Indices of biopolymer metabolism in connective tissue during repeated stress

Experiments on rats have shown that daily strong stress actions (immobilization) brought about the marked increase in the 11-oxycorticosteroid level and indices of the biopolymer exchange in the connective tissue (free oxyproline, glycosaminoglycanes, sialic acids). Under the acupuncture action (weak stresses) all the above indices were changed mainly after the first influence. Preliminary acupuncture stimulations prevent deep changes in the exchange of biopolymers in the connective tissue, developing under strong stresses.     

Recording lifetime behavior and movement in an invertebrate model

Characterization of lifetime behavioral changes is essential for understanding aging and aging-related diseases. However, such studies are scarce partly due to the lack of efficient tools. Here we describe and provide proof of concept for a stereo vision system that classifies and sequentially records at an extremely fine scale six different behaviors (resting, micro-movement, walking, flying, feeding and drinking) and the within-cage (3D) location of individual tephritid fruit flies by time-of-day throughout their lives. Using flies fed on two different diets, full sugar-yeast and sugar-only diets, we report for the first time their behavioral changes throughout their lives at a high resolution. We have found that the daily activity peaks at the age of 15-20 days and then gradually declines with age for flies on both diets. However, the overall daily activity is higher for flies on sugar-only diet than those on the full diet. Flies on sugar-only diet show a stronger diurnal localization pattern with higher preference to staying on the top of the cage during the period of light-off when compared to flies on the full diet. Clustering analyses of age-specific behavior patterns reveal three distinct young, middle-aged and old clusters for flies on each of the two diets. The middle-aged groups for flies on sugar-only diet consist of much younger age groups when compared to flies on full diet. This technology provides research opportunities for using a behavioral informatics approach for understanding different ways in which behavior, movement, and aging in model organisms are mutually affecting.     

Poor maternal environment enhances offspring disease resistance in an invertebrate

Natural populations vary tremendously in their susceptibility to infectious disease agents. The factors (environmental or genetic) that underlie this variation determine the impact of disease on host population dynamics and evolution, and affect our capacity to contain disease outbreaks and to enhance resistance in agricultural animals and disease vectors. Here, we show that changes in the environmental conditions under which female Daphnia magna are kept can more than halve the susceptibility of their offspring to bacterial infection. Counter-intuitively, and unlike the effects typically observed in vertebrates for transfer of immunity, mothers producing offspring under poor conditions produced more resistant offspring than did mothers producing offspring in favourable conditions. This effect occurred when mothers who were well provisioned during their own development then found themselves reproducing in poor conditions. These effects likely reflect adaptive optimal resource allocation where better quality offspring are produced in poor environments to enhance survival. Maternal exposure to parasites also reduced offspring susceptibility, depending on host genotype and offspring food levels. These maternal responses to environmental conditions mean that studies focused on a single generation, and those in which environmental variation is experimentally minimized, may fail to describe the crucial parameters that influence the spread of disease. The large maternal effects we report here will, if they are widespread in nature, affect disease dynamics, the level of genetic polymorphism in populations, and likely weaken the evolutionary response to parasite-mediated selection.     

