Discrepancies Between Osteoporotic Fracture Evaluations in Men Based on German (DVO) Osteoporosis Guidelines or the FRAX Score.

INTRODUCTION: Established scores estimate 10-year fracture risk in osteoporosis to assist with treatment recommendations. This study compared the risk probabilities of major osteoporotic and hip fractures calculated by the FRAX tool with those of the DVO score, established in German-speaking countries. MATERIAL AND METHODS: This seven-year retrospective study analyzed data of 125 male patients (mean age: 59.2±10.7 years) evaluated for osteoporosis. For the DVO score, the therapy threshold of>30% for vertebral and hip fractures suggested by DVO guidelines was implemented. We calculated fracture risks based on FRAX scores with aBMD and applied a common therapy threshold of≥3% for hip fracture and subsequently determined the "DVO-equivalent risk level" for FRAX-based assessment that would identify as many male patients as identified by the DVO score. RESULTS: Based on DVO score, 60.0% of patients had a 10-year risk of hip and vertebral fractures>30%. The recommendations for individuals based on FRAX scores for hip fracture with aBMD with risk≥3% overlapped with those based on DVO score in 36% of patients. Patients identified for treatment only by DVO score presented a higher percentage of spine fractures (65 vs. 41%). The thresholds for this "DVO-equivalent risk level" for 'FRAX with aBMD' was estimated to be≥6.7% for major osteoporotic fracture and≥2.1% for hip fracture.This study demonstrates that the DVO score was more sensitive than the FRAX score for patients with prevalent spinal fractures. We suggest considering the appropriate score and therapy threshold carefully in the daily care of male patients.

Caloric restriction increases serum testosterone concentrations in obese male subjects by two distinct mechanisms.

The concentration of serum testosterone is mainly regulated by the testicular function, which is under control of the central hypothalamic-pituitary-gonadal axis. A certain amount of testosterone is converted into ß-estradiol by adipose tissue. Obesity in men is often associated with decreased androgen levels. The aim of the present study was to examine the effect of caloric restriction on serum testosterone levels in obese men. Dietary intervention study was performed with a very low calorie diet (800 kcal/d) for 12 weeks. Thirteen obese human male subjects (median body mass index: 42.7 kg/m2) were included. Body composition was assessed by impedance analysis. Insulin sensitivity was estimated by leptin-to-adiponectin ratio (LAR). Testosterone (T), ß-estradiol, albumin, sex hormone-binding globulin (SHBG), LH, and FSH serum concentrations were measured by enzyme immunoassays. Statistical analysis was performed on baseline and values after 3 months. Caloric restriction significantly increased total testosterone (6.97 nmol/l to 13.21 nmol/l; p=0.001) and SHBG (22.11 nmol/l to 42.12 nmol/l; p=0.001) concentrations in serum. This is caused by a significant improvement of the testicular function (LH/T: 0.36-0.20; p=0.005) and a significant reduction of the T/ß-estradiol conversion rate (73.59-104.29; p=0.003). There was a significant negative correlation of improvement of testicular function and LAR (rs=-0.683 (p=0.042)). In obese men caloric restriction significantly increases the serum testosterone concentration. This is achieved by 2 distinct mechanisms, that is, improvement of testicular function and reduced conversion of testosterone to ß-estradiol by aromatase activity of the adipose tissue.

Data requirements for risk assessment of furan in food.

Furan is an organic, volatile compound used in various chemical-manufacturing industries. Headspace gas chromatography is the analytical method of choice for obtaining reliable results on its occurrence. The presence of furan in some food items has been known since the late 1970s, but a US Food and Drug Administration (FDA) survey published in 2004 revealed the occurrence of furan in a broad variety of canned and jarred foods, including baby food, that undergo heat treatment. Furan is carcinogenic in rats and mice, showing a dose-dependent increase in hepatocellular adenomas and carcinomas. In rats, a dose-dependent increase of mononuclear leukaemia is evident and a very high incidence of cholangiocarcinomas of the liver, even at the lowest dose tested. There is evidence to indicate that furan-induced carcinogenicity is probably attributable to a genotoxic mechanism. However, chronic toxicity with secondary cell proliferation may indirectly amplify the tumour response. From the available data, there is a relative small difference between possible human exposure and the doses in experimental animals required to produce carcinogenic effects. However, reliable risk assessment requires further data on both toxicity and exposure. The European Food Safety Authority's (EFSA) Scientific Panel on Contaminants in the Food Chain (CONTAM) recommended these studies as part of a reliable risk assessment of furan in food.

