Heparin Decreases in Tumor Necrosis Factor α (TNFα)-induced Endothelial Stress Responses Require Transmembrane Protein 184A and Induction of Dual Specificity Phosphatase 1

Despite the large number of heparin and heparan sulfate binding proteins, the molecular mechanism(s) by which heparin alters vascular cell physiology is not well understood. Studies with vascular smooth muscle cells (VSMCs) indicate a role for induction of dual specificity phosphatase 1 (DUSP1) that decreases ERK activity and results in decreased cell proliferation, which depends on specific heparin binding. The hypothesis that unfractionated heparin functions to decrease inflammatory signal transduction in endothelial cells (ECs) through heparin-induced expression of DUSP1 was tested. In addition, the expectation that the heparin response includes a decrease in cytokine-induced cytoskeletal changes was examined. Heparin pretreatment of ECs resulted in decreased TNFα-induced JNK and p38 activity and downstream target phosphorylation, as identified through Western blotting and immunofluorescence microscopy. Through knockdown strategies, the importance of heparin-induced DUSP1 expression in these effects was confirmed. Quantitative fluorescence microscopy indicated that heparin treatment of ECs reduced TNFα-induced increases in stress fibers. Monoclonal antibodies that mimic heparin-induced changes in VSMCs were employed to support the hypothesis that heparin was functioning through interactions with a receptor. Knockdown of transmembrane protein 184A (TMEM184A) confirmed its involvement in heparin-induced signaling as seen in VSMCs. Therefore, TMEM184A functions as a heparin receptor and mediates anti-inflammatory responses of ECs involving decreased JNK and p38 activity.     

Activation of dorsal periaqueductal gray by glycine produces long lasting hyponociception in rats without overt defensive behaviors

Electrical or glutamate stimulation of the dorsal periaqueductal gray matter (DPAG) of rats induces overt defensive behavior, such as freezing or flight, and hyponociception, while glycine and D-serine, a specific NMDA/GLY(B)-site ligand, produced only subtle defensive behavior related to risk assessment and avoidance from the open arms in the elevated plus-maze test. In order to verify whether the GLY(B) site in the DPAG could also be involved in hyponociception, glycine (GLY; 10, 20, 50, and 80 nmol/0.3 microl) and (+/-)-3-amino-1-hydroxy-2-pyrrolidone (HA966; 10 nmol/0.3 microl), a GLY(B)-site antagonist, were microinjected in rats submitted to the radiant heat-induced tail-flick test. GLY increased tail-flick latencies in a dose-dependent way. This hyponociceptive effect was completely reversed by co-administration with HA966. GLY given in the deep layer of superior colliculus did not produce changes in tail-flick latencies. Therefore, the results suggest that the activation of GLY(B) receptors in the DPAG is also involved in the hyponociception elicited by this brain area.     

Studies on the decondensation of human, mouse, and bull sperm nuclei by heparin and other polyanions

We report heparin-induced decondensation of human, mouse, and bull sperm nuclei. Decondensation did not occur if the spermatozoa were intact but only if the membranes were severely damaged by freezing and thawing or by treatment with a detergent. If a disulphide bond reducing agent (thiol) was absent, decondensation of human sperm nuclei was usually a relatively slow process, with large interindividual variation. Mouse and bull sperm nuclei did not decondense in the absence of a thiol. With a thiol relatively low concentrations of heparin induced a rapid decondensation of the sperm nuclei of all three species. The decondensation activity was not specific for heparin; other polyanions were also active, with heparin being the most effective compound. It is supposed that heparin and other polyanions induce sperm nuclear decondensation because they deplete protamines from the chromatin. Thus the negatively charged phosphate groups of the DNA are no longer opposed by positively charged protamines. Consequently the mutual repulsion of unopposed phosphate groups causes the DNA molecules to stretch, which results in an increase of the sperm nuclear volume. Since heparin and other polyanions induce decondensation under physiological pH and temperature, polyanions might also be active in the oocyte.     

