Neurological manifestations in individuals with pure cutaneous or syndromic (Ruggieri-Happle syndrome) phenotypes with "cutis tricolor": a study of 14 cases.

BACKGROUND: The term cutis tricolor describes the combination of congenital hyper- and hypo-pigmented skin lesions in close proximity to each other in a background of normal complexion. This phenomenon has been reported so far: (i) as pure cutaneous trait, (ii) as a part of a complex malformation syndrome (Ruggieri-Happle syndrome--RHS), (iii) as a distinct type (cutis tricolor parvimaculata); (iv) in association with other (e. g., vascular) skin disturbances. AIM: The aim of this study was to define the spectrum of neurological abnormalities in cutis tricolor. METHODS: A retrospective and prospective 14-year study of clinical, electroencephalographic (EEG), neuroradiological (MRI), cytogenetic and ZFHX1B gene studies of 14 individuals (8 M, 6 F; aged 2-28 years) with cutis tricolor (4 pure cutaneous; 10 syndromic) was undertaken. RESULTS: Neurological involvement was recorded in 71.4% (10/14) of the patients [100% (10/10) in RHS and null (0/4) in cases with isolated skin manifestations] and included psychomotor delay (n=8), seizures (n=9), EEG abnormalities (n=6), a behavioural phenotype (n=4), non-specific brain abnormalities (n=6). Genetic analyses excluded ZFHX1B mutations and revealed a 19qter deletion (n=1). CONCLUSIONS: Even though we could not exclude the ascertainment and referral biases, we concluded that cutis tricolor may be a marker of underlying neurological involvement particularly in subjects with a syndromic (RHS) phenotype.

Characterization of a novel protein kinase C response element in the glucagon gene.

To maintain glucose levels in blood within narrow limits, the synthesis and secretion of pancreatic islet hormones are controlled by a variety of neural, hormonal, and metabolic messengers that act through multiple signal transduction pathways. Glucagon gene transcription is stimulated by cyclic AMP and depolarization-induced calcium influx. In this study, the effect of protein kinase C on glucagon gene transcription was investigated. After transient transfection of a glucagon-reporter fusion gene into the glucagon-producing islet cell line alphaTC2, activation of protein kinase C by 12-O-tetradecanoylphorbol-13-acetate (TPA) stimulated glucagon gene transcription. By 5' deletions, 3' deletions, internal deletion, and oligonucleotide cassette insertion, the TPA-responsive element was mapped to the G2 element (from -165 to -200). Like TPA, overexpression of oncogenic Ras (V-12 Ras) stimulated G2-mediated transcription whereas overexpression of a dominant negative Ras mutant (N-17 Ras) blocked the effect of TPA. A mutational analysis of G2 function and nuclear protein binding indicated that protein kinase C and Ras responsiveness is conferred to the glucagon gene by HNF-3beta functionally interacting with a protein that binds to a closely associated site with sequence similarity to binding sites of Ets family proteins. HNF-3beta belongs to the winged-helix family of transcription factors and has been implicated in the control of cell-specific and developmental gene expression. The results of the present study show that the cell lineage-specific transcription factor HNF-3beta is an essential component of a novel protein kinase C response element in the glucagon gene.

Nuclear and chromosomal replication patterns in chorionic villi cells by bromodeoxyuridine labelling and DNA flow cytometry.

Cell kinetics of chorionic villi (CV) were studied by BrdUrd-incorporation detected by fluorescence-plus-Giemsa and BrdUrd-antibody techniques, and by DNA flow cytometry. Growth characteristics of long-term cultures of CV resembled fibroblasts with a total cell cycle time of 26 h, final S phase of 9 h, penultimate S phase of 16 h and G2/M phase of 3-4 h. Especially useful for a quick routine diagnostic approach, Ultroser RG, a commercially available serum supplement, significantly increased cell proliferation and stabilized cell cycle lengths to a total cell cycle time of 14 h, final S phase of 7 h, penultimate S phase of 6 h and G2/M phase of 4 h. Moreover, mitotic activity steadily increased in cultured CV, when studying six successive subculturings. This reflects adaptation to the culture conditions rather than an inherent response of cultured CV cells of increasing passage numbers. Native villi exposed to BrdUrd immediately after biopsy show lower rates of uptake than do aliquots after overnight incubation. As shown by BrdUrd-pulse labelling studies, more than 7 h are required to overcome the proposed 'biopsy stress'. This correlates with routine diagnostic techniques, in which many more metaphase cells are observed in short-term cultures than in direct preparations.

