Endoplasmic reticulum (ER) stress is caused by disturbances in the structure and function of the ER with the accumulation of misfolded proteins and alterations in the calcium homeostasis. The ER response is characterized by changes in specific proteins, causing translational attenuation, induction of ER chaperones and degradation of misfolded proteins.
Locomotion in mammals relies on a central pattern-generating circuitry of spinal interneurons established during development that coordinates limb movement1. These networks produce left–right alternation of limbs as well as coordinated activation of flexor and extensor muscles2. Here we show that a premature stop codon in the DMRT3 gene has a major effect on the pattern of locomotion in horses. The mutation is permissive for the ability to perform alternate gaits and has a favourable effect on harness racing performance. Examination of wild-type and Dmrt3-null mice demonstrates that Dmrt3 is expressed in the dI6 subdivision of spinal cord neurons, takes part in neuronal specification within this subdivision, and is critical for the normal development of a coordinated locomotor network controlling limb movements. Our discovery positions Dmrt3 in a pivotal role for configuring the spinal circuits controlling stride in vertebrates. The DMRT3 mutation has had a major effect on the diversification of the domestic horse, as the altered gait characteristics of a number of breeds apparently require this mutation.
Mast cells are found in tissues throughout the body where they play important roles in the regulation of inflammatory responses. One characteristic feature of mast cells is their longevity. Although it is well established that mast cell survival is dependent on stem cell factor (SCF), it has not been described how this process is regulated. Herein, we report that SCF promotes mast cell survival through inactivation of the Forkhead transcription factor FOXO3a (forkhead box, class O3A) and down-regulation and phosphorylation of its target Bim (Bcl- 2 IntroductionMast cells are long-lived multifunctional effector cells of the immune system originating from the hematopoietic CD34 ϩ stem cells found in the bone marrow. 1 From the bone marrow, mast cell precursors enter the circulation where they are recruited into peripheral tissues to mature and express their final phenotype under the influence of stem cell factor (SCF) and other locally produced cytokines. 2 Although best known for their role in allergic reactions, mast cells are now also recognized as cells of importance in both innate immunity and in the onset and severity of chronic inflammations. 3,4 The versatile effector mechanisms mast cells have been endowed with can be deduced from their capability to release a wide variety of inflammatory mediators such as histamine, proteases, and cytokines that are preformed and stored in granules and prostaglandins, leukotrienes, and cytokines that are secreted upon activation. 5 The number of tissue mast cells is normally relatively constant, but during an acute or chronic inflammation the number can increase substantially. 6 The regulation of mast cell numbers is most likely regulated by proliferation, migration, and apoptosis or survival. The mechanisms that regulate the viability of mature mast cells or promote mast cell apoptosis are poorly investigated. SCF is a cardinal growth factor in mast cell biology, regulating mast cell growth, differentiation, adhesion, migration, and survival. 7 The number of tissue mast cells is at least in part regulated by SCF produced by resident stromal cells. SCF rescues mast cells from spontaneous apoptosis in vitro, whereas inhibition of SCF synthesis in vivo leads to mast cell apoptosis. [8][9][10] Although it is accepted that SCF is a prosurvival factor for mast cells, it remains largely unclear how SCF promotes survival in these cells.The B-cell lymphoma-2 (Bcl-2) family, which contains both prosurvival and proapoptotic proteins, are essential regulators of cell survival and apoptosis. 11 The levels and interactions of prosurvival versus proapoptotic Bcl-2 family proteins determine whether a cell survives or will undergo apoptosis. During apoptosis induced by proapoptotic Bcl-2 family members, cytochrome c is released from the mitochondria and a caspase cascade is activated that induces DNA fragmentation. 12,13 The prosurvival Bcl-2 family members include Bcl-2, Bcl-X L , Bcl-w, Mcl-1 (myeloid cell For personal use only. on May 12, 2018. by guest www.bloodjournal.org From leuk...
