Neonatal hyperoxia in mice triggers long-term cognitive deficits via impairments in cerebrovascular function and neurogenesis.

Preterm birth is the leading cause of death in children under 5 years of age. Premature infants who receive life-saving oxygen therapy often develop bronchopulmonary dysplasia (BPD), a chronic lung disease. Infants with BPD are at a high risk of abnormal neurodevelopment, including motor and cognitive difficulties. While neural progenitor cells (NPCs) are crucial for proper brain development, it is unclear whether they play a role in BPD-associated neurodevelopmental deficits. Here, we show that hyperoxia-induced experimental BPD in newborn mice led to lifelong impairments in cerebrovascular structure and function as well as impairments in NPC self-renewal and neurogenesis. A neurosphere assay utilizing nonhuman primate preterm baboon NPCs confirmed impairment in NPC function. Moreover, gene expression profiling revealed that genes involved in cell proliferation, angiogenesis, vascular autoregulation, neuronal formation, and neurotransmission were dysregulated following neonatal hyperoxia. These impairments were associated with motor and cognitive decline in aging hyperoxia-exposed mice, reminiscent of deficits observed in patients with BPD. Together, our findings establish a relationship between BPD and abnormal neurodevelopmental outcomes and identify molecular and cellular players of neonatal brain injury that persist throughout adulthood that may be targeted for early intervention to aid this vulnerable patient population.

Isolation of the side population from neurogenic niches enriches for endothelial cells.

In stem cell research, DNA-binding dyes offer the ability to purify live stem cells using flow cytometry as they form a low-fluorescence side population due to the activity of ABC transporters. Adult neural stem cells exist within the lateral ventricle and dentate gyrus of the adult brain yet the ability of DNA-binding dyes to identify these adult stem cells as side populations remains untested. The following experiments utilize the efflux of a DNA-binding dye, Vyrbant DyeCycle Violet (DCV), to isolate bona fide side populations in the mouse dentate gyrus and subventricular zone (SVZ), and test their sensitivity to ABC transporter inhibitors. A distinct side population was found in both the adult lateral ventricle and dentate gyrus using DCV fluorescence and forward scatter instead of the conventional dual fluorescence approach. These side populations responded strongly to inhibition with the ABC transporter antagonists, verapamil and fumitremorgin C. The majority of the cells residing in the side populations of dentate gyrus and SVZ were characterized by their expression of CD31. Additionally, at least 90% of all CD31+ cells found in the dentate gyrus and SVZ were negative for the hematopoietic marker CD45, leading to the hypothesis that the CD31+ cells in the side population were endothelial cells. These findings, therefore, suggest that the side population analysis provides an efficient method to purify CD31-expressing endothelial cells, but not adult neural stem cells.

RB regulates the production and the survival of newborn neurons in the embryonic and adult dentate gyrus.

In mammals, hippocampal dentate gyrus granule cells (DGCs) constitute a particular neuronal population produced both during embryogenesis and adult life, and play key roles in neural plasticity and memory. However, the molecular mechanisms regulating neurogenesis in the dentate lineage throughout development and adulthood are still not well understood. The Retinoblastoma protein (RB), a transcriptional repressor primarily involved in cell cycle control and cell death, plays crucial roles during cortical development but its function in the formation and maintenance of DGCs remains unknown. Here, we show that loss of RB during embryogenesis induces massive ectopic proliferation and delayed cell cycle exit of young DGCs specifically at late developmental stages but without affecting stem cells. This phenotype was partially counterbalanced by increased cell death. Similarly, during adulthood, loss of RB causes ectopic proliferation of newborn DGCs and dramatically impairs their survival. These results demonstrate a crucial role for RB in the generation and the survival of DGCs in the embryonic and the adult brain. © 2016 Wiley Periodicals, Inc.

Mitochondrial Dynamics Impacts Stem Cell Identity and Fate Decisions by Regulating a Nuclear Transcriptional Program.

