Embryonic gene expression and pro-protein processing of proSAAS during rodent development

In vitro assays have demonstrated that peptides derived from the recently-identified proSAAS precursor inhibit prohormone convertase 1 (PC1) suggesting that this novel peptide may function as an endogenous inhibitor of PC1. To further understand the role of proSAAS in vivo, we have investigated the expression of proSAAS mRNA and processing of proSAAS during pre- and early postnatal rodent development. In situ hybridization showed that, by embryonic day 12.5 (e12.5) in the rat, proSAAS mRNA was present in essentially all differentiating neurons in the mantle layer of the myelencephalon, metencephalon, diencephalon, spinal cord and several sympathetic ganglia. During later stages of prenatal development, widespread proSAAS expression continues in post-mitotic neurons of both the CNS and PNS and begins in endocrine cells of the anterior and intermediate pituitary. Although proSAAS expression overlaps with PC1 in several regions, its overall expression pattern is significantly more extensive, suggesting that proSAAS may be multifunctional during development. Processed forms of proSAAS are present by at least mid-gestation with marked accumulation of two C-terminal forms, comprising the PC1 inhibitory fragment of proSAAS.     

Regulated expression of proenkephalin A during ontogenic development of mesenchymal derivative tissues.

Proenkephalin A (PEA), a neuropeptide-encoding gene, is widely expressed in the nervous and endocrine systems. Recently, we demonstrated that in addition to its abundance in fetal brain tissue; PEA is markedly expressed in nondifferentiated mesodermal cells of developing fetuses. To evaluate the implication of these findings for the normal development of tissues of mesodermal origin, we examined the expression of PEA in rat mesenchymal tissues during pre- and postnatal development. Using in situ hybridization analysis combined with RNA blots and a Met-enkephalin-specific radioimmunoassay, we showed that (i) PEA mRNA levels in embryonic and newborn mesenchymal derivative tissues were as high as in the developing brain, (ii) PEA mRNA concentrations in these tissues dropped to undetectable levels shortly after birth, and (iii) this mRNA was translated and processed differentially among different mesenchymal tissues, yielding a tissue-specific pattern of PEA-derived peptides. Our results demonstrate multilevel regulation of PEA gene expression during ontogenic development of mesenchymal derivative tissues. The transient expression and the correlation between PEA mRNA and tissue maturation support the notion that peptides encoded by PEA play a significant role in normal development of these tissues. These findings provide a framework for examination of the mechanisms and roles of PEA gene expression during mesenchymal ontogeny.     

Tachykinin Systems in the Spinal Cord and Basal Ganglia: Influence of Neonatal Capsaicin Treatment or Dopaminergic Intervention on Levels of Peptides, Substance P–Encoding mRNAs, and Substance P Receptor mRNA

The aim of the study was to test whether the synthesis of substance P (SP) and that of its receptor (also known as NK1 receptor) are coordinately regulated after chronic pharmacologic intervention in two neural systems, the spinal cord and basal ganglia. In one set of experiments, capsaicin was administered subcutaneously during the early postnatal period (day 3 after birth) to induce degeneration of afferent sensory neurons in the spinal cord. In the other set of experiments, interruption of dopaminergic transmission was achieved by two methods: (a) The neurotoxin 6-hydroxydopamine was used to denervate dopaminergic neurons during the early postnatal period, and (b) haloperidol was used in adult animals to block dopaminergic transmission by receptor blockade. The spinal cord, striatum, or both were used for the quantification of tachykinin [SP and neurokinin A (NKA)] and opioid peptides [[Met5]-enkephalin (ME) and dynorphin A (1-8) (DYN)] by radioimmunoassays. The abundance of total SP-encoding preprotachykinin (PPT) mRNA and SP receptor (SPR) mRNA in spinal cord (C5 to T1 segments), striatum, or microdissected substantia nigra was determined by northern blot or solution hybridization analysis. Amines and their acid metabolites were quantified by HPLC. Capsaicin administration (subcutaneously) during the early postnatal period increased latency in a hot-plate test, decreased SP and NKA levels, increased levels of PPT mRNAs, and did not affect SPR mRNA levels in the spinal cord. Intraspinal SP systems may attempt to compensate for the loss of afferent SP input, whereas spinal cord receptor mRNA levels do not appear to be altered.(ABSTRACT TRUNCATED AT 250 WORDS)     

