Chromosome

About: Chromosome is a research topic. Over the lifetime, 17538 publications have been published within this topic receiving 660077 citations. The topic is also known as: chromosomes & GO:0005694.

Human neuroblastomas and abnormalities of chromosomes 1 and 17.

Abstract: Structural rearrangements of chromosome 1p have been reported previously as a frequent finding in human neuroblastomas. In a review of karyotypes from 35 neuroblastomas (including 29 published cases and 6 unpublished tumors and cell lines), it was found that, in addition to the abnormalities of chromosome 1p (found in approximately 70% of cases), abnormalities involving only 2 other chromosome segments occurred with significant frequency (in 20% or more of cases) in this cancer. These abnormalities involved trisomies for the long arms of chromosomes 1 and 17. In addition, two novel cytogenetic aberrations, homogeneously staining regions and double minutes, were identified in two-thirds of the cases. It is postulated that the gene change(s) produced by the abnormalities of chromosome 1p in neuroblastoma play a primary role in the development of this cancer. The gene changes produced by the abnormalities of chromosomes 1q and 17q and by the homogeneously staining regions and double minutes are presumed to contribute to tumor progression.

High-resolution chromosomal localization of human genes for amylase, proopiomelanocortin, somatostatin, and a DNA fragment (D3S1) by in situ hybridization

Abstract: The method of in situ hybridization has become a significant technique for specific-site chromosome mapping. We show that the resolution of in situ hybridization can be increased by hybridizing the probe to stretched prometaphase chromosomes with high-resolution banding obtained after 5-bromodeoxyuridine treatment of the cells and with a Hoechst 33258/Giemsa chromosome-staining method. Using this procedure, we assigned to specific chromosome sites three cloned genes and one DNA polymorphism: amylase gene (AMY) to 1p21; proopiomelanocortin gene (POMC) to 2p23, somatostatin gene (SST) to 3q28, and a single copy DNA segment (D3S1) to 3q12.

A central role for chromosome breakage in gene amplification, deletion formation, and amplicon integration.

Abstract: A CHO cell line with a single copy of the DHFR locus on chromosome Z2 was used to analyze the structure of the amplification target and products subsequent to the initial amplification event. Dramatic diversity in the number and cytogenetic characteristics of DHFR amplicons was observed as soon as eight to nine cell doublings following the initial event. Two amplicon classes were noted at this early time: Small extrachromosomal elements and closely spaced chromosomal amplicons were detected in 30-40% of metaphases in six of nine clones, whereas three of nine clones contained huge amplicons spanning greater than 50 megabases. In contrast, the incidence of metaphases containing extrachromosomal amplicons fell to 1-2% in cells analyzed at 30-35 cell doublings, and most amplicons localized to rearranged or broken derivatives of chromosome Z2 at this time. Breakage of the Z2 chromosome near the DHFR gene, and deletion of the DHFR gene and flanking DNA was also observed in cells that had undergone the amplification process. To account for these diverse cytogenetic and molecular consequences of gene amplification, we propose that chromosome breakage plays a central role in the amplification process by (1) generating intermediates that are initially acentric and lead to copy number increase primarily by unequal segregation, (2) creating atelomeric ends that are either incompletely replicated or resected by exonucleases to generate deletions, and (3) producing recombinogenic ends that provide preferred sites for amplicon relocalization.