UMLS:C0011849 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011849 (diabetes)
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Prader-Willi syndrome (PWS) is a genetic disorder characterized by short stature, an insatiable appetite resulting in progressive obesity, hypotonia, and hypogonadism. Many of these symptoms suggest a hypothalamic dysfunction. In fact, reduced growth hormone (GH) secretion and low insulin-like growth factor (IGF- I) are shown in PWS resembling the GH deficient state. The GH treatment of patients with PWS are effective on growth and body composition with decreasing in body fat mass and increasing in body muscle mass, resulting in improvement of respiratory function and bone mineral density. The important advance effects reported during GH treatment of patients with PWS are diabetes mellitus and respiratory dysfunction was recently reported. It is very important that GH should be used with another treatment such as diet therapy, and with only this way GH can play an important role among the overall treatments of PWS.
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PMID:[GH therapy in Prader-Willi syndrome]. 1577 50

Insmed is developing mecasermin rinfabate, a recombinant complex of insulin-like growth factor-I (rhIGF-I) and binding protein-3 (rhIGFBP-3) [insulin-like growth factor-I/insulin-like growth factor binding protein-3, rhIGF-I/rhIGFBP-3, SomatoKine], for a number of metabolic and endocrine indications. In the human body, IGF-I circulates in the blood bound to a binding protein-3 (IGFBP-3), which regulates the delivery of IGF-I to target tissues, and particular proteases clip them apart in response to stresses and release IGF-I as needed. IGF-I, a naturally occurring hormone, is necessary for normal growth and metabolism. For the treatment of IGF-I deficiency, it is desirable to administer IGF-I bound to IGFBP-3 to maintain the normal equilibrium of these proteins in the blood. Mecasermin rinfabate (rhIGF-I/rhIGFBP-3) mimics the effects of the natural protein complex in the bloodstream and would augment the natural supply of these linked compounds. The most advanced indication in development of mecasermin rinfabate is the treatment of severe growth disorders due to growth hormone insensitivity syndrome (GHIS), also called Laron syndrome. GHIS is a genetic condition in which patients do not produce adequate quantities of IGF because of a failure to respond to the growth hormone signal. This results in a slower growth rate and short stature. Mecasermin rinfabate also has potential as replacement therapy for IGF-I, which may become depleted in indications such as major surgery, organ damage/failure, traumatic injury, cachexia and severe burn trauma. It also has potential for the treatment of osteoporosis. Mecasermin rinfabate was developed by Celtrix using its proprietary recombinant protein production technology. Subsequently, Celtrix was acquired by Insmed Pharmaceuticals on 1 June 2000. Insmed and Avecia of the UK have signed an agreement for manufacturing mecasermin rinfabate and its components, rhIGF-1 and rhIGFBP-3. CGMP clinical production of mecasermin rinfabate and its components will be carried out in Avecia's Advanced Biologics Centre, Billingham, UK, which manufactures recombinant-based medicines and vaccines at the capacity of up to 1000L. In April 2004, Insmed announced that it acquired a lease to operate the manufacturing facility formerly operated by Baxter for the commercial production of SomatoKine in Boulder, CO, USA. With the two manufacturing facilities for SomatoKine, Insmed plans to meet the development and commercial demands for the product over the next several years. In its 2003 Form-10K, Insmed announced plans to conduct comparative studies with the previously used drug substance and the new substance produced by Avecia. The comparative data will be included in the regulatory filing for mecasermin rinfabate. Mecasermin rinfabate was originally licensed to Welfide for Japan. On 1 October 2001, Welfide Corporation merged with Mitsubishi-Tokyo Pharmaceuticals to form Mitsubishi Pharma Corporation. The new company is a subsidiary of Mitsubishi Chemical. In October 2004, Insmed announced that Tzamal Pharma has been granted exclusive distribution and marketing rights for mecasermin rinfabate in certain Middle Eastern territories including Israel. Tzamal Pharma also acquired exclusive rights to Insmed's named patient programme for the agent in these territories. Tzamal Pharma intends to begin the appropriate registration activities for mecasermin rinfabate in the treatment of children with growth hormone-insensitivity syndrome. This pivotal, 12-month, multicentre, open-label trial in 30 children with GHIS was initiated in June 2003 and was designed to evaluate the safety and efficacy of the agent in prepubescent children with GHIS. The 6-month endpoint data analysis showed that mecasermin rinfabate given as a once-daily injection was