Cyclin-dependent kinases (CDKs) are commonly known to regulate cell proliferation. However, previous reports suggest that in cultured postmitotic neurons, activation of CDKs is a signal for death rather than cell division. We determined whether CDK activation occurs in mature adult neurons during focal stroke in vivo and whether this signal was required for neuronal death after reperfusion injury. Cdk4͞cyclin D1 levels and phosphorylation of its substrate retinoblastoma protein (pRb) increase after stroke. Deregulated levels of E2F1, a transcription factor regulated by pRb, are also observed. Administration of a CDK inhibitor blocks pRb phosphorylation and the increase in E2F1 levels and dramatically reduces neuronal death by 80%. These results indicate that CDKs are an important therapeutic target for the treatment of reperfusion injury after ischemia.T he mechanism by which stroke-induced neuronal death occurs is complex and is likely dependent upon the severity and duration of ischemic insult and an elaborate interplay between ischemic death initiators such as excitotoxicity, oxidative stress, DNA damage, and inflammatory responses (1-3). Neurons that survive the acute ischemic injury undergo a delayed cell death that exhibits some characteristics of apoptosis (1-3). This delayed cell death is dependent upon selected death-signaling elements such as caspases, poly(ADP-ribose) polymerase, and p53 (4). The identification of signaling molecules that control delayed neuronal death has led to the hope that some of these death-signaling elements may serve as useful therapeutic targets for the reduction of neuropathology and behavioral deficits associated with stroke injury. The mechanism by which stroke-evoked delayed death occurs, however, is not fully understood.The cell cycle is a highly coordinated process regulated by the appropriate and timely activation of cyclin-dependent kinases (CDKs) (5). Regulation of CDKs is complex and includes binding to their obligate cyclin partner, activating and inhibitory phosphorylation events, and endogenous inhibitors of CDK activity. Distinct CDKs regulate progressive phases of the cell cycle. Generally, it is thought that the Cdk4͞6͞cyclin D1 complex regulates the G 0 to G 1 , Cdk2͞cyclin E and Cdk3 control G 1 to S, and Cdk2͞cyclin A and Cdk1͞cyclin B control G 2 and M progressions. Although the downstream targets of CDKs are not fully characterized, one important substrate is the tumor suppresser retinoblastoma protein (pRb), which is phosphorylated by activated Cdk4͞6͞cyclin D complex (6). Once hyperphosphorylated, pRb is released from the transcription factor complex E2F͞DP, which then activates genes required for S phase transition (7-9).Paradoxically, increasing evidence suggests that CDKs may have functions beyond that of cell cycle regulation. Numerous reports indicate the requirement of CDK signals for death of cultured postmitotic neurons exposed to select death insults. For example, inappropriate cyclin B and cyclin D1 transcripts have been observed in neuronal P...
Huntington disease (HD) is caused by polyglutamine [poly(Q)] expansion in the protein huntingtin (htt). Although the exact mechanism of disease progression remains to be elucidated, altered interactions of mutant htt with its protein partners could contribute to the disease. Using the yeast two-hybrid system, we have isolated a novel htt interacting protein, HIP14. HIP14's interaction with htt is inversely correlated to the poly(Q) length in htt. mRNAs of 9 and 6 bp are transcribed from the HIP14 gene, with the 6 kb transcript being predominantly expressed in the brain. HIP14 protein is enriched in the brain, shows partial co-localization with htt in the striatum, and is found in medium spiny projection neurons, the subset of neurons affected in HD. HIP14 localizes to the Golgi, and to vesicles in the cytoplasm. The HIP14 protein has sequence similarity to Akr1p, a protein essential for endocytosis in Saccharomyces cerevisiae. Expression of human HIP14 results in rescue of the temperature-sensitive lethality in akr1 Delta yeast cells and, furthermore, restores their defect in endocytosis, demonstrating a role for HIP14 in intracellular trafficking. Our findings suggest that decreased interaction between htt and HIP14 could contribute to the neuronal dysfunction in HD by perturbing normal intracellular transport pathways in neurons.
ALS2/alsin is a member of guanine nucleotide exchange factors for the small GTPase Rab5 (Rab5GEFs), which act as modulators in endocytic pathway. Loss-of-function mutations in human ALS2 account for a number of juvenile recessive motor neuron diseases (MNDs). However, the normal physiological role of ALS2 in vivo and the molecular mechanisms underlying motor dysfunction are still unknown. To address these issues, we have generated mice homozygous for disruption of the Als2 gene. The Als2-null mice observed through 21 months of age demonstrated no obvious developmental, reproductive or motor abnormalities. However, immunohistochemical and electrophysiological analyses identified an age-dependent, slowly progressive loss of cerebellar Purkinje cells and disturbance of spinal motor neurons associated with astrocytosis and microglial cell activation, indicating a subclinical dysfunction of motor system in Als2-null mice. Further, quantitative epidermal growth factor (EGF)-uptake analysis identified significantly smaller-sized EGF-positive endosomes in Als2-null fibroblasts, suggesting an alteration of endosome/vesicle trafficking in the cells. Collectively, while loss of ALS2 does not produce a severe disease phenotype in mice, these Als2-null animals should provide a useful model with which to understand the interplay between endosomal dynamics and the long-term viability of large neurons such as Purkinje cells and spinal motor neurons.
Mutations in the ALS2 gene cause a number of recessive motor neuron diseases, indicating that the ALS2 protein (ALS2/ alsin) is vital for motor neurons. ALS2 acts as a guanine nucleotide exchange factor (GEF) for Rab5 (Rab5GEF) and is involved in endosome dynamics. However, the spatiotemporal regulation of the ALS2-mediated Rab5 activation is unclear. Here we identified an upstream activator for ALS2 and showed a functional significance of the ALS2 activation in endosome dynamics. ALS2 preferentially interacts with activated Rac1. In the cells activated Rac1 recruits cytoplasmic ALS2 to membrane ruffles and subsequently to nascent macropinosomes via Rac1-activated macropinocytosis. At later endocytic stages macropinosomal ALS2 augments fusion of the ALS2-localized macropinosomes with the transferrin-positive endosomes, depending on the ALS2-associated Rab5GEF activity. These results indicate that Rac1 promotes the ALS2 membranous localization, thereby rendering ALS2 active via Rac1-activated endocytosis. Thus, ALS2 is a novel Rac1 effector and is involved in Rac1-activated macropinocytosis. All together, loss of ALS2 may perturb macropinocytosis and/or the following membrane trafficking, which gives rise to neuronal dysfunction in the ALS2-linked motor neuron diseases.
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