Oral vaccination and protection of striped skunks (Mephitis mephitis) against rabies using ONRAB®.

Skunks are one of the most important rabies vector species in North America due to their wide geographic distribution, high susceptibility to the rabies virus, and tendency to inhabit areas around human dwellings and domestic animals. Oral vaccination is a cost-effective, socially acceptable technique often used to control rabies in terrestrial wildlife; however, control of rabies in skunks has proven especially challenging due to the lack of a vaccine effective by the oral route in this species. In this study, we examined the antibody response of captive striped skunks (Mephitis mephitis) to ONRAB(®) and tested the protection afforded by the vaccine against rabies virus. Thirty-one skunks were each offered one ONRAB(®) vaccine bait, 25 skunks were administered ONRAB(®) via direct instillation into the oral cavity (DIOC) and ten controls received no vaccine. A blood sample was collected from controls and vaccinates 6 weeks prior to treatment, and then 5 and 7 weeks post-vaccination (PV). A competitive ELISA was used to detect rabies antibody (RAb). Pre-vaccination sera for all skunks, and sera for all controls throughout the serology study, were negative for RAb. Fifty-eight percent (18/31) of skunks in the bait group and 100% (25/25) of skunks that received ONRAB(®) DIOC had detectable RAb by 7 week PV. All 10 controls succumbed to experimental rabies infection. In the group of skunks administered ONRAB(®) DIOC, 100% (23/23) survived challenge 247 days PV. Survival of skunks presented ONRAB(®) baits was 81% (25/31). In the bait group, all 18 skunks that had detectable RAb by 7 week PV survived challenge. Seven additional skunks without detectable RAb prior to week 7 PV also survived. Lack of any remarkable pathology in study animals, together with positive serology and challenge results, supports that ONRAB(®) is a safe and effective oral rabies vaccine for use in skunks.

Oral vaccination and protection of red foxes (Vulpes vulpes) against rabies using ONRAB, an adenovirus-rabies recombinant vaccine.

Twenty-seven red foxes (Vulpes vulpes) were each offered a bait containing ONRAB, a recombinant oral rabies vaccine that uses a human adenovirus vector to express the immunogenic rabies virus glycoprotein; 10 controls received no vaccine baits. Serum samples collected from all foxes before treatment, and each week post-treatment for 16 weeks, were tested for the presence of rabies virus neutralizing antibody (RVNA). In the bait group, a fox was considered a responder to vaccination if serum samples from 3 or more consecutive weeks had RVNA ≥0.5 IU/ml. Using this criterion, 79% of adult foxes (11/14) and 46% of juveniles (6/13) responded to vaccination with ONRAB. Serum RVNA of adults first tested positive (≥0.5 IU/ml) between weeks 1 and 3, about 4 weeks earlier than in juveniles. Adults also responded with higher levels of RVNA and these levels were maintained longer. Serum samples from juveniles tested positive for 1-4 consecutive weeks; in adults the range was 2-15 weeks, with almost half of adults maintaining titres above 0.5 IU/ml for 9 or more consecutive weeks. Based on the kinetics of the antibody response to ONRAB, the best time to sample sera of wild adult foxes for evidence of vaccination is 7-11 weeks following bait distribution. Thirty-four foxes (25 ONRAB, 9 controls) were challenged with vulpine street virus 547 days post-vaccination. All controls developed rabies whereas eight of 13 adult vaccinates (62%) and four of 12 juvenile vaccinates (33%) survived. All foxes classed as non-responders to vaccination developed rabies. Of foxes considered responders to vaccination, 80% of adults (8/10) and 67% of juveniles (4/6) survived challenge. The duration of immunity conferred to foxes would appear adequate for bi-annual and annual bait distribution schedules as vaccinates were challenged 1.5 years post-vaccination.

High prevalence of antibodies against canine adenovirus (CAV) type 2 in domestic dog populations in South Africa precludes the use of CAV-based recombinant rabies vaccines.

