Corsi Jean-Marc, Rouer Evelyne, Girault Jean-Antoine, Enslen Hervé
Unité Mixte de Recherche-Santé (UMR-S) 536, Institut National de la Santé et de la Recherche Médicale (INSERM) F-75005, Paris, France.
BMC Genomics. 2006 Aug 4;7:198. doi: 10.1186/1471-2164-7-198.
Focal adhesion kinase (FAK) is a non-receptor tyrosine kinase critical for processes ranging from embryo development to cancer progression. Although isoforms with specific molecular and functional properties have been characterized in rodents and chicken, the organization of FAK gene throughout phylogeny and its potential to generate multiple isoforms are not well understood. Here, we study the phylogeny of FAK, the organization of its gene, and its post-transcriptional processing in rodents and human.
A single orthologue of FAK and the related PYK2 was found in non-vertebrate species. Gene duplication probably occurred in deuterostomes after the echinoderma embranchment, leading to the evolution of PYK2 with distinct properties. The amino acid sequence of FAK and PYK2 is conserved in their functional domains but not in their linker regions, with the absence of autophosphorylation site in C. elegans. Comparison of mouse and human FAK genes revealed the existence of multiple combinations of conserved and non-conserved 5'-untranslated exons in FAK transcripts suggesting a complex regulation of their expression. Four alternatively spliced coding exons (13, 14, 16, and 31), previously described in rodents, are highly conserved in vertebrates. Cis-regulatory elements known to regulate alternative splicing were found in conserved alternative exons of FAK or in the flanking introns. In contrast, other reported human variant exons were restricted to Homo sapiens, and, in some cases, other primates. Several of these non-conserved exons may correspond to transposable elements. The inclusion of conserved alternative exons was examined by RT-PCR in mouse and human brain during development. Inclusion of exons 14 and 16 peaked at the end of embryonic life, whereas inclusion of exon 13 increased steadily until adulthood. Study of various tissues showed that inclusion of these exons also occurred, independently from each other, in a tissue-specific fashion.
The alternative coding exons 13, 14, 16, and 31 are highly conserved in vertebrates and their inclusion in mRNA is tightly but independently regulated. These exons may therefore be crucial for FAK function in specific tissues or during development. Conversely pathological disturbance of the expression of FAK and of its isoforms could lead to abnormal cellular regulation.
粘着斑激酶(FAK)是一种非受体酪氨酸激酶,对从胚胎发育到癌症进展等一系列过程至关重要。尽管在啮齿动物和鸡中已鉴定出具有特定分子和功能特性的同工型,但FAK基因在整个系统发育中的组织情况及其产生多种同工型的潜力尚不清楚。在此,我们研究了FAK在啮齿动物和人类中的系统发育、其基因的组织情况以及转录后加工。
在非脊椎动物物种中发现了FAK和相关的PYK2的单一直系同源物。基因复制可能发生在棘皮动物分支后的后口动物中,导致具有不同特性的PYK2的进化。FAK和PYK2的氨基酸序列在其功能域中保守,但在其连接区不保守,秀丽隐杆线虫中不存在自磷酸化位点。小鼠和人类FAK基因的比较揭示了FAK转录本中保守和非保守的5'-非翻译外显子存在多种组合,表明其表达受到复杂调控。先前在啮齿动物中描述的四个可变剪接编码外显子(13、14、16和31)在脊椎动物中高度保守。在FAK的保守可变外显子或侧翼内含子中发现了已知调节可变剪接的顺式调节元件。相比之下,其他报道的人类可变外显子仅限于智人,在某些情况下还包括其他灵长类动物。这些非保守外显子中的几个可能对应于转座元件。通过RT-PCR检测了发育过程中小鼠和人类大脑中保守可变外显子的包含情况。外显子14和16的包含在胚胎末期达到峰值,而外显子13的包含在成年前稳步增加。对各种组织的研究表明,这些外显子的包含也以组织特异性方式相互独立地发生。
可变编码外显子13、14、16和31在脊椎动物中高度保守,它们在mRNA中的包含受到严格但独立的调控。因此,这些外显子可能对特定组织或发育过程中的FAK功能至关重要。相反,FAK及其同工型表达的病理紊乱可能导致细胞调节异常。
