The germline coordinates mitokine signaling.

The ability of mitochondria to coordinate stress responses across tissues is critical for health. In C. elegans, neurons experiencing mitochondrial stress elicit an inter-tissue signaling pathway through the release of mitokine signals, such as serotonin or the Wnt ligand EGL-20, which activate the mitochondrial unfolded protein response (UPRMT) in the periphery to promote organismal health and lifespan. We find that germline mitochondria play a surprising role in neuron-to-periphery UPRMT signaling. Specifically, we find that germline mitochondria signal downstream of neuronal mitokines, Wnt and serotonin, and upstream of lipid metabolic pathways in the periphery to regulate UPRMT activation. We also find that the germline tissue itself is essential for UPRMT signaling. We propose that the germline has a central signaling role in coordinating mitochondrial stress responses across tissues, and germline mitochondria play a defining role in this coordination because of their inherent roles in germline integrity and inter-tissue signaling.

Neuroendocrine Coordination of Mitochondrial Stress Signaling and Proteostasis.

During neurodegenerative disease, the toxic accumulation of aggregates and misfolded proteins is often accompanied with widespread changes in peripheral metabolism, even in cells in which the aggregating protein is not present. The mechanism by which the central nervous system elicits a distal reaction to proteotoxic stress remains unknown. We hypothesized that the endocrine communication of neuronal stress plays a causative role in the changes in mitochondrial homeostasis associated with proteotoxic disease states. We find that an aggregation-prone protein expressed in the neurons of C. elegans binds to mitochondria, eliciting a global induction of a mitochondrial-specific unfolded protein response (UPR(mt)), affecting whole-animal physiology. Importantly, dense core vesicle release and secretion of the neurotransmitter serotonin is required for the signal's propagation. Collectively, these data suggest the commandeering of a nutrient sensing network to allow for cell-to-cell communication between mitochondria in response to protein folding stress in the nervous system.

Systemic stress signalling: understanding the cell non-autonomous control of proteostasis.

Proteome maintenance is crucial to cellular health and viability, and is typically thought to be controlled in a cell-autonomous manner. However, recent evidence indicates that protein-folding defects can systemically activate proteostasis mechanisms through signalling pathways that coordinate stress responses among tissues. Coordination of ageing rates between tissues may also be mediated by systemic modulation of proteostasis. These findings suggest that proteome maintenance is a systemically regulated process, a discovery that may have important therapeutic implications.

Understanding social attachment as a window into the neural basis of prosocial behavior.

The representation and demonstration of human values are intimately tied to our status as a social species. Humans are relatively unique in our ability to form enduring social attachments, characterized by the development of a selective bond that persists over time. Such relationships include the bonds between parents and offspring, pair bonds between partners and other affiliative contacts, in addition to group relationships to which we may form direct and symbolic affiliations. Many of the cognitive and behavioral processes thought to be linked to our capacity for social attachment-including consolation, empathy, and social motivation, and the implicated neural circuits mediating these constructs, are shared with those thought to be important for the representation of prosocial values. This perspective piece will examine the hypothesis that our ability to form such long-term bonds may play an essential role in the construction of human values and ethical systems, and that components of prosocial behaviors are shared across species. Humans are one of a few species that form such long-term and exclusive attachments and our understanding of the neurobiology underlying attachment behavior has been advanced by studying behavior in non-human animals. The overlap in behavioral and affective constructs underlying attachment behavior and value representation is discussed, followed by evidence from other species that demonstrate attachment behavior that supports the overlapping neurobiological basis for social bonds and prosocial behavior. The understanding of attachment biology has broad implications for human health as well as for understanding the basis for and variations in prosocial behavior.

Attachment across the lifespan: Examining the intersection of pair bonding neurobiology and healthy aging.

Increasing evidence suggests that intact social bonds are protective against age-related morbidity, while bond disruption and social isolation increase the risk for multiple age-related diseases. Social attachments, the enduring, selective bonds formed between individuals, are thus essential to human health. Socially monogamous species like the prairie vole (M. ochrogaster) form long-term pair bonds, allowing us to investigate the mechanisms underlying attachment and the poorly understood connection between social bonds and health. In this review, we explore several potential areas of focus emerging from data in humans and other species associating attachment and healthy aging, and evidence from prairie voles that may clarify this link. We examine gaps in our understanding of social cognition and pair bond behavior. Finally, we discuss physiologic pathways related to pair bonding that promote resilience to the processes of aging and age-related disease. Advances in the development of molecular genetic tools in monogamous species will allow us to bridge the mechanistic gaps presented and identify conserved research and therapeutic targets relevant to human health and aging.

