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APPETITE, OBESITY, DIGESTION, AND METABOLISM

Deterministic construct of amplifying actions of ghrelin on pulsatile growth hormone secretion

¹Division of Endocrinology and Metabolism, Department of Internal Medicine, School of Medicine, University of Virginia, Charlottesville, Virginia; and ²Division of Endocrinology and Metabolism, Department of Internal Medicine, Mayo Medical and Graduate Schools, General Clinical Research Center, Mayo Clinic, Rochester, Minnesota

Submitted 8 July 2004 ; accepted in final form 9 February 2005

	ABSTRACT

TOP ABSTRACT METHODS RESULTS DISCUSSION APPENDIX GRANTS REFERENCES

 
Ghrelin is a native ligand for the growth hormone secretagogue (GHS) receptor that stimulates pulsatile GH secretion markedly. At present, no formal construct exists to unify ensemble effects of ghrelin, GH-releasing hormone (GHRH), somatostatin (SRIF), and GH feedback. To model such interactions, we have assumed that ghrelin can stimulate pituitary GH secretion directly, antagonize inhibition of pituitary GH release by SRIF, oppose suppression of GHRH neurons in the arcuate nucleus (ArC) by SRIF, and induce GHRH secretion from ArC. The dynamics of such connectivity yield self-renewable GH pulse patterns mirroring those in the adult male and female rat and explicate the following key experimental observations. 1) Constant GHS infusion stimulates pulsatile GH secretion. 2) GHS and GHRH display synergy in vivo. 3) A systemic pulse of GHS stimulates GH secretion in the female rat at any time and in the male more during a spontaneous peak than during a trough. 4) Transgenetic silencing of the neuronal GHS receptor blunts GH pulses in the female. 5) Intracerebroventricular administration of GHS induces GH secretion. The minimal construct of GHS-GHRH-SRIF-GH interactions should aid in integrating physiological data, testing regulatory hypotheses, and forecasting innovative experiments.

somatotropic axis; growth hormone secretagogues; feedback; mathematical model; hormone pulsatility; hypothalamus; pituitary

Current models of the basic properties of the GH pulse renewal process assume reciprocal interactions among GHRH, SRIF, and GH (28–30). In the present work, we have used this foundation in an effort to incorporate the known effects of GHS in a simple network-like structure, examine integrative implications of specific pathway hypotheses, and explore the relevance of specific connections in explicating the outcomes of previously published interventional experiments that have typically infused GHS systemically. We thereby formulated four primary hypotheses of physiological control. 1) Stimulation of GHRH release by GHS is required to evoke maximal GH output in both sexes, but especially in the female. 2) Time-delayed GH feedback-induced outflow of SRIF from the periventricular nucleus (SRIF_PeV) to both the ArC and the pituitary gland in the male inhibits GH responses to the second of consecutive GHS pulses. 3) Sex differences in the GH autofeedback drive of SRIF release account for greater acute GHS-stimulated GH secretion in the female than in the male, on average, when GHS is administered intravenously at random times, and female-predominant blunting of pulsatile GH secretion in the transgenic central nervous system (CNS) ghrelin receptor-knockdown model.

	METHODS

TOP ABSTRACT METHODS RESULTS DISCUSSION APPENDIX GRANTS REFERENCES

 
Overview of Core Construct

The present analyses are built on an earlier basic model of the GH pulse renewal process in the adult male and female rat (30). No animal or human experiments were conducted, and the study is IRB exempt. Unforced automaticity of the pulse-generating mechanism arises from 1) intermittent time-delayed peripheral GH drive of SRIF_PeV outflow, which inhibits both ArC GHRH neurons transsynaptically and pituitary GH release after release from the median eminence into hypophysial-portal blood; and 2) rapid reciprocal intrahypothalamic signaling between GHRH and SRIF neurons in the ArC (SRIF_ArC), wherein SRIF_ArC suppresses GHRH neurons and, conversely, GHRH stimulates SRIF_ArC neurons (34, 39, 49, 61, 72). In this formulation, the foregoing two mechanistically distinguishable (systemic CNS and intrahypothalamic) feedback loops are coupled by their convergence on GHRH neurons. The ensemble system confers infrequent (3.3 h) large volleys of GH release with intervolley troughs (nadirs) in the male rat as well as frequent, smaller GH pulses within volleys in the male and at any time in the female animal typical of physiological output patterns (19, 20).

A principal mechanism mediating the sex difference in GH pulsatility is greater GH autofeedback drive of SRIF_PeV release in the male than in the female rodent (17, 28, 29). In the malelike ensemble construct, pulsatile GH feedback-induced SRIF_PeV release transiently inhibits the intrahypothalamic SRIF_ArC-GHRH oscillatory mechanism, thereby enforcing a delimited trough (intervolley interval of secretory quiescence). Metabolic elimination of GH attenuates SRIF_PeV restraint, which evokes a brief volley of more rapid GHRH and GH pulses of waning amplitude as observed in vivo (18–20, 57, 72, 75). In the male rat, experimental attenuation of periventricular nucleus inputs to the ArC blunts or abolishes high-amplitude GH pulses, consistent with an intermittently sensitizing action of cyclic SRIF_PeV release and withdrawal on the presumptive GHRH-SRIF_ArC oscillator (48, 49, 85). On the other hand, in the femalelike model, GH feedback stimulates SRIF_PeV release and damps the GHRH-SRIF_ArC oscillatory mechanism less effectually (30, 66). The outcome in the female includes irregular, low-amplitude GHRH and GH pulses as recorded in vivo (17, 21, 77). The foregoing core linkages thus provide a platform for integrating mechanisms of ghrelin action.

