Familial Klippel-Feil syndrome and paracentric inversion inv(8)(q22.2q23.3).

Klippel-Feil Syndrome (KFS) is characterized by congenital vertebral fusion believed to result from faulty segmentation along the embryo's developing axis. KFS appears to be a heterogeneous disease often associated with craniofacial malformation. Here we provide the first evidence of a familial KFS gene locus on 8q, where an inv(8)(q22.2q23.3) has been found segregating with congenital vertebral fusion. The four-generation KF2-01 family present with dominant form of the KFS where the sequence of vertebral fusion was confined to the cervical spine (always including the C2-3 fusion and reduced expression of the C4-5 and C6-7 fusions) in association with malformation of laryngeal cartilages and mild-to-severe vocal impairment.     

Familial paracentric inversion inv(3)(q21q25.1). Case report and review of the literature

A second case of a paracentric inversion 3q is described. This anomaly was detected during prenatal analysis and found to be inherited from the father.     

Mild phenotype due to inverse duplication 4p16.3 - P15.3 including the Wolf-Hirschhorn critical region

Duplication of distal 4p results in a recognizable clinical phenotype. We report here on a 3 year old girl with a de novo inverse duplication of the chromosome segment 4p16.3-p15.3. The symptoms in this patient are milder than those of previously described patients with 4p duplication syndrome and include a deep hairline, deep-set eyes, short pug nose, full cheeks, simian crease, clinodactily of the fifth digit, no speech development and a moderate psychomotor retardation. Fluorescence in situ hybridization (FISH) using a chromosome 4 painting probe confirmed that the extra material is of chromosome 4 origin. Further analysis with the Wolf-Hirschhorn critical region probe demonstrated the duplication of this region. The lysosomal hydrolase alpha-L-iduronidase (IDUA) gene which is mutated in mucopolysaccaridosis type I (MPS I) and mapped to 4p16.3 might be responsible for some of the MPS like facial features. A phenotype-genotype correlation analysis in combination with literature review was undertaken to allow a further delineation of partial trisomy 4p syndromes.     

A case of intersexuality in pigs associated with a de novo paracentric inversion 9 (p1.2; p2.2)

In several mammalian species, genetic defects can be responsible for the interruption of and/or the deviation from the sequential steps of normal gonadal differentiation, leading to a sex-reversal syndrome. In pigs, female-to-male sex-reversal conditions are particularly frequent, but their aetiologies remain unclear. Chromosomal abnormalities that co-occur with sex-reversal disorders can be useful in the identification of loci containing responsible or susceptibility genes. This report describes a female-to-male SRY-negative intersex pig with a de novo paracentric inversion of the short arm of one chromosome 9 (p1.2; p2.2). We have fine mapped the proximal chromosomal breakpoint of this rearrangement because it corresponded to a region potentially involved in the pig intersexuality. Fluorescent in situ hybridization (FISH) experiments carried out with Bacterial Artificial Chromosome (BAC) clones located within the critical region defined by genetic linkage analysis and ordered on the porcine RH map allowed us to locate the proximal breakpoint between markers SW2571 and SW539. Further investigations are currently in progress to find new markers inside this interval, in order to determine the BAC in which the break occurred.     

Cytogenetic analysis of sperm from a man heterozygous for a pericentric inversion, inv (3) (p25q21).

Human sperm chromosomes were studied in a man heterozygous for a pericentric inversion of chromosome 3(p25q21). The pronuclear chromosomes were analyzed after in vitro penetration of golden hamster eggs. A total of 144 sperm were examined: 69.2% were chromosomally balanced and 30.8% were recombinant. Of the balanced complements, the proportion with a normal chromosome 3 (37.6%) was approximately equal to the proportion with an inverted 3 (31.6%). Of the recombinant complements, the proportion of sperm with a duplication q/deletion p (17.3%) was approximately equal to the reciprocal event of duplication p/deletion q (13.5%). The recombinant chromosome 3 with a duplication q and deletion p has been observed in several abnormal children, but the duplication p/deletion q has never been reported. My results demonstrate that both recombinant chromosomes are produced as expected from an unequal number of crossovers within an inversion loop. In all likelihood the duplication p/deletion q chromosome is an early embryonic lethal because of the amount of genetic material deleted. The proportions of X-bearing (48.9%) and Y-bearing sperm (51.1%) were not significantly different from the expected 1:1 ratio. There was no evidence for an interchromosomal effect. Of the three inversions studied by human sperm chromosome analysis, recombinant chromosomes have been observed only in this case.     

