Bovine protoporphyria: documentation of autosomal recessive inheritance and comparison with the human disease through measurement of heme synthase activity.

Protoporphyria is an autosomal dominant disease in man in which protoporphyrin accumulated because of a defect in heme synthase (ferrochelatase) activity. A disease has been described in cattle that has the same manifestations as does the human disease. We measured heme synthase activity in sonicates of cultured skin fibroblasts and whole liver homogenates from animals with protoporphyria, their unaffected parents, and normal cattle in order to examine the mode of inheritance and compare it with human protoporphyria. The mean activity (+/- SEM) in fibroblasts from the three groups was 2.0 +/- 0.4, 47 +/- 12, and 149 +/- 10 pmol heme formed/mg protein per hr, respectively, consistent with autosomal recessive inheritance. Similarly, the levels of heme synthase activity in livers of the parents were intermediate to those of normal animals and of animals with protoporphyria. When compared with normal human fibroblasts and liver, the specific activity of heme synthase in normal bovine tissue was significantly higher. These studies indicate that manifestations of protoporphyria do not occur in cattle unless the animal is homozygous for the gene defect, whereas in humans, the heterozygous condition is sufficient. This is probably because the specific activity of heme synthase in cells of heterozygous animals is not reduced to a level that significantly alters heme metabolism.     

Systematic analysis of molecular defects in the ferrochelatase gene from patients with erythropoietic protoporphyria.

Erythropoietic protoporphyria (EPP; MIM 177000) is an inherited disorder caused by partial deficiency of ferrochelatase (FECH), the last enzyme in the heme biosynthetic pathway. In EPP patients, the FECH deficiency causes accumulation of free protoporphyrin in the erythron, associated with a painful skin photosensitivity. In rare cases, the massive accumulation of protoporphyrin in hepatocytes may lead to a rapidly progressive liver failure. The mode of inheritance in EPP is complex and can be either autosomal dominant with low clinical penetrance, as it is in most cases, or autosomal recessive. To acquire an in-depth knowledge of the genetic basis of EPP, we conducted a systematic mutation analysis of the FECH gene, following a procedure that combines the exon-by-exon denaturing-gradient-gel-electrophoresis screening of the FECH genomic DNA and direct sequencing. Twenty different mutations, 15 of which are newly described here, have been characterized in 26 of 29 EPP patients of Swiss and French origin. All the EPP patients, including those with liver complications, were heterozygous for the mutations identified in the FECH gene. The deleterious effect of all missense mutations has been assessed by bacterial expression of the respective FECH cDNAs generated by site-directed mutagenesis. Mutations leading to a null allele were a common feature among three EPP pedigrees with liver complications. Our systematic molecular study has resulted in a significant enlargement of the mutation repertoire in the FECH gene and has shed new light on the hereditary behavior of EPP.     

Jacobsen syndrome

Erythropoietic protoporphyria (EPP) is an inherited disorder of the haem metabolic pathway characterised by accumulation of protoporphyrin in blood, erythrocytes and tissues, and cutaneous manifestations of photosensitivity. EPP has been reported worldwide, with prevalence between 1:75,000 and 1:200,000. It usually manifests in early infancy upon the first sun exposures. EPP is characterised by cutaneous manifestations of acute painful photosensitivity with erythema and oedema, sometimes with petechiae, together with stinging and burning sensations upon exposure to sunlight, without blisters. These episodes have a variable severity depending on the exposure duration and may result in chronic permanent lesions on exposed skin. As protoporphyrin is a lipophilic molecule that is excreted by the liver, EPP patients are at risk of cholelithiasis with obstructive episodes, and chronic liver disease that might evolve to rapid acute liver failure. In most patients, EPP results from a partial deficiency of the last enzyme of the haem biosynthetic pathway, ferrochelatase, EC 4.99.1.1/FECH (encoded by the FECH gene). EPP appears to be inherited as an autosomal dominant disease, the clinical expression of which is modulated by the presence of the hypomorphic FECH IVS3-48C allele trans, but recessive inheritance with two mutated FECH alleles has also been described. In about 2% of patients, overt disease was recently shown to be caused by gain-of-function mutations in the erythroid-specific aminolevulinic acid synthase 2 (ALAS2/ALAS, EC 2.3.1.27) gene and named X-linked dominant protoporphyria. Diagnosis is established by finding increased levels of protoporphyrin in plasma and red blood cells, and detection of a plasma fluorescence peak at 634 nm. Investigations for hepatic involvement, ferrochelatase activity level, genetic analysis (FECH mutations, presence of the hypomorphic FECH IVS3-48C allele trans and ALAS2 mutations) and family studies are advisable. Differential diagnosis includes phototoxic drug reactions, hydroa vacciniforme, solar urticaria, contact dermatitis, angio-oedema and, in some cases, other types of porphyria. Management includes avoidance of exposure to light, reduction of protoporphyrin levels and prevention of progression of possible liver disease to liver failure. As the major risk in EPP patients is liver disease, a regular follow-up of hepatic involvement is essential. Sequential hepatic and bone marrow transplantation should be considered as a suitable treatment for most severe cases of EPP with hepatic involvement. EPP is a lifelong disorder whose prognosis depends on the evolution of the hepatic disease. However, photosensitivity may have a significant impact on quality of life of EPP patients.     