The neuropeptide-degrading enzyme NL1 is expressed in specific neurons of mouse brain

Metalloendopeptidases of the M13 family were shown to play critical roles in normal physiological processes such as pain control, hypertension and phosphate metabolism, and in pathological states such as Alzheimer's disease. Recently, NL1, a novel member of the family, has been identified and shown to be expressed in several tissues both as a membrane-bound and a secreted protein. As a further step to understand the physiological role(s) of NL1 in mouse, we mapped NL1 mRNA expression pattern in embryos and in young animals at postnatal days p1 and p3, and in adult nervous tissue, using in situ hybridization at the cellular level. No expression could be detected in embryos and young animals. In contrast, NL1 expression was evident in adult brain, pituitary gland and spinal cord. In the central nervous system (CNS), NL1 mRNA was predominantly found in the ventro-posterior regions, which are mostly associated with vegetative functions. At the cellular level, NL1 mRNA was non-uniformly distributed within subpopulations of neurons. In the spinal cord, specific signal was observed in the gray matter. Then, in order to identify putative relevant substrates for NL1, we studied its enzymatic activity towards peptides known to be co-expressed in the NL1-positive domains. Our study showed that NL1 degrades several of these peptides in vitro, the most readily degraded peptides being Bradykinin and Substance P. These results suggest that NL1 is likely to play a critical role in the central nervous system.     

Transient expression of Bis protein in midline radial glia in developing rat brainstem and spinal cord

Bis (Bcl-2 interacting death suppressor) has been reported to contribute to the differentiation and maturation of specific neuronal populations in the developing rat forebrain, in addition to its well-established functions as a stress or survival-related protein. In the present study, we have analyzed the expression of Bis in the rat brainstem and cervical spinal cord during development by using immunohistochemistry. Bis immunoreactivity was detected in radial glial cells flanking the midline from embryonic day 14. During embryonic and early postnatal development, Bis expression persisted in differentiating radial glia at the midline but disappeared first in the spinal cord by postnatal day 7 (P7) and later also in the brainstem by P14. Bis expression was restricted to a subpopulation of the midline radial glia, i.e., the dorsal midline of the midbrain and spinal cord and the ventral midline of the hindbrain, which were double- or triple-labeled with vimentin and nestin, markers for radial glia, and S100B. However, these markers also labeled all radial glia including the ventral midline glia in the midbrain and spinal cord, with Bis being absent from these structures. In addition, the dorsal midline glia in the midbrain and spinal cord expressed Bis prior to the timing of expression for radial glial markers. Therefore, our results demonstrate the early and transient expression of Bis in the subpopulation of midline glia in the developing brainstem and spinal cord, suggesting that Bis has a unique role in association with the radial glial cells in the developing central nervous system. This research was supported by a grant (10029970) from the Ministry of Knowledge Economy, The Republic of Korea and by a grant (M103KV010010-08 K2201-01010) from Brain Research Center of the 21st Century Frontier Research Program funded by the Ministry of Science and Technology, The Republic of Korea.     

Expression of endothelial nitric oxide synthase in the postnatal developing porcine kidney

The postnatal pattern of renal endothelial nitric oxide synthase (eNOS) is unknown. The purpose of this study was to characterize eNOS expression during maturation and compare this to neuronal NOS (nNOS). The experiments measured whole kidney eNOS mRNA expression by RT-PCR and protein content by Western blot, as well as cortical and medullary protein content in piglets at selected postnatal ages and in adult pigs. Whole kidney eNOS mRNA was compared with nNOS. Whole kidney eNOS expression decreased from the newborn to its lowest at 7 days, returning by 14 days to adult levels. This eNOS mRNA pattern contrasted with nNOS, which was highest at birth, and progressively decreased to its lowest level in the adult. At birth, cortical eNOS protein was greater than medullary, contrasting with the adult pattern of equivalent levels. In conclusion eNOS is developmentally regulated during early renal maturation and may critically participate in renal function during this period. The eNOS developmental pattern differs from nNOS, suggesting that these isoforms may have different regulatory factors and functional contributions in the postnatal kidney.     