Molecular analysis of deletion (17)(p11.2p11.2) in a family segregating a 17p paracentric inversion: implications for carriers of paracentric inversions.

A male child with multiple congenital anomalies initially was clinically diagnosed as having Smith-Lemli-Opitz syndrome (SLOS). Subsequent cytogenetic studies revealed an interstitial deletion of 17p11.2, which is associated with Smith-Magenis syndrome (SMS). Biochemical studies were not supportive of a diagnosis of SLOS, and the child did not display the typical SMS phenotype. The father's karyotype showed a paracentric inversion of 17p, with breakpoints in p11.2 and p13.3, and the same inversion was also found in two of the father's sisters. FISH analyses of the deleted and inverted 17p chromosomes indicated that the deletion was similar to that typically seen in SMS patients and was found to bracket the proximal inversion breakpoint. Available family members were genotyped at 33 polymorphic DNA loci in 17p. These studies determined that the deletion was of paternal origin and that the inversion was of grandpaternal origin. Haplotype analysis demonstrated that the 17p11.2 deletion arose following a recombination event involving the father's normal and inverted chromosome 17 homologues. A mechanism is proposed to explain the simultaneous deletion and apparent "reinversion" of the recombinant paternal chromosome. These findings have implications for prenatal counseling of carriers of paracentric inversions, who typically are considered to bear minimal reproductive risk.     

Familial paracentric inversions inv(2)(q31q35) and inv(8)(q22.3q24.13) ascertained through reproductive abnormalities

Summary Two cases of familial paracentric inversion, one in the long arm of chromosome 2 and the other in the long arm of chromosome 8, are described. The first was ascertained in a woman who was studied because of recurrent abortions. The second was ascertained in the father of a girl with the trichorhinophalangeal syndrome and an interstitial deletion in 8q. The latter is the first case in which unequal crossing over in an inversion loop can be inferred in a male carrier of a paracentric inversion. The reasons for the relatively low frequency of paracentric inversions observed and factors which affect the pregnancy outcome are discussed.     

A familial deletion 4q syndrome: An outcome of a paracentric inversion

Chromosome inversions are intra-chromosomal rearrangements formed when the chromosome breaks occur at two places, and in the process of repair the intervening segments are joined in an inverted or opposite manner. Inversions themselves do not appear to cause clinical anomalies, if balanced. Abnormal phenotypes can occur due to gene disruption at the point of breakage and reunion or due to duplication/deficiency recombinants formed during crossover at meiosis. We report a case with familial deletion 4q syndrome in a 1-year-old female child with dysmorphism and congenital abnormalities. The deletion was an outcome of a paracentric inversion 4q31.2q35.2. The deletion was confirmed by fluorescence in situ hybridization using telomeric DNA probes for chromosome No. 4. An attempt was made to correlate the genotype with the phenotype. The father had the same rearrangement with a milder phenotype. The recurrence risk in such cases is high.     

Familial paracentric inversion in(2)(q31q36)

Summary A paracentric inversion of chromosome 2 is described for the first time. The breakpoints were localized in the bands q31 and q36. The paracentric inversion was initially identified in a female with repeated abortions and thereafter detected in eight other family members over three generations. The meiotic consequences and the risk for liveborn unbalanced chromosomal recombinants is discussed.     

