A role for slow NMDA receptor-mediated, intrinsic neuronal oscillations in the control of fast fictive swimming in Xenopus laevis larvae

In larvae of the amphibian, Xenopus laevis, spinal neurons which are active during fictive swimming also display tetrodotoxin-resistant membrane potential oscillations following the coactivation of N-methyl-DL-aspartate (NMDA) and 5-hydroxytryptamine (serotonin or 5-HT) receptors (Scrymgeour-Wedderburn et al., 1997; Eur. J. Neurosci., 9, 1473-1482). The oscillations are slow (approximately 0.5 Hz) compared with swimming (approximately 7-35 Hz) raising doubt over their contribution to the cycle by cycle depolarizations occurring during swimming. We investigated an alternative: that the intrinsic oscillations modulate swimming activity over many consecutive cycles. Bath application of NMDA induced continuous fictive swimming that differed between embryonic and larval preparations. In 81% of larval preparations (n = 36), there was a slow (approximately every 2 s) rhythmic modulation of ventral root activity in which burst durations and intensities increased as cycle periods decreased. This pattern of activity was enhanced rather than abolished following blockade of glycine and gamma-aminobutyric acid (GABA) A receptors and presumably therefore resulted from a periodic increase in the excitation of motor neurons. To determine whether this slow rhythm resulted from intrinsic, 5-HT-dependent membrane potential oscillations, larvae were spinalized to prevent the release of 5-HT from brainstem raphe neurons. The resulting pattern of NMDA-induced activity lacked any slow modulation. The slow modulation could also be enhanced by the bath application of a 5-HT receptor agonist (5-carboxamidotryptamine) and abolished either by the addition of an antagonist (pindobind-5-HT1A) or by removal of magnesium ions, providing more direct evidence for a contribution of intrinsic oscillations. Thus, the 5-HT-dependent intrinsic oscillations modulate NMDA-induced swimming activity over several consecutive cycles.     

Correlation of plasma corticosterone levels with running activity in the blinded rat

Blinded female reats were placed in running-wheel cages to monitor the phase of their activity cycle. After approximately a month of adaptation to the wheels, jugular vein blood samples were withdrawn at the beginning and end of the running phase of activity and analyzed for plasma corticosterone. By the time blood samples were obtained, the blined rats' activity cycles had desynchronized from the lighting cycle of the room in an apparently free-running fashion, and were out of phase with each other. The corticosterone levels were high at the beginning of the running phase and low at the end: begin run corticosterone was 34.5 +/- 13, end run corticosteronewas 14.2 +/- 10 (mean +/-SD in mug/100 ml of plasma; t = 7.93, df = 82, P less than 0.001). It was concluded that blinded rats do have an adrenocortical rhythm and that it is in phase with the activity cycle of each individual rat.     

Cell cycle and cancer: critical events at the G1 restriction point

In eukaryotic cells, each phase of the cell division cycle is controlled by the sequential activation of various cyclin-dependent kinases (Cdks). These kinases are known to phosphorylate various substrates whose activity is critical for cell cycle progression. As key regulators of the cell cycle, Cdks must be strictly controlled by both extracellular and intracellular signals for adequate responses to occur. There are several distinct molecular mechanisms for controlling the activity of the different Cdks: regulated synthesis and destruction of the activating subunit (cyclin), regulated synthesis and destruction of the inhibitory subunit (Cki), and posttranslational modification of the kinase subunit by highly specific kinases and phosphatases. During the G1 phase of the cell cycle, cells sense, integrate positive and negative signals, and transmit them to the cell cycle machinery. Because of this pivotal role, a vast majority of oncogenic events selectively target elements controlling the G1. In this review we discuss the elements controlling the G1 phase in relationship to the genesis of cancer.     

