Population expansion, clonal growth, and specific differentiation patterns in primary cultures of hepatocytes induced by HGF/SF, EGF and TGF alpha in a chemically defined (HGM) medium

Mature adult parenchymal hepatocytes, typically of restricted capacity to proliferate in culture, can now enter into clonal growth under the influence of hepatocyte growth factor (scatter factor) (HGF/SF), epidermal growth factor (EGF), and transforming growth factor alpha (TGFalpha) in the presence of a new chemically defined medium (HGM). The expanding populations of hepatocytes lose expression of hepatocyte specific genes (albumin, cytochrome P450 IIB1), acquire expression of markers expressed by bile duct epithelium (cytokeratin 19), produce TGFalpha and acidic FGF and assume a very simplified morphologic phenotype by electron microscopy. A major change associated with this transition is the decrease in ratio between transcription factors C/EBPalpha and C/EBPbeta, as well as the emergence in the proliferating hepatocytes of transcription factors AP1, NFkappaB. The liver associated transcription factors HNFI, HNF3, and HNF4 are preserved throughout this process. After population expansion and clonal growth, the proliferating hepatocytes can return to mature hepatocyte phenotype in the presence of EHS gel (Matrigel). This includes complete restoration of electron microscopic structure and albumin expression. The hepatocyte cultures however can instead be induced to form acinar/ductular structures akin to bile ductules (in the presence of HGF/SF and type I collagen). These transformations affect the entire population of the hepatocytes and occur even when DNA synthesis is inhibited. Similar acinar/ductular structures are seen in embryonic liver when HGF/SF and its receptor are expressed at high levels. These findings strongly support the hypothesis that mature hepatocytes can function as or be a source of bipotential facultative hepatic stem cells (hepatoblasts). These studies also provide evidence for the growth factor and matrix signals that govern these complex phenotypic transitions of facultative stem cells which are crucial for recovery from acute and chronic liver injury.

Studying the snail's clock at better than a snail's pace

The eye of Bulla gouldiana, the cloudy bubble snail, contains a circadian pacemaker that times a nocturnal locomotor rhythm. The eye expresses a circadian rhythm in spontaneous impulse activity that is generated within individual neurons at the base of the retina. There are approximately 100 of these "clock neurons" that are electrically interconnected. The retinal clock can be synchronized by light cycles. Synchronization involves membrane depolarization and calcium influx into pacemaker neurons. While rhythm expression involves an ionic calcium flux, and rhythm expression appears to be mediated by changes in potassium conductance, circadian rhythm generation does not appear to rely on transmembrane fluxes. Rather, the molecular events of transcription and translation appear to be critical players in generating the near twenty-four-hour rhythm in optic nerve activity.

Circadian rhythm generation, expression and entrainment in a molluscan model system

The Bulla ocular pacemaker provides remarkable opportunities for cellular study of circadian pacemaker systems. The demonstration of circadian oscillations within individual neurons maintained in culture provides us with a first occasion to study the biophysical and biochemical properties of bona fide neuronal circadian pacemakers. The ocular clock is robust and shares formal similarity with other circadian systems. The development of molecular techniques that can be applied to single neurons should allow research on the Bulla retina to continue to progress towards a molecular analysis of circadian timekeeping.

The anesthetic agents pentobarbital and chloralose block phase shifts of a neuronal in vitro circadian pacemaker

The anesthetic pentobarbital (6 mM) is capable of blocking light or high K(+)-induced phase shifts of the circadian pacemaker in the isolated eye of Bulla. Pentobarbital alone was effective in generating phase shifts consistent with phase response curves obtained to either extracellular low Ca2+ or hyperpolarizing pulses. Patch clamp recordings from the circadian pacemaker cells indicate that pentobarbital reduces the Ca(2+)-dependent K+ current. Together, these data suggest that pentobarbital acts on the pacemaker by reducing an inward Ca2+ current. Chloralose (3 mM) was effective in blocking light, but not high K(+)-induced phase shifts, and did not generate phase shifts when applied alone, suggesting that chloralose may act as a weak Ca2+ channel inhibitor.

