Abnormal nociception and opiate sensitivity of STOP null mice exhibiting elevated levels of the endogenous alkaloid morphine

Calcitonin gene-related peptide (CGRP) plays an important role in peripheral and central sensitization. CGRP also is a key molecule in the spino-parabrachial-amygdaloid pain pathway. Blockade of CGRP1 receptors in the spinal cord or in the amygdala has antinociceptive effects in different pain models. Here we studied the electrophysiological mechanisms of behavioral effects of CGRP in the amygdala in normal animals without tissue injury. Whole-cell patch-clamp recordings of neurons in the latero-capsular division of the central nucleus of the amygdala (CeLC) in rat brain slices showed that CGRP (100 nM) increased excitatory postsynaptic currents (EPSCs) at the parabrachio-amygdaloid (PB-CeLC) synapse, the exclusive source of CGRP in the amygdala. Consistent with a postsynaptic mechanism of action, CGRP increased amplitude, but not frequency, of miniature EPSCs and did not affect paired-pulse facilitation. CGRP also increased neuronal excitability. CGRP-induced synaptic facilitation was reversed by an NMDA receptor antagonist (AP5, 50 μM) or a PKA inhibitor (KT5720, 1 μM), but not by a PKC inhibitor (GF109203X, 1 μM). Stereotaxic administration of CGRP (10 μM, concentration in microdialysis probe) into the CeLC by microdialysis in awake rats increased audible and ultrasonic vocalizations and decreased hindlimb withdrawal thresholds. Behavioral effects of CGRP were largely blocked by KT5720 (100 μM) but not by GF109203X (100 μM). The results show that CGRP in the amygdala exacerbates nocifensive and affective behavioral responses in normal animals through PKA- and NMDA receptor-dependent postsynaptic facilitation. Thus, increased CGRP levels in the amygdala might trigger pain in the absence of tissue injury.     

Changes in the Parameters of Quantal Acetylcholine Release after Activation of PAR1-Type Thrombin Receptors at the Mouse Neuromuscular Junctions

In mature and newly formed neuromuscular synapses of mouse skeletal muscles, miniature endplate potentials (MEPPs) and multiquantal endplate potentials (EPPs) evoked by a single stimulation of the nerve were recorded using intracellular microelectrode technique. The mechanisms underlying the changes in spontaneous and evoked acetylcholine (ACh) release caused by the activation of PAR1-type muscle receptors induced by their peptide agonist TRAP6-NH₂ were studied. It has been shown for the first time that, in either mature or newly formed motor synapses, the activation of PAR1 that lack presynaptic localization causes a sustained increase in the MEPP amplitude due to the increase in the ACh quantal size at the presynaptic level. It was found that phospholipase C (PLC) participates in the signaling mechanism triggered by the PAR1 activation. Exogenously applied brain-derived neurotrophic factor (BDNF) mimics the effect of activation of PAR1 by TRAP6-NH₂. Moreover, an increase in the MEPP amplitude caused by the peptide PAR1 agonist was fully prevented by blocking the BDNF receptors–tropomyosin receptor kinases B (TrkB). Thus, it has been shown for the first time that the increase in ACh quantal size due to the activation of PAR1 in motor synapses is mediated by a complex signaling cascade that starts at the postsynaptic level of the motor synapse and ends at the presynaptic level. It is expected that the activation of PAR1 at the muscle fiber membrane followed by the PLC upregulation results in the release of neurotrophin BDNF as a retrograde signal. Its effect on the presynaptic TrkB receptors triggers the cascade leading to an increase in the quantal size of ACh.     

Properties of miniature postsynaptic currents during depolarization-induced release at a cholinergic neuroneuronal synapse

1. Miniature postsynaptic currents were analyzed at an inhibitory cholinergic neuroneuronal synapse in the buccal ganglion of Aplysia. Under double voltage-clamp, it was possible to induce postsynaptic currents by long-duration depolarizations of the presynaptic neuron and to analyze these as the linear summation of individual miniature postsynaptic currents (MPSCs). The amplitude of these miniature currents (imin) was calculated from the ratio of the variance of the noise (E2) to the mean of the postsynaptic current (Im), according to Campbell's theorem, with imin = 2E2/Im. Their decay time (tau min) was obtained from the cutoff frequencies of the power spectra obtained from the noise. 2. Neither the conductance nor the decay time of MPSCs was voltage dependent. However, imin appeared to decrease when the quantal content of the response increased. Meanwhile, tau min increased slightly with Imin. 3. Carbamylcholine was injected into the neuropile and this led to a decrease in imin and a slight increase in tau min. 4. Power spectra obtained after the application of inhibitors of acetylcholinesterase (AChE), with or without curare, suggested that acetylcholine (ACh) does not accumulate during large depolarizations. 5. The possible origin of the nonlinear relationship between the variance and the mean of the postsynaptic currents is discussed.     

