Role of immediate early gene expression in cortical morphogenesis and plasticity

Paternal ethanol exposure alters offspring motor skills and behavior in a sex-dependent manner and modifies early growth response 1 expression in the medial prefrontal cortex

BACKGROUND

Alcohol consumption is linked to various health issues exerting direct effects on the consumer and indirectly on offspring through both maternal and paternal transmission pathways. Our recent studies highlight the importance of paternal health before conception, showing that male ethanol consumption can alter epigenetic sperm marks and DNA integrity and testicular organization which led to adverse effects on embryonic development and induced alterations in testicular and sperm characteristics in the offspring.

METHODS

Based on these findings, this study explores the effects of paternal ethanol (15 % v/v) consumption for 12 days on motor development in mice offspring. We also analyzed different behavioral parameters and evaluated the expression of immediate early genes from the medial prefrontal cortex in the progeny during adulthood.

RESULTS

Paternal alcohol intake negatively affects the offspring, showing a delay in the acquisition of motor developmental skills at an early age and some modifications of behavior in a sex-dependent manner in adulthood. Furthermore, this consumption shows an increase in the expression of the Early Growth Response 1 gene in both males and females in the medial prefrontal cortex.

LIMITATIONS

In situ expression of the early growth response 1 gene was not measured. Hormonal fluctuations during the estrous cycle of the female offspring were not considered, these changes could interact with the observed outcomes.

CONCLUSIONS

This gene plays a key role in regulating cognition, emotion, and behavior. These findings highlight the importance of considering paternal health and alcohol consumption when assessing the risks to future generations.

Non-cell Autonomous OTX2 Homeoprotein Regulates Visual Cortex Plasticity Through Gadd45b/g

The non-cell autonomous transfer of OTX2 homeoprotein transcription factor into juvenile mouse cerebral cortex regulates parvalbumin interneuron maturation and critical period timing. By analyzing gene expression in primary visual cortex of wild-type and Otx2+/GFP mice at plastic and nonplastic ages, we identified several putative genes implicated in Otx2-dependent visual cortex plasticity for ocular dominance. Cortical OTX2 infusion in juvenile mice induced Gadd45b/g expression through direct regulation of transcription. Intriguingly, a reverse effect was found in the adult, where reducing cortical OTX2 resulted in Gadd45b/g upregulation. Viral expression of Gadd45b in adult visual cortex directly induced ocular dominance plasticity with concomitant changes in MeCP2 foci within parvalbumin interneurons and in methylation states of several plasticity gene promoters, suggesting epigenetic regulation. This interaction provides a molecular mechanism for OTX2 to trigger critical period plasticity yet suppress adult plasticity.

A Mouse Model for Conditional Secretion of Specific Single-Chain Antibodies Provides Genetic Evidence for Regulation of Cortical Plasticity by a Non-cell Autonomous Homeoprotein Transcription Factor

During postnatal life the cerebral cortex passes through critical periods of plasticity allowing its physiological adaptation to the environment. In the visual cortex, critical period onset and closure are influenced by the non-cell autonomous activity of the Otx2 homeoprotein transcription factor, which regulates the maturation of parvalbumin-expressing inhibitory interneurons (PV cells). In adult mice, the maintenance of a non-plastic adult state requires continuous Otx2 import by PV cells. An important source of extra-cortical Otx2 is the choroid plexus, which secretes Otx2 into the cerebrospinal fluid. Otx2 secretion and internalization requires two small peptidic domains that are part of the DNA-binding domain. Thus, mutating these “transfer” sequences also modifies cell autonomous transcription, precluding this approach to obtain a cell autonomous-only mouse. Here, we develop a mouse model with inducible secretion of an anti-Otx2 single-chain antibody to trap Otx2 in the extracellular milieu. Postnatal secretion of this single-chain antibody by PV cells delays PV maturation and reduces plasticity gene expression. Induced adult expression of this single-chain antibody in cerebrospinal fluid decreases Otx2 internalization by PV cells, strongly induces plasticity gene expression and reopens physiological plasticity. We provide the first mammalian genetic evidence for a signaling mechanism involving intercellular transfer of a homeoprotein transcription factor. Our single-chain antibody mouse model is a valid strategy for extracellular neutralization that could be applied to other homeoproteins and signaling molecules within and beyond the nervous system.

