Synaptic proteome changes in the hypothalamus of mother rats.

To establish synaptic proteome changes associated with motherhood, we isolated synaptosome fractions from the hypothalamus of mother rats and non-maternal control females at the 11th postpartum day. Proteomic analysis by two-dimensional differential gel electrophoresis combined with mass spectrometric protein identification established 26 significant proteins, 7 increasing and 19 decreasing protein levels in the dams. The altered proteins are mainly involved in energy homeostasis, protein folding, and metabolic processes suggesting the involvement of these cellular processes in maternal adaptations. The decrease in a significantly altered protein, complement component 1q subcomponent-binding protein (C1qbp) was validated with Western blotting. Furthermore, immunohistochemistry showed its presence in hypothalamic fibers and terminals in agreement with its presence in synaptosomes. We also found the expression of C1qbp in different hypothalamic nuclei including the preoptic area and the paraventricular hypothalamic nucleus at the protein and at the mRNA level using immunohistochemistry and in situ hybridization histochemistry, respectively. Bioinformatical network analysis revealed that cytokines, growth factors, and protein kinases are common regulators, which indicates a complex regulation of the proteome change in mothers. The results suggest that maternal responsiveness is associated with synaptic proteins level changes in the hypothalamus, and that growth factors and cytokines may govern these alterations. BIOLOGICAL SIGNIFICANCE The period of motherhood is accompanied with several behavioral, neuroendocrine, emotional and metabolic adaptations in the brain. Although it is established that various hypothalamic networks participate in the maternal adaptations of the rodent brain, our knowledge on the molecular background of these alterations remains seriously limited. In the present study, we first determined that the functional alterations of the maternal brain can be detected at the level of the synaptic proteome in the hypothalamus. Independent confirmation of synaptic localization, and also the established decrease in the level of C1qbp protein suggest the validity of the data. Common regulators of altered proteins belonging to the growth factor and cytokine family suggest that the synaptic adaptation is governed by these extracellular signals and future studies should focus on their specific roles. Our study was also the first to describe the expression pattern of C1qbp in the hypothalamus, a protein potentially involved in mitochondrial and neuroimmunological regulations of synaptic plasticity. Its presence in the preoptic area responsible for maternal behaviors and also in the paraventricular hypothalamic and arcuate nuclei regulating hormonal levels suggests that the same proteins may be involved in different aspects of maternal adaptations. The conclusions of the present work contribute to establishing the molecular alterations that determine different maternal adaptations in the brain. Since maternal changes are models of neuronal plasticity in all social interactions, the reported results can affect a wide field of molecular and behavioral neuroscience.

[1]  Linda Greensmith,et al.  Induction of heat shock proteins for protection against oxidative stress. , 2009, Advanced drug delivery reviews.

[2]  D. Slattery,et al.  No stress please! Mechanisms of stress hyporesponsiveness of the maternal brain , 2008, The Journal of physiology.

[3]  R. Irwin,et al.  Estradiol In Vivo Regulation of Brain Mitochondrial Proteome , 2007, The Journal of Neuroscience.

[4]  K. Unsicker,et al.  Co-activation of TGF-ss and cytokine signaling pathways are required for neurotrophic functions. , 2000, Cytokine & growth factor reviews.

[5]  L. Boulanger,et al.  Immune Proteins in Brain Development and Synaptic Plasticity , 2009, Neuron.

[6]  D. Pfaff,et al.  Hormonal induction of lordosis and ear wiggling in rat pups: gender and age differences , 2007, Endocrine.

[7]  K. L. Peterson,et al.  The C1q-binding cell membrane proteins cC1q-R and gC1q-R are released from activated cells: subcellular distribution and immunochemical characterization. , 1997, Clinical immunology and immunopathology.

[8]  T. Sist,et al.  Maintenance and decline of the suppression of infanticide in mother rats , 1991, Physiology & Behavior.

[9]  M. Eilers,et al.  Control of cell proliferation by Myc. , 1998, Trends in cell biology.

[10]  A. Douglas,et al.  Adaptive Responses of the Maternal Hypothalamic‐Pituitary‐Adrenal Axis during Pregnancy and Lactation , 2008, Journal of neuroendocrinology.

[11]  K. Bennett,et al.  Dietary magnesium restriction reduces amygdala–hypothalamic GluN1 receptor complex levels in mice , 2014, Brain Structure and Function.

[12]  T. Uchiumi,et al.  p32/gC1qR is indispensable for fetal development and mitochondrial translation: importance of its RNA-binding ability , 2012, Nucleic acids research.

