The polarity of axon growth in the wings of Drosophila melanogaster

We have analyzed the growth of axons in the wings of the mutants Hairy wing and hairy of Drosophila melanogaster. These mutants produce many supernumerary bristle organs and sensilla campaniformia, whose axons grow between the two wing epithelia and can be visualized in both pupal and adult stages. The sensory axons of wild-type animals follow two paths in the wing, within longitudinal veins L1 and L3, and always grow with a distal to proximal polarity. In the mutants, all axons following these two paths likewise grow with correct polarity. Axons elsewhere in the wing, however, are found to grow in many different directions, including from proximal to distal and hence directly away from the central nervous system. A variety of patterns of axon growth and fasciculation are seen in different individuals. Only if the supernumerary axons encounter the two normal paths do they reliably grow toward the base of the wing. We conclude that these two paths provide polarity information for axon growth, information which is either not used or not available elsewhere in the wing in spite of the obvious morphological polarization of every epithelial cell. The time course of neural differentiation suggests that the normal sensory cells of mutant wings, which grow axons relatively early, may be the source of polarity information for the later-differentiating supernumerary cells.     

Fluorescence from sensitizing phycobilin chromophores in the blue-green alga Anacystis nidulans

Regeneration of the pigment system of Anacystis nidulans was studied following nitrate starvation. Three new, distinct fluorescence bands, at 596, 615 and 636 nm attributed to sensitizing phycobilin chromophores were detected. They each possess a separate excitation band at 425, 395 and 410 nm, respectively.     

Developmental compartments in the Drosophila melanogaster wing disc

Distribution of the enzyme aldehyde oxidase (AO) within the pouch of the mature wing disc is precise and differential. General locations of compartmental boundaries have been identified by fate mapping and studies of AO distribution. The suspected locations of the boundaries were verified by analyzing the distribution of AO-negative cells within an AO-stained background in gynandromorphs and in X-ray-induced clones of AO-negative cells. The anterior/posterior border appeared slightly anterior to the junction of the AO⁺ anterior presumptive wing surfaces and AO^? posterior wing surfaces. A narrow band of AO⁺ cells extending proximodistally on both presumptive wing surfaces belongs to the posterior compartment. Two dorsal/ventral (dor./vent.) restrictions were found. The dor./vent. restriction equivalent to the dor./vent. border found in the adult wing was located at the ventral most edge of the AO-stained presumptive wing margin. A second restriction which was less strictly obeyed was found on the dorsal edge of the wing margin. We conclude that the whole presumptive wing margin is part of the dorsal compartment. Within the anterior wing margin an intensively stained oval was also found to be clonally restrictive. Therefore, territories were found within the prospective wing margin for which no such features have been identified in the adult Drosophila melanogaster wing.     

Prenatal chlordiazepoxide effects on metrazol seizures and benzodiazepine receptors density in adult albino rats

Adult offsprings of rats treated with daily injection of chlordiazepoxide (10 mg/kg, i.p.) during pregnancy showed a significant decrease in benzodiazepine receptors in the cortex and the cerebellum without apparent changes in receptor affinity. A reduced susceptibility to metrazol-induced epileptogenesis paralleled this change. These findings are discussed in relation to the differential vulnerability of various types of benzodiazepine receptors.     

Differences between cattle and sheep in their digestion and relative intake of a mature tropical grass hay

The dry-matter digestibility (DMD) of a low quality tropical grass hay was much higher in cattle (49.6%) than in sheep (34.6%). This difference was not due to a difference in relative intake per kg liveweight (W^0.9) nor to a difference in the diet selected. However, neutral-detergent fibre (NDF) was digested better by cattle than by sheep. For each kg of dry matter consumed, cattle digested 415 g NDF and sheep 279 g NDF. This was because 60% more of the hemicellulose and 35% more of the cellulose were digested by cattle than by sheep.Differences between cattle and sheep in the concentrations of urea and sulphate in blood, and the relatively lower excretion of N, P and Ca by the cattle suggested that the rumen micro-organisms of the cattle were utilizing these nutrients better than those of the sheep. This could have increased microbial activity in the rumen and, hence, digestion of fibre.     

