Berman Jules
U.S. National Cancer Institute, Cancer Diagnosis Program, Bethesda, USA.
BMC Cancer. 2005 Aug 10;5:100. doi: 10.1186/1471-2407-5-100.
For over 150 years, pathologists have relied on histomorphology to classify and diagnose neoplasms. Their success has been stunning, permitting the accurate diagnosis of thousands of different types of neoplasms using only a microscope and a trained eye. In the past two decades, cancer genomics has challenged the supremacy of histomorphology by identifying genetic alterations shared by morphologically diverse tumors and by finding genetic features that distinguish subgroups of morphologically homogeneous tumors.
The Developmental Lineage Classification and Taxonomy of Neoplasms groups neoplasms by their embryologic origin. The putative value of this classification is based on the expectation that tumors of a common developmental lineage will share common metabolic pathways and common responses to drugs that target these pathways. The purpose of this manuscript is to show that grouping tumors according to their developmental lineage can reconcile certain fundamental discrepancies resulting from morphologic and molecular approaches to neoplasm classification. In this study, six issues in tumor classification are described that exemplify the growing rift between morphologic and molecular approaches to tumor classification: 1) the morphologic separation between epithelial and non-epithelial tumors; 2) the grouping of tumors based on shared cellular functions; 3) the distinction between germ cell tumors and pluripotent tumors of non-germ cell origin; 4) the distinction between tumors that have lost their differentiation and tumors that arise from uncommitted stem cells; 5) the molecular properties shared by morphologically disparate tumors that have a common developmental lineage, and 6) the problem of re-classifying morphologically identical but clinically distinct subsets of tumors. The discussion of these issues in the context of describing different methods of tumor classification is intended to underscore the clinical value of a robust tumor classification.
A classification of neoplasms should guide the rational design and selection of a new generation of cancer medications targeted to metabolic pathways. Without a scientifically sound neoplasm classification, biological measurements on individual tumor samples cannot be generalized to class-related tumors, and constitutive properties common to a class of tumors cannot be distinguished from uninformative data in complex and chaotic biological systems. This paper discusses the importance of biological classification and examines several different approaches to the specific problem of tumor classification.
150多年来,病理学家一直依靠组织形态学对肿瘤进行分类和诊断。他们取得了惊人的成功,仅通过显微镜和训练有素的眼睛就能准确诊断出数千种不同类型的肿瘤。在过去二十年中,癌症基因组学通过识别形态多样的肿瘤所共有的基因改变,以及发现区分形态学上同质肿瘤亚组的基因特征,对组织形态学的主导地位提出了挑战。
肿瘤的发育谱系分类和肿瘤学将肿瘤按其胚胎起源进行分组。这种分类的假定价值基于这样的预期,即具有共同发育谱系的肿瘤将共享共同的代谢途径以及对靶向这些途径的药物的共同反应。本手稿的目的是表明,根据肿瘤的发育谱系对肿瘤进行分组可以调和形态学和分子方法在肿瘤分类中产生的某些基本差异。在本研究中,描述了肿瘤分类中的六个问题,这些问题体现了肿瘤分类的形态学和分子方法之间日益扩大的分歧:1)上皮性肿瘤和非上皮性肿瘤之间的形态学区分;2)基于共享细胞功能对肿瘤进行分组;3)生殖细胞肿瘤与非生殖细胞起源的多能肿瘤之间的区分;4)已失去分化的肿瘤与源自未分化干细胞的肿瘤之间的区分;5)具有共同发育谱系的形态学不同肿瘤所共有的分子特性,以及6)对形态学相同但临床不同的肿瘤亚组进行重新分类的问题。在描述不同肿瘤分类方法的背景下对这些问题进行讨论,旨在强调可靠肿瘤分类的临床价值。
肿瘤分类应指导针对代谢途径的新一代癌症药物的合理设计和选择。没有科学合理的肿瘤分类,对单个肿瘤样本的生物学测量就无法推广到与类别相关的肿瘤,并且一类肿瘤共有的组成特性就无法与复杂混乱的生物系统中的无信息数据区分开来。本文讨论了生物学分类的重要性,并研究了针对肿瘤分类这一具体问题的几种不同方法。
