Insulin‐like growth factor 1 relieves the constraints on the growth of young wild passerines

To gain a selective advantage for survival in stochastic environments, the growth of different body parameters of juvenile animals should be constantly adjusted according to prevailing conditions. Hormones, especially insulin‐like growth factor 1 (IGF‐1), are an important part of physiological mechanisms mediating life‐history variability in free‐living animals when connecting available resources (e.g. food) with pathways of somatic growth. We used an IGF‐1 injection treatment in free‐living European Pied Flycatcher Ficedula hypoleuca nestlings to mimic experimentally the differentiation of growth conditions for chicks with a similar genetic background. We showed that there is probably a physiological trade‐off for young animals between the growth rates of structural size and body mass, where IGF‐1 could be part of the physiological modulatory system of this trade‐off. By weakening internal constraints that limit growth, IGF‐1 could help to relieve the trade‐off between these competing body size parameters.     

Mediation of vertebrate life histories via insulin‐like growth factor‐1

Life‐history traits describe parameters associated with growth, size, survival, and reproduction. Life‐history variation is a hallmark of biological diversity, yet researchers commonly observe that one of the major axes of life‐history variation after controlling for body size involves trade‐offs among growth, reproduction, and longevity. This persistent pattern of covariation among these specific traits has engendered a search for shared mechanisms that could constrain or facilitate production of variation in life‐history strategies. Endocrine traits are one candidate mechanism that may underlie the integration of life history and other phenotypic traits. However, the vast majority of this research has been on the effects of steroid hormones such as glucocorticoids and androgens on life‐history trade‐offs. Here we propose an expansion of the focus on glucocorticoids and gonadal hormones and review the potential role of insulin‐like growth factor‐1 (IGF‐1) in shaping the adaptive integration of multiple life‐history traits. IGF‐1 is a polypeptide metabolic hormone largely produced by the liver. We summarize a vast array of research demonstrating that IGF‐1 levels are susceptible to environmental variation and that IGF‐1 can have potent stimulatory effects on somatic growth and reproduction but decrease lifespan. We review the few studies in natural populations that have measured plasma IGF‐1 concentrations and its associations with life‐history traits or other characteristics of the organism or its environment. We focus on two case studies that found support for the hypothesis that IGF‐1 mediates adaptive divergence in suites of life‐history traits in response to varying ecological conditions or artificial selection. We also examine what we view as potentially fruitful avenues of research on this topic, which until now has been rarely investigated by evolutionary ecologists. We discuss how IGF‐1 may facilitate adaptive plasticity in life‐history strategies in response to early environmental conditions and also how selection on loci controlling IGF‐1 signaling may mediate population divergence and eventual speciation. After consideration of the interactions among androgens, glucocorticoids, and IGF‐1 we suggest that IGF‐1 be considered a suitable candidate mechanism for mediating life‐history traits. Finally, we discuss what we can learn about IGF‐1 from studies in free‐ranging animals. The voluminous literature in laboratory and domesticated animals documenting relationships among IGF‐1, growth, reproduction, and lifespan demonstrates the potential for a number of new research questions to be asked in free‐ranging animals. Examining how IGF‐1 mediates life‐history traits in free‐ranging animals could lead to great insight into the mechanisms that influence life‐history variation.     

Host‐race formation: promoted by phenology,constrained by heritability

Host‐race formation is promoted by genetic trade‐offs in the ability of herbivores to use alternate hosts, including trade‐offs due to differential timing of host‐plant availability. We examined the role of phenology in limiting host‐plant use in the goldenrod gall fly (Eurosta solidaginis) by determining: (1) whether phenology limits alternate host use, leading to a trade‐off that could cause divergent selection on Eurosta emergence time and (2) whether Eurosta has the genetic capacity to respond to such selection in the face of existing environmental variation. Experiments demonstrated that oviposition and gall induction on the alternate host, Solidago canadensis, were the highest on young plants, whereas the highest levels of gall induction on the normal host, Solidago gigantea, occurred on intermediate‐age plants. These findings indicate a phenological trade‐off for host‐plant use that sets up the possibility of divergent selection on emergence time. Heritability, estimated by parent–offspring regression, indicated that host‐race formation is impeded by the amount of genetic variation, relative to environmental, for emergence time.     

