Social Status Controls Somatostatin Neuron Size and Growth

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The Journal of Neuroscience, June 15, 2000, 20(12):4740-4744

Social Status Controls Somatostatin Neuron Size and Growth
Hans A. Hofmann and Russell D. Fernald
Neuroscience Program, Stanford University, Stanford, California 94305

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Many animal species show flexible behavioral responses to environmental and social changes. Such responses typically requirechanges in the neural substrate responsible for particular behavioralstates. We have shown previously in the African cichlid fish,Haplochromis burtoni, that changes in social status, includingevents such as losing or winning a territorial encounter, resultin changes in somatic growth rate. Here we demonstrate for thefirst time that changes in social status cause changes in thesize of neurons involved in the control of growth. Specifically,somatostatin-containing neurons in the hypothalamus of H. burtoniincrease up to threefold in volume in dominant and socially descendinganimals compared with cell sizes in subordinate and socially ascendingfish. Because somatostatin is known to be an inhibitor of growthhormone release, the differences in cell size suggest a possiblemechanism to account for the more rapid growth rates of subordinateand socially ascending animals compared with those of dominantor socially descending fish. These results reveal possible mechanismsresponsible for socially induced physiological plasticity thatallow animals to shift resources from reproduction to growth orvice versa depending on the socialcontext.

Key words: cichlid fish; dominance; life history; somatostatin; neuron size; social status; phenotypic plasticity

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Distinct behavioral tactics used by individuals of the same species under different social and environmental conditions oftenreflect changes in reproductive opportunity (Williams, 1966; Lott,1982). For example, individuals may delay reproduction if theycannot compete with currently superior animals. In species withindeterminate growth, such as fish, dominance status may affectthe life-history strategies of individuals by regulating growthrate (Metcalfe et al., 1989; Warner, 1991; Hofmann et al., 1999a).How animals adjust to the diverse physiological requirements ofsuch different strategies isunknown.

To understand the neural and endocrine modifications produced by social change, we induced changes in dominance among Africancichlid fish, Haplochromis burtoni, and measured the effects.H. burtoni is a nonseasonal breeder and lives in shore pools ofLake Tanganyika in tropical East Africa (Fernald and Hirata, 1977a,b).The behavior of this species has been carefully described in boththe laboratory (Fernald, 1977) and the field (Fernald and Hirata,1977a). At any time, ~30% of the adult male population show brightbody coloration, perform 17 distinct behavioral acts, maintainterritories, and have mature testes [territorial fish (T)]. OnlyTs are reproductively active. The remaining males [nonterritorialfish (NT)] school with females, are cryptically colored, and sexuallyregressed. We have demonstrated previously that a change in socialstatus leads to a change in the size of gonadotropin-releasinghormone (GnRH)-containing neurons of the hypothalamus. In Ts,GnRH-containing neurons are eight times larger than those in NTs(Francis et al., 1993). These differences between T and NT maleshave been studied in stable social situations or after individualswere moved to new tanks (Francis et al., 1993). However, the naturalconditions under which these fish live are much less stable thanthose in the laboratory (Fernald and Hirata, 1977b). For example,strong winds often produce significant interruption of the threedimensional layout of the shallow habitats. Moreover, Fernaldand Hirata (1977b) reported that hippopotami (Hippopotamus amphibius)traversed their study sites and disrupted the territorial structuresoccupied by T males. In addition to changes in the physical environment,the social system may also change because T males are more likelyto be targets of predation because of their conspicuously brightcoloration (Fernald and Hirata, 1977b). This instability forcesindividuals to adjust their behavior and physiology quickly asreproductive opportunities come andgo.

We have shown previously (Hofmann et al., 1999a) that NTs and males ascending in social rank (NT $right-arrow$ T) show an increased growthrate, whereas Ts and socially descending animals (T $right-arrow$ NT) slow theirgrowth rate or even shrink. Because of the pronounced growth reductionin those social categories (Hofmann et al., 1999a), we hypothesizedthat somatostatin is the most likely mediator of this effect.This neuroendocrine signaling peptide inhibits the release ofgrowth hormone (GH) from the pituitary to regulate somatic growth(Brazeau et al., 1973). To examine whether neurons containingthis neuropeptide might play a role in the socially mediated controlof growth in H. burtoni, we measured the size of somatostatin-containingneurons in the preoptic area (POA) of the hypothalamus as a functionof social status. Many signaling neuropeptides that control therelease of pituitary hormones are produced in the POA, which isknown for its importance in both growth and reproduction (Palkovits,1988).