Developmental expression of the myelin gene MOBP in the rat nervous system

The myelin-associated/oligodendrocyte basic proteins (MOBPs) are recently discovered constituents of myelin and are small, cytoplasmic, and highly basic proteins exclusively expressed postnatally by oligodendrocytes. Due to a clustering of positively charged amino acids observed in the most abundant MOBP isoform similar to myelin basic protein (MBP) and P0, it was speculated that MOBP could function in myelin sheath compaction. The present report strongly supports this view. A direct comparison of MBP and proteolipid protein (PLP) gene expression with that of MOBP by in situ hybridization revealed a very similar regional distribution. It was found that MOBP expression was abundant in the rat CNS at postnatal day 15 (P 15) but is restricted to densely myelinated regions. In contrast to MBP and PLP, expression of MOBP was undetectable in the peripheral nervous system during the entire development. Interestingly, MOBP mRNA was localized in oligodendrocyte processes even at early postnatal stages and throughout development. MOBP showed a very specific timing of expression: in spinal cord and brain, MOBP gene expression occurred significantly later (2–3 days) than that of MBP and PLP, but slightly earlier than myelin oligodendrocyte glycoprotein gene expression. MOBP proteins appeared in spinal cord and brain stem also after MBP protein, suggesting that the MOBPs functionally act after the structural myelin proteins MBP and PLP. Our findings imply a function of MOBP during the late steps of myelin formation, presumably at the initiation of sheath compaction.     

P2X2 and P2X3 receptor expression in postnatal and adult rat urinary bladder and lumbosacral spinal cord

P2X receptors mediate the effects of ATP in micturition and nociception. During postnatal maturation, a spinobulbospinal reflex and voluntary voiding replace primitive voiding reflexes. This may involve changes in neuroactive compounds and receptors in bladder reflex pathways. We examined P2X2 and P2X3 receptors in bladder and spinal cord from postnatal (P0-P36, indicating number of days) and adult Wistar rats. Western blot of whole bladders for P2X2 and P2X3 expression was performed. Immunostaining for P2X2 and P2X3 receptors in urothelium and detrusor smooth muscle whole mounts and spinal cord sections was examined. Western blot demonstrated an age-dependent decrease (R(2) = 0.96, P 相似文献   

Modulation of cardiac ischemia-sensitive afferent neuron signaling by preemptive C2 spinal cord stimulation: effect on substance P release from rat spinal cord

The upper cervical spinal region functions as an intraspinal controller of thoracic spinal reflexes and contributes to neuronal regulation of the ischemic myocardium. Our objective was to determine whether stimulation of the C2 cervical spinal cord (SCS) of rats modified the input signal at the thoracic spinal cord when cardiac ischemia-sensitive (sympathetic) afferents were activated by transient occlusion of the left anterior descending coronary artery (CoAO). Changes in c-Fos expression were used as an index of neuronal activation within the spinal cord and brain stem. The pattern of substance P (SP) release, a putative nociceptive transmitter, was measured using antibody-coated microprobes. Two SCS protocols were used: reactive SCS, applied concurrently with intermittent CoAO and preemptive, sustained SCS starting 15 min before and continuing during the repeated intermittent CoAO. CoAO increased SP release from laminae I and II in the T4 spinal cord above resting levels. Intermittent SCS with CoAO resulted in greater levels of SP release from deeper laminae IV-VII in T4 than CoAO alone. In contrast, SP release from laminae I and II was inhibited when CoAO was applied during preemptive, sustained SCS. Preemptive SCS likewise reduced c-Fos expression in the T4 spinal cord (laminae I-V) and nucleus tractus solitarius but increased expression in the intermediolateral cell column of T4 compared with CoAO alone. These results suggest that preemptive SCS from the high cervical region modulates sensory afferent signaling from the ischemic myocardium.     

