Cardiac and ventilatory responses ofCrangon crangon to cadmium,copper and zinc

The acute (30 min) responses of heart and scaphognathite activities ofCrangon crangon on exposure to concentrations of 1–20 mg Cd, Cu or Zn 1⁻¹ are increased beat frequencies. The relative magnitude of response(Δ f) is linearly related to immediate pretreatment frequency(f) and standardised responses(Δ fs) are given forf values of 70 and 100 beats min⁻¹ for hearts and scaphognathites, respectively.Δ fs values for each organ are also linearly related to test concentration for each metal. Qualitative changes to organ activities described include an increased incidence of scaphognathite reversals in concentrations of 5.0 mg Cu 1⁻¹ and in 20.0 mg Zn 1⁻¹. Chronic (13 days) exposure to incipient lethal levels of the test metals produced increases in scaphognathite rates of the Cd-treated animals and in heart and scaphognathite rates of the coppertreated animals. The general applicability of these methods to studies of pollution stress in decapods is discussed.     

Thoracic leg motoneurons in the isolated CNS of adult Manduca produce patterned activity in response to pilocarpine,which is distinct from that produced in larvae

In the hawkmoth, Manduca sexta, thoracic leg motoneurons survive the degeneration of the larval leg muscles to innervate new muscles of the adult legs. The same motoneurons, therefore, participate in the very different modes of terrestrial locomotion that are used by larvae (crawling) and adults (walking). Consequently, changes in locomotor behavior may reflect changes in both the CNS and periphery. The present study was undertaken to determine whether motor patterns produced by the isolated CNS of adult Manduca, in the absence of sensory feedback, would resemble adult specific patterns of coordination. Pilocarpine, which evokes a fictive crawling motor pattern from the isolated larval CNS, also evoked robust patterned activity from leg motoneurons in the isolated adult CNS. As in the larva, levator and depressor motoneurons innervating the same leg were active in antiphase. Unlike fictive crawling, however, bursts of activity in levator or depressor motoneurons of one leg alternated with bursts in the homologous motoneurons innervating the opposite leg of the same segment and the leg on the same side in the adjacent segment. The most common mode of intersegmental activity generated by the isolated adult CNS resembled an alternating tripod gait, which is displayed, albeit infrequently, during walking in intact adult Manduca. A detailed analysis revealed specific differences between the patterned motor activity that is evoked from the isolated adult CNS and activity patterns observed during walking in intact animals, perhaps indicating an important role for sensory feedback. Nevertheless, the basic similarity to adult walking and clear distinctions from the larval fictive crawling pattern suggest that changes within the CNS contribute to alterations in locomotor activity during metamorphosis. Electronic Publication     

Effects of scaphognathite nerve stimulation on the acutely deafferented crab ventilatory central pattern generator

1. Sensory axons from crab (Carcinus maenas) scaphognathites enter the thoracic ganglion primarily via the LNb branch of the levator nerve. The LNa branch of the levator nerve and the depressor nerve each contain relatively few sensory axons.
2. Acutely deafferented ventilatory central pattern generators show a free running burst rate which is lower than that observed in intact crabs. Electrical stimulation of the levator nerve, or of its LNb branch, increases the burst rate in a frequency dependent manner. Stimulation at high enough intensity to recruit afferents will restart a paused motor rhythm. Stimulation of the levator nerve with short pulse trains phase resets and can entrain the rhythm.
3. In addition to increasing the burst rate, LNb stimulation also causes a progressive elimination of motor neurons from the bursts as the stimulating frequency increases, probably due to depolarization of the 3 oval organ ‘giant’ afferent axons in this branch. Intracellular depolarization of single oval organ afferents will also inhibit some motor neurons as well as slow or stop the rhythm.
4. Continuous stimulation of the depressor nerve does not affect the ganglionic burst rate and this nerve contains only a few small diameter afferent axons; however, brief trains of stimuli can reset the rhythm in a phase-dependent manner.