Regulated mechanisms of stem cell maintenance are key to preventing stem cell depletion and aging. While mitochondrial morphology plays a fundamental role in tissue development and homeostasis, its role in stem cells remains unknown. Here, we uncover that mitochondrial dynamics regulates stem cell identity, self-renewal, and fate decisions by orchestrating a transcriptional program. Manipulation of mitochondrial structure, through OPA1 or MFN1/2 deletion, impaired neural stem cell (NSC) self-renewal, with consequent age-dependent depletion, neurogenesis defects, and cognitive impairments. Gene expression profiling revealed ectopic expression of the Notch self-renewal inhibitor Botch and premature induction of transcription factors that promote differentiation. Changes in mitochondrial dynamics regulate stem cell fate decisions by driving a physiological reactive oxygen species (ROS)-mediated process, which triggers a dual program to suppress self-renewal and promote differentiation via NRF2-mediated retrograde signaling. These findings reveal mitochondrial dynamics as an upstream regulator of essential mechanisms governing stem cell self-renewal and fate decisions through transcriptional programming.

Bcl-2 is required for the survival of doublecortin-expressing immature neurons.

In the adult brain only a small proportion of the neural stem and progenitor cells (NPCs) and their progeny survive to become mature neurons in the hippocampus. Recent studies have elucidated the roles for members of the B-cell lymphoma-2 (Bcl-2) family of proteins in regulating the survival of NPCs and their progeny at different stages of maturation, yet the requirement of Bcl-2 during this process remains unknown. Here we report that inducible removal of Bcl-2 from nestin-expressing neural stem/progenitor cells and their progeny resulted in a reduction in the survival of doublecortin-expressing cells in the absence of changing the number of radial-glial stem cells or dividing NPCs. The requirement of Bcl-2 for the survival of maturing NPCs was confirmed by removal of Bcl-2 through infecting NPCs using a retroviral strategy that resulted in the complete loss of Bcl-2 null cells by 30-day post-viral injection. Furthermore, we observed that the function of Bcl-2 in the adult-generated neurons was dependent on the Bcl-2-associated X (BAX) protein, since Bcl-2 null NPCs were rescued in BAX knockout mice. These results indicate that Bcl-2 is an essential regulator in the survival of doublecortin-expressing immature neurons through a mechanism that is upstream of BAX.

Opposing regulation of Sox2 by cell-cycle effectors E2f3a and E2f3b in neural stem cells.

The mechanisms through which cell-cycle control and cell-fate decisions are coordinated in proliferating stem cell populations are largely unknown. Here, we show that E2f3 isoforms, which control cell-cycle progression in cooperation with the retinoblastoma protein (pRb), have critical effects during developmental and adult neurogenesis. Loss of either E2f3 isoform disrupts Sox2 gene regulation and the balance between precursor maintenance and differentiation in the developing cortex. Both isoforms target the Sox2 locus to maintain baseline levels of Sox2 expression but antagonistically regulate Sox2 levels to instruct fate choices. E2f3-mediated regulation of Sox2 and precursor cell fate extends to the adult brain, where E2f3a loss results in defects in hippocampal neurogenesis and memory formation. Our results demonstrate a mechanism by which E2f3a and E2f3b differentially regulate Sox2 dosage in neural precursors, a finding that may have broad implications for the regulation of diverse stem cell populations.

Conditional disruption of calpain in the CNS alters dendrite morphology, impairs LTP, and promotes neuronal survival following injury.

Ubiquitous classical (typical) calpains, calpain-1 and calpain-2, are Ca(+2)-dependent cysteine proteases, which have been associated with numerous physiological and pathological cellular functions. However, a clear understanding of the role of calpains in the CNS has been hampered by the lack of appropriate deletion paradigms in the brain. In this study, we describe a unique model of conditional deletion of both calpain-1 and calpain-2 activities in mouse brain, which more definitively assesses the role of these ubiquitous proteases in brain development/function and pathology. Surprisingly, we show that these calpains are not critical for gross CNS development. However, calpain-1/calpain-2 loss leads to reduced dendritic branching complexity and spine density deficits associated with major deterioration in hippocampal long-term potentiation and spatial memory. Moreover, calpain-1/calpain-2-deficient neurons were significantly resistant to injury induced by excitotoxic stress or mitochondrial toxicity. Examination of downstream target showed that the conversion of the Cdk5 activator, p35, to pathogenic p25 form, occurred only in the presence of calpain and that it played a major role in calpain-mediated neuronal death. These findings unequivocally establish two central roles of calpain-1/calpain-2 in CNS function in plasticity and neuronal death.

Progressive dopaminergic cell loss with unilateral-to-bilateral progression in a genetic model of Parkinson disease.

