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Human Disorders (human + disorders)

Distribution by Scientific Domains

Life Sciences	70%
Medical Sciences	23%

Selected Abstracts

Distribution of progesterone receptor immunoreactivity in the midbrain and hindbrain of postnatal rats

DEVELOPMENTAL NEUROBIOLOGY, Issue 12 2008
Princy S. Quadros
Abstract Nuclear steroid hormone receptors are powerful transcription factors and therefore have the potential to influence and regulate fundamental processes of neural development. The expression of progesterone receptors (PR) has been described in the developing forebrain of rats and mice, and the mammalian brain may be exposed to significant amounts of progesterone, either from maternal sources and/or de novo synthesis of progesterone from cholesterol within the brain. The present study examined the distribution of PR immunoreactive (PRir) cells within the midbrain and hindbrain of postnatal rats. The results demonstrate that PR is transiently expressed within the first 2 weeks of life in specific motor, sensory and reticular core nuclei as well as within midbrain dopaminergic cell groups such as the substantia nigra and the ventral tegmental area. Additionally, robust PRir was observed in cells of the lower rhombic lip, a transient structure giving rise to precerebellar nuclei. These results suggest that progestins and progesterone receptors may play a fundamental role in the postnatal development of numerous midbrain and hindbrain nuclei, including some areas implicated in human disorders. Additionally, these findings contribute to the increasing evidence that steroid hormones and their receptors influence neural development in a wide range of brain areas, including many not typically associated with reproduction or neuroendocrine function. © 2008 Wiley Periodicals, Inc. Develop Neurobiol, 2008 [source]

FACS-array gene expression analysis during early development of mouse telencephalic interneurons

DEVELOPMENTAL NEUROBIOLOGY, Issue 4 2008
Eric D. Marsh
Abstract Cortical interneuron dysfunction has been implicated in multiple human disorders including forms of epilepsy, mental retardation, and autism. Although significant advances have been made, understanding the biologic basis of these disorders will require a level of anatomic, molecular, and genetic detail of interneuron development that currently does not exist. To further delineate the pathways modulating interneuron development we performed fluorescent activated cell sorting (FACs) on genetically engineered mouse embryos that selectively express green fluorescent protein (GFP) in developing interneurons followed by whole genome microarray expression profiling on the isolated cells. Bioinformatics analysis revealed expression of both predicted and unexpected genes in developing cortical interneurons. Two unanticipated pathways discovered to be up regulated prior to interneurons differentiating in the cortex were ion channels/neurotransmitters and synaptic/vesicular related genes. A significant association of neurological disease related genes to the population of developing interneurons was found. These results have defined new and potentially important data on gene expression changes during the development of cortical interneurons. In addition, these data can be mined to uncover numerous novel genes involved in the generation of interneurons and may suggest genes/pathways potentially involved in a number of human neurological disorders. © 2008 Wiley Periodicals, Inc. Develop Neurobiol, 2008. [source]

Ghrelin: a new peptide regulating the neurohormonal system, energy homeostasis and glucose metabolism

DIABETES/METABOLISM: RESEARCH AND REVIEWS, Issue 5 2008
Peter Pusztai
Abstract Identification of ghrelin started with the discovery of growth hormone secretagogues, continued with the description of ghrelin receptors and ended with the elucidation of the chemical structure of ghrelin. However, several issues concerning the role of ghrelin in physiological and pathophysiological processes are still under investigation. Most of the ghrelin produced in the body is secreted in the stomach, but it is also expressed in the hypothalamus, pituitary, pancreas, intestine, kidney, heart and gonads. Ghrelin stimulates growth hormone secretion via growth hormone secretagogue receptors. Ghrelin secretion in the stomach depends on both acute and chronic changes in nutritional status and energy balance. Current data support the hypothesis that the stomach, in addition to its important role in digestion, not only influences pituitary hormone secretion but, via ghrelin production, it also sends orexigenic (appetite increasing) signals to hypothalamic nuclei involved in the regulation of energy homeostasis. In addition to these main effects, ghrelin influences insulin secretion and glucose metabolism and it may exert potentially important effects on cardiovascular and gastrointestinal functions. Because of its effects on a large number of physiological functions, ghrelin may be involved in the pathomechanism of several human disorders, including disturbances of appetite, energy homeostasis and glucose metabolism. Further research might lead to a better understanding of the pathophysiology of ghrelin and might provide more effective therapy for the above disorders. Copyright © 2008 John Wiley & Sons, Ltd. [source]

