BF types and the mode of inheritance of insulin-dependent diabetes mellitus (IDDM)

Insulin-dependent diabetes mellitus (IDDM) has been found to be highly associated with a rare allele of the complement protein, properdin factor B (BF). Assuming that there is a susceptibility gene for IDDM tightly linked to the genetic locus forBF and the major histocompatibility complex (MHC), the distribution of BF types in more than 1100 North American IDDM patients strongly argues for the rejection of dominant, epistatic, and overdominant modes of inheritance. Other evidence suggesting complex modes of inheritance for IDDM is reviewed and it is concluded that our observations and published data are consistent with the idea of susceptibility to IDDM being inherited as a simple autosomal recessive trait. — C4 and C2 types, also linked toBF and theMHC, were investigated too. C4 Fs⁰ was found to be increased in association with BF F1, while C4 f⁰S and C2 B were each found to occur twice as frequently as in a control population and will be of value in defining haplotypes associated with susceptibility to IDDM.     

Idiopathic hemochromatosis: demonstration of homozygous-heterozygous mating by HLA typing of families

Summary In five families with idiopathic (hereditary) hemochromatosis, clinical and biochemical expression of the disease occurred in offspring of probands, suggesting an autosomal dominant mode of inheritance. However, HLA typing of subjects indicated that a homozygous-heterozygous mating almost certainly had occurred in four of the five families, resulting in homozygous offspring. Thus, in these families inheritance of the hemochromatosis trait was best explained in terms of an autosomal recessive or intermediate mode of inheritance. This study demonstrates the value of HLA typing in identifying homozygous-heterozygous matings in hemochromatosis families.     

Genetic analysis of multiply-affected families of insulin-dependent diabetes mellitus (IDDM) probands

The present study combines segregation and linkage information on 30 families ascertained through a proband and a first degree relative affected with insulin-dependent diabetes mellitus (IDDM). An autosomal dominant model with incomplete penetrance was much more likely to fit the family data than a recessive model, whether or not linkage to HLA was assumed. The lod scores for linkage to HLA were 2.46 at theta M = theta F = 0.00 for dominant and 1.45 at theta M = theta F = 0.22 for a recessive model. The results are discussed in light of heterogeneity in likelihood and lod scores when the families are grouped by familial types, which indicate that the increase in likelihood of a dominant hypothesis can be attributed to the parent-child families and not the sib-sib families.     

Genetic interrelationship between insulin-dependent diabetes mellitus, the autoimmune thyroid diseases, and rheumatoid arthritis.

To investigate the possible coinheritance of autoimmune diseases that are associated with the same HLA antigen, we studied 70 families in which at least two siblings had either type I diabetes mellitus (IDDM), autoimmune thyroid disease (ATD), rheumatoid arthritis (RA), or a combination of these diseases. HLA-A, B, and C typing was performed on all affected sibs in one generation or more. First, we estimated by sib-pair analysis the disease allele frequency (pD) and the mode of inheritance for each disease. According to the method of ascertainment entered into the analysis, the pD for ATD ranged from .120 to .180, for an additive (dominant) mode of inheritance. For RA, the pD ranged from .254 to .341, also for additive inheritance, although recessive inheritance could not be excluded. For IDDM, the pD ranged from .336 to .337 for recessive inheritance; additive inheritance was rejected. Second, we examined the distribution of shared parental haplotypes in pairs of siblings that were discordant for their autoimmune diseases. The results suggested that the same haplotype may predispose to both IDDM and ATD, or IDDM and RA, but not to both RA and ATD. Analysis of pedigrees supported this hypothesis. In 16 families typed for HLA-DR also, the haplotype predisposing to both IDDM and ATD was assigned from pedigree information to DR3 (44%), DR4 (39%), or DR5, DR6, or DR7 (5.5% each). In some families, these haplotypes segregated over several generations with ATD only (either clinical or subclinical), suggesting that in such families, ATD was a marker for a susceptibility to IDDM. In several families, an IDDM haplotype segregated with RA but not with ATD. This suggests that ATD- and RA-associated susceptibilities to IDDM may be biologically different and thus independently increase the risk of IDDM.     