Acquisition of meiotic competence is related to the functionality of the phosphoinositide/calcium signaling pathway in the mouse oocyte

The meiosis resumption process has been related to spontaneous cytoplasmic InsP3-dependent calcium oscillations in fully grown mouse oocytes. Our purpose was to determine whether the acquisition of meiotic competence during the growth phase of oogenesis was associated with that of Ca2+ oscillations and whether these oscillations were dependent on the phosphoinositide cycle. We used confocal laser scanning microscopy to image free calcium ions in fluo-3/AM-loaded oocytes recovered from 12- to 26-day-old mice for 15 min following follicular release. As expected, oocytes isolated from 12-day-old mice were totally incompetent to undergo GVB in vitro, whereas the GVB rate increased progressively with mouse age and oocyte diameter. The percentage of oocytes exhibiting spontaneous calcium oscillations and that of oocytes resuming meiosis were similarly correlated with the female age, with incompetent oocytes failing to exhibit spontaneous Ca2+ oscillations. It is noteworthy that regardless of the stage of growth, thapsigargin induced an ooplasmic calcium release from the InsP3-sensitive stores when it was added to the culture medium. However, intracytoplasmic microinjection of InsP3 induced a shorter sequence of Ca2+ oscillations in 12-day-old mouse oocytes than in 15-day-old mouse oocytes and, whereas InsP3 increased the GVB rate at 15 days, it was unable to induce GVB at 12 days. These data lead us to conclude that the acquisition of meiotic competence is related to the functionality of the InsP3 pathway and, correspondingly, to the oocyte's ability to generate spontaneous cytoplasmic InsP3-dependent calcium oscillations.     

Long-range connections synchronize rather than spread intrathalamic oscillations: computational modeling and in vitro electrophysiology

A thalamic network model was developed based on recent data regarding heterogeneous thalamic reticular (RE) cell axonal arborizations that indicate at least two projection patterns, short-range cluster projections and long-range diffuse projections. The model was constrained based on expected convergence and the biophysical properties of RE and thalamocortical (TC) cells and their synapses. The model reproduced in vitro synchronous slow (3-Hz) oscillatory activity and the known effects of T-channel blockade and cholecystokinin (CCK) application on this activity. Whereas previous models used the speed at which approximately 3-Hz oscillations propagate in vitro to infer the spatial extent of intrathalamic projections, we found that, so long as the gamma-aminobutyric acid-B synaptic conductance was adjusted appropriately, a network with only short-range projections and another network with both short- and long-range projections could both produce physiologically realistic propagation speeds. Although the approximately 3-Hz oscillations propagated at similar speeds in both networks, phase differences between oscillatory activity at different locations in the network were much smaller in the network containing both short- and long-range projections. We measured phase differences in vitro and found that they were similar to those that arise in the network containing both short- and long-range projections but are inconsistent with the much larger phase differences that occur in the network containing only short-range projections. These results suggest that, although they extend much further than do short-range cluster projections, long-range diffuse projections do not spread activity over greater distances or increase the speed at which intrathalamic oscillations propagate. Instead, diffuse projections may function to synchronize activity and minimize phase shifts across thalamic networks. One prediction of this hypothesis is that, immediately after a collision between propagating oscillations, phase gradients should vary smoothly across the thalamic slice. The model also predicts that phase shifts between oscillatory activity at different points along a thalamic slice should be unaffected by T-channel blockers and decreased by suppression of synaptic transmission or application of CCK.     

Oscillations in the activity of a potassium channel at the presynaptic nerve terminal

1. Periodic oscillations were detected in the activity of single macromolecules: potassium channels. 2. When potassium channels are repeatedly activated in isolated patches from fused synaptosomes of Torpedo electric organ, their behavior exhibits a departure from random activation. 3. The departure from random behavior is demonstrated by the runs test and by the lack of fit to Poisson distribution. 4. Under appropriate experimental conditions, the channels display periodic oscillations with a periodicity of approximately 20 s when activated at a rate of 1.25 Hz. 5. The oscillations do not arise from sampling, recording, or computational artifacts. 6. It is conceivable that single-channel oscillations play a role in the generation of membrane oscillations and thus may contribute to the oscillatory behavior of the nervous system.     