Subunits in quantal transmission at the mouse neuromuscular junction: tests of peak intervals in amplitude distributions

The regular spacing of peaks throughout the amplitude distribution of miniature end-plate potentials, quantal evoked end-plate potentials and quantal currents was demonstrated using autocorrelations and power density spectra calculated from the number of events in the successive bins of the histograms built by Matteson et al. (1979), Kriebel & Florey (1983) and Erxleben & Kriebel (1984). At the same mouse neuromuscular junction, the calculated interpeak was constant for evoked and spontaneous quantal releases, throughout sequential sampling and after change of bin size. The presence of regular peak intervals supports the hypothesis that quantal potentials are composed of potential subunits the size of the smallest subminiature potential. Challenging the hypothesis of an acetylcholine quantum composed of acetylcholine subunits, a postsynaptic origin of the subunit is proposed on the basis of the spatial arrangement in rows of the ACh receptors. The ACh-saturating patch evoked by a quantum release (Land et al., 1980, 1981) activates 10-20 rows of receptors, which is roughly the number of subunits composing a quantal event. Therefore the position of the ACh patch or the continuous variations in its size might cause stepwise variations in the total number of ACh receptors activated by an ACh quantum.     

The Role of Endogenous Calcitonin Gene-Related Peptide in the Neurotransmitter Quantal Size Increase in Mouse Neuromuscular Junctions

Changes in parameters of spontaneous acetylcholine (ACh) quantal secretion caused by prolonged high-frequency burst activity of neuromuscular junctions and possible involvement of endogenous calcitonin gene-related peptide (CGRP) and its receptors in these changes were studied. With this purpose, miniature endplate potentials (MEPPs) were recorded using standard microelectrode technique in isolated neuromuscular preparations of m. EDL–n. peroneus after a prolonged high-frequency nerve stimulation (30 Hz for 2 min). An increase in the MEPP amplitudes and time course was observed in the postactivation period that reached maximum 20–30 min after nerve stimulation and progressively faded in the following 30 min of recording. Inhibition of vesicular ACh transporter with vesamicol (1 μM) fully prevented this “wave” of the MEPP enhancement. This indicates the presynaptic origin of the MEPP amplitude increase, possibly mediated via intensification of synaptic vesicle loading with ACh and subsequent increase of the quantal size. Competitive antagonist of the CGRP receptor, truncated peptide isoform CGRP_8–37 (1 μM), had no effect on spontaneous secretion parameters by itself but was able to prevent the appearance of enhanced MEPPs in the postactivation period. This suggests the involvement of endogenous CGRP and its receptors in the observed MEPP enhancement after an intensive nerve stimulation. Ryanodine in high concentration (1 μM) that blocks ryanodine receptors and stored calcium release did not influence spontaneous ACh secretion but prevented the increase of the MEPP parameters in the postactivation period. Altogether, the data indicate that an intensive nerve stimulation, which activates neuromuscular junctions and muscle contractions, leads to a release of endogenous CGRP into synaptic cleft and this release strongly depends on the efflux of stored calcium. The released endogenous CGRP is able to exert an acute presynaptic effect on nerve terminals, which involves its specific receptor action and intracellular cascades leading to intensification of ACh loading into synaptic vesicles and an increase in the ACh quantal size.     

Effects of ionophore X-537A on spontaneous transmitter release and the ultrastructure of locust neuromuscular junctions.

The spontaneous quantal release of neurotransmitter and the fine structure of a glutamatergic synapse has been examined in the presence of ionophore X-537A. Bath applications of X-537A to extensor tibiae nerve-muscle preparations of locust, Schistocerca gregaria, increased the frequency of miniature excitatory post-synaptic potentials (min. e.p.s.p.'s). This action was completely reversible, if preparations were exposed to ionophore for less than 60 min. Application of ionophore for longer times, i.e., longer than 60 min., transiently elevated min. e.p.s.p. frequency to greater than 100/s. Following this period of high activity, miniature frequency declined to 0.4/s and were mostly of "giant" miniature potentials type. The frequency and amplitude of these "giant" miniature potentials remained unchanged after subsequent washing with standard saline. Exposure of nerve terminals to ionophore for 60 min. produced no ultrastructure changes. Longer ionophore treatments, however, led to depletion of synaptic vesicles, damaged mitochondria and disintegration of microtubules and neurofilaments within nerve terminals, suggesting irreversible changes at the locust neuromuscular junction.     