Structural changes in the NH2-terminal domain of fibronectin upon interaction with heparin. Relationship to matrix-driven translocation

The effects of heparin and various related polysaccharides on the circular dichroic spectra of fibronectin and its 31-kDa NH2-terminal tryptic fragment were studied. These effects were evaluated with respect to (i) spectral features of the native proteins that are sensitive to pH denaturation and breaking of disulfide bonds, (ii) sensitivity of spectral changes to Ca2+, and (iii) the fibronectin-dependent interfacial interaction known as "matrix-driven translocation." We found that native heparin causes an attenuation of the positive CD peak at 228 nm with both the intact protein and the fragment, and causes a small but reproducible red shift in the spectrum of the fragment. All of these changes are analogous to spectral changes seen with denaturation or reduction of the proteins. In contrast to the situation with the intact protein, the heparin-induced spectral changes in the fragment were abolished in the presence of 10 mM Ca2+. Desulfation of heparin lessened or destroyed its ability to induce these changes, and carboxymethylated heparin and dextran sulfate induced different kinds of spectral alterations. Fibronectin and heparin determinants required for the induction of the characteristic spectral shift of the NH2-terminal domain corresponded to those required for matrix-driven translocation, suggesting that the associated conformational change in fibronectin plays a role in this biophysical effect.     

Anticoagulation system in animals during learning under the effects of mild magnetic field and opioid peptide opilong

Information load in Wistar rats has not affected the functional state of the anticoagulant system after 20 sessions of learning to solve a food-searching task in comparison with intact animals. Learning under the combined effect of mild magnetic field and pretreatment with five intramuscular injections of an opioid peptide opilong has significantly improved the cognitive behavior but induced an increase in coagulation, imbalance in fibrinolytic processes, and inhibition of the anticoagulation system.     

电刺激大鼠外侧缰核对延髓甩尾相关细胞的活动和甩尾反射的影响

在浅麻醉大鼠上,在延髓腹内侧结构内观察到三种具有不同放电类型的细胞,即乃尾前放电骤停的撤反应细胞,甩尾前放电骤增的给反应细胞和甩尾无关的中性细胞。电刺激外侧缰核可抑制撤反应细胞的自发放电,加强给反应细胞自发放电,从而易化两类细胞的甩尾相关反应,同时易化伤害刺激引起的甩尾反射。实验结果说明,外侧缰核对节段性防御反射有易化作用,这种易化作用可能是通过延髓内撤反应和反应细胞的协同活动而实现的。     

Hyperthyroidism changes nociceptive response and ecto-nucleotidase activities in synaptosomes from spinal cord of rats in different phases of development

Changes in transport, receptors and production of extracellular adenosine have been observed after induction of hyperthyroidism. Adenosine is associated with inhibitory actions such as reduction in release of excitatory neurotransmitters and antinociception at spinal site. In contrast, ATP acts as an excitatory neurotransmitter and produces pronociceptive actions. ATP may be completely hydrolyzed to adenosine by an enzyme chain constituted by an ATP diphosphohydrolase and an ecto-5'-nucleotidase, as previously described in the spinal cord. Thus, we now investigated the effects of the hyperthyroidism on adenine nucleotide hydrolysis in the spinal cord and verified the nociceptive response in this pathology during different phases of development. Hyperthyroidism was induced in male Wistar rats, aged 5, 60 and 330 days by daily intraperitoneal injections of L-thyroxine (T4) for 14 days. Nociception was assessed with a tail-flick apparatus. Rats starting the treatment aged 5 days demonstrated a significant increase in ADP and AMP hydrolysis and increased tail-flick latency (TFL). In contrast, in the spinal cord from hyperthyroid rats aged 60 and 330 days old, the hydrolysis of ATP, ADP and AMP were significantly decreased. Accordingly, the tail-flick latency was decreased, indicating a hyperalgesic response. These results suggest the involvement of ecto-nucleotidases in the control of the hyperthyroidism-induced nociceptive response in rats at distinct developmental stages.     

