In vivo effects of triorganotins on calmodulin activity in rat brain.

We have recently reported that the triorganotins are effective inhibitors of calmodulin (CaM) activity in vitro. The present experiments were designed to investigate the in vivo effects of triorganotins, that is, tributyltin (TBT), triethyltin (TET), and trimethyltin (TMT) on rat brain CaM activity. Male Sprague-Dawley rats were treated orally with TET (0.5, 1.0, and 1.5 mg/kg/d), TMT (0.75, 1.50, and 2.50 mg/kg/d), and TBT (0.75, 1.50, and 2.50 mg/kg/d) for 6 d and they were sacrificed 24 h after the last dose. There was significant loss of body weight in the high-dose group of the organotin treated rats. Ca(2+)-ATPase activity was determined in rat brain synaptic membranes. TET and TMT inhibited Ca(2+)-ATPase in a dose-dependent manner but TBT exhibited its inhibitory effect only at the highest dose (2.5 mg/kg/d). The inhibition of Ca(2+)-ATPase by these triorganotin compounds was reversed to control levels by the addition of CaM (5-10 micrograms) exogenously. The CaM levels of the synaptic membranes of the organotin-treated rats were not significantly changed. The data presented in this paper demonstrate that triorganotins impair the Ca(2+)-pump activity by interacting with CaM, which is a regulatory protein of Ca(2+)-ATPase. The present in vivo data and our previously reported in vitro data together indicate that triorganotins associated neurotoxicity may be due to an altered CaM activity in brain.     

Inhibition of Ca2+ transport associated with cAMP-dependent protein phosphorylation in rat cardiac sarcoplasmic reticulum by triorganotins

Organotin compounds have been shown to interfere with cardiovascular system. We have studied the in vitro and in vivo effects of tributyltin bromide (TBT), triethyltin bromide (TET) and trimethyltin chloride (TMT) on the cardiac SR Ca²⁺ pump, as well as on protein phosphorylation of SR proteins, in order to understand the relative potency of these tin compounds. All the three tin compounds inhibited cardiac SR⁴⁵Ca uptake and Ca²⁺-ATPase in vitro in a concentration-dependent manner. The order of potency for Ca²⁺-ATPase as determined by IC₅₀, is TBT (2 M) > TET (63 M) > TMT (280 M). For⁴⁵Ca uptake, it followed the same order i.e., TBT (0.35 M) > TET (10 M) > TMT (440 M). In agreement with the in vitro results, both SR Ca²⁺-ATPase and⁴⁵Ca uptake were significantly inhibited in rats treated with these tin compounds, indicating that these tin compounds inhibit cardiac SR Ca²⁺ transport. cAMP significantly elevated (70–80%) the³²P-binding to SR proteins in vitro in the absence of any organotin. In the presence of organotins, cAMP-stimulated³²P-binding to proteins was significantly reduced, but the decrease was concentration dependent only at lower concentrations. The order of potency is TBT > TET > TMT. In agreement with in vitro studies, cAMP-dependent³²P bound to proteins was significantly reduced in rats treated with TBT, TET and TMT. SDS-polyacrylamide gel electrophoresis of the cardiac SR revealed at least 30 Coomassie blue stainable bands ranging from 9 to 120 kDa. Autoradiographs from samples incubated in the presence of cAMP indicated³²P incorporation in seven bands. Of these, the band corresponding to about 24 kDa molecular weight protein decreased in its intensity with the treatment of organotins. These results suggest that triorganotins may be affecting Ca²⁺ pumping mechanisms through the alteration of phosphorylation of specific proteins in rat cardiac SR.This work has been presented in part at the Annual meeting of Society of Toxicology, 1990 at Miami Beach, FL. The Toxicologist 10: 35 & 108 (1990).     

Inhaled environmental combustion particles cause myocardial injury in the Wistar Kyoto rat.

Epidemiologists have associated particulate matter (PM) air pollution with cardiovascular morbidity and premature mortality worldwide. However, experimental evidence demonstrating causality and pathogenesis of particulate matter (PM)-induced cardiovascular damage has been insufficient. We hypothesized that protracted, repeated inhalation by rats of oil combustion-derived, fugitive emission PM (EPM), similar in metal composition to selected sources of urban air PM, causes exposure duration- and dose-dependent myocardial injury in susceptible rat strains. Zinc was the only primary water-leachable/bioavailable element of this EPM. Male Sprague-Dawley (SD), Wistar Kyoto (WKY), and spontaneously hypertensive (SH) rats were exposed nose-only to EPM (2, 5, or 10 mg/m(3), 6 h/day for 4 consecutive days or 10 mg/m(3), 6 h/day, 1 day/week for 4 or 16 consecutive weeks). Two days following the last EPM exposure, cardiac and pulmonary tissues were examined histologically. The results showed that particle-laden alveolar macrophages were the only pulmonary lesions observed in all three rat strains. However, WKY rats exposed to EPM (10 mg/m(3) 6 h/day, 1 day/week for 16 weeks) demonstrated cardiac lesions with inflammation and degeneration. To further characterize the nature of EPM-associated lesions, more rigorous histopathological and histochemical techniques were employed for WKY and SD rats. We examined the hearts for myocardial degeneration, inflammation, fibrosis, calcium deposits, apoptosis, and the presence of mast cells. Decreased numbers of granulated mast cells, and multifocal myocardial degeneration, chronic-active inflammation, and fibrosis were present in 5 of 6 WKY rats exposed to EPM for 16 weeks. None of these lesions were present in WKY exposed to clean air. EPM-related cardiac lesions were indistinguishable from air-exposed controls in SD and SH rats. This study demonstrates that long-term inhalation exposures to environmentally relevant PM containing bioavailable zinc can cause myocardial injury in sensitive rats. These findings provide supportive evidence for the epidemiological associations of cardiovascular morbidity and ambient PM.     