     

The scolopidial organs in the first antennal segment in Allacma fusca (Collembola,Sminthuridae)

Summary The proprioceptors of the musculature moving the second antennal segment in the collembolan Allacma fusca were examined with the electron microscope. There are five muscles, the most important of which appear to be a levator and a depressor muscle. Only these two muscles are monitored by proprioceptors. These proprioceptors, the scolopidia, are referred to here as the levator (l-) and the depressor (d-) scolopidium. The former contains two, the latter one sensory cell.Both scolopidia deviate from the usual pattern in that they have unmodified dendritic outer segments (no dilatations, no electron-dense material) and are enveloped by only one cell. But l- and d-scolopidia also differ from one another. The dendritic inner segments of the l-scolopidium are branched to an h-shaped pattern, with one branch ending on the levator muscle and the other running to the antennal nerve where the perikarya are located. In the d-scolopidium a muscle fiber of about 1 m diameter (140–320 myosin filaments) accompanies the scolopidium for a distance of about 0.5 m.On the basis of the structural features it is hypothesized that (1) the mechanical forces possibly act on the membranes of the dendritic inner segments, (2) the small muscle parallel to the d-scolopidium is a receptor muscle, and (3) both scolopidia are highly derivative.Dedicated to Professor Dietrich Burkhardt on the occasion of his 60th birthday     

Structural organization of two fast,rhythmically active crustacean muscles

Summary The organization of the flagellum abductor muscle and of a scaphognathite levator muscle of the green crab, Carcinus maenas, has been compared quantitatively using light and electron microscopy. These muscles are rhythmically active at relatively high frequencies and for long durations. Fibers of both muscles are interconnected to form fascicles of 50 or more fibers within which there is cytoplasmic continuity. A single muscle is made up of 8–12 fascicles. Individual fibers consist of a peripheral rind of densely packed mitochondria, a thick region of glycogen granules, and myofibrils arranged into scattered central islands. Less than half the volume-density of these muscles is contractile material, the balance being largely mitochondria and glycogen. The fibers within a muscle are structurally similar. They have short sarcomeres (about 2 m), thin to thick filament ratios of about 3:1, and junctions between the sarcoplasmic reticulum and the transverse tubules at the M line. Sarcoplasmic reticulum occupies about 10% of the myofibrillar volume-density. A well developed sarcoplasmic reticulum appears to underlie the capacities of these two muscles for high frequency contraction; extensive mitochondria and glycogen stores should confer fatigue resistance under both aerobic and anaerobic conditions.     

Monosynaptic connections mediate resistance reflex in crayfish (Procambarus clarkii) walking legs

Summary In crustacean walking legs, the coxo-basipodite chordotonal organ (CB) composed of about 50 sensory cells, evokes a resistance reflex in the levator (Lev) and depressor (Dep) muscles responsible for the movements of the coxo-basipodite joint where it is located. Mechanical stimulation of the CB strand and electrical stimulation of its sensory nerve have been performed along with systematic intracellular recordings from CB terminals (CB T) and levator (Lev) or depressor (Dep) motoneurons (MNs) in order to study their connections. Measurements of conduction times in the CB nerve demonstrated different pools of sensory fibres, the fastest of which reach the ganglion in 2.5 ms. During imposed movements to the CB strand, intracellularly recorded Lev or Dep MN display EPSPs that are correlated to spikes in the CB nerve, their delays are incompatible with a polysynaptic pathway. Systematic stimulation of the CB nerve demonstrates that about 4 to 8 CB fibres are connected with each Lev or Dep MN. Classical tests for monosynaptic connections indicate that EPSPs occurring between 3 ms and 6 ms correspond mainly to monosynaptic connections with CB T, whereas IPSPs (the latencies of which are above 12 ms) are polysynaptic. In spite of the high selectivity of the CB T onto MNs, eight simultaneous intracellular recordings of coupled CB T and MN (out of more than 300 MNs penetrated) have allowed a direct measurement of synaptic delays (less than 1 ms). The functional significance of these results is discussed in relation to the proprioceptive control of locomotor movements.Abbreviations CB Coxo-basipodite chordotonal organ - CB n CB sensory nerve - CB T CB sensory terminal - Dep depressor - Lev levator - MN motoneuron     

Ventilatory responses to ambient oxygen in stressed and fully settled shore crabs Carcinus maenas (L.)