Growth dynamics in the regeneration of a fragment of the wing imaginal disc of Drosophila melanogaster

Regen rating fragments of wing imaginal discs were cultured in vivo for various periods up to 1 week. At specified times the fragments were removed, macerated, and the resulting cell counts were compared to similar counts made on the contralateral intact disc. Significant growth was seen beginning on the second day if the hosts were transferred to fresh media daily, while seen only on Day 4 and not thereafter if hosts were maintained on the same media throughout the culture period.     

Estimation of the digestibility of low-quality hays by cattle from measurements made with sheep

Seventeen sets of apparent digestibility data derived from 10 experiments, in which both cattle and sheep had been fed on the same hays, were examined. The study was restricted to low-quality hays of less than 60% apparent digestibility of dry matter. On average, digestibility was higher for cattle than for sheep, and the difference was greatest with the samples of lowest digestibility. A linear equation found to describe best the relationship between the digestibility of hays by cattle and sheep was:

$\text{y = 0.673 x + 20.3}$

where y = digestibility of hay to cattle (%) and x = digestibility to sheep (%) (r = 0.843; S_y.x, ± 3.41; standard error of the slope, ± 0.111). This equation may be used to correct apparent digestibility values of 60% or less measured with sheep, or estimated in vitro with the use of sheep standards, if the digestibility data are to be applied to cattle.     

Antibodies to nicotinic acetylcholine receptors used to probe the structural and functional relationships between brain α-bungarotoxin binding sites and nicotinic receptors

Antibodies against peripheral nicotinic acetylcholine receptors (nAChR) were used to determine the proportion of brain α-bungarotoxin binding sites that are immunologically related to the peripheral nAChR. The α-bungarotoxin binding component partially purified from rat brain was labelled with [¹²⁵I]α-bungarotoxin and reacted with increasing concentrations of rabbit anti(nAChR) antisera. At least 75% of the brain protein could be immunoprecipitated by rabbit anti(rat muscle junctional nAChR) antiserum (M) whereas an antiserum against Torpedo nAChR (J) was without effect and clearly failed to cross-react with the brain component. Both antisera precipitated 100% of [¹²⁵I]α-bungarotoxin-labelled nAChR from Torpedo marmorata. The lower precipitation of the brain protein was not a consequence of [¹²⁵I]α-bungarotoxin dissociating during the precipitation. We conclude that the majority of α-bungarotoxin binding sites in brain are clearly recognised by the crossreacting antiserum.Release of [³H]dopamine from striatal synaptosomes could be elicited by nicotine in a dose-dependent manner and the response was prevented by the ganglionic blocker mecamylamine, although antagonism by α-bungarotoxin was less clearcut. Preincubation of the synaptosomes with antiserum M resulted in a statistically significant decrease in the [³H]dopamine response to nicotine at all agonist concentrations tested. Antiserum J, however, had no consistent effect on the response. Thus the actions of the antisera parallel their ability to recognise the brain α-bungarotoxin binding component. We conclude that the cholinergic regulation of dopamine release is in part mediated through a nAChR that is immunologically related to the nAChR of the neuromuscular junction and to the α-bungarotoxin binding component that can be isolated from rat brain.     

Cell cycle changes during growth and differentiation of imaginal leg discs in Drosophila melanogaster

The relative DNA content of Drosophila melanogaster imaginal leg disc nuclei during larval growth and pupal and adult differentiation was measured by microspectrophotometry. During the larval proliferative phase there were twice as many nuclei in the 4C class as nuclei in the 2C class. At the end of the third larval instar, the proportion of nuclei with a 4C DNA value increased. By 3 hr after pupariation, during pupal cuticle secretion, 90% of the nuclei were in this class. After pupal apolysis which occurs at 12 hr after pupariation, the 4C to 2C ratio was reversed. The increase in the proportion of nuclei with a 2C value was observed until 24 hr after pupariation when 90% of the nuclei were in this class. We propose that most cells divide at least once between pupal and adult differentiation. All of these changes in the cell cycle were correlated temporally with changes in the ecdysteroid titers that occur during these periods.     