Association of acetaminophen hepatotoxicity with fasting and ethanol use

OBJECTIVES

To evaluate the association of fasting and alcohol use with hepatotoxicity from acetaminophen ingested for therapeutic reasons.

DESIGN

Retrospective case series.

SETTING

Hospitals of the University of Pittsburgh (Pa) Medical Center.

PATIENTS

A total of 126,779 discharge summaries from January 1987 to July 1993 were reviewed using a comprehensive, whole-text-indexed medical database to identify all patients with acetaminophen ingestion and hepatotoxicity. These patients were categorized according to the intended acetaminophen use and dose of acetaminophen ingested.

MAIN OUTCOMES MEASURED

The independent variables of chronic alcohol use, recent alcohol use, and recent fasting were determined for all patients.

RESULTS

Forty-nine patients with acetaminophen hepatotoxicity (aspartate aminotransferase > 1000 U/L) were identified. Twenty-one patients (43%) ingested acetaminophen for therapeutic purposes. All patients with hepatotoxicity took more than the recommended limit of 4 g/d. Recent fasting was more common than recent alcohol use among those who suffered hepatotoxicity after a dose of 4 to 10 g of acetaminophen per day (P = .02). Recent alcohol use was more common in the group who took more than 10 g/d than in those who took 4 to 10 g/d (P = .004).

CONCLUSION

Acetaminophen hepatotoxicity after a dose of 4 to 10 g/d was associated with fasting and less commonly with alcohol use. Patients who developed hepatoxicity after taking acetaminophen doses of greater than 10 g/d for therapeutic purposes were alcohol users. Acetaminophen hepatotoxicity after an overdose appears to be enhanced by fasting in addition to alcohol ingestion.

Intracellular calcium in the entrainment pathway of molluscan circadian pacemakers

Circadian clock systems contain three components--an entrainment pathway, a pacemaker mechanism, and an output or expressed rhythm. The entrainment pathway for light stimuli can be studied by separating steps involved in light transduction and subsequent events acting on the pacemaker mechanism from the steps critical for continued motion of the pacemaker. Studies indicate that calcium entry across the plasma membrane is a required step in the light entrainment pathway of the ocular circadian pacemaker of the marine snail Bulla gouldiana. A calcium influx due to phase-shifting stimuli has recently been measured using the calcium-sensitive dye Fura-2 in dissociated pacemaker neurons from Bulla. Studies preceding these calcium imaging experiments are presented together with a simple model of the role of Ca2+ influx in entrainment and a discussion of problems in demonstrating that calcium influx alone is a sufficient step in the entrainment pathway.

Calcium plays a central role in phase shifting the ocular circadian pacemaker of Aplysia

The eye of the marine mollusk Aplysia californica contains an oscillator that drives a circadian rhythm of spontaneous compound action potentials in the optic nerve. Both light and serotonin are known to influence the phase of this ocular rhythm. The aim of the present study was to evaluate the role of extracellular calcium in both light and serotonin-mediated phase shifts. Low calcium treatments were found to cause phase shifts which resembled those produced by the transmitter serotonin. However, unlike serotonin, low calcium neither increased ocular cAMP levels nor could these phase shifts be prevented by increasing extracellular potassium concentration. Low calcium-induced phase shifts were prevented by the simultaneous application of the translational inhibitor anisomycin and low calcium treatment resulted in changes in [35S]methionine incorporation into several proteins as measured by a two-dimensional electrophoresis gel analysis. Finally, light treatments failed to produce phase shifts in the presence of low calcium or the calcium channel antagonist nickel chloride. These results are consistent with a model in which serotonin phase shifts the ocular pacemaker by decreasing a transmembrane calcium flux through membrane hyperpolarization while light-induced phase shifts are mediated by an increase in calcium flux.

