Differences in the ability of opioid drugs to promote regulated endocytosis of μ-opioid receptors are related to their tendency to produce drug tolerance and dependence. Here we show that drug-specific differences in receptor internalization are determined by a conserved, 10-residue sequence in the receptor's carboxyl-terminal cytoplasmic tail. Diverse opioids induce receptor phosphorylation at serine (S)375, present in the middle of this sequence, but opioids differ markedly in their ability to drive higher-order phosphorylation on flanking residues [threonine (T)370, T376, and T379]. Multi-phosphorylation is required for the endocytosis-promoting activity of this sequence and occurs both sequentially and hierarchically, with S375 representing the initiating site. Higher-order phosphorylation involving T370, T376, and T379 specifically requires GRK2/3 isoforms, and the same sequence controls opioid receptor internalization in neurons. These results reveal a biochemical mechanism differentiating the endocytic activity of opioid drugs.
Mitochondria are important sources of energy, but they are also the target of cellular stress, toxin exposure, and aging-related injury. Persistent accumulation of damaged mitochondria has been implicated in many neurodegenerative diseases. One highly conserved mechanism to clear damaged mitochondria involves the E3 ubiquitin ligase Parkin and PTEN-induced kinase 1 (PINK1), which cooperatively initiate the process called mitophagy that identifies and eliminates damaged mitochondria through the autophagosome and lysosome pathways. Parkin is a mostly cytosolic protein, but is rapidly recruited to damaged mitochondria and target them for mitophagy. Moreover, Parkin interactomes also involve signaling pathways and transcriptional machinery critical for survival and cell death. However, the mechanism that regulates Parkin protein level remains poorly understood. Here, we show that the loss of homeodomain interacting protein kinase 2 (HIPK2) in neurons and mouse embryonic fibroblasts (MEFs) has a broad protective effect from cell death induced by mitochondrial toxins. The mechanism by which Hipk2 −/− neurons and MEFs are more resistant to mitochondrial toxins is in part due to the role of HIPK2 and its kinase activity in promoting Parkin degradation via the proteasome-mediated mechanism. The loss of HIPK2 leads to higher cytosolic Parkin protein levels at basal conditions and upon exposure to mitochondrial toxins, which protects mitochondria from toxin-induced damage. In addition, Hipk2 −/− neurons and MEFs show increased expression of PGC-1α (peroxisome proliferator-activated receptor-γ coactivator 1), a Parkin downstream target that can provide additional benefits via transcriptional activation of mitochondrial genes. Together, these results reveal a previously unrecognized avenue to target HIPK2 in neuroprotection via the Parkin-mediated pathway. SIGNIFICANCE STATEMENT In this study, we provide evidence that homeodomain interacting protein kinase 2 (HIPK2) and its kinase activity promote Parkin degradation via the proteasome-mediated pathway. The loss of HIPK2 increases cytosolic and mitochondrial Parkin protein levels under basal conditions and upon exposure to mitochondrial toxins, which protect mitochondria from toxin-induced damage. In addition, Hipk2 −/− neurons and mouse embryonic fibroblasts also show increased expression of PGC-1α (peroxisome proliferator-activated receptor-γ coactivator 1), a Parkin downstream target that can provide additional benefits via transcriptional activation of mitochondrial genes. These results indicate that targeting HIPK2 and its kinase activity can have neuroprotective effects by elevating Parkin protein levels.
Author(s): Kotowski, Sarah Jane | Advisor(s): von Zastrow, Mark | Abstract: Regulation of Dopamine Signaling by D1 Receptor Membrane TraffickingDopamine is a major catecholamine neurotransmitter in the central nervous system (CNS). Dopaminergic signaling is a critical component of a number of complex physiological functions including movement, learning and memory, attention and goal-directed behaviors. The cellular actions of dopamine are mediated by a family of G protein-coupled receptors (GPCRs), the dopamine receptors. The D1 receptor is the major excitatory transducer of dopaminergic signaling within the brain. In this study, we examine the contribution of D1 receptor membrane trafficking to the regulation of dopaminergic signaling in a HEK 293 model system, as well as in cortical and striatal neurons known to natively express D1 receptors. We find that D1 receptor membrane trafficking does not play a significant role in determining cellular sensitivity to dopamine after prolonged (30 minutes to 1 hour) agonist incubation. However, when we examine D1 receptor trafficking and signaling with much greater temporal resolution, we find that rapid endocytosis is essential for neuronal dopamine signaling. Further, the kinetics of this regulation approaches those of transient increases in extracellular dopamine observed within the intact brain. This body of work presents a novel, and previously unanticipated role for endocytosis in the regulation of D1 receptor-mediated dopaminergic signaling in neurons.
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