Regulation of neuromuscular synapse development by glial cell line-derived neurotrophic factor and neurturin.

Glial cell line-derived neurotrophic factor (GDNF) is known for its potent effect on neuronal survival, but its role in the development and function of synapses is not well studied. Using Xenopus nerve-muscle co-cultures, we show that GDNF and its family member neurturin (NRTN) facilitate the development of the neuromuscular junction (NMJ). Long-term application of GDNF significantly increased the total length of neurites in the motoneurons. GDNF also caused an increase in the number and the size of synaptic vesicle clustering, as demonstrated by synaptobrevin-GFP fluorescent imaging, and FM dye staining. Electrophysiological experiments revealed two effects of GDNF on synaptic transmission at NMJ. First, GDNF markedly increased the frequency of spontaneous transmission and decreased the variability of evoked transmission, suggesting an enhancement of transmitter secretion. Second, GDNF elicited a small increase in the quantal size, without affecting the average rise and decay times of synaptic currents. Imaging analysis showed that the size of acetylcholine receptor clusters at synapses increased in muscle cells overexpressing GDNF. Neurturin had very similar effects as GDNF. These results suggest that GDNF and NRTN are new neuromodulators that regulate the development of the neuromuscular synapse through both pre- and postsynaptic mechanisms.     

Formation of functional synaptic connections between cultured cortical neurons from agrin-deficient mice.

Numerous studies suggest that the extracellular matrix protein agrin directs the formation of the postsynaptic apparatus at the neuromuscular junction (NMJ). Strong support for this hypothesis comes from the observation that the high density of acetylcholine receptors (AChR) normally present at the neuromuscular junction fails to form in muscle of embryonic agrin mutant mice. Agrin is expressed by many populations of neurons in the central nervous system (CNS), suggesting that this molecule may also play a role in neuron-neuron synapse formation. To test this hypothesis, we examined synapse formation between cultured cortical neurons isolated from agrin-deficient mouse embryos. Our data show that glutamate receptors accumulate at synaptic sites on agrin-deficient neurons. Moreover, electrophysiological analysis demonstrates that functional glutamatergic and gamma-aminobutyric acid (GABA)ergic synapses form between mutant neurons. The frequency and amplitude of miniature postsynaptic glutamatergic and GABAergic currents are similar in mutant and age-matched wild-type neurons during the first 3 weeks in culture. These results demonstrate that neuron-specific agrin is not required for formation and early development of functional synaptic contacts between CNS neurons, and suggest that mechanisms of interneuronal synaptogenesis are distinct from those regulating synapse formation at the neuromuscular junction.     

Constitutive secretion of exogenous neurotransmitter by nonneuronal cells: implications for neuronal secretion.

Fibroblasts in cell culture were loaded with exogenous neurotransmitter acetylcholine (ACh). ACh secretion from loaded cells was detected by whole-cell patch clamp recordings from Xenopus myocytes manipulated into contact with ACh-loaded cells. Two different approaches were used for ACh loading. In the first approach, fibroblasts were incubated in the culture medium containing ACh. Recordings from myocytes revealed fast inward currents that resemble miniature endplate currents found at neuromuscular synapses. The currents observed in recordings from myocytes were due to exocytosis of ACh-containing vesicles. Although exogenous ACh penetrated through the plasma membrane of fibroblasts during incubation and was present in the cytoplasm at detectable levels, cytoplasmic ACh did not contribute to the quantal ACh secretion. In the second approach, exogenous ACh was loaded into the cytoplasm of fibroblasts by microinjection. Under these experimental conditions, fibroblasts also exhibited spontaneous quantal ACh secretion. Analysis of the exocytotic events in fibroblasts following two different protocols of ACh loading revealed that the vesicular compartments responsible for uptake of exogenous ACh are associated with the endocytic recycling pathway. Extrapolation of our results to neuronal cells suggest that in cholinergic neurons, in addition to genuine synaptic vesicles, ACh can be secreted by the vesicles participating in endosomal membrane recycling.     

