Summary Peripheral sensory neurons respond to axon injury by activating an importin-dependent retrograde signaling mechanism. How is this mechanism regulated? Here we show that Ran GTPase and its associated effectors RanBP1 and RanGAP regulate the formation of importin signaling complexes in injured axons. A gradient of nuclear RanGTP versus cytoplasmic RanGDP is thought to be fundamental for the organization of eukaryotic cells. Surprisingly, we find RanGTP in sciatic nerve axoplasm, distant from neuronal cell bodies and nuclei, and in association with dynein and importin α. Following injury, localized translation of RanBP1 stimulates RanGTP dissociation from importins and subsequent hydrolysis, thereby allowing binding of newly synthesized importin β to importin α and dynein. Perturbation of RanGTP hydrolysis or RanBP1 blockade at axonal injury sites reduces the neuronal conditioning lesion response. Thus, neurons employ localized mechanisms of Ran regulation to control retrograde injury signaling in peripheral nerve.
Summary Subcellular localization of mRNA enables compartmentalized regulation within large cells. Neurons are the longest known cells, however so far evidence is lacking for an essential role of endogenous mRNA localization in axons. Localized upregulation of importin β1 in lesioned axons coordinates a retrograde injury signaling complex transported to the neuronal cell body. Here we show that a long 3′ untranslated region (3′UTR) directs axonal localization of importin β1. Conditional targeting of this 3′UTR region in mice causes subcellular loss of importin β1 mRNA and protein in axons, without affecting cell body levels or nuclear functions in sensory neurons. Strikingly, axonal knockout of importin β1 attenuates cell body transcriptional responses to nerve injury and delays functional recovery in vivo. Thus, localized translation of importin β1 mRNA enables separation of cytoplasmic and nuclear transport functions of importins, and is required for efficient retrograde signaling in injured axons.
Members of the signal transducers and activators of transcription (Stat) family regulate essential cellular growth and survival functions in normal cells and have also been implicated in tumorigenesis. We have studied the potential role of Stat5 in mammary tumorigenesis by targeting Stat5 variants to the mammary gland of transgenic mice using regulatory sequences of the -lactoglobulin gene. Mammary-directed expression of the wild-type Stat5, constitutively activated Stat5 and carboxyl-terminally truncated dominant negative Stat5 forms resulted in mammary tumors with incidence rates of up to 22% and latency periods of 8 -12 months. Undifferentiated carcinomas most frequently occurred in mice expressing the carboxyl-terminally truncated Stat5. The more differentiated papillary and micropapillary adenocarcinomas were primarily found in mice overexpressing the native and constitutively active transgenes. Higher levels of translation initiation factor 4E (eIF4E) and cyclin D1 expression but lower levels of activated Stat3 were found in tumors of mice expressing the constitutively active Stat5 when compared to mice expressing the wild-type or truncated forms. A higher expression of the estrogen receptor (ER␣) was observed in carcinomas compared to other phenotypes. The ability of both forms of Stat5, the transactivating form and the dominant negative form, to participate in oncogenesis indicates that there is more than one mechanism by which Stat5 contributes to this process. The transactivation function of Stat5 is involved in the determination of tumors with a more differentiated phenotype.
Signal transducer and activator of transcription (Stat5) is a transcription factor, which transduces extracellular cytokine and growth-factor signals to the nuclei of mammalian cells. As a major mediator of prolactin action, it is involved in the regulation of the development, function, and survival of mammary epithelial cells. The carboxyl terminal of Stat5 encodes a transactivation domain (TAD), which interacts with coactivators and is crucial for the transcriptional induction of Stat5 target genes. To study the role of the Stat5 TAD in mediating Stat5 functions, a carboxy terminally truncated Stat5 variant (Stat5Delta750) was directed for expression in the mammary glands of transgenic mice by regulatory sequences of the beta-lactoglobulin (BLG) gene. Expression of Stat5Delta750 in mammary tissue reduced the rates of cell proliferation at mid and late pregnancy. Subsequently, morphological signs of milk secretion upon parturition were delayed. In double-transgenic mice, expression of Stat5Delta750 drastically decreased BLG/luciferase activity during lactation, but did not affect the expression and secretion of the endogenous beta-casein or alpha-lactalbumin into the milk. Expression of Stat5Delta750 also caused an increase in the number of apoptotic cells during mammary involution by a factor of 3 relative to control glands. Our data established a role for the Stat5 TAD in mediating the effects of Stat5 on mammary development, regulation of milk protein gene activity, and cell survival. The full effects of Stat5Delta750 may be partially buffered by the expression of endogenous wild-type Stat5 and the formation of truncated and wild-type heterodimers.
Background: The ALG2-interacting protein X (ALIX)/AIP1 is an adaptor protein with multiple functions in intracellular protein trafficking that plays a central role in the biogenesis of enveloped viruses. The ubiquitin E3-ligase POSH (plenty of SH3) augments HIV-1 egress by facilitating the transport of Gag to the cell membrane. Recently, it was reported, that POSH interacts with ALIX and thereby enhances ALIX mediated phenotypes in Drosophila.
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