The demographic effects of functional traits: an integral projection model approach reveals population‐level consequences of reproduction‐defence trade‐offs

Quantitatively linking individual variation in functional traits to demography is a necessary step to advance our understanding of trait‐based ecological processes. We constructed a population model for Asclepias syriaca to identify how functional traits affect vital rates and population growth and whether trade‐offs in chemical defence and demography alter population growth. Plants with higher foliar cardenolides had lower fibre, cellulose and lignin levels, as well as decreased sexual and clonal reproduction. Average cardenolide concentrations had the strongest effect on population growth. In both the sexual and clonal pathway, the trade‐off between reproduction and defence affected population growth. We found that both increasing the mean of the distribution of individual plant values for cardenolides and herbivory decreased population growth. However, increasing the variance in both defence and herbivory increased population growth. Functional traits can impact population growth and quantifying individual‐level variation in traits should be included in assessments of population‐level processes.     

Beyond the fast–slow continuum: demographic dimensions structuring a tropical tree community

Life‐history theory posits that trade‐offs between demographic rates constrain the range of viable life‐history strategies. For coexisting tropical tree species, the best established demographic trade‐off is the growth‐survival trade‐off. However, we know surprisingly little about co‐variation of growth and survival with measures of reproduction. We analysed demographic rates from seed to adult of 282 co‐occurring tropical tree and shrub species, including measures of reproduction and accounting for ontogeny. Besides the well‐established fast–slow continuum, we identified a second major dimension of demographic variation: a trade‐off between recruitment and seedling performance vs. growth and survival of larger individuals (≥ 1 cm dbh) corresponding to a ‘stature–recruitment’ axis. The two demographic dimensions were almost perfectly aligned with two independent trait dimensions (shade tolerance and size). Our results complement recent analyses of plant life‐history variation at the global scale and reveal that demographic trade‐offs along multiple axes act to structure local communities.     

No Decrease in Free IGF‐I with Increasing Insulin in Obesity‐Related Insulin Resistance

Objective: Different facts suggest that the insulin growth factor (IGF)/ insulin growth factor‐binding protein (IGFBP) system may be regulated by factors other than growth hormone. It has been proposed that, in healthy subjects, free IGF‐I plays a role in glucose metabolism. The role of free IGF‐I in glucose homeostasis in insulin resistance is poorly understood. This study was undertaken to evaluate the effects of acute changes in plasma glucose and insulin levels on free IGF‐I and IGFBP‐1 in obese and non‐obese subjects. Research Methods and Procedures: Nineteen lean and 24 obese subjects were investigated. A frequently sampled intravenous glucose tolerance test was performed. Free IGF‐I and IGFBP‐1 were determined at 0, 19, 22, 50, 100, and 180 minutes. Results: Basal free IGF‐I levels tended to be higher and IGFBP‐1 lower in obese than in lean subjects. IGFBP‐1 levels inversely correlated with basal insulin concentration. To determine the effects of insulin on the availability of free IGF‐I and IGFBP‐1, changes in their plasma concentrations were measured during a frequently sampled intravenous glucose tolerance test. After insulin administration, a significant suppression of free IGF‐I at 22% was observed in lean subjects. In contrast, plasma‐free IGF‐I levels remained essentially unchanged in the obese group. The differences between both groups were statistically significant at 100 minutes (p < 0.01) and 180 minutes (p < 0.05). Serum IGFBP‐1 was suppressed to a similar extent in both groups. Discussion: These data suggest that the concentrations of free IGF‐I and IGFBP‐1 are differentially regulated by obesity. Obesity‐related insulin resistance leads to unsuppressed free IGF‐I levels.     

