Induction of biologically active antineutrophil cytoplasmic antibodies by immunization with human apoptotic polymorphonuclear leukocytes

Translocation of intracellular components to the cell surface during the priming or apoptosis of polymorphonuclear leukocytes (PMN) is an important mechanism for interaction of antineutrophil cytoplasmic antibodies (ANCA) with these antigens. To test the capacity of apoptotic PMN to trigger production of ANCA, six groups of mice were immunized with either live or apoptotic lymphocytes, or with live, apoptotic, formalin-fixed, or lysed PMN. Mice immunized with both live and apoptotic neutrophils developed high titers of antibodies which gave a granular cytoplasmic immunofluorescent pattern. These antibodies were specific for lactoferrin and myeloperoxidase. Following a second intravenous infusion of apoptotic PMNs, mice developed anti-PR3 antibodies. Vasculitis lesions were not found in mice which developed ANCA. The ANCA-containing IgG fraction induced superoxide production by human PMNs. These results support the hypothesis that neutrophil-specific antigens presented on the cell membranes of apoptotic PMN may induce ANCA in the proper conditions.     

Evidence that amyloid beta-peptide-induced lipid peroxidation and its sequelae in Alzheimer's disease brain contribute to neuronal death

Amyloid beta-peptide [Abeta(1-42)] is central to the pathogenesis of Alzheimer's disease (AD), and the AD brain is under intense oxidative stress, including membrane lipid peroxidation. Abeta(1-42) causes oxidative stress in and neurotoxicity to neurons in mechanisms that are inhibited by Vitamin E and involve the single methionine residue of this peptide. In particular, Abeta induces lipid peroxidation in ways that are inhibited by free radical antioxidants. Two reactive products of lipid peroxidation are the alkenals, 4-hydroxynonenal (HNE) and 2-propenal (acrolein). These alkenals covalently bind to synaptosomal protein cysteine, histidine, and lysine residues by Michael addition to change protein conformation and function. HNE or acrolein binding to proteins introduces a carbonyl to the protein, making the protein oxidatively modified as a consequence of lipid peroxidation. Immunoprecipitation of proteins from AD and control brain, obtained no longer than 4h PMI, showed selective proteins are oxidatively modified in the AD brain. Creatine kinase (CK) and beta-actin have increased carbonyl groups, and Glt-1, a glutamate transporter, has increased binding of HNE in AD. Abeta(1-42) addition to synaptosomes also results in HNE binding to Glt-1, thereby coupling increased Abeta(1-42) in AD brain to increased lipid peroxidation and its sequelae and possibly explaining the mechanism of glutamate transport inhibition known in AD brain. Abeta also inhibits CK. Implications of these findings relate to decreased energy utilization, altered assembly of cytoskeletal proteins, and increased excitotoxicity to neurons by glutamate, all reported for AD. The epsilon-4 allele of the lipid carrier protein apolipoprotein E (APOE) allele is a risk factor for AD. Synaptosomes from APOE knock-out mice are more vulnerable to Abeta-induced oxidative stress (protein oxidation, lipid peroxidation, and ROS generation) than are those from wild-type mice. Further, synaptosomes from allele-specific APOE knock-in mice have tiered vulnerability to Abeta(1-42)-induced oxidative stress, with APOE4 more vulnerable to Abeta(1-42) than are those from APOE2 or APOE3 mice. These results are consistent with the notion of a coupling of the oxidative environment in AD brain and increased risk of developing this disorder. Taken together, the findings from in-vitro studies of lipid peroxidation induced by Abeta(1-42) and postmortem studies of lipid peroxidation (and its sequelae) in AD brain may help explain the APOE allele-related risk for AD, some of the functional and structural alterations in AD brain, and strongly support a causative role of Abeta(1-42)-induced oxidative stress in AD neurodegeneration.     

Characteristics of the delayed rectifier K current compared in myocytes isolated from the atrioventricular node and ventricle of the rabbit heart

