Villanueva A, Lozano J, Morales A, Lin X, Deng X, Hengartner M O, Kolesnick R N
Laboratory of Signal Transduction, Memorial Sloan-Kettering Cancer Center, New York, NY 10021, USA.
EMBO J. 2001 Sep 17;20(18):5114-28. doi: 10.1093/emboj/20.18.5114.
Although in vitro evidence suggests two c-Jun N-terminal kinase (JNK) kinases, MKK4 and MKK7, transactivate JNK, in vivo confirmation is incomplete. In fact, JNK deficiency may differ from the composite deficiency of MKK4 and MKK7 in Drosophila and mice. Recently, the Caenorhabditis elegans homolog of human JNK, jnk-1, and two MKK-7s, mek-1 and jkk-1, were cloned. Here we characterize jnk-1, which encodes two isoforms JNK-1 alpha and JNK-1 beta. A null allele, jnk-1(gk7), yielded worms with defective body movement coordination and modest mechanosensory deficits. Similarly to jkk-1 mutants, elimination of GABAergic signals suppressed the jnk-1(gk7) locomotion defect. Like mek-1 nulls, jnk-1(gk7) showed copper and cadmium hypersensitivity. Conditional expression of JNK-1 isoforms rescued these defects, suggesting that they are not due to developmental errors. While jkk-1 or mek-1 inactivation mimicked jnk-1(gk7) locomotion and heavy metal stress defects, respectively, mkk-4 inactivation did not, but rather yielded defective egg laying. Our results delineate at least two different JNK pathways through jkk-1 and mek-1 in C.elegans, and define interaction between MKK7, but not MKK4, and JNK.
尽管体外实验证据表明两种c-Jun氨基末端激酶(JNK)激酶,即MKK4和MKK7,可反式激活JNK,但体内实验的证实并不完整。事实上,在果蝇和小鼠中,JNK缺陷可能与MKK4和MKK7的复合缺陷有所不同。最近,人类JNK在秀丽隐杆线虫中的同源物jnk-1以及两种MKK-7,即mek-1和jkk-1被克隆出来。在此我们对jnk-1进行了表征,它编码两种异构体JNK-1α和JNK-1β。一个无效等位基因jnk-1(gk7)产生的线虫存在身体运动协调缺陷和适度的机械感觉缺陷。与jkk-1突变体类似,消除GABA能信号可抑制jnk-1(gk7)的运动缺陷。与mek-1缺失突变体一样,jnk-1(gk7)对线铜和镉高度敏感。JNK-1异构体的条件性表达挽救了这些缺陷,表明它们并非由发育错误导致。虽然jkk-1或mek-1失活分别模拟了jnk-1(gk7)的运动和重金属应激缺陷,但mkk-4失活则不然,而是导致产卵缺陷。我们的结果描绘了秀丽隐杆线虫中至少两条通过jkk-1和mek-1的不同JNK途径,并确定了MKK7而非MKK4与JNK之间的相互作用。