[13]  A. D. Mayer,et al.  Hormonal basis during pregnancy for the onset of maternal behavior in the rat , 1988, Psychoneuroendocrinology.

[14]  A. Starkov,et al.  The molecular identity of the mitochondrial Ca2+ sequestration system , 2010, The FEBS journal.

[15]  Á. Dobolyi,et al.  Time Course, Distribution and Cell Types of Induction of Transforming Growth Factor Betas following Middle Cerebral Artery Occlusion in the Rat Brain , 2012, PloS one.

[16]  Peilin Chen,et al.  Identification of neuronal input to the arcuate nucleus (ARH) activated during lactation: implications in the activation of neuropeptide Y neurons , 1999, Brain Research.

[17]  C. Osorio,et al.  2-D Fluorescence Difference Gel Electrophoresis (DIGE) in Neuroproteomics , 2010 .

[18]  J. Russell,et al.  Endocrine induced changes in brain function during pregnancy , 2010, Brain Research.

[19]  Larry J. Young,et al.  Neural mechanisms of mother–infant bonding and pair bonding: Similarities, differences, and broader implications , 2016, Hormones and Behavior.

[20]  M. Numan Motivational systems and the neural circuitry of maternal behavior in the rat. , 2007, Developmental psychobiology.

[21]  A. Willis,et al.  Isolation, cDNA cloning, and overexpression of a 33-kD cell surface glycoprotein that binds to the globular "heads" of C1q , 1994, The Journal of experimental medicine.

[22]  Á. Dobolyi,et al.  The Neuroprotective Functions of Transforming Growth Factor Beta Proteins , 2012, International journal of molecular sciences.

[23]  A. Fleming,et al.  Experience with pups sustains maternal responding in postpartum rats , 1987, Physiology & Behavior.

[24]  A. Fleming,et al.  Dendritic morphology in the striatum and hypothalamus differentially exhibits experience-dependent changes in response to maternal care and early social isolation , 2012, Behavioural Brain Research.

[25]  J. Bockaert,et al.  “Inflammatory” Cytokines , 2000, Journal of neurochemistry.

[26]  E. Masliah,et al.  Loss of TGF-β1 Leads to Increased Neuronal Cell Death and Microgliosis in Mouse Brain , 2003, Neuron.

[27]  D. Poulain,et al.  Maternity leads to morphological synaptic plasticity in the oxytocin system. , 2001, Progress in brain research.

[28]  B. Györffy,et al.  Synaptic mitochondria: a brain mitochondria cluster with a specific proteome. , 2015, Journal of proteomics.

[29]  G. Evan,et al.  Cell cycle: On target with Myc , 1996, Current Biology.

[30]  H. Tsukamura,et al.  Non-metabolic and metabolic factors causing lactational anestrus: rat models uncovering the neuroendocrine mechanism underlying the suckling-induced changes in the mother. , 2001, Progress in brain research.

[31]  R. Froemke,et al.  Oxytocin Enables Maternal Behavior by Balancing Cortical Inhibition , 2015, Nature.

[32]  Cheuk Y. Tang,et al.  Mapping of Brain Activity by Automated Volume Analysis of Immediate Early Genes , 2016, Cell.

[33]  W. R. Crowley Neuroendocrine regulation of lactation and milk production. , 2014, Comprehensive Physiology.

[34]  W. Balch,et al.  Differential Regulation of Exocytosis by Calcium and CAPS in Semi-Intact Synaptosomes , 1998, Neuron.

[35]  M. Palkovits,et al.  Anatomical and physiological evidence for involvement of tuberoinfundibular peptide of 39 residues in nociception , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[36]  S. Goswami,et al.  Hyaluronan binding protein 1 (HABP1)/C1QBP/p32 is an endogenous substrate for MAP kinase and is translocated to the nucleus upon mitogenic stimulation. , 2002, Biochemical and biophysical research communications.

[37]  Á. Dobolyi Central amylin expression and its induction in rat dams , 2009, Journal of neurochemistry.

[38]  T. Usdin,et al.  Maternally involved galanin neurons in the preoptic area of the rat , 2016, Brain Structure and Function.

[39]  C. Dulac,et al.  Neural control of maternal and paternal behaviors , 2014, Science.

[40]  Neuroendocrine regulation of maternal behavior , 2015, Frontiers in Neuroendocrinology.

[41]  M. Santello,et al.  TNFα in synaptic function: switching gears , 2012, Trends in Neurosciences.

[42]  L. Soucek,et al.  Making decisions through Myc , 2001, FEBS letters.

