Effects of oxytocin on serotonin 1B agonist-induced autism-like behavior in mice.

Social impairments in autism remain poorly understood and without approved pharmacotherapies. Novel animals models are needed to elucidate mechanisms and evaluate novel treatments for the social deficits in autism. Recently, serotonin 1B receptor (5-HT1B) agonist challenge in mice was shown to induce autism-like behaviors including perseveration, reduced prepulse inhibition, and delayed alternation deficits. However, the effects of 5-HT1B agonists on autism-related social behaviors in mice remain unknown. Here, we examine the effects of 5-HT1B agonist challenge on sociability and preference for social novelty in mice. We also examine the effects of 5-HT1B agonist treatment on average rearing duration, a putative rodent measure of non-selective attention. Non-selective attention is an associated feature of autism that is also not well understood. We show that 5-HT1B receptor activation reduces sociability, preference for social novelty, and rearing in mice. In addition, we examine the ability of oxytocin, an off-label treatment for the social impairments in autism, to reverse 5-HT1B agonist-induced social and attention deficits in mice. We show that oxytocin restores social novelty preference in mice treated with a 5-HT1B agonist. We also show that oxytocin attenuates 5-HT1B agonist-induced sociability and rearing deficits in mice. Our results suggest that 5-HT1B agonist challenge provides a useful pharmacological mouse model for aspects of autism, and implicate 5-HT1B in autism social and attention deficits. Moreover, our findings suggest that oxytocin may treat the social deficits in autism through a mechanism involving 5-HT1B.

p38α mitogen-activated protein kinase depletion and repression of signal transduction to translation machinery by miR-124 and -128 in neurons.

The p38α to p38δ mitogen-activated protein kinases (MAPKs) are central regulatory nodes coordinating acute stress and inflammatory responses. Their activation leads to rapid adjustment of protein synthesis, for instance translational induction of proinflammatory cytokines. The only known direct link of p38 to translation machinery is the MAPK signal-integrating kinase Mnk. Only p38α and p38ß transcripts are ubiquitously expressed. These mRNAs encode highly conserved proteins that equally phosphorylate recombinant Mnk1 in vitro. We discovered that expression of the p38α protein, but not the p38ß isoform, is suppressed in the brain. This is due to p38α depletion by two neuron-selective microRNAs (miRNAs), miR-124 and -128. Suppression of p38α protein was reversed by miR-124/-128 antisense oligonucleotides in primary explant neuronal cultures. Targeted p38α depletion reduced Mnk1 activation, which cannot be compensated by p38ß. Our research shows that p38α alone controls acute stress and cytokine signaling from p38 MAPK to translation machinery. This regulatory axis is greatly diminished in neurons, which may insulate brain physiology and function from p38α-Mnk1-mediated signaling.

Attenuation of neurovirulence, biodistribution, and shedding of a poliovirus:rhinovirus chimera after intrathalamic inoculation in Macaca fascicularis.

A dependence of poliovirus on an unorthodox translation initiation mode can be targeted selectively to drive viral protein synthesis and cytotoxicity in malignant cells. Transformed cells are naturally susceptible to poliovirus, due to widespread ectopic upregulation of the poliovirus receptor, Necl-5, in ectodermal/neuroectodermal cancers. Viral tumor cell killing and the host immunologic response it engenders produce potent, lasting antineoplastic effects in animal tumor models. Clinical application of this principle depends on unequivocal demonstration of safety in primate models for paralytic poliomyelitis. We conducted extensive dose-range-finding, toxicity, biodistribution, shedding, and neutralizing antibody studies of the prototype oncolytic poliovirus recombinant, PVS-RIPO, after intrathalamic inoculation in Macaca fascicularis. These studies suggest that intracerebral PVS-RIPO inoculation does not lead to viral propagation in the central nervous system (CNS), does not cause histopathological CNS lesions or neurological symptoms that can be attributed to the virus, is not associated with extraneural virus dissemination or replication and does not induce shedding of virus with stool. Intrathalamic PVS-RIPO inoculation induced neutralizing antibody responses against poliovirus serotype 1 in all animals studied.