The delayed rectifier potassium current (I _K) is known to be important in action potential repolarisation and may contribute to the diastolic pacemaker depolarisation in pacemaker cells from the heart. In this study, using whole-cell patch clamp, we investigated the characteristics of I _K in morphologically normal cells from the atrioventricular node (AVN) and ventricle of the rabbit heart. Cells were held at −40 mV and 5 μM external nifedipine was used to block L-type calcium current (I _Ca,L). Significant I _K was observed with pulses to potentials more positive than −30 mV. The steady-state activation curve in both cell types showed maximal activation at between + 10 and + 20 mV. Half-maximal activation of I _K occurred at −4.9 and −4.1 mV with slope factors of 8.3 and 12.4 mV in ventricular and AVN cells, respectively. Using pulses of increasing duration, significant I _K tails after repolarisation from + 40 mV were observed with pulses of 20 ms and increased with pulses up to 100–120 ms in both cell types. Pulses of longer duration did not activate further I _K and this suggested that only the rapid component of I _K, called I _Kr, was present in either cell type. Moreover, I _K tails after pulses to all potentials were blocked completely by E-4031, a selective blocker of I _Kr. The reversal potential of I _K varied with the concentration of external K. Superfusion of AVN cells with medium containing 4, 15 and 40 mM [K⁺]_o resulted in reversal potentials of −81, −56 and −32 mV, respectively, which are close to values predicted if the I _K channel were highly selective for K. The time constants for deactivation of I _K in ventricle and AVN on return to −40 mV after a 500-ms activating pulse to + 60 mV were 480 ms and 230 ms, respectively. The faster deactivation of I _K in AVN cells was a distinguishing feature and suggests that there may be differences in the I _Kr channel protein between ventricular and AVN cells. Received: 24 July 1995 /Received after revision: 20 October 1995 /Accepted: 23 October 1995     

The hyperpolarisation-activated current,I f,is not required for pacemaking in single cells from the rabbit atrioventricular node

Using electrophysiological and radiotracer studies in parallel, we have investigated the characteristics of the endogenous Na⁺-dependent amino acid transporter (system B^0,+) in Xenopus oocytes with regard to ion dependence, voltage dependence and transport stoichiometry. In voltage-clamped oocytes (–60 mV) superfusion with saturating concentrations of amino acids (1 mM) in 100 mM NaCl resulted in reversible, inward currents (mean±SEM): alanine, 1.83±0.09 nA (n=21); arginine, 2.54±0.18 nA (n=17); glutamine, 1.73±0.10 nA (n=19). Only arginine evoked a current in choline medium (0.50±0.13 nA, n=10), whereas Cl^– replacement had no effect on evoked currents. The glutamine-evoked current was saturable (I _max=1.73 nA, glutamine K _m=0.12 mM) and linearly dependent upon voltage between –90 and –30 mV. Using direct and indirect (activation) methods, we found that transport can proceed with Na⁺/amino acid coupling stoichiometry of either 11 or 21, but coupling was the same for each amino acid tested (alanine, arginine and glutamine) within a batch of oocytes (i.e. from a single toad). Despite the net single positive charge on arginine, the magnitude of the net transmembrane charge movement during Na⁺-coupled arginine transport was identical to that for the zwitterionic neutral amino acids glutamine and alanine; this may be explained by a concomitant stimulation of K⁺ efflux during arginine transport with a putative coupling of 1 K⁺1 arginine.     

Murine Brca1: sequence and significance for human missense mutations

We have cloned and sequenced a mouse homologue of the humanbreast and ovarian cancer susceptibility gene, BRCA1. The predictedmouse Brca1 protein is composed of 1812 amino acids. The murineprotein is 60% identical and 72% similar to the human BRCA1protein. Two regions of high homology have been identified betweenthe two proteins. First is the Cys3—His—Cys4 typezinc-finger domain that is identical between the two proteins.The second region is defined by 115 amino acids near the carboxyend of the Brca 1 protein that is 83% identical to human BRCA1sequence. Seven of eight amino acids involved in human missensemutations that are associated with the disease were found tobe conserved between the two species. In contrast, most of theamino acids that are involved in polymorphic variations werenot conserved. We therefore propose that the interspecies conservationof predicted amino acid sequences can be used as an additionalcriterion to determine the significance of human missense mutations.     

Concurrent infection with an intestinal helminth parasite impairs host resistance to enteric Citrobacter rodentium and enhances Citrobacter-induced colitis in mice

Infections with intestinal helminth and bacterial pathogens, such as enteropathogenic Escherichia coli, continue to be a major global health threat for children. To test the hypothesis that intestinal helminth infection may be a risk factor for enteric bacterial infection, a murine model was established by using the intestinal helminth Heligomosomoides polygyrus. To analyze the modulatory effect of a Th2-inducing helminth on the outcome of enteric bacterium Citrobacter rodentium infection, BALB/c and STAT 6 knockout (KO) mice were infected with H. polygyrus, C. rodentium, or both. We found that only BALB/c mice coinfected with H. polygyrus and C. rodentium displayed a marked morbidity and mortality. The enhanced susceptibility to C. rodentium and intestinal injury of coinfected BALB/c mice were shown to be associated with a significant increase in helminth-driven Th2 responses, mucosally and systemically, and correlated with a significant downregulation of protective gamma interferon and with a dramatic upregulation of the proinflammatory tumor necrosis factor alpha response. In addition, C. rodentium-associated colonic pathology in coinfected BALB/c mice was significantly enhanced, whereas bacterial burden was increased and clearance was delayed. In contrast, coinfection in STAT 6 KO mice failed to promote C. rodentium infection or to induce a more severe intestinal inflammation and tissue injury, demonstrating a mechanism by which helminth influences the development of host protective immunity and susceptibility to bacterial infections. We conclude that H. polygyrus coinfection can promote C. rodentium-associated disease and colitis through a STAT 6-mediated immune mechanism.     

