Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UMLS:C0024141 (
systemic lupus erythematosus
)
44,322
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We examined 18 families with infants who had neonatal lupus erythematosus (NLE) syndrome to determine whether abnormalities in C4 phenotypes and genotypes were an additional risk factor for this syndrome. Fifteen of 18 mothers of infants with NLE (83%) had C4 null allotypes compared with 36% of population controls (p = less than .001). This increased frequency was due mainly to the presence of C4A null allotypes (11/18, 61%). C4 gene abnormalities, i.e., deletion or probable duplication, were present in 100% (16/16) of mothers of infants with NLE. The most common molecular genetic abnormality in mothers of infants with NLE in this study was deletion of C4A genes. Duplication of C4A and C4B loci was also commonly seen. Duplication of C4A genes was detected only in mothers of infants with complete congenital heart block (CCHB), and duplication of C4B was detected only in mothers of infants with dermatitis. No significant increase in C4A or C4B null allotypes or protein deficiencies was noted in mothers of infants with neonatal
lupus
when compared with anti-Ro(SS-A)-positive mothers delivered of clinically normal infants. Fathers of infants with NLE showed a trend toward increase in C4B null allotypes when compared with population controls (75%, 3/4, p = .06). The two infants with CCHB examined were C4B protein-deficient, in contrast to infants with
lupus
dermatitis, who had frequent C4B null allotypes but no C4B
protein deficiency
. C4B null allotypes were not seen in unaffected siblings of infants with NLE and in only 1 of 7 anti-Ro(SS-A)-positive mothers who delivered clinically normal infants. We conclude that inheritance of C4A null allotypes is not predictive of increased risk of neonatal
lupus
when present in anti-Ro(SS-A)-positive women. Examination of paternal and maternal C4 genes of additional infants with NLE, in particular those with CCHB, and of normal infants born to anti-Ro(SS-A)-positive mothers--and of the normal infants' parents--is required to determine if abnormal C4B genes are a critical factor rendering susceptibility to the NLE syndrome.
...
PMID:Neonatal lupus erythematosus syndrome: analysis of C4 allotypes and C4 genes in 18 families. 154 98
The paper treats the results of the 5-year use of plasma protein heparin cryoprecipitation (selective plasmapheresis) (SPA) in patients with immune complex pathology. The method consists in the removal of fibronectin and bound complement components, cryoglobulins, cryofibrinogen, circulating immune complexes (CIC), and other gross-dispersed proteins in the presence of heparin in the cold. The SPA was applied to 122 patients with immune complex diseases and syndromes. Altogether 1279 procedures were carried out. The method turned out effective in 80% of patients with hemorrhagic vasculitis,
systemic lupus erythematosus
, rheumatoid arthritis, and other types of vasculitis. The changes in the blood serum concentration of immune complexes correlated with the time-course of changes in the clinical and laboratory parameters. The SPA efficacy was in agreement with the reduction in the level of immune complexes. Provided 2-3 procedures were carried out a week, the lowering of the level of immune complexes and other laboratory parameters marking the degree of inflammation could be seen by procedures 4-6. Therefore, to attain a stable clinical effect, its is necessary to perform not less than 6 SPA procedures. It has been demonstrated that SPA can be used an unlimited number of times, for the use of the method does not entail the development of plasma
protein deficiency
. This circumstance is of paramount importance for the treatment of chronic relapsing immune complex diseases.
...