Rabies in dogs can be controlled through mass vaccination. Oral vaccination of domestic dogs would be useful in the developing world, where greater vaccination coverage is needed especially in inaccessible areas or places with large numbers of free-roaming dogs. From this perspective, recent research has focused on development of new recombinant vaccines that can be administered orally in a bait to be used as adjunct for parenteral vaccination. One such candidate, a recombinant canine adenovirus type 2 vaccine expressing the rabies virus glycoprotein (CAV2-RG), is considered a promising option for dogs, given host specificity and safety. To assess the potential use of this vaccine in domestic dog populations, we investigated the prevalence of antibodies against canine adenovirus type 2 in South African dogs. Blood was collected from 241 dogs from the Gauteng and KwaZulu-Natal provinces. Sampled dogs had not previously been vaccinated against canine adenovirus type 1 (CAV1) or canine adenovirus type 2 (CAV2). Animals from both provinces had a high percentage of seropositivity (45% and 62%), suggesting that CAV2 circulates extensively among domestic dog populations in South Africa. Given this finding, we evaluated the effect of pre-existing CAV-specific antibodies on the efficacy of the CAV2-RG vaccine delivered via the oral route in dogs. Purpose-bred Beagle dogs, which received prior vaccination against canine parvovirus, canine distemper virus and CAV, were immunized by oral administration of CAV2-RG. After rabies virus (RABV) infection all animals, except one vaccinated dog, developed rabies. This study demonstrated that pre-existing antibodies against CAV, such as naturally occurs in South African dogs, inhibits the development of neutralizing antibodies against RABV when immunized with a CAV-based rabies recombinant vaccine.

Multidisciplinary approach to epizootiology and pathogenesis of bat rabies viruses in the United States.

Zoonotic disease surveillance is typically initiated after an animal pathogen has caused disease in humans. Early detection of potentially high-risk pathogens within animal hosts may facilitate medical interventions to cope with an emerging disease. To effectively spillover to a novel host, a pathogen may undergo genetic changes resulting in varying transmission potential in the new host and potentially to humans. Rabies virus (RABV) is one model pathogen to consider for studying the dynamics of emerging infectious diseases under both laboratory and field conditions. The evolutionary history of RABV is characterized by regularly documented spillover infections and a series of notable host shifts. Within this context, enhanced field surveillance to improve detection of spillover infections will require validated techniques to non-invasively differentiate infected from non-infected individuals. In this study, we evaluate the use of infrared thermography to detect thermal changes associated with experimental RABV infection in big brown bats (Eptesicus fuscus) in a captive colony. Our results indicated that 62% of rabid bats had detectable facial temperature decreases (-4.6°C, SD ± 2.5) compared with pre-inoculation baseline values. These data suggest potential utility for discriminating rabid bats in natural field settings. In addition, focusing upon RABV circulating in the United States between 2008 and 2011, we confirmed spillover events of bat RABV among carnivores and identified cross-species transmission events caused by four lineages of RABV associated with insectivorous bats. Additionally, our analysis of RABV glycoprotein sequences identified substitutions in antigenic sites that may affect neutralizing activity associated with monoclonal antibodies proposed for use in human post-exposure prophylaxis. This study provides a glimpse into RABV pathobiology and spillover dynamics among and between bats and a variety of mesocarnivores.

Glycopeptide insensitive Staphylococcus aureus subdural empyema treated with linezolid and rifampicin.

A 4-year-old boy had surgical debulking of a cerebral astrocytoma followed by chemotherapy. He developed a subdural empyema with a teicoplanin and methicillin resistant Staphylococcus aureus. He was successfully treated with surgical drainage and 6 weeks of antibiotic therapy which included linezolid, rifampicin and metronidazole. Linezolid may be successful in treating other CNS infections caused by antibiotic resistant gram-positive organisms.

Pattern of growth and adiposity from infancy to adulthood in atopic dermatitis.