A small molecule-directed approach to control protein localization and function.

Protein localization is tightly linked with function, such that the subcellular distribution of a protein serves as an important control point regulating activity. Exploiting this regulatory mechanism, we present here a general approach by which protein location, and hence function, may be controlled on demand in the budding yeast. In this system a small molecule, rapamycin, is used to temporarily recruit a strong cellular address signal to the target protein, placing subcellular localization under control of the selective chemical stimulus. The kinetics of this system are rapid: rapamycin-directed nucleo-cytoplasmic transport is evident 10-12 min post-treatment and the process is reversible upon removal of rapamycin. Accordingly, we envision this platform as a promising approach for the systematic construction of conditional loss-of-function mutants. As proof of principle, we used this system to direct nuclear export of the essential heat shock transcription factor Hsf1p, thereby mimicking the cell-cycle arrest phenotype of an hsf1 temperature-sensitive mutant. Our drug-induced localization platform also provides a method by which protein localization can be uncoupled from endogenous cell signalling events, addressing the necessity or sufficiency of a given localization shift for a particular cell process. To illustrate, we directed the nuclear import of the calcineurin-dependent transcription factor Crz1p in the absence of native stimuli; this analysis directly substantiates that nuclear translocation of this protein is insufficient for its transcriptional activity. In total, this technology represents a powerful method for the generation of conditional alleles and directed mislocalization studies in yeast, with potential applicability on a genome-wide scale.

Analysis of the yeast kinome reveals a network of regulated protein localization during filamentous growth.

The subcellular distribution of kinases and other signaling proteins is regulated in response to cellular cues; however, the extent of this regulation has not been investigated for any gene set in any organism. Here, we present a systematic analysis of protein kinases in the budding yeast, screening for differential localization during filamentous growth. Filamentous growth is an important stress response involving mitogen-activated protein kinase and cAMP-dependent protein kinase signaling modules, wherein yeast cells form interconnected and elongated chains. Because standard strains of yeast are nonfilamentous, we constructed a unique set of 125 kinase-yellow fluorescent protein chimeras in the filamentous Sigma1278b strain for this study. In total, we identified six cytoplasmic kinases (Bcy1p, Fus3p, Ksp1p, Kss1p, Sks1p, and Tpk2p) that localize predominantly to the nucleus during filamentous growth. These kinases form part of an interdependent, localization-based regulatory network: deletion of each individual kinase, or loss of kinase activity, disrupts the nuclear translocation of at least two other kinases. In particular, this study highlights a previously unknown function for the kinase Ksp1p, indicating the essentiality of its nuclear translocation during yeast filamentous growth. Thus, the localization of Ksp1p and the other kinases identified here is tightly controlled during filamentous growth, representing an overlooked regulatory component of this stress response.

Overexpression of autophagy-related genes inhibits yeast filamentous growth.

Under conditions of nitrogen stress, the budding yeast S. cerevisiae initiates a cellular response involving the activation of autophagy, an intracellular catabolic process for the degradation and recycling of proteins and organelles. In certain strains of yeast, nitrogen stress also drives a striking developmental transition to a filamentous form of growth, in which cells remain physically connected after cytokinesis. We recently identified an interrelationship between these processes, with the inhibition of autophagy resulting in exaggerated filamentous growth. Our results suggest a model wherein autophagy mitigates nutrient stress, and filamentous growth is responsive to the degree of this stress. Here, we extended these studies to encompass a phenotypic analysis of filamentous growth upon overexpression of autophagy-related (ATG) genes. Specifically, overexpression of ATG1, ATG3, ATG7, ATG17, ATG19, ATG23, ATG24 and ATG29 inhibited filamentous growth. From our understanding of autophagy in yeast, overexpression of these genes does not markedly affect the activity of the pathway; thus, we do not expect that this filamentous growth phenotype is due strictly to diminished nitrogen stress in ATG overexpression mutants. Rather, these results highlight an additional undefined regulatory mechanism linking autophagy and filamentous growth, possibly independent of the upstream nitrogen-sensing machinery feeding into both processes.