Current radioactive fallout contamination along a trans-European gradient assessed using terricolous lichens

Lichens are considered to be good indicators of contamination of the terrestrial environment. In this study, we investigated the level of ¹³⁷Cs and ⁴ K accumulated by Cladonia arbuscula and Stereocaulon alpinum along a longitudinal gradient from northern Norway, across Sweden to southern Poland. Additionally, we compared isotope contents between the selected lichen species, and investigated the correlation of the ¹³⁷Cs content accumulated by C. arbuscula with ¹³⁷Cs fallout after the Chernobyl disaster. The activity of ¹³⁷Cs varied from 3.58 Bq kg^-1 to 559 Bq kg^-1 for S. alpinum, and from 1.18 Bq kg^-1 to 130 Bq kg^-1 for C. arbuscula. The activity of ⁴ K ranged from 114 Bq kg^-1 to 341 Bq kg^-1 for S. alpinum and from 27.2 Bq kg^-1 to 314 Bq kg^-1 for C. arbuscula. The ¹³⁷Cs content did not differ between C. arbuscula and S. alpinum; however, the difference between species was significant for ⁴ K accumulation. The activity of ¹³⁷Cs in C. arbuscula was significantly correlated with deposition from 1986. Based on our findings we created a spatial map of ¹³⁷Cs activity in lichens measured 30 years after the event that was the primary source of this isotope. We showed that C. arbuscula can be used to assess contamination and create interpolation maps of radionuclide deposition, even if the primary deposition took place many years ago.

Impact of distance from the glacier on the content of 137Cs and 90Sr in the lichen Cetrariella delisei

The Arctic region is substantially a pristine area, but this unique part of the globe has also been contaminated by anthropogenic radioactive nuclides, and now there is still measurable activity of anthropogenic isotopes, even though more than 50 years have passed since the main source. Radionuclides in the Arctic, especially ⁹⁰Sr have seldom been studied despite their considerable environmental importance. This manuscript covers the results of ⁹⁰Sr and ¹³⁷Cs measurements in soil and lichen Cetrariella delisei collected from the Svalbard in 2012. In both lichen thalli and surface soils high activities of ⁹⁰Sr and ¹³⁷Cs were recorded and ranged between 3.69 and 28.1 Bq kg^{-1 90}Sr and 5.38-280.1 Bq kg^-1137Cs in thalli and between 4.53 and 12.78 Bq kg^-1dw ⁹⁰Sr and 60.6-426.1 Bq kg^-1dw ¹³⁷Cs in surface soil layer. The activity of ⁹⁰Sr and ¹³⁷Cs in lichen thalli was influenced by distance from the glacier. This showed that during radionuclide biomonitoring of particular area with the use of lichens, it is important to take into account influence of environmental variability on radionuclides contents.

Matrix metaloproteinases activity during the evolution of hypoxic-ischemic brain damage in the immature rat. The effect of 1-methylnicotinamide (MNA)

Matrix metalloproteinases (MMPs) are a family of proteolytic enzymes that degrade the extracellular matrix and carry out key functions during brain development. Apart from a physiological role, excessive activation of MMPs in brain tissue has been postulated to represent a pathway for cell death arising from ischemia. To evaluate the possible involvement of MMPs in the perinatal brain asphyxia, we exposed 7-day-old rats to hypoxia-ischemia (HI). Unilateral HI was administered by ligation of the common carotid artery followed by hypoxia (7.4% O2/92.6% N2) for 65 minutes. This insult is known to produce brain damage confined to the cerebral hemisphere ipsilateral to the arterial occlusion in > 90% of animals. HI resulted in a significant elevation of MMP-2 and MMP-9 activity in the ipsilateral forebrain. The maximum activation was found at 48 hours and 7-14 days after the insult. These results suggest that early and late induction of MMPs may play a role in neuronal death as well as in repair processes. The treatment of animals subjected to HI with 1-methylnicotinamide (MNA), the anti-inflammatory agent, led to the inhibition of MMP-9 in an acute phase of ischemic damage and to the activation of MMP-2 in the later stages after injury. The timing of MMPs modulation by MNA may indicate its possible therapeutic implications.