Ghrelin and GH Network: Basis of Model Structure

First, we assumed that systemic ghrelin availability is relatively stable, albeit possibly variable locally (22, 43, 44, 51, 52, 56, 78). Serum ghrelin concentrations change by <30% in relation to food intake, with no consistent correlation with GH peaks or troughs in the conscious, freely moving male rat (62, 80). One clinical study found a mean difference between women in the late follicular phase of the menstrual cycle and in men (5), and transgenic knockdown of the GHS receptor gene in catecholaminergic GHRH neurons in mice diminished GH concentrations in the adult female only (74). The model attempts to explain the latter gender contrast.

Second, GHS, like GHRH, consistently stimulate GH secretion two- to fivefold by pituitary cells in vitro (7, 12, 13, 70, 71, 89). Unlike GHRH, GHS and ghrelin induce GH gene expression only upon prolonged delivery to the infantile rat in vivo or to somatotropes in vitro (42, 54). Thus model parameters in the adult animal include GHS-dependent stimulation of GH secretion but not de novo GH synthesis.

Third, experiments have affirmed that GHS receptors are expressed in the mediobasal hypothalamus on GHRH and other neurons activated by GHS (23–25, 38, 46, 79) and that GHS stimulate total (i.e., amplitude or frequency of) GHRH release into hypothalamopituitary portal blood in vivo in the ram and ewe (31, 35). Accordingly, the model incorporates GHS-driven outflow of GHRH from the ArC.

Fourth, studies have indicated that GHS can limit hypothalamic SRIF release in vitro, but not detectably into portal blood in vivo; that it can oppose octreotide or SRIF-dependent inhibition of ArC GHRH (and NPY) neurons in the rat and guinea pig in vivo (9, 25, 27); and that it can antagonize SRIF-mediated suppression of GH secretion in the rat and human in vitro and in vivo (10, 13, 26, 71, 78). Model terms are included to represent these intrahypothalamic and hypophysial sites of SRIF-GHS antagonism.

Fifth, continuous intravenous GHS infusion amplifies GH pulse amplitude (but not frequency) 5- to 30-fold in both men and women (11, 41, 45, 73). Therefore, augmentation of GH peak height is an expectation of valid model performance.

Figure 1 is a schema showing inferred connections among ghrelin (GHS), GH, GHRH, SRIF_ArC, and SRIF_PeV with corresponding time delays. Primary pathways include feedforward by systemic GH on SRIF_PeV release after a lag D₁, GHRH stimulation of SRIF_ArC activity after lag D₂, rapid SRIF_ArC inhibition of GHRH secretion and GHRH stimulation of SRIF_ArC, and prompt SRIF_PeV inhibition of pituitary GH release and hypothalamic GHRH-SRIF_ArC oscillations (30). Superimposed on this basic structure, ghrelin presumptively attenuates SRIF_PeV- and/or SRIF_ArC-dependent inhibition of GHRH outflow (described below), facilitates GHRH secretion, antagonizes SRIF_PeV inhibition of pituitary GH release locally, and stimulates GH secretion directly. We tested the hypothesis that these collective capabilities mediate the efficacy of ghrelin and GHS more markedly in vivo than in vitro (1, 10, 63).

View larger version (31K): [in this window] [in a new window]   Fig. 1. Schema of primary connections inferred among growth hormone-releasing hormone (GHRH), somatostatin (SRIF), growth hormone (GH), and ghrelin, in the postulated GH network of the rat. The vertical dashed line separates neurons residing in the arcuate nucleus (ArC) and the periventricular nucleus (PeV). The horizontal line demarcates hypothalamic from pituitary loci of control. Putative sites and types of action of ghrelin are denoted by dotted lines and plus (stimulatory) or minus (inhibitory) signs.

The first two sections modify the earlier model to include combined (pituitary and hypothalamic) actions of GHS/ghrelin.

Pituitary gland. The rate of change of plasma GH concentrations is controlled jointly by the distribution volume, elimination kinetics, and secretion rate of GH (33, 61). In turn, the GH secretion rate is determined at least twofold by GHRH stimulation and noncompetitive SRIF inhibition (28, 29). These relationships are represented by cooperative and asymptotic dose-response Hill functions.

Two Hill functions link GHRH and SRIF_PeV outflow to GH release by the pituitary gland as follows:

(1)

where the prime denotes the rate of change of GH concentrations; GH and GHRH define instantaneous GH and GHRH concentrations; k₁ and k_r,1 are rate constants of GH elimination and secretion, respectively; n₁, and n₂ are slope (sensitivity) terms associated with the stimulatory and inhibitory effects of GHRH and SRIF, respectively; and t₁ and t₂ designate potencies of GHRH and SRIF (i.e., half-maximally stimulatory or inhibitory concentrations, EC₅₀ or IC₅₀) respectively. The assumption is that GH release requires feedforward by GHRH and partial withdrawal of SRIF antagonism (7, 15) as defined by the large-bracketed, noncompetitive relationship shown in Eq. 1.