Reciprocal translocation t(1;15)(p36.2;p11.2): confirmation of a suggestive cytogenetic diagnosis by in situ hybridization and clinical case report on resulting monosomy (1p).

A newborn girl with generalized muscular hypotonia and minor anomalies was referred for chromosome analysis. Cytogenetic investigation showed a satellite and an Ag-positive NOR on the distal short arm of one chromosome 1, thus indicating an unbalanced translocation involving the short arm of an acrocentric chromosome. The phenotypically normal mother had the same satellited chromosome 1 with Ag-positive NOR. One chromosome 15 was the only acrocentric chromosome in her karyotype lacking recognizable satellites and an Ag-positive NOR. Thus a balanced reciprocal translocation between the short arms of chromosomes 1 and 15 in the mother was suggested. The cytogenetic diagnosis was confirmed by nonradioactive in situ hybridization with the most distal DNA probe on chromosome 1, the probe p1-79, localized at chromosome band 1p36.3. The probe was biotinylated by nick-translation, and detection was done by FITC labelled avidin binding. Hybridization signals were observed on both the mother's normal chromosome 1 and the derivative chromosome 15 but not on her derivative chromosome 1. Consequently, the index patient has an unbalanced karyotype with monosomy (1p36.3). Comparing their clinical reports shows that patients with similar terminal deletions of 1p share several manifestations.

Dup(1q)(q42-->qter) syndrome: case report and review of literature.

We report on a patient with primordial growth retardation, mental retardation, and minor anomalies (triangular face, open sagittal suture, frontal bossing, telecanthus, upturned nose, micrognathia, and small mouth with downturned corners). The diagnosis of Russell-Silver syndrome (RSS) had been considered but was abandoned when cytogenetic evaluation showed a partial trisomy 1q or duplication 1q (46,XY,15, + der(15)t(1;15)(q42;qter). Data from another 5 reports of dup(1)(q42-->qter) do not allow delineation of a typical syndrome. However, individuals with dup(1q), del(15q), and Russell-Silver syndrome share common manifestations (i.e., low birth weight, growth retardation, triangular face, low set/abnormal ears, micrognathia, renal anomalies.

How can the frequency of false-negative findings in prenatal diagnoses of fra(X) be reduced: experience with first trimester chorionic villi sampling.

We report on 12 prenatal diagnoses performed between weeks 10 and 13 on normal women with a well-documented family history of the Martin-Bell syndrome. Seven were obligate and three were potential carriers. One male and 2 female fetuses were found to be fragile X [fra(X)]-positive. The diagnoses were confirmed in fibroblasts or lymphocytes after interruption or postnatally. In one fra(X)-negative female fetus, the analysis of linked DNA markers indicated that most probably she was a heterozygote. Reexamination after birth gave a fra(X)-positive result. Hence this was a case of a false-negative prenatal fra(X) result. The occurrence of false-negative cytogenetic results represents a common problem that limits the sensitivity of prenatal diagnostics in the Martin-Bell syndrome. A study of linked DNA markers can improve the reliability of negative cytogenetic results in first trimester prenatal diagnosis. In case of doubt, the chromosomes could be reexamined after fetal blood sampling.

Familial occurrence of agonadism and multiple internal malformations in phenotypically normal girls with 46,XY and 46,XX karyotypes, respectively: a new autosomal recessive syndrome.

