Barbee Scott A, Evans Thomas C
Cell and Developmental Biology Program, University of Colorado School of Medicine, Mail Stop 8108, P.O. Box 6511, Aurora, CO 80045, USA.
Dev Biol. 2006 Mar 1;291(1):132-43. doi: 10.1016/j.ydbio.2005.12.011. Epub 2006 Jan 18.
Sm and Sm-like proteins are core components of the splicesome but have other functions distinct from pre-mRNA processing. Here, we show that Sm proteins also regulate germ cell specification during early C. elegans embryogenesis. SmE and SmG were required to maintain transcriptional quiescence in embryonic germ cell precursors. In addition, depletion of SmE inhibited expression of the germ lineage-specific proteins PIE-1, GLD-1, and NOS-2, but did not affect maintenance of several maternal mRNAs. PIE-1 had previously been shown to activate transcriptional silencing and NOS-2 expression. We found that PIE-1 also promotes GLD-1 expression by a process that is independent of transcriptional silencing. Thus, Sm proteins could control transcriptional silencing and maternal protein expression by regulating PIE-1. However, loss of SmE function also caused defects in P granule localization and premature division in early germline blastomeres, processes that are independent of PIE-1 function. Therefore, the Sm proteins control multiple aspects of germ cell precursor development. Because depletion of several other core splicing factors did not affect these events, these Sm functions are likely distinct from pre-mRNA splicing. Sm family proteins assemble into ribonucleoprotein complexes (RNPs) that control RNA activities. We suggest that novel Sm RNPs directly or indirectly influence posttranscriptional control of maternal mRNAs to promote germ cell specification in the early C. elegans embryo.
Sm 蛋白和 Sm 样蛋白是剪接体的核心成分,但具有与前体 mRNA 加工不同的其他功能。在此,我们表明 Sm 蛋白在秀丽隐杆线虫胚胎发育早期也调节生殖细胞特化。SmE 和 SmG 是维持胚胎生殖细胞前体转录静止所必需的。此外,SmE 的缺失抑制了生殖系特异性蛋白 PIE-1、GLD-1 和 NOS-2 的表达,但不影响几种母源 mRNA 的维持。此前已表明 PIE-1 可激活转录沉默和 NOS-2 的表达。我们发现 PIE-1 还通过一个独立于转录沉默的过程促进 GLD-1 的表达。因此,Sm 蛋白可能通过调节 PIE-1 来控制转录沉默和母源蛋白表达。然而,SmE 功能的丧失也导致 P 颗粒定位缺陷和早期生殖系卵裂球过早分裂,这些过程独立于 PIE-1 的功能。因此,Sm 蛋白控制生殖细胞前体发育的多个方面。由于其他几种核心剪接因子的缺失并不影响这些事件,这些 Sm 功能可能与前体 mRNA 剪接不同。Sm 家族蛋白组装成控制 RNA 活性的核糖核蛋白复合物(RNP)。我们认为,新型 Sm RNP 直接或间接影响母源 mRNA 的转录后控制,以促进秀丽隐杆线虫胚胎早期的生殖细胞特化。