[Task and function of the European Food Safety Authority]. / Aufgaben und Funktion der Europäischen Behörde für Lebensmittelsicherheit.

In 2002, the European Commission and the European Parliament established the European Food Safety Authority (EFSA). The provisional seat of the new Authority is Brussels and the final seat of the authority will be Parma, Italy. EFSA's main task is to carry out risk assessment and to provide independent scientific advice on all matters linked to food and feed safety. This includes animal health and welfare and plant health-as well as nutrition. Therefore, EFSA's risk assessments provide risk managers with a sound scientific basis for regulatory measures in order to ensure a high level of consumer protection. EFSA is confessed to openness and transparence. The authority keeps good links to all European institutions, particularly to the European Commission and the European Parliament, to national authorities, which have similar tasks to EFSA, and to stakeholders such as consumer and food industry organisations.

Identification of a novel mutation in the arginine vasopressin-neurophysin II gene in familial central diabetes insipidus.

Familial central diabetes insipidus is an inherited disease of predominant autosomal dominant trait characterized by a deficiency of arginine vasopressin. The arginine vasopressin-neurophysin II ( AVP-NPII) gene consists of three exons and is located on chromosome 20p13 encoding for the precursor protein of AVP. We investigated two Caucasian families with a typical autosomal dominant trait of familial central diabetes insipidus, defined by deficiency of arginine vasopressin. After PCR amplification of exon 1 and exon 2/3, fragments were pooled and purified. Nucleotide sequencing was performed with the Taq DyeDeoxy-terminator cycle sequencing method using nested primers. Two mutations in the coding region of NPII were identified. In family C we found a heterozygous G ==> C missense mutation (AA61) in exon 2 leading to the substitution of cystein with serine. In family D a novel heterozygous nonsense mutation in exon 3 (AA 83, GAG ==> TAG) was indentified, leading to a stop codon instead of glutamine. Both mutations were confirmed by restriction analysis and were found in all affected but not in healthy family members or control subjects. We therefore have identified a missense mutation of the AVP-NPII gene and a novel mutation predicting a truncated protein.

The tumor suppressor protein menin interacts with NF-kappaB proteins and inhibits NF-kappaB-mediated transactivation.

Multiple endocrine neoplasia type 1 is an autosomal dominant tumor syndrome. Manifestations include neoplasms of the parathyroid glands, enteropancreatic neuroendocrine cells, and the anterior pituitary gland. The MEN1 tumor suppressor gene encodes menin, a 610 amino acid nuclear protein without sequence homology to other proteins. To elucidate menin function, we used immunoprecipitation to identify interacting proteins. The NF-kappaB proteins p50, p52 and p65 were found to interact specifically and directly with menin in vitro and in vivo. The region of NF-kappaB proteins sufficient for binding to menin is the N-terminus. Furthermore, amino acids 305-381 of menin are essential for this binding. Menin represses p65-mediated transcriptional activation on NF-kappaB sites in a dose-dependent and specific manner. Also, PMA (phorbol 12-myristate 13-acetate)-stimulated NF-kappaB activation is suppressed by menin. These observations suggest that menin's ability to interact with NF-kappaB proteins and its modulation of NF-kappaB transactivation contribute to menin's tumor suppressor function.

Identification and characterization of JunD missense mutants that lack menin binding.