Rat models of cardiometabolic diseases: baseline clinical chemistries,and rationale for their use in examining air pollution health effects

Abstract

Individuals with cardiovascular and metabolic diseases (CVD) are shown to be more susceptible to adverse health effects of pollutants. Rodent models of CVD are used for examining susceptibility variations. CVD models developed by selective inbreeding are shown to represent the etiology of human disease and metabolic dysfunction. The goal of this article was to review the origin and the pathobiological features of rat models of varying CVD with or without metabolic syndrome and healthy laboratory rat strains to allow better interpretation of the data regarding their susceptibility to air pollutant exposures. Age-matched healthy Sprague–Dawley (SD), Wistar (WIS) and Wistar Kyoto (WKY), and CVD-prone spontaneously hypertensive (SH), Fawn-Hooded hypertensive (FHH), SH stroke-prone (SHSP), SHHF/Mcc heart failure obese (SHHF) and insulin-resistant JCR:LA-cp obese (JCR) rat models were considered for this study. The genetics and the underlying pathologies differ between these models. Normalized heart weights correlated with underlying cardiac disease while wide differences exist in the number of white blood cells and platelets within healthy strains and those with CVD. High plasma fibrinogen and low angiotensin converting enzyme activity in FHH might relate to kidney disease and associated hypertension. However, other obese strains with known kidney lesions do not exhibit decreases in ACE activity. The increased activated partial thromboplastin time only in SHSP correlates with their hemorrhagic stroke susceptibility. Increases plasma lipid peroxidation in JCR might reflect their susceptibility to acquire atherosclerosis. These underlying pathologies involving CVD and metabolic dysfunction are critical in interpretation of findings related to susceptibility variations of air pollution health effects.     

Cardiac and thermoregulatory effects of instilled particulate matter-associated transition metals in healthy and cardiopulmonary-compromised rats

Particulate matter air pollution has been associated with cardiopulmonary morbidity and mortality in many recent epidemiological studies. Previous toxicological research has demonstrated profound cardiac and thermoregulatory changes in rats following exposure to residual oil fly ash (ROFA), a combustion-derived particulate. The response to ROFA appeared biphasic, consisting of both immediate (0-6 h) and delayed (24-96 h) bradycardia and hypothermia. Other studies have demonstrated that much of the pulmonary toxicity of ROFA was caused by its constitutive transition metals, namely, Fe, Ni, and V. This study examined the contributions of these metals to the observed cardiac and thermoregulatory changes caused by ROFA in conscious, unrestrained rats. Prior to exposure, each animal was surgically implanted with a radiotelemetry device capable of continuously monitoring heart rate, electrocardiographic, and core temperature data. Individual metals were intratracheally instilled in healthy rats (n = 4 per metal species) and in rats with monocrotaline (MCT; 60 mg/kg)-induced pulmonary hypertension (n = 10 per metal species); combinations of metals were instilled in MCT-treated rats only (n = 6 per combination of metal species). Metals were administered in doses equivalent to those found in the highest dose of ROFA used in previous studies, that is, 105 microg Fe(2)(SO(4))(3), 263 microg NiSO(4), and 245 microg VSO(4). Healthy and MCT-treated rats demonstrated similar responses to metals. Fe caused little response, whereas V caused marked bradycardia, arrhythmogenesis, and hypothermia immediately following instillation and lasting approximately 6 h. Ni caused no immediate response, but induced a delayed bradycardia, arrhythmogenesis, and hypothermia that began approximately 24 h after instillation and lasted for several days. When instilled in combination, Ni appeared to exacerbate the immediate effects of V, whereas Fe attenuated them. These data suggest that the biphasic response to instilled ROFA may result from a summation of the temporally different effects of V and Ni.     