Elucidation of gene function using C-5 propyne antisense oligonucleotides

Identification of human disease-causing genes continues to be an intense area of research. While cloning of genes may lead to diagnostic tests, development of a cure requires an understanding of the gene's function in both normal and diseased cells. Thus, there exists a need for a reproducible and simple method to elucidate gene function. We evaluate C-5 propyne pyrimidine modified phosphorothioate antisense oligonucleotides (ONs) targeted against two human cell cycle proteins that are aberrantly expressed in breast cancer: p34cdc2 kinase and cyclin B1. Dose-dependent, sequence-specific, and gene-specific inhibition of both proteins was achieved at nanomolar concentrations of ONs in normal and breast cancer cells. Precise binding of the antisense ONs to their target RNA was absolutely required for antisense activity. Four or six base-mismatched ONs eliminated antisense activity confirming the sequence specificity of the antisense ONs. Antisense inhibition of p34cdc2 kinase resulted in a significant accumulation of cells in the Gap2/mitosis phase of the cell cycle in normal cells, but caused little effect on cell cycle progression in breast cancer cells. These data demonstrate the potency, specificity, and utility of C-5 propyne modified antisense ONs as biological tools and illustrate the redundancy of cell cycle protein function that can occur in cancer cells.     

Development of oscillatory activity in the limbic cortex in vitro

The generation of EEG theta rhythms in the mammalian limbic cortex is a prime example of rhythmic activity that involves central mechanisms of oscillations and synchrony. In 1985 for the first time we demonstrated that bath perfusion of the hippocampal formation slices with cholinergic agonists resulted in theta-like oscillations. Since this initial demonstration of the in vitro theta activity, we have carried out a number of experiments in an attempt to answer the general question: what are the similarities between the cholinergic-induced in vitro theta and theta rhythm which naturally occurs in the vivo preparation. Thus far, our in vitro studies provided strong evidence that the in vitro recorded theta oscillations replicate many physiological and pharmacological properties of the in vivo observed theta rhythm. In addition, our studies validate the in vitro maintained limbic cortex as a model for studying central mechanisms of oscillations and synchrony.     

Chromosome association of minichromosome maintenance proteins in Drosophila endoreplication cycles

Minichromosome maintenance (MCM) proteins are essential eukaryotic DNA replication factors. The binding of MCMs to chromatin oscillates in conjunction with progress through the mitotic cell cycle. This oscillation is thought to play an important role in coupling DNA replication to mitosis and limiting chromosome duplication to once per cell cycle. The coupling of DNA replication to mitosis is absent in Drosophila endoreplication cycles (endocycles), during which discrete rounds of chromosome duplication occur without intervening mitoses. We examined the behavior of MCM proteins in endoreplicating larval salivary glands, to determine whether oscillation of MCM-chromosome localization occurs in conjunction with passage through an endocycle S phase. We found that MCMs in polytene nuclei exist in two states: associated with or dissociated from chromosomes. We demonstrate that cyclin E can drive chromosome association of DmMCM2 and that DNA synthesis erases this association. We conclude that mitosis is not required for oscillations in chromosome binding of MCMs and propose that cycles of MCM-chromosome association normally occur in endocycles. These results are discussed in a model in which the cycle of MCM-chromosome associations is uncoupled from mitosis because of the distinctive program of cyclin expression in endocycles.     

Binding of the non-peptide vasopressin V1a receptor antagonist SR-49059 in the rat brain: an in vitro and in vivo autoradiographic study

The role of the sympathetic limb of the autonomic nervous system (ANS) in the mediation of oscillations in consecutive beat-to-beat RR interval (RRI) and systolic blood pressure (SBP) values of lizards, Gallotia galloti, was investigated using spectral analysis and measuring effects of autonomic blockers. alpha-Adrenergic blockade decreased the power spectral density (PSD) of both RRI and SBP very low frequency (VLF: 0.007-0.055 Hz) and low frequency (LF: 0.055-0.150 Hz) bands, whereas beta-adrenergic blockade increased the PSD of both RRI- and SBP-VLF and RRI- and SBP-LF bands. These findings suggest that in lizards 1) the VLF and LF peaks of RRI and SBP power spectra are alpha-adrenergic mediated, and that 2) the beta-adrenergic activity of the sympathetic system may act buffering all RRI and SBP oscillations below 0.150 Hz. These results, when analyzed jointly with the ones obtained from a previous study (De Vera and González. 1997. Comp Biochem Physiol 85A:389-394) on the effects of parasympathetic blockade on lizards' RRI and SBP oscillations, demonstrate that these reptiles, like mammals, exhibit spontaneous short-term oscillations in their HR and SBP which are mediated by the ANS. However, unlike mammals, the RRI and ABP low-frequency oscillations in Gallotia seem to be similarly affected by the ANS and appear to be powered by alpha-adrenergic and parasympathetic activities and buffered by beta-adrenergic activity.     