To incorporate ghrelin action on the pituitary gland, we modified the stimulatory and inhibitory terms in Eq. 1. First, the feedforward term

is replaced by

where GHRELIN denotes the concentration of ghrelin, the coefficient n_g,0 defines sensitivity to ghrelin, t_g,0 designates stimulatory potency (EC₅₀) of GHRELIN, and g₀ corresponds to maximal efficacy of ghrelin action. Second, the feedback term

in Eq. 1 is replaced by

where

n₂ and n_g,1 define the respective sensitivities of SRIF_PeV inhibition and ghrelin stimulation, t₂ designates inhibitory potency (IC₅₀) of SRIF_PeV when GHRELIN = 0, t_g,1 represents potency (EC₅₀), and g₁ denotes efficacy of ghrelin action. The function F₁ limits opposition by ghrelin of SRIF action on the pituitary as evident in vitro (10).

Hypothalamus. The rate of change of SRIF_ArC is determined by local SRIF elimination and GHRH feedforward within ArC as follows:

(2)

where SRIF_ArC denotes the SRIF concentration in ArC, k₂ and k_r,2 are respective rate constants of elimination and release of SRIF_ArC, D₂ reflects the time delay for GHRH to stimulate SRIF_ArC release, n₃ is the slope (sensitivity) of GHRH drive of SRIF_ArC outflow, and t₃ is the EC₅₀ of GHRH feedforward on SRIF_ArC secretion. In Eqs. 2 and 3, we use sharp (i.e., direct) delays to simplify the model (28–30, 66), thus obviating the need for additional parameters to define a delay distribution.

The rate of change of SRIF_PeV is governed by the elimination process and GH feedback drive superimposed on low basal SRIF_PeV outflow as defined by the following equation:

(3)

where SRIF_PeV is the SRIF concentration in PeV, SRIF_basal is the constitutive (time-invariant basal) SRIF_PeV release, k₄ and k_r,4 are the respective rate constants of elimination and release of SRIF_PeV, D₁ is the time delay for systemic GH concentrations to stimulate SRIF_PeV release, n₅ is the slope (i.e., sensitivity) of GH drive of SRIF_PeV outflow, and t₅ is the EC₅₀ of GH feedforward on SRIF_PeV secretion. A gender distinction arises from unequal efficacy (k_r,4) of GH feedback in stimulating SRIF_PeV secretion (17, 21, 58), which here is assumed nominally to be 4.5-fold less in the female than in the male.

The rate of change of GHRH concentrations was described previously (30) using the following equation:

(4)

To represent noncompetitive antagonism between total SRIF in ArC and ghrelin on GHRH output and concentration-dependent stimulation of GHRH release from ArC by ghrelin, we replaced the rightmost inhibitory term in Eq. 4 by the following:

where

SRIF = SRIF_PeV + SRIF_ArC; t₄ and t_g,2 are the IC₅₀ and EC₅₀ of total SRIF and ghrelin, respectively; n₄ and n_g,2 are inhibitory and stimulatory slopes associated with the actions of SRIF and ghrelin, respectively; and g₂ is maximal ghrelin action on GHRH secretion (viz., GHS efficacy). We assume that supramaximal SRIF suppresses GHRH action and release noncompetitively with respect to GHS stimulation (7, 15, 27, 88, 89). Small biological variation in stochastic input to the GHRH-SRIF_ArC oscillator is achieved by allowing random variability in the sensitivity of GHRH neurons to total SRIF_ArC and SRIF_PeV inhibition (30). Specifically, the half-maximally inhibitory concentration of SRIF (t₄ in the control function above) is varied by imposing random, zero-mean, unit-normalized Gaussian noise at a nominal 5% coefficient of variation (standard deviation/mean x 100%) at 30-min intervals. Recent analyses indicate that endogenous stochastic inputs may modulate in vivo dose responsiveness in other neuroendocrine axes (50).

Model Formulation

We use two different models in the simulations. Model A (discussed in Construct for preliminary single-component analyses) includes a minor modification of the basic earlier construct (30) to represent the capability of high concentrations of ghrelin to stimulate GH secretion directly 2.5-fold (see the introduction). Model A is applied to test the impact of four putatively separate GHS actions before examining their aggregate effects. The simulations demonstrated that no single action of ghrelin is sufficient to reproduce in vivo observations fully. Accordingly, we developed model B (described in Integrative construct) to combine all four presumptive actions of GHS.

Construct for preliminary single-component analyses (model A). By extension of an earlier construct (Eqs. 1–4), we tested the impact of direct pituitary stimulation by ghrelin; i.e., a 2.5-fold effect at zero GHRH and zero SRIF. The reference model (model A) thus comprises the following (note change from Eq. 1):

(A1)

(A2)

(A3)

(A4)

with the coefficients as summarized in a previous publication (30) (S_basal = 0) and n_g,0, t_g,0, and g₀ as shown in Table 1. The gender contrast is incorporated by an approximately fourfold lower value for k_r,4 in the female to reflect reduced GH-on-SRIF feedforward (30).

