Protein Kinase C Modulates Ventilatory Patterning in the Developing Rat

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Protein Kinase C Modulates Ventilatory Patterning in the Developing Rat

HARI P. R. BANDLA, NARONG SIMAKAJORNBOON, GAVIN R. GRAFF, and DAVID GOZAL

Constance S. Kaufman Pediatric Pulmonary Research Laboratory, Departments of Pediatrics and Physiology, and Inter-Departmental Neuroscience and Cellular and Molecular Biology Programs, Tulane University School of Medicine, New Orleans, Louisiana

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Protein kinase C (PKC) mediates important components of signal transduction pathways underlying neuronal excitability andmodulates respiratory timing mechanisms in adult rats. To determineventilatory effects of systemic PKC inhibition during development,whole-body plethysmographic recordings were conducted in 2-3-d(n = 11), 5-6-d (n = 19), 10-12-d (n = 14), and 20-21-d-old (n= 14) rat pups after treatment with vehicle and Ro 32-0432 (100mg/kg, intraperitoneally). Ro 32-0432 decreased minute ventilation( $V$ E) by 51.0 ± 5.5% (mean ± SEM) in youngest pups (p < 0.01)but only 19.1 ± 6.8% in 20-21-d-old pups (p < 0.01). $V$ E decreaseswere always due to frequency reductions with tidal volume (VT)remaining unaffected. Respiratory rate decreases primarily resultedfrom marked expiratory time (TE) prolongations being more pronouncedin 2-3-d-old (115.5 ± 28.9%) compared with 20-21-d old (36.6 ±10.9%; p < 0.002 analysis of variance [ANOVA] ). Expression ofthe PKC isoforms $alpha$ , $beta$ , $gamma$ , $delta$ , $iota$ , and µ was further examined inbrainstem and cortex by immunoblotting and revealed differentpatterns with postnatal age and location. We conclude that endogenousPKC inhibition elicits age-dependent ventilatory reductions whichprimarily affect timing mechanisms rather than changes in volumedrive. This effect on ventilation abates with increasing postnatalage suggesting that the neural substrate mediating overall respiratoryoutput may be more critically dependent on PKC activity in theimmatureanimal.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The role of second messenger systems in neuronal populations underlying generation and maintenance of eucapnic ventilationin mammals is mostly unknown. Protein kinase C (PKC) is a prominentsecond messenger system in mammalian cells which is ubiquitouslyexpressed in neural tissue (1), and has been implicated inthe transduction of multiple extracellular signals into the neuronalcell (2). The PKC family consists of 12 major isoforms dividedinto three major subgroups, classic ( $alpha$ , $beta$ 1, $beta$ 2, and $gamma$ ), novel( $delta$ , $varepsilon$ , $theta$ , $eta$ , and µ), and atypical PKC ( $zeta$ , $iota$ , and $lambda$ ) based ontheir structural characteristics and activation requirements (3,4). In cortical regions, expression of certain PKC isoformsis developmentally regulated with increasing levels of expressionoccurring with advancing postnatal age (5, 6). Furthermore,most of the known PKC isoforms are expressed within the dorsocaudalbrainstem nuclei of the rat (7, 8), where they play a significantrole in hypoxic chemotransduction. In addition, a previous studyfrom our laboratory showed that modification of endogenous PKCactivity by a blood-brain barrier permeable PKC inhibitor (Ro32-0432) prolonged expiratory duration (TE) and reduced normoxicventilation in conscious, freely behaving adult rats (9). Thus,we hypothesized that developmental changes in PKC expression andendogenous PKC activity may underlie important components of ventilatorypatterning in the postnatalrat.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The experimental protocols were approved by the Institutional Animal Use and Care Committee. Time-pregnant Sprague-Dawleyrats were obtained from a commercial breeder (Charles River, Wilmington,MA) and delivery times recorded. For all experiments, pups wererandomly selected from every litter at postnatal ages 2-3 d, 5-6d, 10- 12 d, and 20-21 d. These ages have been previously shownas being representative of important maturational changes in ventilation(10).