DJ-1 mutations cause autosomal recessive early-onset Parkinson disease (PD). We report a model of PD pathology: the DJ1-C57 mouse. A subset of DJ-1-nullizygous mice, when fully backcrossed to a C57BL/6 [corrected] background, display dramatic early-onset unilateral loss of dopaminergic (DA) neurons in their substantia nigra pars compacta, progressing to bilateral degeneration of the nigrostriatal axis with aging. In addition, these mice exhibit age-dependent bilateral degeneration at the locus ceruleus nucleus and display mild motor behavior deficits at aged time points. These findings effectively recapitulate the early stages of PD. Therefore, the DJ1-C57 mouse provides a tool to study the preclinical aspects of neurodegeneration. Importantly, by exome sequencing, we identify candidate modifying genes that segregate with the phenotype, providing potentially critical clues into how certain genes may influence the penetrance of DJ-1-related degeneration in mice.

Calcium-sensitive adenylyl cyclases in depression and anxiety: behavioral and biochemical consequences of isoform targeting.

BACKGROUND: Adenylyl cyclases (ACs) represent a diverse family of enzymes responsible for the generation of cyclic adenosine monophosphate (cAMP), a key intracellular second messenger. The Ca(2+)/calmodulin-stimulated AC1 and AC8 isoforms as well as the calcium-inhibited AC5 isoform are abundantly expressed within limbic regions of the central nervous system. This study examines the contribution of these AC isoforms to emotional behavior. METHODS: Male and female AC1/8 double knockout mice (DKO) and AC5 knockout mice (AC5KO) were examined on a series of standard laboratory assays of emotionality. Mice were also assayed for hippocampal cell proliferation and for changes in brain-derived neurotrophic factor signaling in the nucleus accumbens, amygdala, and hippocampus, three forebrain structures involved in the regulation of mood and affect. RESULTS: The AC5KO mice showed striking anxiolytic and antidepressant phenotypes on standard behavioral assays. In contrast, AC1/8 DKO mice were hypoactive, exhibited diminished sucrose preference, and displayed alterations in neurotrophic signaling, generally consistent with a prodepressant phenotype. Neither line of mice displayed alterations in hippocampal cell proliferation. CONCLUSIONS: These data illustrate the complex manner in which Ca(2+)/calmodulin-stimulated ACs contribute to emotional behavior. In addition, they support the possibility that a selective AC5 antagonist would be of therapeutic value against depression and anxiety disorders.

Dynamic contribution of nestin-expressing stem cells to adult neurogenesis.

Understanding the fate of adult-generated neurons and the mechanisms that influence them requires consistent labeling and tracking of large numbers of stem cells. We generated a nestin-CreER(T2)/R26R-yellow fluorescent protein (YFP) mouse to inducibly label nestin-expressing stem cells and their progeny in the adult subventricular zone (SVZ) and subgranular zone (SGZ). Several findings show that the estrogen ligand tamoxifen (TAM) specifically induced recombination in stem cells and their progeny in nestin-CreER(T2)/R26R-YFP mice: 97% of SGZ stem-like cells (GFAP/Sox2 with radial glial morphology) expressed YFP; YFP+ neurospheres could be generated in vitro after recombination in vivo, and maturing YFP+ progeny were increasingly evident in the olfactory bulb (OB) and dentate gyrus (DG) granule cell layer. Revealing an unexpected regional dissimilarity in adult neurogenesis, YFP+ cells accumulated up to 100 d after TAM in the OB, but in the SGZ, YFP+ cells reached a plateau 30 d after TAM. In addition, most SVZ and SGZ YFP+ cells became neurons, underscoring a link between nestin and neuronal fate. Finally, quantification of YFP+ cells in nestin-CreER(T2)/R26R-YFP mice allowed us to estimate, for example, that stem cells and their progeny contribute to no more than 1% of the adult DG granule cell layer. In addition to revealing the dynamic contribution of nestin-expressing stem cells to adult neurogenesis, this work highlights the utility of the nestin-CreER(T2)/R26R-YFP mouse for inducible gene ablation in stem cells and their progeny in vivo in the two major regions of adult neurogenesis.

Gender and endogenous levels of estradiol do not influence adult hippocampal neurogenesis in mice.