Decrease of PKC precedes other cellular signs of calpain activation in area CA1 of the hippocampus after transient cerebral ischemia

One of the specific features of severe brain injury is an activation of calcium-dependent proteolysis by calpains. We have observed a significant increase of activity as early as 3 h after the insult in a well defined model of delayed ischemic neuronal death in gerbil hippocampus. At 24 h, the enzymatic activity transiently normalized, then increased again, following the place and time of selective cellular death in the CA1 region of hippocampus. The enhanced postischemic proteolysis resulted in concomitant cleavage of calpain-specific endogenous substrates like protein kinase C (PKC), fodrin and microtubule-associated protein-2 (MAP2). These effects were also time-dependent and restricted to the vulnerable, CA1 pyramidal neurons-containing the dorsal part (DP) of the hippocampus. We have also characterized the postischemic changes of six different isoforms of PKC. The vulnerable dorsal part of the hippocampus, but not its relative resistant abdominal part (AbP), exhibited a loss of PKCalpha, beta, gamma, and delta isoforms as early as 3 h after ischemic insult. However, at this time, solely in the soluble fraction of homogenate. Later (72 h), a further loss of the enzyme proteins, comprised the particulate fraction as well and resulted in an about 50% decrease of total PKCs in the vulnerable DP region. In the case of PKCalpha, the immunostaining pattern showed, in addition to the disappearance of the enzyme from the injured area, an extensive translocation into nuclei of the survived, ischemia-resistant neurones. The early decreases of PKC isoforms in the cytosol paralleled the transient calpain activation at 3h postischemia but substantially preceded the proteolysis of any other classical calpain substrates, such as fodrin and MAP2, being evidenced not earlier than 48-72 h after the insult and restricted also to the vulnerable dorsal part. In conclusion, our results of the time-dependent effects of transient global cerebral ischemia on the calpain activity, levels and localization of its several substrates suggest, that calpain-mediated proteolysis is specifically involved in the early (induction) as well as in the late (execution) phases of delayed ischemic neuronal death in the CA1 hippocampus.

Ischemia-induced modifications of protein components of rat brain postsynaptic densities

Considering that postsynaptic densities (PSD) are a functionally active zone involved in excitatory synaptic transmission we evaluated the influence of global, postdecapitative cerebral ischemia of 15 min duration on characteristic protein constituents of PSD in rats. Ischemia induced changes in the assembly and function of calcium, calmodulin-dependent kinase II (CaMKII), calpains and a novel, 85 kDa/RING3 kinase but to different extents. CaMKII is translocated toward the PSD very rapidly and extensively after the first seconds of ischemia. Concomitantly, the total phosphorylating potency of this kinase with endogenous, as well as exogenous, substrates was elevated but to a lower extent than suggested by the increased protein content. Of the two brain-specific isoforms of calpain (mu and m), only recently recognized in PSD, the proteolytically activated, 76 kDa subunit of mu-calpain was significantly down-regulated after 15 min of brain ischemia. However, this effect is coupled with the decline of fodrin, the only calpain substrate that has been demonstrated to be a calpain target in vivo. Together, these findings may suggest that calpains, primarily activated by calcium in ischemic PSD, are subsequently degraded. A new observation is the relatively high phosphorylating activity of a novel, 85 kDa/RING3 kinase in the PSD which independently of other kinase systems, was greatly enhanced after ischemia. These data provide evidence that the signal transduction processes could be rapidly altered by short-term (15 min) brain ischemia due to changes in the assembly and function of PSD connected proteins.

Dual response of calpain to rat brain postdecapitative ischemia

Calpains, Ca(2+)-dependent neutral proteinases (microM and mM Ca(2+)-sensitive), and their endogenous inhibitor calpastatin were examined in rat brain. Specific activity of m-calpain exceeded almost 10 times that of mu-calpain, and the both isoforms of calpain together with calpastatin were mainly located in the soluble fraction of homogenate. Acute postdecapitative ischemia of 15 min duration resulted in a gradual, time-dependent decrease of total mu-calpain activity (to 60% of control values) and in the moderate elevation of calpastatin activity (by 28%). The decrease of total mu-calpain activity coincided with its remarkable increase (above 300% of control values) in particulate fraction. In the case of m-calpain, the only observed effect of ischemia was its redistribution and, as a consequence, the elevation of activity in particulate fraction. The accumulation of breakdown products, resulting from calpain-catalyzed proteolysis of fodrin (as revealed by Western blotting) indicated activation of calpain under ischemia. The findings suggest that this rapid activation involves partial enzyme translocation toward membranes, and is followed (at least in acute phase) by mu-calpain downregulation and increased calpastatin activity.

