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Recent Progress In Hormone Research[JOURNAL]

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The multifunctional role of the co-activator CBP in transcriptional regulation.

Goldman PS, Tran VK, Goodman RH

Recent Prog Horm Res · 1997 · PMID 9238849

One of the most studied and best-understood examples of second messenger-regulated gene transcription involves the activation of genes by the cyclic AMP pathway: stimulation of several hormone, growth factor, and neurotr... One of the most studied and best-understood examples of second messenger-regulated gene transcription involves the activation of genes by the cyclic AMP pathway: stimulation of several hormone, growth factor, and neurotransmitter receptors activates adenylyl cyclase, generating cyclic AMP that, by binding to the regulatory subunit of protein kinase A (PKA), dissociates the PKA catalytic subunit. The free catalytic subunit is transported to the nucleus where it phosphorylates and consequently activates the transcription factor CREB. This phosphorylation of CREB allows interaction with the co-activator CBP, which binds to components of the basal transcriptional machinery. CBP and its homologue p300 are targets for several viral-transforming proteins, implying that these co-activators have a more extensive role in cellular function. Indeed, recent studies have demonstrated that multiple transcription factors bind to CBP, including c-jun, c-myb, MyoD, E2F1, YY1, and members of the steroid hormone receptor superfamily, although it is not yet clear which of these transcription factors depend upon CBP for function. Determining exactly which transcriptional pathways require CBP in vivo and which genes are activated by CBP will provide an important clue in developmental regulation and cell cycle control, since mutations in the human CBP gene have been found to cause developmental abnormalities and a predisposition for some types of cancer. In this review, we will discuss the mechanisms involved in the PKA-dependent activation of CREB and describe how the co-activator CBP and its homologue are involved in this process. In addition, we will outline the various transcription factor pathways that CBP has been proposed to activate. Finally, we will discuss the possible role of CBP in cellular transformation and differentiation.

Nongenomic actions of steroids on gonadotropin release.

Wiebe JP

Recent Prog Horm Res · 1997 · PMID 9238848

The release of gonadotropins is effected by GnRH and regulated by steroids. The classical mechanism of steroid hormone action, which implies the binding of hormone receptor complexes to regulatory elements of nuclear gen... The release of gonadotropins is effected by GnRH and regulated by steroids. The classical mechanism of steroid hormone action, which implies the binding of hormone receptor complexes to regulatory elements of nuclear genes, is derived largely from the well-studied and familiar steroids such as progesterone, testosterone, and estradiol. Their effects on gonadotropin release generally have been examined following hours or days of exposure and therefore cannot account for the rapid effects of steroids on gonadotropin release. Moreover, tissues such as gonad, pituitary, and hypothalamus can produce a variety of hormonally active steroids in addition to these well-studied, traditional ones. The recently discovered allylic steroid, 3 alpha-hydroxy-4-pregnen-20-one (3 alpha HP), is readily interconverted from/to progesterone and is found at appreciable levels in serum, gonads, pituitary, hypothalamus, and other tissues. 3 alpha HP has provided the "missing link" in the progesterone biosynthetic/ metabolic pathways, allowing cyclical 4-pregnene and 5 alpha-pregnane pathways to be described for steroidogenic tissues. Among the functions ascribed to 3 alpha HP is the ability to selectively and rapidly (within seconds or minutes) suppress GnRH-provoked FSH release. In vitro studies using pituitary gonadotropes in culture and in perifusion paradigms suggest that suppression of FSH release by 3 alpha HP occurs as a result of nongenomic mechanisms of action. These mechanisms are discussed and include interaction at the level of receptors in the gonadotrope membrane and the cell-signaling pathway involving protein kinase C, phospholipase C, or IP3-induced Ca2+ mobilization and Ca2+ channels. This may be the first evidence of a gonadal steroid regulating gonadotropin release by nongenomic mechanisms of action. In order to understand the critical role of steroids in the rapid regulation of secretory (and bence, circulating) levels of gonadotropins, other gonadal steroids will need to be examined for their nongenomic action on gonadotropes.

Estrogen: nontranscriptional signaling pathway.

Moss RL, Gu Q, Wong M

Recent Prog Horm Res · 1997 · PMID 9238847

The long-term, genomic actions of estrogen and other steroid hormones are now relatively well understood. In this process, steroids bind to a cytoplasmic/nuclear receptor and the hormone receptor complex that, in turn, b... The long-term, genomic actions of estrogen and other steroid hormones are now relatively well understood. In this process, steroids bind to a cytoplasmic/nuclear receptor and the hormone receptor complex that, in turn, binds to DNA and triggers RNA-dependent protein synthesis. This process produces a response over time periods of several minutes to hours to days. Estrogen also exerts a variety of short-term effects (observed in milliseconds to minutes) on target organs that are not compatible with the classical genomic mechanism. These short-term, nontranscriptional actions are thought to be neuromodulatory in nature and critical for cell-cell communication. This chapter discusses current evidence for nontranscriptional effects of estrogen, with major emphasis on electrophysiological results demonstrating rapid, estrogen-induced changes in neuronal excitability. The mechanisms for nontranscriptional estrogen effects are also considered. These mechanisms include nonspecific influences on the lipid bilayer, specific binding to novel membrane receptors, direct modulation of neurotransmitter-ion channel complexes, and direct activation of second messenger systems. Particular attention will be focused on studies from our laboratory investigating mechanisms of estrogenic potentiation of kainate-induced currents in hippocampal neurons. Finally, the physiological relevance of short-term estrogenic actions will be addressed.