Menin, the product of the MEN1 tumor suppressor gene, binds to the AP1 transcription factor JunD and represses JunD transcriptional activity. The effects of human or mouse JunD missense mutations upon menin interaction were studied by random and alanine scanning mutagenesis of the menin binding region of JunD (amino acids 1-70). JunD mutant proteins were tested for menin binding in a reverse yeast two-hybrid assay, and for transcriptional regulation by menin in AP1-reporter assays. Random mutagenesis identified two different mutations that disrupted menin interaction at mouse JunD amino acid 42 (G42E and G42R). Mutation G42A generated by alanine scanning did not affect menin binding, likely reflecting the conserved nature of this amino acid substitution. Furthermore, by size exclusion chromatography menin co-migrated with wild type JunD but not with the JunD mutant tested (G42E). Alanine scanning mutagenesis of residues 30-55 revealed two different amino acids, P41 and P44, of mouse JunD that were critical for interaction with menin. Mouse JunD missense mutants P41A, G42R, G42E and P44A failed to bind menin and also escaped menin's control over their transcriptional activity. At lower amounts of transfected menin, the transcriptional effect of menin on the mutants P41A, G42R and G42E was changed from repression to activation, similar to that with c-jun. In conclusion, a small N-terminal region of JunD mediates a key difference between JunD and c-jun, and a component of this difference is dependent on JunD binding to menin.

Five cases with central diabetes insipidus and hypogonadism as first presentation of neurosarcoidosis.

OBJECTIVES: We retrospectively reviewed 5 patients with neurosarcoidosis, who all presented with central diabetes insipidus and hypogonadism. DESIGN: This was a single-centre, retrospective analysis of 5 cases with a minimum follow-up of 2 years. METHODS: Case analysis included clinical, biochemical, and endocrinological evaluation and frequent CT/MRI scans of involved organs as primary evaluation and in response to immunosuppressive therapy. RESULT: Neurosarcoidosis was diagnosed in all patients. Two patients had no proven extracerebral manifestation and had a stable disease over 3 and 5 years. One patient showed deterioration with corticosteroids alone but partial remission after additional cyclophosphamide. Pituitary dysfunction remained unchanged in all patients, despite total clinical and radiological remission in two patients. However, one of these patients died of acute granulomatous meningoencephalitis after two years of follow-up. CONCLUSION: Although the presenting symptoms of neurosarcoidosis may vary, the occurrence of central diabetes insipidus associated with typical radiological features is suggestive of neurosarcoidosis. However, there is an increasing number of case reports on lymphocytic hypophysitis. Without the bioptic diagnosis, the differentiation between potentially lethal isolated neurosarcoidosis and lymphocytic hypophysitis is difficult. These cases demonstrate the difficulties in diagnosing neurosarcoidosis and reflect experiences with follow-up parameters.

Genotype/phenotype correlation of multiple endocrine neoplasia type 1 gene mutations in sporadic gastrinomas.

Multiple endocrine neoplasia type 1 (MEN1) gene mutations are reported in some gastrinomas occurring in patients without MEN1 as well as in some other pancreatic endocrine tumors (PETs). In some inherited syndromes phenotype-genotype correlations exist for disease severity, location, or other manifestations. The purpose of the present study was to correlate mutations of the MEN1 gene in a large cohort of patients with sporadic gastrinomas to disease activity, tumor location, extent, and growth pattern. DNA was extracted from frozen gastrinomas from 51 patients and screened by dideoxyfinger-printing (ddF) for abnormalities in the 9 coding exons and adjacent splice junctions of the MEN1 gene. Tumor DNA exhibiting abnormal ddF patterns was sequenced for mutations. The findings were correlated with clinical manifestations of the disease, primary tumor site, disease extent, and tumor growth postoperatively. Tumor growth was determined by serial imaging studies. Sixteen different MEN1 gene mutations in the 51 sporadic gastrinomas (31%) were identified (11 truncating, 4 missense, and 1 in-frame deletion). Nine of the 16 mutations were located in exon 2 compared to 7 of 16 in the remaining 8 coding exons (P = 0.005 on a per nucleotide basis). Primary pancreatic or lymph node gastrinomas with a mutation had only exon 2 mutations, whereas duodenal tumors uncommonly harbored exon 2 mutations (P = 0.011). Similarly, small primary tumors (<1 cm) more frequently contained a nonexon 2 mutation (P = 0.02). There was no difference between patients with or without a mutation with respect to clinical characteristics, primary tumor site, disease extent, or proportion of patients disease free after surgery. Postoperative tumor growth tended to be more aggressive in patients with a mutation (P = 0.09). No correlation in the rate of disease-free status or postoperative tumor growth in patients with active disease to the location of the mutation was seen. These results demonstrate that the MEN1 gene is mutated in 31% of sporadic gastrinomas, and mutations are clustered between amino acids 66-166, which differs from patients with familial MEN1, in whom mutations occur throughout the gene. The presence of an MEN1 gene mutation does not correlate with clinical characteristics of patients with gastrinomas, gastrinoma extent, or growth pattern; however, the location of the mutation differed with gastrinoma location. These data suggest that mutations in the MEN1 gene are important in a proportion of sporadic gastrinomas, but the presence or absence of these mutations will not identify the clinically important subgroups with different growth patterns.

