NOC/oFQ contributes to age-dependent impairment of NMDA-induced cerebrovasodilation after brain injury

This study characterized the effects of fluid percussion brain injury (FPI) on N-methyl-D-aspartate (NMDA)-induced vasodilation and determined the role of nociceptin/orphanin FQ (NOC/oFQ) in such changes as a function of age and time postinsult. FPI elevated cerebrospinal fluid (CSF) NOC/oFQ from 70 +/- 3 to 444 +/- 56 pg/ml ( approximately 10(-10) M) within 1 h and to 1,931 +/- 112 pg/ml within 8 h, whereas values returned to control levels within 168 h in the newborn pig. In contrast, FPI elevated CSF NOC/oFQ from 77 +/- 4 to 202 +/- 16 pg/ml within 1 h and values returned to control levels within 8 h in the juvenile pig. Topical NOC/oFQ (10(-10) M) had no effect on pial artery diameter but attenuated NMDA (10(-8), 10(-6) M)-induced dilation (9 +/- 1 and 16 +/- 1 vs. 5 +/- 1 and 10 +/- 1%) in both age groups. In the newborn, NMDA-induced pial artery dilation was reversed to vasoconstriction within 1 h post-FPI and responses remained impaired for 72 h, but such vasoconstriction was attenuated by pretreatment with [F/G]NOC/oFQ(1-13)-NH(2) (10(-6) M, 1 mg/kg iv), an NOC/oFQ antagonist (9 +/- 1 and 16 +/- 1 vs. -7 +/- 1 and -12 +/- 1 vs -2 +/- 1 and -3 +/- 1% for control, FPI, and FPI pretreated with the NOC/oFQ antagonist). In contrast, in the juvenile, NMDA-induced vasodilation was only attenuated within 1 h post-FPI and returned to control within 8 h. Such dilation was also partially restored by the NOC/oFQ antagonist. These data indicate that NOC/oFQ contributes to impaired NMDA pial artery dilation after FPI. These data suggest that the greater NOC/oFQ release in the newborn versus the juvenile may contribute to age-related differences in FPI effects on excitatory amino acid-induced pial dilation.     

Age dependent endothelin contribution to NOC/oFQ induced impairment of NMDA cerebrovasodilation after brain injury

This study was designed to characterize the role of endothelin-1 (ET-1) in nociceptin/orphanin FQ (NOC/oFQ) induced impairment of NMDA cerebrovasodilation after fluid percussion brain injury (FPI) as a function of age in newborn (1-5 days old) and juvenile (3-4 weeks old) pigs equipped with a closed cranial window. Previous studies have observed that NOC/oFQ is released into CSF and contributes to impaired NMDA induced pial artery dilation following FPI to a greater extent in newborn vs juvenile pigs. Topical ET-1 (10(-10) M), a concentration approximating that observed in CSF following FPI in the newborn, increased CSF NOC/oFQ from 67 +/- 4 to 119 +/- 7 pg/ml under non FPI conditions. CSF NOC/oFQ was elevated within 60 min of FPI (70 +/- 3 to 444 +/- 51 pg/ml) but such release was attenuated by the ET-1 antagonist BQ123 in the newborn (66 +/- 3 to 145 +/- 10 pg/ml). CSF ET-1 and NOC/oFQ were not elevated as greatly in the juvenile following FPI and BQ123 correspondingly did not attenuate CSF NOC/oFQ release as much as in the newborn. Under non injury conditions, ET-1 (10(-10) M) coadministered with NMDA attenuated pial dilation to this excitatory amino acid. Following FPI in the newborn, NMDA (10(-8), 10(-6) M) induced pial artery dilation was reversed to vasoconstriction and both NOC/oFQ and ET-1 receptor antagonists partially prevented such alterations (9 +/- 1 and 16 +/- 1, sham control; -7 +/- 1 and -12 +/- 1, FPI; -2 +/- 1 and -3 +/- 1, FPI-NOC/oFQ antagonist; and 2 +/- 1 and 5 +/- 1 %, FPI-ET-1 antagonist). NMDA induced pial dilation was only attenuated following FPI in the juvenile and modestly restored by NOC/oFQ and ET-1 receptor antagonists. These data show that ET-1, in concentrations present in CSF following FPI, contributes to the release of CSF NOC/oFQ following such an insult. The greater release of such ET-1 following FPI in the newborn contributes to the corresponding greater release of NOC/oFQ in the newborn vs the juvenile. Moreover, ET-1 also contributes to the impairment of NMDA cerebrovasodilation after brain injury to a greater extent in newborns vs juveniles. These data suggest that ET-1 contributes to NOC/oFQ induced impairment of NMDA cerebrovasodilation after brain injury in an age dependent manner.     