RFT1 deficiency in three novel CDG patients,

HUMAN MUTATION, Issue 10 2009
Wendy Vleugels
Abstract The medical significance of N-glycosylation is underlined by a group of inherited human disorders called Congenital Disorders of Glycosylation (CDG). One key step in the biosynthesis of the Glc3Man9GlcNAc2 -PP-dolichol precursor, essential for N-glycosylation, is the translocation of Man5GlcNAc2 -PP-dolichol across the endoplasmic reticulum membrane. This step is facilitated by the RFT1 protein. Recently, the first RFT1-deficient CDG (RFT1-CDG) patient was identified and presented a severe N-glycosylation disorder. In the present study, we describe three novel CDG patients with an RFT1 deficiency. The first patient was homozygous for the earlier reported RFT1 missense mutation (c.199C>T; p.R67C), whereas the two other patients were homozygous for the missense mutation c.454A>G (p.K152E) and c.892G>A (p.E298,K), respectively. The pathogenic character of the novel mutations was illustrated by the accumulation of Man5GlcNAc2 -PP-dolichol and by reduced recombinant DNase 1 secretion. Both the glycosylation pattern and recombinant DNase 1 secretion could be normalized by expression of normal RFT1 cDNA in the patients' fibroblasts. The clinical phenotype of these patients comprised typical CDG symptoms in addition to sensorineural deafness, rarely reported in CDG patients. The identification of additional RFT1-deficient patients allowed to delineate the main clinical picture of RFT1-CDG and confirmed the crucial role of RFT1 in Man5GlcNAc2 -PP-dolichol translocation. Hum Mutat 30:1,7, 2009. © 2009 Wiley-Liss, Inc. [source]

GENOMIZER: an integrated analysis system for genome-wide association data,

HUMAN MUTATION, Issue 6 2006
Andre Franke
Abstract Genome-wide association analysis appears to be a promising way to identify heritable susceptibility factors for complex human disorders. However, the feasibility of large-scale genotyping experiments is currently limited by an incomplete marker coverage of the genome, a restricted understanding of the functional role of given genomic regions, and the small sample sizes used. Thus, genome-wide association analysis will be a screening tool to facilitate subsequent gene discovery rather than a means to completely resolve individual genetic risk profiles. The validation of association findings will continue to rely upon the replication of "leads" in independent samples from either the same or different populations. Even under such pragmatic conditions, the timely analysis of the large data sets in question poses serious technical challenges. We have therefore developed public-domain software, GENOMIZER, that implements the workflow of an association experiment, including data management, single-point and haplotype analysis, "lead" definition, and data visualization. GENOMIZER (www.ikmb.uni-kiel.de/genomizer) comes with a complete user manual, and is open-source software licensed under the GNU Lesser General Public License. We suggest that the use of this software will facilitate the handling and interpretation of the currently emerging genome-wide association data. Hum Mutat 27(6), 583,588, 2006. © 2006 Wiley-Liss, Inc. [source]

BONE MARROW TRANSFER FROM WILD-TYPE MICE REVERTS THE BENEFICIAL EFFECT OF GENETICALLY MEDIATED IMMUNE DEFICIENCY IN MYELIN MUTANTS