Neurosteroids: of the nervous system, by the nervous system, for the nervous system.

Baulieu EE

Recent Prog Horm Res · 1997 · PMID 9238846

Neurosteroids are synthesized in the central and peripheral nervous system, particularly but not exclusively in myelinating glial cells, from cholesterol or steroidal precursors imported from peripheral sources. They inc... Neurosteroids are synthesized in the central and peripheral nervous system, particularly but not exclusively in myelinating glial cells, from cholesterol or steroidal precursors imported from peripheral sources. They include 3 beta-hydroxy-delta 5-compounds, such as pregnenolone (PREG) and dehydroepiandrosterone (DHEA), their sulfates, and reduced metabolites such as the tetrahydroderivative of progesterone 3 alpha-hydroxy-5 alpha-pregnane-20-one (3 alpha,5 alpha-THPROG). These compounds can act as allosteric modulators of neurotransmitter receptors, such as GABAA, NMDA, and sigma receptors. Progesterone (PROG) is also a neurosteroid, and a progesterone receptor (PROG-R) has been identified in peripheral and central glial cells. At different places in the brain, neurosteroid concentrations vary according to environmental and behavioral circumstances, such as stress, sex recognition, or aggressiveness. A physiological function of neurosteroids in the central nervous system is strongly suggested by the role of hippocampal PREGS with respect to memory, observed in aging rats. In the peripheral nervous system, a role for PROG synthesized in Schwann cells has been demonstrated in the repair of myelin after cryolesion of the sciatic nerve in vivo and in cultures of dorsal root ganglia neurites. It may be important to study the effect of abnormal neurosteroid concentrations/metabolism with a view to the possible treatment of functional and trophic disturbances of the nervous system.

Resistance to thyrotropin and other abnormalities of the thyrotropin receptor.

Refetoff S, Sunthornthepvarakul T, Gottschalk ME … +1 more , Hayashi Y

Recent Prog Horm Res · 1996 · PMID 8701094

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A nuclear matrix acceptor site for the progesterone receptor in the avian c-myc gene promoter.

Spelsberg TC, Lauber AH, Sandhu NP … +1 more , Subramaniam M

Recent Prog Horm Res · 1996 · PMID 8701093

It has been the goal of this project to determine the location, composition, and biological function of the nuclear acceptor sites (i.e., the nuclear binding sites) for the avian oviduct progesterone (Pg) receptor (PR).... It has been the goal of this project to determine the location, composition, and biological function of the nuclear acceptor sites (i.e., the nuclear binding sites) for the avian oviduct progesterone (Pg) receptor (PR). Many laboratories have demonstrated a native-(in vivo) like cell-free binding of steroid receptor complexes to specific acceptor sites in nuclei/chromatin in a variety of target tissue systems. These sites appear to involve protein-DNA complexes and some of these have been shown to reside in the nuclear matrix, including the chromatin acceptor sites for the avian oviduct PR. We have purified a nuclear matrix "acceptor protein" for the avian PR. termed receptor binding factor-1 (RBF-1), based on its ability to generate specific, high-affinity PR binding on avian genomic DNA. This 10 kD nuclear matrix protein was found to be unique with minimal homology to a couple of other proteins. Using immunohistochemical techniques and antibodies against the purified RBF-1, the RBF-1 was localized to the nuclei of many avian and rat tissues. Co-localizations of RBF-1 and PR in select cell types in the avian oviduct and rat reproductive organs were also reported. A tissue specificity was found with regard to RBF-1 concentrations. The full length cDNA to RBF-1 has been isolated and used to identify a 0.7 kb mRNA whose levels in various avian tissues reflect the protein levels. Genomic sequences of RBF-1 have been isolated and characterized. Preliminary studies indicate that the over-expression of the RBF in human MCF-7 cells results in an inhibition of the c-myc gene promoter activity which is further inhibited by steroid hormone treatments of the cells. Past studies in our laboratory demonstrated that the c-myc mRNA steady state levels are rapidly (approximately 15 min) reduced by Pg and glucocorticoids in the avian oviduct. Further, partially purified fractions of RBF-1 were shown to generate specific PR binding sites only on the genomic DNAs of certain animal species and on the c-myc gene, but not ovalbumin gene. Using Southwestern blot analyses, the purified RBF-1 was shown to bind specifically to sequences in the 5' end of c-myc, c-jun proto-oncogenes but not to genomic sequences of the ovalbumin gene. A specific DNA binding element in the promoter region of the c-myc proto-oncogene has been identified as AT-rich domain of homopurine/pyrimidine stretches flanked by GC-rich sequences. Southern blot analyses using 200 bp matrix DNA fragments protected by the nuclear matrix structure indicate that the matrix is attached on either side of the RBF-1 binding element. A model is described for a nuclear matrix acceptor site attached to the c-myc promoter which may mediate the Pg-induced down-regulation of the c-myc gene expression.