NOC/oFQ PKC-dependent superoxide generation contributes to hypoxic-ischemic impairment of NMDA cerebrovasodilation

This study determined whether nociceptin/orphanin FQ (NOC/oFQ) generates superoxide anion (O(2)(-)) in a protein kinase C (PKC)-dependent manner and whether such production contributes to hypoxic-ischemic (H-I) impairment of N-methyl-D-aspartate (NMDA)-induced pial artery dilation in newborn pigs equipped with closed cranial windows. Superoxide dismutase (SOD)-inhibitable nitroblue tetrazolium (NBT) reduction was an index of O(2)(-) generation. Under non-H-I conditions, topical NOC/oFQ (10(-10) M, concentration present in cerebrospinal fluid after I or H-I) increased SOD-inhibitable NBT reduction from 1 +/- 1 to 20 +/- 3 pmol/mm(2). PKC inhibitors staurosporine and chelerythrine (10(-7) M) blunted NBT reduction (1 +/- 1 to 7 +/- 2 pmol/mm(2) for chelerythrine), whereas the NOC/oFQ receptor antagonist [F/G]NOC/oFQ (1-13)-NH(2) (10(-6) M) blocked NBT reduction. [F/G]NOC/oFQ(1-13)-NH(2) and staurosporine also blunted the NBT reduction observed after I or H-I. NMDA (10(-8), 10(-6) M)-induced pial artery dilation was reversed to vasoconstriction after H-I. The NOC/oFQ antagonist staurosporine and free radical scavengers partially prevented this impaired dilation (sham: 9 +/- 1 and 16 +/- 1; H-I: -5 and -10 +/- 1; H-I staurosporine pretreated: 3 +/- 1 and 6 +/- 1%). These data show that NOC/oFQ increased O(2)(-) production in a PKC-dependent manner and contributed to this production after insult and that NOC/oFQ contributed to impaired NMDA-induced pial artery dilation after H-I, suggesting, therefore, that PKC-dependent O(2)(-) generation by NOC/oFQ links NOC/oFQ release to impaired NMDA dilation after H-I.     

Differential role of PTK and ERK MAPK in superoxide impairment of K(ATP) and K(Ca) channel cerebrovasodilation

Previously, superoxide (O2 -) has been observed to impair pial artery dilation (PAD) to activators of the ATP-sensitive (KATP) and calcium-sensitive (KCa) K+ channels. This study tested the hypothesis that activation of protein tyrosine kinase (PTK) and the ERK isoform of MAPK by O2 - contribute to impairment of KATP and KCa channel PAD. Exposure of the cerebral cortex to a xanthine oxidase O2 --generating system (OX) blunted PAD to cromakalim, a KATP agonist, but preadministration of genistein, a PTK antagonist, or U-0126, an ERK MAPK inhibitor, almost completely prevented such impairment (11 +/- 1 and 22 +/- 1 vs. 3 +/- 1 and 7 +/- 1 vs. 10 +/- 1 and 16 +/- 2% for cromakalim with 10-8 and 10-6 M PAD during control, OX, and OX + genistein conditions). In contrast, neither genistein nor U-0126 robustly protected PAD to NS-1619, a KCa agonist, after OX exposure (11 +/- 1 and 18 +/- 2 vs. 1 +/- 1 and 2 +/- 1 vs. 4 +/- 1 and 6 +/- 1% for 10-8 and 10-6 M NS-1619 during control, OX, and OX + genistein conditions). These data show that PTK and ERK MAPK activation contribute to O2 --induced KATP and KCa channel PAD impairment and suggest a differential greater role for PTK and ERK MAPK in KATP vs. KCa channel PAD impairment.     