Population genetic studies of retinitis pigmentosa.

A questionnaire survey characterized a sample of 670 probands with retinitis pigmentosa (RP) and allied disorders. Segregation analysis provided some evidence for a small proportion of sporadic cases and for decreased segregation ratios of the dominant and recessive genotypes, which could be attributed to delayed age of onset in some cases. The overall incidence of RP was indirectly calculated to be approximately 1 in 3,700, while the incidence of autosomal recessive RP, including at least two genocopies, was estimated to be about 1 in 4,450. Family data analysis included the calculation of the likelihood that each family represented autosomal recessive, autosomal dominant, and X-linked inheritance patterns. These likelihoods were then converted to relative probabilities and summed over the sample population to yield estimates of the proportions of the three Mendelian types. This large, heterogeneous sample indicated that approximately 84% of the cases in the United States may be autosomal recessive, while about 10% are dominant and 6% X-linked recessive.     

Notch signaling in human development and disease

Mutations in Notch signaling pathway members cause developmental phenotypes that affect the liver, skeleton, heart, eye, face, kidney, and vasculature. Notch associated disorders include the autosomal dominant, multi-system, Alagille syndrome caused by mutations in both a ligand (Jagged1 (JAG1)) and receptor (NOTCH2) and autosomal recessive spondylocostal dysostosis, caused by mutations in a ligand (Delta-like-3 (DLL3)), as well as several other members of the Notch signaling pathway. Mutations in NOTCH2 have also recently been connected to Hajdu-Cheney syndrome, a dominant disorder causing focal bone destruction, osteoporosis, craniofacial morphology and renal cysts. Mutations in the NOTCH1 receptor are associated with several types of cardiac disease and mutations in NOTCH3 cause the dominant adult onset disorder CADASIL (cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy), a vascular disorder with onset in the 4th or 5th decades. Studies of these human disorders and their inheritance patterns and types of mutations reveal insights into the mechanisms of Notch signaling.     

Genetic analysis of the Ehlers-Danlos syndrome in a large family tree

The results of genetic investigation of Ehlers - Danlos syndrome in the kindred of 205 members are presented. The autosomal dominant inheritance hypothesis was tested using two modes of ascertainment, complete and truncated. The data from the segregation analysis provide evidence for the Ehlers - Danlos syndrome type I being inherited as an autosomal dominant trait.     

Genetic analysis of juvenile periodontitis in families ascertained through an affected proband.

Data from 28 families ascertained through a proband with juvenile periodontitis were used to test a series of Mendelian models of inheritance that included both autosomal and X-linked transmission. There was strong evidence of familial aggregation of this progressive dental disease, and the best-fitting model was an autosomal recessive model. Because of the rather limited age range for expression of the disease in this situation, simulations were done, in a model-choice analysis using samples of this size, to assess the chance of mistaking an autosomal dominant disease (with masking of the affected phenotype outside a specified age range) for an autosomal recessive disease. While the rate of Type II error was fairly high (40%) when competing models in these simulations were compared, these data suggest that it is reasonable to infer that juvenile periodontitis is an autosomal recessive disorder.     

Recessive sex-determining genes in human XX male syndrome

Maleness is normally inherited as a dominant trait (a single copy of the Y chromosome induces testicular differentiation of the embryonic gonad), but our genealogic study of three XX males in one pedigree indicated an autosomal recessive mode of male inheritance. Subsequent study revealed the presence of H-Y antigens in the three XX males and in their mothers, and suggested that excess H-Y may be found in the fathers. Inasmuch as H-Y loci have been mapped to the human Y chromosome, these data favor the view that H-Y structural loci comprise a family of testis-determining genes, and that Y autosome (or Y-X) translocation can generate either dominant or recessive modes of XX sex reversal, depending upon the particular portion of H-Y genes transferred.     

A combined segregation and linkage analysis of insulin-dependent diabetes mellitus.