The Prediction of Intracranial Injury After Minor Head Trauma in the Pediatric Population

Reference: Dunning J, Batchelor J, Stratford-Smith P, et al. A meta-analysis of variables that predict significant intracranial injury in minor head trauma. Arch Dis Child. 2004;89:653–659.Clinical Question: Which clinical signs or symptoms of minor head trauma are predictive of intracranial hemorrhage in children and adolescents?Data Sources: Investigations were identified by MEDLINE and EMBASE searches from 1990 through 2002 by a search of the grey literature and by contacting experts for additional papers. The search terms were selected to find all studies reporting intracranial hemorrhage (ICH) or complications after head trauma.Study Selection: A full systematic review was conducted, and all cohort or nested cohort studies that presented data on minor head injuries in children less than 18 years old, with or without ICH, were identified. Studies were then judged for inclusion based on the presentation of a series of at least 100 patients and a documented reliable standard for the detection of ICH for all patients in the study. The use of computed tomography (CT) and medical follow-up was considered an acceptable gold standard. Intracranial hemorrhage was defined as any abnormality detected on the CT scan due to the traumatic presence of extravascular blood. Minor head trauma was defined as patients presenting with a Glasgow Coma Scale (GCS) score of 13–15.Data Extraction: Seven clinical correlates were used for data extraction, including skull fracture, headache, vomiting, focal neurology, seizure, loss of consciousness, and a GCS score of less than 15. Data were analyzed using a pooled estimate of the relative risk ratio with a random-effects model.Main Results: The searches identified a total of 2134 studies for the initial review. After an abstract review by 2 independent examiners, 98 studies were identified for a full-paper review. Each study was graded on a 4-point scale according to the level of evidence provided, using scales consistent with the Oxford Centre for Evidence-Based Medicine and the National Institute for Clinical Excellence. Thirty-four of these articles were of adequate quality for inclusion; however, many did not include data that could be separated into a specific data set for children, had too small a sample size, or lacked enough data on individual correlates to head trauma. Nineteen studies provided data on children, but 3 of these were excluded due to poor quality or lack of a reported CT scan, leaving a total of 16 studies for the meta-analysis.The analysis included a total of 22 420 patients ranging between 0 and 18 years of age. The meta-analysis showed a significant increased relative risk of ICH for patients sustaining loss of consciousness (2.23), GCS <15 (5.51), skull fracture (6.13), and focal neurology (9.43). No significant increases in risk for headache (1.02), vomiting (0.878), or seizure (2.82) were noted; however, heterogeneity was significant for this last correlate. The prevalence of ICH ranged from 1.3 to 36%, supporting the notion of a large amount of heterogeneity or variability in the inclusion criteria among the studies.Conclusions: These findings demonstrate that loss of consciousness, decreased level of consciousness (GCS <15), skull fracture, and focal neurology are risk factors for ICH in the pediatric population. However, these findings are not definitive enough to establish pediatric head-injury guidelines regarding CT scanning or admission to hospital after minor head trauma.COMMENTARYAlthough intracranial hemorrhage (ICH) after mild head injury is a rare occurrence in athletes, certified athletic trainers (ATCs) must be aware of the signs and symptoms of all severities of head trauma, including ICH. The initial role of the ATC when there is a suspected head injury is the detection of focal traumatic brain injury (TBI), including epidural hematoma, subdural hematoma, cerebral contusion, and intracerebral hemorrhage and hematoma.^1,2 To successfully recognize these potentially life-threatening head injuries, the ATC must understand the various presentations of athletes with head injuries and the signs and symptoms that often accompany them, such as loss of consciousness (LOC), cranial nerve deficits, decreasing mental status, and worsening symptoms.¹Dunning et al³ presented a meta-analysis that has direct relevance to the practice of athletic training and the management of minor head injuries. Understanding the potential risk factors for ICH is an important step in ensuring adequate referral to medical professionals and a quick diagnosis of possible ICH. Often, the ATC must decide whether an athlete should be referred to the emergency room once he or she has sustained a mild head injury and, once at the emergency room, physicians need to decide on a course of diagnostics. This is even more of a concern in the pediatric athlete because of the potential for both short-term and long-term complications in the still-developing brain.^4–7 As a general rule, failure of an athlete''s mental status to clear rapidly should lead to a referral for neuroimaging.⁸ With the suspicion of focal TBI, CT scans have been recommended as the neuroimaging modality of choice because they can easily detect acute blood collection and skull fracture.