Protocol

Ventilatory measurements were initially performed for approximately 30 min before and after intraperitoneal administrationof 0.2 ml normal saline (control). Animals were then allowed torecover with their mother for at least 60 min, were returned tothe barometric chamber, and a new baseline was determined. Animalswere then injected with the systemically active, blood-brain barrierpermeable, nonisoform-selective PKC inhibitor Ro 32-0432 (100mg/kg intraperitoneally in 0.2 ml normal saline; Roche Products,Welwyn Garden City, UK; 11-13), and ventilation was monitoredfor 2 to 6 h. Ro 32-0432 is a bisindolylmaleimide derivative inwhich, in addition to a straight-chain alkyl side-chain bearinga cationic substitute, the position of the amine substituent wascorrectly conformationally restricted (12). In a subset of animals,recordings were repeated after a second dose of normal salineto ascertain reproducibility and variability of ventilatory patterning.The adequacy of Ro 32-0432 inhibitor dosages and experimentaltime frames has been previously validated (9). Because ventilatoryrecordings using the methods described subsequently are sensitiveto body temperature changes, we measured changes in core bodytemperature in three 13-d-old rat pups after receiving Ro 32-0432injections, and confirmed that no significant changes in bodytemperatureoccurred.

Ventilatory Recordings

Respiratory measures were continuously acquired in the freely behaving, unrestrained animal placed in a previously calibrated0.5-L barometric chamber (Buxco Electronics, Troy, NY), usingthe methods described by Bartlett and Tenney (14), and Pappenheimer(15). To minimize the long-term effect of signal drift causedby temperature and pressure changes outside the chamber, a referencechamber of equal size in which temperature was measured usinga T type thermocouple was used. In addition, as previously recommendedby Epstein and colleagues, a correction factor was incorporatedinto the software routine to account for inspiratory and expiratorybarometric asymmetries (16). Environmental temperature was maintainedwithin 29 to 32° C, which corresponds to usual temperatures recordedin the dam. A calibration volume of 0.5 ml of air was repeatedlyintroduced into the chamber prior to, and upon completion of recordings.At least 30 min before the start of each protocol, animals wereallowed to acclimate to the chamber, in which humidified air (90%relative humidity) warmed at 30° C was passed through at a rateof 2 L · min¹, using a precision flow pump-reservoir system. Pressure changesin the chamber caused by the inspiratory and expiratory temperaturechanges (17) were measured using a high gain differential pressuretransducer (Model MP45-1; Validyne, Northridge, CA). Analog signalswere continuously digitized, and analyzed on-line by a microcomputersoftware program (Buxco Electronics). A rejection algorithm wasincluded in the breath-by-breath analysis routine and allowedfor accurate rejection of motion-induced artifacts. Tidal volume(VT), inspiratory duration (TI), TE, respiratory frequency (f),and minute ventilation ( $V$ E) were computed and stored for subsequentoff-lineanalysis.

Immunoblot Analysis

Rat pups at postnatal ages 2 d, 5 d, 10 d, and 15 d, and adult male rats were killed with a pentobarbital overdose. The skullwas rapidly opened, the brain was extracted, immediately placedon dry ice, and dissected under surgical microscopy. The obexwas visually identified, and a coronal section 1.5 mm caudal to1.5 mm rostral to the obex was performed. The dorsal half of thisbrainstem section (DB) as well as a portion of parietofrontalcortex (Cx) were carefully removed. Tissues corresponding to theDB or Cx from 4 to 10 animals were pooled and homogenized at 0°C with a tissue blender in 20 mM tris (hydroxymethyl) aminomethane(Tris)/HCl buffer pH 7.5, containing 2 mM ethylenediaminetetraaceticacid (EDTA), 0.5 mM ethyleneglycol-bis- ( $beta$ -aminoethyl ether)-N,N'-tetraaceticacid (EGTA), 25 µg/ml leupeptin, 25 µg/ml aprotinin, and 1 mMphenylmethylsulfonyl fluoride (PMSF). The homogenate was centrifugedfor 10 min at 1,000 × g at 4° C to remove cell debris. Proteincontent was measured in each soluble fraction using the Bradfordmethod (DC-Biorad protein assay, Hercules, CA), and samples frozenat $-$ 70° C until analysis. Proteins (75 µg/sample) were subjectedto sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE)(8% acrylamide gel), and transferred on a 0.2 µM nitrocellulosemembrane. Membranes were blocked for 1 h in a 5% nonfat dry milksolution in Tris-buffered saline (TBS)- Tween. After overnightincubations with antibodies to $alpha$ , $beta$ , $gamma$ , $delta$ , $iota$ , and µ PKC isoforms(Transduction Laboratories, Lexington, KY), membranes were washedand incubated for 1 h with a horseradish peroxidase (HRP)-labeledgoat anti-mouse (1:30,000; Kirkegaard & Perry Laboratories, Gaithersburg,MD). In all experiments, a control lysate provided by TransductionLaboratories for each PKC isoform was included. The concentrationsof the PKC isoform antibodies were as follows: PKC $alpha$ (1:2,000),PKC $beta$ (1:250), PKC $gamma$ (1:500), PKC $delta$ (1:250), PKC $iota$ (1:250), andPKC µ (1:800). Proteins were visualized by enhanced chemiluminescence(ECL; Amersham), and semiquantitative analysis of PKC isoformbands was performed by scanning densitometry. At least five differentexperiments each consisting of pooled tissue obtained from 4 to10 animals were conducted for each postnatal age. To normalizedata across experiments, densitometric values for each postnatalage were expressed as a ratio in which the control lysate densitometricreadings served as thedenominator.