Release of Ca2+ ions from the sarcoplasmic reticulum of skeletal muscle induced by heparin. Relation between the Ca2+ release caused by Ca2+ ions and caffeine

Using a Ca2+-selective electrode and Quin 2 and chlortetracycline fluorescence, a Ca2+ release from terminal cysterns of skeletal muscle sarcoplasmic reticulum under effects of heparin, caffeine and Ca2+ has been studied. It was shown that Ca2+ release induced by heparin is insensitive to the blockers of Mg2+-dependent system of Ca2+-induced Ca2+ release, i.e., Mg2+, tetracaine and dimethylsulfoxide. Preliminary release of Ca2+ in the presence of caffeine, which activates Mg2+-dependent Ca2+ release, does not prevent the heparin-induced Ca2+ release. At the same time, after Ca2+ release caused by Ca2+ in a Mg2+-independent system, heparin cannot cause additional efflux of Ca2+. It has been shown that the heparin-induced release of Ca2+ diminishes with a decrease in a decrease in Ca2+ concentration. This effect is less pronounced in the presence of Na+ than with K+. The data obtained suggest that sarcoplasmic reticulum terminal cysterns contain two systems of Ca2+-induced release of Ca2+, i.e., a Mg2+-dependent, caffeine-sensitive and a Mg2+-independent heparin-sensitive ones. The mechanism of activation of both systems by caffeine and heparin consists, in all probability, in their increased affinity for Ca2+.     

The biochemical and behavioral effects of phospholipase A2 and morphine microinjections in the periaqueductal gray of the rat

In order to characterize the in vivo action of phospholipase A2 (PLA2) on opiate receptors and opiate-induced behaviors, the effects of injections of PLA2 into the periaqueductal gray region (PAG) of the rat were assessed on free fatty acid (FFA) release, opiate-binding levels, and morphine-induced behaviors. Rats received bilateral PAG injections of 2 micrograms of PLA2 while anesthetized. One hour later, regions around the cannulae tracts in PLA2-treated rats contained over 2.5 times more FFA than saline-injected controls, and 3H-dihydromorphine binding was reduced on average more than 70%. In another series of experiments, conscious rats were given 2 micrograms of PLA2 prior to 10 micrograms of morphine through cannulae chronically implanted into the PAG. PLA2 did not significantly attenuate morphine-induced analgesia as measured by the tail-flick test to radiant heat, but did prevent the explosive motor behavior observed following morphine injections alone. PLA2 by itself did not induce analgesia, but did cause explosive motor behavior 2 hr after the injections. Neither lysophosphatidylcholine nor trypsin resulted in motor seizures following PAG injections. It was concluded that the behavioral effects of PLA2 result from the unique properties of the enzyme, rather than generalized membrane damage, and that the opioid sites and mechanisms that mediate analgesia are different from those associated with explosive motor behavior.     

Central antinociceptive effects of lysine-vasopressin and an analogue

Vasopressin (VP) neurons project to extrahypothalamic sites involved in pain perception, including the substantia gelatinosa of the spinal cord as well as the trigeminal and vagus nerves. Previous studies have reported antinociceptive activity following intracerebroventricular (ICV) or subcutaneous (SC) VP injections (16–100 μg) on the tail-flick test while hyperalgesia has been observed in rats either genetically deficient in VP or treated with antisera to VP. The present study investigated whether nanogram (ng) doses of lysine-vasopressin (LVP) and a VP analogue with prolonged activity increased tail-flick latencies and flinch-jump thresholds following ICV or SC injections. LVP (150 and 500 ng, ICV) significantly increased tail-flick latencies while the analogue 1-deamino-(8-Lys-N^?-(Gly-Gly-Gly))-VP (500 ng, ICV) produced more powerful and prolonged analgesia. In contrast, latencies were not increased by SC injections of LVP (150–1500 ng). Further, flinch-jump thresholds were affected minimally by either ICV or SC LVP injections. These data suggest a role for VP in pain modulation and a central site of this action.     