Programmed cell death in human breast cancer cells.

McCloskey DE, Armstrong DK, Jackisch C … +1 more , Davidson NE

Recent Prog Horm Res · 1996 · PMID 8701092

The need for improved systemic therapy for breast cancer is great. Cancer growth represents an imbalance between cell proliferation and cell death: thus, effective anti-cancer therapies may act to decrease cell prolifera... The need for improved systemic therapy for breast cancer is great. Cancer growth represents an imbalance between cell proliferation and cell death: thus, effective anti-cancer therapies may act to decrease cell proliferation or increase cell death, or both. This chapter delineates the role of the programmed cell death process in maintaining homeostasis in normal mammary tissues. The preservation of such death pathways in malignant mammary cells and the ability of chemotherapeutic agents to initiate the programmed cell death process in these cells is reviewed. Finally, ongoing research exploring new ways to take advantage of these death pathways in the clinical setting is examined.

The biochemistry and molecular biology of glucocorticoid-induced apoptosis in the immune system.

Cidlowski JA, King KL, Evans-Storms RB … +3 more , Montague JW, Bortner CD, Hughes FM

Recent Prog Horm Res · 1996 · PMID 8701091

Apoptosis is a form of programmed cell death that occurs under numerous developmental and physiological conditions that require the selective elimination of cells from tissues and organs without the production of an infl... Apoptosis is a form of programmed cell death that occurs under numerous developmental and physiological conditions that require the selective elimination of cells from tissues and organs without the production of an inflammatory response. The initiation of apoptosis is controlled by a regulation of the balance between death and life signals perceived by the cell. A typical response of cells to an apoptotic stimulus includes a reduction in cell volume, compaction of intracellular organelles, chromatin condensation, and the generation of apoptotic bodies which contain degraded cellular components. Apoptotic bodies are often engulfed by neighboring cells or macrophages, preventing the occurrence of an inflammatory response in the region of the dying cells. Although the molecular basis for this cellular suicide is poorly understood, evidence indicates that apoptosis is an active process, requiring energy for its effective completion. We have sought to define the catabolic "effector" molecules that carry out the apoptotic process using glucocorticoid-induced apoptosis in rodent and human lymphocytes as model systems. These cells respond to dexamethasone with an arrest of cell growth, chromatin condensation, cell shrinkage, and the selective degradation of DNA, RNA, and protein. These effects are dependent on the presence of functional glucocorticoid receptors and require gene expression. The fragmentation of DNA and its associated cell shrinkage has been a focus of our efforts, because these effects reflect an irreversible commitment to death. Accordingly, we have developed assays to study apoptosis at the single cell level and to identify, purify, and clone the nuclease(s) that cause DNA damage in apoptotic cells. Using these approaches, we have identified and characterized a novel low molecular weight nuclease (NUC18) whose activity correlates with the DNA degradation occurring during apoptosis. NUC18 requires calcium for optimal activity in vitro and is inhibited by zinc and aurintricarboxylic acid, two known inhibitors of apoptosis. The amino acid sequence of pure NUC18 reveals a surprising homology to the cyclophilin family of proteins. Furthermore, recombinant cyclophilins have biochemical and pharmacological properties identical to those of NUC18. We have also studied the molecular basis for the catabolism of RNA and proteins that occurs during lymphocyte apoptosis. Recent experiments have identified selective cleavage of 28S ribosomal RNA and a novel nonlysosomal protease, both of which contribute to the demise of the cell. In summary, we present an evolving model that unifies the activation of apoptosis in lymphocytes by glucocorticoids with the counter-balancing effect of inhibitors such as Bcl-2.

Gonadal cell apoptosis.