BACKGROUND: Impaired linear growth has been reported in children with atopic dermatitis (AD) but the pattern of growth in height and weight through childhood and adolescence has not been described. OBJECTIVES: To define the pattern of linear growth and adiposity in AD from early childhood through to adult life. PATIENTS AND METHODS: Growth measurements of 70 male and 40 female patients with AD followed through childhood and adolescence were studied retrospectively and compared with the 1990 U.K. normal values. Height, weight and body mass index (BMI) were converted to standard deviation scores (SDS). Regression analysis examined whether the mean trend was different from zero. RESULTS: While dermatitis was the predominant atopic problem in all 110 patients, 92 had a history of asthma which was mild in 85 of 92. Regression analyses showed that the trends in height, weight and BMI SDS for AD patients were significantly different from zero and also different between males and females. Both sexes were short and relatively overweight from early childhood, a trend that was more pronounced in males than females. At 5 years (school entry), the 50th centile BMI of male (but not female) patients was 0.44 kg m(-2) higher than the reference population but height and weight were lower. The age at adiposity rebound in AD males and females was 0.8 year and 0.7 year later than the U.K. population (6.2 years vs. 5.4 years and 6.2 years vs. 5.3 years, respectively). AD patients attained peak height velocity later than the 1990 U.K. population (males 16.0 years vs. 13.5 years, P = 0.0002; females 13.4 years vs. 11.0 years, P = 0.008). In addition, males had greater mean gain in height during late adolescence (12.2 vs. 8.8 cm, P = 0.03) and were shorter as young adults (170.9 vs. 177.6 cm, P = 0.0005). CONCLUSIONS: Our patients with AD were relatively overweight very early but had a later adiposity rebound, were short in childhood and had a delayed adolescent growth spurt. Serial growth measurements should be done on all children with troublesome AD and can be helpful in counselling about the growth prognosis.

Hypothalamic-pituitary-adrenal function and glucocorticoid sensitivity in atopic dermatitis.

OBJECTIVES: Topical glucocorticoids (GCs) fail to produce a clinical response in some children with atopic dermatitis (AD), suggesting that GC resistance may be present. To determine whether such resistance is generalized or specific to diseased skin, hypothalamic-pituitary-adrenal (HPA) axis function has been assessed in children with moderate to severe AD, who showed a variable response to treatment with topical GC. STUDY DESIGN: Thirty-five patients (.7-18.7 years old; median: 9.3 years) with AD requiring topical GCs from infancy underwent a low-dose adrenocorticotrophin hormone (ACTH; Synacthen) test (LDST) (500 ng/1.73 m(2) ACTH). Groups 1 (7 patients), 2 (17 patients), and 3 (4 patients) used mild, moderate, or potent/very potent topical preparations, respectively. Group 4 (7 boys with severe, treatment-resistant disease) had received GC in at least 1 form (inhaled +/- intranasal +/- oral) in addition to varying potencies of topical GC. Fourteen healthy subjects (3.8-17.3 years old) served as control subjects. Group 4 patients had a daytime plasma cortisol profile and 08.00 hours measurement of plasma ACTH and its precursors. RESULTS: The response to ACTH for groups 1 and 2 did not differ from that of control subjects. Group 3 had lower peak, increment, and area under curve cortisol responses than those in controls, whereas group 4 had lower baseline, peak, and area under curve cortisol responses. Eight patients failed the LDST (peak cortisol <500 nmol/L and increment <200 nmol/L): controls = 0/14, group 1 = 0/7, group 2 = 1/17, group 3 = 4/4, and group 4 = 3/7. Treatment score (based on GC potency, area treated, and duration) was the only factor to influence peak cortisol response on LDST (r(2) = 24%). In group 4, only 1 of 7 patients had a cortisol profile within the normal range but he failed the LDST. In the 5 subjects with an 08.00 hours cortisol <300 nmol/L, the matched ACTH level was inappropriately low. CONCLUSIONS: HPA suppression was rarely found in children or adolescents with moderate to severe AD who used mild or moderately potent topical GCs over many years. However, HPA suppression was common in those receiving potent topical GC preparations or a combination of GC routes of administration. In those with severe AD, evidence of HPA suppression but lack of clinical response to GC treatment excluded significant generalized GC resistance. This would suggest that localized resistance to GCs within the diseased skin may be part of the aetiopathogenesis of severe AD.

Benign focal ischemic preconditioning induces neuronal Hsp70 and prolonged astrogliosis with expression of Hsp27.