Effects of instilled combustion-derived particles in spontaneously hypertensive rats. Part II: Pulmonary responses

A consistent association between exposure to high concentrations of ambient particulate matter (PM) and excess cardiopulmonary-related morbidity and mortality has been observed in numerous epidemiological studies, across many different geographical locations. To elicit a similar response in a controlled laboratory setting, spontaneously hypertensive rats were exposed to an oil combustion-derived PM (HP-12) and monitored for changes in pulmonary function and indices of pulmonary injury. Rats were implanted with radiotelemeters to monitor electrocardiogram, heart rate, systemic arterial blood pressure, core temperature, and activity. Animals were divided into four groups and exposed via intratracheal instillation (IT) to suspensions of HP-12 (0.0, 0.83, 3.33, and 8.33 mg/kg; control, low, mid, and high dose, respectively) in saline vehicle. Telemetered rats were monitored continuously for 4-7 days post-IT and pulmonary function was examined using a whole-body plethysmograph system for 6 h/day on post-IT days 1-7. At 24, 96, and 192 h post-IT, bronchoalveolar lavage fluid (BALF) was obtained from subsets of nontelemetered animals in order to assess the impact of HP-12 on biochemical indices of pulmonary inflammation and injury. Immediate dose-related changes in pulmonary function were observed after HP-12 exposure, consisting of decreases in tidal volume (decreasing 12-41%) and increases in breathing frequency (increasing 52-103%), minute ventilation (increasing 12-25%), and enhanced pause (increasing 113-187%). These functional effects were resolved by 7 days post-IT, although some average BALF constituents remained elevated through day 7 for mid- and high-dose groups when compared to those of the saline-treated control group. This study demonstrates significant deficits in pulmonary function, along with significant increases in BALF indices of pulmonary inflammation and injury in SH rats after IT exposure to HP-12.     

Assessing the role of ortho-substitution on polychlorinated biphenyl binding to transthyretin, a thyroxine transport protein

ortho-Substituted polychlorinated biphenyls (PCBs) make up a large part of the PCB residue found in the environment and human tissues. Our laboratory as well as others have demonstrated that ortho-substituted congeners exhibit important biological activities by aryl hydrocarbon (Ah) receptor-independent mechanisms, including changes in second messenger systems necessary for normal cell function and growth. Previous structure-activity relationship (SAR) studies on second messengers and transthyretin (TTR; prealbumin) binding focused little attention on the ortho-substituted PCBs. Disruption of thyroid hormone (TH) transport is one potentially important mechanism by which PCBs can alter TH homeostasis. A more systematic study of PCB binding to TTR, a major TH transport protein, was undertaken, in which the role of ortho-substitution was more thoroughly investigated. Results from this study indicated that the ortho-only substituted series showed significant binding activity and the relative affinities were 2,2',6 > 2,2' = 2,6 > 2 = 2,2',6, 6'. As anticipated on the basis of steric considerations, bromine was shown to be more active as an ortho-substituent where the relative affinity of 2,2'-Br was equivalent to 2,2',6-Cl. The congener patterns (di-meta-substitution in one or both rings) most closely resembling the diiodophenolic ring of thyroxine (T(4)) showed the highest binding activity. Multiple ortho-substituents were shown to decrease binding activity in such patterns. Congener patterns (single meta-substitution in one or both rings) more closely resembling the monoiodophenolic ring of T(3) showed significantly lower binding activity, consistent with the relatively low binding activity of T(3) and smaller size of chlorine compared to iodine. The addition of ortho-substitution to such patterns gave variable results depending on the substituent relationship (adjacency or nonadjacency) to the pattern. Some patterns such as 2, 2',4,4',5,5' showed good binding activity and represent common congeners in the commercial Aroclor mixtures and in the environment. The binding potencies of ortho-PCBs to TTR may represent a signature SAR that predicts specific biologic/toxic effects. In this regard, the binding potencies were consistent with measured biological activities of these PCBs, including effects on cell dopamine content, Ca(2+) homeostasis, and protein kinase C translocation in neuronal cells and brain homogenate preparations.     

Neuroendocrine actions of organohalogens: Thyroid hormones, arginine vasopressin, and neuroplasticity

Organohalogen compounds are global environmental pollutants. They are highly persistent, bioaccumulative, and cause adverse effects in humans and wildlife. Because of the widespread use of these organohalogens in household items and consumer products, indoor contamination may be a significant source of human exposure, especially for children. One significant concern with regard to health effects associated with exposure to organohalogens is endocrine disruption. This review focuses on PCBs and PBDEs as old and new organohalogens, respectively, and their effects on two neuroendocrine systems; thyroid hormones and the arginine vasopressin system (AVP). Regarding neuroendocrine effects of organohalogens, there is considerable information on the thyroid system as a target and evidence is now accumulating that the AVP system and associated functions are also susceptible to disruption. AVP-mediated functions such as osmoregulation, cardiovascular function as well as social behavior, sexual function and learning/memory are discussed. For both thyroid and AVP systems, the timing of exposure seems to play a major role in the outcome of adverse effects. The mechanism of organohalogen action is well understood for the thyroid system. In comparison, this aspect is understudied in the AVP system but some similarities in neural processes, shown to be targeted by these pollutants, serve as promising possibilities for study. One challenge in understanding modes of action within neuroendocrine systems is their complexity stemming, in part, from interdependent levels of organization. Further, because of the interplay between neuroendocrine and neural functions and behavior, further investigation into organohalogen-mediated effects is warranted and may yield insights with wider scope. Indeed, the current literature provides scattered evidence regarding the role of organohalogen-induced neuroendocrine disruption in the neuroplasticity related to both learning functions and brain structure but future studies are needed to establish the role of endocrine disruption in nervous system function and development.