We report on 2 phenotypic sisters, one with 46,XY; the other with 46,XX. The 2 girls had similar related internal malformations, including agonadism, hypoplasia of the right pulmonary artery, hypoplasia of the right lung, isolated dextrocardia with complex vitium cordis, and diaphragmatic hernia (only sib 1) or omphalocele (only sib 2). This combination of malformations did not fit into any of the previously described syndromes. For this syndrome we suggest the acronym PAGOD ([hypoplasia of the] pulmo, and pulmonary artery, agonadism, omphalocele/diaphragmatic defect, dextrocardia). The occurrence of a basically similar set of malformations in 2 unlike sex is interpreted as evidence for autosomal recessive inheritance. The different gonosomal status excludes the Y chromosome as a responsible factor. The peculiar finding of a 46,XX sex chromosome constitution combined with agonadism and an intact urogenitral tract emphasizes the concept of secondary regression of Wolffian and Müllerian structures. The associated malformations of mesodermal structures can be interpreted as midline defects. We suggest that, from the developmental field perspective, secondary regression of midline structures including the gonadal anlage explains the pathogenesis reasonably well.

Mirror-symmetric duplicated chromosome 21q with minor proximal deletion, and with neocentromere in a child without the classical Down syndrome phenotype.

We report on a mentally retarded child with multiple minor anomalies and an unusually rearranged chromosome 21. This der(21) chromosome has a deletion of 21p and of proximal 21q, whereas the main portion of 21q is duplicated leading to a mirror-symmetric appearance with the mirror axis at the breakpoint. The centromere is only characterized by a secondary constriction (with a centromeric index of a G chromosome) at an unexpected distal position, but fluorescence in situ hybridization (FISH) with either chromosome specific or with all human centromeres alpha satellite DNA shows no cross hybridization. Thus, the marker chromosome represents a further example of an "analphoid marker with neocentromere." Molecular analysis using polymorphic markers on chromosome 21 verified a very small monosomic segment of the proximal long arm of chromosome 21, and additionally trisomy of the remaining distal segment. Although trisomic for almost the entire 21q arm, our patient shows no classical Down syndrome phenotype, but only a few minor anomalies found in trisomy 21 and in monosomy of proximal 21q, respectively.

X/autosome translocation in three generations ascertained through an infant with trisomy 16p due to failure of spreading of X-inactivation.

We report on a reciprocal translocation t(X;16)(q28;p12) detected in a newborn girl with clinical manifestations of partial trisomy 16p. A balanced translocation was found in the mother and in the maternal grandmother. Replication studies on lymphocytes and fibroblasts showed nonrandom X-inactivation in both the patient and her mother. In the mother, the derivative X (der(X)) was active, whereas the normal X was late replicating. In contrast, in the patient the der(X) was late replicating, and there was no spreading of X-inactivation onto the autosomal segment, thus giving an explanation for the full clinical picture of partial trisomy 16p.

Agonadism in two sisters with XY gonosomal constitution, mental retardation, short stature, severely retarded bone age, and multiple extragenital malformations: a new autosomal recessive syndrome.

We report on 12- and 14-year old sisters with a 46, XY chromosome constitution, normal female external genitalia, and absence of gonadal tissue. Except for omphalocele, right renal agenesis and malrotation of the colon in the elder sister, the internal organs were normal. Both were mentally retarded, of short stature, and had extremely retarded bone age. In addition, they had an almost identical pattern of minor anomalies: peculiar face, hypodontia, short neck, inverted nipples, thoracolumbar scoliosis, "dysplastic" hips, partial clino-/syndactyly of toes. The occurrence of a basically similar set of malformations in two sisters and the first cousin consanguinity of the parents suggests autosomal recessive inheritance. The conserved region of the SRY gene ([high mobility group] HMG box) was sequenced in the elder sib and was normal. No consistent malformations are observed at present in agonadal patients. This supports the idea that several autosomal genes have the potential of influencing the sequence of events of sex determination.

XX-agonadism in a fetus with multiple dysraphic lesions: a new syndrome.

We report on a 19-week-old fetus with a 46,XX karyotype, normal female external genitalia, complete gonadal agenesis, large encephalocele, spina bifida, and omphalocele. We postulate a new syndrome. Hitherto no consistent malformation patterns have been observed in agonadism patients. True agonadism, including even the unusual finding of an XX gonosomal status, is obviously not as rare as suggested.

Diagnosis of retinoblastoma in a presymptomatic stage after detection of interstitial chromosomal deletion 13q.