Intracellular calcium responses of circadian pacemaker neurons measured with fura-2

The circadian pacemaker in the eye of the mollusk Bulla gouldiana is located within basal retinal neurons (BRNs) that express a circadian rhythm in cell culture. Light and other depolarizing stimuli shift the phase of the pacemaker in the eye through a process that requires extracellular calcium and is blocked by Ni2+. To test directly if an influx of Ca2+ is present throughout depolarizing treatments that produce phase shifts, dissociated BRNs in cell culture were loaded with a membrane-permeable form of the calcium-sensitive dye fura-2, and then depolarized with elevated levels of extracellular K+. Calcium levels in the BRNs remained elevated during treatments with 50 mM K+ lasting 1 h, a sufficient duration to phase shift the circadian pacemaker. Lowering extracellular free Ca2+ (approx. 1.7 x 10(-7) M) during depolarization blocked the rise in intracellular Ca2+, verifying that a Ca2+ influx is required. The sustained Ca2+ elevation during depolarization was also prevented with 50 mM Ni2+, which blocks phase shifts of the rhythm to depolarization, but not with 5 mM Ni2+, which does not block phase shifts. The initial rise in [Ca2+]i in response to 50 mM K+ was largest on average during the subjective night. The results show that a critical portion of the entrainment pathway persists in pacemaker neurons during cell culture, and that the phase-shifting stimulus may depend on a prolonged Ca2+ signal.

Formal approaches to understanding biological oscillators

In this brief review, we have attempted to illustrate the utility of our qualitative scheme proposed in 1984 (27). This scheme provides a means of summarizing information concerning oscillating systems by identifying system variables and parameters and the interactions between variables. Moreover, the qualitative scheme can be employed to deduce the form of system differential equations. This second step then clearly shows the rate constants that must be deduced through experimentation for the construction of explicit mathematical models.

The effects of lithium on a neuronal in vitro circadian pacemaker

Previous studies have suggested a causal connection between abnormalities of the circadian system and affective disorders. The effectiveness of lithium or rubidium as a treatment for affective disorders and the ability of lithium or rubidium to influence circadian pacemakers has stimulated research into the mechanism of lithium's action on circadian systems. In this study we used a neuronal in vitro circadian pacemaker preparation, the eye of the mollusc Bulla, to examine the cellular effects of lithium and rubidium. Continuous extracellular LiCl application lengthens the period of the circadian rhythm of the Bulla pacemaker in a concentration-dependent manner. Rubidium was found to be more effective than lithium in period lengthening. Stable phase delays were generated by 2-h pulses of 395 mM LiCl applied extracellularly from zeitgeber time (ZT) 5-7 (mid subjective day). Concomitant continuous application of 16 mM LiCl and light (a depolarizing agent) generated period lengthening substantially greater than the arithmetic sum of the modest period lengthening of each treatment alone. Furthermore, LiCl pulses, applied together with depolarizing extracellular KCl concentrations, yielded an increasing magnitude of phase delays with increasing KCl concentration. These data suggest that LiCl acts intracellularly on the circadian pacemaker cells by entering through a voltage-dependent channel, most likely a sodium channel.

Circadian rhythms

Circadian rhythms are a ubiquitous adaptation of eukaryotic organisms to the most reliable and predictable of environmental changes, the daily cycles of light and temperature. Prominent daily rhythms in behavior, physiology, hormone levels and biochemistry (including gene expression) are not merely responses to these environmental cycles, however, but embody the organism's ability to keep and tell time. At the core of circadian systems is a mysterious mechanism, located in the brain (actually the suprachiasmatic nucleus of the hypothalamus) of mammals, but present even in unicellular organisms, that functions as a clock. This clock drives circadian rhythms. It is independent of, but remains responsive to, environmental cycles (especially light). The interest in temporal regulation--its organization, mechanism and consequences--unites investigators in diverse disciplines studying otherwise disparate systems. This diversity is reflected in the brief reviews that summarize the presentations at a meeting on circadian rhythms held in New York City on October 31, 1992. The meeting was sponsored by the Fondation pour l'Etude du Système Nerveux (FESN) and followed a larger meeting held 18 months earlier in Geneva, whose proceedings have been published (M. Zatz (Ed.), Report of the Ninth FESN Study Group on 'Circadian Rhythms', Discussions in Neuroscience, Vol. VIII, Nos. 2 + 3, Elsevier, Amsterdam, 1992). Some speakers described progress made in the interim, while others addressed aspects of the field not previously covered.