PMID:[The results of 5 years' use of a method for heparin cryoprecipitation of plasma proteins (selective plasmapheresis) in patients with an immune-complex pathology]. 253 73
Muscle may suffer from a number of diseases or disorders, some being fatal to humans and animals. Their management or treatment depends on correct diagnosis. Although no single method may be used to identify all diseases, recognition depends on the following diagnostic procedures: (1) history and clinical examination, (2) blood biochemistry, (3) electromyography, (4) muscle biopsy, (5) nuclear magnetic resonance, (6) measurement of muscle cross-sectional area, (7) tests of muscle function, (8) provocation tests, and (9) studies on protein turnover. One or all of these procedures may prove helpful in diagnosis, but even then identification of the disorder may not be possible. Nevertheless, each of these procedures can provide useful information. Among the most common diseases in muscle are the muscular dystrophies, in which the newly identified muscle protein dystrophin is either absent or present at less than normal amounts in both Duchenne and Becker's muscular dystrophy. Although the identification of dystrophin represents a major breakthrough, treatment has not progressed to the experimental stage. Other major diseases of muscle include the inflammatory myopathies and neuropathies. Atrophy and hypertrophy of muscle and the relationship of aging, exercise, and fatigue all add to our understanding of the behavior of normal and abnormal muscle. Some other interesting related diseases and disorders of muscle include myasthenia gravis, muscular dysgenesis, and myclonus. Disorders of energy metabolism include those caused by abnormal glycolysis (Von Gierke's, Pompe's, Cori-Forbes, Andersen's, McArdle's, Hers', and Tauri's diseases) and by the acquired diseases of glycolysis (disorders of mitochondrial oxidation). Still other diseases associated with abnormal energy metabolism include lipid-related disorders (carnitine and carnitine palmitoyl-transferase deficiencies) and myotonic syndromes (myotonia congenita, paramyotonia congenita, hypokalemic and hyperkalemic periodic paralysis, and malignant hyperexia). Diseases of the connective tissues discussed include those of nutritional origin (scurvy, lathyrism, starvation, and
protein deficiency
), the genetic diseases (dermatosparaxis, Ehlers-Danlos syndrome, osteogenesis imperfecta, Marfan syndrome, homocystinuria, alcaptonuria, epidermolysis bullosa, rheumatoid arthritis in humans, polyarthritis in swine, Aleutian disease of mink, and the several types of
systemic lupus erythematosus
) and the acquired diseases of connective tissues (abnormal calcification, systemic sclerosis, interstitial lung disease, hepatic fibrosis, and carcinomas of the connective tissues). Several of the diseases of connective tissues may prove to be useful models for determining the relationship of collagen to meat tenderness and its other physical properties. Several other promising models for studying the nutrition-related disorders and the quality-related characteristics of meat are also reviewed.
...
PMID:Diseases and disorders of muscle. 839 47
Previous studies on the prevalence of biological abnormalities causing venous thrombosis and the clinical characteristics of thrombotic patients are conflicting. We conducted a prospective study on 2.132 consecutive evaluable patients with venous thromboembolism to determine the prevalence of biological causes. Antithrombin, protein C, protein S, plasminogen and heparin cofactor-II deficiencies, dysfibrinogenemia,
lupus
anticoagulant and antiphospholipid antibodies were investigated. The risk of any of these alterations in patients with familial, recurrent, spontaneous or juvenile venous thrombosis was assessed. The overall prevalence of protein deficiencies was 12.85% (274/2,132) and antiphospholipid antibodies were found in 4.08% (87/2,132). Ten patients (0.47%) had antithrombin deficiency, 68 (3.19%) protein C deficiency, 155 (7.27%) protein S deficiency, 16 (0.75%) plasminogen deficiency, 8 (0.38%) heparin cofactor-II deficiency and 1 had dysfibrinogenemia. Combined deficiencies were found in 16 cases (0.75%). A
protein deficiency
was found in 69 of 303 (22.8%) patients with a family history of thrombosis and in 205/1,829 (11.2%) without a history (crude odds ratio 2.34, 95% CI 1.72-3.17); in 119/665 (17.9%) patients with thrombosis before the age of 45 and 153/1,425 (10.7%) after the age of 45 (crude odds ratio 1.81, 95% CI 1.40-2.35); in 103/616 (16.7%) with spontaneous thrombosis and in 171/1,516 (11.3%) with secondary thrombosis (crude odds ratio 1.58, 95% CI 1.21-2.06); in 68/358 (19.0%) with recurrent thrombosis and in 206/1,774 (11.6%) with a single episode (crude odds ratio 1.78, 95% CI 1.32-2.41). Patients with combined clinical factors had a higher risk of carrying some deficiency. Biological causes of venous thrombosis can be identified in 16.93% of unselected patients. Family history of thrombosis, juvenile, spontaneous and recurrent thrombosis are the main clinical factors which enhance the risk of a deficiency. Laboratory evaluation of thrombotic patients is advisable, especially if some of these clinical factors are present.