Multiple endocrine neoplasia type 1: clinical and genetic features of the hereditary endocrine neoplasias.

MEN1 is a syndrome of parathyroid adenomas, gastrinomas, prolactinomas, and other endocrine tumors. Collagenomas and facial angiofibromas are newly recognized but common skin expressions. Many tumors in MEN1 are benign; however, many entero-pancreatic neuroendocrine tumors and foregut carcinoid tumors are malignant. MEN1 is thus the expression of a cancer gene but without available prevention or cure for malignancy. Hereditary (as compared to sporadic) endocrine tumors show early onset age and multiplicity, because each cell of the body has "one hit" by inheritance. Multiple neoplasia syndromes with endocrine tumor(s) all include nonendocrine components; their known defective genes seem mainly to disturb cell accumulation. Hereditary neoplasia/hyperplasia of one endocrine tissue reflects a defect that is tissue selective and directed at cell secretion. Though the hereditary endocrine neoplasias are rare, most of their identified genes also contribute to common sporadic endocrine neoplasms. Hereditary tumors may be caused by activation of an oncogene (e.g., RET) or, more often, by inactivation of a tumor suppressor gene (e.g., P53, MEN1). Recently, MEN1 was identified by positional cloning. This strategy included narrowing the gene candidate interval, identifying many or all genes in that interval, and testing the newly identified candidate genes for mutation in MEN1 cases. MEN1 was identified because it showed mutation in 14 of 15 MEN1 cases. NIH testing showed germline MEN1 mutations in 47 of 50 MEN1 index cases and in seven of eight cases with sporadic MEN1. Despite proven capacity to find germline MEN1 mutation, NIH testing found no MEN1 mutation among five families with isolated hyperparathyroidism, suggesting that this often arises from mutation of other gene(s). Analogous studies in Japan found that familial isolated pituitary tumors also did not show MEN1 germline mutation. MEN1 mutation testing can now be considered for cases of MEN1 and its phenocopies and for asymptomatic members of families with known MEN1 mutation. Germline MEN1 testing does not have the urgency of RET testing in MEN2a and 2b, as MEN1 testing does not commonly lead to an important intervention. Somatic MEN1 mutation was found in sporadic tumors: parathyroid adenoma (21%), gastrinoma (33%), insulinoma (17%), and bronchial carcinoid (36%). For each of these, MEN1 was the known gene most frequently mutated. MEN1 has a widely expressed mRNA that encodes a protein (menin) of 610 amino acids. The protein sequence is not informative about domains or functions. The protein was mainly nuclear. Menin binds to JunD, an AP-1 transcription factor, inhibiting JunD's activation of transcription. Most of the germline and somatic MEN1 mutations predict truncation of menin, a likely destructive change. Inactivating MEN1 mutations in germline and in sporadic neoplasms support prior predictions that MEN1 is a tumor suppressor gene. Germline MEN1 mutation underlies all or most cases of MEN1 (familial or sporadic). Somatic MEN1 mutation is the most common gene mutation in many sporadic endocrine tumor types.

Stable overexpression of MEN1 suppresses tumorigenicity of RAS.