In a newborn with only minor malformations the finding of an extended interstitial chromosome deletion 13q was unexpectedly found [46,XY,del(13) (q14.11q22.2)]. The included deletion of chromosome band 13q14, which is known to be predisposing for retinoblastoma (Rb), gave rise to subsequent ophthalmological inspection. A multifocal tumor was detected immediately in the right eye and 11 months later contralaterally. In contrast to the Knudson hypothesis, which suggests a high risk of a multifocal and bilateral tumor in patients with an inherited mutation of the RB-1 gene, literature data indicate a reduced tumorigenesis in patients with a cytogenetic deletion of the critical Rb region of chromosome 13. However, the authors' patient shows that even with a cytogenetic deletion early, bilateral, and multifocal tumor formation is possible. Reliable risk estimates of tumorigenesis for patients with a chromosome deletion cannot be given, since most of these were ascertained by their tumor.

Congenital prosopagnosia: multistage anatomical and functional deficits in face processing circuitry.

Face recognition is a primary social skill which depends on a distributed neural network. A pronounced face recognition deficit in the absence of any lesion is seen in congenital prosopagnosia. This study investigating 24 congenital prosopagnosic subjects and 25 control subjects aims at elucidating its neural basis with fMRI and voxel-based morphometry. We found a comprehensive behavioral pattern, an impairment in visual recognition for faces and buildings that spared long-term memory for faces with negative valence. Anatomical analysis revealed diminished gray matter density in the bilateral lingual gyrus, the right middle temporal gyrus, and the dorsolateral prefrontal cortex. In most of these areas, gray matter density correlated with memory success. Decreased functional activation was found in the left fusiform gyrus, a crucial area for face processing, and in the dorsolateral prefrontal cortex, whereas activation of the medial prefrontal cortex was enhanced. Hence, our data lend strength to the hypothesis that congenital prosopagnosia is explained by network dysfunction and suggest that anatomic curtailing of visual processing in the lingual gyrus plays a substantial role. The dysfunctional circuitry further encompasses the fusiform gyrus and the dorsolateral prefrontal cortex, which may contribute to their difficulties in long-term memory for complex visual information. Despite their deficits in face identity recognition, processing of emotion related information is preserved and possibly mediated by the medial prefrontal cortex. Congenital prosopagnosia may, therefore, be a blueprint of differential curtailing in networks of visual cognition.

Mosaic status in lymphocytes of infertile men with or without Klinefelter syndrome.

BACKGROUND: Gonosomal aneuploidies such as Klinefelter syndrome (47,XXY) are the most frequent chromosomal aberration in infertile men. Normally the chromosomal status of patients is detected by karyotyping of up to 20 metaphase spreads of lymphocyte nuclei, whereby low grade mosaicism may be overlooked. To test whether Klinefelter patients with 47,XXY karyotype or infertile men with 46,XY karyotype represent gonosomal mosaicisms, we performed meta- and interphase fluorescence in situ hybridization (FISH) on 45 men. METHODS AND RESULTS: A total of 400 interphase and 40 metaphase lymphocyte nuclei per patient were scored after hybridization with DNA probes specific for chromosomes X and Y, and chromosome 9 as a control. On the basis of conventional karyotype, hormone levels and clinical appearance, patients were subdivided into 18 Klinefelter syndrome patients with 47,XXY (group I), 11 Klinefelter syndrome-like patients with normal karyotype, 46,XY (group II) and six non-Klinefelter-like infertile patients with normal 46,XY karyotype (group III). Ten normal men (group IV) served as controls. Testicular volume in the Klinefelter group I was smaller compared with group II (P = 0.016), group III (P < 0.001) and group IV (P < 0.001). In addition, testicular volumes in group II were lower compared with group III and group IV (P < 0.004). No significant differences between the aneuploidy rate analysed by FISH in interphase nuclei and metaphases were found in either single patients or groups. Patients with Klinefelter syndrome, 47,XXY (group I) or with symptoms similar to those in Klinefelter patients 46,XY (group II) showed a similar aneuploidy rate (group I 7.1 +/- 4.0% and group II 4.6 +/- 3.4%) and two 47,XXY patients with a high prevalence for normal 46,XY lymphocytes had sperm in their ejaculate. However, in general, no correlations between FISH mosaic status and serum hormone parameters, nor with ejaculate parameters were found. CONCLUSIONS: The results suggest that 47,XXY patients with an increased incidence of XY cells (average of 4.2 +/- 2.3) may have a higher probability of germ cells as we found sperm only in the ejaculate of Klinefelter syndrome patients with mosaic 46,XY cells (6.0 and 7.0%). On the other hand, 46,XY patients with mosaic sex chromosome aneuploidies detected by FISH analysis more often show symptoms of hypogonadism phenotypically resembling Klinefelter syndrome.