Alterations in the motor neuron–renshaw cell circuit in the Sod1G93A mouse model
Motor neurons become hyperexcitable during progression of amyotrophic lateral sclerosis (ALS). This abnormal firing behavior has been explained by changes in their membrane properties, but more recently it has been suggested that changes in premotor circuits may also contribute to this abnormal activity. The specific circuits that may be altered during development of ALS have not been investigated. Here we examined the Renshaw cell recurrent circuit that exerts inhibitory feedback control on motor neuron firing. Using two markers for Renshaw cells (calbindin and Chrna2 , cholinergic nicotinic receptor subunit alpha2), two general markers for motor neurons (NeuN and VAChT, vesicular acethylcholine transporter ) and two markers for fast motor neurons (Chondrolectin and Calca, calcitonin-related polypeptide alpha), we analyzed the survival and connectivity of these cells during disease progression in the Sod1G93A mouse model. Most calbindin-immunoreactive (IR) Renshaw cells survive to end-stage but downregulate postsynaptic Chrna2 in presymptomatic animals. In motor neurons, some markers are downregulated early (NeuN, VAChT, Chondrolectin) and others at end-stage(Calca). Early downregulation of presynaptic VAChT and Chrna2 was correlated with disconnection from Renshaw cells as well as major structural abnormalities of motor axon synapses inside the spinal cord. Renshaw cell synapses on motor neurons underwent more complex changes, including transitional sprouting preferentially over remaining NeuN-IR motor neurons. We conclude that the loss of presynaptic motor axon input on Renshaw cells occurs at early stages of ALS and disconnects the recurrent inhibitory circuit, presumably resulting in a diminished control of motor neuron firing.
We have investigated the signaling of OX 1 receptors to cell death using Chinese hamster ovary cells as a model system. OX 1 receptor stimulation with orexin-A caused a delayed cell death independently of cytosolic Ca 2؉ elevation. The classical mitogen-activated protein kinase (MAPK) pathways, ERK and p38, were strongly activated by orexin-A. p38 was essential for induction of cell death, whereas the ERK pathway appeared protective. A pathway often implicated in the p38-mediated cell death, activation of p53, did not mediate the cell death, as there was no stabilization of p53 or increase in p53-dependent transcriptional activity, and dominantnegative p53 constructs did not inhibit cell demise. Under basal conditions, orexin-A-induced cell death was associated with compact chromatin condensation and it required de novo gene transcription and protein synthesis, the classical hallmarks of programmed (apoptotic) cell death. However, though the pan-caspase inhibitor N-benzyloxycarbonyl-Val-Ala-Asp-(O-methyl)fluoromethyl ketone (Z-VAD-fmk) fully inhibited the caspase activity, it did not rescue the cells from orexin-A-induced death. In the presence of Z-VAD-fmk, orexin-A-induced cell death was still dependent on p38 and de novo protein synthesis, but it no longer required gene transcription. Thus, caspase inhibition causes activation of alternative, gene transcription-independent death pathway. In summary, the present study points out mechanisms for orexin receptor-mediated cell death and adds to our general understanding of the role of G-protein-coupled receptor signaling in cell death by suggesting a pathway from G-protein-coupled receptors to cell death via p38 mitogen-/stress-activated protein kinase independent of p53 and caspase activation.There is a growing interest in the ability of G-protein-coupled receptors (GPCRs) 2 to affect synaptic plasticity and cell differentiation as well as cell growth, death, and survival (reviewed in Refs. 1-3). However, the mechanisms of GPCR signaling in these processes are poorly characterized. The pathways engaged seem to include classical GPCR signals like second messenger-dependent activation of protein kinase A and C but also (for GPCRs) more novel signal transducers like small G-proteins (of Ras and Rho families), PI3K (phosphatidylinositol 3-kinase) and nonreceptor tyrosine kinases (e.g. Src).In this study we have focused on the signaling of a novel GPCR, OX 1 orexin receptor. Little is known about the intracellular signaling of OX 1 receptor and its cognate receptor, OX 2 receptor. Orexin receptor-expressing neuronal, endocrine, and muscle cells often seem to be excited by orexins, an effect that may be related to activation of Ca 2ϩ or nonselective cation channels (reviewed in Refs. 4 and 5). Recently, orexin receptors have been suggested to regulate cell plasticity. ERK (extracellular signal-regulated kinase) is strongly activated in CHO cells heterologously expressing OX 1 receptors (4, 6, 7). In the hippocampus, orexin receptors regulate synaptic plasticity (8). Lo...