Rig-1 a new member of Robo family genes exhibits distinct pattern of expression during mouse development

The Robo genes encode a family of proteins that are the receptors for the midline repellent Slits and play a role in axon guidance. In addition to Robo1 and Robo2, Rig-1 has been recently identified in mouse as a novel member of the Robo family of proteins. As a first step in elucidating the role of Rig-1 during vertebrate development, we characterised the expression of Rig-1 by in situ hybridisation together with Robo1 and Robo2 in the spinal cord and other tissues of the mouse embryo. Our results show that Rig-1 has a dynamic pattern of expression in the developing CNS. In the spinal cord Rig-1 shows overlapping but distinct pattern of expression with Robo1 and Robo2.     

Activity-induced and developmental downregulation of the Nogo receptor

The three axon growth inhibitory proteins, myelin associated glycoprotein, oligodendrocyte-myelin glycoprotein and Nogo-A, can all bind to the Nogo-66 receptor (NgR). This receptor is expressed by neurons with high amounts in regions of high plasticity where Nogo expression is also high. We hypothesized that simultaneous presence of high levels of Nogo and its receptor in neurons confers a locked state to hippocampal and cortical microcircuitry and that one or both of these proteins must be effectively and temporarily downregulated to permit plastic structural changes underlying formation of long-term memory. Hence, we subjected rats to kainic acid treatment and exposed rats to running wheels and measured NgR mRNA levels by quantitative in situ hybridization at different time points. We also studied spinal cord injuries and quantified NgR mRNA levels in spinal cord and ganglia during a critical postnatal period using real-time PCR. Strikingly, kainic acid led to a strong transient downregulation of NgR mRNA levels in gyrus dentatus, hippocampus, and neocortex during a time when BDNF mRNA was upregulated instead. Animals exposed to running wheels for 3 and 7, but not 1 or 21, days showed a significant downregulation of NgR mRNA in cortex, hippocampus and the dentate gyrus. NgR mRNA levels decreased from high to low expression in spinal cord and ganglia during the first week of life. No robust regulation of NgR was observed in the spinal cord following spinal cord injury. Together, our data show that NgR levels in developing and adult neurons are regulated in vivo under different conditions. Strong, rapid and transient downregulation of NgR mRNA in response to kainic acid and after wheel running in cortex and hippocampus suggests a role for NgR and Nogo-A in plasticity, learning and memory.     

Spatiotemporal Patterns of SSeCKS Expression After Rat Spinal Cord Injury

Src suppressed C kinase substrate (SSeCKS) was identified as a PKC substrate/PKC-binding protein, which plays a role in mitogenic regulatory activity and has a function in the control of cell signaling and cytoskeletal arrangement. However its distribution and function in the central nervous system (CNS) lesion remain unclear. In this study, we mainly investigated the mRNA and protein expression and cellular localization of SSeCKS during spinal cord injury (SCI). Real-time PCR and Western blot analysis revealed that SSeCKS was present in normal whole spinal cord. It gradually increased, reached a peak at 3 days for its mRNA level and 5 days for its protein level after SCI, and then declined during the following days. In ventral horn, the expression of SSeCKS underwent a temporal pattern that was similar with the whole spinal cord in both mRNA and protein level. However, in dorsal horn, the mRNA and protein for SSeCKS expression were significantly increased at 1 day for its mRNA level and 3 days for its protein level, and then gradually declined to the baseline level, ultimately up-regulated again from 7 to 14 days. The protein expression of SSeCKS was further analysed by immunohistochemistry. The positively stained areas for SSeCKS changed with the similar pattern to that of protein expression detected by immunoblotting analysis. Double immunofluorescence staining showed that SSeCKS immunoreactivity (IR) was found in neurons, astrocytes, oligodendrocytes of spinal cord tissues within 5 mm from the lesion site. Importantly, injury-induced expression of SSeCKS was co-labeled by active caspase-3 (apoptotic marker), Tau-1 (the marker for pathological oligodendrocyte) and β-1,4-galactosyltransferase 1 (GalT). All the results suggested that SSeCKS might play important roles in spinal cord pathophysiology and further research is needed to have a good understanding of its function and mechanism. Feng Xiao and Min Fei contributed equally to this work.     

