The detection of acquired copy-number abnormalities (CNAs) and copy-neutral loss of heterozygosity (CN-LOH) in neoplastic disorders by chromosomal microarray analysis (CMA) has significantly increased over the past few years with respect to both the number of laboratories utilizing this technology and the broader number of tumor types being assayed. This highlights the importance of standardizing the interpretation and reporting of acquired variants among laboratories. To address this need, a clinical laboratory-focused workgroup was established to draft recommendations for the interpretation and reporting of acquired CNAs and CN-LOH in neoplastic disorders. This project is a collaboration between the American College of Medical Genetics and Genomics (ACMG) and the Cancer Genomics Consortium (CGC). The recommendations put forth by the workgroup are based on literature review, empirical data, and expert consensus of the workgroup members. A four-tier evidence-based categorization system for acquired CNAs and CN-LOH was developed, which is based on the level of available evidence regarding their diagnostic, prognostic, and therapeutic relevance: tier 1, variants with strong clinical significance; tier 2, variants with some clinical significance; tier 3, clonal variants with no documented neoplastic disease association; and tier 4, benign or likely benign variants. These recommendations also provide a list of standardized definitions of terms used in the reporting of CMA findings, as well as a framework for the clinical reporting of acquired CNAs and CN-LOH, and recommendations for how to deal with suspected clinically significant germline variants.

暂无摘要。

Studies evaluating selected patients treated with partial breast irradiation (PBI) in accelerated fractionation schemes have demonstrated the equivalence of PBI with traditional whole-breast irradiation. The major advantage of PBI is the time compression of treatment down to less than 1 week compared with 6.5 weeks for whole-breast external beam treatments. Four techniques are available to deliver PBI. These include interstitial brachytherapy multicatheter systems, the Mammosite Radiation Therapy System applicator, external beam three-dimensional conformal radiation therapy and intraoperative radiation therapy. For the two brachytherapy techniques of multicatheter implantation and the Mammosite, accurate placement is achieved with image guidance via intraoperative ultrasonography, mammography, and/or CT scanning. Technologies such as image-guided cone beam CT assure accurate delivery of PBI with external beam three-dimensional conformal radiation therapy. Results of PBI show excellent control rates with mild toxicities; cosmetic outcomes are good to excellent in the vast majority of patients.

The International Consensus Panel on cytology and bladder tumor markers evaluated markers that have the ability to predict tumor recurrence, progression, development of metastases, or response to therapy or patient survival. This article summarizes those findings. The panel mainly reviewed articles listed in PubMed on various prognostic indicators for bladder cancer. Based on these studies, most of which were case-control retrospective studies, various prognostic indicators were classified into 6 groups: (1) microsatellite-associated markers, (2) proto-oncogenes/oncogenes, (3) tumor suppressor genes, (4) cell cycle regulators, (5) angiogenesis-related factors, and (6) extracellular matrix adhesion molecules. The panel concluded that although certain markers, such as Ki-67 and p53, appear to be promising in predicting recurrence and progression of bladder cancer, the data are still heterogeneous. The panel recommends that identifying definitive criteria for test positivity, a clearly defined patient population, standardization of techniques used to evaluate markers, and clearly specified endpoints and statistical methods will help to bring accurate independent prognostic indicators into the clinical management of patients with bladder cancer.

The processed product of the human gene preprocortistatin, the peptide cortistatin-17 (hCST-17), bears a strong structural resemblance to the peptide somatostatin (SST), which has an identical receptor binding domain. CST has affinity to all known SST receptor (SSTR) subtypes. Expression of both SST and its receptors has been shown in previous studies to have biological and clinical significance in neuroblastomas, with a putative role in tumor differentiation and apoptosis in vivo. In this work we have employed radiation hybrid mapping and BAC physical mapping to map the human preprocortistatin gene (CORT) to chromosome region 1p36.3-->p36.2, close to the genetic marker D1S244. D1S244 defines the centromeric border of the smallest region of overlap of deletion in our primary neuroblastoma material. We have also defined the genomic sequence of the gene by BAC sequencing and found that preprocortistatin consists of two exons divided by a 1-kb intron. Two polymorphic sites, neither of which causes amino acid exchange, have been detected in the coding region of the gene. Expression studies showed that preprocortistatin is expressed in neuroblastomas of all different stages, as well as in ganglioneuromas. Through genomic sequencing we made mutation analyses of exonic sequences in 49 primary neuroblastomas of all different stages, but no mutations could be detected.

Chromosomal arm 1p has long been suspected, on the basis of loss of heterozygosity (LOH) and other data, to harbor a tumor suppressor gene important in pancreatic carcinomas and other tumors. We constructed a high-resolution map of LOH at I p in a panel of pancreatic adenocarcinomas. Using 44 markers, we identified LOH on I p in 49% of 43 cancers. Breakpoints in 1p were identified in 15 of the carcinomas and could be used to ascertain consensus patterns. We found a major consensus region of LOH at 1p35 between loci D1S233 and D1S247. This region participates in the majority of LOH events on 1 p in pancreatic cancer. These data provide a roadmap for further regional mapping, homozygous deletion searches, comparison to LOH patterns seen in other tumor types, and prioritization of studies using candidate genes.

Frequent loss of chromosome 10q sequences in endometrial cancers suggests the involvement of a tumor suppressor gene. Previous loss-of-heterozygosity (LOH)studies have pointed to the 10q25-q26 region as the likely site of a tumor suppressor involved in endometrial tumorigenesis (S. L. Peiffer et al., 1995, Cancer Res. 55: 1922-1926; S. Nagase et al., 1996, Br. J. Cancer 74: 1979-1983; S. Nagase et al.,1997, Cancer Res. 57: 1630-1633). In an attempt to define further the localization of a tumor suppressor gene at 10q25, we screened a panel of 123 endometrioid adenocarcinomas for loss of heterozygosity of 10q25.3 sequences. Forty-three (35%) revealed LOH at one or more loci. The observed patterns of allelic loss define a minimum consensus region of deletion between D10S221 and D10S610. A sequence-ready bacterial clone contig and a long-range restriction map for a 1-Mb interval spanning the deletion region were developed as the first step in experiments directed toward the discovery the 10q25 tumor suppressor.