Central infusion of angiotensin IV or its more stable analogues facilitates memory retention and retrieval in normal animals and reverses amnesia induced by scopolamine or by bilateral perforant pathway lesions. These peptides bind with high affinity and specificity to a novel binding site designated the angiotensin AT 4 receptor. Until now, the AT 4 receptor has eluded molecular characterization. Here we identify the AT 4 Central infusions of the hexapeptide VYIHPF (angiotensin IV, Ang IV) 1 or its more stable analogues, Nle 1 -Ang IV andNorleucinal Ang IV, facilitate memory retention and retrieval in rats in the passive avoidance and Morris water maze paradigms (1-3). In two rat models of amnesia, induced by the muscarinic antagonist, scopolamine, or bilateral perforant pathway lesion, the Ang IV analogues reversed the memory deficits detected utilizing the Morris water maze paradigm (3, 4). Enhancement of long term memory by Ang IV has also been demonstrated in species as distant as crabs (5). Angiotensin IV and its analogues enhance long term potentiation in both the dentate gyrus in vivo (6) and the CA1 region of the hippocampus in vitro (7), possibly via actions at the post-synaptic terminal. We have also shown that Ang IV enhances K ϩ -evoked acetylcholine release from rat hippocampal slices (8).The actions of Ang IV and its analogues are mediated by the angiotensin AT 4 receptor, defined by an international nomenclature committee (9) as the high affinity binding site specific for Ang IV (10). The AT 4 receptor has since been shown to bind with nanomolar affinity the decapeptide, LVVYPWTQRF (LVV-H7), isolated from sheep cerebral cortex (19).Although first identified in bovine adrenal, the receptor is widely distributed throughout the brain and peripheral organs (11). In the central nervous system, its distribution is highly conserved in guinea pig (12), macaque monkey (13), and human (14) brains. AT 4 receptors occur in high levels in the basal nucleus of Meynert, in the CA1 to CA3 regions of Ammon's horn in the hippocampus, and throughout the neocortex, areas important for cognitive processing. Despite the dramatic central effects of Ang IV and the abundance of the receptor in the central nervous system, the identity of the AT 4 receptor and the mechanism by which its ligands mediate their actions were unknown. MATERIALS AND METHODSProtein Purification-AT 4 receptors in bovine adrenal membranes (16 mg of membrane protein) were cross-linked to the photoactivatable analogue of Ang IV, [ 125 I]Nle 1 -BzPhe 6 -Gly 7 -Ang IV as described previously (15). Cross-linked membranes were solubilized in solubilization buffer (1% CHAPS, 20 mM Tris-HCl, pH 7.5, 5 mM EDTA) with shaking at room temperature for 48 h, and insoluble material was pelleted by centrifugation at 100,000 ϫ g for 1 h at 4°C. Non-cross-linked membranes (48 mg of protein) were solubilized and centrifuged similarly, and the supernatant was combined with that from cross-linked membranes. Solubilized membrane proteins were applied to a 1-ml DEAE fas...
SOX (SRY-related HMG box) proteins are transcription factors that have critical roles in the regulation of numerous developmental processes. They share at least 50% homology in their HMG domains, which bind the DNA element AACAAT. How different SOX proteins achieve specific regulation of target genes is not known. We determined the DNA-binding specificity of SOX9 using a random oligonucleotide selection assay. The optimal SOX9 binding sequence, AGAACAATGG, contained a core DNA-binding element AACAAT, flanked by 5' AG and 3' GG nucleotides. The specific interaction between SOX9 and AGAACAATGG was confirmed by mobility shift assays, DNA competition and dissociation studies. The 5' AG and 3' GG flanking nucleotides enhance binding by SOX9 HMG domain, but not by the HMG domain of another SOX factor, SRY. For SRY, different 5' and 3' flanking nucleotides are preferred. Our studies support the notion that SOX proteins achieve DNA sequence specificity through subtle preferences for flanking nucleotides and that this is likely to be dictated by signature amino acids in their HMG domains. Furthermore, the related HMG domains of SOX9 and Sox17 have similar optimal binding sites that differ from those of SRY and Sox5, suggesting that SOX factors may co-evolve with their DNA targets to achieve specificity.