safe and well tolerated. The agent demonstrated a significant increase in height velocity in children with GHIS similar to that observed by Pfizer in their pivotal study with twice-daily injections of rhIGF-I. The full results from the pivotal trial are expected in 2005. In April 2003 Insmed initiated a named patient programme in Europe that will make available mecasermin rinfabate for the treatment of GHIS-Laron syndrome. The treatment of patients was initiated in Scandinavia, with authorisation pending in several other European countries. Mecasermin rinfabate will be made available to those GHIS patients who, in the opinion of their doctor, may benefit from IGF-I therapy. At precommercial scale quantities, the drug will be available on a limited basis.A phase II dose-ranging study in children with GHIS was completed at Saint Bartholomew's and the Royal London School of Medicine, London, UK. A single dose of mecasermin rinfabate delivered the same amount of IGF-1 as two daily injections of unbound IGF-1. No adverse events were reported. Insmed has acquired an exclusive licence to Pharmacia's regulatory filings concerning yeast-derived insulin-like growth factor 1 (IGF-1). These filings were used by Pharmacia to receive marketing approvals in several European countries and also in the IND application with the US FDA. Insmed believes that this licence will facilitate the development of mecasermin rinfabate for the treatment of children with GHIS. In January 2003, Insmed announced positive results from a double-blind, placebo-controlled, dose-ranging study of mecasermin rinfabate in adolescent patients with type 1 diabetes receiving insulin therapy. The study was conducted at the University of Cambridge, Cambridge, UK, under supervision of Prof. D. Dunger. The researchers from The Robarts Research Institute and the University of Western Ontario, Canada (leading investigator T.L. Delovitch, the Sheldon H. Weinstein scientist in Diabetes at the University of Western Ontario) have found that mecasermin rinfabate complex was significantly more effective than IGF-1 in reducing the severity of insulitis, beta cell destruction and delaying the onset of type 1 diabetes. The study was supported by grants from Canadian Institutes of Health and the Juvenile Diabetes Research Foundation. Insmed plans to initiate large-scale phase II clinical studies in this indication. At the BIO 2004 Annual International Convention (BIO-2004) in June 2004, Insmed announced that it has received a grant from the US National Institutes of Health (NIH)/Muscular Dystrophy Association (MDA) worth USD $6.5 million to investigate the efficacy of mecasermin rinfabate for the treatment of myotonic dystrophy. It has also been granted orphan drug status for the treatment of GHIS-Laron syndrome in the US and Europe. In December 2003, Insmed announced that mecasermin rinfabate was designated orphan drug status by the FDA for the treatment of extreme insulin resistance. This provides Insmed with 7 years of market exclusivity following approval of mecasermin rinfabate for this indication. Insmed has received orphan drug designation for mecasermin rinfabate in the treatment of extreme insulin resistance in Europe (October 2004). In November 2004, Insmed was granted the European patent EP1183042 entitled "Methods for Treating Diabetes". This patent corresponds with the US patent US 6,040,292 also entitled "Methods for Treating Diabetes". Both patents cover type 1 and type 2 diabetes mellitus and insulin resistant diabetes including type A insulin resistance (the least severe form of extreme insulin resistance syndromes). In January 2004, Insmed obtained a non-exclusive licence to the patents for use of IGF-I for the treatment of extreme or severe insulin-resistant diabetes from Fujisawa Pharmaceutical. Insmed will have worldwide rights in territories (excluding Japan) with existing valid patent claims including the US and Europe. Insmed holds 28 US issued or allowed patents for the composition, production, antibodies and methods of use of mecasermin rinfabate. These US patents expire at various times between the years 2010 and 2019. Insmed through their lawyers filed its defense and counterclaim to the alleged patent infringement brought by Tercica against Insmed in the London High Court of Justice. Insmed asserted that it did not infringe any valid patent claims as none of the claims of the patent were patentable because the subject matter was not new. Insmed also stated that the patent did not involve an inventive step, did not have capability of industrial application and had no clear description of the invention so that invention can be performed by the person skilled in the art. Insmed is seeking revocation of the patent on these grounds.
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PMID:Mecasermin rinfabate: insulin-like growth factor-I/insulin-like growth factor binding protein-3, mecaserimin rinfibate, rhIGF-I/rhIGFBP-3. 1577 6