Integrative construct (model B). Model B embodies the direct pituitary effect of GHS and four other putative actions (see Ghrelin and GH network: basis of model structure). The ensemble interactions are encapsulated algebraically as follows:

(B1)

(B2)

(B3)

(B4)

Nominal values of interactive constants are summarized in Table 1 and discussed further in the text. Analogously to model A, we assumed that GH feedback efficacy (k_r,4) was nominally fourfold less in the female than in the male.

PARAMETER SPECIFICS. The choice of model parameters was discussed previously (28–30) on the basis of direct measurements in the case of GHRH, SRIF, and GHS/ghrelin (76, 88, 89). The resultant parameter set under the basic model assumptions yields established pulsatile properties of GH secretion (34, 61).

In addition to a direct pituitary action of GHS in model A (mathematically modeled by the addition of a ghrelin-dependent feedforward term in Eq. B1), model B assumes that GHS opposes SRIF competitively at sites of SRIF action. There are various ways to incorporate this feature. Herein we have chosen an expression that preserves SRIF competition at the pituitary by the function F₁ and at the ArC by F₂. Because both functions are bounded from above and the action of SRIF is not restricted, GHS has a limited capability to overcome the suppressive effect of high pharmacological SRIF concentrations. The parameter choices that define F₁ and F₂ assume the following: 1) at low concentrations (including the postulated typical endogenous levels GHRELIN = 250 pg·ml^–1; Table 1), GHS is more potent at the ArC than the pituitary (t_g1 > t_g2), and 2) at high concentrations, GHS is more effective at the pituitary than at the ArC (mathematically, g₁ > g₂). Thereby, in model B, uninfused ghrelin primarily opposes the negative action of SRIF at the ArC rather than at the pituitary. The distinction is crucial in explaining the results of the experiment of Shuto et al. (74) involving transgenic silencing of the ArC (but not the pituitary) GHS receptor in the male and female mouse.

Under model B assumptions, ghrelin is active on the hypothalamus at endogenous concentrations (mathematically by means of the control function F₂). In addition, the GHRH secretion function (Eq. B4) differs from that in model A (30) by way of higher values of n₁ and n₃ to drive the GHRH-SRIF_ArC oscillator under the added GHS linkages.

Partial sensitivity analysis of model B (see APPENDIX; see also Table 6) shows that individual parameters can be varied within certain limits without disruption of model output. In addition, random Gaussian variability between 5% and 25% superimposed on GHS-driven GHRH release does not disrupt model oscillations (see APPENDIX).

Intravenous or intracerebroventricular (ICV) bolus injection of ghrelin (and in one analysis GHRH) was incorporated by adding ghr(t) to GHRELIN (or to GHRH) in core equations to reflect the hypothesized site of ghrelin action, wherein

(5)

and

(6)

where C defines the relative magnitude and "onset" designates the time of apparent GHS (or GHRH) delivery, k is the rate constant of elimination of bioactive peptide, and 0.1 h represents a nominal delay for peptide distribution and access to all sites of action.

The function ghr(t) simulates a change in the concentration of any given signal in the system without altering linkages. For example, in the initial analysis of model A, we imitated a 30-fold decrease in SRIF concentration at certain sites by dividing the corresponding local SRIF concentration by 1 + ghr(t), where ghr(t) is determined by setting C = 50 and k = 1.7 h^–1 in Eqs. 5 and 6.

Numerical Procedures and Initial Conditions

To integrate model equations, we used a Runge-Kutta 4 algorithm (Berkeley Madonna software, version 8.0.1). To solve delayed equations, we assumed a constant value for the unknown delayed functions on the required time interval to generate appropriate initial conditions.

Infusion simulations were performed after generating 50-h profiles, thereby marginalizing any impact of initial conditions. Random changes in the initial conditions were used to verify that simulation results are robust.

	RESULTS

TOP ABSTRACT METHODS RESULTS DISCUSSION APPENDIX GRANTS REFERENCES

 
Numerical results are divided into three groups. First (see Feedforward by Systemic Ghrelin: Single-Component Analyses of Pathway Relevance) model A is used to establish the need to combine putative sites of ghrelin action into a single construct. Second (see Impact of Systemic GHS Delivery on Predicted Outflow of SRIF_PeV, SRIF_ArC, GHRH, and GH; Gender Contrasts in GHS Stimulation; Female-Predominant Reduction in GH Concentrations After Partial Molecular Silencing of the GHS Receptor Expressed by Catecholaminergic Neurons in ArC; Simulation of Continuous Peripheral Ghrelin Stimulation; and Impact of Simulated Central Neural Administration of Ghrelin), model B is evaluated to explain key published observations. Third (see Analyses of Complementary and Alternative Model Connections), we extend the analysis of model B system-parameter changes.