Scaphognathite activity and ventilatory responses to changes of ambient oxygen have been studied in stressed and fully settled crabs, Carcinus maenas (L.). Compared with resting, fully settled animals, resting stressed crabs exhibited very high values of scaphognathite beat frequency, negative hydrostatic pressure in the gill chamber and amount of time spent ventilating, suggesting a much elevated ventilatory flow rate. Unlike fully settled animals, stressed crabs did not show significant ventilatory responses to changes of ambient oxygenation.     

Sensorimotor pathways involved in interjoint reflex action of an insect leg

Coordination of motor output between leg joints is crucial for the generation of posture and active movements in multijointed appendages of legged organisms. We investigated in the stick insect the information flow between the middle leg femoral chordotonal organ (fCO), which measures position and movement in the femur-tibia (FT) joint and the motoneuron pools supplying the next proximal leg joint, the coxa-trochanteral (CT) joint. In the inactive animal, elongation of the fCO (by flexing the FT joint) induced a depolarization in eight of nine levator trochanteris motoneurons, with a suprathreshold activation of one to three motoneurons. Motoneurons of the depressor trochanteris muscle were inhibited by fCO elongation. Relaxation signals, i.e., extension of the FT joint, activated both levator and depressor motoneurons; i.e., both antagonistic muscles were coactivated. Monosynaptic as well as polysynaptic pathways contribute to interjoint reflex actions in the stick insect leg. fCO afferents were found to induce short latency EPSPs in levator motoneurons, providing evidence for direct connections between fCO afferents and levator motoneurons. In addition, neuronal pathways via intercalated interneurons were identified that transmit sensory information from the fCO onto levator and/or depressor motoneurons. Finally, we describe two kinds of alterations in interjoint reflex action: (a) With repetitive sensory stimulation, this interjoint reflex action shows a habituation-like decrease in strength. (b) In the actively moving animal, interjoint reflex action in response to fCO elongation, mimicking joint flexion, qualitatively remained the same sign, but with a marked increase in strength, indicating an increased influence of sensory signals from the FT joint onto the adjacent CT joint in the active animal. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 891–913, 1997     

山溪鲵头部肌肉大体解剖

通过染色、解剖、观察和绘图对山溪鲵头部肌肉做了详细描述.山溪鲵头部肌肉包括头侧肌肉、头腹肌肉、眼部肌肉及喉部肌肉.其肌肉组成与有尾类头部肌肉的一般构成基本一致.从第二鳃弓游离端内侧发出一细条状肌纤维,附着在三角骨外侧末端,此种情况在以前其他有尾类肌肉系统研究中未见报道.     

The ventilation mechanism of the Pacific hagfish Eptatretus stoutii

We made anatomical and physiological observations of the breathing mechanisms in Pacific hagfish Eptatretus stoutii, with measurements of nostril flow and pressure, mouth and pharyngo-cutaneous duct (PCD) pressure and velum and heart impedance and observations of dye flow patterns. Resting animals frequently exhibit spontaneous apnea. During normal breathing, water flow is continuous at a high rate (~125 ml kg⁻¹ min⁻¹ at 12°C) powered by a two-phase unidirectional pumping system with a fast suction pump (the velum, ~22 min⁻¹) for inhalation through the single nostril and a much slower force pump (gill pouches and PCD ~4.4 min⁻¹) for exhalation. The mouth joins the pharynx posterior to the velum and plays no role in ventilation at rest or during swimming. Increases in flow up to >400 ml kg⁻¹ min⁻¹ can be achieved by increases in both velum frequency and stroke volume and the ventilatory index (product of frequency x nostril pressure amplitude) provides a useful proxy for ventilatory flow rate. Two types of coughing (flow reversals) are described. During spontaneous swimming, ventilatory pressure and flow pulsatility becomes synchronised with rhythmic body undulations.     

