PACAP Expression in an Auditory Neurocircuit Relay Center

Pituitary adenylyl cyclase-activating polypeptide (PACAP) is a small pleiotropic neuropeptide found throughout the central and peripheral nervous system. It binds with highest affinity to its complementary receptor, pituitary adenylyl cyclase-activating polypeptide receptor 1. Using PACAP-Cre transgenic mice, an adeno-assisted viral construct was injected into the diencephalon for Cre-dependent expression of mCherry fluorescent protein in PACAP-expressing neurons. We observed red mCherry fluorescence in PACAP expressing neurons in the suprageniculate (SG) thalamic nucleus, a component of the auditory sensory pathway. The nucleus receives afferent fibers from the deep layers of the superior colliculus (SC) and sends axonal projections to various targets including the auditory cortex and posterior parietal cortex. Previous studies in hippocampal and limbic systems have shown that PACAP is co-expressed in glutamatergic neurons. In coherence, inspection of Allen’s Brain Atlas for vesicular glutamate transporter (VGLUT) and glutamic acid decarboxylase (GAD) transcript expression, as markers for glutamate and GABA neurons, respectively, suggests that the PACAP expressing neurons are glutamatergic in nature. The findings of this study are novel in identifying PACAP expression in an auditory relay nucleus

Dynamic Regulation of Oct1 during Mitosis by Phosphorylation and Ubiquitination

Transcription factor Oct1 regulates multiple cellular processes. It is known to be phosphorylated during the cell cycle and by stress, however the upstream kinases and downstream consequences are not well understood. One of these modified forms, phosphorylated at S335, lacks the ability to bind DNA. Other modification states besides phosphorylation have not been described.We show that Oct1 is phosphorylated at S335 in the Oct1 DNA binding domain during M-phase by the NIMA-related kinase Nek6. Phospho-Oct1 is also ubiquitinated. Phosphorylation excludes Oct1 from mitotic chromatin. Instead, Oct1(pS335) concentrates at centrosomes, mitotic spindle poles, kinetochores and the midbody. Oct1 siRNA knockdown diminishes the signal at these locations. Both Oct1 ablation and overexpression result in abnormal mitoses. S335 is important for the overexpression phenotype, implicating this residue in mitotic regulation. Oct1 depletion causes defects in spindle morphogenesis in Xenopus egg extracts, establishing a mitosis-specific function of Oct1. Oct1 colocalizes with lamin B1 at the spindle poles and midbody. At the midbody, both proteins are mutually required to correctly localize the other. We show that phospho-Oct1 is modified late in mitosis by non-canonical K11-linked polyubiquitin chains. Ubiquitination requires the anaphase-promoting complex, and we further show that the anaphase-promoting complex large subunit APC1 and Oct1(pS335) interact.These findings reveal mechanistic coupling between Oct1 phosphorylation and ubquitination during mitotic progression, and a role for Oct1 in mitosis

Entrainment of the Mammalian Cell Cycle by the Circadian Clock: Modeling Two Coupled Cellular Rhythms

The cell division cycle and the circadian clock represent two major cellular rhythms. These two periodic processes are coupled in multiple ways, given that several molecular components of the cell cycle network are controlled in a circadian manner. For example, in the network of cyclin-dependent kinases (Cdks) that governs progression along the successive phases of the cell cycle, the synthesis of the kinase Wee1, which inhibits the G2/M transition, is enhanced by the complex CLOCK-BMAL1 that plays a central role in the circadian clock network. Another component of the latter network, REV-ERBα, inhibits the synthesis of the Cdk inhibitor p21. Moreover, the synthesis of the oncogene c-Myc, which promotes G1 cyclin synthesis, is repressed by CLOCK-BMAL1. Using detailed computational models for the two networks we investigate the conditions in which the mammalian cell cycle can be entrained by the circadian clock. We show that the cell cycle can be brought to oscillate at a period of 24 h or 48 h when its autonomous period prior to coupling is in an appropriate range. The model indicates that the combination of multiple modes of coupling does not necessarily facilitate entrainment of the cell cycle by the circadian clock. Entrainment can also occur as a result of circadian variations in the level of a growth factor controlling entry into G1. Outside the range of entrainment, the coupling to the circadian clock may lead to disconnected oscillations in the cell cycle and the circadian system, or to complex oscillatory dynamics of the cell cycle in the form of endoreplication, complex periodic oscillations or chaos. The model predicts that the transition from entrainment to 24 h or 48 h might occur when the strength of coupling to the circadian clock or the level of growth factor decrease below critical values