In several species, including rat and vole, the proliferation of new neurons in the adult dentate gyrus (DG) subgranular zone (SGZ) is influenced by both gender and endogenous levels of the gonadotropic steroid hormone estradiol. However, little is known about how adult neurogenesis is regulated by these factors in the mouse. We report here that adult C57BL/6 mice do not have gender differences in hippocampal proliferation or neurogenesis. In addition, the production of new SGZ cells in female mice was not influenced by estrous cycle or after ovariectomy, suggesting that fluctuations in endogenous estradiol levels do not alter adult neurogenesis in the mouse. Both male and female mice had a greater number of BrdU-immunoreactive SGZ cells following chronic treatment with fluoxetine. This demonstrates a parallel proliferation response in both genders, and opens avenues for addressing the neurogenesis hypothesis of depression in female rodents. These findings underscore a distinct regulation of adult neurogenesis in mice vs. other rodents, and are discussed in regard to their implications for the study of adult hippocampal neurogenesis.

Mood-stabilizing drugs: are their neuroprotective aspects clinically relevant?

The possibility that there may be subtypes of bipolar disorder and the slow progress in understanding the therapeutic mechanism for approved mood-stabilizing drugs make the challenges of intelligent drug design seem daunting. Nonetheless, the numerous shortcomings in current pharmaco-therapy underscore the need to develop novel therapies. There are significant problems with currently approved mood-stabilizing drugs: 1. Up to 40% of patients fail to respond to monotherapy with either lithium or valproic acid. 2. Common use of polypharmacotherapy increases the side effects associated with treatment. 3. Treatment must continue for weeks to months for therapeutic effects to be greater than placebo. 4. Up to 60% of patients will discontinue therapy, which is somewhat attributable to unwanted side effects. Thus, it is critical that new medications without these problems be developed for bipolar disorder. The hypothesis that mood-stabilizing drugs are neuroprotective is an important first step in new drug development. To determine if the clinical efficacy of mood-stabilizing drugs is dependent on the neuroprotective or neurogenic properties of these medications, greater strides need to be made in relating findings from cell culture and animal models to human imaging and pathology. Mounting evidence supports the neuroprotective and neurogenic properties of lithium and valproic acid ina variety of cell-culture models. It is important for clinical, biochemical, and in vitro differences between these medications to be examined, not ignored,because these differences may reveal critical distinctions between the neural mechanisms of these drugs. Continuation of the in vitro work will aid in the understanding of the mechanism by which these drugs are neuroprotective,but such studies do not advance the understanding of whether these effects are critical for the clinical efficacy of these medications. In attempting to understand the in vivo effects of these medications, a variety of evidence supports the neuroprotective and neurogenic aspects of lithium and valproic acid in healthy rodents and animal models of gross brain insult. More work needs to be done to assess whether these effects occur in animal models for bipolar disorder. The proof of principle for supporting the claim that the neuroprotective or neurogenic properties are important clinically will come from longitudinal clinical studies that compare brain morphology and function before and during treatment. If enough evidence supports the hypothesis that the neuroprotective and neurogenic properties of mood-stabilizing drugs are important for their clinical efficacy, new medications that are more efficacious and have fewer side effects will be designed based on this discovery.

Valproic acid fails to induce polycystic ovary syndrome in female rats.

PURPOSE: Valproic acid (VPA) treatment in female patients is suggested to be associated with the occurrence of a variety of endocrine side effects that include many characteristic symptoms of polycystic ovary syndrome (PCOS). The aim of our study was to prospectively measure whether VPA treatment was associated with the presentation of PCOS symptoms in rats, as well as determine whether this model could be used to examine the underlying mechanism by which these effects are induced. METHODS: Normal estrus-cycling female rats (n=22) were treated perorally three times daily with VPA (300 mg/kg/day), divalproex sodium (DVS) (330 mg/kg/day), or phosphate-buffered saline for a minimum of 30 days. PCOS-associated symptoms (estrus cycle, weight, estradiol and testosterone levels, aromatase activity, and ovarian morphology) were assessed at baseline, mid-, and endpoint. RESULTS: There was no significant difference in the mean number of days animals were in proestrus-estrus or metestrus-diestrus between the three groups. All groups of animals gained weight during the study and there were no appreciable differences in mean weight gain or leptin between groups. Total serum estradiol or testosterone levels and ovarian aromatase activity were not significantly different between the groups. The number of corpora lutea was not significantly different between the groups; however, cystic follicles were present in 50% of the drug-treated animals compared to 25% of saline-treated animals. CONCLUSIONS: VPA and DVS treatment were associated with a higher proportion of animals developing cystic follicles but did not mimic the VPA-induced PCOS that is observed in women. Thus, it appears that the rat has limited usefulness for modeling VPA-induced symptoms associated with PCOS.