Hsueh AJ, Eisenhauer K, Chun SY … +2 more , Hsu SY, Billig H

Recent Prog Horm Res · 1996 · PMID 8701090

Apoptosis is an important cellular process by which superfluous or unwanted cells are deleted from an organism during tissue remodeling and differentiation. Recent studies have demonstrated the role of this programmed ce... Apoptosis is an important cellular process by which superfluous or unwanted cells are deleted from an organism during tissue remodeling and differentiation. Recent studies have demonstrated the role of this programmed cell death or "controlled cell suicide" in the physiological function of an organism. Suppression of apoptosis increases the susceptibility of an individual to malignancy whereas uncontrolled cell death is associated with degenerative diseases. Normal development of both female and male gonads is characterized by massive cell death. More than 99% of ovarian follicles endowed at early life are destined to undergo apoptosis and the exhaustion of these follicles serves as a "clock" for female reproductive senescence. In the testis, up to 75% of male germ cells also undergo apoptosis, perhaps as a mechanism to delete superfluous or defective germ cells. Gonadal cell apoptosis provides valuable models to study hormonal regulation of apoptosis. In the ovary, gonadotropins, estrogens, growth hormone, growth factors (IGFI, EGF/TGF-alpha, basic FGF), cytokine (interleukin-1 beta) and nitric oxide act in concert to ensure the survival of preovulatory follicles. In contrast, androgens, interleukin-6 and gonadal GnRH-like peptide are apoptotic factors. Developmental studies further indicate that fractions of endowed follicles are recruited throughout the reproductive life whereas most of the primordial follicles are "arrested" at the initial stage of development for a prolonged time. Because a transcriptional factor WT1 is expressed in high levels in follicles at early stages of development and because WT1 over-expression represses the promoter activity of inhibin-alpha gene, this nuclear protein may be important in the maintenance of follicles at early stages of development. Once a cohort of follicles is recruited to grow, it is destined to undergo apoptosis unless rescued by survival factors. After puberty onset and under gonadotropin stimulation, some of the growing antral follicles are "selected" to continue their final maturation and secrete high levels of estrogens to trigger ovulation. Following repeated cycles of recruitment, atresia or ovulation, the follicle reserve is exhausted, thus signaling the onset of reproductive senescence. Although the somatic granulosa cell is the major cell type undergoing apoptosis in the ovary, the germ cells in the testis also exhibit signs of apoptotic cell demise. In the testis, gonadotropins and androgens act as survival factors whereas exposure to elevated temperature in cryptorchid testes increases apoptosis. In the seasonally breeding hamster model, photoperiod-entrained regression and recrudescence of testis tissue serves as a unique natural model of apoptosis. With recent advances in our understanding of the cellular mechanism of apoptosis, including the elucidation of the Ced9/bc12 and Ced3/ICE family of proteins, further investigation of gonadal apoptosis may lead to a better understanding of gonadal degenerative disorders (such as premature ovarian failure and oligospermia), reproductive senescence and tumorigenesis. The gonadal model should also be valuable in studying the regulation of intracellular apoptosis genes by external hormonal signals.

Extracellular matrix signaling from the cellular membrane skeleton to the nuclear skeleton: a model of gene regulation.

Lelièvre S, Weaver VM, Bissell MJ

Recent Prog Horm Res · 1996 · PMID 8701089

It is well established that cells must interact with their microenvironment and that such interaction is crucial for coordinated function and homeostasis. However, how cells receive and integrate external signals leading... It is well established that cells must interact with their microenvironment and that such interaction is crucial for coordinated function and homeostasis. However, how cells receive and integrate external signals leading to gene regulation is far from understood. It is now appreciated that two classes of cooperative signals are implicated: a soluble class including hormones and growth factors and a class of insoluble signals emanating from the extracellular matrix (ECM) directly through contact with the cell surface. Using 3-dimensional culture systems and transgenic mice, we have been able to identify some of the elements of this ECM-signaling pathway responsible for gene regulation in rodent mammary gland differentiation and involution. Our major observations are 1) the requirement for a laminin-rich basement membrane; 2) the existence of a cooperative signaling pathway between basement membrane and the lactogenic hormone prolactin (PRL);3) the importance of beta 1-integrins and bHLH transcription factor(s) and the presence of DNA response elements (exemplified by BCE-1, located on a milk protein gene, beta-casein); and 4) the induction of mammary epithelial cell programmed cell death following degradation of basement membrane. We hypothesize that this cooperative signaling between ECM and PRL may be achieved through integrin- and laminin-directed restructuring of the cytoskeleton leading to profound changes in nuclear architecture and transcription factor localization. We postulate that the latter changes allow the prolactin signal to activate transcription of the beta-casein gene. To further understand the molecular mechanisms underlying ECM and hormonal cooperative signaling, we are currently investigating ECM regulation of a "solid-state" signaling pathway including ECM fiber proteins, plasma membrane receptors, cytoskeleton, nuclear matrix and chromatin. We further postulate that disruption of such a pathway may be implicated in cell disorders including transformation and carcinogenesis.

Protein tyrosine phosphatases: their roles in signal transduction.