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

To induce social change, we subjected animals to a fluctuating environment (Hofmann et al., 1999a), simulating alterationsin the natural environment caused by hippopotamus visits, winds,predation, etc. (Fernald and Hirata, 1977a). Animals were observedand their growth was measured before they were killed, after whichchanges in the preoptic brain area weremeasured.

Animal care. Fish derived from a wild-caught stock population were kept in aquaria under conditions similar to those of theirnatural environment (Fernald and Hirata, 1977b): pH 8, 28°C watertemperature, and 12 hr light/dark cycle with full-spectrum illumination.Gravel covered the floor of the aquaria, and flowerpots on thesubstrate facilitated the establishment and maintenance of territoriesnecessary for successful reproduction (Fernald and Hirata, 1977a).Fish were fed every morning ad libitum with cichlid pellets andflakes (AquaDine, Healdsburg, CA). All work was in compliancewith the Animal Care and Use Guidelines at Stanford Universityand approved by the local Administrative Panel on Laboratory AnimalCarecommittee.

Experimental design. Males that were individually identified via colored tags (7-10 fish per tank) from different age cohortswere placed in 100 l aquaria (91 × 45 × 25 cm) with approximatelythe same number of females. The standard lengths (SL) and weightsof each fish were measured weekly or biweekly. Because fish typicallydisplay their normal behaviors <1 hr after being measured, theinterval between times of handling was long enough for the fishto recover from this stressor. We defined the growth rate as therelative change in SL over a 7 d period (Hofmann et al., 1999a).Growth rates were independent of standard length (Fig. 1), aswas shown by linear regression analysis (regression ANOVA; F_(1,19)= 0.7975; r² = 0.04; p = 0.383).

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Figure 1. Growth rate shown as a function of standard lengths, illustrating that these are independent for the range of fish sizes in this study (linear regression ANOVA; F_(1,19) = 0.7975; r² = 0.04; p = 0.383).

We induced changes in social status by altering the habitat through rearrangement of the number and location of territorialshelters. Five days after an environmental change, we measuredthe standard length and weight of each animal and recorded theirsocial status. The three possible outcomes are that animals (1)maintained their status as T or NT; (2) ascended in status (NT $right-arrow$ T);or (3) descended in status (T $right-arrow$ NT). After these manipulations,the fish often showed dramatic changes in growth; NTs and NT $right-arrow$ Tsgrew faster than Ts and T $right-arrow$ NTs, which either grew slightly or evenshrank (Hofmann et al., 1999a).

Behavioral observations. Before being killed, all animals were observed at least three times per week for ~20 min between10:00 A.M. and 1:00 P.M. Ts and NTs were categorized based ontheir characteristic coloration and behavioral patterns (Fernald,1977). Brightly colored T males display a black lachrymal stripeacross the eyes and are aggressive, as seen by their chasing,biting, exhibiting threat displays, and border conflicts withother Ts. These males are reproductively active, as shown by diggingspawning pits in the gravel and courting and spawning with females.In contrast, the sandy gray NTs tend to form schools and fleefrom chasing Ts. The location of the territories within each tankwas alsorecorded.

Gonadal analysis. Five days after a habitat disruption, animals were anesthetized and quickly killed by rapid cervical transection.Gonads were removed and weighed, and the gonadosomatic index (GSI)was calculated: GSI = (organ weight [g]/body weight [g]) ×100.

Immunocytochemistry. After the animals were killed, brains were rapidly removed and immersion-fixed overnight (4% paraformaldehydein phosphate buffer, 4°C). The tissue was cryoprotected overnight(4°C in 30% sucrose), frozen at $-$ 20°C, and then sagittally sectionedat 30 µm on a microtome cryostat (Microm, Heidelberg, Germany).Tissue was collected on slides (Colorfrost/Plus; Fisher Scientific,Pittsburgh, PA) and kept at $-$ 20°C until further processing. Toidentify somatostatin-immunoreactive (IR) cells, sections wereincubated overnight at 4°C with a primary polyclonal antiserumraised in rabbit against somatostatin (Peninsula Laboratories,Belmont, CA), previously used successfully on teleost fish neurons(Stroh and Zupanc, 1996). To locate the antibody binding site,avidin-biotin amplification was used (Vector Laboratories, Burlingame,CA) and visualized using nickel-enhanced 3,3'-diaminobenzidineas chromogen. After dehydration in an ascending alcohol seriesand clearing in xylene, sections were mounted in Permount (FisherScientific) under coverslips. Four brains (one of each socialcategory) were processed as agroup.