Human immunodeficiency virus type 1-specific cytotoxic T lymphocytes (CTL), virus load, and CD4 T cell loss: evidence supporting a protective role for CTL in vivo

We report here the comparative analysis of human Mcm/P1 proteins (HsMcm2, -3, -5 and -7), including a characterization of their mutual interactions, cell cycle dependent expression and nuclear localization during the cell cycle and the quiescent state. The mRNA levels of these genes, which undergo cell cycle dependent oscillations with a peak at G1/S phase, may be regulated by E2F motifs, two of which were detected in the 5' upstream region of the HsMCM5 gene. In contrast, the protein levels of these Mcm proteins were found to remain rather constant during the HeLa cell cycle. However, their levels gradually increased in a variable manner as KD cells progressed from GO into the G1/S phase. In the GO stage, the amounts of HsMcm2 and -5 proteins were much lower than those of HsMcm7 and -3 proteins, suggesting that they are not present in stoichiometric amounts, and that only a proportion of these molecules actively participate in cell cycle regulation as part of Mcm/P1 complexes.     

Calcium handling by the sarcoplasmic reticulum during oscillatory contractions of skinned skeletal muscle fibres

Isometric ATP consumption and force were investigated in mechanically skinned fibres from iliofibularis muscle of Xenopus laevis. Measurements were performed at different [Ca2+], in the presence and absence of caffeine (5 nM). In weakly Ca2+-buffered solutions without caffeine, spontaneous oscillations in force and ATPase activity occurred. The repetition frequency was [Ca2+]-and temperature-dependent. The Ca2+ threshold (+/- SEM) for the oscillations corresponded to a pCa of 6.5 +/- 0.1. The maximum ATP consumption associated with calcium uptake by the sarcoplasmic reticulum (SR) reached during the oscillations was similar to the activity under steady-state conditions at saturating calcium concentrations in the presence of caffeine. Maximum activity was reached when the force relaxation was almost complete. The calculated amount of Ca2+ taken up by the SR during a complete cycle corresponded to 5.4 +/ 0.4 mmol per litre cell volume. In strongly Ca2+-buffered solutions, caffeine enhanced the calcium sensitivity of the contractile apparatus and, at low calcium concentrations, SR Ca uptake. These results suggest that when the SR is heavily loaded by net Ca uptake, there is a massive calcium-induced calcium release. Subsequent net Ca uptake by the SR then gives rise to the periodic nature of the calcium transient.     

Melatonin entrains the restored circadian activity rhythms of syrian hamsters bearing fetal suprachiasmatic nucleus grafts

A circadian pacemaker consists of at least three essential features: the ability to generate circadian oscillations, an output signal, and the ability to be entrained by external signals. In rodents, ablation of the suprachiasmatic nucleus (SCN) results in the loss of circadian rhythms in activity. Rhythmicity can be restored by transplanting fetal SCN into the brain of the lesioned animal, demonstrating the first two of the essential pacemaker features within the grafts. External signals, such as the light/dark cycle, have not, however, been shown to entrain the restored rhythms. Melatonin injections are an effective entraining stimulus in fetal and neonatal Syrian hamsters of the same developmental ages used to provide donor tissue for transplantation. Therefore, melatonin was used to test the hypothesis that SCN grafts contain an entrainable pacemaker. Daily injections of melatonin were given to SCN-lesioned hosts beginning on the day after transplantation of fetal SCN. Two groups that received melatonin at different times of day 12 hr apart each showed significantly clustered phases but with average phases that differed by 8.67 hr. Thus melatonin was able to entrain the restored circadian activity rhythms. In contrast to these initial injections, injections given 6 weeks after transplantation were unable to entrain or phase shift the rhythms. The results demonstrate that SCN grafts contain an entrainable circadian pacemaker. In addition, the results also indicate that the fetal SCN is directly sensitive to melatonin and, as with intact hamsters, sensitivity to melatonin is lost during SCN development.     