We have established a focal preconditioning (PC) paradigm that produces significant and prolonged ischemic tolerance (IT) of the brain to subsequent permanent middle cerebral artery occlusion (MCAO). PC using 10 min of MCAO induces brain tolerance at 1-7 days of reperfusion that requires active protein synthesis. The protective protein(s) involved are unknown. In these studies the increased transcription and translation of the inducible 70-kDa heat shock protein (Hsp70) and the 27-kDa heat shock protein (Hsp27), and astrogliosis/glial fibrillary acidic protein (GFAP) were determined by Northern analysis and immunohistochemistry following PC. Cellular localization of proteins was determined by double labeling. PC produced no brain injury but did increase Hsp70 mRNA transiently at 6 h and increased Hsp27 mRNA later at 24 h for at least 5 days. Protein expression induced by PC exhibited a similar profile. Hsp70 protein was primarily expressed in neurons from 1 to 5 days post-PC throughout the PC cortex. Hsp27 protein expression was initiated later for a much longer period of time. A remarkable astroglyosis was verified with increased astrocytic Hsp27 from 1 to 7 days after PC. Gliosis with increased Hsp27 in the PC cortex was still present but reduced 4 weeks after PC. Therefore, PC that results in brain tolerance/neuroprotection increases neuronal Hsp70 in the PC cortex and activated astrocytic Hsp27 in the PC cortex in a temporal fashion associated with developing IT. The short duration of benign ischemia (PC) that produces IT produces a robust, long-lived cellular and protein synthetic response that extends throughout the entire cortex (i.e. well beyond the MCA perfusion territory). The resulting IT is associated with changes in astrocyte-activation that might provide increased support and protection from injury. Although both Hsp70 and Hsp27 may participate in the neuroprotection/brain tolerance induced by PC, the temporal expression patterns of these proteins indicate that they are not solely responsible for the tolerance to brain injury.

Caspase-8 and caspase-3 are expressed by different populations of cortical neurons undergoing delayed cell death after focal stroke in the rat.

A number of studies have provided evidence that neuronal cell loss after stroke involves programmed cell death or apoptosis. In particular, recent biochemical and immunohistochemical studies have demonstrated the expression and activation of intracellular proteases, notably caspase-3, which act as both initiators and executors of the apoptotic process. To further elucidate the involvement of caspases in neuronal cell death induced by focal stroke we developed a panel of antibodies and investigated the spatial and temporal pattern of both caspase-8 and caspase-3 expression. Our efforts focused on caspase-8 because its "apical" position within the enzymatic cascade of caspases makes it a potentially important therapeutic target. Constitutive expression of procaspase-8 was detectable in most cortical neurons, and proteolytic processing yielding the active form of caspase-8 was found as early as 6 hr after focal stroke induced in rats by permanent middle cerebral artery occlusion. This active form of caspase-8 was predominantly seen in the large pyramidal neurons of lamina V. Active caspase-3 was evident only in neurons located within lamina II/III starting at 24 hr after injury and in microglia throughout the core infarct at all times examined. Terminal deoxynucleotidyl transferase-mediated biotinylated UTP nick end labeling, gel electrophoresis of DNA, and neuronal cell quantitation indicated that there was an early nonapoptotic loss of cortical neurons followed by a progressive elimination of neurons with features of apoptosis. These data indicate that the pattern of caspase expression occurring during delayed neuronal cell death after focal stroke will vary depending on the neuronal phenotype.

Astrocytic demise precedes delayed neuronal death in focal ischemic rat brain.