The NDUFS4 nuclear gene of complex I of mitochondria and the cAMP cascade

Results of studies on the role of the 18 kDa (IP) polypeptide subunit of complex I, encoded by the nuclear NDUFS4 gene, in isolated bovine heart mitochondria and human and murine cell cultures are presented.The mammalian 18 kDa subunit has in the carboxy-terminal sequence a conserved consensus site (RVS), which in isolated mitochondria is phosphorylated by cAMP-dependent protein kinase (PKA). The catalytic and regulatory subunits of PKA have been directly immunodetected in the inner membrane/matrix fraction of mammalian mitochondria. In the mitochondrial inner membrane a PP2Cgamma-type phosphatase has also been immunodetected, which dephosphorylates the 18 kDa subunit, phosphorylated by PKA. This phosphatase is Mg(2+)-dependent and inhibited by Ca(2+). In human and murine fibroblast and myoblast cultures "in vivo", elevation of intracellular cAMP level promotes phosphorylation of the 18 kDa subunit and stimulates the activity of complex I and NAD-linked mitochondrial respiration.Four families have been found with different mutations in the cDNA of the NDUFS4 gene. These mutations, transmitted by autosomal recessive inheritance, were associated in homozygous children with fatal neurological syndrome. All these mutations destroyed the phosphorylation consensus site in the C terminus of the 18 kDa subunit, abolished cAMP activation of complex I and impaired its normal assembly.     

An integrated radiation hybrid map of bovine chromosome 18 that refines a critical region associated with multiple ocular defects in cattle

Congenital multiple ocular defects (MOD) of Japanese black cattle is a hereditary ocular disorder with an autosomal recessive mode of inheritance showing developmental defects of the lens, retina and iris, persistent embryonic eye vascularization and microphthalmia. The MOD locus has been mapped by linkage analysis to a 6.6-cM interval on the proximal end of bovine chromosome 18, which corresponds to human chromosome 16q and mouse chromosome 8. To refine the MOD region in cattle, we constructed an integrated radiation hybrid (RH) map of the proximal region of bovine chromosome 18, which consisted of 17 genes and 10 microsatellite markers, using the SUNbRH7000 panel. Strong conservation of gene order was found among the corresponding chromosomal regions in cattle, human and mouse. The MOD-critical region was fine mapped to a 59.5-cR region that corresponds to a 6.3-Mb segment of human chromosome 16 and a 4.8-Mb segment of mouse chromosome 8. Several positional candidate genes, including FOXC2 and USP10, were identified in this region.     

Linkage of early-onset osteoarthritis and chondrocalcinosis to human chromosome 8q.

Calcium pyrophosphate-deposition disease (CPDD), also called "chondrocalcinosis" or "pseudogout," is a disorder characterized by the deposition of calcium-containing crystals in joint tissue, which leads to arthritis-like symptoms. The presence of these crystals in joint tissue is a common finding in the elderly, and, in this population, there is a poor correlation with joint pain. In contrast, early-onset CPDD has been described in several large families in which the disease progresses to severe degenerative osteoarthritis (OA). In these families, an autosomal dominant mode of inheritance is observed, with an age at onset between the 2d and 5th decades of life. In this report, we describe a large New England family with early-onset CPDD and severe degenerative OA. We found genetic linkage between the disease in this family and chromosome 8q, with a multipoint lod score of 4.06. These results suggest that a defective gene at this location causes the disease in this family.     