A simple method for the assay of eight steroids in small volumes of plasma

A simple method is described for the simultaneous radioligand assay of four delta5-3beta-hydroxysteroids adjacent to one another on the biosynthetic pathway (pregnenolone [1], 17alpha-hydroxypregnenolone, dehydroepiandrosterone and 5-androsterone-3beta, 17beta-diol), and their four delta4-3keto products (progesterone, 17alpha-hydroxyprogesterone, 4-androstene-3, 17-dione and testosterone). Two plasma aliquots are extracted and fractionated each for four steroids and individual corrections are made for losses. For fractionation, maximum use is made of the high resolution and reproducibility of celite minicolumns, using propylene glycol as stationary phase, and a discontinuous gradient of ethyl acetate in iso-octane as mobile phase. The fractions are then assayed in the appropriate radioligand end-assay system. Each assay was finally validated by demonstrating coincidence of peaks of immuno- and radioactive steroid in extracts of female plasma. Results in pre-pubertal girls and women in the follicular phase of the menstrual cycle suggest that the major change in adrenal steroid production at puberty may be an increase in 17, 20-desmolase activity. There appears to be little reversal of this change in adrenal function after ovariectomy.     

Regulation of the anaphase-promoting complex/cyclosome by bimAAPC3 and proteolysis of NIMA

Surprisingly, although highly temperature-sensitive, the bimA1(APC3) anaphase-promoting complex/cyclosome (APC/C) mutation does not cause arrest of mitotic exit. Instead, rapid inactivation of bimA1(APC3) is shown to promote repeating oscillations of chromosome condensation and decondensation, activation and inactivation of NIMA and p34(cdc2) kinases, and accumulation and degradation of NIMA, which all coordinately cycle multiple times without causing nuclear division. These bimA1(APC3)-induced cell cycle oscillations require active NIMA, because a nimA5 + bimA1(APC3) double mutant arrests in a mitotic state with very high p34(cdc2) H1 kinase activity. NIMA protein instability during S phase and G2 was also found to be controlled by the APC/C. The bimA1(APC3) mutation therefore first inactivates the APC/C but then allows its activation in a cyclic manner; these cycles depend on NIMA. We hypothesize that bimAAPC3 could be part of a cell cycle clock mechanism that is reset after inactivation of bimA1(APC3). The bimA1(APC3) mutation may also make the APC/C resistant to activation by mitotic substrates of the APC/C, such as cyclin B, Polo, and NIMA, causing mitotic delay. Once these regulators accumulate, they activate the APC/C, and cells exit from mitosis, which then allows this cycle to repeat. The data indicate that bimAAPC3 regulates the APC/C in a NIMA-dependent manner.     

Maternal entrainment of the developing circadian system in the Siberian hamster (Phodopus sungorus)

The aim of these studies was to investigate maternal entrainment of developing circadian locomotor activity rhythms in the Siberian hamster. In Experiment 1, mothers were transferred from a 16:8 LD cycle into constant dim red light (DD) from the day of parturition, and wheel-running activity of the mother and pups was individually monitored from the time of weaning. The phases of the individual pups' rhythms were found to be synchronized both to the phase of the mother and to the phase of lights off (ZT 12) of the photo cycle that the mother was exposed to until the day of parturition. To investigate whether this synchrony might reflect direct effects of light acting upon the fetal circadian system in late gestation, the experiment was repeated but with mothers placed into DD early in pregnancy (< or = day 7 of gestation). The results were similar to the first study, suggesting that the mother rather than the photo cycle during the latter part of gestation entrains the developing circadian system. The third experiment investigated whether this entrainment occurred during the postnatal period. Breeding pairs were maintained on alternative light-dark cycles, LD and DL, that were 12 h out of phase. Litters born to mothers on one light-dark cycle were exchanged on the day of birth with foster mothers from the reversed light-dark cycle, then raised in DD. Control litters exchanged between mothers from the same light-dark cycle had similar litter synchrony as shown by nonfostered litters of Experiment 1. However, pups cross-fostered with mothers on reversed LD cycles showed a very different distribution of pup phases. Pups were not synchronized to their natural mother but to their foster mother. Moreover, pups were more scattered over the 24-h period and were found to be significantly synchronized to the phase of the reversed LD cycle. These results demonstrate the occurrence of postnatal entrainment in the Siberian hamster. The increased scatter produced by the cross-fostering paradigm results from some litters being completely entrained to the phase of the foster mother, some with an intermediate distribution between the phase of the natural and foster mothers, and a minority being associated with the phase of the natural mother. These results suggest that Siberian hamster pups are initially synchronized either prenatally or at birth but that the mother continues to provide entrainment signals during the postnatal period.     

