Identification and characterization of a new type of asymmetrical dicentric chromosome derived from a single maternal chromosome 18.

Molecular cytogenetic analysis identified a new type of dicentric chromosome involving different breakpoints at 18q in a female fetus. The chromosome anomaly was designated as an asymmetrical pseudoisodicentric chromosome 18, 46,XX,psu dic(18)(pter-->q11.2::q21.3-->pter)mat. A series of BAC clones for 18q11.2 and q21.3 regions were used to identify one breakpoint within the region q11.2 between 19.8 and 21.6 Mb from the telomere of 18p and another breakpoint within q21.3 between 55.4 and 56.9 Mb from the telomere of 18p by FISH analysis. Real-time quantitative PCR and microsatellite analysis further verified that the dicentric chromosome was maternal in origin and resulted from a break-reunion between sister chromatids of a single maternal chromosome. We propose that a loop-type configuration of sister chromatids took place and that the break-reunion occurred at cross sites of the loop to form an asymmetrical isodicentric chromosome during either mitosis or meiosis. In this case, the asymmetrical pseudoisodicentric resulted in an 18pter--> q11.2 duplication and an 18q21.3-->qter deletion, which could have led to certain dysmorphic features of 18q- syndrome in this fetus.

Spectral karyotyping and fluorescence in situ hybridization analysis of de novo partial trisomy 7p (7p21.2-->pter) and partial monosomy 12q (12q24.33-->qter).

An 8-year-old boy presenting with hypotonia, moderate mental retardation, developmental delay, and psychomotor retardation is reported. Magnetic resonance imaging of the brain at age 3 years revealed a Dandy-Walker variant. Cytogenetic analysis of the peripheral blood revealed a derivative chromosome 12 with unknown additional material attached to the distal region of the long arm of chromosome 12. The parental karyotypes were normal. Spectral karyotyping (SKY) using the 24-color SKY probes and fluorescence in situ hybridization (FISH) using the specific 7p, 7q, 12p, and 12q telomeric probes confirmed a duplication of distal 7p and a deletion of terminal 12q. The karyotype of the proband was designated as 46,XY.ish der(12)t(7;12) (p21.2;q24. 33)(SKY+, 7pTEL+, 12qTEL-). The present case provides evidence for the association of partial trisomy 7p (7p21.2-->pter) and partial monosomy 12q (12q24.33-->qter) with a cerebellar malformation and the usefulness of SKY and FISH in the identification of a de novo aberrant chromosome resulting from an unbalanced translocation.

Karyotypic evolution of a novel cervid satellite DNA family isolated by microdissection from the Indian muntjac Y-chromosome.

A minilibrary was constructed from DOP-PCR products using microdissected Y-chromosomes of Indian muntjac as DNA templates. Two microclones designated as IM-Y4-52 and IM-Y5-7 were obtained from negative screening of all three cervid satellite DNAs (satellites I, II, and IV). These two microclones were 295 and 382 bp in size, respectively, and shared approximately 70% sequence homology. Southern blot analysis showed that the IM-Y4-52 clone was repetitive in nature with an approximately 0.32-kb register in HaeIII digest. Sequence comparison revealed no similarities to DNA sequences deposited in the GenBank database, suggesting that the microclone sequences were from a novel satellite DNA family designated as cervid satellite V. A subclone of an Indian muntjac BAC clone which screened positive for IM-Y4-52 had a 3,325-bp insert containing six intact monomers, four deleted monomers, and two partial monomers. The consensus sequence of the monomer was 328 bp in length and shared more than 80% sequence homology with every intact monomer. A zoo blot study using IM-Y4-52 as a probe showed that the strong hybridization with EcoRI digested male genomic DNA of Indian muntjac, Formosan muntjac, Chinese muntjac, sambar deer, and Chinese water deer. Female genomic DNA of Indian muntjac, Chinese water deer, and Formosan muntjac also showed positive hybridization patterns. Satellite V was found to specifically localize to the Y heterochromatin region of the muntjacs, sambar deer, and Chinese water deer and to chromosome 3 of Indian muntjac and the X-chromosome of Chinese water deer.

Calreticulin expression in neuroblastoma--a novel independent prognostic factor.

BACKGROUND: Calreticulin (CRT), an endoplasmic reticulum protein, has been reported to be essential for the differentiation of neuroblastoma (NB) cells, suggesting that CRT may affect the tumor behavior of neuroblastoma. The aim of this study was to evaluate the association of clinicopathologic factors and patient survival with the expression of CRT in patients with NB. PATIENTS AND METHODS: Sixty-eight NBs were investigated by immunohistochemical staining against CRT, and were divided into positive and negative immunostaining groups. Correlations between calreticulin expression, various clinicopathologic and biologic factors, and patient survival were studied. In seven tumor samples, CRT mRNAs and proteins were evaluated with real-time PCR and western blot, respectively, and correlated with immunohistochemical findings. RESULTS: Among 68 NBs, 32 (47.1%) showed positive CRT expression. Positive CRT immunostaining strongly correlated with differentiated histologies, as well as known favorable prognostic factors such as detected from mass screening, younger age (< or =1 year) at diagnosis and early clinical stages, but inversely correlated with MYCN amplification. Kaplan-Meier analysis revealed that NB patients with CRT expression did have better survival. Multivariate analysis demonstrated CRT expression to be an independent prognostic factor. Moreover, CRT expression also predicted better survival in patients with advanced-stage NBs, and its absence predicted poorer survival in patients whose tumor had no MYCN amplification. The amount of CRT mRNAs and proteins in NB tumor samples tested correlated well with the immunohistochemical expressions. CONCLUSIONS: CRT expression correlates with the differentiation of NB and predicts favorable survival, thereby suggesting CRT to be a useful indicator for planning treatment of NB.

Cloning, characterization and physical mapping of three cervid satellite DNA families in the genome of the Formosan muntjac (Muntiacus reevesi micrurus).

Due to their high sequence diversity even among closely related species, satellite DNA sequences can be a useful molecular marker for phylogenetic and taxonomic analyses. To characterize the satellite DNA in the genome of a native muntjac species of Taiwan, the Formosan muntjac, satellite DNA clones representing three different cervid satellite DNA families from this species were isolated and analyzed. Genomic organization study of these satellite DNAs was also undertaken. Three Formosan muntjac satellite DNA clones were obtained and designated as FM-satI (1,391 bp), FM-satII (1,143 bp) and FM-satIV (1,103 bp), and found to share approximately 82, 81 and 98% sequence homology with the Chinese muntjac satellite I clone (C5), Indian muntjac satellite II clone (Mmv-0.7) and Chinese muntjac satellite IV clone (MR-1.0), respectively. These three satellite DNA families are organized in a pter<--FM-satII-FM-satIV-FM-satI-->qter orientation in the centromeric region with satII closely associated with the telomeric sequences. Satellite DNA sequence comparison, in combination with chromosome data concludes that the Formosan muntjac is likely a subspecies of M. reevesi, closely related to the Chinese muntjac. With the kinetochore satellite II DNA co-localizing with the telomeric sequences, the Formosan muntjac chromosomes could be truly telocentric.