Anatomical-Molecular Distribution of EphrinA1 in Infarcted Mouse Heart Using MALDI Mass Spectrometry Imaging.

EphrinA1 is a tyrosine kinase receptor localized in the cellular membrane of healthy cardiomyocytes, the expression of which is lost upon myocardial infarction (MI). Intra-cardiac injection of the recombinant form of ephrinA1 (ephrinA1-Fc) at the time of ligation in mice has shown beneficial effects by reducing infarct size and myocardial necrosis post-MI. To date, immunohistochemistry and Western blotting comprise the only experimental approaches utilized to localize and quantify relative changes of ephrinA1 in sections and homogenates of whole left ventricle, respectively. Herein, we used matrix-assisted laser desorption ionization mass spectrometry imaging (MALDI-MSI) coupled with a time-of-flight mass spectrometer (MALDI/TOF MS) to identify intact as well as tryptic fragments of ephrinA1 in healthy controls and acutely infarcted murine hearts. The purpose of the present study was 3-fold: (1) to spatially resolve the molecular distribution of endogenous ephrinA1, (2) to determine the anatomical expression profile of endogenous ephrinA1 after acute MI, and (3) to identify molecular targets of ephrinA1-Fc action post-MI. The tryptic fragments detected were identified as the ephrinA1-isoform with 38% and 34% sequence coverage and Mascot scores of 25 for the control and MI hearts, respectively. By using MALDI-MSI, we have been able to simultaneously measure the distribution and spatial localization of ephrinA1, as well as additional cardiac proteins, thus offering valuable information for the elucidation of molecular partners, mediators, and targets of ephrinA1 action in cardiac muscle. Graphical Abstract ᅟ.

The extracellular domain of myelin oligodendrocyte glycoprotein elicits atypical experimental autoimmune encephalomyelitis in rat and Macaque species.

Atypical models of experimental autoimmune encephalomyelitis (EAE) are advantageous in that the heterogeneity of clinical signs appears more reflective of those in multiple sclerosis (MS). Conversely, models of classical EAE feature stereotypic progression of an ascending flaccid paralysis that is not a characteristic of MS. The study of atypical EAE however has been limited due to the relative lack of suitable models that feature reliable disease incidence and severity, excepting mice deficient in gamma-interferon signaling pathways. In this study, atypical EAE was induced in Lewis rats, and a related approach was effective for induction of an unusual neurologic syndrome in a cynomolgus macaque. Lewis rats were immunized with the rat immunoglobulin variable (IgV)-related extracellular domain of myelin oligodendrocyte glycoprotein (IgV-MOG) in complete Freund's adjuvant (CFA) followed by one or more injections of rat IgV-MOG in incomplete Freund's adjuvant (IFA). The resulting disease was marked by torticollis, unilateral rigid paralysis, forelimb weakness, and high titers of anti-MOG antibody against conformational epitopes of MOG, as well as other signs of atypical EAE. A similar strategy elicited a distinct atypical form of EAE in a cynomolgus macaque. By day 36 in the monkey, titers of IgG against conformational epitopes of extracellular MOG were evident, and on day 201, the macaque had an abrupt onset of an unusual form of EAE that included a pronounced arousal-dependent, transient myotonia. The disease persisted for 6-7 weeks and was marked by a gradual, consistent improvement and an eventual full recovery without recurrence. These data indicate that one or more boosters of IgV-MOG in IFA represent a key variable for induction of atypical or unusual forms of EAE in rat and Macaca species. These studies also reveal a close correlation between humoral immunity against conformational epitopes of MOG, extended confluent demyelinating plaques in spinal cord and brainstem, and atypical disease induction.

Effects of acute psychosocial stress in a nonhuman primate model of allergic asthma.