Although there is indirect genetic evidence that MEN1, the gene for multiple endocrine neoplasia type 1, is a tumor suppressor gene, little is known about the MEN1-encoded protein, menin. Menin was stably overexpressed in a well-characterized murine tumor cell line, (valine-12)-RAS-transformed NIH3T3 cells. Menin overexpression reverted the morphology of the RAS-transformed NIH3T3 cells towards the more flattened and more spread, fibroblastic shape of wild type NIH3T3 cells. The proliferation rate of the RAS-transformed cells in 0.5% calf serum was also slower with menin overexpression. Menin overexpression reduced the RAS-induced clonogenicity in soft agar. Menin also reduced tumor growth after injection of cells in nude mice. In conclusion, stable overexpression of MEN1 suppressed partially the RAS-mediated tumor phenotype in vitro and in vivo. Overexpressed menin protein had biological effects, directly supporting MEN1 gene function as a tumor suppressor.

The gene for multiple endocrine neoplasia type 1: recent findings.

Multiple endocrine neoplasia type 1 (MENI) is a promising model to understand endocrine and other tumors. Its most common endocrine expressions are tumors of parathyroids, entero-pancreatic neuro-endocrine tissue, and anterior pituitary. Recently, collagenomas and multiple angiofibromas of the dermis also have been recognized as very common. MEN1 can be characterized from different perspectives: (a) as a hormone (parathyroid hormone, gastrin, prolactin, etc.) excess syndrome with excellent therapeutic options; (b) as a syndrome with sometimes lethal outcomes from malignancy of entero-pancreatic neuro-endocrine or foregut carcinoid tissues; or (c) as a disorder than can give insight about cell regulation in the endocrine, the dermal, and perhaps other tissue systems. The MEN1 gene was identified recently by positional cloning, a comprehensive strategy of narrowing the candidate interval and evaluating all or most genes in that interval. This discovery has opened new approaches to basic and clinical issues. Germline MEN1 mutations have been identified in most MEN1 families. Germline MENI mutations were generally not found in families with isolated hyperparathyroidism or with isolated pituitary tumor. Thus, studies with the MENI gene helped establish that mutation of other gene(s) is likely causative of these two MEN1 phenocopies. MEN1 proved to be the gene most frequent L4 mutated in common-variety, nonhereditary parathyroid tumor, gastrinoma, insulinoma, or bronchial carcinoid. For example, in common-variety parathyroid tumors, mutation of several other genes (such as cyclin D1 and P53) has been found, but much less frequently than MEN1 mutation. The majority of germline and somatic MEN1 mutations predicted truncation of the encoded protein (menin). Such inactivating mutations strongly supported prior predictions that MEN1 is a tumor suppressor gene insofar as stepwise mutational inactivation of both copies can release a cell from normal growth suppression. Menin is principally a nuclear protein; menin interacts with junD. Future studies, such as discovery of menin's metabolic pathway, could lead to new opportunities in cell biology and in tumor therapy.

Menin interacts with the AP1 transcription factor JunD and represses JunD-activated transcription.

MEN1 is a tumor suppressor gene that encodes a 610 amino acid nuclear protein (menin) of previously unknown function. Using a yeast two-hybrid screen with menin as the bait, we have identified the transcription factor JunD as a direct menin-interacting partner. Menin did not interact directly with other Jun and Fos family members. The menin-JunD interaction was confirmed in vitro and in vivo. Menin repressed transcriptional activation mediated by JunD fused to the Gal4 DNA-binding domain from a Gal4 responsive reporter, or by JunD from an AP1-responsive reporter. Several naturally occurring and clustered MEN1 missense mutations disrupted menin interaction with JunD. These observations suggest that menin's tumor suppressor function involves direct binding to JunD and inhibition of JunD activated transcription.

MEN1 gene analysis in sporadic adrenocortical neoplasms.

