TOR pathway activation in Zea mays L. tissues: Conserved function between animal and plant kingdoms

In most non-photosynthetic eukaryotes it has been demonstrated a conserved signal transduction pathway, namely TOR-S6K, that coordinates growth and cell proliferation. This pathway targets the translational apparatus to induce selective translation of ribosomal mRNAs as well as stimulate the cell cycle transition through the G₁/S phase. Thus, by activation of this pathway through environmental signals, nutrients, stress, or specific growth factors, such as insulin or insulin-like growth factors (IGF), this pathway allows organisms to regulate growth and cell division. In plants, evidence has shown that TOR protein has been highly conserved through evolution, being involved in growth and cell proliferation control as well. Particularly in maize, a peptide named ZmIGF has been found in actively growing tissues. It targets the maize TOR pathway at the same extent as insulin and, by doing so it induces growth, as well as ribosomal proteins and DNA synthesis. Thus, higher metazoans and plants seem to conserve similar biochemical paths to regulate cell growth through equivalent targets that conduce to activation of the TOR-S6K pathway. Recent research shows evidence that supports this proposal by uncovering the ZmIGF receptor in maize, providing further means for analyzing the role of the conserved TOR signaling pathway in this plant.     

Insulin-induced changes in metabolism-related proteins during maize germination

Insulin regulates a wide range of metabolic processes in mammals, such as homeostasis and the breakdown of glucose. Recently, the existence of an insulin-related growth factor in maize (ZmIGF) and a possible receptor for this growth factor has been reported. This peptide exerts effects on plant growth and promotes germination by activating the target of rapamycin (TOR) signaling pathways, which is similar to the insulin response in mammals. In this study, we analyzed the insulin response in maize embryos using a proteomic approach. Our results indicated that insulin modulates the expression of proteins involved in processes, such as storage protein degradation, protein processing, redox and desiccation stress, and glucose metabolism. The involvement of TOR signaling pathways was analyzed using the TOR inhibitor, rapamycin. The results showed that the modulation of these proteins by insulin is independent of the TOR pathway. These results indicated that insulin promotes changes in metabolism-related proteins to ensure successful germination in maize.     

Recent advances in the biochemistry and physiology of the insulin-like growth factor/somatomedin family

The insulin-like growth factors (IGF) or somatomedins (Sm) are a family of low molecular weight circulating growth factors which have a major, but not absolute, dependence on GH, and have been shown to stimulate body growth and skeletal metabolism in vivo. They are thus considered to mediate the effects of GH on skeletal growth. In humans, the family consists of two well-characterized forms--IGF-I or SmC (a basic peptide) and IGF-II (a "neutral" peptide)--as well as perhaps two less well characterized forms--SmA (a neutral peptide) and an acidic insulin-like activity (ILA pI 4.8). Similar IGF/Sm species have been found and well-characterized in rat serum. Some higher mol wt forms also exist in tissues and body fluids and may represent possible precursor forms. On the basis of in vitro, clinical and in vivo evidence it has been postulated that IGF-I is the primary growth factor in the adult, whilst IGF-II is probably a major foetal growth factor. In vitro the IGF/Sms have a variety of effects including (1) acute insulin-like metabolic actions, which are observed primarily in insulin target tissues and are initiated largely at insulin receptors, and (2) longer term effects, associated with cell growth and skeletal tissue metabolism, and which occur in traditionally non-insulin target tissues, primarily via IGF/Sm receptors. These observations, together with the circumstantial clinical evidence favouring a close association between IGF levels and growth status, clearly indicate a role for IGF/Sms in growth regulation. This concept is now fully supported by the demonstration that IGF-I infused into hypophysectomized (GH-deficient) rats results in increased growth and skeletal metabolism. The physiological regulation of the expression of net IGF activity in vivo is complex and is controlled by the following three determinants: the levels of IGFs, the levels of the specific carrier-proteins and the levels of IGF inhibitors. Both IGFs and their carrier-proteins are influenced by the GH status of the animal as well as by other hormones, nutritional status and chronic illness. Little is known yet about the control of the various IGF inhibitors that have been described. Of importance, however, is the general concept that normal growth is dependent on an adequate balance between all three determinants and that some regard must be had for the contribution of each in determining the overall potential for growth under given circumstances.     

