A rare non-Robertsonian translocation involving chromosomes 15 and 21

CONTEXT: Robertsonian translocations (RT) are among the most common balanced structural rearrangements in humans and comprise complete chromatin fusion of the long arm of two acrocentric chromosomes. Nevertheless, non-Robertsonian translocation involving these chromosomes is a rare event. CASE REPORT: We report a de novo unbalanced translocation involving chromosomes 15 and 21. The newborn was the daughter of a 29-year-old mother and a 42-year-old father. The couple was non-consanguineous. Clinical findings led to the diagnosis of Down syndrome (DS) with severe congenital heart defects (persistent arterial duct, and complete atrioventricular septal defect), as well as low birth length and weight (< 5th and < 10th percentile, respectively, based on specific measurement curves for DS). Conventional cytogenetic analysis revealed the karyotype 46,XX,der(15)(15pter→15q26.2::21q11.2→21qter). The translocation was confirmed by means of fluorescence in situ hybridization. The parents had normal karyotypes. CONCLUSIONS: Differently from RT, in our case a rare event occurred involving the distal segment of 15q and the proximal segment of 21q. Only two reports of this translocation, involving chromosomes 15 and 21 but different breakpoints, have been described so far. The association between 21q duplication and 15q deletion makes it difficult to separate the effect of each chromosome, but might also be responsible for increasing the growth retardation, as detected in our case. Cytogenetic analysis on DS patients is mandatory not only to confirm the diagnosis, but also to assess the risk of recurrence at genetic counseling, as well as to evaluate the contribution of other chromosome aberrations in the final phenotype.


INTRODUCTION
The majority (approximately 95%) of Down syndrome cases are caused by simple trisomy of chromosome 21.2][3] Almost all of these translocations involve a Robertsonian translocation, which comprises the longarm elements of two acrocentric chromosomes (chromosomes 13, 14, 15, 21 and 22). 3 Less common distinct forms of Down syndrome result from structural changes in chromosome 21.For example, reciprocal translocations are extraordinarily rare and are the cause of less than 0.1% of Down syndrome cases.These translocations with partial trisomy have been used to define a Down syndrome critical region or Down syndrome loci, consisting of a segment of the long arm of chromosome 21. 1,2cent studies have attempted to delineate an association between rare terminal deletions of the long arm of chromosome 15 and a specific phenotype, in particular short stature caused especially by the loss of one copy of the IGF1R (insulin-like growth factor receptor) gene. 4,5e main aim of this study was to report a very rare de novo of vaginal delivery with a birth length of 41 cm (< 5 th percentile), weight of 2000 g (< 10 th percentile) and head circumference of 33 cm (50 th percentile, all measurement based on a standard chart for Down syndrome). 6inical examination revealed hypotonia, brachycephaly, frontal bossing, flat face, upslanting palpebral fissures, protruding tongue, short neck with excess skin, brachydactyly, clinodactyly of the fifth fingers with a single interdigital crease on the right side and overlapping toes (Figure 1).At the age of three months, her length (51.5 cm) and weight (3,350 g) were still < 5 th and < 10 th percentiles, respectively, and her head circumference (36 cm) was normal, based on specific standard measurement charts for Down syndrome. 6Echocardiography showed a persistent arterial duct, and a complete atrioventricular septal defect, which included a ventricular septal defect.
Metaphase chromosome spreads were obtained from temporary lymphocyte cultures and the slides were subjected to Giemsa trypsin G-banding (GTG-banding).Fluorescence in situ hybridization (FISH) was performed using commercial probes.Unfortunately, the patient did not return for a follow-up and our service was unable to contact this specific patient/family due to a change in their address and phone number.Consequently, it was impossible to have more information about this case and to collect more blood samples.

DISCUSSION
A translocation involving chromosome 21 has the potential to produce duplication of the Down syndrome critical region. 1,2plication of a long segment of 21q could explain the predominant Down syndrome phenotype, as detected in our case.9][10][11][12][13] A large number of genes have been mapped within the terminal 15q region, and among them, IGF1R seems to play the main role in the phenotype of 15qter syndrome.Copy number variations of this gene result in prenatal and postnatal growth restriction.Additionally, IGF1R contributes towards development of the central nervous and cardiovascular systems. 4,5,12r study had some limitations due to the loss of contact with the patient.For example, we were unable to observe the IGF1 levels, which might have shown evidence of the IGF1R deficiency.
][9][10][11][12][13] All these features and the Down syndrome findings overlap.For this reason, it was difficult to separate the effects of 21q duplication from those of 15q deletion, in our case.The association between these two chromosomal aberrations may have been responsible for increasing the growth retardation in our case.
To the best of our knowledge (Table 1), only two reports on non-Robertsonian translocation, involving chromosomes 15 and 21, have been published so far.Abeliovich et al. described the karyotype t(15;21)(q15;q22.1)pat in two siblings. 14One of them had Prader-Willi syndrome.An interesting case of a patient with typical Down syndrome phenotype and apparently normal karyotype was studied by Nadal et al. 15 Using FISH, these authors found the unbalanced karyotype t(15;21)(q26;q22.1). 14e father and other members of the family carried a balanced translocation between chromosomes 15 and 21.Although these cases have some similarities to our patient, these three translocations present different breakpoints.A deeper search with more complex and more expensive methods, such as array comparative

CONCLUSION
An association between these two chromosomal aberrations could be responsible for increasing the growth retardation, as detected in our case.
Cytogenetic analysis on Down syndrome patients is mandatory, not only to confirm the diagnosis, but also to assess the risk of recurrence at genetic counseling, in particular when translocations are involved.Moreover, this makes it possible to evaluate the contribution of other chromosome aberrations to the final phenotype.
non-Robertsonian translocation involving chromosomes 15 and 21, and to show the importance of cytogenetic investigation in all cases of clinical diagnosis of Down syndrome.CASE REPORT A female newborn was referred to the Genetic Counseling Service of Universidade Estadual Paulista (Unesp), Botucatu, São Paulo, with a clinical diagnosis of Down syndrome.She was the only child of non-consanguineous parents.Her 29-year-old mother was normal and her 42-year-old healthy father had a normal daughter from a previous marriage.Ultrasound examination during pregnancy detected the presence of oligohydramnios, but no renal malformations.She was born at term by means

Figure 1 .
Figure 1.The patient at the age of three months.(A) Face, (B) profile, (C) feet (note the overlapping toes).
CGH), might have clarified some points such as the precise breakpoints.Unfortunately, we were unable to obtain further blood samples from this patient.On the other hand, the techniques carried out in our study were sufficient to show the rare non-Robertsonian translocation, the involvement of chromosomes 21 and 15 and the chromosome 21 trisomy.The results obtained provide evidence for the occurrence of this atypical chromosome aberration, and for the importance of cytogenetic analysis.