Dixon JE

Recent Prog Horm Res · 1996 · PMID 8701088

Protein tyrosine phosphatases play critical roles in a number of cellular signal transduction pathways. Receptor-like PTPases such as CD45 are essential for antigen-induced proliferative responses of T-cells. Intracellul... Protein tyrosine phosphatases play critical roles in a number of cellular signal transduction pathways. Receptor-like PTPases such as CD45 are essential for antigen-induced proliferative responses of T-cells. Intracellular PTPases have been shown to associate with specific growth factor receptors and this association has a dramatic effect on receptor signaling mechanisms. Other phosphatases (e.g., the product of the CDC25 gene) are essential for cell cycle progression. It appears that the cellular location of the intracellular PTPases plays an important role in defining the substrate specificity. Phosphatases are also present in both pathogenic bacteria and viruses. These PTPases most likely function to disrupt important signal transduction pathways present in the host. More than 30 different phosphatases have been cloned and characterized. A detailed understanding of their catalytic properties suggests that all PTPases use a common mechanism for removing phosphatase from various phosphoproteins. Two PTPase structures recently have been determined. The structural information along with biochemical and kinetic data provides a basis for understanding the catalytic properties of these enzymes.

The JAK-STAT pathway: summary of initial studies and recent advances.

Darnell JE

Recent Prog Horm Res · 1996 · PMID 8701087

Polypeptides redirect cells by causing immediate changes in gene transcription. A direct connection between polypeptide receptors on the cell surface and genes in the nucleus has been provided by the recognition of the J... Polypeptides redirect cells by causing immediate changes in gene transcription. A direct connection between polypeptide receptors on the cell surface and genes in the nucleus has been provided by the recognition of the JAK-STAT pathway. Results leading to our present understanding of this pathway are reviewed.

Modulator and messenger functions of cyclic ADP-ribose in calcium signaling.

Lee HC

Recent Prog Horm Res · 1996 · PMID 8701086

Cyclic ADP-ribose (cADPR), a Ca+2 mobilizing cyclic nucleotide derived from NAD+, is emerging as an endogenous modulator of the Ca(+2)-induced Ca+2 release (CICR) mechanism in cells. cADPR was discovered because of the p... Cyclic ADP-ribose (cADPR), a Ca+2 mobilizing cyclic nucleotide derived from NAD+, is emerging as an endogenous modulator of the Ca(+2)-induced Ca+2 release (CICR) mechanism in cells. cADPR was discovered because of the prominent delay in the initiation of Ca+2 release by NAD+ in sea urchin egg homogenates, which was due to enzymatic conversion to cADPR. In addition to the egg, an invertebrate cell, amphibian neurons, a variety of mammalian cells and plant vacuoles are found to be responsive to cADPR, indicating its generality. The cyclic structure of cADPR has been determined by X-ray crystallography. A series of analogs has been synthesized, which includes cyclic GDP-ribose, a fluorescent analog, a series of specific antagonists, a photoaffinity label and caged cADPR. The use of these analogs of cADPR has provided definitive evidence for the authenticity of its Ca+2 mobilizing activity and insights for understanding its mechanism and biological functions. Results show that its action requires a soluble protein which is identified as calmodulin. The effect of calmodulin is synergistic with cADPR and both act to sensitize CICR to Ca+2. Together, the Ca+2 sensitivity of CICR can be increased by several orders of magnitude. In addition to being a modulator of CICR. cADPR can also function as a messenger. Activation of its synthetic enzyme can lead to large increases in cellular concentrations of cADPR, which would sensitize CICR to such an extent that even basal levels of cellular Ca+2 are sufficient to trigger further release. This is operationally equivalent to being a Ca+2 messenger. Three types of enzymes are involved in the metabolism of cADPR, a soluble ADP-ribosyl cyclase; a bifunctional ecto-enzyme, CD38, which is also a lymphocyte antigen; and an intracellular enzyme activable by a cGMP-dependent process. The importance of two cysteine residues in the bifunctionality of CD38 has been shown by site-directed mutagenesis. Both ADP-ribosyl cyclase and CD38 can catalyze the exchange of the nicotinamide group in NADP+ with nicotinic acid, leading to the formation of another Ca+2 mobilizing metabolite, nicotinic acid dinucleotide phosphate (NAADP). Pharmacological and desensitization studies show that the NAADP-mechanism is totally independent of the cADPR- and inositol trisphosphate-mechanisms and the Ca+2 stores responsive to NAADP are separable from those sensitive to the other two Ca+2 agonists. Microinjection studies show that all three mechanisms are present and functional in cells. The emerging picture of multiplicity in Ca+2 signaling mechanisms underscores the versatility of Ca+2 in regulating diverse cellular functions.

Desensitization of G protein-coupled receptors.