Current husbandry and care guidelines for laboratory animals recommend social housing for nonhuman primates and all other social species. However, not all individuals of a social species are compatible, which can lead to psychosocial stress on certain members. Because stress affects immune responses, we undertook the present study to determine whether psychosocial stress associated with changes in the group housing of nonhuman primates affected allergic responses in a nonhuman primate model of allergic asthma. Historic records from 35 cynomolgus macaques (Macaca fascicularis) sensitive to house dust mites (HDM) and enrolled in asthma studies from 2007 to 2011 were reviewed for variations in response to aerosolized HDM that could not be explained by clinical or experimental interventions. We then compared these variations with husbandry and clinical records to determine whether the unexplained variations in responses were associated with events known to induce psychosocial stress in this species, including restructuring of social groups, temporary isolation of group members, and changes in cage or room configurations. Adult macaques in stable social groups exhibited little variation in responses to aerosolized antigen. Changes in group membership (conspecifics), cage configurations, and temporary isolation of a group member were associated with decreased responses to HDM. This attenuation lasted 2 to 3 mo on average, although some macaques showed prolonged responses. No evidence for a stress-induced increase in allergic responses was noted. These results demonstrate that acute stress in HDM-sensitive cynomolgus macaques diminishes the physiologic response to inhaled allergen.

Immunotoxicological impact of engineered nanomaterial exposure: mechanisms of immune cell modulation.

Abstract Engineered nanomaterials (ENMs) are increasingly being utilized in many consumer products and various medical applications, thereby leading to the potentiality of increased human exposures. Assessment of the adverse effects on the immune system is an important component for evaluating the overall health and safety of ENM. Tasked with eliminating pathogens and removing cancerous cells, the immune system is constantly functioning to maintain homeostasis. Small modifications to the immune system, which may occur following ENM exposure, could lead to impaired protection or an inappropriate immune response resulting in autoimmunity and damage to the host. This review seeks to survey and evaluate the current literature to better understand the impact of ENM exposure on cells critical to the innate and adaptive immune systems.

A circadian clock in murine bone marrow-derived mast cells modulates IgE-dependent activation in vitro.

Circadian rhythm is expressed in most organisms, and many functions and parameters in the immune system are associated with time-of-day. However, it is largely unknown if local circadian clocks in immune cells directly control physiological outcomes. We hypothesized that a circadian clock in murine bone marrow derived mast cells (BMMCs) modulates IgE-dependent activation in vitro. Mature BMMCs, grown from bone marrow of C57BL/6 mice, were synchronized with serum rich media (50% horse serum). Total RNA was harvested from BMMCs at 4 h intervals for up to 72 h following synchronization and expression of circadian genes (mPer1, mPer2, Bmal1, Rev-erbα, and Dbp) was measured by quantitative PCR. Serum shock synchronized expression of circadian genes (mPer2, Bmal1, Rev-erbα, and Dbp) in BMMCs. Synchronized BMMCs stimulated via the high affinity IgE receptor (FcεRI) at different time intervals display circadian rhythms in IL-13 and IL-6 mRNA expression. The expression of fcer1a gene and FcεRIα protein displayed a circadian pattern following serum shock, with mean periods of 18.9 and 28.6 h, respectively. These results demonstrate that synchronized BMMCs provide an in vitro model to study circadian mechanism(s) associated with allergic disease and that circadian oscillation of cytokine production following IgE-dependent activation is at least in part due to circadian oscillation of FcεRIα.

Nocturnal thoracoabdominal asynchrony in house dust mite-sensitive nonhuman primates.

Nocturnal bronchoconstriction is a common symptom of asthma in humans, but is poorly documented in animal models. Thoracoabdominal asynchrony (TAA) is a noninvasive clinical indication of airway obstruction. In this study, respiratory inductive plethysmography (RIP) was used to document nocturnal TAA in house dust mite (HDM)-sensitive Cynomolgus macaques. Dynamic compliance (C(dyn)) and lung resistance (R(L)) measured in anesthetized animals at rest and following exposure to HDM allergen, methacholine, and albuterol were highly correlated with three RIP parameters associated with TAA, ie, phase angle of the rib cage and abdomen waveforms (PhAng), baseline effort phase relation (eBPRL) and effort phase relation (ePhRL). Twenty-one allergic subjects were challenged with HDM early in the morning, and eBPRL and ePhRL were monitored for 20 hours after provocation. Fifteen of the allergic subjects exhibited gradual increases in eBPRL and ePhRL between midnight and 6 am, with peak activity at 4 am. However, as in humans, this nocturnal response was highly variable both between subjects and within subjects over time. The results document that TAA in this nonhuman primate model of asthma is highly correlated with C(dyn) and R(L), and demonstrate that animals exhibiting acute responses to allergen exposure during the day also exhibit nocturnal TAA.