Active neuronal-glial interaction is important in the maintenance of brain homeostasis and is vital for neuronal survival following brain injury. The time course of post-ischemic astroglial dysfunction and neuronal death was studied in the spontaneously hypertensive rat (SHR) brain following permanent middle cerebral artery occlusion (MCAO). In situ hybridization with 35S-labeled riboprobes for GFAP and GLUT3 was used to monitor mRNA expression in glia and neurons. Astrocytic proteins GFAP, vimentin, S100, Glutathione-S-Transferase Yb (GST Yb) and neuronal protein TG2 were detected by immunofluorescence. Cells were co-stained with in situ end labeling (ISEL) to detect DNA fragmentation, a hallmark of cell death. GFAP mRNA expression declined rapidly in the ischemic region of the cortex and was almost absent by 12 h. Immunohistochemical studies revealed a parallel decline in the corresponding protein: a reduction in GFAP staining was apparent in the infarct after 3 h and by 24 h, there was essentially no remaining GFAP. Three other glial proteins (vimentin, S100 and GST Yb) disappeared from infarct over a similar time course. A few ISEL positive cells were observed in the infarct at 6 h, but maximal detection was not seen until 24-48 h. Most of the ISEL-positive cells were neurons, identified by co-staining with the neuronal marker TG2. Few cells expressing GFAP or other glial markers were positive at any time point. Neuronal GLUT3 mRNA declined more slowly than GFAP mRNA in the ischemic core and disappeared during the period of neuronal death. Concurrent with the loss of GFAP mRNA and protein expression in the infarct, there was a rapid rise in GFAP mRNA in the peri-infarct region of ipsilateral hemisphere and proximal region of the contralateral hemisphere. This was followed by the enhanced GFAP protein expression characteristic of reactive astrocytes, but over a significantly slower time course. These studies show that MCAO leads to a rapid decline of GFAP mRNA and glial proteins, which appears to precede the decline in neuronal mRNA and neuronal death within the infarct. Early astroglial dysfunction may play a critical role in determining the outcome of acute hypoxic-ischemic injury by compromising neuronal-glial interactions.

Matrix remodeling after stroke. De novo expression of matrix proteins and integrin receptors.

Following an ischemic insult to the central nervous system a reorganization of cells and tissue takes place as the surrounding cells attempt to limit the injury, repair the damage, and restore normal architecture of the brain. This tissue remodeling requires de novo synthesis of genes and proteins which enables cells to actively change their relationship with the existing extracellular matrix and with other cells to reorganize the damaged tissue. We have identified two key molecular components of the matrix remodeling process after focal ischemia: osteopontin (OPN) and its integrin receptor alpha v beta 3 (alpha v beta 3). OPN is initially expressed by activated macrophages and microglia in the periinfarct region (24-48 hr) and at later times (5-15 days) in the core infarct. After focal stroke the alpha v beta 3 was upregulated by astrocytes in the periinfarct region. Spatial and temporal analyses demonstrated that at 5 days after injury the alpha v beta 3-positive astrocytes were at a distance from the osteopontin-expressing macrophages; by 15 days the alpha v beta 3-expressing astrocytes were localized within an osteopontin-rich matrix. In vitro OPN was shown to induce migration of astrocytes in a Boyden chamber system. These data suggest that OPN derived from microglia at the infarct border zone (and possible macrophages in the infarct core) may serve as an "astrokine" (suggested term for astrocyte chemoattractant) to organize the astrocyte scar after focal stroke. Our data demonstrate profound changes in brain matrix remodeling after focal ischemic stroke, including the synthesis and release of matrix proteins alien to the normal brain, the expression of integrin receptors that ligate these proteins, and possibly a novel function for microglial-derived OPN in astrocyte migration after focal ischemia that may drive glial activation, organization, and repair functions.

Embryonic expression of the myelin basic protein gene: identification of a promoter region that targets transgene expression to pioneer neurons.

The myelin basic protein (MBP) gene produces two families of structurally related proteins from three different promoters-the golli products, generated from the most upstream promoter, and the MBPs, produced from the two downstream promoters. In this report we describe the expression of golli proteins within some of the earliest neuronal populations of the brain, including Cajal-Retzius cells and preplate neurons of the forebrain, representing a new marker for these cells. To identify elements responsible for neuronal expression of the golli products, we generated transgenic animals from constructs containing different portions of the upstream promoter. A construct containing 1.1 kb immediately upstream of the golli transcription start site targeted expression of beta-galactosidase to preplate neurons and a subset of Cajal-Retzius cells in transgenic mice-the first reported genetic element to target expression to these pioneer cortical populations. Although expression in Cajal-Retzius cells declined with embryonic development, preplate cells continued to express the transgene after arriving at their final destination in the subplate. Interestingly, expression persisted in subplate neurons found within a distinct layer between the white matter and cortical layer VI well into postnatal life. Birth dating studies with bromodeoxyuridine indicated that these neurons were born between E10.5 and E12.5. Thus, the transgene marked subplate neurons from their birth, providing a fate marker for these cells. This work suggests a role for the MBP gene in the early developing brain long before myelination and especially in the pioneer cortical neurons important in the formation of the cortical layers.