The role of extracellular calcium in generating and in phase-shifting the Bulla ocular circadian rhythm

Since extracellular calcium is known to be involved in the entrainment of the circadian pacemaker in the retina of Bulla gouldiana, we have assessed the requirement for extracellular calcium in the generation of the circadian rhythm. To enable us to assay the state of the pacemaker during low-calcium treatment, which often obscures rhythmicity, long-duration pulses of low-calcium artificial seawater (no added calcium, 10 mM EGTA, calculated calcium concentration = 4.5 x 10(-10) M) were applied, and the phase of the subsequent rhythm was measured. Pulse treatments started at zeitgeber time (ZT) 6, and durations ranged from 4 to 72 hr. Although no phase shifts followed pulses ending before the next projected dawn (ZT 24), phase delays of up to 4 hr followed pulses ending after projected dawn, and delays of up to 8 hr followed pulses spanning two dawns. Some activity records exhibited unequivocal circadian rhythmicity during the long low-calcium treatments, with phases and periods similar to untreated control eye records; this finding suggests that the phase delays observed following long low-calcium pulses are attributable to the pulsatile nature of the treatment. These data suggest that extracellular calcium is not an essential requirement for the pacemaker in generating the circadian rhythm.

Circadian rhythm in membrane conductance expressed in isolated neurons

Although isolated neurons can generate rhythmic activity, they have not yet been shown to generate rhythms with a period in the circadian range (near 24 hours). The eye of the mollusk Bulla gouldiana expresses a circadian rhythm in optic nerve impulses that is generated by electrically coupled cells known as basal retinal neurons (BRNs). Daily fluctuations in the membrane potential of the BRNs appear to be driven by a rhythm in membrane conductance. Isolated BRNs exhibited spontaneous conductance changes similar to those observed in the intact retina. Membrane conductance was high in the late subjective night and decreased approximately twofold near projected dawn during at least two circadian cycles in culture. The persistence of daily conductance changes in isolated BRNs indicates that individual neurons can function as circadian pacemakers.

Evidence that potassium channels mediate the effects of serotonin on the ocular circadian pacemaker of Aplysia

The eye of the marine mollusk Aplysia californica contains a photo-entrainable circadian pacemaker that drives an overt circadian rhythm of spontaneous compound action potentials in the optic nerve. Serotonin is known to influence the phase of this ocular rhythm. The aim of the present study was to evaluate whether potassium channels are involved in effects on the ocular circadian rhythm. Our experimental approach was to study the effect of the potassium channel antagonist barium on serotonin-induced phase shifts of this rhythm. The application of barium was found to block serotonin-induced phase shifts whereas barium alone did not cause significant phase shifts. The effects of barium were found to be dose dependent. In addition, barium blocked forskolin-induced phase advances but did not interfere with serotonin-induced increases in cAMP content. Finally, barium antagonized serotonin-induced suppression of compound action potential activity. These results are consistent with a model in which the application of serotonin phase shifts the ocular pacemaker by causing a membrane hyperpolarization which is mediated by a cAMP-dependent potassium conductance.