Prolactin binding in rat mammary gland during pregnancy and lactation

Lactogenic hormones from the placenta and pituitary are primarily responsible for the growth and function of the mammary gland during pregnancy and lactation. In the present study we describe the optimal conditions for the measurement of ¹²⁵I-labeled ovine prolactin binding to mammary gland slices of pregnant and lactating rats. Prolactin binding is saturable (K_{d approx. 2.36 · 10^?9 M)}, hormone specific and destroyed by proteases. The hormonal environments of pregnancy and lacation dramatically influence the availability and measurement of prolactin binding sites. Whereas binding consistently appears to be low in mammary glands removed from rats during pregnancy, binding levels rise 7–8-fold shortly after birth and remain high during the 22 days of lactation. However, the removal of the ovaries and gravid uteri at specific times during pregnancy results in prompt 3–6-fold increase in prolactin binding. Elevated levels in potential prolactin binding capacity appear in mammary tissue coincident with the reported rise in serum rat placental lactogen between the eight and eleventh days. We suggest that high levels of this lactogenic hormone promote the appearance of prolactin binding sites during pregnancy and mask the sites such that they are not available for measurement in vitro.     

Regulation of exocellular protease in Neurospora crassa: induction and repression under conditions of nitrogen starvation.

Exponential-phase cells of Neurospora crassa require the continued presence of a protein inducer and nitrogen starvation to induce exocellular protease under conditions where protein is the sole nitrogen source. The nature of the protein inducer appears relatively unimportant, since both soluble proteins (e.g., myoglobin) and insoluble proteins (e.g., corn zein) will effect induction. Nonstarved cells of N. crassa appear to have small nitrogen pools, since nitrogen starvation of exponential cells prior to transfer into a medium where protein is the sole nitrogen source effects starvation-time-dependent decreases in protease biosynthesis. Ammonium ion represses protease synthesis, with apparent specificity at low concentrations. The amino acids arginine, tryptophan, and threonine effect repression of protease biosynthesis under conditions of nitrogen starvation. Under conditions of sulfur starvation, the amino acids cysteine, methionine, and cystine repress protease biosynthesis. In carbon-starved cells, all of the above amino acids, plus histidine, isoleucine, leucine, lysine, phenylalanine, and valine, effect repression. Examination of amino acid pools formed when cells are grown on protein as the sole nitrogen source demonstrated that the amino acids which repress protease biosynthesis under conditions where protein is the sole carbon source accumulate in significant amounts during the course of protease induction, with kinetics consonant with the induction process.     

Antibodies to muscarinic acetylcholine receptors in myasthenia gravis

IgG obtained from patients with myasthenia gravis block the specific binding of the muscarinic antagonists (³H)-N-methyl-4-piperidyl benzilate (4NMPB) and (³H)-Quinuclidinyl benzilate to rat brain muscarinic acetylcholine receptors. IgG obtained from healthy controls have a much smaller effect. The inhibitory effect of the myasthenic IgG increases linearly with immunoglobulin concentration and has no effect on the affinity of the muscarinic receptors towards (³H)-4NMPB (K_D = 0.7 ± 0.1 nM). This implies that the inhibition is probably due to the blocking of some of the muscarinic receptors by the myasthenic IgG, and not due to alteration in affinity of all the receptors. it remains to be established whether the presence of antimuscarinic receptor activity in the serum of myasthenic patients is of importance in the pathophysiology and diagnosis of myasthenia gravis.     

Quantitative in situ hybridization of ribosomal RNA species to polytene chromosomes of Drosophila melanogaster.