Depression of ventilatory responses after daily, cyclic hypercapnic hypoxia in piglets.

Ventilatory responses (VRs) were measured via a sealed face mask and pneumotachograph in 30 unsedated, mixed-breed miniature piglets at 12.6 +/- 2.3 days of age (day 1) and then repeated after seven daily 24-min exposures to 10% O(2)-6% CO(2) [hypercapnic hypoxia (HH)]. Arterial blood was sampled at baseline, after 10 min of exposure, and after 10 min of recovery. VRs included hypoxia (10% O(2) in N(2)), hypercapnia (6% CO(2) in air), and HH (10% O(2)-6% CO(2)-balance N(2)). Treatment groups (n = 10 each) were exposed to 24 min of HH from day 2 to 8 as sustained HH (24 min of HH and then 24 min of air) or cyclic HH (4 min of HH alternating with 4 min of air). Day 1 and 9 data were compared in treatment and control groups. After cyclic HH, respiratory responses to CO(2) were reduced during hypercapnia and during HH (P < 0.001 vs. control for minute ventilation in both). In both treatment groups, time to peak minute ventilation was delayed in hypoxia (P = 0.02, ANOVA), and response amplitude was increased (P < 0.001 and P = 0.003, sustained and cyclic HH, respectively, vs. control). Respiratory pattern was also altered during the VRs and among treatment groups. Stimulus presentation characteristics exert effects on VRs that are independent of those elicited by daily HH.     

Systemic hemodynamics affecting cardiac output during hypocapnic and hypercapnic hypoxia

Systemic hemodynamic adjustments involved in the control of cardiac output (CO) were examined in chronically instrumented unanesthetized sheep inhaling gas mixtures resulting in hypocapnic hypoxia (H) [arterial pH (pHa) = 7.53, arterial partial pressure of O2 (Pao2) = 30 Torr, arterial partial pressure of CO2 (Paco2) = 29 Torr] or hypercapnic hypoxia (HCH) (pHa = 7.14, Pao2 = 34 Torr, Paco2 = 72 Torr) for 1 h. H (n = 7) and HCH (n = 6) resulted in 26% and 61% increases in CO, respectively, and mean systemic arterial pressure rose to a greater extent during HCH. Both H and HCH resulted in increased blood flow (microsphere method) to the peripheral systemic circulation including the brain, heart, diaphragm, and nonrespiratory skeletal muscle (the latter blood flow increased 120% during H and 380% during HCH). Gastrointestinal and renal blood flow remained unchanged during H and HCH. Transit time of green dye from the pulmonary artery to regional veins in the hindlimb and intestine was 5.0 and 8.2 s, respectively, during base-line conditions and remained unchanged with HCH. During HCH, regional O2 consumption increased 274% for the hindlimb and decreased 39% for the intestine. Total catecholamines rose 250% during H and 3,700% during HCH. During hypocapnic and hypercapnic hypoxia, CO is augmented in part by systemic hemodynamic adjustments that include a redistribution of blood flow and a translocation of blood volume to the fast transit time peripheral systemic circuit. The sympathetic nervous system may play an important role in mediating these systemic hemodynamic adjustments.     