Gamma frequency oscillation in the hippocampus of the rat: intracellular analysis in vivo

Gamma frequency field oscillations reflect synchronized synaptic potentials in neuronal populations within the approximately 10-40 ms range. The generation of gamma activity in the hippocampus was investigated by intracellular recording from principal cells and basket cells in urethane anaesthetized rats. The recorded neurones were verified by intracellular injection of biocytin. Gamma frequency field oscillations were nested within the slower theta waves. The phase and amplitude of intracellular gamma were voltage dependent with an almost complete phase reversal at Cl- equilibrium potential in pyramidal cells. Basket cells fired at gamma frequency and were phase-locked to the same phase of the gamma oscillation as pyramidal cells. Current-induced depolarization coupled with synaptically induced inhibition resulted in gamma frequency discharge (30-80 Hz) of pyramidal cells without accommodation. These observations suggest that at least part of the gamma frequency field oscillation reflects rhythmic hyperpolarization of principal cells, brought about by the rhythmically discharging basket neurones. Resonant properties of pyramidal cells might facilitate network synchrony in the gamma frequency range.     

Petunia p34cdc2 protein kinase activity in G2/M cells obtained with a reversible cell cycle inhibitor, mimosine

Protoplasts isolated from petunia leaf mesophyll are non-cycling cells mostly with 2C content. Cells regenerating from protoplast culture enter mitosis after 48 h. This experimental model is used to relate p34cdc2 kinase activity to cell cycle phase. Our results show that the histone H1 phosphorylation, and hence p34cdc2 kinase activity, peaks with G2+early M cell cycle phase. However, a trace kinase activity was already present when most cells were entering S phase. To obtain a maximum of cells in G1+S phases, the protoplast culture was treated with the rare amino acid, mimosine. Mimosine blocked plant cells derived from protoplast culture both at G1 and in early and mid S phase. Despite the increased G1+S level, p34cdc2 kinase activity did not increase. This suggests that the trace activity appearing when the majority of cells are entering S does not correspond to any putative p34cdc2 activation at G1/S transition but to the activation of the minor 4C population initially present in the leaf: the hypothesis remains that p34cdc2 kinase activity is solely related to G2+M phase in petunia.     

华蟾素注射液对人肝癌HepG-2细胞增殖及周期的影响

Objective: The aim of our study was to investigate the effect of Cinobufacini injection on the proliferation and cell cycle of human hepatoma HepG-2 cells. Methods: Cell proliferation was assessed by MTT assay, cell cycle distributionwas detected by the flow cytometry (FCM). The expression of Cyclin A, CDK2 mRNA levels were examined by RT-PCR.Quantitative colorimetric assay was used to analyze Cyclin NCDK2 activity in HepG-2 cells. Results: Cinobufacini injection significantly inhibited HepG-2 cells proliferation in dose- and time-dependent ways; FCM analysis showed Cinobufacini injection induced cell cycle arrest at S phase; RT-PCR assay showed Cinobufacini injection down-regulated Cyclin A, CDK2expression at mRNA levels; Quantitative colorimetric assay showed Cinobufacini injection deceased Cyclin A/CDK2 activity in HepG-2 cells. Conclusion: Cinobufacini injection can inhibit human hepatoma HepG-2 cells growth, induce cell apoptosis and induce cell cycle arrest at S phase, the mechanism of which might be partly related to the down-regulation of Cyclin A,CDK2 mRNA expression and inhibition of Cyclin A/CDK2 activity.