Effects of stress agents and heparin administration on hematological parameters in Wistar rats

In chronic experiments in Wistar rats, the behavioral and hematological effects of the following stress factors were investigated: learning in complex maze and five multiple injections of the physiological saline (0.85%). Increasing of the erythrocyte volume and the contents of hemoglobin per erythrocyte in saline-induced groups and naive rats were observed after the learning. Moreover, the level of corticosterone in plasma of these rats was high. While in heparin-pretreated animals (unfractioned heparin, 64 and 640 IU/kg once per day, i.m., 5 days) these markers of stress are not revealed. The speed and efficiency of learning, behavior organization were significantly better in heparin pretreated rats than in naive and saline-induced groups. In heparin treated rats, a few types of unconditioned responses may be observed suggesting an anxiety or fear. We suppose that, after injections of heparin, complicated biochemical modifications of the rat organism that cause harmonization of inhibiting and excitatory processes of central nervous system, take place.     

Amphetamine-induced aggression is enhanced in rats pre-treated with the anabolic androgenic steroid nandrolone decanoate

Aggression is one of the most commonly reported psychiatric side effects among anabolic-androgenic steroids (AAS) users. Furthermore, anecdotal stories say the aggression is even more profound when a current, or former, AAS-user consumes other drugs of abuse such as amphetamine and alcohol. In the present study, we examined the effect of amphetamine on defensive reactivity and defensive aggression in Sprague-Dawley rats after chronic AAS treatment (daily intramuscular [i.m.] injections with 15 mg/kg nandrolone decanoate [ND] for 14 days). Defensive reactions in rodents occur in response to a real threat, but also to perceived provocation, for example, elicited by innocuous stimuli as reaction towards the experimenter. The defensive reactivity and aggression test employed in this study evaluates each rat's reaction towards four different stimuli (I: approach of a rod; II: startle to an air puff; III: poking with a rod at the flanks, and IV: capturing with a gloved hand) at two different occasions. Immediately following the ND treatment period, no change in the defensive response was found. Nevertheless, an amphetamine challenge given 3 weeks after the last ND or vehicle injection induced a marked increased defensive aggressive response in the ND, compared to vehicle-pre-treated rats. Both ND- and vehicle-pre-treated rats receiving amphetamine were found to be more aggressive than comparable groups receiving a saline injection. It can be concluded that pre-treatment with ND modulates the behavioral response to amphetamine and induces long lasting changes in the behavioral response.     

Tail-flick latency and self-mutilation following unilateral deafferentation in rats

Unilateral deafferentation induced by transection of the C(4)-C(8) dorsal roots of spinal cord, followed by a complex of abnormal self-mutilating behavior, is interpreted as an animal model of chronic nociception. The objective of our study was to test the differences in tail-flick latency between intact control and unilaterally deafferented animals and to assess the changes in their acute nociceptive sensation. The initial hypothesis was that deafferentation-induced painful sensation might cause stress-induced analgesia that should be manifested as prolonged tail-flick latency. The experiment was carried out on 11 male and 10 female adult Wistar rats. The tail-flick latency was repeatedly measured over a period of 10 consecutive weeks both in the preoperative baseline period and following multiple cervical dorsal rhizotomy. Contrary to our hypothesis, unilateral deafferentation was followed by a significant shortening of the tail-flick latency both in males and females. In deafferented animals, compared to the controls, variations of tail-flick latency were reduced. In individual animals after deafferentation, concurrent dynamic changes were observed in self-mutilating behavior, in a loss and regaining of body weight, and in tail-flick latency. Our data suggest that changes in tail-flick latency may be interpreted in terms of central sensitization and that tail-flick latency might be considered as a useful marker of chronic nociception.     