Branched-chain amino acids (BCAAs) influence brain function by modifying large, neutral amino acid (LNAA) transport at the blood-brain barrier. Transport is shared by several LNAAs, notably the BCAAs and the aromatic amino acids (ArAAs), and is competitive. Consequently, when plasma BCAA concentrations rise, which can occur in response to food ingestion or BCAA administration, or with the onset of certain metabolic diseases (e.g., uncontrolled diabetes), brain BCAA concentrations rise, and ArAA concentrations decline. Such effects occur acutely and chronically. Such reductions in brain ArAA concentrations have functional consequences: biochemically, they reduce the synthesis and the release of neurotransmitters derived from ArAAs, notably serotonin (from tryptophan) and catecholamines (from tyrosine and phenylalanine). The functional effects of such neurochemical changes include altered hormonal function, blood pressure, and affective state. Although the BCAAs thus have biochemical and functional effects in the brain, few attempts have been made to characterize time-course or dose-response relations for such effects. And, no studies have attempted to identify levels of BCAA intake that might produce adverse effects on the brain. The only "model" of very high BCAA exposure is a very rare genetic disorder, maple syrup urine disease, a feature of which is substantial brain dysfunction but that probably cannot serve as a useful model for excessive BCAA intake by normal individuals. Given the known biochemical and functional effects of the BCAAs, it should be a straightforward exercise to design studies to assess dose-response relations for biochemical and functional effects and, in this context, to explore for adverse effect thresholds.
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PMID:Branched-chain amino acids and brain function. 1593 Apr 66

The remarkable achievements in human genetics over the years have been due to technological advances in gene mapping and in statistical methods that relate genetic variants to disease. Nearly every Mendelian genetic disorder has now been mapped to a specific gene or set of genes, but these discoveries have been limited to high-risk, variant alleles that segregate in rare families. With a working draft of the human genome now in hand, the availability of high-throughput genotyping, a plethora of genetic markers, and the development of new analytical methods, scientists are now turning their attention to common complex disorders such as diabetes, obesity, hypertension, and Alzheimer disease. In this issue, the JCI provides readers with a series dedicated to complex genetic disorders, offering a view of genetic medicine in the 21st century.
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PMID:Mapping the new frontier: complex genetic disorders. 1593 74

Prader-Willi syndrome is a complex genetic disorder with a characteristic cognitive, behavioral, and endocrinologic phenotype. Obesity, partial growth hormone (GH) secretion, and hypogonadism are common. Results of several somatropin (GH therapy) studies in children with Prader-Willi syndrome have shown improvement in growth, body composition, physical strength, and agility. GH deficiency in adults without Prader-Willi syndrome is associated with abdominal obesity, insulin resistance, and an unfavorable lipid profile, and the partial state of GH deficiency seen in Prader-Willi syndrome thus renders these patients exposed to a lifelong risk of metabolic diseases. The nongrowth effects of somatropin in children with Prader-Willi syndrome have directed interest towards adults in preventing long-term consequences of GH deficiency, but the potential impact of somatropin therapy in adults with Prader-Willi syndrome is not known in detail. To date, only one study has been published. In this study, 17 patients (9 men and 8 women) with a mean age of 25 years and a mean body mass index of 35 +/- 3.2 kg/m2 were examined. Eleven had the Prader-Willi syndrome genotype. They were treated with somatropin (Genotropin) for 12 months after an initial placebo-controlled period of 6 months. Compared with placebo, somatropin increased insulin-like growth factor-1 levels (p < 0.01) and decreased body fat (p = 0.04). During the 12-month period with somatropin therapy, the mean reduction in body fat was 2.5% (p < 0.01), concomitant with a mean increase in lean body mass of 2.2kg (p < 0.05). Lipid profiles were normal in most patients before treatment and did not change. The oral glucose tolerance test was impaired in one patient at study start and in five patients at 12 months. No patients developed diabetes mellitus. Furthermore, insulin levels remained unchanged, and estimation of insulin resistance by homeostasis model assessment did not disclose any change. Transient adverse effects attributed to water retention occurred in three patients. In conclusion, the one published study of somatropin therapy in adults with Prader-Willi syndrome showed beneficial effects on body composition without pronounced adverse effects. However, further studies are required to establish the definite role and optimal dosage of somatropin, as well as long-term effects, in adults with Prader-Willi syndrome.
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PMID:Somatropin therapy in adults with Prader-Willi syndrome. 1602 11

In neonatal diabetes mellitus (NDM), a rare genetic disorder, insulin therapy is required but the management is difficult. Frequent blood glucose determinations are necessary in most cases. Microdialysis subcutaneous glucose monitoring (MSGM) is feasible in neonates and has been proposed to reduce painful blood sampling and blood loss. We have applied long-term MSGM to a small-for-date female newborn with transient NDM. We found a good correlation of subcutaneous and blood glucose concentration over a wide range of values. MSGM enabled a reduction in blood glucose determinations during optimization of intravenous insulin treatment and initiation of continuous subcutaneous insulin infusion. We conclude that long-term MSGM is feasible and may reduce painful blood sampling and blood loss in NDM. Furthermore, long-term MSGM may hold a potential for avoiding hypoglycemic episodes and earlier discharge.
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PMID:Use of long-term microdialysis subcutaneous glucose monitoring in the management of neonatal diabetes. A first case report. 1616 71