IL-10 reduces rat brain injury following focal stroke.

The effects of the anti-inflammatory cytokine, IL-10, on brain injury following permanent focal ischemia were determined. Rats subjected to occlusion of the right middle cerebral artery (MCAO) were administered IL-10 (1 microg) centrally into the lateral ventricle 30 min and 3 h post MCAO or systemically into the tail vein (5 or 15 microg/h) starting 30 min post MCAO for 3 h. Brains were removed 24 h later and infarct size was measured. IL-10 administered centrally significantly (P < 0.01) reduced infarct size by 20.7% +/- 6.0 compared to vehicle. Systemic IL-10 administration at 5 and 15 microg/h significantly (P < 0.05) decreased infarct size (40.3% +/- 14.0 and 30.7% +/- 13.7, respectively). These studies indicate that an anti-inflammatory therapeutic approach using IL-10 can provide neuroprotection in ischemic stroke.

Prolonged expression of interferon-inducible protein-10 in ischemic cortex after permanent occlusion of the middle cerebral artery in rat.

Focal cerebral ischemia elicits local inflammatory reaction as demonstrated by the accumulation of inflammatory cells and mediators in the ischemic brain. Interferon-inducible protein-10 (IP-10) is a member of the C-X-C chemokine family that possesses potent chemoattractant actions for monocytes, T cells, and smooth muscle cells. To investigate a potential role of IP-10 in focal stroke, we studied the temporal expression of IP-10 mRNA after occlusion of the middle cerebral artery in rat by means of northern analysis. IP-10 mRNA expression after focal stroke demonstrated a unique biphasic profile, with a marked increase early at 3 h (4.9-fold over control; p < 0.01), a peak level at 6 h (14.5-fold; p < 0.001) after occlusion of the middle cerebral artery, and a second wave induction 10-15 days after ischemic injury (7.2- and 9.3-fold increase for 10 and 15 days, respectively; p < 0.001). In situ hybridization confirmed the induced expression of IP-10 mRNA and revealed its spatial distribution after focal stroke. Immunohistochemical studies demonstrated the expression of IP-10 peptide in neurons (3-12 h) and astroglial cells (6 h to 15 days) of the ischemic zone. To explore further the potential role of IP-10 in focal stroke, we demonstrated a dose-dependent chemotactic action of IP-10 on C6 glial cells and enhanced attachment of rat cerebellar granule neurons. Taken together, the data suggest that ischemia induces IP-10, which may play a pleiotropic role in prolonged leukocyte recruitment, astrocyte migration/activation, and neuron attachment/sprouting after focal stroke.

Osteopontin and its integrin receptor alpha(v)beta3 are upregulated during formation of the glial scar after focal stroke.