Somatomedin C/insulin-like growth factor 1: an intratesticular differentiative factor of Leydig cells?

By using immature porcine Sertoli cells cultured in serum-free defined medium, we report that medium conditioned by Sertoli cells contained immunoreactive somatomedin C/insulin-like growth factor 1 (SmC/IGF1) measured following acidic gel filtration. The release of this immunoreactive SmC/IGF1 was slightly increased following Sertoli cell treatment with fibroblast growth factor but not with follicle-stimulating hormone or growth hormone. On the other hand, human biosynthetic SmC/IGF1 exerts a potent stimulatory effect on Leydig cell differentiated functions such as LH/hCG-binding (greater than 4-fold) and hCG-stimulated testosterone secretion (greater than 15-fold). This effect was dose and time dependent and the maximal increase of Leydig cell function was observed following 48 h treatment with 50 ng/ml SmC/IGF1. The steroidogenic action of the peptide was not related to Leydig cell growth since both cell number and 3H-thymidine incorporation into DNA were not or slightly (approximately equal to 1.5-fold) increased in the optimal conditions with SmC/IGF1 treatment (100 ng/ml for 48 h). Moreover, the concomitant treatment of Leydig cells by both arabinoside C (10(-5) M), a DNA synthesis inhibitor, and SmC/IGF1 did not modify the stimulating effect of the peptide on LH/hCG-binding and hCG-stimulated testosterone production. Taken together, the present findings support the concept that Sertoli cell derived SmC/IGF1 could be a potent regulator of Leydig cell differentiated functions.     

Serum leptin, insulin-like growth factor-I components and sex-hormone binding globulin. Relationship with sex, age and body composition in healthy population

Leptin plays an important role in the regulation of food intake and thermogenesis, regulates long term energy balance and reproductive function and its concentrations are closely linked to body mass index. Leptin secretion is influenced by many factors and the age-related changes in different hormones might modify circulating leptin concentrations. Sex dimorphism in leptin concentrations has been clearly shown in previous studies and its concentrations were lower in men than in women in all decades of life. Insulin growth factor-I (IGF-I) is a peptide growth factor that is present in all types of physiologic fluids and is also produced by connective tissue cell types and its autocrine/paracrine secretion is nearly always present within tissues. There is a physiological decline of the growth hormone (GH)/IGF-I axis with ageing and in addition, insulin, thyroid hormones and the supply of dietary energy may directly regulate the circulating levels of the IGFs and growth hormone binding protein (GHBP). Furthermore, there is no doubt that GH participates in the regulation of body composition, and with advanced age there is a decrease in muscle and an increase in adiposity associated with a decline in GH and total IGF-I. The biological activities of the IGF ligands are modulated by the family of high affinity GHBP. Sex hormone binding globulin (SHBG) concentrations are thought to be regulated primarily through opposing actions of sex steroids on hepatic SHBG production, with oestrogen stimulating and androgen inhibiting SHBG production, and thyroid hormones are also a potent stimulator of SHBG production concentrations. Some studies support an independent IGFBP3 contribution to SHBG variability and these findings are compatible with the hypothesis that some of the anabolic effects ascribed to the GH/IGF axis may be caused by SHBG-mediated changes in testosterone activity or SHBG/total testosterone index.     

Polyamines, molecules necessary for cell division, colocalize with peptide growth factors

The naturally occurring polyamines spermidine and spermine are necessary for cell division and growth. By restaining experiments, using three independent polyamine cytochemical methods, together with peptide immunocytochemistry, we show that substantial amounts of polyamines occur in a number of peptide growth factor-producing cell types. These include submandibular granular convoluted duct cells producing epidermal growth factor (EGF), pancreatic islet cells producing insulin and anterior pituitary cells producing growth hormone (GH). Other cell types in these tissues display only weak or no polyamine reactivity. Also blood platelets, known to contain platelet-derived growth factor (PDGF), are strongly stained for polyamines. Moreover, in EGF cells, insulin cells and blood platelets, polyamines are clearly localized in secretory granules. The possibility that polyamines may be coreleased and act in concert with peptide growth factors is discussed.     

