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Название	Essential Endocrinology and Diabetes
Автор произведения	Richard I. G. Holt
Жанр	Медицина
Серия
Издательство	Медицина
Год выпуска	0
isbn	9781118764121

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also called NR5A1) is a critical mediator of endocrine organ formation. Without it, the anterior pituitary gonadotrophs, adrenal gland and gonad fail to develop. It is also critical for the ongoing expression of many important genes within these cell types (e.g. the enzymes that orchestrate steroidogenesis; Figure 2.6). A variant receptor with a similar expression profile is DAX1 (also called NROB1), mutation of which causes X‐linked congenital adrenal hypoplasia (i.e. under‐development). Duplication of the region that includes the gene encoding DAX1 causes male‐to‐female sex reversal (Chapters 6 and 7). Increasingly, endogenous compounds are being identified that occupy the three‐dimensional structure created by the ligand‐binding domain. Whether these substances are the true hormone ligands remains debatable.

Schematic illustration of hormonal stimulation of intracellular phospholipid turnover and calcium metabolism. Phosphatidylinositol metabolism includes the membrane intermediaries, PI monophosphate (PIP) and PI bisphosphate (PIP2). Hormone action stimulates phospholipase C, which hydrolyzes PIP2 to diacylglycerol (DAG) and inositol triphosphate (IP3). IP3 mobilizes calcium, particularly from the endoplasmic reticulum. DAG activates protein kinase C and increases its affinity for calcium ions, which further enhances activation.

Figure 3.16 Hormonal stimulation of intracellular phospholipid turnover and calcium metabolism. Phosphatidylinositol (PI) metabolism includes the membrane intermediaries, PI monophosphate (PIP) and PI bisphosphate (PIP₂). Hormone action stimulates phospholipase C, which hydrolyzes PIP₂ to diacylglycerol (DAG) and inositol triphosphate (IP₃). IP₃ mobilizes calcium, particularly from the endoplasmic reticulum. DAG activates protein kinase C and increases its affinity for calcium ions, which further enhances activation. Collectively, these events stimulate phosphorylation cascades of proteins and enzymes that alter intracellular metabolism.

Schematic illustration of eicosanoid signalling. Arachidonic acid, released by phospholipase A2, is the rate-limiting precursor for generating eicosanoid signalling molecules by cyclo-oxygenase (COX) and lipoxygenase pathways.

Figure 3.17 Eicosanoid signalling. Arachidonic acid, released by phospholipase A₂, is the rate‐limiting precursor for generating eicosanoid signalling molecules by cyclo‐oxygenase (COX) and lipoxygenase pathways. This example produces prostaglandin E₂ (PGE₂), but there are at least 16 prostaglandins, all structurally related, 20‐carbon, fatty acid derivatives. They are released from many cell‐types and exert paracrine and autocrine actions (e.g. the inflammatory response and contraction of uterine smooth muscle). Their circulating half‐life is short (3–10 min). Aspirin inhibits prostaglandin production at sites of inflammation. There are different forms of COX; until withdrawn due to side‐effects, inhibitors of COX‐2 were used as anti‐inflammatory agents.

Schematic illustration of nuclear hormone action. (a) Free hormone (a steroid is shown), in equilibrium with protein-bound hormone, diffuses across the target cell membrane. (b) Inside the cell, free hormone binds to its receptor. This may occur in the cell cytoplasm or in the cell nucleus. (c) The activated hormone–receptor complex, now present in the nucleus, binds to the hormone-response element of its target genes. (d) This interaction promotes DNA-dependent RNA polymerase (Pol II) to start transcription of mRNA. (e) Post-transcriptional modification and splicing sees the mRNA exit the nucleus for translation into protein on ribosomes. Post-translational modification provides the final protein.

Figure 3.18 Simplified schematic of nuclear hormone action. (a) Free hormone (a steroid is shown), in equilibrium with protein‐bound hormone, diffuses across the target cell membrane. (b) Inside the cell, free hormone binds to its receptor ( c03g001 ). This may occur in the cell cytoplasm (e.g. glucocorticoid receptor) or in the cell nucleus (e.g. thyroid hormone receptor). (c) The activated hormone–receptor complex ( c03g001 *), now present in the nucleus, binds to the hormone‐response element of its target genes. (d) This interaction promotes DNA‐dependent RNA polymerase (Pol II) to start transcription of mRNA. (e) Post‐transcriptional modification and splicing sees the mRNA exit the nucleus for translation into protein on ribosomes. Post‐translational modification provides the final protein.

Endocrine transcription factors

Other transcription factors play roles in development and regulating mature function comparable to some of the orphan and variant nuclear receptors although they are not part of the nuclear receptor superfamily (Table 3.4). This is important because inactivating mutations in these transcription factors cause endocrine pathology, particularly in the paediatric setting. For instance, pituitary‐specific transcription factor 1 (PIT1) regulates expression of the genes encoding GH, PRL and the β‐subunit of TSH. People with inactivating PIT1 mutations show loss of these hormones, causing short stature, and a developmental secondary hypothyroidism accompanied by severe learning disability. Via whole‐exome and, increasingly, whole‐genome sequencing, clinical genetics and genomics can provide increasingly precise diagnostic answers to these developmental endocrinology problems (Chapter 4).

Schematic illustration of the nuclear hormone receptor superfamily. The receptors, named according to their ligands, range in size from 395 to 984 amino acids.

Figure 3.19 The nuclear hormone receptor superfamily. The receptors, named according to their ligands (shown to the right), range in size from 395 to 984 amino acids.

Table 3.2 Examples of modifications to hormones, their precursors or metabolites within the cell prior to nuclear receptor action

Modification that increases activity	Modification that decreases activity
Deiodination of thyroxine (T₄) to tri‐iodothyronine (T₃) by type 1 and type 2 selenodeiodinase (Figure 8.7)	Inactivation of T₄ and T₃ by the formation of reverse T₃ and di‐iodothyronine (T₂) by type 3 selenodeiodinase (Figure 8.7)
Reduction of testosterone to dihydrotestosterone (DHT) by 5α‐reductase (Figure 7.7); sex steroid function in males by local conversion of testosterone to oestradiol by the action of aromatase (CYP19; e.g. in bone; Figure 2.6)	Loss of androgenic activity by conversion of testosterone to oestradiol by the action of aromatase (CYP19; Figure 2.6)
Conversion of 25‐hydroxyvitamin D to 1,25‐dihydroxyvitamin D (calcitriol) by 1α‐hydroxylase (Figure 9.2)	Conversion of 25‐hydroxyvitamin D to 24,25‐dihydroxyvitamin D or the inactivation of 1,25‐dihydroxyvitamin D to 1,24,25‐trihydroxyvitamin D by 24α‐hydroxylase (Figure 9.2) Скачать книгу В начало < 21 22 23 24 25 26 27 28 29 30 > В конец

Essential Endocrinology and Diabetes. Richard I. G. Holt

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Endocrine transcription factors