During the past decade, three proteins that possess the capability of packaging glutamate into presynaptic vesicles have been identified and characterized. These three vesicular glutamate transporters, VGLUT1–3, are encoded by solute carrier genes Slc17a6–8. VGLUT1 (Slc17a7) and VGLUT2 (Slc17a6) are expressed in glutamatergic neurons, while VGLUT3 (Slc17a8) is expressed in neurons classically defined by their use of another transmitter, such as acetylcholine and serotonin. As glutamate is both a ubiquitous amino acid and the most abundant neurotransmitter in the adult central nervous system, the discovery of the VGLUTs made it possible for the first time to identify and specifically target glutamatergic neurons. By molecular cloning techniques, different VGLUT isoforms have been genetically targeted in mice, creating models with alterations in their glutamatergic signalling. Glutamate signalling is essential for life, and its excitatory function is involved in almost every neuronal circuit. The importance of glutamatergic signalling was very obvious when studying full knockout models of both VGLUT1 and VGLUT2, none of which were compatible with normal life. While VGLUT1 full knockout mice die after weaning, VGLUT2 full knockout mice die immediately after birth. Many neurological diseases have been associated with altered glutamatergic signalling in different brain regions, which is why conditional knockout mice with abolished VGLUT-mediated signalling only in specific circuits may prove helpful in understanding molecular mechanisms behind such pathologies. We review the recent studies in which mouse genetics have been used to characterize the functional role of VGLUT2 in the central nervous system.
Appearance of Cxcl10‐expressing cell clusters is common for traumatic brain injury and neurodegenerative disorders
Traumatic brain injury (TBI) in the mouse results in the rapid appearance of scattered clusters of cells expressing the chemokine Cxcl10 in cortical and subcortical areas. To extend the observation of this unique pattern, we used neuropathological mouse models using quantitative reverse transcriptase-polymerase chain reaction, gene array analysis, in-situ hybridization and flow cytometry. As for TBI, cell clusters of 150-200 mum expressing Cxcl10 characterize the cerebral cortex of mice carrying a transgene encoding the Swedish mutation of amyloid precursor protein, a model of amyloid Alzheimer pathology. The same pattern was found in experimental autoimmune encephalomyelitis in mice modelling multiple sclerosis. In contrast, mice carrying a SOD1(G93A) mutant mimicking amyotrophic lateral sclerosis pathology lacked such cell clusters in the cerebral cortex, whereas clusters appeared in the brainstem and spinal cord. Mice homozygous for a null mutation of the Cxcl10 gene did not show detectable levels of Cxcl10 transcript after TBI, confirming the quantitative reverse transcriptase-polymerase chain reaction and in-situ hybridization signals. Moreover, unbiased microarray expression analysis showed that Cxcl10 was among 112 transcripts in the neocortex upregulated at least threefold in both TBI and ageing TgSwe mice, many of them involved in inflammation. The identity of the Cxcl10(+) cells remains unclear but flow cytometry showed increased numbers of activated microglia/macrophages as well as myeloid dendritic cells in the TBI and experimental autoimmune encephalomyelitis models. It is concluded that the Cxcl10(+) cells appear in the inflamed central nervous system and may represent a novel population of cells that it may be possible to target pharmacologically in a broad range of neurodegenerative conditions.
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