Pathophysiological and clinical importance of insulin-like growth factor-I with respect to bone metabolism

The modern concept of causality of diseases emphasizes the study of natural defense functions of the organism and possibilities of influencing them, which will lead to effective prevention of these diseases. A great deal of information has been obtained on the system growth hormone (GH)/insulin-like growth factor (IGF)-I, which is of quite fundamental importance for the integrity of the organism. An imbalance of the system may be the cause of diseases of the neonatal period, as well as diseases associated with aging. In old age, the synthesis of the crucial peptide system, IGF-I, declines as well as the sensitivity of tissues to this hormone. At the same time the changes in the expression of IGF-binding proteins (IGFBP) occur. Systemic growth factors are present in measurable concentrations in the circulation, they are, however, taken up or synthesized by some tissues, where they act as local cellular regulators. IGF-I is produced by many tissues, including bones under the control of estrogens, growth hormone and the parathyroid hormone. A decline of bone IGF-I in the cortical portion of bones is one of the many mechanisms leading to the development of involutional osteoporosis. Correlation studies, which have provided evidence of a relationship between the IGF system and the building of peak bone mass and its subsequent loss contributed to the understanding of the pathogenesis of this disease. It may be foreseen that the results of intervention studies focused on the effects of the recombinant IGF-I will also influence therapeutic and preventive approaches. Modern antiresorption pharmacotherapy stabilizes or enhances bone density and reduces the risk of fractures. The addition of effective anabolics might increase the effectiveness of treatment by shifting the remodeling equilibrium in favor of formative processes. Because both recombinant GH and IGF-I have certain therapeutic limitations, it is considered to utilize substances which either stimulate endogenous IGF-I production directly in the bone or modulate synthesis and distribution of binding proteins for the peptide. Further new findings related to physiology and pathophysiology of this peptide will contribute to designing new strategies in the prevention of osteoporosis and other serious diseases of old age, such as diabetes, neoplasias or cardiovascular diseases.     

Primary structure of a putative receptor for a ligand of the insulin family

Nucleotide sequence analysis of human and guinea pig genomic DNA encoding a new member of the insulin receptor (IR) family revealed that the predicted primary structure of this IR-related protein is as similar to the IR and insulin-like growth factor (IGF) I receptor as the IR and IGF-IR are to each other. The conservation of this IR-related sequence among mammals and with the IR and IGF-IR suggests that this IR-related protein is a novel receptor for insulin, IGF-I, IGF-II, or an as yet unidentified peptide hormone or growth factor belonging to the insulin family.     

The structure-function relationships of insulin-like growth factor 1 Ec in C2C12 cells

Insulin-like growth factor 1 (IGF1) is a crucial growth factor, that regulates skeletal muscles development during cell growth and repair. Recently, its alternative splicing variant, named IGF1Ec, also named mechano-growth factor (MGF), has gained attentions as a new damage repair factor. However, the structure-function relationships of IGF1Ec have not been fully clarified due to contradictory reports. In this study, we systematically investigated physiologic responses of C2C12 muscle cells to IGF1Ec, IGF1 and MGF E peptide. Our data indicate that while the N-terminal sequence of IGF1Ec, which is homolog in part with IGF1, promotes proliferation; the C-terminal sequence of IGF1Ec, which is identical to MGF E, promotes differentiation and migration of C2C12 cells. Our results suggest that MGF E cannot completely replace all the functions of IGF1Ec on muscle repair and regeneration, and elucidate the relationships between structure and function of IGF1Ec.     

Role of insulin and IGF1 receptors in proliferation of cultured renal proximal tubule cells.

We have used a murine proximal tubule cell line (MCT cells) to determine the presence and binding characteristics of insulin and IGF1 receptors and to correlate these parameters with the concentration-response relationships for ligand-induced cellular proliferation. Separate insulin and IGF1 receptors were identified by equilibrium binding assays. Half-maximal displacement of either peptide occurred at 3-10 nM; crossover binding to the alternate receptor occurred with a 10- to 100-fold lower affinity. Peptide effects on cellular proliferation were determined by measuring [3H]thymidine incorporation. Both insulin and IGF1 stimulate thymidine incorporation in a dose-dependent manner with similar increases above the basal level. The estimated half-maximal stimulation (EC50) occurred at 4 nM for IGF1 and 8 nM for insulin. A comparison of the receptor binding affinities with the dose-response relationships for [3H]thymidine incorporation reveals that each growth factor appears to be exerting its effect via binding to its own receptor. Therefore, in this cell line, physiologic concentrations of either insulin or IGF1 can modulate cellular growth. To our knowledge this is the first demonstration of a mitogenic effect which may be modulated by ligand binding to the insulin receptor in proximal tubule epithelia.     