Angiotensin IV (Ang IV) exerts profound effects on memory and learning, a phenomenon ascribed to its binding to a specific AT 4 receptor. However the AT 4 receptor has recently been identified as the insulin-regulated aminopeptidase (IRAP). In this study, we demonstrate that AT 4 receptor ligands, including Ang IV, branes with high affinity, which was up to 200-fold greater than in the catalytic assay; this difference was not consistent among the peptides, and could not be ascribed to ligand degradation. Although some AT 4 ligands were subject to minor cleavage by HEK293T membranes, none were substrates for IRAP. Of a range of peptides tested, only vasopressin, oxytocin, and met-enkephalin were rapidly cleaved by IRAP. We propose that the physiological effects of AT 4 ligands result, in part, from inhibition of IRAP cleavage of neuropeptides involved in memory processing.
The architectural transcription factor SRY (sex-determining region of the Y chromosome) plays a key role in sex determination as indicated by the fact that mutations in SRY are responsible for XY gonadal dysgenesis in humans. Although many SRY mutations reduce DNA-binding͞bending activity, it is not clear how SRY mutations that do not affect interaction with DNA contribute to disease. The SRY high-mobility group domain harbors two nuclear localization signals (NLSs), and here we examine SRY from four XY females with missense mutations in these signals. In all cases, mutant SRY protein is partly localized to the cytoplasm, whereas wild-type SRY is strictly nuclear. Each NLS can independently direct nuclear transport of a carrier protein in vitro and in vivo, with mutations in either affecting the rate and extent of nuclear accumulation. The N-terminal NLS function is independent of the conventional NLS-binding importins (IMPs) and requires unidentified cytoplasmic transport factors, whereas the C-terminal NLS is recognized by IMP. The SRY-R133W mutant shows reduced IMP binding as a direct consequence of the sex-reversing C-terminal NLS mutation. Of the N-terminal NLS mutants examined, SRY-R62G unexpectedly shows a marked reduction in IMP binding, whereas SRY-R75N and SRY-R76P show normal IMP binding, suggesting defects in the IMP-independent pathway. We conclude that SRY normally requires the two distinct NLS-dependent nuclear import pathways to reach sufficient levels in the nucleus for sex determination. This study documents cases of human disease being explained, at a molecular level, by the impaired ability of a protein to accumulate in the nucleus.
In humans, mutations in SOX9 result in a skeletal malformation syndrome, campomelic dysplasia (CD). The present study investigated two major classes of CD mutations: 1) point mutations in the high mobility group (HMG) domain and 2) truncations and frameshifts that alter the C terminus of the protein. We analyzed the effect of one novel mutation and three other point mutations in the HMG domain of SOX9 on the DNA binding and DNA bending properties of the protein. The F12L mutant HMG domain shows negligible DNA binding, the H65Y mutant shows minimal DNA binding, whereas the A19V mutant shows near wild type DNA binding and bends DNA normally. Interestingly, the P70R mutant has altered DNA binding specificity, but also bends DNA normally. The effects of the point mutations were interpreted using a molecular model of the SOX9 HMG domain. We analyzed the effects upon transcription of mutations resembling the truncation and frameshift mutations in CD patients, and found that progressive deletion of the C terminus causes progressive loss of transactivation. Maximal transactivation by SOX9 requires both the C-terminal domain rich in proline, glutamine, and serine and the adjacent domain composed entirely of proline, glutamine, and alanine. Thus, CD arises by mutations that interfere with DNA binding by SOX9 or truncate the C-terminal transactivation domain and thereby impede the ability of SOX9 to activate target genes during organ development.In humans, mutations in SOX9 cause campomelic dysplasia (CD), 1 a skeletal malformation syndrome that is often associated with XY sex reversal (1). Other tissues affected include kidney, heart, and brain, consistent with the expression pattern of Sox9 in developing mouse (2, 3). There are four major classes of mutations causing CD: 1) amino acid substitutions in the HMG domain (Fig. 1A), 2) truncations or frameshifts that alter the C terminus of SOX9 (Fig. 1B), 3) mutations at splice junctions, and 4) chromosomal translocations, of which classes 1 and 2 are investigated here. Most CD patients are heterozygous for wild type and mutant alleles of SOX9. CD appears to result from haploinsufficiency; presumably, a critical dose of SOX9 is required to switch on the appropriate genes during development. The present study reports the identification in a CD patient of a novel amino acid substitution mutation (H65Y) in the HMG domain of SOX9. We report the effects of this and three other point mutations (F12L, A19V, and P70R) on the DNA binding and DNA bending activities of the HMG domain.SOX proteins represent a large class of transcription factors related to SRY, the testis-determining factor, through their HMG domains that bind and bend DNA in a sequence-specific manner. Expression of these proteins in defined cell types at specific stages of development appears to govern cell fate decisions. SOX9 activates expression of type II and type XI collagen in vivo (4 -6), consistent with a role in bone development.SOX proteins fall within a larger group of HMG domain proteins comprising two clas...
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Five patients with campomelic dysplasia who have survived (age range 7 to 20 years) are described, all of whom have molecular or cytogenetic evidence of campomelic dysplasia. The phenotype and radiological features of these cases are consistent. Complications in this group include recurrent apnoea and upper respiratory infections, progressive kyphoscoliosis, mild to moderate learning difficulties, short stature, and dislocation of the hips. All five had very similar facial features. The radiological features include hypoplastic scapulae, defective ischiopubic ossification, absent or hypoplastic patellae, and spinal dysraphism.Campomelic dysplasia (CMD) is a rare skeletal dysplasia resulting from mutations in SOX9. It is usually lethal in the first year of life. Three-quarters of the cases with a male karyotype have complete or partial sex reversal.1 The skeletal changes in the neonatal period are well recognised and include hypoplastic scapulae, bowing of the long bones, vertical narrow iliac bones, and absence of ossification of the thoracic pedicles.The case histories of five children who share a number of clinical and radiological features are presented. CASE REPORTSCase 1 A mother was diagnosed at the age of 18 years after giving birth to a daughter with the classical features of campomelic dysplasia. 2The daughter had shortening of all four limbs, tibial bowing, with skin dimpling over the apex of each tibia. There was bilateral talipes equinovarus and relative macrocephaly (head circumference on the 50th centile, length <3rd centile). She had micrognathia and a depressed nasal bridge. The karyotype was normal female. She had the classical radiological features of campomelic dysplasia with hypoplastic scapulae and absent pedicles in the mid-thoracic region, 11 pairs of ribs, shortening of the long bones with bowing, narrow iliac bones with dislocation of the hips, short first metacarpals, and short phalanges in the hands and feet.2 She died of respiratory problems in the neonatal period.At that time her mother was examined and found to have some skeletal abnormalities. She was below the 3rd centile for height (1.5 m) with a flat face, long philtrum, depressed nasal bridge, small mouth, and micrognathia (fig 1). A right fibula osteotomy was required at the age of 11 years because of a 4 cm asymmetry of her lower limbs. The halluces on both sides were short. Both thumbs and little fingers were short and the nails were hypoplastic. She had conductive hearing loss of the left ear and was myopic. Intelligence was normal but seizures began at the age of 13 requiring treatment with sodium valproate. Radiographs showed a small left iliac bone with non-ossification of the inferior pubic rami and short ischia on both sides, hypoplastic scapulae, 11 pairs of ribs, short first metacarpals, short middle phalanges of the index and little fingers, and thoracic scoliosis. The patellae were small and there was mild bowing of the tibia (see fig 1A and ). Mutation analysis of SOX9 confirmed deletion at C155 resulting in a fr...
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