*Department of Ecology and Evolutionary Biology, UCLA, 621 Young Drive South, Los Angeles, CA 90095-1606, USA; Department of Molecular, Cellular and Developmental Biology, UCLA, 621 Young Drive South, Los Angeles, CA 90095-1606, USA; Department of Molecular and Cell Biology, 142 Life Sciences Addition, University of California, Berkeley, CA 94720, USA.
Integr Comp Biol. 2007 Nov;47(5):712-23. doi: 10.1093/icb/icm094. Epub 2007 Sep 27.
Cnidaria have traditionally been viewed as the most basal animals with complex, organ-like multicellular structures dedicated to sensory perception. However, sponges also have a surprising range of the genes required for sensory and neural functions in Bilateria. Here, we: (1) discuss "sense organ" regulatory genes, including; sine oculis, Brain 3, and eyes absent, that are expressed in cnidarian sense organs; (2) assess the sensory features of the planula, polyp, and medusa life-history stages of Cnidaria; and (3) discuss physiological and molecular data that suggest sensory and "neural" processes in sponges. We then develop arguments explaining the shared aspects of developmental regulation across sense organs and between sense organs and other structures. We focus on explanations involving divergent evolution from a common ancestral condition. In Bilateria, distinct sense-organ types share components of developmental-gene regulation. These regulators are also present in basal metazoans, suggesting evolution of multiple bilaterian organs from fewer antecedent sensory structures in a metazoan ancestor. More broadly, we hypothesize that developmental genetic similarities between sense organs and appendages may reflect descent from closely associated structures, or a composite organ, in the common ancestor of Cnidaria and Bilateria, and we argue that such similarities between bilaterian sense organs and kidneys may derive from a multifunctional aggregations of choanocyte-like cells in a metazoan ancestor. We hope these speculative arguments presented here will stimulate further discussion of these and related questions.
刺胞动物传统上被认为是最基础的动物,具有复杂的、器官样的多细胞结构,专门用于感觉感知。然而,海绵也拥有一系列令人惊讶的与感觉和神经功能相关的基因,这些基因在两侧对称动物中存在。在这里,我们:(1) 讨论“感觉器官”调节基因,包括在刺胞动物感觉器官中表达的 sine oculis、Brain 3 和 eyes absent;(2) 评估刺胞动物的水螅体、水螅幼虫和水母体的感觉特征;(3) 讨论表明海绵具有感觉和“神经”过程的生理和分子数据。然后,我们提出了一些论点,解释了发育调控在感觉器官之间以及感觉器官和其他结构之间的共同方面。我们专注于涉及从共同祖先条件发散进化的解释。在两侧对称动物中,不同类型的感觉器官共享发育基因调节的成分。这些调节因子也存在于基础后生动物中,这表明多个两侧对称动物器官是从后生动物祖先中较少的先前感觉结构进化而来的。更广泛地说,我们假设感觉器官和附肢之间的发育遗传相似性可能反映了它们来自共同祖先的密切相关结构或复合器官,我们认为两侧对称动物的感觉器官和肾脏之间的这种相似性可能源于后生动物祖先中类似领细胞的细胞的多功能聚集。我们希望这里提出的这些推测性论点将进一步激发对这些问题和相关问题的讨论。