Energy metabolism, stress hormones and neural recovery from cerebral ischemia/hypoxia

All the advancements in the understanding of the molecular and cellular processes leading to the great investments in developing neuroprotection against cerebral ischemic/hypoxic damage cannot obscure the simple fact that exhaustion of energy supplies is still at the basis of this disorder. Much has been investigated and postulated over the years about the quick collapse of energy metabolism that follows oxygen and glucose deprivation in the brain. Anaerobic glycolysis, recognized as a pathway of paramount importance in keeping energy supplies, although, at bare minimum, has also presented a dilemma-a significant increase in lactate production during ischemia/hypoxia (IH). The dogma of lactate as a useless end product of anaerobic glycolysis and its postulated role as a detrimental player in the demise of the ischemic cell has persisted for the past quarter of a century. This persistence is due to, at least in part, the well-documented phenomenon termed "the glucose paradox of cerebral ischemia," the unexplained aggravation of postischemic neuronal damage by preischemic hyperglycemia. Recent studies have questioned the deleterious effect of lactic acid, while others even have offered the possibility that this monocarboxylate serves as an aerobic energy substrate during recovery from IH. Reviewed here are studies published over the past few years along with some key older papers on the topic of energy metabolism and recovery of neural tissue from IH. New insights gained from both in vitro and in vivo studies on energy metabolism of the ischemic/hypoxic brain should improve our understanding of this key metabolic process and the chances of protecting this organ from the consequences of energy deprivation.     

Prevention of kidney ischemia/reperfusion-induced functional injury, MAPK and MAPK kinase activation, and inflammation by remote transient ureteral obstruction.

Protection against ischemic kidney injury is afforded by 24 h of ureteral obstruction (UO) applied 6 or 8 days prior to the ischemia. Uremia or humoral factors are not responsible for the protection, since unilateral UO confers protection on that kidney but not the contralateral kidney. Prior UO results in reduced postischemic outer medullary congestion and leukocyte infiltration. Prior UO results in reduced postischemic phosphorylation of c-Jun N-terminal stress-activated protein kinase 1/2 (JNK1/2), p38, mitogen-activated protein kinase (MAPK) kinase 4 (MKK4), and MKK3/6. Very few cells stain positively for proliferating cell nuclear antigen after obstruction, indicating that subsequent protection against ischemia is not related to proliferation with increased numbers of newly formed daughter cells more resistant to injury. UO increases the expression of heat shock protein (HSP)-25 and HSP-72. The increased HSP-25 expression persists for 6 or 8 days, whereas HSP-72 does not. HSP-25 expression is increased in the proximal tubule cells in the outer stripe of the outer medulla postobstruction, prior to, and 24 h after ischemia. In LLC-PK(1) renal epithelial cells, adenovirus-expressed human HSP-27 confers resistance to chemical anoxia and oxidative stress. Increased HSP-27 expression in LLC-PK(1) cells results in reduced H(2)O(2)-induced phosphorylation of JNK1/2 and p38. In conclusion, prior transient UO renders the kidney resistant to ischemia. This resistance to functional consequences of ischemia is associated with reduced postischemic activation of JNK, p38 MAP kinases, and their upstream MAPK kinases. The persistent increase in HSP-25 that occurs as a result of UO may contribute to the reduction in phosphorylation of MAPKs that have been implicated in adhesion molecule up-regulation and cell death.     

Lamotrigine and phenytoin, but not amiodarone, impair peripheral chemoreceptor responses to hypoxia.