Data Analysis

Values are reported as mean ± SEM unless indicated otherwise. Baseline ventilation was defined as the average of the 3 minimmediately preceding each intraperitoneal injection. Post-treatmentventilatory measurements were defined as the average of threeconsecutive 1-min bins corresponding to the maximal ventilatorychanges. Differences in data among the various age groups or withineach age group for the saline and Ro 32-0432 treatments were comparedby analysis of variance (ANOVA; two-way ANOVA for repeated measures)and the Newman-Keuls test (18). A p value of < 0.05 was consideredstatisticallysignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Ventilatory Measurements

In all animals, following Ro 32-0432 administration $V$ E decreases occurred within 10 to 15 min after injection, had peakedin all animals within 20 min, and remained within 90% of peakchanges for at least 4 to 6 h (Table 1). The ventilatory reductioninduced by Ro 32-0432 was largest in the youngest animals, andgradually decreased with advancing postnatal age (Table 1; Figure1; p < 0.002, two-way ANOVA), such that at 20 to 21 d postnatalage $V$ E decreases were similar to those previously found in adultrats (9). At all postnatal ages, $V$ E decreases were primarilyassociated with TE prolongation. However, in the 2-3-d and 5-6-d-oldgroups, mild increases in TI also developed. VT changes were minimaland did not reach statistical significance at any postnatal age(Table 1; Figure 1). Concordantly, VT/TI was markedly reducedin youngest pups (from 0.73 ± 0.13 ml/s in control conditionsto 0.37 ± 0.03 ml/s after Ro 32-0432, i.e., $-$ 39.7 ± 6.1%) whereassmaller decreases in VT/TI occurred in 5-6-d ( $-$ 21.7 ± 3.4%), 10-12-d( $-$ 22.1 ± 4.4%), and 20-21-d-old pups ( $-$ 10.2 ± 5.6%). PKC inhibitionwith Ro 32-0432 exhibited significant age dependencies for TE,f, and $V$ E (p < 0.002, two-way ANOVA; Figure 1).

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TABLE 1

VENTILATORY AND WEIGHT MEASUREMENTS IN 2-3-d, 5-6-d, 10-12-d, AND 20-21-d-OLD RAT PUPS AFTER VEHICLE AND Ro 32-0432 ADMINISTRATION^*

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Figure 1. Mean (± SEM) changes (expressed as percentage change from corresponding baseline) in TI, TE, f, VT, and $V$ E after intraperitoneal injection of either vehicle (open squares) or 100 mg/kg Ro 32-0432 (closed circles) in 2-3-d, 5-6-d, 10-12-d, and 20-21-d-old rat pups. Significant differences between vehicle and Ro 32-0432 were present at all postnatal ages for TE, f, and $V$ E (p < 0.01), whereas such differences were restricted only to the younger animals for TI (p < 0.01). VT changes with Ro 32-0432 were not significantly different at any postnatal age. A prominent age-dependent effect of Ro 32-0432 was found for TE, f, and $V$ E (p < 0.002, two-way ANOVA).

PKC Expression in Dorsal Brainstem and Cortex

Western blots of protein equivalents from tissue homogenates derived from dorsal brainstem and cortical tissue at variouspostnatal ages revealed markedly different changes in PKC expressionwithin DB and Cx with maturation (Figures 2 and 3). PKC $alpha$ increasedin both DB (p < 0.04) and Cx (p < 0.01) over time. However, whilesignificant increases in PKC $beta$ occurred in Cx with advancing postnatalage (p < 0.02), significantly decreased rather than increasedexpression emerged with maturation in DB (p < 0.02; Figures 2and 3). In contrast, no developmental changes occurred in DB forPKC $gamma$ whereas increased postnatal expression of PKC $gamma$ in Cx wasobserved (p < 0.02; Figures 2 and 3). Interestingly, expressionof PKC $delta$ was lower in DB compared with Cx (p < 0.001; Figures2 and 3). PKC $iota$ expression levels were highest in younger animalsin both DB and Cx and diminished with age (p < 0.02). In DB, expressionof PKC µ was highest in 2-d-old pups and decreased with age (p< 0.02; Figures 2 and 3), whereas in Cx PKC µ increased with timereaching peak levels in adult animals (p < 0.02).