Feedforward by Systemic Ghrelin: Single-Component Analyses of Pathway Relevance

Initial analyses (model A) were performed to test the individual assumptions that iv ghrelin stimulates GHRH secretion, opposes SRIF_PeV-mediated inhibition of GHRH release, antagonizes SRIF_ArC-enforced repression of GHRH secretion, or restrains SRIF_PeV-dependent inhibition of pituitary GH secretion. By implementation of Eq. A1 only, we show that four simulated iv ghrelin doses defined by C values (in thousands) of 20, 60, 200, and 600 yield unopposed peak GH concentrations (secretory-burst area shown in parentheses) of 115 (106), 305 (354), 385 (660), and 408 (940). These values are the same in the male- and femalelike formulations of this particular question (59, 68, 81, 89).

To simulate ghrelin injection during a spontaneous GH peak or trough in the male, we defined GHS times of onset as 53.5 h (volley) and 55.5 h (trough). These times occur randomly in the female GH pulse renewal process. Stimulus strength was designed to elicit a near-maximal GH response to the first GHS injection. The network structure included direct GHS drive of GH secretion plus any one of the following. 1) GHRH stimulation: in Eq. 6, C = 115,000, with the term ghr added to the right-hand side of Eq. A4. 2) Opposition to SRIF_PeV-mediated inhibition of GHRH release: in Eq. 6, C = 50, with the term SRIF_PeV in Eq. A4 divided by (1 + ghr). 3) Antagonism of SRIF_ArC-enforced repression of GHRH secretion: in Eq. 6, C = 50, with the term SRIF_ArC in Eq. A4 divided by (1 + ghr); or 4) Restraint of SRIF_PeV-dependent inhibition of pituitary GH secretion: in Eq. 6, C = 50, with the term SRIF_PeV in Eq. A1 divided by (1 + ghr). Significant GH secretory responses are predicted by each separate connection (Fig. 2). However, no single action with direct pituitary GHS drive is sufficient to reproduce the combined experimental observations reported previously (78).

View larger version (59K): [in this window] [in a new window]   Fig. 2. Inferred impact of each of four putative discrete loci of systemically injected ghrelin action superimposed on direct GHS stimulation of pituitary GH release (top), namely, stimulation of GHRH release from ArC (second row from top), inhibition of repression of GHRH neurons by outflow of SRIF from the PeV (SRIFPeV; third row from top), antagonism of suppression of GHRH neurons by outflow of SRIF from the SRIF (SRIFArC; fourth row from top), and opposition to blockade of pituitary GH release by SRIFPeV (fifth row from top). Outcomes are shown for two consecutive identical ghrelin pulses administered systemically at the indicated times (arrows) 2 h apart, corresponding to a spontaneous GH peak and trough in the male (left) and at any time in the female (right). In each graph, the bottom two curves are GH and GHRH (left ordinate) and the top two curves are the PeV and total (ArC + PeV) SRIF concentrations.

View larger version (33K): [in this window] [in a new window]   Fig. 3. Model-assisted predictions of the impact of fourfold combined mechanisms of intravenous ghrelin action shown in Fig. 2 superimposed on direct pituitary stimulation of GH secretion in the male and female feedback models. Two consecutive identical GHS pulses were administered (53.5 and 55.5 h) in the format described in Fig. 2.

Impact of Systemic GHS Delivery on Predicted Outflow of SRIF_PeV, SRIF_ArC, GHRH, and GH

In the adult female rat, the amplitude of GH secretory responses to consecutive identical GHS injections is consistent, but in the male animal it depends on whether stimuli are administered in rapid succession (within 3 h or less) and during a spontaneous GH peak or trough (78). To examine the possible mechanisms underlying this sex distinction, we reconstructed the predicted patterns of hypothalamic peptide outflow after sequential iv GHS pulses. Figure 4 depicts inferred time courses of the release of SRIF_PeV to the pituitary gland, the sum of SRIF_ArC plus SRIF_PeV within ArC, GHRH from ArC, and GH from the pituitary. Injections were simulated during spontaneous GH pulses (Fig. 4, top) and a putative peak vs. trough (in the male) and at any time (in the female) by way of two putative GHS doses (C = 6,000 and C = 30,000; Fig, 4, middle and bottom). Under these conditions, SRIF_PeV released by the first GHS-stimulated GH pulse in the male acted to repress intrahypothalamic SRIF_ArC-GHRH oscillations, which otherwise maintained pulsatile GHRH secretion; attenuate the amplitude of the second GHS-induced GH peak; and introduce a time delay before the onset of GH secretion in the second peak as inferred in vivo (78).

View larger version (55K): [in this window] [in a new window]   Fig. 4. Time-evolving outflow of each of SRIFPeV, SRIFArC + SRIFPeV, (GHRH, and GH for the reference model output (top), and two different pairs (low dose, middle; high dose, bottom) of peripheral ghrelin stimuli delivered during a spontaneous GH peak or interpulse trough in the male and female feedback systems (Fig. 2 format). The contrast between the sexes in the amplitude of the second GH peak reflects greater SRIFPeV repression of GHRH and GH release induced by the first GHS-stimulated GH pulse in the malelike construct. Note the difference in the left ordinate scale at top.