Uroporphyrinogen III cosynthetase in asymptomatic carriers of congenital erythropoietic porphyria

Mean activity of the enzyme uroporphyrinogen III cosynthetase in hemolysates from five asymptomatic carriers of bovine erythropoietic porphyria was intermediate to the means of the activities in normal controls and affected animals. Similarly, mean cosynthetase activity in hemolysates from eight presumed carriers of human congenital erythropoietic porphyria was lower than the mean for 38 nonporphyric individuals and higher than the activity in hemolysates from patients. These results are consistent with the known autosomal recessive mode of inheritance of the disorder in cattle and the presumed autosomal recessive inheritance in man. The activity of cosynthetase is higher in young red cells than in older ones, which explains the relatively high enzyme activities in blood from human patients with nonporphyric hemolytic disorders accompanied by reticulocytosis. It also explains why cosynthetase activity is higher in newborn porphyric calves than in older porphyric animals, because the former have a period of accelerated erythropoiesis and a high percentage of very young red cells in the circulation.Supported in part by U.S. Public Health Service Grants NB-05367 and AM-10858.     

Physical maps of 4p16.3, the area expected to contain the Huntington disease mutation

The gene for Huntington disease, a neurodegenerative disorder with autosomal dominant inheritance, has been localized to the terminal portion of the short arm of human chromosome 4 (4p16.3) by linkage analysis. Since eventual isolation of the gene requires the application of high-resolution genetic analysis coupled with long-range DNA mapping and cloning techniques, we have constructed a physical map of the chromosomal region 4p16.3 using more than 20 independently derived probes. We have grouped these markers into three clusters which have been ordered and oriented by genetic and somatic cell genetic mapping information. The mapped region extends from D4S10 (G8) toward the telomere and covers minimally 5 Mb.     

Pathenogenesis and Therapy of Liver Disease in Protoporphyria

Protoporphyria is an inherited disorder in man characterized by the overproduction of protoporphyrin, a compound that is excreted by the liver. Hepatobiliary disease may occur in protoporphyria, and several cases have been reported in which death was due to liver disease. Based on the histological evaluation of liver biopsy specimens from 18 patients, 6 of whom died with cirrhosis and liver failure, we speculate that liver disease in this condition is caused by protoporphyrin deposits in hepatobiliary structures. These deposits are composed of crystals and have a characteristic birefringence when examined by polarization microscopy.One patient with early liver damage was given cholestyramine and vitamin E in an attempt to reduce the amount of protoporphyrin which the liver excreted daily. Liver function tests returned to normal, and red cell and plasma protoporphyrin levels decreased. A repeat liver biopsy after one year of therapy showed healing, with decrease of the protoporphyrin deposits.Liver disease in protoporphyria may be treated by directing therapy toward the metabolic abnormality.     

The mutation of Pro789 to Leu reduces the activity of the fast-twitch skeletal muscle sarco(endo)plasmic reticulum Ca2+ ATPase (SERCA1) and is associated with Brody disease

Brody disease is a rare inherited disorder of fast-twitch skeletal muscle function and is characterized by a lifelong history of exercise-induced impairment of skeletal muscle relaxation, stiffness, and cramps. The autosomal recessive inheritance of mutations in ATP2A1, the gene encoding SERCA1, which is the fast-twitch skeletal muscle sarcoplasmic reticulum Ca2+ ATPase, has been associated with Brody disease in three of six Brody families in which ATP2A1 has been sequenced. In the present analysis of the ATP2A1 gene in four unrelated families with autosomal recessive inheritance of Brody disease, three mutations were found in two families, leading to premature stop codons and truncated SERCA1. In a third family, the homozygous substitution of T for C2366 led to the missense mutation of Pro789 to Leu. The Pro789 to Leu mutant was readily expressed in HEK-293 cells, but it demonstrated an almost complete loss of Ca2+ transport activity because of reduced Ca2+ affinity. In a fourth family, the heterozygous substitution of T for C2455, mutating Arg819 to Cys, was identified. This mutation was also readily expressed in HEK-293 cells and shown to have near normal Ca2+ transport activity, indicating that it is not causal for Brody disease. These results confirm the genetic heterogeneity of Brody disease and emphasize the importance of a functional test for mutant SERCA1; immunostaining of skeletal muscle to detect the loss of SERCA1a protein is not adequate for the diagnosis of ATP2A1-linked Brody disease.     