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Figure 2. Representative immunoblots for PKC $alpha$ , $beta$ , $gamma$ , $delta$ , $iota$ , and µ of dorsal brainstem (DB) and neocortex (Cx) tissue lysates harvested from 2-d, 5-d, 10-d, and 15-d-old rat pups and adult rats.

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Figure 3. Mean (± SEM) PKC expression in DB and Cx for isoforms $alpha$ , $beta$ , $gamma$ , $delta$ , $iota$ , and µ at 2 d, 5 d, 10 d, and 15 d postnatally and in adult rats (n = 5). To normalize across experiments, individual results were expressed as tissue lysate:control lysate densitometry ratios (see METHODS). In the Cx, increased expression occurred for all PKC isoforms except PKC $iota$ with maturation (p < 0.02). For PKC $iota$ , decreases rather increases occurred with advancing postnatal age (p < 0.02). In the DB, no significant changes with age occurred for PKC $gamma$ , and $delta$ , whereas increased expression of PKC $alpha$ emerged (p < 0.04). In contrast, significant age-dependent decreases in PKC $beta$ , $iota$ , and µ were present in the DB (p < 0.02).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

We have shown that in the developing rat pup endogenous PKC activity is a major determinant of normoxic ventilatory patterning.During the initial postnatal days, PKC inhibition was associatedwith marked disruption of mechanisms underlying respiratory rhythm.With advanced maturation, TE prolongation, which emerged as themajor respiratory component affected by Ro 32-0432, resulted inprogressively diminished effects. Thus, youngest animals exhibitedincreased dependency on PKC-mediated second messenger pathwaysmediating normoxic ventilation, and such role abated with increasingpostnatalage.

PKC is very abundant in neuronal tissue; for example, PKC $gamma$ is exclusively found in the central nervous system (3). Immunocytochemicallocalization studies for PKC $alpha$ and $beta$ isoforms in adult rat brainreveal heterotopic expression of these isoforms in various neuralstructures suggestive of important functional implications (19,20). Indeed, a substantial body of evidence points to a criticalrole for PKC in both pre- and postsynaptic modulation of neuronalactivity (2). Thus, the relative abundance of PKC in neuraltissue and the heterogeneity of distribution for the various isoformswithin the central nervous system is strongly suggestive thatPKC may underlie components of central ventilatory output. Insupport of such hypothesis, Haji and colleagues showed that PKCactivity modulates tonic activity and excitability of expiratoryneurons within the ventral respiratory group in the cat (21).Because the excitatory synaptic drive of these expiratory neuronsrelies on glutamate via N-methyl-D-aspartate (NMDA) and alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate(AMPA)/quisqualate receptors (22), excitatory cationic inwardcurrents in these expiratory neurons appear to be under PKC-mediatedtonic modulatory control (21). In addition, we have previouslyshown that endogenous PKC activity mediates both tonic and chemosensitiveexcitatory respiratory drives during both normoxia and hypoxiain freely behaving adult rats (7). Thus, current evidence supportsthe contention that PKC plays a prominent role in neuronal pathwaysresponsible for maintaining spontaneous ventilatory output ingeneral, and more specifically in the regulation of TE (9).

Current results further extend such findings to the developing animal which demonstrates increased dependency on PKC-mediatedsignal transduction pathways for generation and maintenance ofrespiratory timing mechanisms. As the rat pup matures, PKC dependencyof f is reduced and reaches adult levels by 20 to 21 d of age.Indeed, the magnitude of TE prolongation and consequent ventilatoryreduction were strikingly similar to those previously found inadult rats (9). Furthermore, decreases in VT/TI as an indicatorof respiratory drive occurred following Ro 32-0432 in all animalsin the absence of significant body temperature changes. The VT/TIchanges were however more pronounced in the youngest pups, lendingfurther support to the concept of a developmentally regulatedPKC dependency of respiratory drives. It should be stressed thatthe current study precludes any definitive inferences on the potentialneural sites whose activity was modulated by administration ofthe PKC inhibitor. However, we postulate that signal transductionpathways of glycinergic or GABA-ergic receptors mediating neuronalexcitability of expiratory neurons within the Bötzinger complexcould be candidate loci for the observed effect on expiratoryduration induced by Ro 32-0432 (23). Indeed, this brainstemregion which encompasses the rostral portion of the nucleus ambiguusjust caudal to the facial nucleus, and an area located in thenucleus retroambiguus at the level of the caudal medulla displaysa high density of neurons with rhythmical changes in membranepotential characterized by a depolarization in the intervals betweenphrenic bursts, thereby indicative of expiratory activity (24,25). Alternatively, endogenous PKC activity could play a modulatoryrole on cellular mechanisms involved in presynaptic neurotransmitterrelease or affect postsynaptic receptor activation in one or morebrainstem regions mediating respiratorytiming.