In teleosts, neuropeptide-producing hypothalamic neurons project to their respective target cells in the pituitary directly,because there is no portal system (Peter et al., 1990). Grau etal. (1985) have shown that, in a closely related cichlid species,the Tilapia, preoptic somatostatin-IR neurons project to the pituitary.In the H. burtoni pituitary, somatostatin immunoreactivity ismost prevalent where the proximal pars distalis interdigitateswith the central and posterior neurohypophysis (H. A. Hofmannand R. D. Fernald, unpublished observations). This is also thelocation in which the growth hormone-producing somatotrophs arelocated in cichlids (Melamed et al., 1999).

In addition to the neuron population in the POA, the somatostatin antiserum consistently stained cells in the ventrolateraltelencephalon, the optic tectum, the caudal hypothalamus, themedulla oblongata, and occasionally in other areas, consistentwith previous reports in fish (Grau et al., 1985; Margolis-Nunnoet al., 1987; Batten et al., 1990; Stroh and Zupanc, 1996; Vallarinoet al., 1997).

Cell size measurements. The soma sizes of neurons immunoreactive to somatostatin in the POA were measured using computer-aidedanalysis of video images (NIH Image 1.61; Wayne Rasband, NationalInstitutes of Health, Gaithersburg, MD) viewed via microscope(Axioskop; Zeiss, Oberkochen, Germany). For a minimum of 50 neuronsper animal, the cross-sectional area was measured for neuronswith the nucleus in the plane of section. The measuring errorwas <7%, as estimated by repeatedly measuring cells of the samesections in some fish. Measurements of stained cells in the ventraltelencephalon of some individuals did not yield any evidence forsoma sizedifferences.

We tested whether body size differences contributed to differences in somatostatin-IR soma size for the range of fish we used(4.30 cm/2.48; 7.85 cm/15.79). The size of somatostatin-containingcells is not a function of animal size (Spearman rank correlation;r_s = 0.1709; p = 0.4590; n = 18). Nonetheless, to eliminate anypossible variation introduced by body size differences, cell sizemeasurements were corrected with the following procedure (Whiteand Fernald, 1993): corrected soma sizes SS_c = SS_u + {[(SS_u *SL_x/SL) $-$ SS_u] * K}, where SS_u is the uncorrected mean soma sizeof an individual fish, SL its standard length, and SL_x is themean standard length for the whole subject pool of this study.K is a constant for the contribution of SL to SS_u as determinedby the Spearman rank test for that sample. This correction was5.2% orless.

Statistics. All values are presented as means ± SE. Soma sizes and growth rates of different social categories were comparedby means of ANOVA with post hoc group comparisons after Tukey-Kramerusing GB-Stat software (Dynamic Microsystems, Silver Spring,MD).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Five days after a habitat disruption, changes were observed in social status of some animals. In individuals that changedstatus, we found changes in rate of growth, gonad size, and sizeof somatostatin-containing neurons in the POA. Thus, an environmentalmanipulation produced substantial changes in the behavior, body,and brain of individualmales.

Growth

In the 5 d after an environmental change was induced, NTs and NT $right-arrow$ T males grew significantly faster than Ts and T $right-arrow$ NTs (Fig.2). This result is consistent with our previous findings (Hofmannet al., 1999a). Growth rates of NTs and NT $right-arrow$ Ts were combined, aswere growth rates of Ts and T $right-arrow$ NTs, because their respective growthrates were not significantly different.

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Figure 2. Average ± SE growth rates calculated as the relative change in standard length for four distinct social classes of males shown 5 d after a habitat disruption. NT and NT $right-arrow$ T males grew significantly faster than T and T $right-arrow$ NT animals (ANOVA; F_(3,14) = 8.4407; p < 0.002).

Gonad size

NT fish had relatively smaller gonads than did NT $right-arrow$ T, T, and T $right-arrow$ NT males (Fig. 3). Thus, within 5 d after habitat disruption,NT $right-arrow$ Ts increased gonad size to nearly T levels, whereas T $right-arrow$ NTs didnot show a significant decrease.