Classically, cell signaling is based on the secretion of molecules that bind cell surface receptors. Lipophilic agents can do without cell-surface receptors due to their ability to diffuse through the plasma membrane, but this is normally not the case for proteins, which cannot pass the membrane barrier. However, homeoprotein transcription factors represent an exception as they are secreted and internalized by live cells owing to two peptidic domains. An important illustration of this novel signaling mechanism is provided by Otx2, a homeoprotein that travels from the choroid plexus to specific inhibitory neurons in the cerebral cortex, where it regulates physiological plasticity throughout life. Because the two transfer peptides are in the DNA-binding domain of Otx2, it is impossible to mutate them without altering both cell signaling and cell-autonomous functions. We have therefore developed a mouse in which a secreted anti-Otx2 single-chain antibody can be induced to trap extracellular Otx2 while leaving its cell autonomous function untouched. We show that neutralizing extracellular Otx2 modifies the expression of plasticity genes in the visual cortex, thus providing the first genetic demonstration for homeoprotein signaling in a mammal.

RANTES correlates with inflammatory activity and synaptic excitability in multiple sclerosis

BACKGROUND

Alterations of synaptic transmission induced by inflammatory activity have been linked to the pathogenic mechanisms of multiple sclerosis (MS). Regulated upon activation, normal T-cell expressed, and secreted (RANTES) is a pro-inflammatory chemokine involved in MS pathophysiology, potentially able to regulate glutamate release and plasticity in MS brains, with relevant consequences on the clinical manifestations of the disease.

OBJECTIVE

To assess the role of RANTES in the regulation of cortical excitability.

METHODS

We explored the association of RANTES levels in the cerebrospinal fluid (CSF) of newly diagnosed MS patients with magnetic resonance imaging (MRI) and laboratory measures of inflammatory activity, as well its role in the control of cortical excitability and plasticity explored by means of transcranial magnetic stimulation (TMS), and in hippocampal mouse slices in vitro.

RESULTS

CSF levels of RANTES were remarkably high only in active MS patients and were correlated with the concentrations of interleukin-1β. RANTES levels were associated with TMS measures of cortical synaptic excitability, but not with long-term potentiation (LTP)-like plasticity. Similar findings were obtained in mouse hippocampal slices in vitro, where we observed that RANTES enhanced basal excitatory synaptic transmission with no effect on LTP.

CONCLUSION

RANTES correlates with inflammation and synaptic excitability in MS brains.

Satb1 ablation alters temporal expression of immediate early genes and reduces dendritic spine density during postnatal brain development

Complex behaviors, such as learning and memory, are associated with rapid changes in gene expression of neurons and subsequent formation of new synaptic connections. However, how external signals are processed to drive specific changes in gene expression is largely unknown. We found that the genome organizer protein Satb1 is highly expressed in mature neurons, primarily in the cerebral cortex, dentate hilus, and amygdala. In Satb1-null mice, cortical layer morphology was normal. However, in postnatal Satb1-null cortical pyramidal neurons, we found a substantial decrease in the density of dendritic spines, which play critical roles in synaptic transmission and plasticity. Further, we found that in the cerebral cortex, Satb1 binds to genomic loci of multiple immediate early genes (IEGs) (Fos, Fosb, Egr1, Egr2, Arc, and Bdnf) and other key neuronal genes, many of which have been implicated in synaptic plasticity. Loss of Satb1 resulted in greatly alters timing and expression levels of these IEGs during early postnatal cerebral cortical development and also upon stimulation in cortical organotypic cultures. These data indicate that Satb1 is required for proper temporal dynamics of IEG expression. Based on these findings, we propose that Satb1 plays a critical role in cortical neurons to facilitate neuronal plasticity.