Reductions in serum IGF‐1 during aging impair health span

In lower or simple species, such as worms and flies, disruption of the insulin‐like growth factor (IGF)‐1 and the insulin signaling pathways has been shown to increase lifespan. In rodents, however, growth hormone (GH) regulates IGF‐1 levels in serum and tissues and can modulate lifespan via/or independent of IGF‐1. Rodent models, where the GH/IGF‐1 axis was ablated congenitally, show increased lifespan. However, in contrast to rodents where serum IGF‐1 levels are high throughout life, in humans, serum IGF‐1 peaks during puberty and declines thereafter during aging. Thus, animal models with congenital disruption of the GH/IGF‐1 axis are unable to clearly distinguish between developmental and age‐related effects of GH/IGF‐1 on health. To overcome this caveat, we developed an inducible liver IGF‐1‐deficient (iLID) mouse that allows temporal control of serum IGF‐1. Deletion of liver Igf ‐1 gene at one year of age reduced serum IGF‐1 by 70% and dramatically impaired health span of the iLID mice. Reductions in serum IGF‐1 were coupled with increased GH levels and increased basal STAT5B phosphorylation in livers of iLID mice. These changes were associated with increased liver weight, increased liver inflammation, increased oxidative stress in liver and muscle, and increased incidence of hepatic tumors. Lastly, despite elevations in serum GH, low levels of serum IGF‐1 from 1 year of age compromised skeletal integrity and accelerated bone loss. We conclude that an intact GH/IGF‐1 axis is essential to maintain health span and that elevated GH, even late in life, associates with increased pathology.     

The role of the tolerance–fecundity trade‐off in maintaining intraspecific seed trait variation in a widespread dimorphic herb

Coexistence of species with different seed sizes is a long‐standing issue in community ecology, and a trade‐off between fecundity and stress tolerance has been proposed to explain co‐occurrence in heterogeneous environments. Here we tested an intraspecific extension of this model: whether such trade‐off also explains seed trait variation among populations of widespread plants under stress gradients. We collected seeds from 14 populations of Plantago coronopus along the Atlantic coast in North Africa and Europe. This herb presents seed dimorphism, producing large basal seeds with a mucilaginous coat that facilitates water absorption (more stress tolerant), and small apical seeds without coats (less stress tolerant). We analysed variation among populations in number, size and mucilage production of basal and apical seeds, and searched for relationships between local environment and plant size. Populations under higher stress (higher temperature, lower precipitation, lower soil organic matter) had fewer seeds per fruit, higher predominance of basal relative to apical seeds, and larger basal seeds with thicker mucilaginous coats. These results strongly suggest a trade‐off between tolerance and fecundity at the fruit level underpins variation in seed traits among P. coronopus populations. However, seed production per plant showed the opposite pattern to seed production per fruit, and seemed related to plant size and other life‐cycle components, as an additional strategy to cope with environmental variation across the range. The tolerance–fecundity model may constitute, under stress gradients, a broader ecological framework to explain trait variation than the classical seed size–number compromise, although several fecundity levels and traits should be considered to understand the diverse strategies of widespread plants to maximise fitness in each set of local conditions.     

Effect of weight loss on free insulin-like growth factor-I in obese women with hyposomatotropism

Objective: It has been hypothesized that increased free insulin‐like growth factor (IGF)‐I levels generated from an increase in IGF‐binding protein (IGFBP) protease activity could be the inhibitory mechanism for the decreased growth hormone (GH) secretion observed in obese subjects. Research Methods and Procedures: In this study, we determined basal and 24‐hour levels of free IGF‐I and ‐II, total IGF‐I and ‐II, IGFBP‐1, as well as basal IGFBP‐2, ?3, and ?4, acid‐labile subunit (ALS), IGFBP‐1, ?2, and ?3 protease activity, and 24‐hour GH release in obese women before and after a diet‐induced weight loss. Sixteen obese women (age, 29.5 ± 1.4 years) participated in a weight loss program and 16 age‐matched non‐obese women served as controls. Results: Circulating free IGF‐I and 24‐hour GH release were significantly decreased in obese women at before weight loss compared with non‐obese women (1.29 ± 0.12 vs. 0.60 ± 0.09 μg/L; p < 0.001 and 862 ± 90 vs. 404 ± 77 mU/24 hours; p < 0.001, respectively). Free IGF‐I and 24‐hour GH release were not inversely correlated to each other. IGFBP‐1 and ?2 levels were decreased, whereas ALS, IGFBP‐3 and ?4, and IGFBP‐1, ?2, and ?3 protease activity were similar in obese and non‐obese women. Eight of the 16 obese women achieved an average weight loss of 30 ± 5 kg during 26 to 60 weeks of dieting. After the considerable weight loss, significant differences in free IGF‐I, GH release, and IGFBP‐1 and ?2 levels were no longer present between previously obese and non‐obese women. Discussion: We showed that circulating free IGF‐I is markedly decreased in severely obese women and does not per se mediate the concomitant hyposomatotropism. The decreased levels of free IGF‐I seem to be transient and restored to normal levels after weight loss.     