Pre- and postsynaptic mechanisms in Hebbian activity-dependent synapse modification

We have used a three compartment tissue culture system that involved two separate populations of cholinergic neurons in the side compartments that converged on a common target population of myotubes in the center compartment. Activation of the axons from one population of neurons produced selective down-regulation of the synaptic inputs from the other neuronal population (when the two inputs innervated the same myotubes). The decrease in heterosynaptic inputs was mediated by protein kinase C (PKC). An activity-dependent action of protein kinase A (PKA) was associated with the stimulated input and this served to selectively stabilize this input. These changes associated with PKA and PKC activation were mediated by alterations in the number of acetylcholine receptors at the neuromuscular junction. These results suggest that neuromuscular electrical activity produces postsynaptic activation of both PKA and PKC, with the latter producing generalized synapse weakening and the former a selective synapse stabilization. Treatment of the neuronal cell body and axon to increase PKC activity by putting phorbal ester (PMA) in the side chamber did not affect synaptic transmission (with or without stimulation). By contrast, PKA blockade in the side compartment did produce an activity-dependent decrease in synaptic efficacy, which was due to a decrease in quantal release of neurotransmitter. Thus, when the synapse is activated, it appears that presynaptic PKA action is necessary to maintain transmitter output.     

Evidence for a presynaptic action of chlordimeform at the insect neuromuscular junction

The mechanism of action of chlordimeform on the mealworm nerve-muscle preparation was studied with microelectrodes. Chlordimeform affected neither the mean amplitude nor the frequency of spontaneous miniature excitatory postsynaptic potentials. Extracellular focal recordings show that in the presence of 0.8 mM chlordimeform the presynaptic spike is almost unchanged, but the quantal content for evoked transmitter release is reduced. It is suggested that chlordimeform decreases the influx of calcium at the presynaptic terminal during the active phase of the nerve terminal action potential, thereby inhibiting evoked transmitter release.     

The role of pannexin 1 in the purinergic regulation of synaptic transmission in mouse motor synapses

The role of pannexin 1 in the release to the extracellular space of ATP/adenosine modulating the acetylcholine (ACh) secretion was studied in mouse diaphragm motor synapses. Using neuromuscular preparations obtained from wild-type and pannexin-1 knockout mice, the miniature endplate potential (MEPPs) and evoked endplate potentials (EPPs) were recorded in combination with pharmacological modulation of P2-type ATP receptors and A₁-type adenosine receptors. Selective inhibition of A₁ receptors with DPCPX or P2 receptors with PPADS increased quantal content of EPPs in wild-type mice. MRS 2211, selective antagonist of P2Y13 receptors, produced the same effect. Activation of receptors A₁ or P2Y₁₃ by their agonists (2-CADO and IDP, respectively) decreased the EPP quantal content. It means that the activity of endogenous ATP and adenosine is synergistic and directed to depression of the ACh release. ARL67156, an inhibitor of synaptic ecto-ATPases, which blocks the hydrolysis of ATP to adenosine and increases the level of ATP in the synaptic cleft, prolonged EPPs without changing their quantal content. In pannexin-1 knockout mice there were no changes in the EPP quantal content and in other parameters of synaptic transmission as compared to wildtype mice. However, downregulation of purinergic effects with antagonists of A₁ or P2 receptors (DPCPX, PPADS, MRS 2211) did not change EPP quantal content and any other parameters of spontaneous or evoked ACh release in all cases. ARL67156 did not alter the temporal parameters of EPPs, either. Nevertheless, 2-CADO, the A₁-type receptor agonist, decreased the EPP quantal content, while the agonist of P2Y₁₃ receptors decreased the MEPP amplitude. Thus, in mice lacking pannexin 1, procedures revealing the presence and regulatory activity of synaptic ATP/adenosine did not change the parameters of synaptic transmission. The obtained data substantiate a mandatory role of pannexin 1 in the purinergic regulation of motor synapse activity by endogenous ATP/adenosine.     

Formation of functional synaptic connections between cultured cortical neurons from agrin‐deficient mice