Tail myology and flight behaviour: Differences between caracaras,falcons and forest falcons (Aves,Falconiformes)

Caracaras, falcons and forest falcons, which are representative of the three subfamilies of the family Falconidae, have different flight behaviour. Since, during flight, the tail works in coordination with the wings, the tail muscles could be indicative of the type of flight behaviour. The aim of this work was to describe in detail the little-known tail muscles of the Falconidae and to explore their possible association with this different behaviour, by using the muscle mass as an indicator. To this end, the tail muscles of 18 specimens representing the three subfamilies of Falconidae were dissected, weighed and their percentage to the body mass calculated. The possible differences in tail muscle mass between Falconinae and Polyborinae were explored with a Bayesian statistical approach. In all species, the muscles depressor caudae and levator caudae had the highest mass values (0.028%–0.329% and 0.120%–0.274%, respectively), in accordance with the key movements performed during flight, that is, the tail depression and elevation. The total muscle masses of Falconinae and those of Polyborinae were significantly different (p < 0.05). This difference can be related with the different flight behaviour of falcons and caracaras, that is, fast and erratic flight, respectively.     

Effects of Dietary Lactiplantibacillus plantarum subsp. plantarum L7, Alone or in Combination with Limosilactobacillus reuteri P16, on Growth,Mucosal Immune Responses,and Disease Resistance of Cyprinus carpio

Skin mucosal lymphoid tissues of fish are the first line of defence against pathogen invasion. We investigated the effects of Lactiplantibacillus plantarum subsp. plantarum L7, singularly or in combination with Limosilactobacillus reuteri P16, on mucosal immunity and diseases resistance of carp Cyprinus carpio. C. carpio (average weight: 26.28 ± 1.02 g) were divided into five experimental groups. Fish in each group were fed with one of the following potential probiotic-supplemented diets: control (0 – basal diet), D1 (10⁷ CFU/g L7), D2 (10⁸ CFU/g L7), D3 (10⁹ CFU/g L7), and D4 (10⁸ CFU/g L7 + 10⁸ CFU/g P16). Eight weeks post-feeding, growth performance was higher in D4, with a final weight gain of 67.18 ± 1.47 g. Results showed a significantly higher skin mucosal lysozyme, alkaline phosphatase, mucus protein level, superoxide dismutase, and catalase activities in D2 and D4 compared to the control. However, potential probiotics had no significant effect on skin mucosal immunoglobulin level. Skin mucus of D4 exhibited stronger inhibition zones against pathogenic bacterial strains. Moreover, digestive enzyme activities (protease, lipase) were highest in D4. Intesinal lactic acid bacterial counts of fish fed combind probiotics (i.e. D4) was significantly higher than the control. Further, supplementation of potential probiotics altered the expression of IL-1β, TNF-α, and IL-10 cytokines. Fish from D4 exhibited significantly higher relative post-challenge survival (69.7%) against Aeromonas hydrophila, followed by D2 (66.67%). Therefore, the inclusion of L. plantarum subsp. plantarum L7 at 10⁸ CFU/g or in combination with L. reuteri P16 could enhance the growth performance, mucosal immune responses, and disease resistance of C. carpio.

     

On a technique for monitoring heart and scaphognathite activity in natantia

A modified impedance technique for monitoring heart and scaphognathite activity of crustaceans has been described. Examples are given of recordings of cardiac and ventilatory activity of Crangon crangon (L.), during a variety of its normal activities. The advantage of the technique in studies of small (≈ 0.3–0.4 g) crustaceans is discussed.     

The lower muscular balance of the face used to lift labial commissures

One of the weak points in face lifts is their failure to fully correct the ptosis of the labial commissures. This article illustrates a new technique to optimize this commissural repositioning in face lifts by using the muscular balances of the lower half of the face. There is, in effect, a third type of muscular balance, which acts on the commissural modiolus and is created by the opposing forces of the levator muscles (notably the zygomaticus major and the levator anguli oris) and the depressor muscles (principally the depressor anguli oris). Rarely a purely cutaneous problem, labial commissural ptosis is more a part of mediofacial ptosis affecting the entire soft tissue. I have used the malar subperiosteal face lift technique, the only approach that allows the centrofacial features to be lifted as a whole block, since late 1996 and have treated a series of more than 30 patients affected with mediofacial ptoses involving the malar eminences, the nasolabial folds, and the labial commissures. Retensioning the levator muscles was combined with wholesale subperiosteal release of the depressor muscles, notably the depressor anguli oris. Patient follow-up has lasted between 6 and 20 months. In all instances, this use of the lower facial muscular balances allowed optimal repositioning of the labial commissure. In particularly outstanding cases, unilateral release of the depressor muscles was used to correct facial asymmetry at the level of the lip commissures and thereby restore harmony and alignment. In 10 of our cases, this slackening of the depressor muscles was also used in conjunction with a peripheral face lift; the resulting heightening of the commissures was, in these cases, perhaps less spectacular, but it invariably contributed to the rejuvenation of the face.     