In an effort to clarify the mode of inheritance of insulin-dependent diabetes mellitus (IDDM), a total of 230 nuclear families with pointers were analyzed using the computer program COMBIN. Each family was ascertained without deliberate selection for multiplex families, and most families were completely typed for HLA-B, HLA-DR, and properdin factor B (Bf). There were 186 families with normal parents, 44 families with one affected parent, and no families with two affected parents. The computer program COMBIN evaluates evidence for a major locus of disease susceptibility, linkage of the major locus to a known genetic marker locus, linkage disequilibrium between the marker haplotypes and disease susceptibility, pleiotropic effects, and presence of an unlinked modifier. The parameters of COMBIN are T, Q, and D, representing the displacement, gene frequency of the IDDM allele, and dominance, respectively, of the major locus--and TM, QM, and DM being the analogous parameters of the modifier. In addition, the recombination fraction, theta, between the IDDM locus and HLA as well as the coupling frequencies are estimated. Finally, COMBIN simultaneously performs segregation and linkage analysis, with the optimal model being adjusted by the fit to the haplotype sharing distribution of IDDM. The results of these analyses indicated that the best-fitting genetic model of diabetic susceptibility appears to be a single major locus with near recessivity on a scale of standardized genetic liability, with gene frequency of the IDDM susceptibility allele of approximately 14%. In addition, the recombination fraction between the major locus and HLA is zero in all models; that is, for the B-BF-DR haplotype, the IDDM locus is tightly linked, probably (according to data from previous studies) to HLA-DR. Information determined by magnitude of coupling frequencies indicated that there is significant positive linkage disequilibrium with the haplotypes B8-BfS-DR4 and B15-BfS-DR4, significant negative linkage disequilibrium with B7-BfS-DR2, and intermediate disequilibrium for B8-BfS-DR3, B18-BfF1-DR3, and B40-BfS-DR4. Significant evidence in favor of an unlinked (to HLA) modifier (either single major locus or polygenes) could not be demonstrated. In conclusion, genetic susceptibility to IDDM appears to be most consistent with a single major locus with near recessivity that is tightly linked to HLA.     

Genetic aspects of hemifacial microsomia

Summary The majority of patients with hemifacial microsomia (HM) including Goldenhar syndrome are sporadic cases. The sporadic nature of this disorder is emphasized by the discordant occurrence of HM in one of female monozygotic twins reported here. Previous publications, however, also suggest autosomal dominant and autosomal recessive modes of inheritance. Possible formes frustes will also have to be considered when giving genetic counsel.     

A gene for autosomal recessive limb-girdle muscular dystrophy in Manitoba Hutterites maps to chromosome region 9q31-q33: evidence for another limb-girdle muscular dystrophy locus.

Characterized by proximal muscle weakness and wasting, limb-girdle muscular dystrophies (LGMDs) are a heterogeneous group of clinical disorders. Previous reports have documented either autosomal dominant or autosomal recessive modes of inheritance, with genetic linkage studies providing evidence for the existence of at least 12 distinct loci. Gene products have been identified for five genes responsible for autosomal recessive forms of the disorder. We performed a genome scan using pooled DNA from a large Hutterite kindred in which the affected members display a mild form of autosomal recessive LGMD. A total of 200 markers were used to screen pools of DNA from patients and their siblings. Linkage between the LGMD locus and D9S302 (maximum LOD score 5.99 at recombination fraction .03) was established. Since this marker resides within the chromosomal region known to harbor the gene causing Fukuyama congenital muscular dystrophy (FCMD), we expanded our investigations, to include additional markers in chromosome region 9q31-q34.1. Haplotype analysis revealed five recombinations that place the LGMD locus distal to the FCMD locus. The LGMD locus maps close to D9S934 (maximum multipoint LOD score 7.61) in a region that is estimated to be approximately 4.4 Mb (Genetic Location Database composite map). On the basis of an inferred ancestral recombination, the gene may lie in a 300-kb region between D9S302 and D9S934. Our results provide compelling evidence that yet another gene is involved in LGMD; we suggest that it be named "LGMD2H."     