Familial inv(2) (p2300q11.2)

A hitherto undescribed inv(2) (p2300q11.2) was found in 2 generations of a family ascertained through a holoprosencephalic liveborn boy with normal karyotype. This inversion, quite probably not related to the child malformations, does not seem neither impair reproductive fitness nor to yield viable recombination aneusomies.     

Chromosomal localization of the human alpha-L-iduronidase gene (IDUA) to 4p16.3.

The lysosomal hydrolase alpha-L-iduronidase (IDUA) is one of the enzymes in the metabolic pathway responsible for the degradation of the glycosaminoglycans heparan sulfate and dermatan sulfate. In humans a deficiency of IDUA leads to the accumulation of glycosaminoglycans, resulting in the lysosomal storage disorder mucopolysaccharidosis type I. A genomic subclone and a cDNA clone encoding human IDUA were used to localize IDUA to chromosome 4p16.3 by in situ hybridization and this was confirmed by Southern blot analysis. This localization is different from that of a previous report mapping IDUA to chromosome 22 and places the gene for IDUA in the same region of chromosome 4 as the Huntington disease gene. Measurement of expressed human IDUA activity in human-mouse hybrid cell lines confirmed that IDUA is on chromosome 4.     

Prenatal detection of a paracentric inversion 16(q11.2q13)

We report the prenatal detection of an inherited paracentric inversion 16(q11.2q13).     

Impact of pericentric inversion of Chromosome 9 [inv (9) (p11q12)] on infertility

BACKGROUND:

One of the frequent occurrences in chromosome rearrangements is pericentric inversion of the Chromosome 9; inv (9) (p11q12), which is consider to be the variant of normal karyotype. Although it seems not to correlate with abnormal phenotypes, there have been many controversial reports indicating that it may lead to abnormal clinical conditions such as infertility. The incidence is found to be about 1.98% in the general population.

MATERIALS AND METHODS:

We investigated the karyotypes of 300 infertile couples (600 individuals) being referred to our infertility clinic using standard GTG banding for karyotype preparation.

RESULTS:

The chromosomal analysis revealed a total of 15 (2.5%) inversions, among these, 14 male patients were inversion 9 carriers (4.69%) while one female patient was affected (0.33%). The incidence of inversion 9 in male patients is significantly higher than that of normal population and even than that of female patients (P< 0.05).

CONCLUSIONS:

This result suggests that inversion 9 may often cause infertility in men due to spermatogenic disturbances, which are arisen by the loops or acentric fragments formed in meiosis.     

Pericentric inversion inv(7)(p11q21.1): report on two cases and genotype-phenotype correlations

We report on two unrelated cases of pericentric inversion 46,XY,inv(7)(p11q21.1) associated with distinct pattern of malformation including mental retardation, development delay, ectrodactyly, facial dismorphism, high arched palate. Additionally, one case was found to be characterized by mesodermal dysplasia. Cytogenetic analysis of the families indicated that one case was a paternally inherited inversion whereas another case was a maternally inherited one. Molecular cytogenetic studies have shown paternal inversion to have a breakpoint within centromeric heterochromatin being the cause of alphoid DNA loss. Maternal inversion was also associated with a breakpoint within centromeric heterochromatin as well as inverted euchromatic chromosome region flanked by two disrupted alphoid DNA blocks. Basing on molecular cytogenetic data we hypothesize the differences of clinical manifestations to be produced by a position effect due to localization of breakpoints within variable centromeric heterochromatin and, alternatively, due to differences in the location breakpoints, disrupteding different genes within region 7q21-q22. Our results reconfirm previous linkage analyses suggested 7q21-q22 as a locus of ectrodactily and propose inv (7)(p11q21.1) as a cause of recognizable pattern of malformations or a new chromosomal syndrome.     

Paracentric inversion inv(11) (q21q23) in the Netherlands

Summary We report the result of investigations from 20 families with 72 carriers of the paracentric inversion inv(11)(q21q23) in the Netherlands. There is no increase in the rate of spontaneous abortions among carriers of the inversion or their partners. Also, so far, there are no children with recombinant chromosomes arising from the inversion. It is doubtful whether prenatal diagnosis would be helpful to carriers of this inversion. The results of the genealogy study and geographical distribution are discussed; it is suggested that all the families have arisen from a single mutation.     