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Figure 3. Mean ± SE GSIs presented for each of the four social categories of NT, NT $right-arrow$ T, T, and T $right-arrow$ NT 5 d after habitat disruption. Differences between NTs and Ts are significant (Mann-Whitney U test; U = 31; n₁ = 5; n₂ = 7; p < 0.02), whereas differences between NTs and NT $right-arrow$ Ts (U = 30; n₁ = 5; n₂ = 8; p = 0.11) and T $right-arrow$ NTs (U = 32; n₁ = 5; n₂ = 8; p = 0.06), respectively, are only nearly significant. Interestingly, NT $right-arrow$ T animals display T-sized gonads only 5 d after they became territorial (U = 39; n₁ = 8; n₂ = 7; p = 0.17). Correspondingly, the gonads of T $right-arrow$ NT males had not regressed compared with Ts after the same time interval (U = 40; n₁ = 8; n₂ = 7; p = 0.73).

Somatostatin-IR soma sizes

The size of somatostatin-IR somata depended on social status. NTs and NT $right-arrow$ Ts had substantially smaller somatostatin-containingneurons than did T $right-arrow$ NTs and Ts, as can be seen from the representativeexamples in Figure 4. Statistical analysis confirmed that thesoma size differences are significant (for details, see Fig. 5a).Somatostatin cell size is significantly correlated with overallgrowth rate (Fig. 5b). The resulting inverse relationship betweencell sizes and growth rates was fitted by a linear regressionanalysis (regression ANOVA; F_(1,16) = 11.4133; r² = 0.42; p < 0.001). Interestingly, staining intensity as an indicatorof antigen amount appeared to vary as well between the groups.The somatostatin-IR cells of NTs and NT $right-arrow$ Ts generally exhibitedlighter staining compared with T $right-arrow$ NTs and Ts (Fig. 4). Althoughthese differences were qualitatively consistent, they are difficultto quantify.

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Figure 4. Photomicrographs of neurons in the preoptic area of H. burtoni of four different social categories, stained to reveal presence of somatostatin. Five days after social change was induced, brains were dissected and immunolabeled (see Materials and Methods). Note that NT and NT $right-arrow$ T males have smaller somatostatin-immunoreactive somata than do T and T $right-arrow$ NT animals. Scale bar, 10 µm.

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Figure 5. Relationship among social status, somatostatin cell size, and growth rate. a, Somatostatin-immunoreactive neuronal soma size (mean ± SE) shown for each of the four social categories. Cross-sectional soma areas (n $>=$ 50 cells for each individual) differ significantly depending on social status (ANOVA; F_(3,14) = 8.7834; p < 0.002). NT (n = 5) and NT $right-arrow$ T (n = 4) males have smaller soma sizes than do T $right-arrow$ NT (n = 6) fish (p < 0.05 and p < 0.01, respectively; Tukey-Kramer post hoc comparisons). Soma sizes of NTs and NT $right-arrow$ Ts are also different from those in Ts (n = 3) (p < 0.05 for both comparisons). b, Growth rates plotted as a function of the somatostatin-IR soma size. NTs and NT $right-arrow$ Ts males (filled circles) have smaller soma cross-sectional areas and grow faster than Ts and T $right-arrow$ NTs (open circles). Data are fitted (dark line) with y = 0.19 * x + 8.95 using linear regression analysis (regression ANOVA; F_(1,16) = 11.4133; r² = 0.42; p < 0.001).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The goal of these experiments was to discover the neuroendocrine mechanisms responsible for differential growth rates afterchanges in social status. How is growth rate modified in malesthat change social status? Animals must recognize a change inreproductive opportunity, change social status, and adjust theirphysiological and neural state appropriately. The differentialregulation of somatostatin release is a likely mechanism for thiscontrol, because this neurohormone is known to inhibit the releaseof GH from the pituitary (Brazeau et al., 1973). Our findingssuggest that, if somatostatin cell size is correlated with itsrelease, either positively or negatively, the levels of GH maychange appropriately to allow the observed changes ingrowth.