DEFENSE TRAITS OF LARVAL DROSOPHILA MELANOGASTER EXHIBIT GENETICALLY BASED TRADE‐OFFS AGAINST DIFFERENT SPECIES OF PARASITOIDS

Populations of Drosophila melanogaster face significant mortality risks from parasitoid wasps that use species‐specific strategies to locate and survive in hosts. We tested the hypothesis that parasitoids with different strategies select for alternative host defense characteristics and in doing so contribute to the maintenance of fitness variation and produce trade‐offs among traits. We characterized defense traits of Drosophila when exposed to parasitoids with different host searching behaviors (Aphaereta sp. and Leptopilina boulardi). We used host larvae with different natural alleles of the gene Dopa decarboxylase (Ddc), a gene controlling the production of dopamine and known to influence the immune response against parasitoids. Previous population genetic analyses indicate that our focal alleles are maintained by balancing selection. Genotypes exhibited a trade‐off between the immune response against Aphaereta sp. and the ability to avoid parasitism by L. boulardi. We also identified a trade‐off between the ability to avoid parasitism by L. boulardi and larval competitive ability as indicated by differences in foraging and feeding behavior. Genotypes differed in dopamine levels potentially explaining variation in these traits. Our results highlight the potential role of parasitoid biodiversity on host fitness variation and implicate Ddc as an antagonistic pleiotropic locus influencing larval fitness traits.     

Phenotypic constraints and community structure: Linking trade‐offs within and among species

Trade‐offs are central to many topics in biology, from the evolution of life histories to ecological mechanisms of species coexistence. Trade‐offs observed among species may reflect pervasive constraints on phenotypes that are achievable given biophysical and resource limitations. If so, then among‐species trade‐offs should be consistent with trade‐offs within species. Alternatively, trait variation among co‐occurring species may reflect historical contingencies during community assembly rather than within‐species constraints. Here, we test whether a key trade‐off between relative growth rate (RGR) and water‐use efficiency (WUE) among Sonoran Desert winter annual plants is apparent within four species representing different strategies in the system. We grew progeny of maternal families from multiple populations in a greenhouse common garden. One species, Pectocarya recurvata, displayed the expected RGR–WUE trade‐off among families within populations. For other species, although RGR and WUE often varied clinally among populations, among‐family variation within populations was lacking, implicating a role for past selection on these traits. Our results suggest that a combination of limited genetic variation in single traits and negative trait correlations could pose constraints on the evolution of a high‐RGR and high‐WUE phenotype within species, providing a microevolutionary explanation for phenotypes that influence community‐level patterns of abundance and coexistence.     

Quality–quantity trade‐off of human offspring under adverse environmental conditions

A central paradigm in life‐history theory is the trade‐off between offspring number and quality. Several studies have investigated this trade‐off in humans, but data are inconclusive, perhaps because prosperous socio‐cultural factors mask the trade‐off. Therefore, we studied 2461 offspring groups in an area under adverse conditions in northern Ghana with high fertility and mortality rates. In a linear mixed model controlling for differences in age and tribe of the mother and socioeconomic status, each additional child in the offspring group resulted in a 2.3% (95% CI 1.9–2.6%, P < 0.001) lower proportional survival of the offspring. Furthermore, we made use of the polygamous population structure and compared offspring of co‐wives in 388 households, thus controlling for variation in resources between compounds. Here, offspring survival decreased 2.8% (95% CI 2.3–4.0%, P < 0.001) for each increase in offspring number. We interpret these data as an apparent quality–quantity trade‐off in human offspring.     