Testes‐specific transgene expression in insulin‐like growth factor‐I transgenic mice

Insulin‐like growth factor‐I (IGF‐I) is a low molecular weight peptide that mediates the cell proliferating actions of growth hormone. Evidence exists indicating that IGF‐I is produced by various cell types and this growth factor has been implicated in a variety of reproductive processes. To investigate the effect of IGF‐I over‐expression on reproductive systems, we generated three independent lines of transgenic mice harbouring a human IGF‐I cDNA (hIGF‐I) under the control of a Cytomegalovirus immediate early (CMV) promoter. The CMV promoter was used in an attempt to direct expression of IGF‐I into a variety of tissues both reproductive and non‐reproductive. Yet expression of the foreign hIGF‐I gene, determined by Northern blot, was found to occur only in the testicular tissues of the male mice, apparently due to methylation of the transgene in all the tissues tested except the testes, which demonstrate transgene hypomethylation. Evaluation of the transgene expression during testicular development revealed that expression begins between 10 and 15 days of development, coinciding with the appearance of the zygotene and pachytene primary spermatocytes during early spermatogenesis, therefore indicating germ line expression of the transgene. Extensive study of the CMV‐hIGF‐I transgenic lines of mice has revealed that the effects of the transgene expression do not extend beyond the testicular tissues. No significant differences (P > 0.05) in the IGF‐I serum levels, growth rates, or testicular histology have been observed between transgenic and non‐transgenic male siblings. The ability of transgenic males to produce offspring also appears unaffected. Evaluation of the IGF binding protein (IGFBP) levels in the testicular tissues of CMV‐hIGF‐I transgenic mice by Western ligand blot revealed an increase in the concentration of testicular proteins with molecular weights corresponding to IGFBP‐2 and IGFBP‐3. These results suggest that the testicular over‐expression of IGF‐I induces increased IGFBP localization in this tissue. Inhibition of IGF activity by the IGFBPs would explain the lack of a dramatic physiological effect in the CMV‐hIGF‐I transgenic mice, despite the presence of elevated testicular IGF‐I. The observation that testis specific IGF‐I overexpression induces localization of IGFBPs in this tissue confirms the existence of a well regulated testicular IGF system and supports the convention that this growth factor plays an important role in testicular function. Mol. Reprod. Dev. 54:32–42, 1999. © 1999 Wiley‐Liss, Inc.     

Insulin-like growth factor signaling regulates zebrafish embryonic growth and development by promoting cell survival and cell cycle progression

Although much is known about the global effects of insulin-like growth factor 1 receptor (IGF1R)-mediated signaling on fetal growth and the clinical manifestations resulting from IGF/IGF1R deficiencies, we have an incomplete understanding of the cellular actions of this essential pathway during vertebrate embryogenesis. In this study, we inhibited IGF1R signaling during zebrafish embryogenesis using antisense morpholino oligonucleotides or a dominant-negative IGF1R fusion protein. IGF1R inhibition resulted in reduced embryonic growth, arrested development and increased lethality. IGF1R-deficient embryos had significant defects in the retina, inner ear, motoneurons and heart. No patterning abnormalities, however, were found in the brain or other embryonic tissues. At the cellular level, IGF1R inhibition increased caspase 3 activity and induced neuronal apoptosis. Coinjection of antiapoptotic bcl2-like mRNA attenuated the elevated apoptosis and rescued the retinal and motoneuron defects, but not the developmental arrest. Subsequent cell cycle analysis indicated an increased percentage of cells in G1 and a decreased percentage in S phase in IGF1R-deficient embryos independent of apoptosis. These results provide novel insight into the cellular basis of IGF1R function and show that IGF1R signaling does not function as an anteriorizing signal but regulates embryonic growth and development by promoting cell survival and cell cycle progression.     