...
PMID:Laboratory evaluation and clinical characteristics of 2,132 consecutive unselected patients with venous thromboembolism--results of the Spanish Multicentric Study on Thrombophilia (EMET-Study). 906 91
Hemolytic uremic syndrome (HUS) is related to a renal thrombotic microangiopathy, inducing hypertension and acute renal failure (ARF). Its pathogenesis involves an activation/lesion of microvascular endothelial cells, mainly in the renal vasculature, secondary to bacterial toxins, drugs, or autoantibodies. An overactivation of the complement alternate pathway secondary to a heterozygote deficiency of regulatory proteins (factor H, factor I or MCP) or to an activating mutation of factor B or C3 can also result in HUS. Less frequently, renal microthrombi are due to an acquired or a constitutional deficiency in ADAMTS-13, the protease cleaving von Wilebrand factor. Hemolytic anemia with schistocytes, thrombocytopenia without evidence of disseminated intravascular coagulation, and renal failure are consistently found. In typical HUS, a prodromal diarrhea, with blood in the stools, is observed, related to pathogenic enterobacteria, most frequently E. Coli O157:H7. HUS may also occur in the post partum period, and is then related to a factor H or factor I deficiency. HUS may also occur after various treatments such as mitomycin C, gemcitabine, ciclosporin A, or tacrolimus, and as reported more recently bevacizumab, an anti VEGF antibody. Atypical HUS are not associated with diarrhea, may be sporadic or familial, and can be related to an overactivation of the complement alternate pathway. More recently, some of them have been related to a mutation of thrombomodulin, which also regulates the alternate pathway of complement. In adults, several HUS are encountered in the course of chronic nephropathies: nephroangiosclerosis, chronic glomerulonephritis, post irradiation nephropathy, scleroderma,
disseminated lupus erythematosus
, antiphospholipid syndrome. Overall the prognosis of HUS has improved, with a patient survival greater than 85% at 1 year. Chronic renal failure is observed as a sequella in 20 to 65% of the cases. Plasma infusions and plasma exchanges are effective in most of the cases to treat hemolysis and thrombocytopenia. Steroid therapy is debated, as well as immunosuppressive drugs, including rituximab, in autoimmune forms. A new monoclonal anti-C5 antibody is tested, and seems to be effective in atypical HUS with abnormal complement alternate pathway activation. If terminal renal failure occurs, renal transplantation can be performed but the risk of recurrence, which very low in post infectious forms of HUS, is about 70 to 80% in genetic forms of complement regulatory
protein deficiency
.
...
PMID:[Hemolytic uremic syndrome in adults]. 2039 68
The role of the complement system in mediating human renal disease has long been recognized in immune-complex excess syndromes such as
systemic lupus erythematosus
and in dense deposit disease in which no immunoglobulin (Ig) is present. Over the past 15 years, mutations in complement regulatory genes have been demonstrated to predispose to thrombotic microangiopathies including atypical hemolytic uremic syndrome, C3 and C1q glomerulopathies, and preeclampsia. Excessive complement activation on an endothelial cell, due to either an autoantibody or a regulatory
protein deficiency
, sets up a procoagulant state in these diseases as well as in the antiphospholipid syndrome. Knowledge of the genes involved and the functional consequences of alterations in their structure has led to therapy that blocks complement activation.
...
PMID:Defective complement inhibitory function predisposes to renal disease. 2312 Nov 80