BACKGROUND AND PURPOSE: Microglia and astrocytes in the peri-infarct region are activated in response to focal stroke. A critical function of activated glia is formation of a protective barrier that ultimately forms a new glial-limiting membrane. Osteopontin, a provisional matrix protein expressed during wound healing, is induced after focal stroke. The present study was performed to determine the spatial and temporal expression of osteopontin and its integrin receptor alpha(v)beta3 during formation of the peri-infarct gliotic barrier and subsequent formation of a new glial-limiting membrane. METHODS: Spontaneously hypertensive rats (n = 19) were subjected to permanent occlusion of the middle cerebral artery and killed 3, 6, and 24 hours and 2, 5, and 15 days after occlusion. The spatial and temporal expression of osteopontin mRNA was determined by in situ hybridization, and that of osteopontin ligand and its integrin receptor alpha(v)beta3 was determined by immunohistochemistry. RESULTS: Osteopontin mRNA was expressed de novo in the peri-infarct region from 3 to 48 hours; by 5 days osteopontin mRNA expression was restricted to the infarct. Osteopontin protein was expressed by peri-infarct microglia beginning at 24 hours and by microglia/macrophages at 48 hours in the infarct. Integrin receptor alpha(v)beta3 was expressed in peri-infarct astrocytes at 5 and 15 days. CONCLUSIONS: Early microglial/macrophage expression of osteopontin mRNA defines the borders and final infarct area at 24 hours. At 5 days osteopontin ligand is at a distance from the peri-infarct astrocytes expressing integrin receptor alpha(v)beta3. By 15 days astrocytes expressing integrin receptor alpha(v)beta3 are localized in an osteopontin-rich region concomitant with formation of the new glial-limiting membrane. The de novo expression and interaction of osteopontin ligand with its receptor integrin alpha(v)beta3 suggest a role in wound healing after focal stroke.

Delayed expression of osteopontin after focal stroke in the rat.

Focal brain ischemia induces inflammation, extracellular matrix remodeling, gliosis, and neovascularization. Osteopontin (OPN) is a secreted glycoprotein that has been implicated in vascular injury by promoting cell adhesion, migration, and chemotaxis. To investigate the possible involvement of OPN in brain matrix remodeling after focal stroke, we examined the expression of OPN in ischemic cortex after permanent or temporary occlusion of the middle cerebral artery (MCAO) of the rat. OPN mRNA and protein levels in nonischemic cortex were not detected consistently, although significant induction of OPN was observed in the ischemic cortex. OPN mRNA increased 3.5-fold at 12 hr and reached peak levels 5 d (49.5-fold; p < 0.001) after permanent MCAO. The profile of OPN mRNA induction after transient MCAO (160 min) with reperfusion was essentially the same as that of permanent MCAO. In situ hybridization and immunohistochemical studies demonstrated strong induction of OPN in the ischemic cortex, which was localized primarily in a subset of ED-1-positive macrophages that accumulated in the ischemic zone. Moreover, OPN immunoreactivity was detected in the matrix of ischemic brain, suggesting a functional role of the newly deposited matrix protein in cell-matrix interactions and remodeling. Indeed, using a modified Boyden chamber, we demonstrated a dose-dependent chemotactic activity of OPN in C6 astroglia cells and normal human astrocytes. Taken together, these data suggest that the upregulation of OPN after focal brain ischemia may play a role in cellular (glia, macrophage) migration/activation and matrix remodeling that provides for new matrix-cell interaction.

A dental-based, athletic trainer-mediated spit tobacco cessation program for professional baseball players.

During 1997 spring training, the National Spit Tobacco Education Program provided a spit (smokeless) tobacco intervention program to 16 professional baseball clubs. The program consisted of an awareness-raising presentation and an opportunity to discuss quitting spit tobacco use with an expert cessation counselor. For two clubs, however, a more extensive intervention was pilot-tested for feasibility and acceptability among their major- and minor-league teams during their regularly scheduled health examinations at the beginning of spring training. The intervention included an oral exam by a dentist who advised spit tobacco users to stop and pointed out any spit tobacco-associated lesions in the player's mouth, brief cessation counseling by a specially trained dental hygienist, and ongoing support and follow-up by the certified athletic trainer to promote cessation. Findings from this pilot study indicate that this intervention, which is dependent upon involvement of dental professionals, was feasible to implement during spring training and appeared to be well-received by the athletes. Dental professionals are in an excellent position to advise and help spit tobacco users to quit and can have an important role in helping youth overcome this rapidly growing addiction.

The trkC receptor is transiently localized to Purkinje cell dendrites during outgrowth and maturation in the rat.