Chromosome 3 duplication q21 leads to qter deletion p25 leads to pter syndrome in children of carriers of a pericentric inversion inv(3) (p25q21).

Close phenotypic similarity between two cases carrying a rec(3) dup q,inv(3) (p25q21), 12 additional infants from the same inv (3)(p25q21) kindred who lived less than 1 year, and eight cases studied in other medical centers has led us to postulate the existence of a distinct chromosome 3 duplication-deletion syndrome. In the presence of trisomy for (3)q21 leads to qter and monosomy for (3)p25 leads to pter, the facial dysmorphy is unique: a distorted head shape due to irregular cranial sutures, thick low eyebrows, long eyelashes, persistent lanugo, distended veins on the scalp, hypertelorism, oblique palpebral fissures, a very short nose with a broad depressed bridge and anteverted nares, protruding maxilla, thin upper lip, micrognathia, low-set ears, and a short webbed neck. Port-wine stains, congenital glaucoma, cloudy corneas, cleft palate and harelip also occur frequently. Each infant has difficulty sucking and swallowing. Congenital anomalies of the cardiovascular system, of midgut rotation, and of the urogenital system are noted for the infants who died neonatally. Most frequent is a ventricular septal defect, followed by atrial septal defect, patent ductus arteriosus, patent foramen ovale, and coarctation of the aorta. Omphalocele, umbilical hernia, hyperplastic kidneys, polycystic kidneys, double ureter, hydro-ureter, hydronephrosis, and undescended testes often occur. The extremities are short in proportion to the length of the trunk. Clinodactyly, coxa valga, talipes, and spina bifida are frequently observed.     

Sequence-tagged sites (STSs) spanning 4p16.3 and the Huntington disease candidate region.

The generation of sequence-tagged sites (STSs) has been proposed as a unifying approach to correlating the disparate results generated by genetic and various physical techniques being used to map the human genome. We have developed an STS map to complement the existing physical and genetic maps of 4p16.3, the region containing the Huntington disease gene. A total of 18 STSs span over 4 Mb of 4p16.3, with an average spacing of about 250 kb. Eleven of the STSs are located within the primary candidate HD region of 2.5 Mb between D4S126 and D4S168. The availability of STSs makes the corresponding loci accessibility to the general community without the need for distribution of cloned DNA. These STSs should also provide the means to isolate yeast artificial chromosome clones spanning the HD candidate region.     

Mouse paracentric inversion In(3)55Rk mutates the urate oxidase gene

The paracentric inversion In(3)55Rk on mouse Chromosome 3 (Chr 3) was induced by cesium irradiation. Genetic crosses indicate the proximal breakpoint cosegregates with D3Mit324 and D3Mit92; the distal breakpoint cosegregates with D3Mit127, D3Mit160, and D3Mit200. Giemsa-banded chromosomes show the inversion spans approximately 80% of Chr 3. The proximal breakpoint occurs within band 3A2, not 3B as reported previously; the distal breakpoint occurs within band 3H3. Mice homozygous for the inversion exhibit nephropathy indicative of uricase deficiency. Southern blot analyses of urate oxidase, Uox, show two RFLPs of genomic mutant DNA: an EcoRI site between exons 4-8 and a BamHI site 3' to exon 6. Mutant cDNA fails to amplify downstream of base 844 at the 3' end of exon 7. FISH analysis of chromosomes from inversion heterozygotes, using a cosmid clone containing genomic wild-type DNA for Uox exons 2-4, shows that a 5' segment of the mutated Uox allele on the inverted chromosome has been transposed from the distal breakpoint region to the proximal breakpoint region. Clinical, histopathological, and Northern analyses indicate that our radiation-induced mutation, uox(In), is a putative null.