Cytokines as a common components of two different disorders: metabolic syndrome and hemophagocytic lymphohystiositosis.

Increased cytokines secretion occurs in several different disorders. Hemophagocytic lymphohystiositosis (HLH) and metabolic syndrome (MS) are consist two of them. Hemophagocytic lymphohystiositosis results from uncontrolled macrophage activation and huge amounts of cytokine secretion. The metabolic syndrome is a multicomponent condition characterized by insulin resistance, dyslipidemia, abdominal obesity, hypertension, and increased level of proinflammatory cytokines. It was presented a 6.8 years old girl, diagnosed as HLH. Because she was morbid obese, endocrinological investigation had been done and metabolic syndrome, thyroid hormone dysfunction, and hypercortisolemia with disturbances of diurnal rhythm were detected. During follow-up of patient, metabolic syndrome components disappear gradually while haemophagocytosis was recovered. Endocrine system can be affect during HLH attack, and MS can be developed. Cytokines seems to act central role of pathological changes for both diseases.

31 cases with oculoauriculovertebral dysplasia (Goldenhar syndrome): clinical, neuroradiologic, audiologic and cytogenetic findings.

Goldenhar syndrome (GS) or oculoauriculovertebral dysplasia (OAVD) is characterized by pre-auricular skin tags, microtia, facial asymmetry, ocular abnormalities and vertebral anomalies of different size and shape. The phenotypical findings of this syndrome are variable due to heterogenous aetiology. For that reason, the physician sometimes faces difficulty when making a definite diagnosis of OAVD. We reviewed the clinical and laboratory findings of 31 patients (15 boys and 16 girls) aged from 1 day to 16 years with the clinical diagnosis of GS. The characteristic features were pre-auricular skin tags (90%), microtia (52%), hemifacial microsomia (77%) and epibulbar dermoids (39%). Vertebral anomalies were noted in 70% of the patients. Cardiac malformations were found in 39% while a genitourinary anomaly was noted in 23% and various central nervous system malformations in 47%. There were 3 pregnancies following an intracytoplasmic sperm injection (ICSI) technique among the 31 patients. Two patients with GS came from the same family. Their relatives had hydrocephaly, myelomeningocele and neural tube defects. It is known that some chromosomal aberrations are seen in GS. We performed chromosome analysis of 29 patients. Among these cases, only one patient with severe mental and motor retardation had a 47,XX,+der(22)t(11,22)(q23; q11 karyotype due to a maternal balanced translocation t(11;22)(q23;q11). This translocation was demonstrated in her sister, brother and maternal uncle. Additionally CATCH 22 analysis in 13 cases with OAVD with a CATCH 22 phenotype revealed no deletion. OAVD patients present with different morphologic features and systemic manifestations. A multidisciplinary approach should be undertaken by departments such as pediatric cardiology, audiology, ophthalmology and plastic surgery when evaluating patients with OAVD. Chromosome analysis should be performed in every patient with Goldenhar syndrome.

The t(4;8) is mediated by homologous recombination between olfactory receptor gene clusters, but other 4p16 translocations occur at random.

The t(4;8)(p16;p23) is the second most common constitutional chromosomal translocation and is caused by an ectopic meiotic recombination between the olfactory receptor gene clusters (ORGC), located on chromosome 4p and 8p. Given that ORGCs are scattered across the genome and make-up about 0.1% of the human genome we reasoned that translocations between 4p16 and other chromosomes might be mediated by ectopic recombination between different ORGC. In 13 patients, we mapped the breakpoints of either a balanced or unbalanced translocation between chromosome 4p16 and different chromosomes. For all four t(4;8) cases, the breakpoints fall within the 4p and 8pter ORGC, confirming that non-allelic homologous recombination (NAHR) between the ORGC is the main mechanism of the t(4;8) formation. For the nine other translocations, the breakpoints on chromosome 4 mapped to different loci, one of them within the ORGC and in two flanking the ORGC. In these three cases, the translocation breakpoint at the reciprocal chromosome did not contain ORGC sequences. We conclude that only the t(4;8) is mediated by NAHR between ORGC.

Partial trisomy (11;22) syndrome with manifestations of Goldenhar sequence due to maternal balanced t(11;22).

Here we report a 15-year-old girl patient who had severe mental and growth retardation, cleft palate, hemifacial microsomia, skin tags, hypoplasia of the external auditory canal, scoliosis and renal agenesis. Our patient was the fourth child of nonconsanguineous marriage. Peripheral blood chromosomal analysis of the patient revealed 47,XX,+der(22)t(11;22)(q23;q11). The maternal karyotype was reported as 46,XX,t(11;22)(q23;q11). Maternal balanced translocation t(11;22)(q23;q11) causing Goldenhar syndrome with 47,XX,+der(22) has not been reported previously. The presented case clearly indicates that in every case with Goldenhar syndrome, chromosome analysis should be done for the possibility of unbalanced translocations.