We do not yet know how social status regulates somatostatin expression and release into the pituitary. Fox et al. (1997) recentlyshowed in this species that socially descending fish (T $right-arrow$ NT) consistentlyexhibited high levels of cortisol. This change in cortisol levelmay be part of an endocrine mechanism for growth control becauseglucocorticoids are known to inhibit somatic growth (humans: Blodgettet al., 1956; rats: Loeb, 1976; Mosier et al., 1976; teleosts:Pickering, 1990). In a closely related tilapia species, Oreochromismossambicus, chronic administration of cortisol leads to a reductionin body weight and reproductive indicators, such as gamete sizeand levels of sex steroids (Foo and Lam, 1993). However, the interactionsbetween somatostatin, GH, and cortisol are notoriously complex(for review, see Thakore and Dinan, 1994; van Weerd and Komen,1998), so there may be additional factors involved in the sociallymediated growth regulation of H. burtoni.

Our discovery that growth rates are inversely correlated with somatostatin neuron size suggests that, at least in descendinganimals with high levels of cortisol (Fox et al., 1997), socialsignals mediate cell size via a cortisol-mediated pathway. Inaddition, because Ts spend less time feeding (Fernald and Hirata,1977a; Munthali, 1996), they may be comparable with fasting fishin which growth hormone levels are increased despite a reductionin growth (Sumpter et al., 1991). Interestingly, measurementsof circulating GH in H. burtoni suggest that GH levels may indeedbe increased in Ts and T $right-arrow$ NTs (Hofmann et al., 1999b). Althoughit is not completely clear what role somatostatin plays in fastingfish (Holloway et al., 1994), one possibility is that, in thisstate, somatostatin release is inhibited, possibly resulting inpeptide accumulation in thecells.

Whether larger somatostatin-IR neurons reflect increased accumulation or production is unknown. Interestingly, in rodents,hypothalamic somatostatin expression and peptide content are sexuallydimorphic and dependent on gonadal steroids (Murray et al., 1999;Nurhidayat et al., 1999). These differences are inversely correlatedto secretory capacity (Murray et al., 1999). Several factors areknown to affect hypothalamic somatostatin secretion. In vitroexperiments in rats showed that the food intake-controlling hormoneleptin (Quintela et al., 1997a), transforming growth factor- $beta$ (Quintela et al., 1997b), and the inhibitory transmitter GABAin concert with estrogen (Arancibia et al., 1997) each inhibitsomatostatin secretion. In addition, somatostatin can inhibitits own release via a negative autofeedback (Aguila, 1998). Inrainbow trouts, the sex steroid estradiol decreases plasma somatostatinlevels and makes pituitary somatotrophs less sensitive to somatostatin-mediatedGH inhibition (Holloway et al., 1997). Somatostatin secretionis stimulated by NMDA and L-glutamate (Joanny et al., 1997) andnitric oxide (Aguila, 1994). Together, there are clearly numerouspossible regulatory factors associated with the control of somatostatinneuron size in H. burtoni.

When social opportunities change, animals must exhibit quick behavioral and physiological responses. For example, defeatedH. burtoni males slow their growth but maintain their reproductivecapabilities as long as possible (Nguyen et al., in preparation).In our study, such descending males still exhibited T-size gonads5 d after the loss of their territory. Later, they show what mightbe called "environmental optimism" by allocating resources againtoward growth. When they finally become territorial again, theirgonads mature extremely rapidly. However, the broader questionof how social information is transduced into cellular and physiologicalchanges remains a mystery. Socially induced responses that occuronly under pathological conditions, such as psychosocial dwarfismin humans (Sänger et al., 1977; Green et al., 1984), may reflectadaptive mechanisms that evolved under less severe circumstances,such as changes in social status exhibited by H. burtoni. Becausethe social environment clearly regulates many aspects of physiologyin humans and other animals, understanding the mechanisms responsiblemay allow us to understand the evolution and control of this importantfeature of socialinteractions.

  FOOTNOTES

Received Oct. 12, 1999; revised Feb. 15, 2000; accepted April 6, 2000.

This work was supported by a postdoctoral fellowship from the Deutsche Forschungsgemeinschaft (H.A.H.) and National Institutesof Health Grant NS 34950 (R.D.F.). We thank A. Ettinger, A. Greenwood,R. Henderson, K. Hoke, W. Loher, R. Robison, and C. Zygar forcomments on earlier versions of this manuscript, and E. Bennettand S. Stonington for the help with some of theexperiments.
Correspondence should be addressed to Hans A. Hofmann, Neuroscience Program, Stanford University, Jordan Hall, Building 420,Stanford, CA 94305. E-mail: hans{at}psych.stanford.edu.

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MATERIALS AND METHODS
RESULTS
DISCUSSION
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