⁸It is important to note that differences exist between sport-related minor head trauma and minor head trauma from additional mechanisms, such as motor vehicle accidents, falls, and other accidents. None of the studies used by Dunning et al³ were investigations of sport-related minor head injury. Minor head injuries that produce ICH or any of the clinical correlates found to be significant predictors of ICH (LOC, focal neurology, Glasgow Coma Scale [GCS] <15, or skull fracture) are rare in athletes.² In fact, recent authors have reported that only 6.3 to 8.9% of collegiate athletes experienced LOC after a concussion.^9–11 Regardless of the rarity of focal TBI and injuries that result in ICH during athletics, it is imperative that these injuries be ruled out by the ATC.Based on this meta-analysis, the correlates identified as predictors of ICH included LOC, a GCS score of <15, focal neurology, and a skull fracture. Fortunately, the presence of these clinical signs and symptoms in an athlete would warrant physician referral based on the recommendations made in the National Athletic Trainers'' Association position statement on sport-related concussion and other recommendations for on-field management of head trauma.^1,2,8 Even though headache and vomiting were not predictive of ICH, documenting these and other signs and symptoms of mild head trauma should be part of the ATC''s assessment protocol.^1,12,13 By quantifying the number of signs and symptoms present as well as the frequency and/or duration of these signs and symptoms, the ATC can track the recovery of the athlete and use the information for referral if the athlete does not demonstrate improvement. In addition, the ATC should use age-appropriate adjunct assessments, including neurocognitive testing^7,14–18 (traditional pen-and-paper neuropsychological tests, ImPACT [Immediate Postconcussion Assessment and Cognitive Testing, University of Pittsburgh Medical Center, Pittsburgh, PA], ANAM [Automated Neuropsychological Assessment Metrics, National Rehabilitation Hospital Assistive Technology and Neuroscience Center, Washington, DC], Concussion Resolution Index [HeadMinder Inc, New York, NY], Standardized Assessment of Concussion [CNS Inc, Waukesha, WI]) and postural stability testing¹⁸ to aid in the decision-making process.The findings of Dunning et al³ provide insight into specific risk factors the ATC should look for when evaluating minor head trauma in children and adolescents. The presence of any of the significant predictors should warrant immediate referral. The authors also acknowledge that other signs and symptoms (eg, dizziness, drowsiness, confusion) could be predictive of ICH; however, these factors had not been adequately investigated in the pediatric literature identified for this meta-analysis and therefore were not included. This factor, along with the variability in the inclusion criteria, timing of CT scans, and differences in the ICH definitions in the individual studies are limitations of this meta-analysis. Another potential limitation regarding the predictive value of the headache variable to ICH stems from a lack of information regarding the severity of the headaches reported in the individual studies. Some evidence suggests a relationship between severe headaches and ICH¹⁹; therefore, headache severity should also be questioned during the clinical examination. Several other limitations of this meta-analysis include no listing of specific medical subject headings terms used to search the databases, not describing the duration of LOC from the various studies used, and not adequately describing or defining the specific types of focal neurology used as a correlate. However, other authors have described focal neurologic changes as including posturing and dilating pupils.²Although this meta-analysis offers medical professionals working with children and adolescents one interpretation of the evidence regarding clinical risk factors predictive of ICH, it does not provide strong enough evidence to alter the current head-injury management and CT scanning protocols for children.²⁰ Future studies should address the limitations outlined by Dunning et al³ to better determine the predictive value of various clinical signs and symptoms of minor head trauma in the pediatric population.     

Neurobehavioral phenotype in carriers of the fragile X premutation

There have been contradictory findings in the fragile X (fraX) literature about possible neurocognitive and psychological symptoms due to the fraX premutation (pM). The purpose of the present study was to investigate the relationship between CGG repeat length and neurobehavioral functioning in carriers of the fraX pM. Eighty‐five female carriers of the pM with allele sizes ranging from 59–166 were administered a comprehensive IQ test (WAIS‐III) and completed a questionnaire designed to measure psychopathology (Symptom Checklist (SCL)‐90‐R). No relationship between allele size and cognition was identified. A significant negative relationship between allele size and age was found, as well as a positive relationship between allele size and depression. Follow‐up analyses separating small and large allele sizes (below and above 100 CGG repeats) indicated that individuals with larger allele sizes scored significantly higher on the Interpersonal Sensitivity and Depression subscales of the SCL‐90‐R. Despite the limitation of few individuals with high CGG repeat lengths, our findings suggest that females with larger premutated alleles (≥ 100 repeats) display some clinical manifestations of fraX syndrome. © 2001 Wiley‐Liss, Inc.