JOURNAL OF THE PERIPHERAL NERVOUS SYSTEM, Issue 1 2002
M Maurer
Inherited demyelinating neuropathies are chronically disabling human disorders caused by various genetic defects, including deletions, single site mutations, and duplications in the respective myelin genes. We have shown in a mouse model of one distinct hereditary demyelinating neuropathy (heterozygous PO-deficiency, PO±) that an additional null mutation in the recombination activating gene-1 (RAG-1--) leads to a substantially milder disorder, indicating a disease modifying role of T-lymphocytes. In the present study, we addressed the role of lymphocytes in the mouse model by reconstituting bone marrow of PO±/RAG-1-- mice with bone marrow from immunocompetent wild-type mice. We compared the pathology and nerve conduction in double mutant mice (PO±/RAG-1-- on a C57BL/6 background) with that in double mutants after receiving a bone marrow transplant. We found that the milder demyelination seen in the lymphocyte-deficient PO±/RAG-1-- mutants was reverted to the more severe pathology by reestablishing a competent immune system by bone marrow transfer. These data corroborate the concept that the immune system contributes substantially to the pathologic process in this mouse model and may open new avenues to ameliorate human hereditary neuropathies by exploiting immunosuppressive treatments. [source]

Tissue culture methods to study neurological disorders: Establishment of immortalized Schwann cells from murine disease models

NEUROPATHOLOGY, Issue 1 2003
Kazuhiko Watabe
Previously, the authors have established spontaneously immortalized cell lines from long-term cultures of normal adult mouse Schwann cells. Establishment of such Schwann cell lines derived from murine disease models may greatly facilitate studies of the cellular mechanisms of their peripheral nervous system lesions in the relevant diseases. Recently, the authors have established immortalized Schwann cell lines derived from Niemann,Pick disease type C mice (NPC; spm/spm) and globoid cell leukodystrophy mice (twitcher). In the present study, long-term cultures were maintained of Schwann cells derived from dorsal root ganglia and consecutive peripheral nerves of another NPC mouse (npcnih/npcnih, npcnih/+), myelin P0 protein-deficient mice (P0,/,, P0+/,) with their wild-type littermates (P0+/+), and neurofibromatosis type 1 gene (NF1)-deficient mice (Nf1Fcr/+) for 8,10 months, and immortalized cell lines from all these animals established spontaneously. These cell lines had spindle-shaped Schwann cell morphology and distinct Schwann cell phenotypes and retained genomic and biochemical abnormalities, sufficiently representing the in vivo pathological features of the mutant mice. These immortalized Schwann cell lines can be useful in studies of nervous system lesions in these mutant mice and relevant human disorders. [source]

Imprinted genes and human disease,

AMERICAN JOURNAL OF MEDICAL GENETICS, Issue 3 2010
Rosanna Weksberg
Abstract This issue of Seminars of Medical Genetics features a series of articles on human disorders caused by the dysregulation of imprinted genes. At the outset, there is a review of the general mechanisms by which genomic imprinting is normally regulated followed by an exploration of the clinical and molecular aspects of human imprinting disorders. As we enter an era of bioinformatics and genome-wide analyses with increasing access to high density microarrays and next generation sequencing, it is becoming apparent that the concept of a single mutation or epimutation leading to a disease is outdated. The role of the clinician will become increasingly important, in concert with these molecular advances, in terms of evaluating phenotypic variation to further our understanding of imprinting disorders. Such investigations will benefit children and families as we become better able to define recurrence risk, predict phenotype, and tailor medical management. © 2010 Wiley-Liss, Inc. [source]

Ciliary biology: Understanding the cellular and genetic basis of human ciliopathies,

AMERICAN JOURNAL OF MEDICAL GENETICS, Issue 4 2009
Magdalena Cardenas-Rodriguez
Abstract Motile cilia have long been known to play a role in processes such as cell locomotion and fluid movement whereas the functions of primary cilia have remained obscure until recent years. To date, ciliary dysfunction has been shown to be causally linked to a number of clinical manifestations that characterize the group of human disorders known as ciliopathies. This classification reflects a common or shared cellular basis and implies that it is possible to associate a series of different human conditions with ciliary dysfunction, which allows gaining insight into the cellular defect in disorders of unknown etiology solely based on phenotypic observations. Furthermore, to date we know that the cilium participates in a number of biological processes ranging from chemo- and mechanosensation to the transduction of a growing list of paracrine signaling cascades that are critical for the development and maintenance of different tissues and organs. Consequently, the primary cilium has been identified as a key structure necessary to regulate and maintain cellular and tissue homeostasis and thus its study is providing significant information to understand the pathogenesis of the different phenotypes that characterize these human conditions. Finally, the similarities between different ciliopathies at the phenotypic level are proving to be due to their shared cellular defect and also their common genetic basis. To this end, recent studies are showing that mutations in a given ciliary gene often appear involved in the pathogenesis of more than one clinical entity, complicating their genetic dissection, and hindering our ability to generate accurate genotype,phenotype correlations. © 2009 Wiley-Liss, Inc. [source]