Escherichia coli populations adapt to complex,unpredictable fluctuations by minimizing trade‐offs across environments

In nature, organisms are simultaneously exposed to multiple stresses (i.e. complex environments) that often fluctuate unpredictably. Although both these factors have been studied in isolation, the interaction of the two remains poorly explored. To address this issue, we selected laboratory populations of Escherichia coli under complex (i.e. stressful combinations of pH, H₂O₂ and NaCl) unpredictably fluctuating environments for ~900 generations. We compared the growth rates and the corresponding trade‐off patterns of these populations to those that were selected under constant values of the component stresses (i.e. pH, H₂O₂ and NaCl) for the same duration. The fluctuation‐selected populations had greater mean growth rate and lower variation for growth rate over all the selection environments experienced. However, whereas the populations selected under constant stresses experienced trade‐offs in the environments other than those in which they were selected, the fluctuation‐selected populations could bypass the across‐environment trade‐offs almost entirely. Interestingly, trade‐offs were found between growth rates and carrying capacities. The results suggest that complexity and fluctuations can strongly affect the underlying trade‐off structure in evolving populations.     

Tree species diversity alters plant defense investment in an experimental forest plantation in southern Mexico

How plant species diversity affects traits conferring herbivore resistance (e.g., chemical defenses), as well as the mechanisms underlying such effects, has received little attention. One potential mechanism for the effect of diversity on plant defenses is that increased plant growth at high diversity could lead to reduced investment in defenses via growth–defense trade‐offs. We measured tree growth (diameter at breast height) and collected leaves to quantify total phenolics in 2.5‐year‐old plants of six tropical tree species (N = 597 plants) in a young experimental plantation in southern Mexico. Selected plants were classified as monocultures or as polycultures represented by mixtures of four of the six species examined. Tree species diversity had a significant negative effect on total phenolics, where polycultures exhibited a 13 percent lower mean concentration than monocultures. However, there was marked variation in the effects of diversity on defenses among tree species, with some species exhibiting strong reductions in phenolic levels in mixtures, whereas others were unresponsive. In addition, tree species diversity had no effect on growth, nor was the negative effect of diversity on chemical defenses mediated by a growth–defense trade‐off. These results demonstrate that tree diversity can alter investment in chemical defenses in long‐lived tree species but that such effect may not always be under strong control by plant endogenous resource allocation trade‐offs. Regardless of the underlying mechanism, these findings have important implications for predicting effects on consumers and ecosystem function.     

IGF‐I deficient mice show reduced peripheral nerve conduction velocities and decreased axonal diameters and respond to exogenous IGF‐I treatment

Although insulin‐like growth factor‐I (IGF‐I) can act as a neurotrophic factor for peripheral neurons in vitro and in vivo following injury, the role IGF‐I plays during normal development and functioning of the peripheral nervous system is unclear. Here, we report that transgenic mice with reduced levels (two genotypes: heterozygous Igf1^+/− or homozygous insertional mutant Igf1^m/m) or totally lacking IGF‐I (homozygous Igf1^−/−) show a decrease in motor and sensory nerve conduction velocities in vivo. In addition, A‐fiber responses in isolated peroneal nerves from Igf1^+/− and Igf1^−/− mice are impaired. The nerve function impairment is most profound in Igf1^−/− mice. Histopathology of the peroneal nerves in Igf1^−/− mice demonstrates a shift to smaller axonal diameters but maintains the same total number of myelinated fibers as Igf1^+/+ mice. Comparisons of myelin thickness with axonal diameter indicate that there is no significant reduction in peripheral nerve myelination in IGF‐I–deficient mice. In addition, in Igf1^m/m mice with very low serum levels of IGF‐I, replacement therapy with exogenous recombinant hIGF‐I restores both motor and sensory nerve conduction velocities. These findings demonstrate not only that IGF‐I serves an important role in the growth and development of the peripheral nervous system, but also that systemic IGF‐I treatment can enhance nerve function in IGF‐I–deficient adult mice. © 1999 John Wiley & Sons, Inc. J Neurobiol 39: 142–152, 1999     