Additional points regarding the developmental changes in normoxic ventilation after PKC inhibition deserve some comment. First,we can not exclude the possibility that Ro 32-0432 may cross theblood-brain barrier more readily in younger rat pups. However,we selected the dose of Ro 32-0432 based on a dose-response curvein adult animals whereby increases in dosage beyond 100 mg/kgwere not associated with additional changes in ventilation (9).Thus, it is unlikely that differences in drug transport acrossthe blood-brain barrier account for the changes in ventilation.Second, it is possible that PKC inhibition could have affectedcarotid body afferent input either via a direct effect on glomuscell tonic activity or by modification of synaptic relays in thepetrosal ganglion. However, we found no evidence that peripheralchemoreceptor afferent input was modified in adult rats basedon the absence of any difference in the ventilatory responseswhen experiments were conducted in normoxia and hyperoxia (9).Thus, if PKC plays a functional role at the carotid body levelwe postulate that such role will be of minor consequences to normoxicventilatorypatterning.

It was not our specific aim to identify at this stage which of the PKC isoforms mediate the developmentally regulated respiratoryfunctions affected by inhibition of endogenous PKC activity. However,we attempted to gain more insights into this issue by examiningpostnatal patterns of PKC expression in the dorsal brainstem andneocortex. We targeted the dorsal brainstem rather than the wholemedulla because multiple nuclei with defined respiratory rolesare located in this region, and such assessment would extend onprevious information from similar studies in the adult rat (7).It is clear that more detailed mapping of PKC isoform expressionin the brainstem will be necessary, and that studies assessingthe effect of PKC inhibition on c-fos expression as a marker ofneuronal recruitment during application of respiratory stimulimay provide valuable information regarding expression-functionrelationships (26). Our findings in the neocortex for PKC $alpha$ ,PKC $beta$ , and PKC $gamma$ are in close agreement with previous studiesshowing increased levels of expression with maturation (5, 6,27- 29). Such temporally mediated increases have been postulatedto correlate with ongoing synaptogenesis in various brain regionssuch as the visual cortex, hippocampus, and cerebellum (27,30). In the current study, significantly different postnatalchanges in DB compared Cx occurred for the three calcium-dependentPKC isoforms. This was not surprising because marked differencesin time-course of PKC postnatal expression have been previouslyreported for subregions of the hippocampus (31). Indeed, PKC $alpha$ - $gamma$ transcripts showed a gene-specific expression pattern, andsignificant differences in expression were observed between theneurons of CA1, CA3, and fascia dentata within the hippocampus(31). Considering the developmental changes in the ventilatoryresponses to administration of Ro 32-0432, the more likely PKCcandidates underlying such responses would be those PKC isoformsdisplaying progressive decreases in expression within the dorsalbrainstem over time, i.e., PKC $beta$ , PKC $iota$ , and PKC µ. Obviously,verification of such hypothetical framework will have to awaitfuture development of isoform-selective PKC inhibitors or creationof transgenic animal models with site-specific targeted disruptionsin a particular PKC isoformgene.

In summary, we have shown that developing rat pups display enhanced dependency on PKC-mediated pathways for respiratory rhythmgeneration and preservation of ventilatory output. Such maturationalchanges may reflect dynamic postnatal alterations in the relativecontributions of second messenger systems to the central patterngenerator neuralnetwork.

	Footnotes

Correspondence and requests for reprints should be addressed to David Gozal, M.D., Section of Pediatric Pulmonology, Department of Pediatrics, SL-37, Tulane University School of Medicine, 1430 Tulane Avenue, New Orleans, LA 70112.

(Received in original form May 13, 1998 and in revised form August 21, 1998).

Acknowledgments: The authors are extremely grateful to Roche Products for generously providing Ro 32-0432.

Supported in part by grants from the National Institute of Child Health and Development (HD-01072), the Maternal and ChildHealth Bureau (MCJ-229163), and the American Lung Association(CI-002-N).

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