Liver and kidney disease in ciliopathies,,

AMERICAN JOURNAL OF MEDICAL GENETICS, Issue 4 2009
Meral Gunay-Aygun§
Abstract Hepatorenal fibrocystic diseases (HRFCDs) are among the most common inherited human disorders. The discovery that proteins defective in the autosomal dominant and recessive polycystic kidney diseases (ADPKD and ARPKD) localize to the primary cilia and the recognition of the role these organelles play in the pathogenesis of HRFCDs led to the term "ciliopathies." While ADPKD and ARPKD are the most common ciliopathies associated with both liver and kidney disease, variable degrees of renal and/or hepatic involvement occur in many other ciliopathies, including Joubert, Bardet,Biedl, Meckel,Gruber, and oral,facial,digital syndromes. The ductal plate malformation (DPM), a developmental abnormality of the portobiliary system, is the basis of the liver disease in ciliopathies that manifest congenital hepatic fibrosis (CHF), Caroli syndrome (CS), and polycystic liver disease (PLD). Hepatocellular function remains relatively preserved in ciliopathy-associated liver diseases. The major morbidity associated with CHF is portal hypertension (PH), often leading to esophageal varices and hypersplenism. In addition, CD predisposes to recurrent cholangitis. PLD is not typically associated with PH, but may result in complications due to mass effects. The kidney pathology in ciliopathies ranges from non-functional cystic dysplastic kidneys to an isolated urinary concentration defect; the disorders contributing to this pathology, in addition to ADPKD and ARPKD, include nephronophithisis (NPHP), glomerulocystic kidney disease and medullary sponge kidneys. Decreased urinary concentration ability, resulting in polyuria and polydypsia, is the first and most common renal symptom in ciliopathies. While the majority of ADPKD, ARPKD, and NPHP patients require renal transplantation, the frequency and rate of progression to renal failure varies considerably in other ciliopathies. This review focuses on the kidney and liver disease found in the different ciliopathies. Published 2009 Wiley-Liss, Inc. [source]

Mutations of key hydrophobic surface residues of 11,-hydroxysteroid dehydrogenase type 1 increase solubility and monodispersity in a bacterial expression system

PROTEIN SCIENCE, Issue 7 2009
Alexander J. Lawson
Abstract 11,-Hydroxysteroid dehydrogenase type 1 (11,-HSD1) is a key enzyme in the conversion of cortisone to the functional glucocorticoid hormone cortisol. This activation has been implicated in several human disorders, notably the metabolic syndrome where 11,-HSD1 has been identified as a novel target for potential therapeutic drugs. Recent crystal structures have revealed the presence of a pronounced hydrophobic surface patch lying on two helices at the C-terminus. The physiological significance of this region has been attributed to facilitating substrate access by allowing interactions with the endoplasmic reticulum membrane. Here, we report that single mutations that alter the hydrophobicity of this patch (I275E, L266E, F278E, and L279E in the human enzyme and I275E, Y266E, F278E, and L279E in the guinea pig enzyme) result in greatly increased yields of soluble protein on expression in E. coli. Kinetic analyses of both reductase and dehydrogenase reactions indicate that the F278E mutant has unaltered Km values for steroids and an unaltered or increased kcat. Analytical ultracentrifugation shows that this mutation also decreases aggregation of both the human and guinea pig enzymes, resulting in greater monodispersity. One of the mutants (guinea pig F278E) has proven easy to crystallize and has been shown to have a virtually identical structure to that previously reported for the wild-type enzyme. The human F278E enzyme is shown to be a suitable background for analyzing the effects of naturally occurring mutations (R137C, K187N) on enzyme activity and stability. Hence, the F278E mutants should be useful for many future biochemical and biophysical studies of the enzyme. [source]