Turner syndrome is a common genetic disorder associated with abnormalities of the X chromosome and occurs in about 50 per 100,000 liveborn girls. It is associated with reduced adult height, gonadal dysgenesis and thus insufficient circulating levels of female sex steroids and infertility. Morbidity and mortality are increased throughout the lifespan. The average intellectual performance is within the normal range. A number of recent clinical studies have given new insight particularly into the adult phase of Turner syndrome. Treatment with growth hormone during childhood and adolescence enables a considerable gain in adult height. In most cases puberty has to be induced and female sex hormone replacement therapy is given during adulthood. Type 2 diabetes is often seen, and hypertension and associated cardiovascular disorders are frequent. The proper treatments of these disorders have not been firmly established. Since the risk of cardiovascular and endocrinological disease is clearly elevated, proper care during adulthood is crucial. Cognition and social functioning are altered in Turner syndrome.
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PMID:Turner syndrome in adulthood. 1628 80

Excessive body iron or iron overload occurs under conditions such as primary (hereditary) hemochromatosis and secondary iron overload (hemosiderosis), which are reaching epidemic levels worldwide. Primary hemochromatosis is the most common genetic disorder with an allele frequency greater than 10% in individuals of European ancestry, while hemosiderosis is less common but associated with a much higher morbidity and mortality. Iron overload leads to iron deposition in many tissues especially the liver, brain, heart and endocrine tissues. Elevated cardiac iron leads to diastolic dysfunction, arrhythmias and dilated cardiomyopathy, and is the primary determinant of survival in patients with secondary iron overload as well as a leading cause of morbidity and mortality in primary hemochromatosis patients. In addition, iron-induced cardiac injury plays a role in acute iron toxicosis (iron poisoning), myocardial ischemia-reperfusion injury, Friedreich ataxia and neurodegenerative diseases. Patients with iron overload also routinely suffer from a range of endocrinopathies, including diabetes mellitus and anterior pituitary dysfunction. Despite clear connections between elevated iron and clinical disease, iron transport remains poorly understood. While low-capacity divalent metal and transferrin-bound transporters are critical under normal physiological conditions, L-type Ca2+ channels (LTCC) are high-capacity pathways of ferrous iron (Fe2+) uptake into cardiomyocytes especially under iron overload conditions. Fe2+ uptake through L-type Ca2+ channels may also be crucial in other excitable cells such as pancreatic beta cells, anterior pituitary cells and neurons. Consequently, LTCC blockers represent a potential new therapy to reduce the toxic effects of excess iron.
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PMID:Role of L-type Ca2+ channels in iron transport and iron-overload cardiomyopathy. 1660 32

Carnitine palmitoyltransferases 1 and 2 (CPTs) facilitate the import of long-chain fatty acids into mitochondria. Modulation of the catalytic activity of the CPT system is currently under investigation for the development of novel drugs against diabetes mellitus. We report here the 1.6 A resolution structure of the full-length mitochondrial membrane protein CPT-2. The structure of CPT-2 in complex with the generic CPT inhibitor ST1326 ([R]-N-[tetradecylcarbamoyl]-aminocarnitine), a substrate analog mimicking palmitoylcarnitine and currently in clinical trials for diabetes mellitus treatment, was solved at 2.5 A resolution. These structures of CPT-2 provide insight into the function of residues involved in substrate binding and determination of substrate specificity, thereby facilitating the rational design of antidiabetic drugs. We identify a sequence insertion found in CPT-2 that mediates membrane localization. Mapping of mutations described for CPT-2 deficiency, a hereditary disorder of lipid metabolism, implies effects on substrate recognition and structural integrity of CPT-2.
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PMID:The crystal structure of carnitine palmitoyltransferase 2 and implications for diabetes treatment. 1661 1

Originally regarded as a rare affliction notable for its distinctive evolution to "bronze diabetes," hereditary hemochromatosis is now recognized as the most common genetic disorder in populations of European ancestry. Recent advances in our understanding of iron metabolism, the identification of the gene responsible for hemochromatosis, and large epidemiologic studies have changed the diagnostic approach toward patients with hereditary hemochromatosis and other forms of iron overload. This article reviews the pathophysiology, epidemiology, clinical features, diagnostic testing, and management of hemochromatosis for the primary care provider.
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PMID:Revisiting hereditary hemochromatosis: current concepts and progress. 1665 Oct 49

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