Gender Contrasts in GHS Stimulation

The impact of iv GHS and GHRH pulses was simulated using C = 3,000 for GHS and C = 10,500 for GHRH imposed singly or together at different times in a 3.3-h GH cycle. Peripheral GHS, but not GHRH, was assumed to gain access to ArC. When the GHS stimulus was introduced during a spontaneous volley, GH release in the male construct exceeded that in the female (Table 2). Conversely, when the GHS pulse was delivered during an interpeak trough, responses were reduced in the male only. Given that the duration of a GH volley is shorter than that of a trough, randomly timed GHS pulses over 3.3 h evoked 38% more GH secretion in the female model. This distinction is due to higher time-integrated SRIF_PeV outflow in the male (Fig. 1). Combined GHS and GHRH stimulation yielded a mean gender contrast of 24% (female > male). The outcomes are consistent with previous studies in which untimed GHS injections evoked greater GH secretion in either the male or the female (6), average responses to GHS were greater in the female than in the male rodent and human (1, 2, 10, 11, 55, 71), and GHS and GHRH were found to act in synergy (3, 10, 14, 37, 78).

Shuto et al. (74) reported significant reduction in GH pulse amplitude in the adult female, but not in the male, transgenic mouse after partial molecular silencing of the ArC GHS receptor. To simulate attenuation of CNS GHS action, we imposed a graded (1.77-, 3.16-, and 5.62-fold) decrease in the system parameter g₂ (efficacy of GHS feedforward on GHRH and antagonism of total SRIF in the ArC) and disallowed stochastic variability in ArC responsiveness for clarity (Fig. 5). According to these simulations, GHS drive is more important to maintaining GH secretion in the female feedback construct.

View larger version (54K): [in this window] [in a new window]   Fig. 5. Simulation of influence of partial molecular silencing of the GHS receptor on GHRHergic neurons in ArC in the male and female ensemble formulations under equivalent stable peripheral ghrelin drive. GH secretion patterns reflect predicted responses to 1.7-, 3.1-, and 5.6-fold decreases in the efficacy of ghrelin to drive GHRH release.

Figure 6 depicts model-predicted GH secretory responses to 1.3-, 1.7-, 2.4-, and 3.1-fold elevation of continuous peripheral ghrelin drive in the male and female constructs [imposed by increasing the term GHRELIN (250 pg·ml^–1) by these graded amounts in Eqs. B1 and B4]. Constant GHS infusion augmented the amplitude of GH pulses without disrupting their frequency or altering the sex difference in GH secretion. The effects of continuous peripheral infusion of synthetic GHS on pulsatile GH release in the human mirror the foregoing outcomes (11, 41, 45, 73).

View larger version (55K): [in this window] [in a new window]   Fig. 6. Model-assisted forecast of pulsatile patterns of GH secretion before (50–56 h) and during (56–70 h) constant systemic infusion of ghrelin in the male (left) and female (right) at graded rates sufficient to elevate peripheral ghrelin concentrations 1.3-, 1.7-, 2.4-, and 3.1-fold. Predicted outcomes for both sexes include an initial burst of GH secretion followed by sustained elevation of the amplitude of GH pulses without disruption of sex-specific pulse frequency.

One report inferred inhibition of GH secretion by ICV delivery of GHS in the male rat when injections were administered during a trough (87). In other studies, dose-dependent stimulation of GH secretion was quantitated over a large range of ICV GHS stimulus intensities (27, 87). To evaluate the implications of ICV ghrelin delivery, we assumed that central GHS acts on GHRH and SRIF neurons in ArC, but not on the pituitary gland. Therefore, the term ghr was added to Eq. B4, but not Eq. B1; the ICV stimulus parameter C in Eq. 6 was arbitrarily defined as 6,000 or 30,000; and GHS stimuli were applied during a peak or a trough in the male and at any time in the female. As shown in Fig. 7, the predicted effects of the first of consecutive ICV GHS injections on SRIF_PeV, SRIF_ArC, GHRH, and GH were similar to those inferred for the first of two peripheral GHS injections. On the other hand, the second ICV GHS pulse was less effective, especially in the male construct. The reason for this finding is that ICV delivery of ghrelin cannot antagonize inhibition of GH release by SRIF_PeV secreted in the male after the first GH pulse. Impaired responsiveness to the second of consecutive ICV GHS stimuli is observed experimentally in the adult male rat (78). Data are lacking in the female rat.

View larger version (51K): [in this window] [in a new window]   Fig. 7. Inferred ensemble model-based effects of two consecutive identical intracerebroventricular (ICV) injections of ghrelin administered 2 h apart in the male (left) and female (right). Predicted peptide responses illustrate that SRIFPeV release driven by the first GH pulse would inhibit GHRH secretion and GH release during the second ICV ghrelin stimulus in both sexes. The construction assumes that ICV ghrelin does not directly antagonize SRIFPeV inhibition of pituitary GH release.

The plausibility of certain combined (but incomplete) pathway connections was appraised on the basis of selected modifications of Eqs. B1–B4.

First, we tested the implications of stepwise muting of ghrelin's bipartite capabilities to stimulate GHRH secretion and antagonize total SRIF inhibition in the ArC. Simulations comprised two iv GHS stimuli of identical strength C = 30,000 (a maximally effective input) administered 2 h apart. The two central actions of GHS in the ArC were blunted by reducing the system parameter g₂ 3.1-, 10-, and 31.6-fold, which progressively decreased GHS-stimulated GH secretion, especially in the female (Fig. 8).