Oxytocin receptor is not required for social attachment in prairie voles.

Prairie voles are among a small group of mammals that display long-term social attachment between mating partners. Many pharmacological studies show that signaling via the oxytocin receptor (Oxtr) is critical for the display of social monogamy in these animals. We used CRISPR mutagenesis to generate three different Oxtr-null mutant prairie vole lines. Oxtr mutants displayed social attachment such that males and females showed a behavioral preference for their mating partners over a stranger of the opposite sex, even when assayed using different experimental setups. Mothers lacking Oxtr delivered viable pups, and parents displayed care for their young and raised them to the weanling stage. Together, our studies unexpectedly reveal that social attachment, parturition, and parental behavior can occur in the absence of Oxtr signaling in prairie voles.

Rethinking the Architecture of Attachment: New Insights into the Role for Oxytocin Signaling.

Social attachments, the enduring bonds between individuals and groups, are essential to health and well-being. The appropriate formation and maintenance of social relationships depend upon a number of affective processes, including stress regulation, motivation, reward, as well as reciprocal interactions necessary for evaluating the affective state of others. A genetic, molecular, and neural circuit level understanding of social attachments therefore provides a powerful substrate for probing the affective processes associated with social behaviors. Socially monogamous species form long-term pair bonds, allowing us to investigate the mechanisms underlying attachment. Now, molecular genetic tools permit manipulations in monogamous species. Studies using these tools reveal new insights into the genetic and neuroendocrine factors that design and control the neural architecture underlying attachment behavior. We focus this discussion on the prairie vole and oxytocinergic signaling in this and related species as a model of attachment behavior that has been studied in the context of genetic and pharmacological manipulations. We consider developmental processes that impact the demonstration of bonding behavior across genetic backgrounds, the modularity of mechanisms underlying bonding behaviors, and the distributed circuitry supporting these behaviors. Incorporating such theoretical considerations when interpreting reverse genetic studies in the context of the rich ethological and pharmacological data collected in monogamous species provides an important framework for studies of attachment behavior in both animal models and studies of human relationships.

Magnetic resonance spectroscopic investigation of mitochondrial fuel metabolism and energetics in cultured human fibroblasts: effects of pyruvate dehydrogenase complex deficiency and dichloroacetate.

The pyruvate dehydrogenase complex (PDC) is integral to metabolism and energetics. Congenital PDC deficiency leads to lactic acidosis, neurological degeneration and early death. An investigational compound for such defects is dichloroacetate (DCA), which activates the PDC (inhibiting reversible phosphorylation of the E1alpha subunit) and decreases its turnover. Here, primary human fibroblast cultures from five healthy subjects and six patients with mutations in the PDC-E1 component were grown in media+/-DCA, exposed to media containing (13)C-labeled glucose, and studied (as cell extracts) by nuclear magnetic resonance (NMR) spectroscopy. Computer modeling of NMR-derived (13)C-glutamate isotopomeric patterns estimated relative carbon flow through TCA cycle-associated pathways and characterized effects of PDC deficiency on metabolism and energetics. Rates of glucose consumption (GCR) and lactate production (LPR) were measured. With the exception of one patient cell line expressing an unusual splicing mutation, PDC-deficient cells had significantly higher GCR, LPR and label-derived acetyl-CoA, indicative of increased glycolysis vs. controls. In all cells, DCA caused a major shift (40% decrease) from anaplerotic-related pathways (e.g., pyruvate carboxylase) toward flux through PDC. Ignoring the patient with the splicing mutation, DCA decreased average glycolysis (29%) in patient cells, but had no significant effect on control cells, and did not change LPR or the nucleoside triphosphate to diphosphate ratio (NTP/NDP) in either cell type. Maintenance of NTP despite reduced glycolysis indicates that DCA improves metabolic efficiency by increasing glucose oxidation. This study demonstrates that NMR spectroscopy provides insight into biochemical consequences of PDC deficiency and the mechanism of putative therapeutic agents.