Heparin-induced leukocytosis requires 6-O-sulfation and is caused by blockade of selectin- and CXCL12 protein-mediated leukocyte trafficking in mice

Leukocytosis refers to an increase in leukocyte count above the normal range in the blood and is a common laboratory finding in patients. In many cases, the mechanisms underlying leukocytosis are not known. In this study, we examined the effects, the structural determinants, and the underlying mechanisms of heparin-induced leukocytosis, a side effect occurring in 0.44% of patients receiving heparin. We observed that heparin induced both lymphocytosis and neutrophilia, and the effects required heparin to be 6-O-sulfated but did not require its anticoagulant activity. Cell mobilization studies revealed that the lymphocytosis was attributable to a combination of blockage of lymphocyte homing and the release of thymocytes from the thymus, whereas the neutrophilia was caused primarily by neutrophil release from the bone marrow and demargination in the vasculature. Mechanistic studies revealed that heparin inhibits L- and P-selectin, as well as the chemokine CXCL12, leading to leukocytosis. Heparin is known to require 6-O-sulfate to inhibit L- and P-selectin function, and in this study we observed that 6-O-sulfate is required for its interaction with CXCL12. We conclude that heparin-induced leukocytosis requires glucosamine 6-O-sulfation and is caused by blockade of L-selectin-, P-selectin-, and CXCL12-mediated leukocyte trafficking.     

An inhibitor of DNA polymerases alpha and delta in calf thymus DNA.

Most, although not all, samples of commercial calf thymus DNA were strongly inhibitory to DNA polymerase alpha; the inhibition made the DNA useless as a template for this enzyme. In a pre-assembled DNA polymerase assay mixture (minus enzyme but including activated DNA) the inhibition tended to diminish with time but at a rate that was not predictable, and some inhibition usually persisted. It was concluded that the inhibition was the result of contamination of the DNA by a heparin-like material on the basis of the following: 1) the inhibition could be reversed by treatment of the DNA with heparinase; 2) both the endogenous inhibitory effect of calf thymus DNA as well as the inhibitory effect of heparin on DNA polymerase alpha are reversed by protamine (which is known to prevent the antithrombin activity of heparin); 3) both the endogenous inhibition and inhibition by heparin are also reversed by ampholyte (which also prevents the antithrombin activity of heparin); and 4) both the endogenous and the heparin-induced inhibitory effects display the same spectrum of activity against mammalian DNA polymerases, i.e. both DNA polymerases alpha and delta are extremely sensitive whereas, DNA polymerases beta and gamma are resistant. The last result also suggests the use of heparin as a specific inhibitor of purified mammalian DNA polymerases alpha and delta, similar to the use of aphidicolin.     

Specific changes in the sodium chloride intake and activity of the taste receptor apparatus of rats administered the peptide litorin and its albumin conjugate

The role of bombesin-like peptide litorin in control of salt consumption was studied in rats. The influence of exogenous injection and binding of the endogenous litorin in the organism on the consumption of sodium chloride and sucrose solutions was analyzed in deprived rats in the process of 15-min. testing. It was found that intraperitoneal injection of 10(-6) - 10(-5) M of litorin led to an increase, and rats immunization by peptide conjugate with ox serum albumin--to a decrease of the consumption of salt solution, without changing the consumption of sucrose solution. Titres of antibodies to litorin in the plasma of rats immunized with the conjugate were higher than in the control. Intraperitoneal, subcutaneous or intranasal injections of 10(-5) M of litorin led to selective increase of gustatory responses (recorded from the chorda tympani) to tongue stimulation by salt and acid solutions not influencing the responses to quinine and sucrose in anesthetized rats. The study shows, that the peptide litorin selectively participates in the control of sodium chloride consumption. In the process of such control the increase of taste apparatus sensitivity to the sodium chloride is probably involved.     

Electrophysiological study of effects of chronic injection of caffeine on defensive reflex conditioning in grape snail

It was found that chronic injection of caffeine to grape snail increases a velocity of elaboration of conditioned defensive reflex. It was shown that after daily injection of caffeine immediately after procedure of learning the conditioned defensive reflex elaborated faster than daily injection before procedure of learning. It has been shown, that chronic injection of caffeine both in naive as well as learned snails led to depolarizing shift of membrane potential and to decrease of threshold potential of command neurons of the defensive behaviour of grape snails. It was also found that addition of caffeine in bath solution led to decrease of threshold of generation of action potential of command neurons both in intact and learned snails. The resting membrane potential of command neurons was not changed.     