View larger version (66K): [in this window] [in a new window]   Fig. 8. Putative outcomes of muting maximal ghrelin-dependent stimulation of GHRH release and ghrelin-dependent inhibition of total SRIF suppression in the ArC. Three graded restrictions were imposed on both of two consecutive GHS pulses in the male and female models.

to the right-hand side of Eq. B3 and the term ghr to Eqs. B3 and B4, but not to Eq. B1. Different efficacies of GHS are imposed by adjusting values of the factor f. The coefficient k_r,g = 12 pg·ml^–1·h^–1 was chosen a priori to yield a minimal change in the GH response to ICV ghrelin if f = 1 (<1% difference between f = 0 and f = 1). Because the kinetics of ICV ghrelin are not known, we explored fixed, near-maximal GHS efficacy (f = 300) and each of nine nominal ICV ghrelin half-lives (1-, 1.33-, 1.77-, 2.37-, ..., and 10-fold less than the reference plasma value) (Table 5). We postulated that reboundlike GH secretion would occur with rapid decay of ICV ghrelin, allowing withdrawal of putative GHS-stimulated SRIF_PeV outflow. Rebound GH release was generated in the female at any time and in the male during a trough. These analyses suggest that GHS-induced rebound GH release would require a shorter half-life of ghrelin in the brain than it would in the circulation.

View larger version (72K): [in this window] [in a new window]   Fig. 9. Implications of assumed dose-escalating stimulation of SRIFPeV release (from left to right in each row) by a single ICV GHS pulse at 53.5 h in the male during a volley (53.5 h, top) or during a trough (51.5 h, middle) and in the female (53.5 h, bottom). Numerical values in brackets denote simulated relative (i.e., "-fold") stimulation of SRIFPeV outflow.

View larger version (66K): [in this window] [in a new window]   Fig. 10. Model implications of putatively graded suppression of SRIFPeV release by a single systemic ghrelin pulse administered during a volley (middle and right) or trough (left). Suppression was simulated by 3.1-, 10-, and 31.6-fold reductions in SRIFPeV release (top, middle, and bottom, respectively) in both the male (left and center) and female (right) constructs. The resultant profiles show greater efficacy of the GHS pulse imposed during a trough than during a volley in the male and progressive quenching of spontaneous GH pulse amplitude in the male, but not in the female, because of diminished cyclic outflow of SRIFPeV to the SRIFArC-GHRH oscillator and to the pituitary gland.

View larger version (67K): [in this window] [in a new window]   Fig. 11. Effect of restricting peripheral GHS-dependent stimulation of GHRH release and antagonism of SRIFArC (but not SRIFPeV) action. The plots show (from top to bottom) graded 3.1-, 10-, or 31.6-fold suppression of both actions of GHS at 53.5 and 55.5 h.

	DISCUSSION

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Simulation studies supported the thesis that important loci of GHS action comprise the following: 1) antagonism of the combined actions of SRIF_PeV and SRIF_ArC within ArC, thereby sustaining high-amplitude GH pulsatility under continuous GHS drive; 2) inhibition of SRIF_PeV-imposed repression of the GHRH-SRIF_ArC oscillator, thus maintaining sex-related distinctions in GH secretory burst frequency; 3) enhancement of GHRH release acutely from ArC; and 4) direct stimulation of GH secretion from the pituitary gland. In this light, experimental data indicate that anatomic hypothalamopituitary disconnection attenuates GHS efficacy markedly in the rat, pig, and human (65, 78); GHRH antiserum or a GHRH receptor antagonist inhibits GHS-stimulated GH secretion by >80% (27, 63); truncational deletion of the GHRH-receptor gene reduces GHS efficacy profoundly in the human and mouse (32, 63, 68, 69); transgenic knockdown of GHS receptors on GHRH neurons reduces GH secretion in the adult female mouse but not the male (74); and GHS and GHRH stimulate GH secretion synergistically in vivo but only additively in vitro (3, 10, 14, 37, 78).

On the basis of these assumptions, the current model predicts that stimulation of GHRH release by GHS is required to evoke maximal GH output in both sexes, but especially in the female, and time-delayed, GH feedback-induced SRIF_PeV outflow to both the ArC and the pituitary gland in the male could inhibit GH responses to the second of consecutive GHS pulses. A corollary prediction is that a single GHS stimulus will evoke less GHRH-GH outflow in the male during a spontaneous trough than during a pulse but comparable GHRH-GH release at any time in the female animal. These inferences coincide with in vivo observations (17, 36, 58, 78).

Third, the multipeptide model allowed indirect assessment of plausible mechanisms conferring sex differences in GHS action. For example, the sex difference in GH autofeedback could account fully for greater acute GHS stimulation in the female than in the male, on average, when GHS is administered intravenously at random times and female-predominant blunting of pulsatile GH secretion in the transgenic CNS ghrelin receptor-knockdown model. The first outcome is recognized in the rat and human and the second in the mouse (1, 11, 55, 74, 78). Nonetheless, available experimental data do not exclude additional feedback-independent mechanisms of heightened GHS action in the female compared with the male. For example, estrogen induces transcription of the human GHS receptor gene in vitro and stimulates synthesis of GH in the autotransplanted pituitary gland in vivo (16, 64).