Neuromuscular coordination and proprioceptive control of rhythmical abdominal ventilation in intactLocusta migratoria migratorioides

Summary Within the fifth abdominal segment of intact locusts a group of dorso-ventral expiratory muscles and one inspiratory antagonist display alternating ventilatory patterns of three basic types. Accelerated movements in the dorso-ventral plane are supported by isometric activity of the intersegmental muscles which prevent extensions in the longitudinal axis.The intersegmental coupling of ventilatory motor patterns is strict during strong ventilation and loose and more metachronal with weaker pumping movements.In resting animals ventilatory rhythms are discontinuous and the long intervening pauses are interrupted by miniature inspirations only. Pumping series have a tendency to prolong the later ventilatory cycles, and interfering rhythms of different pumping types occur. Low concentrations of atmospheric CO₂ up to 3 % do not accelerate ventilatory rhythms.Afferent activity from proprioceptors could be related to ventilatory motor bursts and stimulation of the sensory nerve produces inspiratory bursts via the segmental ganglion.The neuronal mechanisms of synergistic and antagonistic muscle control as well as the segmental and intersegmental coordination and the effect of autonomous ganglionic oscillators in ventilation are discussed.     

Burst control: Synaptic conditions for burst generation in cortical layer 5 pyramidal neurons

The output of neocortical layer 5 pyramidal cells (L5PCs) is expressed by a train of single spikes with intermittent bursts of multiple spikes at high frequencies. The bursts are the result of nonlinear dendritic properties, including Na⁺, Ca²⁺, and NMDA spikes, that interact with the ~10,000 synapses impinging on the neuron’s dendrites. Output spike bursts are thought to implement key dendritic computations, such as coincidence detection of bottom-up inputs (arriving mostly at the basal tree) and top-down inputs (arriving mostly at the apical tree). In this study we used a detailed nonlinear model of L5PC receiving excitatory and inhibitory synaptic inputs to explore the conditions for generating bursts and for modulating their properties. We established the excitatory input conditions on the basal versus the apical tree that favor burst and show that there are two distinct types of bursts. Bursts consisting of 3 or more spikes firing at < 200 Hz, which are generated by stronger excitatory input to the basal versus the apical tree, and bursts of ~2-spikes at ~250 Hz, generated by prominent apical tuft excitation. Localized and well-timed dendritic inhibition on the apical tree differentially modulates Na⁺, Ca²⁺, and NMDA spikes and, consequently, finely controls the burst output. Finally, we explored the implications of different burst classes and respective dendritic inhibition for regulating synaptic plasticity.     

Physiological response to emersion in the amphibious crab Chasmagnathus granulata Dana (Decapoda Grapsidae): biochemical and ventilatory adaptations

The adaptation of Chasmagnathus granulata to air breathing depends on two types of physiological mechanisms: (1) Biochemical adjustments, comprising the achievement of new steady state values for partial pressure of carbon dioxide (P_CO2) and total carbon dioxide concentration (C_CO2). The initial increase in hemolymph bicarbonate is stabilized by dehydration to CO₂ presumably catalyzed by carbonic anhydrase (CA) at the basolateral side of the gill epithelium. Thus, an adequate transbranchial gradient of P_CO2 is restored. Inhibition of CA with acetazolamide (Az) reduces the rate of CO₂ excretion and elevates P_CO2. The respiratory acidosis caused by increased P_CO2 is compensated by increase in the difference between Na⁺ and Cl⁻ concentrations. Az does not affect hemolymph ionic concentrations. (2) Ventilatory control: untreated animals show a significant decrease in scaphognathite frequency (F_SC) during emersion, while Az treated crabs show a slight increase of this variable. F_SC of Az crabs tends to decrease with hemolymphatic CO₂, presumably by clearance of the CA inhibitor from hemolymph. These results suggest that C. granulata possess a ventilatory control based on a primary oxygen-dependent stimulus and a secondary one dependent on CO₂.     