Adrenocortical tumors occur as sporadic tumors, as part of the multiple endocrine neoplasia type 1 (MEN1) syndrome or as part of other hereditary disorders. We recently cloned the MEN1 gene, a tumor-suppressor gene located on chromosome 11q13. Subsequently, we showed that sequential somatic inactivation of both alleles of the MEN1 gene contributes to the development of some sporadic endocrine neoplasms (parathyroid, enteropancreatic neuroendocrine, bronchial carcinoid, and pituitary tumors). We now studied whether somatic inactivation of the MEN1 gene contributes to the pathogenesis of sporadic adrenocortical neoplasms. Seven adrenocortical carcinomas, 2 adrenocortical carcinoma cell lines, and 11 aldosterone-secreting, 8 cortisol-secreting, and 5 nonsecreting benign adrenocortical tumors were studied. Seven tumors (5 of 5 carcinomas, 2 of 21 nonsecreting benign adenomas; P < 0.001) exhibited loss of heterozygosity on 11q13. All 33 tumors and cell lines were screened for mutation throughout the MEN1 open-reading frame and adjacent splice junctions. None exhibited a mutation within the MEN1-coding region. We conclude that somatic MEN1 mutation within the MEN1-coding region does not occur commonly in sporadic adrenocortical tumors, although the majority of adrenocortical carcinomas exhibit 11q13 loss of heterozygosity.

Analysis of recurrent germline mutations in the MEN1 gene encountered in apparently unrelated families.

Multiple endocrine neoplasia type 1 (MEN1) is an autosomal dominant disorder that manifests as varying combinations of tumors of endocrine and other tissues (parathyroids, pancreatic islets, duodenal endocrine cells, the anterior pituitary and others). The MEN1 gene is on chromosome 11q13; it was recently identified by positional cloning. We previously reported 32 different germline mutations in 47 of the 50 familial MEN1 probands studied at the NIH. Eight different germline MEN1 mutations were encountered repeatedly in two or more apparently unrelated families. We analyzed the haplotypes of families with recurrent MEN1 mutations with seven polymorphic markers in the 11q13 region surrounding the MEN1 gene (from D11S1883 to D11S4908). Disease haplotypes were inferred from germline DNA and also from tumors with 11ql3 loss of heterozygosity. Two different disease haplotype cores were shared by apparently unrelated families for two mutations in exon 2 (five families with 416delC and six families with 512delC). These two repeat mutations were associated with the two founder effects that we reported in a prior haplotype analysis. The disease haplotypes for each of the other six repeat mutations (seen twice each) were discordant, suggesting independent origins of these recurrent mutations. Most of the MEN1 germline mutations including all of those recurring independently occur in regions of CpG/CpNpG, short DNA repeats or single nucleotide repeat motifs. In conclusion, recurring germline mutations account for about half of the mutations in North American MEN1 families. They result from either founder effects or independent occurrence of one mutation more than one time.

Germline and somatic mutation of the gene for multiple endocrine neoplasia type 1 (MEN1).

Dideoxyfingerprinting was used to screen for germline and somatic MEN1 mutations. This method, applied to a panel of germline DNA from 15 probands with multiple endocrine neoplasia type 1 (MEN-1), allowed confident discovery of the MEN1 gene. Germline MEN1 mutation has been found in 47 out of 50 probands with familial MEN-1, in 7 out of 8 cases with sporadic MEN-1, and in 1 out of 3 cases with atypical sporadic MEN-1. Germline MEN1 mutation was not found in any of five probands with familial hyperparathyroidism. Somatic MEN1 mutations were found in 7 out of 33 parathyroid tumours not associated with MEN-1. Allowing for repeating mutations, a total of 47 different germline or somatic MEN1 mutations have been identified. Most predict inactivation of the encoded 'menin' protein. supporting expectations that MEN1 is a tumour suppressor gene. The 16 observed missense mutations were distributed across the gene, suggesting that many domains are important to its as yet unknown functions.

Neuroendocrine dysfunction in African trypanosomiasis. The role of cytokines.