Stopping the circadian pacemaker with inhibitors of protein synthesis

The requirement for protein synthesis in the mechanism of a circadian pacemaker was investigated by using inhibitors of protein synthesis. Continuous treatment of the ocular circadian pacemaker of the mollusc Bulla gouldiana with anisomycin or cycloheximide substantially lengthened (up to 39 and 52 hr, respectively) the free-running period of the rhythm. To determine whether high concentrations of inhibitor could stop the pacemaker, long pulse treatments of various durations (up to 44 hr) were applied and the subsequent phase of the rhythm was assayed. The observed phases of the rhythm after the treatments were a function of the time of the end of the treatment pulse, but only for treatments which spanned subjective dawn. The results provide evidence that protein synthesis is required in a phase-dependent manner for motion of the circadian pacemaker to continue.

Phase shifting of the circadian rhythm in the eye of Bulla by inhibition of chloride conductance

Inhibition of Cl- conductance has been previously found to shorten the free-running period of the circadian eye rhythm of the marine snail Bulla gouldiana. In this study, we describe a phase-response curve for 6-h pulses of Cl(-)-free seawater, consisting only of phase advances with the largest in the late subjective night (1.5 h) and smaller phase shifts in the late subjective day. Intracellular recordings revealed that at both circadian times retinal pacemaker neurons hyperpolarized in response to the removal of extracellular chloride. Since previous studies indicate that membrane potential generates both phase advances and delays it seems unlikely that the action of chloride removal is mediated exclusively by the change in membrane potential.

The retinal cells generating the circadian small spikes in the Bulla optic nerve

A circadian rhythm in the frequency of compound action potentials (CAPs) in the optic nerve of the mollusc Bulla gouldiana is believed to be generated by the basal retinal neurons (BRNs) of the eye. Along with the CAPs, which are about 100 microV in amplitude, there are 10- to 40-microV impulses from an undetermined cell type in records from the optic nerve. These impulses, called "small spikes," are generated spontaneously in darkness and show a circadian rhythm in frequency that is about 12 hr out of phase with the CAP rhythm. To enable us to determine the origin of the small spikes, intracellular recordings were made from retinal cells while optic nerve activity was monitored. The cells were identified by their light responses and then injected with the fluorescent dye Lucifer Yellow CH or the tracer biocytin. It was found that the large photoreceptors of the distal retina generated graded depolarizations in response to light, and had axons in the optic nerve, but did not show impulses at the level of the photoreceptor layer. By contrast, the spiking retinal cells of the photoreceptor layer generated depolarizations and impulses in response to light. In addition, the spiking cells were found to be dye-coupled to a series of retinal cells approximately 7 microns in diameter, connected to a single axon in the optic nerve. Impulses from the spiking cells occurred spontaneously and correspond with the small spikes in the optic nerve. The BRNs appear to inhibit the retinal cells that generate the small spikes. Hyperpolarization of the BRNs, through constant-current injection, increased the number of small spikes in the optic nerve. Release from hyperpolarization led to a decrease in small spikes. This could explain how circadian changes in BRN membrane potential might modulate spontaneous firing of the spiking cells, resulting in the circadian rhythm in small-spike frequency.

Vitamin D and osteocalcin levels in liver transplant recipients. Is osteocalcin a reliable marker of bone turnover in such cases?

Patients with advanced liver disease are at increased risk for the development of hepatic osteodystrophy in the form of either osteomalacia or osteoporosis. The pathogenesis of these two bone diseases is multifactorial and includes, among other factors, alterations in vitamin D metabolism, malnutrition and hypogonadism. Little is known regarding vitamin D metabolism and the osteoblastic activity in liver transplant recipients. In order to clarify these issues, vitamin D metabolites and osteocalcin levels were measured prior to and 30 days following liver transplantation in 30 cirrhotic patients of various etiologies. While the mean plasma concentrations of 25-hydroxyvitamin D and 1,25-dihydroxyvitamin D of the entire group of 30 patients were significantly greater prior to orthotopic liver transplantation (OLTx) as compared to those after OLTx (11.5 +/- 8.6 vs. 7.4 +/- 5.8 ng/ml, p = 0.0066 and 41.0 +/- 34.6 vs. 20.4 +/- 11.0 pg/ml, p = 0.0003, respectively), no significant changes in osteocalcin concentrations pre- or post-transplantation could be demonstrated (5.2 +/- 3.0 vs. 6.4 +/- 4.1 ng/ml, p = 0.51). Furthermore, no correlation between the plasma concentration of osteocalcin and either vitamin D metabolite, the prothrombin time or cyclosporine levels was found. The reasons for the normal levels of osteocalcin prior to OLTx can be explained by the fact that in vitamin-K-deficient states osteocalcin is predominantly decarboxylated and, therefore, a smaller proportion is bound to bone and/or the synthesis of osteocalcin is partially modulated by 1,25-dihydroxyvitamin D, the level of which has been found to be normal.(ABSTRACT TRUNCATED AT 250 WORDS)