Interacting effects of predation risk and resource level on escape speed of amphibian larvae along a latitudinal gradient

Fast‐growing genotypes living in time‐constrained environments are often more prone to predation, suggesting that growth‐predation risk trade‐offs are important factors maintaining variation in growth along climatic gradients. However, the mechanisms underlying how fast growth increases predation‐mediated mortality are not well understood. Here, we investigated if slow‐growing, low‐latitude individuals have faster escape swimming speed than fast‐growing high‐latitude individuals using common frog (Rana temporaria) tadpoles from eight populations collected along a 1500 km latitudinal gradient. We measured escape speed in terms of burst and endurance speeds in tadpoles raised in the laboratory at two food levels and in the presence and absence of a predator (Aeshna dragonfly larvae). We did not find any latitudinal trend in escape speed performance. In low food treatments, burst speed was higher in tadpoles reared with predators but did not differ between high‐food treatments. Endurance speed, on the contrary, was lower in high‐food tadpoles reared with predators and did not differ between treatments at low food levels. Tadpoles reared with predators showed inducible morphology (increased relative body size and tail depth), which had positive effects on speed endurance at low but not at high food levels. Burst speed was positively affected by tail length and tail muscle size in the absence of predators. Our results suggest that escape speed does not trade‐off with fast growth along the latitudinal gradient in R. temporaria tadpoles. Instead, escape speed is a plastic trait and strongly influenced by the interaction between resource level and predation risk.     

Impacts of environmental variability on desiccation rate,plastic responses and population dynamics of Glossina pallidipes

Physiological responses to transient conditions may result in costly responses with little fitness benefits, and therefore, a trade‐off must exist between the speed of response and the duration of exposure to new conditions. Here, using the puparia of an important insect disease vector, Glossina pallidipes, we examine this potential trade‐off using a novel combination of an experimental approach and a population dynamics model. Specifically, we explore and dissect the interactions between plastic physiological responses, treatment‐duration and ‐intensity using an experimental approach. We then integrate these experimental results from organismal water‐balance data and their plastic responses into a population dynamics model to examine the potential relative fitness effects of simulated transient weather conditions on population growth rates. The results show evidence for the predicted trade‐off for plasticity of water loss rate (WLR) and the duration of new environmental conditions. When altered environmental conditions lasted for longer durations, physiological responses could match the new environmental conditions, and this resulted in a lower WLR and lower rates of population decline. At shorter time‐scales however, a mismatch between acclimation duration and physiological responses was reflected by reduced overall population growth rates. This may indicate a potential fitness cost due to insufficient time for physiological adjustments to take place. The outcomes of this work therefore suggest plastic water balance responses have both costs and benefits, and these depend on the time‐scale and magnitude of variation in environmental conditions. These results are significant for understanding the evolution of plastic physiological responses and changes in population abundance in the context of environmental variability.     

IGF‐I regulates the age‐dependent signaling peptide humanin

Aging is influenced by endocrine pathways including the growth hormone/insulin‐like growth factor‐1 (GH/IGF) axis. Mitochondrial function has also been linked to the aging process, but the relevant mitochondrial signals mediating the effects of mitochondria are poorly understood. Humanin is a novel signaling peptide that acts as a potent regulator of cellular stress responses and protects from a variety of in vitro and in vivo toxic and metabolic insults. The circulating levels of humanin decline with age in mice and humans. Here, we demonstrate a negative correlation between the activity of the GH‐IGF axis and the levels of humanin, as well as a positive correlation between humanin and lifespan in mouse models with altered GH/IGF‐I axis. Long‐lived, GH‐deficient Ames mice displayed elevated humanin levels, while short‐lived GH‐transgenic mice have reduced humanin levels. Furthermore, treatment with GH or IGF‐I reduced circulating humanin levels in both mice and human subjects. Our results indicate that GH and IGF are potent regulators of humanin levels and that humanin levels correlate with lifespan in mice. This suggests that humanin represents a circulating mitochondrial signal that participates in modulating the aging process, adding a coordinated mitochondrial element to the endocrine regulation of aging.