Hormonal control of invertebrate behavior

Invertebrates show a wide variety of behaviors that are influenced by hormones. In insects the involvement of hormones at a particular life stage is directly correlated with the complexity of the behavioral repertoire at that stage. In larval stages, the steroid hormone, ecdysone, when present with juvenile hormone, apparently causes the behaviors observed during the periodic molts. At the end of larval life, ecdysone in the absence of juvenile hormone triggers the onset of premetamorphic behaviors such as wandering behavior and cocoon-spinning behavior. In insects having complete metamorphosis, the emergence (eclosion) of the adult from the pupal case is accomplished by a stereotyped program of movements that are triggered by a peptide hormone. In moths, injection of this “eclosion hormone” into competent recipients will cause the release of the eclosion program. Also this program can be elicited by the hormone from the isolated abdominal central nervous system (CNS). The onset of reproductive behavior in females of various species requires juvenile hormone. In addition, certain peptides are then involved in the transition from virgin to mated behaviors. Also, pupatitive peptide factors trigger specific stereotyped behaviors such as those involved in mate attraction and in oviposition. In males, the control is simpler. Juvenile hormone is required for the maturation of sexual behavior in only a few species. But in at least one insect group, the cockroaches, a neurosecretory hormone serves to release directly copulatory behavior. Social behavior and migratory behavior in certain insects are also under hormonal influence. Hormones play a prominent role in regulating the behavior of gastropod mollusks. The best studied examples involve the hormonal stimulation of egg-laying behavior by CNS peptides. Also, peptide hormones cause stereotyped changes in specific identified neurons in the CNS of various gastropods. In at least some cases, these latter changes are related to arousal from aestivation.With their simple nervous systems, invertebrates are especially suited for studies on the mode of action of hormones on the nervous system. In most cases the behavioral effects of these hormones appear to be due to their direct action on the CNS. Indeed, the isolated moth CNS will respond to the eclosion hormone by generating the motor program that gives rise to the emergence behavior, and various isolated molluscan preparations will respond to hormones with stereotyped neural responses. By the direct application of hormone to the surface of identified nerve cells in mollusks it has been possible to localize target cells for specific hormones. Little is known of the mode of action of ecdysone or juvenile hormone in altering behavior. Peptide hormones appear to have effects which long outlast the actual presence of the hormone. In at least two cases, cyclic AMP has been implicated as a mediator of the hormonal response.     

Physical behavior of gelatin gels: a simple model for connective tissue

The swelling behavior of gelatin gels when immersed in buffer or in osmotically active solutions of dextran 500 has been studied, and the results can be described by means of the Flory-Rehner theory of the thermodynamic properties of three-dimensional network structures. The density of crosslinkages formed in the gel is found to be related to the concentration of gelatin at which gelation occurs. Values of rigidity moduli are estimated from the density of crosslinkages by use of the statistical thermodynamic theory of rubber elasticity. These values are in excellent agreement with direct measurements.     

Electric dichroism of DNA. Influence of the ionic environment on the electric polarizability

In order to test the diffuse ion atmosphere polarization model recently developed by us, the effects of ionic strength, titrating with Mg2+ and Co(NH3)3+6, and coion charge on the electric polarizability of short fragments of DNA are investigated. The results are consistent with the predictions of the theory and show that the diffuse ion atmosphere polarization contributes significantly to the overall orientation of DNA. At low ionic strengths, we attempt to separate the total dipole moment into two components: one that agrees well with the Debye-Hückel ion atmosphere calculations, while the other, presumably due to condensed counterion polarization, appears to be substantially independent of the ionic strength. At higher salt concentrations, however, a simple separation into dipole components is not possible, perhaps due to a significant coupling of ion flows between the diffuse atmosphere and the condensed counterion layer.     

Trabeculated embryonic myocardium shows rapid stress relaxation and non-quasi-linear viscoelastic behavior

Passive viscoelastic behavior is important in embryonic cardiovascular function, influencing the rate and magnitude of contraction and relaxation. We hypothesized that if viscoelastic behavior is influenced by interstitial fluid flow, then the stage-21 (312d) and stage-24 (4d) chick myocardium with large intertrabecular spaces will exhibit much different viscoelastic behavior than stage-16 (212d) and stage-18 (3d) compact myocardium and a non-quasi-linear response. Excised left ventricular sections were tested with ramp-and-hold stress relaxation tests at axial stretch ratios of 1.05:1.1:1.2:1.3. The measured stress relaxation was much more rapid than previously observed in the compact, non-trabeculated myocardium. The reduced relaxation curves depended significantly on the stretch level. A continuous-spectrum quasi-linear relaxation function described their shape well but the model-fit parameters also depended on the stretch level. Sinusoidal stretching of ventricular sections at rates from 0.2 to 25Hz showed that the steepening of stress-strain curves with increasing strain rate was half as much as predicted by a quasi-linear model. Hysteresis ranged from 25-35%, varied little with loading rate from 0.2 to 8Hz, and was twice that predicted from a quasi-linear model. Doubling the viscosity of the perfusate in stress-relaxation tests produced increased stiffness and decreased relaxation rate. These results demonstrate that the passive viscoelastic behavior of the trabeculated embryonic myocardium is markedly different from that of younger, compact myocardium and is not quasi-linear.