Increased serum concentrations of macrophage inhibitory cytokine-1 in patients with obesity and type 2 diabetes mellitus: the influence of very low calorie diet

OBJECTIVE

Macrophage inhibitory cytokine-1 (MIC-1) is a novel regulator of energy homeostasis. We explored whether alterations in MIC-1 levels contribute to metabolic disturbances in patients with obesity and/or obesity and type 2 diabetes mellitus (T2DM).

DESIGN

We measured serum MIC-1 levels and its mRNA expression in subcutaneous and visceral adipose tissue of 17 obese nondiabetic women, 14 obese women with T2DM and 23 healthy lean women. We also explored the relationship of MIC-1 with anthropometric and biochemical parameters and studied the influence of 2-week very low calorie diet (VLCD) on serum MIC-1 levels.

METHODS

Serum MIC-1 levels were measured by ELISA and its mRNA expression was determined by RT-PCR.

RESULTS

Both obese and T2DM group had significantly elevated serum MIC-1 levels relative to controls. T2DM group had significantly higher serum MIC-1 levels relative to obese group. Serum MIC-1 positively correlated with body weight, body fat, and serum levels of triglycerides, glucose, HbAlc, and C-reactive protein and it was inversely related to serum high-density lipoprotein cholesterol. Fat mRNA MIC-1 expression did not significantly differ between lean and obese women but it was significantly higher in subcutaneous than in visceral fat in both groups. VLCD significantly increased serum MIC-1 levels in obese but not T2DM group.

CONCLUSION

Elevated MIC-1 levels in patients with obesity are further increased by the presence of T2DM. We suggest that in contrast to patients with cancer cachexia, increased MIC-1 levels in obese patients and diabetic patients do not induce weight loss.

Mechanisms mediating brain plasticity: IGF1 and adult hippocampal neurogenesis

This review addresses the role of serum insulin-like growth factor 1 (IGF1) as one mechanism of adult neural plasticity, specifically, its regulation of hippocampal neurogenesis among other plasticity-related processes. It is suggested that IGF has been reused advantageously both for the control of energy expenditure as a function of the organism's activity and to protect, repair, and plastically modulate the brain. Moreover, because as the main source of IGF1 in the adult organism is outside the brain and its presence in this organ is a function of the activity, IGF1 becomes an ideal factor to induce plastic/neuroprotective functions as a function of the organism's activity. The link for this point of view comes from the original function of IGF1 during ontogeny/phylogeny, the promotion of cell survival and control of neural cell numbers, whereas one of the IGF1 functions in the adult brain is the control of hippocampal neurogenesis. The investigation of the IGF1 role as mediator of exercise effects suggests that many but not all the effects of physical activity are mediated by IGF1. These investigations have contributed to delimit the role of IGF1 as mediator of exercise actions, but at the same time are unveiling new roles for serum IGF1 inside the brain.

The tuberous sclerosis complex proteins – a GRIPP on cognition and neurodevelopment

Tuberous sclerosis complex (TSC) is a multi-system disorder associated with mutations in the TSC1 (hamartin) or TSC2 (tuberin) genes. The neurocognitive features of TSC show wide variability and have generally been attributed to structural brain abnormalities and/or seizures. We review the fundamental roles of TSC1 and TSC2 in cell signalling and propose that because the hamartin-tuberin complex (hereafter referred to as TSC1-2) acts as a global regulator and integrator of a range of physiological processes ('GRIPP') the neurocognitive manifestations of TSC result directly from cell-signalling abnormalities. Under the GRIPP hypothesis, the spectrum of neurodevelopmental abnormalities is caused by the biochemical consequences of individual TSC1 and TSC2 mutations. Recognizing the importance of signalling disruption in the brain might improve our understanding of other neurocognitive disorders.