Proteomic profiling of animal models mimicking skeletal muscle disorders

PROTEOMICS - CLINICAL APPLICATIONS, Issue 9 2007
Philip Doran
Abstract Over the last few decades of biomedical research, animal models of neuromuscular diseases have been widely used for determining pathological mechanisms and for testing new therapeutic strategies. With the emergence of high-throughput proteomics technology, the identification of novel protein factors involved in disease processes has been decisively improved. This review outlines the usefulness of the proteomic profiling of animal disease models for the discovery of new reliable biomarkers, for the optimization of diagnostic procedures and the development of new treatment options for skeletal muscle disorders. Since inbred animal strains show genetically much less interindividual differences as compared to human patients, considerably lower experimental repeats are capable of producing meaningful proteomic data. Thus, animal model proteomics can be conveniently employed for both studying basic mechanisms of molecular pathogenesis and the effects of drugs, genetic modifications or cell-based therapies on disease progression. Based on the results from comparative animal proteomics, a more informed decision on the design of clinical proteomics studies could be reached. Since no one animal model represents a perfect pathobiochemical replica of all of the symptoms seen in complex human disorders, the proteomic screening of novel animal models can also be employed for swift and enhanced protein biochemical phenotyping. [source]

Mixed-effects Logistic Approach for Association Following Linkage Scan for Complex Disorders

ANNALS OF HUMAN GENETICS, Issue 2 2007
H. Xu
Summary An association study to identify possible causal single nucleotide polymorphisms following linkage scanning is a popular approach for the genetic dissection of complex disorders. However, in association studies cases and controls are assumed to be independent, i.e., genetically unrelated. Choosing a single affected individual per family is statistically inefficient and leads to a loss of power. On the other hand, because of the relatedness of family members, using affected family members and unrelated normal controls directly leads to false-positive results in association studies. In this paper we propose a new approach using mixed-model logistic regression, in which associations are performed using family members and unrelated controls. Thus, the important genetic information can be obtained from family members while retaining high statistical power. To examine the properties of this new approach we developed an efficient algorithm, to simulate environmental risk factors and the genotypes at both the disease locus and a marker locus with and without linkage disequilibrium (LD) in families. Extensive simulation studies showed that our approach can effectively control the type-I error probability. Our approach is better than family-based designs such as TDT, because it allows the use of unrelated cases and controls and uses all of the affected members for whom DNA samples are possibly already available. Our approach also allows the inclusion of covariates such as age and smoking status. Power analysis showed that our method has higher statistical power than recent likelihood ratio-based methods when environmental factors contribute to disease susceptibility, which is true for most complex human disorders. Our method can be further extended to accommodate more complex pedigree structures. [source]

Imprinting Status of G,S, NESP55, and XL,s in Cell Cultures Derived from Human Embryonic Germ Cells: GNAS Imprinting in Human Embryonic Germ Cells

CLINICAL AND TRANSLATIONAL SCIENCE, Issue 5 2009
Janet L. Crane M.D.
Abstract GNAS is a complex gene that through use of alternative first exons encodes signaling proteins G,s and XL,s plus neurosecretory protein NESP55. Tissue-specific expression of these proteins is regulated through reciprocal genomic imprinting in fully differentiated and developed tissue. Mutations in GNAS account for several human disorders, including McCune-Albright syndrome and Albright hereditary osteodystrophy, and further knowledge of GNAS imprinting may provide insights into variable phenotypes of these disorders. We therefore analyzed expression of G,s, NESP55, and XL,s prior to tissue differentiation in cell cultures derived from human primordia germ cells. We found that the expression of G,s was biallelic (maternal allele: 52.6%± 2.5%; paternal allele: 47.2%± 2.5%; p= 0.07), whereas NESP55 was expressed preferentially from the maternal allele (maternal allele: 81.9%± 10%; paternal allele: 18.1%± 10%; p= 0.002) and XL,s was preferentially expressed from the paternal allele (maternal allele: 2.7%± 0.3%; paternal allele: 97.3%± 0.3%; p= 0.007). These results demonstrate that imprinting of NESP55 occurs very early in development, although complete imprinting appears to take place later than 5,11 weeks postfertilization, and that imprinting of XL,s occurs very early postfertilization. By contrast, mprinting of G,s most likely occurs after 11 weeks postfertilization and after tissue differentiation. [source]