Actions of insulin-like growth factor binding protein-5 (IGFBP-5) are potentially regulated by tissue kallikrein in rat brains

Tissue kallikrein (EC 3.4.21.35) that hydrolyzes kininogen and releases a physiologically active peptide, kinin, is found in rat brains. Insulin-like growth factor binding proteins (IGFBPs) that modulate IGF actions are also expressed in a variety of tissues including rat brains, and one of the major IGFBPs expressed in brain is known to be IGFBP-5, which is reported to be hydrolyzed in vitro by prostate-specific antigen (PSA) and gamma-nerve growth factor (gamma-NGF), both of which belong to the member of the kallikrein gene family. This study was designed to determine whether or not kallikrein has a potential to hydrolyze IGFBP-5 and their topographic proximity was investigated in rat brain using double immunohistochemical staining method. Immunohistochemically, IGFBP-5 positive cells were numerous and widespread in the cerebral cortex and belonged to neurons in the cell configuration. IGFBP-5 positive cells were negative for S-100 protein and were positive for betaIII tubulin, confirming them to be neurons. In addition, kallikrein positive cells were virtually all IGFBP-5 positive cells. IGFBP-5 was clearly hydrolyzed by kallikrein with cleavage sites of Arg188-Met189 and Arg136-Arg137 of IGFBP-5. Therefore, there is a possibility that kallikrein plays an important role in brain physiology, specifically in the neurons by regulating the actions of IGFBP-5 and IGF.     

Distribution of insulin-like growth factor peptides in the developing chick embryo

Growth factors are likely to be of major significance in developmental biology. Here, the distribution of insulin-like growth factor (IGF) peptides is described during development of the chick embryo. IGF was immunolocalised using a polyclonal antibody to human IGF I detected with a modified Vectastain ABC procedure. Under the conditions used, the antibody binds strongly to IGF I and weakly to IGF II; thus the distribution of IGF peptide, rather than the individual factors, is described. Muscle, peripheral nerve and the notochord were labelled whenever present. Muscle label was associated with the myotubes and neural labelling with neurons; Schwann cells were unlabelled. IGF distribution changed during differentiation of connective tissues. Regions of mesenchyme destined to form cartilage labelled weakly or not at all, and cartilage condensations were unlabelled. In the limb, chondrocytes became labelled once cartilage rudiments had formed; however, in later development, label was absent in zones of rounded and flattened chondrocytes and appeared strongly at the onset of hypertrophy. Early osteogenic mesenchyme was also unlabelled, although later bone cells were strongly stained. In the neural tube, label was associated with differentiating neuroblasts and cell bodies and with axons, especially in the developing dorsolateral tracts. These results show a possible correlation between IGF label and cell division in early mesenchyme; cartilage condensations, which have reduced mitotic indices, do not label. In other tissues, notably muscle and nerve but also later connective tissues, label is associated with differentiating, rather than dividing, cells.     

The POLARIS peptide of Arabidopsis regulates auxin transport and root growth via effects on ethylene signaling

The rate and plane of cell division and anisotropic cell growth are critical for plant development and are regulated by diverse mechanisms involving several hormone signaling pathways. Little is known about peptide signaling in plant growth; however, Arabidopsis thaliana POLARIS (PLS), encoding a 36-amino acid peptide, is required for correct root growth and vascular development. Mutational analysis implicates a role for the peptide in hormone responses, but the basis of PLS action is obscure. Using the Arabidopsis root as a model to study PLS action in plant development, we discovered a link between PLS, ethylene signaling, auxin homeostasis, and microtubule cytoskeleton dynamics. Mutation of PLS results in an enhanced ethylene-response phenotype, defective auxin transport and homeostasis, and altered microtubule sensitivity to inhibitors. These defects, along with the short-root phenotype, are suppressed by genetic and pharmacological inhibition of ethylene action. PLS expression is repressed by ethylene and induced by auxin. Our results suggest a mechanism whereby PLS negatively regulates ethylene responses to modulate cell division and expansion via downstream effects on microtubule cytoskeleton dynamics and auxin signaling, thereby influencing root growth and lateral root development. This mechanism involves a regulatory loop of auxin-ethylene interactions.