Chronic membrane depolarization-induced morphological alteration of developing neurons

During development of CNS, young neurons experience various stimuli, and thereafter differentiate to mature neurons in an activity-dependent manner. Membrane depolarization acts as an inducer of excitability and various signals in the neurons, which can be used as a model of neuronal activity. However, the mechanisms of the influence of membrane depolarization on neuronal differentiation have not been fully understood. Therefore, we investigated the effect of membrane depolarization on morphology of spines and generation of valid electrical activity. Using rat hippocampal cultures treated from the plating day with or without high KCl (35 mM, termed HK), we directly observed living neurons transfected with green fluorescence protein-expressing plasmid through a two-photon laser scanning confocal microscope and electrophysiological recording using a patch-clamp technique. Compared with controls, the neurons cultured with HK for 3 days in vitro (DIV) showed marked filopodia-like protrusions as well as an increase in the number of spines, but those cultured with HK for 6 DIV profoundly lost these spines, resulting in a small number of fine filopodia-like protrusions proximally and on the cell body, and a smooth surface of distal dendrites. Electrophysiological recordings showed no spontaneous responses in 6 DIV HK-treated neurons. Moreover, addition of an N-methyl-D-aspartate receptor (NMDAR) antagonist to HK-treated neurons blocked the shrinkage and decrease in the number of filopodia-like protrusions significantly. These findings suggest that membrane depolarization of developing neurons induces synaptogenesis in the early stages of development but chronic treatment with HK causes pathological changes through NMDAR, and that there may be alternative mechanisms for the physiological differentiation of neurons in later developmental stages.

Intermittent ethanol exposure induces inflammatory brain damage and causes long-term behavioural alterations in adolescent rats

Adolescent brain development seems to be important for the maturation of brain structures and behaviour. Intermittent binge ethanol drinking is common among adolescents, and this type of drinking can induce brain damage. Because we have demonstrated that chronic ethanol treatment induces inflammatory processes in the brain, we investigate whether intermittent ethanol intoxication enhances cyclooxygenase-2 (COX-2) and inducible nitric oxide synthase (iNOS) in adolescent rats, and whether these mediators induce brain damage and cause permanent cognitive dysfunctions. Adolescent rats were exposed to ethanol (3.0 g/kg) for two consecutive days at 48-h intervals over 14 days. Levels of COX-2, iNOS and cell death were assessed in the neocortex, hippocampus and cerebellum 24 h after the final ethanol administration. The following day or 20 days after the final injection (adult stage), animals were tested for different behavioural tests (conditional discrimination learning, rotarod, object recognition, beam-walking performance) to assess cognitive and motor functions. Our results show that intermittent ethanol intoxication upregulates COX-2 and iNOS levels, and increases cell death in the neocortex, hippocampus and cerebellum. Furthermore, animals treated with ethanol during adolescence exhibited behavioural deficits that were evident at the end of ethanol treatments and at the adult stage. Administration of indomethacin, a COX-2 inhibitor, abolishes the induction of COX-2 and iNOS expression and cell death, preventing ethanol-induced behavioural deficits. These findings indicate that binge pattern exposure to ethanol during adolescence induces brain damage by inflammatory processes and causes long-lasting neurobehavioural consequences. Accordingly, administering indomethacin protects against ethanol-induced brain damage and prevents detrimental ethanol effects on cognitive and motor processes.

Knockdown of Nurr1 in the rat hippocampus: implications to spatial discrimination learning and memory

Nurr1 expression is up-regulated in the brain following associative learning experiences, but its relevance to cognitive processes remains unclear. In these studies, rats initially received bilateral hippocampal infusions of control or antisense oligodeoxynucleotides (ODNs) 1 h prior to training in a holeboard spatial discrimination task. Such pre-training infusions of nurr1 antisense ODNs caused a moderate effect in learning the task and also impaired LTM tested 7 d later. In a second experiment, ODN infusions were given immediately after the animals had received two sessions of training, during which all animals showed normal learning. Although antisense treated rats were significantly impaired during the post-infusion stages of acquisition of the task, no group differences were observed during the LTM test given 7 d later. These animals were subjected 3 d later to reversal training in the same maze in the absence of any additional treatments. Remarkably, rats previously treated with antisense ODNs displayed perseveration: The animals were fixated with the previously learned pattern of baited holes, causing them to be significantly impaired in the extinction of acquired spatial preferences and future learning. We postulate that Nurr1 function in the hippocampus is important for normal cognitive processes.