In situ hybridization of ¹²⁵I-labelled 5 S and 18 + 28 S ribosomal RNAs to the salivary polytene chromosomes of Drosophila melanogaster was successfully quantitated. Although the precision of the data is low, it is possible to compare the hybridization reaction between an RNA sample and chromosomes in situ with the reaction between the same RNA sample and Drosophila DNA immobilized on nitrocellulose filters. The in situ hybrid dissociates over a narrow temperature range with a midpoint similar to the value expected for the filter hybrid. The kinetics of the in situ hybridization reaction can be fit with a single first-order rate constant that has a value from three to five times smaller than the corresponding filter hybridization reaction. Although the reaction saturates at longer times or higher RNA concentrations, the saturation value does not correspond to an RNA molecule bound to every available DNA sequence. With the acid denaturation procedure most commonly used to preserve cytological quality, only 5 to 10% of the complementary DNA in the chromosomes is available to form hybrids in situ. This hybridization efficiency is a function of how the slides are prepared and the conditions of annealing, but is approximately constant with a given procedure for both 5 S RNA and 18 + 28 S RNA over a number of different cell types with different DNA contents. The results provide further evidence that the formation of RNA-DNA hybrids is the sole basis of in situ hybridization, and show that the properties of the in situ hybrids are remarkably similar to those of filter hybrids. It is also suggested that for reliable chromosomal localization using the in situ hybridization technique, the kinetics of the reaction should be followed to ensure that the correct rate constant is obtained for the major RNA species in the sample and an impurity in the sample is not localized instead.     

Patterns of cell division and cell movement in the formation of the imaginal nervous system in Drosophila melanogaster.

Tritiated thymidine was administered at various times, and for various lengths of time, during the larval stages of Drosophila melanogaster. The thymidine was incorporated into DNA and was subsequently detected by autoradiography. These procedures allowed identification of those cells undergoing DNA replication at a particular time and also allowed determination of subsequent changes in relative position of these cells and some of their progeny. An analysis of these data has elucidated characteristic patterns of cell division and cell movement in the formation of the adult nervous system during postembryonic developmental stages.     

Energy transformation and entropy production in living systems I. Applications to embryonic growth

Generalized material and energy balances are presented for biological systems that experience negligible kinetic, elastic, and potential energy changes. The balances are used to characterize the mass changes and energy transformations that occur in the developing avian embryo, using as an example a consistent set of data for the chicken egg. It is shown that the rate of total chemical energy turnover by the embryo is a quantity of interest and that this rate is not necessarily equivalent to the metabolic rate that is predicted from heat transfer measurements or oxygen consumption rates. The energy required for evaporative water loss is accounted for in the overall energy balance. Using the results of the energy calculations and a generalized expression for the rates of internal and total entropy production, the Prigogine-Wiame hypothesis is examined for the developing embryo with two different assumptions regarding the efficiency of biomass conversion. An order of magnitude analysis of the internal heat-conduction term is performed to show that the chemical reaction term dominates the entropy production relation. The constant efficiency case is shown to be in agreement with the Prigogine-Wiame hypothesis for the data used in the analysis.     

Membrane-bound tubulin: Resistance to cathepsin D and susceptibility to thrombin

In recent studies we found that cytoplasmic tubulin from brain was rapidly split by brain cathepsin D. Two pools could be established; the major portion was split at 18%/h, a minor portion at 2%/h, under our experimental circumstances. In the present work these experiments were extended to membrane-bound tubulin from brain. The membrane-bound form, in contrast to the cytoplasmic tubulin, was not degraded by cerebral cathepsin D under similar experimental conditions. This was not due to the presence of an inhibitory protein since added cytoplasmic tubulin was degraded. Several other protein components of membrane fractions (synaptosomal, mitochondrial) were degraded by cathepsin D, as measured on two-dimensional electropherograms. Thrombin degraded cytoplasmic tubulin, but the degradation products differed from those of cathepsin D degradation. Thrombin also hydrolyzed membrane-bound tubulin, but at a lower rate than the cytoplasmic form. Our results indicate great differences in the breakdown rate of a protein, which depend on its localization, in accord with the differences found in in vivo turnover rates.