In vivo studies of granule cell gene expression during corticocerebellar development and in vitro studies of Purkinje cell neurite outgrowth suggest that neurotrophin-3 may influence growth of Purkinje cell dendrites. To determine whether neurotrophic substances affect the growth of specific neuronal processes (i.e. axons and dendrites) or nonspecifically cause process development by exerting a trophic influence upon neuronal physiology we performed an immunohistochemical examination of trkC protein expression during early postnatal development of the rat cerebellum. Our findings indicate that Purkinje cells begin to synthesize trkC protein coincident with the onset of dendritic outgrowth. Robust immunostaining was evident throughout the entire somatodendritic domain of Purkinje cells during dendritic development but became faint and restricted to the cell body subsequent to the completion of dendritogenesis. These results suggest that growth and maturation of the Purkinje cell dendritic arbor may be influenced by neurotrophin-3 activation of trkC receptors distributed within developing dendrites.

CNTF induces GFAP in a S-100 alpha brain cell population: the pattern of CNTF-alpha R suggests an indirect mode of action.

In a recent report, we demonstrated that intracerebral injections of the pleiotropic cytokine, ciliary neurotrophic factor (CNTF), into developing postnatal rats evoked a severe inflammatory response as determined by the appearance of reactive astrocytes and activated microglia. Considering the likely involvement of CNTF in the injury response, we felt it was important to further understand the role of CNTF in the developing rat CNS. In this study, we examined the responsiveness of other cell populations to intracerebral injections of CNTF. We report that CNTF increases glial fibrillary acidic protein (GFAP), while having no appreciable effect on the levels of other intermediate filaments including vimentin and neurofilament. Moreover, CNTF did not affect the expression of the mature oligodendrocyte gene, myelin basic protein. These results suggest that CNTF is highly specific in its regulation of GFAP. In our previous study, we showed CNTF to increase GFAP in a cell population that already exists in the CNS parenchyma. To determine the origin of the CNTF-induced reactive astrocytes, therefore, we have utilized a technique of combined in situ hybridization and immunocytochemistry. To examine the possibility that CNTF acts on oligodendrocyte precursors to give rise to reactive astrocytes, the platelet-derived growth factor alpha receptor (PDGF-alpha R) was utilized as a riboprobe in conjunction with an antibody to GFAP. Examination of CNTF-induced GFAP+ astrocytes revealed no colocalization with PDGF-alpha R mRNA. In contrast, when we utilized an S100 alpha antibody recognizing a calcium binding protein in immature astrocytes, we found colocalization of S100 alpha and GFAP mRNA. These data suggest that CNTF induces an upregulation of GFAP in immature S100 alpha + astrocytes. Examination of the CNTF-alpha receptor mRNA revealed no change in expression following CNTF treatment. Unexpectedly, however, the CNTF-induced astrogliotic response appears to be indirect since the CNTF-alpha receptor was solely expressed by neurons in the cytokine-treated animals.

Expression of the myelin basic protein gene locus in neurons and oligodendrocytes in the human fetal central nervous system.

The myelin basic protein (MBP) gene locus is composed of two overlapping transcription units that share all of the MBP exons. One of these transcription units expresses the MBPs and the other expresses a family of proteins structurally related to the MBPs. This second transcription unit is called the Golli gene, and the entire complex is called the Golli-mbp gene. In this study, the expression of the Golli gene was examined in the human fetal central nervous system (CNS). By using reverse transcriptase-polymerase chain reaction cloning we have identified eight new members of the Golli gene family of transcripts expressed in the human CNS. Golli gene expression was examined by in situ hybridization and immunohistochemistry, and surprisingly, Golli products were found to be expressed in neurons as well as oligodendrocytes. Furthermore, the subcellular distribution of Golli immunoreactivity in fetal spinal cord interneurons shifted between the various laminae. Golli protein was localized within the nuclei of interneurons in the posterior horn, but was found in the cell bodies and processes of interneurons in the anterior horn. Within oligodendrocytes, Golli protein was detected in the cell bodies and processes, including processes which were wrapping axonal segments. Golli mRNA expression was also observed in neurons within the cerebral cortex between 18 and 20 weeks postconception, prior to myelination of this brain region. During this period, there was a striking developmental increase in the numbers and in the locations of neurons expressing Golli mRNAs within the cortical plate. The diverse distribution of Golli proteins within neurons and oligodendrocytes indicates that their function is quite different from that of the MBPs to which they are closely related.