Amiodarone, lamotrigine, and phenytoin, common antiarrhythmic and antiepileptic drugs, inhibit a persistent sodium current in neurons (I(NaP)). Previous results from our laboratory suggested that I(NaP) is critical for functionality of peripheral chemoreceptors. In this study, we determined the effects of therapeutic levels of amiodarone, lamotrigine, and phenytoin on peripheral chemoreceptor and ventilatory responses to hypoxia. Action potentials (APs) of single chemoreceptor afferents were recorded using suction electrodes advanced into the petrosal ganglion of an in vitro rat peripheral chemoreceptor complex. AP frequency (at Po(2) approximately 150 Torr and Po(2) approximately 90 Torr), conduction time, duration, and amplitude were measured before and during perfusion with therapeutic dosages of the drug or vehicle. Hypoxia-induced catecholamine secretion within the carotid body was measured using amperometry. With the use of whole body plethysmography, respiration was measured in unanesthesized rats while breathing room air, 12% O(2), and 5% CO(2), before and after intraperitoneal administration of amiodarone, lamotrigine, phenytoin, or vehicle. Lamotrigine (10 microM) and phenytoin (5 microM), but not amiodarone (5 microM), decreased chemoreceptor AP frequency without affecting other AP parameters or magnitude of catecholamine secretion. Similarly, lamotrigine (5 mg/kg) and phenytoin (10 mg/kg) blunted the hypoxic but not the hypercapnic ventilatory response. In contrast, amiodarone (2.5 mg/kg) did not alter the ventilatory response to hypoxia or hypercapnia. We conclude that lamotrigine and phenytoin at therapeutic levels impair peripheral chemoreceptor function and ventilatory response to acute hypoxia. These are consistent with I(NaP) serving an important function in AP generation and may be clinically important in the care of patients using these drugs.     

Autophagic neuron death in neonatal brain ischemia/hypoxia

Hypoxia/ischemia (H/I) brain injury at birth is an important cause of cerebral palsy, mental retardation, and epilepsy. The H/I insult also causes energy failure, oxidative stress, and unbalanced ion fluxes, leading to high induction of autopahgy in brain neurons. Since the mice unable to execute autophagy (due to brain-specific deletion of Atg7 or Atg5) die by massive loss of cerebral and cerebellar neurons with accumulation of ubiquitin aggregates, induction of neuronal autophagy after H/I injury is generally considered neuroprotective by maintaining cellular homeostasis. However, our recent results show that hippocampal pyramidal neurons undergoing caspase-dependent or -independent death following neonatal H/I injury possess abundant LC3-positive granules, and such H/I neuronal death is largely prevented by Atg7 deficiency. In the present review we discuss the roles of autophagy and other forms of programmed cell death in the neonatal H/I brain insult.     

Autophagic neuron death in neonatal brain ischemia/hypoxia

Hypoxia/ischemia (H/I) brain injury at birth is an important cause of cerebral palsy, mental retardation, and epilepsy. The H/I insult also causes energy failure, oxidative stress, and unbalanced ion fluxes, leading to high induction of autopahgy in brain neurons. Since the mice unable to execute autophagy (due to brain-specific deletion of Atg7 or Atg5) die by massive loss of cerebral and cerebellar neurons with accumulation of ubiquitin aggregates, induction of neuronal autophagy after H/I injury is generally considered neuroprotective by maintaining cellular homeostasis. However, our recent results show that hippocampal pyramidal neurons undergoing caspase-dependent or -independent death following neonatal H/I injury possess abundant LC3-positive granules, and such H/I neuronal death is largely prevented by Atg7 deficiency. In the present review we discuss the roles of autophagy and other forms of programmed cell death in the neonatal H/I brain insult.     

塞来昔布对慢性低O_2高CO_2大鼠肺动脉高压的影响及其机制研究

目的：探讨塞来昔布对慢性低O2高CO2大鼠肺动脉高压的作用。方法：将SD大鼠分为正常对照组,慢性低O2高CO2组,慢性低O2高CO2＋塞来昔布组。用电镜、放免等方法,观察各组大鼠肺动脉平均压、颈动脉平均压、肺细小动脉显微结构、血浆和肺匀浆血栓素B2（TXB2）及6-酮-前列腺素F1α（6-keto-PGF1α）含量的变化。结果：①慢性低O2高CO2组平均肺动脉压（mPAP）比正常组显著升高,塞来昔布组的mPAP比慢性低O2高CO2组显著升高,3组间平均颈动脉压（mCAP）比较差异无显著性。②慢性低O2高CO2组与正常对照组相比血浆和肺匀浆TXB2浓度、TXB2/6-keto-PGF1α比值显著增高,6-keto-PGF1α浓度显著下降;塞来昔布组与慢性低O2高CO2组相比血浆和肺匀浆TXB2浓度无明显变化、TXB2/6-keto-PGF1α显著升高,6-keto-PGF1α显著下降。③光镜下慢性低O2高CO2组与正常组相比,肺细小动脉管壁面积/管总面积（WA/TA）和肺细小动脉中膜厚度（PAMT）均显著增高。塞来昔布组与慢性低O2高CO2组相比WA/TA和PAMT显著增高。④电镜下慢性低O2高CO2组大鼠肺细小动脉内皮细胞吞饮小泡增多,血管壁增厚,中膜平滑肌细胞增生,纤维细胞增多,肺泡II型上皮细胞微绒毛脱落;塞来昔布组中膜平滑肌细胞增大、增多,胞浆肌丝丰富,平滑肌细胞间隙增宽,肺泡隔胶原纤维增生明显。结论：塞来昔布可能有加重慢性低O2高CO2性肺动脉高压和肺血管结构重建倾向,过度抑制COX-2,使TXA2/PGI2比值升高可能是其作用机制之一。     

