to (?)-cotinine $\text{(}\text{3}\text{) (}\text{i.}\text{e.}$, the oxidation of the intermediate $\text{2}\text{)}$ is mediated mainly, if not solely, by the enzyme aldehyde oxidase (EC 1.2.3.1). Of the molecular species that constitute $\text{2}$, nicotine Δ^1′(5′) iminium ion $\text{(}\text{2a}\text{)}$ appears to serve as the substrate. The enzyme has a strong affinity for $\text{2a}$, as shown in a study on the inhibition of the oxidation of 3-(aminocarbonyl)-1-methylpyridinium chloride. This study gave a value of K_i = 6 μM; K_m = 2 μM (pH 7.4). Mainly in view of this finding, “iminium oxidase” seems to be a more adequate name than “aldehyde oxidase” for this enzyme.     

Practical acid dissociation constants,temperature coefficients,and buffer capacities for some biological buffers in solutions containing dimethyl sulfoxide between 25 and −12 °C

Acid dissociation constants (K_a), usually expressed as pK_a (-logK_a) can be considered as indices of acid-base equilibria in solution and their evaluation under the solution conditions that exist during the exposure of biological systems to low temperatures are as important as the measurement of pH per se. The assignment of pH1 standards to define pH1 scales in the binary mixed solvent, dimethyl sulfoxide-water (27), has provided the basis for measuring the pK_a1 values of some biological buffers in mixtures of Me₂SO and H₂O which have particular relevance to studies which demonstrate the “pH-dependent” recovery of smooth muscle after low-temperature storage (9, 31). “Practical” ionization conslants in water (pK′_a) and in 20% ($\text{w}\text{w}$) and 30% ($\text{w}\text{w}$) dimethylsulfoxide-water (pK_a1) have been measured by potentiometric titration of a range of zwitterionic buffer compounds at 25, 0, ?5.5, and ?12 °C together with the respective buffer capacities and temperature coefficients. Measurements have been made with reference to the relevant standard states for each solvent system, thereby endowing the values with as much thermodynamic significance as possible.     

Consequences of delayed lateral inhibition in the retina of Limulus. I. Elementary theory of spatially uniform fields.

Although the magnitude of lateral inhibition in the retina of the compound eye of Limulus polyphemus depends strongly on the distance between ommatidia, the delay time τ between the response of one ommatidium and the consequent inhibition of another is independent of the distance between them and is approximately 0·1 sec (cf., e.g., Ratliff, Knight, Dodge &; Hartline,1973). We have recently shown (Coleman &; Renninger, 1974) that under appropriate circumstances the response r of such a retina to a temporally constant and spatially uniform excitation of amount e should be a succession of “bursts” and “rest periods”, each of duration τ, so that r, although spatially uniform, is a periodic function of time with period 2τ and mean value $\text{1}\text{2}\text{ϵ}$. Further, the periodic function r can have a fine structure in which there is repeated information about the duration and sequence, but not the amplitude, of any short pulses which occurred immediately (i.e. within a time interval of length τ) before the onset of steady uniform excitation. We derive here implications of several plausible general hypotheses about the functional form of lateral inhibition. We show that, under those of the considered hypotheses which are expected to hold for Limulus in strong light, periodic bursting behavior for r is stable and is rapidly approached if the excitation is held steady and uniform.     

Cognitron: A self-organizing multilayered neural network

A new hypothesis for the organization of synapses between neurons is proposed: “The synapse from neuron x to neuron y is reinforced when x fires provided that no neuron in the vicinity of y is firing stronger than y”. By introducing this hypothesis, a new algorithm with which a multilayered neural network is effectively organized can be deduced. A self-organizing multilayered neural network, which is named “cognitron”, is constructed following this algorithm, and is simulated on a digital computer. Unlike the organization of a usual brain models such as a three-layered perceptron, the self-organization of a cognitron progresses favorably without having a “teacher” which instructs in all particulars how the individual cells respond. After repetitive presentations of several stimulus patterns, the cognitron is self-organized in such a way that the receptive fields of the cells become relatively larger in a deeper layer. Each cell in the final layer integrates the information from whole parts of the first layer and selectively responds to a specific stimulus pattern or a feature.     

Crystals of glutamine synthetase from Escherichia coli.

Further details are given of crystals of glutamine synthetase prepared from Escherichia coli. Crystals of two kinds have been observed: (1) rhombic dodecahedra which correspond to the morphology of the crystals studied by Eisenberg et al. (1971) (and which were found by them to contain dodecamers), and (2) rhombohedra, reported here. Cell dimensions and packing considerations led to the consideration of two possible structures for the rhombohedral crystals. These we have called the “T = 7 structure” and the “B.C.C. structure”. The T = 7 structure would be related to that derived by Eisenberg and would contain dodecamers, but is inconsistent with our X-ray intensity data. The B.C.C. structure is considered more probable. It is built of cubic octomers or square tetramers. Electron micrographs of our glutamine synthetase preparations show a wide variety of aggregates, including dodecamers and tetramers. The unit cell dimensions of our crystals are $\text{a = 140 ± 2}\text{A}\text{̊}$, and $\text{c = 148 ± 2}\text{A}\text{̊}$. The Laue symmetry group is $\text{3}\text{̄}$m P3₁.     

Separation of acetanilide and its hydroxylated metabolites and quantitative determination of "acetanilide 4-hydroxylase activity" by high-pressure liquid chromatography.

A simple and very sensitive method for the separation of 4-hydroxyacetanilide, 3-hydroxyacetanilide, 2-hydroxyacetanilide, and acetanilide was developed with the use of high-pressure liquid chromagraphy. Each of these phenolic derivatives can be separated completely from acetanilide and from one another. A simple assay for “acetanilide 4-hydroxylase activity” is thus described. The limit of sensitivity for cytochrome P-450-mediated acetanilide 4-hydroxylase activity is estimated to be 1.0 pmol/min/mg microsomal protein, thereby allowing this assay to be useful in detecting monooxygenase activity in “low level” nonhepatic tissues. Hepatic acetanilide 4-hydroxylase activity is induced about fourfold in $\text{C57BL}\text{6N}$ mice by 3-methylcholanthrene. Although acetanilide 2-hydroxylase activity is about seven times lower than the 4-hydroxylase activity, the 2-hydroxylase is also induced about three- or fourfold in $\text{C57BL}\text{6N}$ mice by 3-methylcholanthrene. The “2-hydroxylase activity” cannot, however, be strictly quantitated under the conditions described herein. The K_m values of both the 3-methylcholanthrene-induced and control 4-hydroxylase activity are about 0.55 mm; V_max values for 3-methylcholanthrene-treated and control mice, respectively, are 4.9 ± 1.1 and 1.1 ± 0.31 nmol/min/mg microsomal protein. The 4-hydroxylase in the liver of both 3-methylcholanthrene-treated and control mice appears to represent two or more catalytic activities, i.e., two or more forms of P-450 having widely differing affinities for the substrate acetanilide.