Definition and characterization of a region of 1p36.3 consistently deleted in neuroblastoma.

Substantial genomic and functional evidence from primary tumors and cell lines indicates that a consistent region of distal chromosome 1p is deleted in a sizable proportion of human neuroblastomas, suggesting that this region contains one or more tumor suppressor genes. To determine systematically and precisely the location and extent of 1p deletion in neuroblastomas, we performed allelic loss studies of 737 primary neuroblastomas and genotype analysis of 46 neuroblastoma cell lines. Together, the results defined a single region within 1p36.3 that was consistently deleted in 25% of tumors and 87% of cell lines. Two neuroblastoma patients had constitutional deletions of distal 1p36 that overlapped the tumor-defined region. The tumor- and constitutionally-derived deletions together defined a smallest region of consistent deletion (SRD) between D1S2795 and D1S253. The 1p36.3 SRD was deleted in all but one of the 184 tumors with 1p deletion. Physical mapping and DNA sequencing determined that the SRD minimally spans an estimated 729 kb. Genomic content and sequence analysis of the SRD identified 15 characterized, nine uncharacterized, and six predicted genes in the region. The RNA expression profiles of 21 of the genes were investigated in a variety of normal tissues. The SHREW1 and KCNAB2 genes both had tissue-restricted expression patterns, including expression in the nervous system. In addition, a novel gene (CHD5) with strong homology to proteins involved in chromatin remodeling was expressed mainly in neural tissues. Together, these results suggest that one or more genes involved in neuroblastoma tumorigenesis or tumor progression are likely contained within this region.

CHD5, a new member of the chromodomain gene family, is preferentially expressed in the nervous system.

Chromatin remodeling is one of the mechanisms by which gene expression is regulated developmentally. Chromatin structure is controlled at least in part by post-translational modification of histones, as well as by chromodomain proteins. We have identified a novel gene encoding a protein with chromatin remodeling, helicase and DNA-binding motifs. This gene, called CHD5, is the fifth member of the CHD gene family identified in humans. This gene is most homologous to CHD3 and CHD4, which encode proteins that are part of the nucleosome remodeling and histone deacetylation (NuRD) complex. CHD5 is preferentially expressed in total brain, fetal brain, and cerebellum. It is also moderately expressed in the adrenal gland, but expression is undetectable in almost all other tissues examined. CHD5 maps within a small region of deletion on 1p36.3 in human neuroblastomas, a common pediatric tumor. We examined a panel of neuroblastoma cell lines for CHD5 expression, which was consistently low or undetectable in all these lines. Expression was also examined in a panel of 137 primary neuroblastomas, and low expression was highly correlated with 1p deletion, MYCN amplification, advanced stage, and unfavorable histology. These findings suggest that this gene may play a role in the development of the nervous system, and it may also play a role in the pathogenesis of neural tumors.

Expression of a MYCN-interacting isoform of the tumor suppressor BIN1 is reduced in neuroblastomas with unfavorable biological features.

PURPOSE: Amplification of the MYCN proto-oncogene is strongly correlated with poor outcome in neuroblastoma (NB), although deregulated MYCN is a potent inducer of apoptosis. BIN1 (2q14) encodes multiple isoforms of a Myc-interacting adaptor protein that has features of a tumor suppressor, including the ability to inhibit Myc-mediated cell transformation and to promote apoptosis. We hypothesized that BIN1 may function as a suppressor gene in NB, because Bin1 is highly expressed in neural tissues and binds the Myc Box motifs that are conserved in MycN. EXPERMENTAL DESIGN: Expression of MYCN, total BIN1, and BIN1 isoforms were determined in 56 primary NBs using the real-time PCR. Expression was correlated with biological and genetic features. To determine the functional significance of BIN1 expression we ectopically expressed BIN1 isoforms in NB cell lines with and without MYCN amplification, and assessed clonogenic growth. RESULTS: Four predominant BIN1 isoforms resulting from alternative splicing of exon 12A (a neural tissue-specific exon) and exon 13 (a Myc-binding domain encoding exon) were variably expressed in the 56 primary NBs. Expression of BIN1 was lower in: NBs with MYCN amplification (n = 10) compared with those without, P < 0.03; in International Neuroblastoma Risk Group high-risk NB (n = 19) compared with low- or intermediate-risk NB, P < 0.01; and in metastatic NB (n = 21) compared with localized NB, P < 0.06. BIN1 inactivation by deletion or genomic rearrangement was identified infrequently. Forced expression of BIN1 isoforms containing the Myc-binding domain (with or without exon 12A) inhibited colony formation in NB cell lines with MYCN amplification (P < 0.01) but not in those without. Forced expression of BIN1 isoforms with a MBD deletion did not inhibit colony formation in any cell line assessed. CONCLUSIONS: These data support that reduced BIN1 expression contributes to the malignant phenotype of childhood NB. As we reported previously, BIN1 may function to circumvent MycN-mediated apoptosis in NBs with MYCN amplification.

Communicating with dementia patients on hospice.

There are distinct differences in caringfor the "typical " hospice patient as opposed to the hospice patient who has Alzheimer's disease. The entire long-term care team, from volunteers to physicians, can benefit from hospice training in this area. This article addresses this topic in terms of what to be aware of in the disease process, understanding and responding to the caregiver's experience and needs, and, of course, patient care. Particular communication techniques are presented to facilitate interactions with the dementia patient at each of the stages of his or her disease.

Communicating with dementia patients on hospice.

There are distinct differences in caring, for the "typical" hospice patient as opposed to the hospice patient who has Alzheimer's disease. The entire hospice team from volunteers to physicians, can benefit from dementia-specific training in this area. This article addresses this topic in terms of what to be aware of in the disease process, understanding and responding to the caregiver's experience and needs, and, of course, patient care. Particular communication techniques are presented to facilitate interactions with the dementia patient at each of the stages of his or her disease.