A Missense Mutation in a Highly Conserved Region of CASQ2 Is Associated with Autosomal Recessive Catecholamine-Induced Polymorphic Ventricular Tachycardia in Bedouin Families from Israel

Catecholamine-induced polymorphic ventricular tachycardia (PVT) is characterized by episodes of syncope, seizures, or sudden death, in response to physical activity or emotional stress. Two modes of inheritance have been described: autosomal dominant and autosomal recessive. Mutations in the ryanodine receptor 2 gene (RYR2), which encodes a cardiac sarcoplasmic reticulum (SR) Ca(2+)-release channel, were recently shown to cause the autosomal dominant form of the disease. In the present report, we describe a missense mutation in a highly conserved region of the calsequestrin 2 gene (CASQ2) as the potential cause of the autosomal recessive form. The CASQ2 protein serves as the major Ca(2+) reservoir within the SR of cardiac myocytes and is part of a protein complex that contains the ryanodine receptor. The mutation, which is in full segregation in seven Bedouin families affected by the disorder, converts a negatively charged aspartic acid into a positively charged histidine, in a highly negatively charged domain, and is likely to exert its deleterious effect by disrupting Ca(2+) binding.     

Spectrum and territorial distribution of hereditary diseases in the population of the Krasnodar Krai]

The analysis of the spectrum of hereditary diseases in the population of the Krasnodar province is performed and the influence of the population dynamics factors on the spectrum is discussed. More than 130 nosological forms were discovered in the population of approx. 200,000. Among these, there are 63 autosomal dominant, 49 autosomal recessive and 17 X-linked recessive forms. Of the most frequent autosomal dominant diseases (more than 1 per 50,000) autosomal recessive and X-linked recessive disorders 13, 7 and 7 forms, respectively, were picked up. The coefficient of diversity of hereditary diseases (the number of nosological forms per 10 inhabitants) with different types of inheritance is higher in the Krasnodar population, as compared with the Kostroma population. The problem of similarity of the "nucleus" of autosomal-recessive disorders in Russian populations is discussed.     

Metabolic interference and the +− heterozygote. A hypothetical form of simple inheritance which is neither dominant nor recessive

Another form of simple inheritance is possible which is neither dominant nor recessive and in which the heterozygote alone is affected. In this system, homozygosity for the normal allele AA, and the mutant allele A'A', give a normal phenotype. Only the heterozygous condition AA' (+ − heterozygote) produces an abnormal phenotype because the two alleles, when present together, interact to produce a harmful effect. This metabolic interference may occur because the two allelic genes code for different subunits of a multisubunit enzyme or structural protein. The two genes may interact in other ways and need not be allelic.

The various matings result in pedigrees, which in some cases resemble those of dominant or recessive inheritance, and in other cases are unique. Certain unusual pedigrees in the literature are compatible with the predictions of metabolic interference and are difficult to explain by other means. Metabolic interference is most likely to be recognized as: (1) a disorder limited to females, apparently dominant or recessive, especially a disorder passed to affected females through unaffected males; (2) a disorder occurring in all members of a large sibship with normal parents; (3) a disorder occurring in all members of a large sibship with one parent similarly affected; (4) an apparently dominant disorder with females more severely affected than males; (5) an apparently X-linked dominant disorder in which males are not more severely affected; or (6) any autosomal dominant disorder.

Examples of possible metabolic interference exist among disorders of animals, and the mechanism could be a factor in speciation. Tissue culture methods could be used to demonstrate metabolic interference.

     

Genetic hemochromatosis and HLA linkage

Summary We previously reported five families with primary, genetic (idiopathic) hemochromatosis in whom HLA typing of subjects indicated that a homozygous-heterozygous mating had almost certainly occurred and in whom inheritance of the disease trait was best explained by an autosomal recessive mode of inheritance. However, in one family, two children apparently homozygous for hemochromatosis did not manifest overt evidence of the disease, and alternative explanations were postulated, including autosomal dominant inheritance in this family. Subsequent study of the family members, including repeat HLA-DR serology with more recently defined antisera and DNA genotyping at the HLA-DR locus has, we believe, provided the true explanation for the previous apparent anomaly and adds further evidence for the tight linkage of the disease to the HLA-A locus.     