Freedman NJ, Lefkowitz RJ

Recent Prog Horm Res · 1996 · PMID 8701085

Waning responsiveness to continuous or repeated stimulation constitutes the phenomenon of desensitization, which pervades biological systems. Over the last several years, molecular mechanisms for desensitization of cellu... Waning responsiveness to continuous or repeated stimulation constitutes the phenomenon of desensitization, which pervades biological systems. Over the last several years, molecular mechanisms for desensitization of cellular signaling through G protein-coupled receptors have been delineated, particularly at the level of the receptors themselves. This review focuses on those aspects of G protein-coupled receptor desensitization which occur within minutes of agonist exposure. Agonist-dependent desensitization of these receptors can reduce their signaling responsiveness to maximum stimulation by up to 70-80%; indeed, in some receptor systems, the process of receptor desensitization appears to effect the termination of the cellular signaling response. Agonist-induced desensitization involves phosphorylation of G protein-coupled receptors by two currently recognized classes of serine/threonine protein kinases. Second messenger-dependent kinases, phosphorylating a variety of proteins, mediate a generalized cellular hyporesponsiveness termed heterologous desensitization. G protein-coupled receptor kinases (GRKs) phosphorylate specifically agonist-occupied, or activated, receptors, and thereby initiate receptor-specific, or homologous, desensitization. GRK-mediated receptor phosphorylation facilitates the binding of an inhibitory arrestin protein to the phosphorylated receptor, an event which substantially impairs receptor signaling. The GRK family comprises six, and the arrestin family comprises four known members. Each GRK demonstrates the ability to phosphorylate a limited number of model receptor substrates, but the widespread expression of several GRKs and the two somatic arrestins suggest that GRK-initiated homologous desensitization is of general importance to a wide range of G protein-coupled receptors. Exploration of the substrate specificity for GRKs and the ligand specificity for arrestins remains in its early stages. Currently, GRKs can most readily be differentiated by the mechanisms each employs to associate with the plasma membrane. Accumulating data from human disease states and transgenic mice attest to the physiologic significance of GRK-initiated receptor desensitization.

The melanocortin receptors: agonists, antagonists, and the hormonal control of pigmentation.

Cone RD, Lu D, Koppula S … +7 more , Vage DI, Klungland H, Boston B, Chen W, Orth DN, Pouton C, Kesterson RA

Recent Prog Horm Res · 1996 · PMID 8701084

Molecular cloning experiments have led to the identification and characterization of a family of five receptors for the melanocortin (melanotropic and adrenocorticotropic) peptides. The first two members of the family cl... Molecular cloning experiments have led to the identification and characterization of a family of five receptors for the melanocortin (melanotropic and adrenocorticotropic) peptides. The first two members of the family cloned were the well-characterized melanocyte-stimulating hormone receptor (MSH-R) and adrenocorticotropin receptor (ACTH-R). The three new melanocortin receptors have been termed the MC3-R, MC4-R, and MC5-R, according to the order of their discovery, and little is known at this point concerning their function. Agouti and extension are two genetic loci known to control the amounts of eumelanin (brown-black) and phaeomelanin (yellow-red) pigments. Chromosomal mapping demonstrated that the MSH-R, now termed MCI-R, mapped to extension. Extension was shown to encode the MCI-R, and mutations in the MCI-R are responsible for the different pigmentation phenotypes caused by this locus. Functional variants of the MCI-R, originally characterized in the mouse, have now also been identified in the guinea pig and cow. Dominant constitutive mutants of the MCI-R are responsible for causing dark black coat colors while recessive alleles result in yellow or red coat colors. Agouti, a secreted 108 amino acid peptide produced within the hair follicle, acts on follicular melanocytes to inhibit alpha-MSH-induced eumelanin production. Experiments demonstrate that agouti is a high-affinity antagonist, acting at the MCI-R to block alpha-MSH stimulation of adenylyl cyclase, the effector through which alpha-MSH induces eumelanin synthesis. The MCI-R is thus a unique bifunctionally controlled receptor, activated by alpha-MSH and antagonized by agouti, both contributing to the variability seen in mammalian coat colors. The variable tan and black coat color patterns seen in the German Shepherd, for example, can now be understood on the molecular level as the interaction of a number of extension and agouti alleles encoding variably functioning receptors and a differentially expressed antagonist of the receptor, respectively.

Modulation of pulsatile GH release through a novel receptor in hypothalamus and pituitary gland.

Smith RG, Pong SS, Hickey G … +11 more , Jacks T, Cheng K, Leonard R, Cohen CJ, Arena JP, Chang CH, Drisko J, Wyvratt M, Fisher M, Nargund R, Patchett A

Recent Prog Horm Res · 1996 · PMID 8701083

Hormone replacement should provide a serum hormone profile similar to that found in normal physiology. This is generally impractical because hormones are usually released episodically and therefore require frequent admin... Hormone replacement should provide a serum hormone profile similar to that found in normal physiology. This is generally impractical because hormones are usually released episodically and therefore require frequent administration. However, rather than replacing the hormone directly, in theory, one could administer a mimic or amplifier of the pulse generator that controls pulsatile release of the particular hormone. Using growth hormone (GH) as a paradigm we sought such a mimetic that would provide episodic GH release when administered by the oral route. A GH secretagogue MK0677, is described that has these ideal properties; following oral administration MK0677 amplifies episodic GH release. Mechanistically, it synergizes with growth hormone releasing hormone (GHRH) through a receptor and signal transduction pathway distinct from that of GHRH and is a functional antagonist of somatostatin (SRIF). MK0677 also acts on the arcuate nucleus and appears to stimulate GHRH release. By using 35S-MK0677, a new G-protein coupled receptor for MK0677 was characterized in the plasma membrane fraction of pituitary and hypothalamic tissue. The receptor is present in very low abundance and couples to phospholipase C. Other ligands selective for this receptor also cause synchronization of well-defined pathways leading to GH release. Repeated oral treatment of dogs once daily with MK0677 initiates amplified pulsatile GH release accompanied by increases in IGF-1 that are sustained. The unique biological properties of MK0677 and other synthetic ligands that bind to the same receptor force us to predict that these ligands mimic a naturally occurring hormone that regulates pulsatile GH release. Understanding the regulatory mechanisms involved in this paradigm has broad implications for the control of pulsatile rhythms in the endocrine system.