Molecular genetics of left ventricular dysfunction

The left ventricle (LV) plays a central role in the maintenance of health of children and adults due to its role as the major pump of the heart. In cases of LV dysfunction, a significant percentage of affected individuals develop signs and symptoms of congestive heart failure (CHF), leading to the need for therapeutic intervention. Therapy for these patients include anticongestive medications and, in some, placement of devices such as aortic balloon pump or left ventricular assist device (LVAD), or cardiac transplantation. In the majority of patients the etiology is unknown, leading to the term idiopathic dilated cardiomyopathy (IDC). During the past decade, the basis of LV dysfunction has begun to unravel. In approximately 30-40% of cases, the disorder is inherited; autosomal dominant inheritance is most common (although X-linked, autosomal recessive and mitochondrial inheritance occurs). In the remaining patients, the disorder is presumed to be acquired, with inflammatory heart disease playing an important role. In the case of familial dilated cardiomyopathy (FDCM), the genetic basis is beginning to unfold. To date, two genes for X-linked FDCM (dystrophin, G4.5) have been identified and four genes for the autosomal dominant form (actin, desmin, lamin A/C, delta-sarcoglycan) have been described. In one form of inflammatory heart disease, coxsackievirus myocarditis, inflammatory mediators and dystrophin cleavage play a role in the development of LV dysfunction. In this review, we will describe the molecular genetics of LV dysfunction and provide evidence for a "final common pathway" responsible for the phenotype.     

Total anonychia congenita: a rare heterogeneic disorder

Total anonychia congenita is a very rare disorder in which all the finger nails and the toenails are absent without significant bone anomalies. This condition is reported to have an autosomal dominant inheritance pattern. There are a variety of syndromes or conditions associated with anonychia congenita. In this study we present a monozygotic twin with isolated anonychia congenita totals. Interestingly there is no family history of anonychia and this condition seems to be caused by a sporadic mutation.     

Characterization of the Gene Encoding Human Sarcolipin (SLN), a Proteolipid Associated with SERCA1: Absence of Structural Mutations in Five Patients with Brody Disease

Sarcolipin (SLN) is a low-molecular-weight protein that copurifies with the fast-twitch skeletal muscle sarcoplasmic reticulum Ca²⁺ATPase (SERCA1). Genomic DNA and cDNA encoding human sarcolipin (SLN) were isolated and characterized and theSLNgene was mapped to chromosome 11q22–q23. Human, rabbit, and mouse cDNAs encode a protein of 31 amino acids. Homology of SLN with phospholamban (PLN) suggests that the first 7 hydrophilic amino acids are cytoplasmic, the next 19 hydrophobic amino acids form a single transmembrane helix, and the last 5 hydrophilic amino acids are lumenal. The cytoplasmic and transmembrane sequences are not well conserved among the three species, but the lumenal sequence is highly conserved. Like SERCA1, SLN is highly expressed in rabbit fast-twitch skeletal muscle, but it is expressed to a lower extent in slow-twitch muscle and to an even lower extent in cardiac muscle, where SERCA2a and PLN are highly expressed. It is expressed in only trace amounts in pancreas and prostate.SLNandPLNgenes resemble each other in having two small exons, with their entire coding sequences lying in exon 2 and a large intron separating the two segments. Brody disease is an inherited disorder of skeletal muscle function, characterized by exercise-induced impairment of muscle relaxation. Mutations in theATP2A1gene encoding SERCA1 have been associated with the autosomal recessive inheritance of Brody disease in three families, but not with autosomal dominant inheritance of the disease. A search for mutations in theSLNgene in five Brody families, four of which were not linked toATP2A1,did not reveal any alterations in coding, splice junction or promoter sequences. The homozygous deletion of C438 in the coding sequence ofATP2A1in Brody disease family 3, leading to a frameshift and truncation following Pro₁₄₇in SERCA1, is the fourthATP2A1mutation to be associated with autosomal recessive Brody disease.     