Sleeping sickness (SS; African trypanosomiasis) is an anthropozoonosis transmitted by the tsetse fly. Infection with Trypanosoma brucei in humans is associated with adynamia, lethargy, anorexia, and more specifically amenorrhea/infertility in women and loss of libido/impotence in men. Recent evidence suggests that experimental infection in animals with Trypanosoma brucei species causes polyglandular endocrine failure by local inflammation of the pituitary, thyroid, adrenal, and gonadal glands. In a cross-sectional study we investigated the prevalence and significance of neuroendocrine abnormalities in 137 Ugandan patients with SS. In the untreated stage of the disease, there was a high prevalence of adrenal insufficiency (27%), hypothyroidism (50%) and hypogonadism (85%). Pituitary function tests suggested an unusual combined central (hypothalamic/pituitary) and peripheral defect in hormone secretion. Specific therapy resulted in a rapid recovery of adrenal/thyroid function, whereas hypogonadism persisted for years in a substantial portion of patients. We did not detect pituitary, thyroid, adrenal, and gonadal autoantibodies in patients with endocrine dysfunction, ruling out an autoimmune origin of the endocrine abnormalities. However, the presence of hypopituitarism correlated with high cytokine concentrations (TNF-alpha, IL-6) which--together with direct parasitic infiltration of the endocrine glands--are involved in the pathogenesis of SS-associated endocrine dysfunction.

Identification of common allergenic structures in mugwort and ragweed pollen.

UNLABELLED: Identification of common allergenic structures in mugwort and ragweed pollen. BACKGROUND: Despite the rare occurrence of ragweed in Middle Europe, a surprisingly high number of patients allergic to mugwort, a frequently encountered weed, display IgE reactivity against ragweed pollen allergens. OBJECTIVE: The aim of this study was to investigate whether the high prevalence of IgE reactivity against ragweed in patients allergic to mugwort is caused by the presence of common allergenic determinants. We also sought to characterize any cross-reactive allergens. METHODS: Common allergenic structures in mugwort and ragweed pollen were characterized by qualitative IgE immunoblot inhibition experiments performed with natural allergen extracts and recombinant allergens. The degree of cross-reactivity was estimated by quantitative CAP-FEIA competitions. The clinical significance of cross-reactive IgE antibodies was studied with histamine release experiments and nasal provocation tests. RESULTS: Mugwort and ragweed RAST values were significantly correlated in a population of 82 Austrian patients allergic to mugwort. IgE antibodies cross-reacted with allergens of comparable molecular weight that were present in both extracts. By using recombinant birch profilin and specific antisera for IgE inhibition experiments, profilin was identified as one of the cross-reactive components in mugwort and ragweed pollen. Preincubation of sera from patients allergic to mugwort with mugwort extract inhibited IgE binding to ragweed pollen extract greater than 80%. Mugwort and ragweed pollen extract induced comparable histamine release and reduction of nasal air flow in a patient with IgE reactivity against the major mugwort allergen Art v 1. CONCLUSION: In addition to profilin, mugwort and ragweed pollen contain a number of cross-reactive allergens, among them the major mugwort allergen Art v 1. Cross-reactive IgE antibodies can lead to clinically significant allergic reactions.

Identification of mutations of the arginine vasopressin-neurophysin II gene in two kindreds with familial central diabetes insipidus.

Familial central diabetes insipidus is transmitted as an autosomal dominant trait with almost complete penetrance. Twenty-three different mutations of the arginine vasopressin-neurophysin II gene have been reported to date, located within the signal peptide-, the arginine vasopressin-, or the neurophysin II-coding region. In the present study two kindreds with familial central diabetes insipidus were examined. The entire coding region of the arginine vasopressin-neurophysin II gene of one affected subject of each family was amplified by PCR and subcloned into a pUC 18 plasmid, and six positive clones were sequenced. After identification of the mutation, direct sequencing was performed on the respective sequence of family members and 28 healthy control subjects. In family A, a missense mutation (C-->T) at nucleotide position 280 was detected, predicting the substitution of alanine by valine at position -1 of the signal peptide. All affected subjects were heterozygote for the mutation, whereas none of the unaffected family members or control subjects displayed the mutant sequence. In family B, a missense mutation within the neurophysin II-coding sequence was identified (nucleotide 1757, G-->C), predicting the substitution of glycine by arginine at position 23. Again, affected family members were found to be heterozygote for the mutation, which was not observed in unaffected family members or in control subjects. Although the mutation of family A was recently described in 3 other kindreds as well, the mutation within the neurophysin II-coding region represents a novel mutation of the AVP-NP II gene.