The gene responsible for adrenal hypoplasia congenita, DAX-1, encodes a nuclear hormone receptor that defines a new class within the superfamily.

Burris TP, Guo W, McCabe ER

Recent Prog Horm Res · 1996 · PMID 8701082

X-linked adrenal hypoplasia congenita (AHC) is an inherited disorder of the development of the adrenal cortex. The gene responsible for this genetic disorder has been identified using positional cloning methods and has b... X-linked adrenal hypoplasia congenita (AHC) is an inherited disorder of the development of the adrenal cortex. The gene responsible for this genetic disorder has been identified using positional cloning methods and has been named DAX-1 based on its localization within the dosage-sensitive sex reversal (DSS) locus and the AHC locus on the X chromosome. The DAX-1 gene consists of two exons separated by a 3.4 kb intron. Analysis of DNA from patients with deletions in the AHC critical region in the X chromosome provided strong indication for the involvement of the DAX-1 gene in X-linked AHC. A number of intragenic mutations within the DAX-1 gene have also been identified in patients with isolated AHC. The DAX-1 gene product belongs to the nuclear hormone receptor superfamily based on the presence of an entire ligand binding domain present in the carboxy-terminal region of the receptor. However, DAX-1 has a domain structure which is very unusual with respect to other nuclear hormone receptor superfamily members. The amino-terminal portion of DAX-1 contains a novel domain consisting of 3.5 repeats of a 65-67 amino acid motif that contains two putative zinc finger structures in place of the more usual amino-terminal domain, DNA binding domain, and hinge region of the typical nuclear hormone receptors. It has been proposed that the amino-terminal portion of the DAX-1 protein is the DNA binding domain. The expression pattern of DAX-1 suggests that it may play a role in the regulation of steroidogenesis. Not only is DAX-1 expressed in the adrenal glands, but it is also expressed in the ovaries and testes. Most recently, we demonstrated that DAX-1 is also expressed in the hypothalamus and pituitary gland. The expression of DAX-1 in the neuroendocrine system suggests that interruption of the expression in these tissues may be the cause of the hypogonadotropic hypogonadism (HH) that is frequently associated with AHC. Interestingly, hybridization of a human DAX-1 cDNA probe with genomic DNA from various species indicated that a DAX-1 homologue may exist in yeast. Thus, DAX-1 or a DAX-1-like transcription factor may be the most primitive member of the nuclear hormone receptor superfamily. Although the molecular mechanism of action of DAX-1 is not yet characterized, its importance for the development and physiology of the adrenal gland and gonads is indicated by its involvement in AHC and HH. Analysis of the functions of DAX-1 along with its regulation of expression will not only provide information concerning the actions of this new member of the nuclear hormone receptor superfamily, but will also yield insight into the pathogenesis of AHC and HH and may allow for the development of gene therapy protocols for the treatment of these diseases.

The gonadotropin genes: evolution of distinct mechanisms for hormonal control.

Albanese C, Colin IM, Crowley WF … +4 more , Ito M, Pestell RG, Weiss J, Jameson JL

Recent Prog Horm Res · 1996 · PMID 8701081

The glycoprotein hormones (TSH, FSH, LH, CG) are structurally related proteins with diverse physiologic functions. This family of hormones offers an opportunity to address fundamental questions concerning how gene expres... The glycoprotein hormones (TSH, FSH, LH, CG) are structurally related proteins with diverse physiologic functions. This family of hormones offers an opportunity to address fundamental questions concerning how gene expression is regulated in a cell-specific manner and in response to different hormones. For example, the alpha-subunit gene is expressed in several different pituitary cell types (gonadotropes and thyrotropes) as well as in the placenta. Because it must be coordinantly expressed with the different beta-subunit genes, the alpha-gene provides an interesting model for multihormonal control which varies in a cell-type specific manner. Many of the promoter regulatory DNA sequences and cognate transcription factors in the alpha-gene have been identified. These studies reveal a remarkable series of composite regulatory elements that interact with families of transcription factors that are still being characterized. In contrast, the beta-subunit genes are notable for restricted cell-type expression and more limited hormonal regulation that reflects their individual physiologic roles. The TSH beta gene is expressed only in thyrotropes where, in conjunction with the alpha-gene, it is subject to transcriptional repression by thyroid hormone. The FSH beta gene is expressed in gonadotropes where its expression is controlled primarily by activin and inhibin, with additional regulation by GnRH. The LH beta gene is also expressed in gonadotropes, but it is more dependent upon GnRH input and its expression is unaffected by the activin/inhibin system. The CG beta gene evolved recently from the LH beta gene and in the process, the CG beta promoter acquired new regulatory elements that favor its expression in the placenta rather than the pituitary gland. Less is known about the regulatory elements in the beta genes, in part because highly differentiated cells are required for their normal regulation. This chapter reviews the regulation of this family of genes with an emphasis on recent studies from our laboratory involving the gonadotropins (LH, FSH, CG). Concomitant with our advancing understanding of how the gonadotropin genes are regulated, we are also learning about genetic causes of gonadotropin deficiency syndromes.