Cornelia de Lange syndrome, cohesin, and beyond

CLINICAL GENETICS, Issue 4 2009
J Liu
Cornelia de Lange syndrome (CdLS) (OMIM #122470, #300590 and #610759) is a dominant genetic disorder with multiple organ system abnormalities which is classically characterized by typical facial features, growth and mental retardation, upper limb defects, hirsutism, gastrointestinal and other visceral system involvement. Mutations in three cohesin proteins, a key regulator of cohesin, NIPBL, and two structural components of the cohesin ring SMC1A and SMC3, etiologically account for about 65% of individuals with CdLS. Cohesin controls faithful chromosome segregation during the mitotic and meiotic cell cycles. Multiple proteins in the cohesin pathway are also involved in additional fundamental biological events such as double-strand DNA break repair and long-range regulation of transcription. Moreover, chromosome instability was recently associated with defective sister chromatid cohesion in several cancer studies, and an increasing number of human developmental disorders is being reported to result from disruption of this pathway. Here, we will discuss the human disorders caused by alterations of cohesin function (termed ,cohesinopathies'), with an emphasis on the clinical manifestations of CdLS and mechanistic studies of the CdLS-related proteins. [source]

Human embryo and early fetus research

CLINICAL GENETICS, Issue 2 2006
H Ostrer
Studies of human embryos and fetuses have highlighted developmental differences between humans and model organisms. In addition to describing the normal biology of our own species, a justification in itself, studies of early human development have aided identification of candidate disease genes mapped by positional cloning strategies, understanding pathophysiology, where human disorders are not faithfully reproduced by models in other species, and, more recently, potential therapies based on human embryonic stem and embryonic germ cells. In this article, we review these applications. We also discuss when and how to study human embryo and early fetuses and some of the regulations of this research. [source]

Dopamine and Oxytocin Interactions Underlying Behaviors: Potential Contributions to Behavioral Disorders

CNS: NEUROSCIENCE AND THERAPEUTICS, Issue 3 2010
Tracey A. Baskerville
Dopamine is an important neuromodulator that exerts widespread effects on the central nervous system (CNS) function. Disruption in dopaminergic neurotransmission can have profound effects on mood and behavior and as such is known to be implicated in various neuropsychiatric behavioral disorders including autism and depression. The subsequent effects on other neurocircuitries due to dysregulated dopamine function have yet to be fully explored. Due to the marked social deficits observed in psychiatric patients, the neuropeptide, oxytocin is emerging as one particular neural substrate that may be influenced by the altered dopamine levels subserving neuropathologic-related behavioral diseases. Oxytocin has a substantial role in social attachment, affiliation and sexual behavior. More recently, it has emerged that disturbances in peripheral and central oxytocin levels have been detected in some patients with dopamine-dependent disorders. Thus, oxytocin is proposed to be a key neural substrate that interacts with central dopamine systems. In addition to psychosocial improvement, oxytocin has recently been implicated in mediating mesolimbic dopamine pathways during drug addiction and withdrawal. This bi-directional role of dopamine has also been implicated during some components of sexual behavior. This review will discuss evidence for the existence dopamine/oxytocin positive interaction in social behavioral paradigms and associated disorders such as sexual dysfunction, autism, addiction, anorexia/bulimia, and depression. Preliminary findings suggest that whilst further rigorous testing has to be conducted to establish a dopamine/oxytocin link in human disorders, animal models seem to indicate the existence of broad and integrated brain circuits where dopamine and oxytocin interactions at least in part mediate socio-affiliative behaviors. A profound disruption to these pathways is likely to underpin associated behavioral disorders. Central oxytocin pathways may serve as a potential therapeutic target to improve mood and socio-affiliative behaviors in patients with profound social deficits and/or drug addiction. [source]