Human β-endorphin: Development of tolerance and behavioral activity in rats

Human β-endorphin produced a potent antinociceptive response as estimated by the tail-flick test in rats after intraventricular injection. On a molar basis, the peptide was 21 times more potent than morphine and in addition, the peptide produced morphine-like catatonia and hypothermia. These responses were blocked by naloxone. Repeated injections of the peptide induced tolerance to analgesic response, catatonia and hypothermia. Cross tolerance to morphine was also observed.     

Basal forebrain cholinergic neurons are necessary for estrogen to enhance acquisition of a delayed matching-to-position T-maze task

Intraseptal injections of the selective cholinergic immunotoxin 192 IgG-saporin (SAP) were performed to determine whether basal forebrain cholinergic neurons are necessary for hormone-mediated enhancement of acquisition in a delayed matching-to-position (DMP) T-maze task. The DMP task is a simple spatial learning task. Studies have shown that continuous estradiol replacement enhances acquisition of the DMP task in young ovariectomized rats and that long-term treatment with either estradiol or estradiol + progesterone can prevent a deficit in DMP acquisition in old rats. In the present study, continuous estradiol replacement significantly enhanced acquisition of the DMP task by non-SAP-treated, ovariectomized rats. In contrast, neither continuous estradiol nor weekly administration of estradiol + progesterone significantly enhanced acquisition of the DMP task in rats that received intraseptal injections of either a high dose (1.0 microg) or a low dose (0.22 microg) of SAP. Animals that reached criterion were significantly impaired by rotating the maze 180 degrees regardless of treatment, suggesting that animals in all groups used extramaze cues to at least some degree to solve the task. SAP-treated animals were slightly more sensitive to increasing the intertrial delay than non-SAP-treated controls, suggesting that the SAP lesions produced a modest deficit in spatial working memory. Immunohistochemistry confirmed the loss of cholinergic neurons in specific regions of the basal forebrain of SAP-treated animals. In addition, DMP acquisition correlated significantly with ChAT activity in the hippocampus and frontal cortex. The data suggest that basal forebrain cholinergic projections are necessary for hormone-mediated enhancement of DMP acquisition.     

Regulation of cell motility, morphology, and growth by sulfated glycosaminoglycans

Due to the recent observation that heparin binds to several growth factors and cell adhesion molecules, the effect of heparin on biological processes governed by growth factors and cell adhesion molecules was investigated. Pharmacological doses of heparin were found to alter cell growth rate, cellular morphology, and cell motility. Concentrations (microgram/ml) of heparin or dextran sulfate decreased cell growth rate, but not the final cell density attained in plateau phase. The effect of heparin on cell growth rate was most pronounced when cells were cultured in low concentrations of serum. A heparin-induced decrease in cell growth rate could be reversed by addition of platelet-derived growth factor (PDGF), a heparin-binding growth factor. Heparin altered the morphology of all cell lines studied to various degrees. The effect of heparin on cell morphology was quantitated by measuring the heparin-induced change in cell surface area. HT-1080 and HeLa cells nearly doubled in surface area upon exposure to 10 micrograms/ml heparin. Since several heparin-binding cell adhesion proteins mediate both cell spreading and cell migration, the influence of heparin on cell migration was investigated with an improved version of the phagokinetic track technique. Low concentrations of heparin and dextran sulfate were found to increase the rate of cell migration in a dose-dependent fashion. Since the quantitative effect of heparin on cell growth rate, morphology, and migration depends on the cell line studied, it is suggested that three separate phenomena may be involved. The results presented indicate a central role for sulfated glycosaminoglycans in the control of both cell growth and cell-cell interactions.