Cellular mechanisms of entrainment

This review summarizes our current understanding of the signal transduction cascade by which light causes phase shifts of the circadian oscillators found in the eye of Bulla and Aplysia. The isolated retina of these marine mollusks contains a circadian oscillator, a photoreceptor, and a light transduction pathway sufficient for entrainment. This preparation offers unique advantages for the cellular analysis of entrainment and the generation of circadian oscillations. There is evidence that similar cellular mechanisms may underlie mammalian and molluscan circadian oscillations. Thus, the models developed to explain entrainment in the molluscan retina are likely to have utility in exploring the mammalian suprachiasmatic nucleus.

Phase-shifting of a neuronal circadian pacemaker in Bulla gouldiana by pentylenetetrazol

1. The convulsant agent pentylenetetrazol generates compound action potential activity from the circadian pacemaker cells in the Bulla retina. 2. The phase response curve to 3 hr pulses of pentylenetetrazol consists of only phase delays which occur following pulses delivered in the early subjective night. 3. Phase shifts to pentylenetetrazol are independent of extracellular calcium since they persist in a low-calcium EGTA solution.

FMRFamide modulates the action of phase shifting agents on the ocular circadian pacemakers of Aplysia and Bulla

The eye of the marine mollusk Aplysia californica contains a photo-entrainable circadian pacemaker that drives an overt circadian rhythm of spontaneous compound action potentials in the optic nerve. Both light and serotonin are known to influence the phase of this ocular rhythm. The current study evaluated the effect of FMRFamide on both light and serotonin induced phase shifts of this rhythm. The application of FMRFamide was found to block serotonin induced phase shifts but, by itself, FMRFamide did not cause significant phase shifts. Furthermore, the effects of FMRFamide on light-induced phase shifts appeared to be phase dependent (i.e., the application of FMRFamide inhibited light-induced phase delays but actually enhanced the magnitude of phase advances). As in Aplysia, the eye of Bulla gouldiana also contains a circadian pacemaker. In Bulla, FMRFamide prevented light-induced phase advances and delays. Although FMRFamide alone generated phase dependent phase shifts, it did not cause phase shifts at the phases where it blocked the effects of light. These data demonstrate that FMRFamide can have pronounced modulatory effects on phase shifting inputs to the ocular pacemakers of both Aplysia and Bulla.

Effects of Photoperiod and Temperature on Egg-Laying Behavior in a Marine Mollusk, Aplysia californica