Transcriptional control of cell phenotypes in the neuroendocrine system.

Rosenfeld MG, Bach I, Erkman L … +8 more , Li P, Lin C, Lin S, McEvilly R, Ryan A, Rhodes S, Schonnemann M, Scully K

Recent Prog Horm Res · 1996 · PMID 8701080

A fundamental aspect of the development of complex organ systems is a requirement for precise temporal and spatial coordination in the genesis of tissues of distinct embryonic origins, in order to form functional units r... A fundamental aspect of the development of complex organ systems is a requirement for precise temporal and spatial coordination in the genesis of tissues of distinct embryonic origins, in order to form functional units required for physiological homeostasis and survival. Such a requirement is particularly well exemplified in mammalian development in the formation of the hypothalamic-pituitary axis. Neuronally expressed POU domain factors might exert effects on terminal differentiation events similar to those of Pit-1 in the maturation of anterior pituitary gland cell phenotypes. Neurons comprising the endocrine hypothalamus develop in tandem with their ultimate target, the pituitary gland, and arise from a primordium in which three related class III POU domain factors-Brn-2, Brn-4, and Brn-1-are initially co-expressed. These factors subsequently exhibit stratified patterns of ontogenic expression, correlating with the appearance of distinct neuropeptides that define three major endocrine hypothalamic cell types. Deletion of the Brn-2 genomic locus affects terminal differentiation and/or maintenance of hypothalamic neurosecretory neurons and development of the posterior pituitary gland. Thus, both neuronal and endocrine components of the hypothalamic-pituitary axis are critically dependent upon the action of specific POU domain factors at a penultimate step in the sequential events that underlie the appearance of mature cellular phenotypes.

IGF-I receptor signalling: lessons from the somatotroph.

Melmed S, Yamashita S, Yamasaki H … +7 more , Fagin J, Namba H, Yamamoto H, Weber M, Morita S, Webster J, Prager D

Recent Prog Horm Res · 1996 · PMID 8701079

Insulin-like growth factor 1 (IGF-I) is a major feedback regulator of pituitary GH secretion, with defined actions occurring at both the hypothalamus and pituitary. The IGF-I gene is expressed in the anterior pituitary i... Insulin-like growth factor 1 (IGF-I) is a major feedback regulator of pituitary GH secretion, with defined actions occurring at both the hypothalamus and pituitary. The IGF-I gene is expressed in the anterior pituitary in a GH-dependent manner thus providing for both endocrine-as well as autocrine-mediated GH regulation. In turn, IGF-I selectively and specifically inhibits GH gene transcription and secretion, its attenuating effects on nascent GH mRNA synthesis being demonstrable within 1 h. Binding of IGF-I to its pituitary cell surface receptor is followed by rapid activation of the intrinsic tyrosine kinase activity of the receptor beta-subunit and phosphorylation of insulin receptor substrate 1 (IRS-1). Structure-function studies of the human IGF-I receptor were performed in stable, GH-secreting transfectants expressing either the cDNA encoding the wild-type (WT) human IGF receptor and exhibiting enhanced IGF-I responsiveness, or cDNAs encoding IGF-I receptor mutants and a truncated, kinase-deficient receptor (952STOP). 950Tyr situated on the submembrane receptor domain was found to be critical for transducing the IGF-I signal to the GH gene. IGF-I failed to suppress GH secretion by signalling endogenous rat IGF-I receptors when hybrid receptors were formed with kinase-deficient human receptors and rat hemi-receptors. This dominant negative effect on hormone secretion was also evidenced when mitogenic IGF-I signals were blocked in vitro and in vivo by these hybrid receptors. Using similar doses of IGF-I, the IGF-I receptor cell transfectants also demonstrated ligand-dependent activation of ERKs in pituitary cells. In conclusion, the pituitary IGF-I receptor mediates the negative feedback regulation of GH. Thus, IGF-I receptor mass may determine GH responses to malnutrition, pregnancy, and refeeding. IGF-I receptor mutations may also prove useful to abrogate the growth of IGF-I-dependent tumors. These structure-function studies of the human IGF-I receptor provide mechanistic insights into both metabolic control of the GH axis, as well as target tissue proliferative characteristics.
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