[43]  B. Soltys,et al.  Localization of P32 protein (gC1q-R) in mitochondria and at specific extramitochondrial locations in normal tissues , 2000, Histochemistry and Cell Biology.

[44]  A. Fleming,et al.  Flexibility and adaptation of the neural substrate that supports maternal behavior in mammals , 2013, Neuroscience & Biobehavioral Reviews.

[45]  A. Fleming,et al.  Disruption of maternal behaviour in virgin and postparturient rats following sagittal plane knife cuts in the preoptic area-hypothalamus , 1983, Behavioural Brain Research.

[46]  Ruibing Chen,et al.  Identification of a novel mitochondrial interacting protein of C1QBP using subcellular fractionation coupled with CoIP-MS , 2016, Analytical and Bioanalytical Chemistry.

[47]  J. Simpkins,et al.  Estrogen actions on mitochondria—Physiological and pathological implications , 2008, Molecular and Cellular Endocrinology.

[48]  W. Jahnen-Dechent,et al.  The multiligand-binding protein gC1qR, putative C1q receptor, is a mitochondrial protein. , 1998, Journal of immunology.

[49]  D. Alkon,et al.  Insulin, PKC signaling pathways and synaptic remodeling during memory storage and neuronal repair. , 2008, European journal of pharmacology.

[50]  F. Petraglia,et al.  Neuroendocrine mechanisms in pregnancy and parturition. , 2010, Endocrine reviews.

[51]  C. Baines,et al.  Complement 1q-binding protein inhibits the mitochondrial permeability transition pore and protects against oxidative stress-induced death. , 2011, The Biochemical journal.

[52]  J. Mercer,et al.  Hunger and Satiety Mechanisms and Their Potential Exploitation in the Regulation of Food Intake , 2016, Current Obesity Reports.

[53]  J. Sweatt,et al.  The Mitogen-Activated Protein Kinase Cascade Couples PKA and PKC to cAMP Response Element Binding Protein Phosphorylation in Area CA1 of Hippocampus , 1999, The Journal of Neuroscience.

[54]  M. Ehlers,et al.  TGF-β Signaling Specifies Axons during Brain Development , 2010, Cell.

[55]  M. Numan Hypothalamic neural circuits regulating maternal responsiveness toward infants. , 2006, Behavioral and cognitive neuroscience reviews.

[56]  T. Uchiumi,et al.  The role of TFAM-associated proteins in mitochondrial RNA metabolism. , 2012, Biochimica et biophysica acta.

[57]  D. Hockenbery,et al.  MYC and mitochondrial biogenesis. , 2014, Cold Spring Harbor perspectives in medicine.

[58]  Surjyendu Ray,et al.  An Examination of Dynamic Gene Expression Changes in the Mouse Brain During Pregnancy and the Postpartum Period , 2015, G3: Genes, Genomes, Genetics.

[59]  Jeffrey W. Smith,et al.  Mitochondrial p32 Protein Is a Critical Regulator of Tumor Metabolism via Maintenance of Oxidative Phosphorylation , 2010, Molecular and Cellular Biology.

[60]  Ofer Yizhar,et al.  A sexually dimorphic hypothalamic circuit controls maternal care and oxytocin secretion , 2015, Nature.

[61]  A. Halestrap What is the mitochondrial permeability transition pore? , 2009, Journal of molecular and cellular cardiology.

[62]  Peilin Chen,et al.  Suckling-induced activation of neuronal input to the dorsomedial nucleus of the hypothalamus: possible candidates for mediating the activation of DMH neuropeptide Y neurons during lactation , 2003, Brain Research.

[63]  K. Abe,et al.  Transforming growth factor-β1 promotes re-elongation of injured axons of cultured rat hippocampal neurons , 1996, Brain Research.

[64]  C. Dang,et al.  Studying Myc's role in metabolism regulation. , 2013, Methods in molecular biology.

[65]  S. Gammie,et al.  Genetic and neuroendocrine regulation of the postpartum brain , 2016, Frontiers in Neuroendocrinology.

[66]  C. Plata-salamán Cytokines and feeding. , 1998, International journal of obesity and related metabolic disorders : journal of the International Association for the Study of Obesity.

[67]  K. Kovács,et al.  Maternal neglect with reduced depressive-like behavior and blunted c-fos activation in Brattleboro mothers, the role of central vasopressin , 2012, Hormones and Behavior.

[68]  J. O'Callaghan,et al.  Divergent Roles for Tumor Necrosis Factor-α in the Brain , 2007, Journal of Neuroimmune Pharmacology.