Growth Differentiation Factor-15: Induction in Liver Injury Through p53 and Tumor Necrosis Factor-Independent Mechanisms1

Expression of macrophage inhibitory cytokine-1 (MIC-1), a divergent transforming growth factor-beta family member, and its murine ortholog, growth/differentiation factor-15 (GDF-15), is induced in hepatocytes by surgical and chemical injury and heat shock. Here, we demonstrate that the regulation of GDF-15/MIC-1 expression may be evolutionarily conserved because MIC-1 was induced in diseased human livers. Gdf15 induction was independent of protein synthesis, a hallmark of immediate-early gene regulation. Although tumor necrosis factor (TNF) induced GDF-15 expression, injury-elicited Gdf15 expression was not reduced in mice deficient for both TNF receptor subtypes. Furthermore, although the stress sensor p53 is known to induce GDF-15/MIC-1 expression, injury-elicited Gdf15 expression was unchanged in p53 null mice. Our results demonstrate that GDF-15 induction is an immediate early response to liver injury that can occur through TNF and p53 independent pathways.

Gene expression profile activated by the chemokine CCL5/RANTES in human neuronal cells

Differentiated human NT2-N neurons were shown to express CCR5 and CXCR4 chemokine receptor mRNA and protein, and to be responsive to the chemokines CCL5 and CXCL12. Using cDNA microarray technology, CCL5 was found to induce a distinct transcriptional program, with reproducible induction of 46 and 9 genes after 2 and 8 hr of treatment, respectively. Conversely, downregulation of 20 and 7 genes was observed after 2 and 8 hr of treatment, respectively. Modulation of a selected panel of CCL5-responsive genes was also confirmed by quantitative RT-PCR and Western blot and compared to gene expression changes induced by CXCL12 treatment. Gene clustering identified distinct functional subsets of CCL5-responsive molecules, and a significant number of expressed sequence tags encoding unknown genes. CCL5-responsive genes comprise a significant number of enzymes, transcription factors, and miscellaneous molecules involved in neuronal survival and differentiation, including neurite outgrowth and synaptogenesis. Our results suggest that CCL5 biological functions might go beyond its recognized chemotactic activity in the central nervous system, in particular with regard to the control of neural plasticity events both during development and in postnatal life.

Effect of early isolation on the synaptic function in the dentate gyrus and field CA1 of the guinea pig

We previously reported that neonatal isolation shapes neuron morphology remarkably in the dentate gyrus and hippocampus of the guinea pig, a precocial rodent whose brain is at an advanced stage of maturation at birth. The aim of the present work was to investigate the effects of early isolation on the physiology of the hippocampal trisynaptic circuit. Male and female guinea pigs were assigned at 6-7 days of age to either a social or an isolated environment. After 90-100 days, the animals were anesthetized and electrophysiological experiments were carried out. The monosynaptic response evoked by medial perforant path stimulation in the dentate gyrus (DG) and the following response trisynaptically evoked in field CA1 by the DG-CA3 system were evaluated with several stimulus protocols: (1) current source-density (CSD) analysis; (2) input/output function; (3) paired-pulse potentiation (PPP); and (4) long-term potentiation (LTP). Isolated animals exhibited a reduction in the magnitude of the current sinks in the middle molecular layer and granule cell layer of the DG and in the input/output function of the granule cell population excitatory postsynaptic potential (EPSP) and population spike (PS) over a wide range of stimuli. The latter effect was larger in males. The ratio between the PS and EPSP of the granule cells was reduced in isolated compared to control males, but the opposite occurred in females. Isolation affected PPP of the granule cell response in males only, causing a larger facilitation of the PS. No isolation-related effects were found in the magnitude of the LTP of the DG response in either sex. Isolated animals exhibited a reduction in the current sinks in stratum radiatum and stratum pyramidale of field CA1 and in the input/output function of the EPSP and PS of field CA1. These effects were larger in males. The results show that early isolation causes a reduction in the synaptic function of the DG-CA3-CA1 system, driven by perforant path volleys. The isolation-induced impairment in signal processing along the hippocampal network suggests that the outcome of early isolation may be an impairment in the memory functions in which the entorhinal-hippocampal system plays a key role.