Numerous studies suggest that the extracellular matrix protein agrin directs the formation of the postsynaptic apparatus at the neuromuscular junction (NMJ). Strong support for this hypothesis comes from the observation that the high density of acetylcholine receptors (AChR) normally present at the neuromuscular junction fails to form in muscle of embryonic agrin mutant mice. Agrin is expressed by many populations of neurons in the central nervous system (CNS), suggesting that this molecule may also play a role in neuron–neuron synapse formation. To test this hypothesis, we examined synapse formation between cultured cortical neurons isolated from agrin‐deficient mouse embryos. Our data show that glutamate receptors accumulate at synaptic sites on agrin‐deficient neurons. Moreover, electrophysiological analysis demonstrates that functional glutamatergic and gamma‐aminobutyric acid (GABA)ergic synapses form between mutant neurons. The frequency and amplitude of miniature postsynaptic glutamatergic and GABAergic currents are similar in mutant and age‐matched wild‐type neurons during the first 3 weeks in culture. These results demonstrate that neuron‐specific agrin is not required for formation and early development of functional synaptic contacts between CNS neurons, and suggest that mechanisms of interneuronal synaptogenesis are distinct from those regulating synapse formation at the neuromuscular junction. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 547–557, 1999     

Long release latencies are increased by acetylcholine at frog endplate

Uni-quantal endplate currents (EPCs) were recorded extracellularly at the frog neuromuscular synapse and their latency dispersions expressed as P(90) were estimated in the presence of acetylcholine. Stimulation-evoked EPCs with long release latencies increased in number when acetylcholine was applied. P90, which is designated as the interval between the minimal synaptic delay and the time at which 90 per cent of all measured uni-quantal EPCs had occurred, was significantly and reversibly increased by 66 per cent from 0.51 ms to 0.85 ms in the presence of 5x10(-4) M acetylcholine. This indicates that the evoked release pattern is less synchronous and the increased asynchrony leads to a substantial drop (by 28 per cent) in the amplitude of reconstructed multi-quantal currents.     

Nicardipine inhibits axon conduction but causes dual changes of acetylcholine release in the mouse motor nerve

The effects of nicardipine, a dihydropyridine Ca2(+)-channel antagonist, on neuromuscular transmission and impulse-evoked release of acetylcholine were compared with those of nifedipine. In the isolated mouse phrenic nerve diaphragm, nicardipine (50 microM), but not nifedipine (100 microM), induced neuromuscular block, fade of tetanic contraction, and dropout or all-or-none block of end-plate potentials. Nicardipine had no significant effect on the resting membrane potential and the amplitude of miniature end-plate potentials but increased the frequency and caused the appearance of large size miniature potentials. The quantal contents of evoked end-plate potentials were increased. In the presence of tubocurarine, however, nicardipine depressed the amplitude of end-plate potentials. The compound nerve action potential was also decreased. It is concluded that nicardipine blocks neuromuscular transmission by acting on Na+ channels and inhibits axonal conduction. Nicardipine appeared to affect the evoked release of acetylcholine by dual mechanisms, i.e., an enhancement presumably by an agonist action on Ca2+ channels, like Bay K 8644 and nifedipine, and inhibition by an effect on Na+ channels, like verapamil and diltiazem. In contrast with its inactivity on the amplitude of miniature end-plate potentials, depolarization of the end plate in response to succinylcholine was greatly depressed. The contractile response of baby chick biventer cervicis muscle to exogenous acetylcholine was noncompetitively antagonized by nicardipine (10 microM), but was unaffected by nifedipine (30 microM). These results may implicate that nicardipine blocks the postsynaptic acetylcholine receptor channel by enhancing receptor desensitization or by a use-dependent effect.     

Pre- and post-synaptic actions of memantine at cholinergic central synapse of Achatina fulica

The effects of memantine, an anticonvulsant, on (1) postsynaptic currents (PSC), (2) the responses to microperfused acetylcholine (ACh) and (3) Ca-currents were studied at voltage-clamped identified Lp10 neuron of Achatina fulica. Memantine (5.58 μM) evoked PSCs; however, it did not affect responses of Lp 10 neuron to microperfused ACh. PSCs evoked by memantine were blocked by d-tubocurarine (d-Tc) and removed in low Ca²⁺-high Mg²⁺ solutions. Memantine did not evoke PSCs if the same neurone was physically isolated. The PSCs evoked by memantine and microperfusion of ACh opened the same Cl-currents and both currents were blocked by d-Tc. Memantine increased the amplitude of the voltage-activated Ca-current at the neurones neighborhood to Lp10 neuron by 43±7%. Flunarizine (10 μM), a Ca channel antagonist, decreased 66±5% of the amplitude of Ca current and it also prevented memantine-induced PSCs. The amplitude of responses to microperfused ACh was not affected by flunarizine. These results suggest that memantine triggers the release of ACh at this synapse and this effect of memantine seems to be secondary to memantine-induced increase of Ca²⁺ entry through voltage activated Ca channels.     