Comparison of human and bovine protoporphyria.

Protoporphyria (PP) is an inherited disorder of porphyrin metabolism in man in which there is excessive accumulation and excretion of protoporphyrin. Recently, a similar disorder has been described in cattle. In this report, the clinical, biochemical, and genetic features of bovine and human PP are compared. Human and bovine PP are characterized by photosensitivity and elevation of erythrocyte and fecal protoporphyrin levels. In both disorders, a deficiency of heme synthase activity is present in all tissues which have been examined. The diseases differ clinically in that hepatobiliary disease has been found thus far only in human PP. They also have different inheritance patterns. Human PP is an autosomal dominant disease, while initial studies strongly suggest that there is an autosomal recessive pattern of inheritance in bovine PP.     

Immunofluorescence of mineralocorticoid receptors in peripheral lymphocytes: Presence of receptor-like activity in patients with the autosomal dominant form of pseudohypoaldosteronism, and its absence in the recessive form

Pseudohypoaldosteronism is a syndrome characterized by salt wasting and a failure to thrive due to the resistance towards the action of aldosterone. Aldosterone levels and plasma renin activity are extremely elevated and aldosterone binding sites in peripheral mononuclear leukocytes have regularly shown to be reduced or absent. Sporadic as well as familial cases have been identified and an autosomal dominant as well as an autosomal recessive mode of inheritance has been described. A defect in the aldosterone receptor has been postulated, however, molecular genetic analysis in selected patients has not revealed a mutation in the sequence of the coding region of the cDNA of the mineralocorticoid receptor gene. In the present study we have used a fluorescence-labeled antibody to detect possible receptor expression in monocytes from patients with various clinical forms of pseudohypoaldosteronism. Patients with the sporadic as well as with the autosomal dominant form were clearly immunopositive despite being negative in terms of aldosterone receptor binding. In contrast in two patients with the autosomal recessive form there was no detectable receptor protein, consistent with the results obtained in the aldosterone binding studies. These results suggest that the pathogenesis of pseudohypoaldosteronism is heterogeneous not only regarding the mode of inheritance but also in terms of receptor binding. Thus, in a subgroup of patients the inability of the receptor to bind ligand may be due to a defect involving other, probably cellular factors rather than a deficiency or a defect in the mineralocorticoid receptor system itself.     

Molecular genetics of retinitis pigmentosa.

Retinitis pigmentosa is a model for the study of genetic diseases. Its genetic heterogeneity is reflected in the different forms of inheritance (autosomal dominant, autosomal recessive, or X-linked) and, in a few families, in the presence of mutations in the visual pigment rhodopsin. Clinical and molecular genetic studies of these disorders are discussed. Animal models of retinal degeneration have been investigated for many years with the hope of gaining insight into the cause of photoreceptor cell death. Recently, the genes responsible for two of these animal disorders, the rds and rd mouse genes, have been isolated and characterized. The retinal degeneration of the rd mouse is presented in detail. The possible involvement of human analogues of these mouse genes in human retinal diseases is being investigated.     

HLA and autoimmunity in North Indian type I (insulin-dependent) diabetic multiplex families

The HLA haplotype segregation and autoantibody spectrum in 7 type I (insulin-dependent) diabetic multiplex families of North Indian origin were determined. Of the total of 17 diabetic sibs, 7 shared both haplotypes and 3 shared one haplotype with the proband. No HLA-non-identical sibs were observed. This distribution of haplotypes was non-random (P approximately equal to 0.005). The mode of inheritance was compatible with an autosomal recessive model, while a dominant model was unlikely. Pancreatic islet-cell antibodies were found in 23.5% of affected sibs, but in no healthy family member. A high incidence of other autoantibodies (parietal-cell and thyroglobulin/thyroid microsomal antibodies) was detected in both the diabetic patients (26.3%), and in healthy first-degree relatives (22.2%). These findings emphasize the role of HLA-linked genes and autoimmunity in the pathogenesis of type I diabetes in North India.