Bakthavatsalam Deenadayalan, Choe Jonathan M, Hanson Nana E, Gomer Richard H
Department of Biochemistry and Cell Biology, MS-140, Rice University, Houston, TX, USA.
BMC Biol. 2009 Jul 27;7:44. doi: 10.1186/1741-7007-7-44.
Several studies have shown that organ size, and the proliferation of tumor metastases, may be regulated by negative feedback loops in which autocrine secreted factors called chalones inhibit proliferation. However, very little is known about chalones, and how cells sense them. We previously identified two secreted proteins, AprA and CfaD, which act as chalones in Dictyostelium. Cells lacking AprA or CfaD proliferate faster than wild-type cells, and adding recombinant AprA or CfaD to cells slows their proliferation.
We show here that cells lacking the G protein components Galpha8, Galpha9, and Gbeta proliferate faster than wild-type cells despite secreting normal or high levels of AprA and CfaD. Compared with wild-type cells, the proliferation of galpha8-, galpha9- and gbeta- cells are only weakly inhibited by recombinant AprA (rAprA). Like AprA and CfaD, Galpha8 and Gbeta inhibit cell proliferation but not cell growth (the rate of increase in mass and protein per nucleus), whereas Galpha9 inhibits both proliferation and growth. galpha8- cells show normal cell-surface binding of rAprA, whereas galpha9- and gbeta- cells have fewer cell-surface rAprA binding sites, suggesting that Galpha9 and Gbeta regulate the synthesis or processing of the AprA receptor. Like other ligands that activate G proteins, rAprA induces the binding of [3H]GTP to membranes, and GTPgammaS inhibits the binding of rAprA to membranes. Both AprA-induced [3H]GTP binding and the GTPgammaS inhibition of rAprA binding require Galpha8 and Gbeta but not Galpha9. Like aprA- cells, galpha8- cells have reduced spore viability.
This study shows that Galpha8 and Gbeta are part of the signal transduction pathway used by AprA to inhibit proliferation but not growth in Dictyostelium, whereas Galpha9 is part of a differealnt pathway that regulates both proliferation and growth, and that a chalone signal transduction pathway uses G proteins.
多项研究表明,器官大小以及肿瘤转移的增殖可能受负反馈回路调节,在这些回路中,名为抑素的自分泌分泌因子会抑制增殖。然而,对于抑素以及细胞如何感知它们,我们知之甚少。我们之前鉴定出两种分泌蛋白,AprA和CfaD,它们在盘基网柄菌中作为抑素发挥作用。缺乏AprA或CfaD的细胞比野生型细胞增殖得更快,并且向细胞中添加重组AprA或CfaD会减缓它们的增殖。
我们在此表明,缺乏G蛋白成分Gα8、Gα9和Gβ的细胞比野生型细胞增殖得更快,尽管它们分泌正常水平或高水平的AprA和CfaD。与野生型细胞相比,重组AprA(rAprA)对Gα8、Gα9和Gβ细胞增殖的抑制作用较弱。与AprA和CfaD一样,Gα8和Gβ抑制细胞增殖但不抑制细胞生长(每个细胞核的质量和蛋白质增加速率),而Gα9同时抑制增殖和生长。Gα8细胞显示出rAprA的正常细胞表面结合,而Gα9和Gβ细胞的细胞表面rAprA结合位点较少,这表明Gα9和Gβ调节AprA受体的合成或加工。与其他激活G蛋白的配体一样,rAprA诱导[3H]GTP与膜结合,并且GTPγS抑制rAprA与膜的结合。AprA诱导的[3H]GTP结合以及GTPγS对rAprA结合的抑制都需要Gα8和Gβ,但不需要Gα9。与aprA细胞一样,Gα8细胞的孢子活力降低。
本研究表明,Gα8和Gβ是AprA用于抑制盘基网柄菌增殖但不抑制生长的信号转导途径的一部分,而Gα9是调节增殖和生长的不同途径的一部分,并且一种抑素信号转导途径使用G蛋白。