The primary purpose of these studies was to determine whether photoperiodic signals could influence seasonal egg-laying behavior in the marine mollusk, Aplysia californica. Egg-laying behavior was monitored from groups of animals that were collected at four times of year and maintained in different temperature and photoperiodic conditions in the laboratory. Animals that were obtained in autumn and kept in warm water laid eggs more frequently than those in cold water, regardless of photoperiod. Furthermore, animals maintained on short days and warm water laid eggs more frequently than those on long days and warm water. Animals in cold water showed little to no egg laying, and a photoperiodic response was not evident. Animals that were collected in either winter or spring and maintained in warm water showed little or no spontaneous egg laying throughout the study, regardless of photoperiod. As with the autumn animals, Aplysia individuals obtained in summer and kept on short days and warm water laid eggs more frequently than those kept on long days and warm water. These results provide the first evidence that the reproductive system of A. californica is responsive to photoperiod. Overall, the data suggest that warm water is permissive for egg laying, and that short days can further stimulate this behavior. However, there is a strong inhibition of spontaneous egg laying during the winter and spring, which neither warm water nor short photoperiod can overcome. The role of the eyes in mediating the photoperiodic response was also investigated. A control group of intact animals kept on short days laid eggs more frequently than those on long days, but this photoperiodic response was not evident in eyeless animals. These results suggest that the eyes play a role in mediating the effects of photoperiod on egg laying behavior.

Disease recurrence and rejection following liver transplantation for autoimmune chronic active liver disease

Autoimmune chronic active liver disease (ACALD), a major indication for liver transplantation, is associated strongly with antigenic determinants HLA-B8 and DR3. A retrospective analysis of 43 patients who underwent OLTx for putative ACALD and who, as well as their tissue organ donors, were typed, was performed. Disease recurrence and graft rejection episodes were determined by chart review and histopathological review of all material available. Disease recurrence was histologically documented in 11 (25.6%) of these 43 cases. Graft rejection episodes occurred in 24 (55.8%). All recurrences were in recipients of HLA-DR3-negative grafts. Nine of the recurrences were in HLA-DR3-positive recipients (odds ratio: 6.14, P less than 0.03). Two of 11 cases of disease recurrence were in recipients who were HLA-DR3-negative. Nine of these 11 had received HLA-DR3-negative grafts. Rejection occurred in 13 HLA-B8-positive recipients, 12 of whom received HLA-B8-negative grafts. Eleven HLA-B8-negative recipients experienced at least one rejection episode and 9 of these had received HLA-B8-negative grafts. Based upon these data we conclude: 1) that recurrence of putative ACALD is more likely to occur in HLA-DR3-positive recipients of HLA-DR3-negative grafts; (2) that recurrences were not seen in recipients of HLA-DR3-positive grafts; (3) that HLA-B8 status does not affect disease recurrence; and (4) that neither the HLA-B8 nor the DR3 status of the graft or recipient has an effect on the observed frequency of rejection.

Does low intracellular pH stop the motion of the Bulla circadian pacemaker?

The eye of the mollusk Bulla has proven itself useful as an in vitro neural circadian pacemaker. Here, we report that treatments applied to lower intracellular pH may stop the motion of this circadian pacemaker in a phase-dependent manner. Lowering the extracellular pH of the artificial seawater bath to 6.9, or application of the stilbene derivatives 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS) or 4,4-di-isothiocyanostilbene-2,2'-disulfonic acid (DIDS), abolishes the circadian rhythm in optic nerve compound action-potential frequency. Because these treatments are known to lower intracellular pH, these data suggest that the pacemaker may be inhibited by low intracellular pH. In order to assess the state of the pacemaker during low extracellular pH treatment, pulses of seawater at pH 6.8 were applied, and the phase of the rhythm subsequent to the pulse was observed. All pulses started 1 hr after subjective dusk [circadian time (CT) 13] and were applied to eyes in constant darkness; pulse lengths varied from 4 to 47 hr for different preparations. The phases of the eye rhythms following pulses that ended before subjective dawn (about CT 24) were not different from untreated preparations. However, for pulses longer than 11 hr and therefore ending after subjective dawn, the subsequent phase of the rhythm was a function of the ending time of the pulse. These data suggest that the pacemaker's motion was stopped at dawn during the low-pH treatment and resumed following restoration of normal pH. To distinguish between phase and duration dependence of this effect in the above experiment, phase shifts were obtained to 14-hr pulses of pH 6.8 seawater applied at three different phases.(ABSTRACT TRUNCATED AT 250 WORDS)