Developmental regulation of PSD-95 and nNOS expression in lumbar spinal cord of rats

Postsynaptic density (PSD)-95 is originally isolated from glutamatergic synapse where it serves as a physical tether to allow neuronal nitric oxide synthase (nNOS) signaling by N-methyl-D-aspartate receptor (NMDAR) activity. Considering the physiological importance of glutamate receptor and nitric oxide (NO) during development, we examined the spatiotemporal expression of PSD-95 and nNOS in the lumbar spinal cord at a postnatal stage. Temporally, both gene and protein levels of them gradually increased with age after birth, peaked at the postnatal day 14 (P14), and then decreased to an adult level. In addition, the enhanced coimmunoprecipitations between PSD-95 and nNOS were detected in developing spinal cord. Spatially, PSD-95 staining codistributed with nNOS in NeuN-positive motor neurons and sensory neurons at P14. These findings indicate that PSD-95 and nNOS might collectively participate in spinal cord development.     

Effects on neurite outgrowth and cell survival of a secreted fibroblast growth factor binding protein upregulated during spinal cord injury

The fibroblast growth factor binding protein (FGF-BP; GenBank accession no. NP_005121) is a secreted protein that mobilizes FGFs from the extracellular matrix, protects them from degradation, and enhances their biological activity. Several previous studies reported that FGF-BP is an early response gene upregulated during tissue repair processes including wound healing and atherogenesis. In this study we analyzed whether FGF-BP expression was impacted by spinal cord injury and could have an effect on neuronal cell viability. Immunohistochemical and in situ hybridization studies revealed a dramatic upregulation of FGF-BP protein and mRNA levels following unilateral hemisection and contusion injury of adult rat spinal cord. In spinal cord sections of laminectomized rats, increased FGF-BP expression was observed in the fibers and cell bodies ipsilateral to the lesion site but was absent in the uninjured spinal cord tissue contralateral to the lesion. Increased expression of FGF-BP was observed at all postinjury time points, examined with peak levels occurring at day 4, a time when injury-induced increased levels of FGF2 have also been reported to be maximal. Moreover, using PC12 cells as a neuronal model, we observed that exogenous FGF-BP increased the capacity of FGF2 to stimulate neurite outgrowth and to increase cell survival. At the molecular level, FGF-BP enhanced FGF2-induced protein tyrosine phosphorylation and AKT/PKB activation. Collectively, these results suggest that FGF-BP is an early response gene after spinal cord injury and that its upregulation in regenerating spinal cord tissue may provide a molecular mechanism for enhancing the initial FGF2-mediated neurotrophic effects occurring after such tissue damage.     

Altered chemokine expression in the spinal cord and brain contributes to differential interleukin-1beta-induced neutrophil recruitment

The pattern of neutrophil recruitment that accompanies inflammation in the CNS depends on the site of injury and the stage of development. The adult brain parenchyma is refractory to neutrophil recruitment and associated damage as compared to the spinal cord or juvenile brain. Using quantitative Taqman RT-PCR and enzyme-liked immunosorbent assay (ELISA), we compared mRNA and protein expression of the rat neutrophil chemoattractant chemokines (CINC) in spinal cord and brain of adult and juvenile rats to identify possible association with the observed differences in neutrophil recruitment. Interleukin-1beta (IL-1beta) injection resulted in up-regulated chemokine expression in both brain and spinal cord. CINC-3 mRNA was elevated above CINC-1 and CINC-2alpha, with expression levels for each higher in spinal cord than in brain. By ELISA, IL-1beta induced greater CINC-1 and CINC-2alpha expression compared to CINC-3, with higher protein levels in spinal cord than in brain. In the juvenile brain, significantly higher levels of CINC-2alpha protein were observed in response to IL-1beta injection than in the adult brain following an equivalent challenge. Correspondingly, neutrophil recruitment was observed in the juvenile brain and adult spinal cord, but not in the adult brain. No expression of CINC-2beta mRNA was detected. Thus differential chemokine induction may contribute to variations in neutrophil recruitment in during development and between the different CNS compartments.