The effect of single giant interneuron lesions on wind-evoked motor responses in the cockroach,Periplaneta americana

In order to determine the contribution of individual giant interneurons (GIs) to wind-evoked motor outputs, responses were recorded from depressor and levator motor neurons in the cockroach Periplaneta americana to wind puffs of different directions. The depressor response was generally stronger to wind from the ipsilateral rear than to wind from the contralateral rear. The levator response was more variable but was more often stronger to wind from the contralateral rear than to wind from the ipsilateral rear. These results are as expected based on behavioral responses to wind puffs. (Camhi and Tom, 1978). The depressor response was nearly or totally abolished by severing the ipsilateral connective of the nerve cord but was little affected by severing the contralateral connective. The levator reponse was greatly reduced for some angles by severing the ipsilateral connective and for other angles by severing the contralateral connective. Blocking conduction in the ipsilateral GI 5 nearly or completely abolished the depressor response to wind from the ipsilateral rear. This is the first time that a GI has been shown to be necessary, not just sufficient, for a given motor output.     

Effects of dimethoate on snail B-esterase and growth as a function of dose,time and exposure route in a laboratory bioassay

The aim was to study the effects of dimethoate on enzymatic targets and on the growth of Helix aspersa for different times and modes of exposure under laboratory conditions. Young snails were exposed to increasing dimethoate concentrations in the food (D.exp) or in an artificial substrate (S.exp) for 1, 2, 7 and 14 days. Both acetylcholinesterase (AChE) and carboxylesterase (CaE) activities were measured in the foot of the snails for each concentration and exposure time tested. Growth was evaluated after 7 days of exposure. AChE inhibition, dose-dependent for all lengths of exposure, was stronger in S.exp. AChE was more sensitive than CaE for both modes of exposure. IC₅₀-7 days was 38.3μg g^-1 in D.exp and 11.7μg g^-1 in S.exp for AChE and was higher than 150 μg g^-1 in two exposure modes for CaE. AChE activity decreased from the first day to reach maximum inhibition after 7 days of exposure. As noted for B-esterase activities, growth inhibition was stronger in S.exp and was only significant for AChE inhibition of >90%. The present results show that AChE activity could be used to give early warning of toxic effects of dimethoate in terrestrial gastropods.     

Engineered glucose isomerase from <Emphasis Type="Italic">Streptomyces</Emphasis> sp. SK is resistant to Ca<Superscript>2+</Superscript> inhibition and Co<Superscript>2+</Superscript> independent

The role of two amino acid residues linked to the two catalytic histidines His54 and His220 in kinetics and physicochemical properties of the Streptomyces sp. SK glucose isomerase (SKGI) was investigated by site-directed mutagenesis and molecular modeling. Two single mutations, F53L and G219D, and a double mutation F53L/G219D was introduced into the xylA SKGI gene. The F53L mutation increases the thermostability and the catalytic efficiency and also slightly shifts the optimum pH from 6.5 to 7, but displays a profile being similar to that of the wild-type enzyme concerning the effect of various metal ions. The G219D mutant is resistant to calcium inhibition retaining about 80% of its residual activity in 10 mM Ca²⁺ instead of 10% for the wild-type. This variant is activated by Mn²⁺ ions, but not Co²⁺, as seen for the wild-type enzyme. It does not require the latter for its thermostability, but has its half-life time displaced from 50 to 20 min at 85°C. The double mutation F53L/G219D restores the thermostability as seen for the wild-type enzyme while maintaining the resistance to the calcium inhibition. Molecular modeling suggests that the increase in thermostability is due to new hydrophobic interactions stabilizing α2 helix and that the resistance to calcium inhibition is a result of narrowing the binding site of catalytic ion.