Pre‐ and postsynaptic mechanisms in Hebbian activity‐dependent synapse modification

We have used a three compartment tissue culture system that involved two separate populations of cholinergic neurons in the side compartments that converged on a common target population of myotubes in the center compartment. Activation of the axons from one population of neurons produced selective down‐regulation of the synaptic inputs from the other neuronal population (when the two inputs innervated the same myotubes). The decrease in heterosynaptic inputs was mediated by protein kinase C (PKC). An activity‐dependent action of protein kinase A (PKA) was associated with the stimulated input and this served to selectively stabilize this input. These changes associated with PKA and PKC activation were mediated by alterations in the number of acetylcholine receptors at the neuromuscular junction. These results suggest that neuromuscular electrical activity produces postsynaptic activation of both PKA and PKC, with the latter producing generalized synapse weakening and the former a selective synapse stabilization. Treatment of the neuronal cell body and axon to increase PKC activity by putting phorbal ester (PMA) in the side chamber did not affect synaptic transmission (with or without stimulation). By contrast, PKA blockade in the side compartment did produce an activity‐dependent decrease in synaptic efficacy, which was due to a decrease in quantal release of neurotransmitter. Thus, when the synapse is activated, it appears that presynaptic PKA action is necessary to maintain transmitter output. Published 2002 Wiley Periodicals, Inc. J Neurobiol 52: 241–250, 2002     

Estimates of quantal content during 'chemical potentiation' of transmitter release.

The number of quantal transmitter packets (m), released from motor nerve terminals in response to a single stimulus, has been estimated from the ratio of the amplitudes of endplate currents (e.p.c.) to spontaneous miniature endplate currents (m.e.p.c.), in voltage-clamped endplates of the frog. At 6 degrees C, the average value of m at normal nerve-muscle junctions was about 300. If allowance is made for the temporal dispersion of quantal transmitter release during the e.p.c., this value is increased by about 30%. After treatment with diaminopyridine or tetraethylammonium, transmitter release in response to a nerve stimulus is greatly enhanced and values of m exceeding 10(4) are frequently found. Moreover, the duration of the e.p.c. becomes much longer than that of the m.e.p.cs. The number of packets then liberated during the e.p.c. is much larger than the number of 'active zones' of the endplate and may even exceed the total number of vesicles lined up in twin-files adjacent to the presynaptic membrane.     

Quantal release of ATP in mouse cortex

Transient currents occur at rest in cortical neurones that reflect the quantal release of transmitters such as glutamate and gamma-aminobutyric acid (GABA). We found a bimodal amplitude distribution for spontaneously occurring inward currents recorded from mouse pyramidal neurones in situ, in acutely isolated brain slices superfused with picrotoxin. Larger events were blocked by glutamate receptor (AMPA, kainate) antagonists; smaller events were partially inhibited by P2X receptor antagonists suramin and PPADS. The decay of the larger events was selectively prolonged by cyclothiazide. Stimulation of single intracortical axons elicited quantal glutamate-mediated currents and also quantal currents with amplitudes corresponding to the smaller spontaneous inward currents. It is likely that the lower amplitude spontaneous events reflect packaged ATP release. This occurs with a lower probability than that of glutamate, and evokes unitary currents about half the amplitude of those mediated through AMPA receptors. Furthermore, the packets of ATP appear to be released from vesicle in a subset of glutamate-containing terminals.     

Determination of allatostatin levels in relation to the gonadotropic cycle in the female of Blattella germanica (L.) (Dictyoptera, Blattellidae)

A polyclonal antibody against the allatostatin BLAST-3 (AGSDGRLYSFGL-NH₂) of the cockroach Blattella germanica (L.) (Dictyoptera, Blattellidae) has been raised and characterized, and an ELISA (enzyme-linked immunosorbent assay) for allatostatin quantification has been developed. Allatostatin contents in brain, midgut and haemolymph have been measured in females of B. germanica during the first gonadotropic cycle. Brain allatostatin content increases steadily from adult emergence to the formation of the first ootheca. The values range from 2 ng/brain on the day of adult emergence to 25 ng/brain when the insect forms the ootheca 8 days later. In the midgut, the pattern is similar but the values are about half those of the brain. Allatostatin concentrations in the haemolymph after HPLC separation are in the nanomolar range. The occurrence of allatostatins in the haemolymph suggests that these peptides can act through a humoral pathway, as well as via nerves. The allatostatin content of both brain and midgut are high while the female is transporting the ootheca, which suggests that these peptides could be related to the low metabolic status characterising the period of oothecal transport.