Differentiated recurrence risk estimations in the Prader-Willi syndrome.

The Prader-Willi syndrome usually occurs sporadically. About 60% of the patients show a chromosomal deletion of proximal 15q. There are only a few reports on familial recurrence. Two previous estimates give either a low but recognizable recurrence risk of 1.6% or a risk of less than 0.1%. The inconsistency is obviously due to differences in the stringency of the diagnostic criteria used and to different modes of ascertainment of cases. This gave rise to a review of the literature, leading to the following suggestions: (1) A deletion at 15q has not been found in a familial case of PWS, except in those cases where del(15q) is due to familial structural chromosome rearrangements. Hence, with de novo deletion, the recurrence risk should be nearly zero. (2) In cases with familial translocation, risk estimates depend on the variable nature of the familial chromosome mutation. (3) If only one child is affected and has no deletion at 15q, this may be a sporadic or an isolated familial case. For this situation I estimated an overall recurrence risk of 0.4%. (4) If two or more sibs are affected, I consider a risk of 50% that the next sib may also be affected. This estimate reflects the observed segregation ratio and is in accordance with the proposed genomic imprinting model in the etiology of PWS. Prenatal cytogenetic diagnosis in a pregnancy at risk for PWS is hampered since del(15q) is almost exclusively found in sporadic cases. Hence, this method is limited to those very rare cases where del(15q) is due to familial structural chromosome rearrangements.(ABSTRACT TRUNCATED AT 250 WORDS)

A genetic model for the Prader-Willi syndrome and its implication for Angelman syndrome.

Sporadic cases of Prader-Willi syndrome (PWS) are associated with the physical absence of the paternal Prader-Willi chromosome region (PWCR) by deletion 15q11-13, by segmental maternal heterodisomy or by chromosome rearrangements resulting in homozygosity for maternal PWCR. In isolated/familial cases, it is proposed that the expression of PWS depends on the functional absence caused by mutated gene(s) within the paternal PWCR. The same mutation on a maternally derived chromosome 15 is not able to express PWS. An epigenetic mechanism associated with the paternal meiosis is essential. In the Angelman syndrome (AS), inverse mechanisms are postulated. There is convincing evidence for specific PWS and AS genes or alleles within PWCR. This is compatible with the observations of interstitial chromosome deletions of the critical region in normal individuals or in probands with phenotypes other than PWS or AS. The new ideas of the model stated here are: (1) the proposed epigenetic mechanism in PWCR is obviously common in humans, but is usually of no phenotypic relevance; (2) interactions with specific chromosomal or gene mutations are required for the clinical expression of PWS or AS; (3) each factor alone is not able to produce an abnormal phenotype.

Intrauterine growth retardation associated with chromosomal aneuploidy confined to the placenta. Three observations: triple trisomy 6,21,22; trisomy 16; and trisomy 18.

Cytogenetic analysis in three pregnancies revealed chromosomal mosaicism confined to chorionic villi. They were ascertained in the third trimester by intrauterine growth retardation (IUGR) in otherwise normal fetuses. In case of triple trisomy 6,21,22 and trisomy 16, it was obvious that these findings were most likely restricted to the placenta. These trisomies act as early lethal factors when they occur in the embryo itself. With trisomy 18, however, the interpretation of the cytogenetic finding remains ambiguous. The question arises as to whether an abnormal karyotype may be the cause of placenta insufficiency or is just coincidentally associated.