Genetic diseases of copper metabolism

There are several known examples of mutations which influence copper homeostasis in humans and animals. Pleiotropic effects are observed when the mutant gene disturbs copper flux. In some cases, the mutation alters the level of a specific copper ligand (enzyme) and the clinical consequences are unique. The two most widely studied genetic maladies in humans are Menkes' and Wilson's diseases. Menkes' disease is an X-linked fatal disorder in which copper accumulates in some organs (intestine and kidney) and is low in others (liver and brain). Wilson's disease is an autosomal recessive disorder in which copper accumulates, if untreated, in liver and subsequently in brain and kidney. Pathophysiological consequences of copper deficiency and toxicity characterize these two disorders. Specific mutations of human cuproenzymes include overproduction of copper-zinc superoxide dismutase in Down's syndrome, absence of tyrosinase in albinism, hereditary mitochondrial myopathy due to reduction in cytochrome c oxidase, and altered lysyl oxidase in X-linked forms of cutis laxa and Ehlers-Danlos syndrome. Mutations altering copper metabolism are also known in animals. Several murine mutants have been studied. The most extensively investigated mutants are the mottled mice, in particular brindled mice, which have a mutation analogous to that of Menkes' disease. Another recently described murine mutation is toxic milk (tx) an autosomal recessive disorder that is characterized by copper accumulation in liver. Two other mutants, crinkled and quaking, were once thought to exhibit abnormal copper metabolism. Recent data has not confirmed this. A mutation in Bedlington terriers has been described which is very similar to Wilson's disease.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cloning of bovine LYST gene and identification of a missense mutation associated with Chediak-Higashi syndrome of cattle

An inheritable bleeding disorder with light coat color caused by an autosomal recessive gene has been reported in a population of Japanese black cattle. The disease has been diagnosed as Chediak-Higashi Syndrome (CHS) of cattle which correspond to a human inheritable disorder caused by mutation in LYST gene. To characterize the molecular lesion causing CHS in cattle, cDNAs encoding bovine LYST were isolated from a bovine brain cDNA library. The nucleotide and deduced amino acid sequences of bovine LYST had 89.6 and 90.2% identity with those of the human LYST gene, respectively. In order to identify the mutation within the LYST gene causing CHS in cattle, cDNA fragments of the LYST gene were amplified from an affected animal by RT-PCR and their nucleotide sequences were completely determined. Notably, a nucleotide substitution of A to G transition, resulting in an amino acid substitution of histidine to arginine (H2015R) was identified in the affected animal. The presence of the substitution was completely corresponding with the occurrence of the CHS phenotype among 105 members of pedigrees of the Japanese black cattle and no cattle of other populations had this substitution. These findings strongly suggested that H2015R is the causative mutation in CHS of Japanese black cattle. Received: 25 May 1999 / Accepted: 26 July 1999     

Parkin,alpha-synuclein and other molecular aspects of Parkinson's disease

Parkinson's disease is a neurodegenerative disorder characterized by the progressive degeneration of the dopaminergic nigrostriatal pathway, and the presence of Lewy bodies. Over the past few years, several genes involved in inherited forms of the disease have been uncovered. In a small number of families with autosomal dominant inheritance, mutations have been identified in the genes encoding a-synuclein and ubiquitin carboxy-terminal hydrolase L1. Mutations in the parkin gene are a common cause of autosomal recessive parkinsonism with early onset, and also account for more than 15% of isolated cases with onset before age 45. The function of Parkin, a ubiquitin ligase involved in the degradation of protein substrates by the ubiquitin-proteasome pathway, highlights that ubiquitin-mediated proteolysis may play an important role in the pathophysiology of idiopathic Parkinson's disease.     

Inheritance of mixed cryoglobulinemia.

This paper describes a family in which 10 members of 3 generations have IgM-IgG cryoglobulinemia. Their pedigree is characteristic of autosomal dominant inheritance. No underlying disease that could account for the cryoglobulinemia has been identified in any patient, and no linkage of the cryoglobulinemia to HLA-A and -B locus haplotypes, blood group antigens, or immunoglobulin Gm allotypes has been detected. The rheumatoid factors of this kindred react with some, but not all, human IgG; however, their rheumatoid factors are not antibodies to any known human Gm or Km allotype. This family demonstrates that "essential" mixed cryoglobulinemia can be inherited, and that the clinical manifestations of an inherited cryoglobulinemia may vary among family members.     

成骨不全的分子机制

成骨不全是一类临床表现为骨质脆弱、易骨折等特征的罕见遗传性疾病.绝大多数（90%以上）显性患者发病系由Ⅰ型前胶原α链COL1A1和COL1A2基因突变引起胶原合成量不足 ,或结构改变.少数隐性患者发病为其他相关基因突变导致胶原翻译后过度修饰、折叠、装配和分泌过程异常.本文就成骨不全发病的遗传学及分子生物学机制作一综述.