缺血后处理对肺缺血／再灌注损伤的保护作用及其机制

目的：探讨缺血后处理（聃）是否通过抑制P38丝裂原活化蛋白激酶（P38MAPK）活化来减轻再灌注损伤肺细胞的凋亡。方法：雄性SD大鼠40只,随机分成5组（n=8）,即对照组（C组）、肺缺血／再灌注组（I／R组）、肺缺血／再灌注＋缺血后处理组（IPO组）、缺血后处理＋溶剂对照组（D组）、缺血后处理＋SB203580组（SB组）。各组分别于再灌注2h留取左肺组织,检测肺组织湿／干重比（W／D）和总肺含水量（TLW）;光镜观察肺组织形态学结构改变并进行肺组织损伤定量评估（IQA）;原住末端标记法（TUNEL）检测肺细胞凋亡情况并计算凋亡指数（AI）;RT-PCR和免疫组化法测定Bax、Bcl-2基因和蛋白的表达。结果：与C组相比,I／R组W／D、TLW、IQA和AI均显著升高（P〈0．05,P〈0．01）,肺组织结构发生明显损伤;Bcl-2、Bcl-2／Bax基因及蛋白表达明显降低,Bax基因及蛋白表达明显升高（P〈0．05,P〈0．01）;IPO组、D组、SB组与I／R组相比,w／D、TLW、IQA和AI均显著降低（P〈0．05,P〈0．01）,肺组织结构损伤情况有所改善;Bcl-2、Bcl-2／Bax基因及蛋白表达明显升高,Bax基因及蛋白表达明显降低（P〈0．05,P〈0．01）;D组与IPO组比较各项指标均无明显差异（均P〉0．05）;SB组与IPO组相比,肺组织W／D、TLW、IQA和AI均显著降低（P〈0．05,P〈0．01）,肺组织结构未见明显损伤;Bcl-2、Bcl-2／Bax基因及蛋白表达明显升高,Bax基因及蛋白表达明显降低（P〈0．05,P〈0．01）。结论：I／R通过激活P38MAPK导致大鼠肺泡结构严重破坏,肺内细胞大量凋亡;IPO可能是通过抑制P38MAPK通路的激活而减轻L／R损伤。     

Laryngeal endocrine cells: topographic distribution and adaptation to chronic hypercapnic hypoxia

The morphology, topographic distribution, effects of denervation, and exposure to hypercapnic hypoxia of endocrine cells were examined in rat larynx. The endocrine cells, which were immunoreactive for protein gene product 9.5 (PGP 9.5) and calcitonin gene-related peptide (CGRP), were observed within the epithelial layer of the laryngeal cavity and in the laryngeal gland, while solitary endocrine cells with apical and/or basal cytoplasmic processes appeared near the glottis. After denervation of the left cervical vagosympathetic trunk and the superior laryngeal nerve, the number of mucosal endocrine cells in the denervated side was not significantly different from that in the intact side. After exposure to hypercapnic hypoxia for 3 months, the number of endocrine cells with PGP 9.5 and CGRP was markedly increased. In conclusion, the secretion of laryngeal endocrine cells may be stimulated by CO2 rather than O2. Furthermore, the endocrine cells and the sensory and autonomic nervous system may regulate each other by an axon reflex mechanism. Endocrine cells appear to play a very important role in the local regulation of the laryngeal mucosa.     