A simplifying assumption was made that blood ghrelin provides a stable stimulus in both the CNS and the pituitary gland (80). Acylated ghrelin is transported from the blood into the CNS, where it exerts pleiotropic effects (4, 23, 84, 86). Ghrelin is synthesized not only in gastric oxyntic cells (44) but also in the anterior pituitary gland, hypothalamus, placenta, kidneys, and elsewhere (22, 51, 52). The sources of ghrelin that primarily drive pulsatile GH secretion are not known.

Previous laboratory and clinical investigations have suggested that GHS may attenuate SRIF-dependent inhibition of GHRH secretion from the ArC and GH release from the pituitary gland (13, 25–27, 60, 67, 71). The relative importance of these two neuroanatomic sites of action is not known (74). From a modeling perspective, definitive estimation will require precise knowledge of the dose-response properties and kinetics of ghrelin at these locations.

By way of qualification, the GHS-GHRH-SRIF-GH feedback model does not embody all possible loci of ghrelin action, but rather focuses on fundamental connections. The objective is to extend intuitive insights by incorporating time delays and nonlinear interface functions objectively in an interlinked system and thereby explore potential pathway adaptations with regard to sex, pubertal development, and aging (54, 55, 89). For example, CNS actions of GHS to promote GHRH release and oppose intra-ArC inhibition by SRIF were crucial to explicate two published paradoxes: the female-predominant response to neuronal GHS-receptor silencing in the mouse (74) and unequal reboundlike GH release in the male and female rat after ICV injection of ghrelin (8). In contrast, simulated inhibition of PeV SRIF outflow by GHS did not reproduce these contrasts.

A second limitation of the current effort is that the model is not completely validated, given that not all parameter values are definable on the basis of earlier experimental data. However, partial parameter sensitivity assessment (see APPENDIX) indicated that particular numerical choices are not highly constraining to general model performance, thus indicating the pivotal importance of relevant connectivity per se. Peptide elimination rates may be viewed as relatively stable within species. Amplifying and damping parameters, such as Hill coefficients, remain to be determined at local interface sites, such as GHS-driven GHRH release or antagonism of SRIF in the ArC. Although precise delay times within the hypothalamus are not known, simulation of a range of kinetics suggested general boundaries for CNS vs. systemic GHS elimination. Last, although stochastic biological inputs operate in some complex physiological systems (50), we did not systematically explore such properties.

The burgeoning repertoire of CNS, pituitary, and systemic signals that are reported to direct pulsatile GH secretion underscores the need to extend integrative concepts that account for variable biological time delays and the nonlinearity of concentration-dependent effects (34, 61). The collective properties of neuroendocrine regulation make intuitive estimates of such dynamic control difficult. For objective estimates, minimal requirements include valid representation of structural connectivity among primary regulatory signals and more precise experimental estimates of in vivo effector kinetics and dose-response properties. The expectation is to thereby reexamine earlier experimental inferences, test the implications of proposed connections, and facilitate alternative interpretations of complex data. Ultimate objectives are to stimulate new mechanistic hypotheses and achieve accurate analytical reconstruction of unobserved interactions.

	APPENDIX

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Partial Parameter Sensitivity Analysis

By testing a nominal range of individual parameter choices, one may estimate boundaries of stable operating properties. The outcomes of this approach are shown in Table 6 for the male rat output model. A valid male system has the minimal requirement of generating recurrent multiphasic volleys as verified over a finite parametric grid.

Although it is not computationally practicable to fully map a 31-dimensional hyperspace, individual parametric sensitivity analysis showed that the reference parameter set (Table 1) has some flexibility. This is consistent with expected physiological variability among individuals. The analysis has limitations when based on exploring each parameter range individually and on the use of a simple sensitivity criterion. Consequently, some parameters allow variation from zero to infinity and, therefore, do not affect the typical features of the male profile as long as all other parameters are fixed. In particular, parameters related to the control function F₁(g₁, t_g,1, and n_g,1) that governs the model response to pharmacological GHS are not relevant within the physiological operating range.

Impact of Increased Variability in the Sensitivity of GHRH Neurons to GHS (t₄)

We tested the impact of elevated random variability in t₄ by increasing the coefficient of variation of superimposed gaussian noise from 5% to 25% (METHODS). The increase does not disrupt the general characteristics of male or female GH profiles (Fig. 12).

View larger version (23K): [in this window] [in a new window]   Fig. 12. Impact of increased variability in the sensitivity of GHRH neurons to ghrelin. The simulation plots compare model predictions based on 5% (dotted lines) and 25% (solid lines) variability in the male (left) and female (right) constructs.

	GRANTS

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	ACKNOWLEDGMENTS

 
We acknowledge excellent assistance provided by Kris Nunez and Kandace Bradford in preparing the manuscript.

	FOOTNOTES

 

Address for reprint requests and other correspondence: J. D. Veldhuis, Division of Endocrinology and Metabolism, Dept. of Internal Medicine, Mayo Medical and Graduate Schools, General Clinical Research Center, Mayo Clinic, 200 First St. SW, Rochester, MN 55905 (E-mail: veldhuis.johannes{at}mayo.edu)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

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