Prolactin induces chitotriosidase expression in human macrophages through PTK,PI3‐K,and MAPK pathways

We previously reported that prolactin (PRL) induces chitotriosidase (CHIT‐1) mRNA expression in human macrophages. In this investigation we determined the signaling pathways involved in CHIT‐1 induction in response to PRL. The CHIT‐1 induction PRL‐mediated was reduced by wortmannin and LY‐294002, inhibitors of phosphatidylinositol 3‐kinase (PI3‐K) and by genistein an inhibitor of protein tyrosine kinase (PTK). Pre‐treatment of macrophages with SB203580, a specific inhibitor of the mitogen‐activated kinases (MAPK) p38, or with U0126, an inhibitor of MAPK p44/42, prevented both basal and exogenous PRL‐mediated CHIT‐1 expression. No significant effects on CHIT‐1 induction PRL‐mediated were observed with a protein kinase C inhibitor (PKC), rottlerin, or with an Src inhibitor, PP2, or with JAK2 inhibitor, AG490. In addition, PRL induced a phosphorylation of AKT that was prevented both by the two MAPK inhibitors SB203580 and U0126 and by the PI3‐K inhibitors wortmannin and LY‐294002. In conclusion, our results indicate that PRL up‐regulated CHIT‐1 expression via PTK, PI3‐K, MAPK, and signaling transduction components. J. Cell. Biochem. 107: 881–889, 2009. © 2009 Wiley‐Liss, Inc.     

Effects of hypoxia and hypercapnic hypoxia on the localization and the elimination of Vibrio campbellii in Litopenaeus vannamei, the Pacific white shrimp

Low oxygen (hypoxia) and elevated CO2 (hypercapnia, are characteristic of estuarine environments. Although hypoxia and hypercapnic hypoxia decrease the resistance of shrimp to bacterial pathogens, their direct effects on the immune system are unknown. Here we present evidence demonstrating in the penaeid shrimp Litopenaeus vannamei that both hypoxia and hypercapnic hypoxia affect the localization of bacteria, their conversion from culturable to non-culturable status (bacteriostasis), and their elimination from hemolymph and selected tissues. Shrimp were injected with a sublethal dose of a pathogenic strain of Vibrio campbellii expressing green fluorescent protein and resistance to kanamycin. Real-time polymerase chain reaction was used to determine the number of intact V. campbellii in hemolymph, gills, hepatopancreas, heart, and lymphoid organ. Selective plating was used to quantify the injected bacteria that remained culturable. We found that both hypercapnic hypoxia and hypoxia increased the percentage of culturable bacteria recovered from the hemolymph and tissues, suggesting an overall decrease in bacteriostatic activity. Hypoxia and hypercapnic hypoxia generally increased the distribution of intact V. campbellii to the hepatopancreas and the gills, which are major targets for the pathogenic effects of Vibrio spp., without affecting the number of intact bacteria in the lymphoid organ, a main site of bacterial accumulation and bacteriostatic activity.     

外泌体对低氧/缺血损伤脑神经的保护作用

低氧/缺血会对神经系统产生损伤,减轻低氧/缺血状态对脑神经损伤的至关重要的一个方面就是抑制氧自由基和炎性因子的产生,这也是目前治疗的一个重要策略。低氧/缺血预适应可以通过抑制氧自由基和炎性因子来保护神经细胞。低氧/缺血预适应刺激的外泌体的转运可能是保护作用机制之一,本文通过对外泌体在低氧/缺血状态下发挥的神经保护作用和作用机制等方面进行综述,为低氧/缺血脑神经保护的治疗研究提供新思路。