Expression of Ca2+-dependent (classical) PKC mRNA isoforms after transient cerebral ischemia in gerbil hippocampus

Cerebral ischemia is known to modify the expression of genetic information in the brain. To complement this knowledge, in the present study we have estimated the expression of calcium- and phospholipid-dependent (classical) protein kinase C (c PKC) isoform mRNAs (alpha, beta1 and gamma) at different time following ischemia. Forebrain cerebral ischemia was performed on Mongolian gerbils by 5 minutes bilateral occlusion of common carotid arteries. At the pointed time the cytoplasmic RNA was extracted from hippocampus and the expression of PKC mRNA quantified by RT PCR technique using GAPDH expression as an internal standard. Results indicate that only one gamma isoform of cPKC mRNA expression becomes significantly modified in postischemic hippocampus. A transient increase up to 145% of control within the first 3 h was followed by its decline to 60-65% at a longer recirculation period. This lowered levels returned back to control at 72 h postischemic recovery. This result indicates that gamma PKC could be particularly sensitive to ischemic insult and would react in accordance with the other early signals determining ischemic outcome.

Phosphorylation of protein kinase C substrate proteins in rat hippocampal slices--effect of calpain inhibition

Incubation of the acutely dissected rat hippocampal slices in calcium-containing media resulted in spontaneous activation-translocation of classical PKC isoforms and their subsequent (especially gamma-type) proteolytic degradation. These changes were blocked by calpain inhibitor MDL 28 170 in 100 microM concentration. Rat hippocampal slices were metabolically prelabelled with 32Pi and stimulated with NMDA/glycine, depolarization or phorbol dibutyrate (PDBu) treatment. The basal phosphorylation of specific PKC substrates (MARCKS, neuromodulin and neurogranin) was significantly reduced in non-stimulated slices by MDL pretreatment. In contrast, only the slices where calpain activity was inhibited responded to further NMDA or phorbol dibutyrate stimulation by a substantial increase of PKC-dependent protein phosphorylation. It is concluded that the PKC phosphorylation system is severely affected by non-specific activation and a subsequent, calpain-dependent proteolysis in the acutely prepared hippocampal slices. Calpain inhibition by 100 microM MDL partially prevented these changes and increased stimulus-dependent phosphorylation of PKC-specific protein substrates.

Cyclic enkephalin analogues with exceptional potency and selectivity for delta-opioid receptors

Superpotent and highly delta-opioid receptor selective cyclic peptides of the general formula H-Tyr-c[D-Pen-Gly-Phe(p-X)-Pen]-Phe-OH (where X = hydrogen or halogen) have been synthesized. In the binding assays the most selective and most potent compound is the p-bromophenyl-alanine-4 analogue (IC50 value = 0.19 nM, selectivity ratio = 21,000 for delta vs mu). In the GPI and MVD bioassays the most selective and most potent analogue is the p-fluoro-substituted analogue Tyr-[D-Pen-Gly-Phe(p-F)-Pen]-Phe-OH. In the MVD assay it has an exceptionally low IC50 value of 0.016 nM and a delta vs mu selectivity ratio of 45,000.

Para-substituted phenylalanine-4 analogues of [L-Ala3]DPDPE: highly selective delta opioid receptor ligands

Several para-substituted Phe4 analogues of the delta 1-selective antagonist [L-Ala3]DPDPE (DPADPE) were prepared and evaluated for their brain-binding and in vitro pharmacological effects. Unlike the p-haloPhe4 analogues of DPDPE and the deltorphins, similar analogues of DPADPE with electron-withdrawing groups substituted at the para-position of the Phe4 aromatic ring did not all have increased potency and selectivity for delta opioid receptors, but all retained high potency and selectivity for delta opioid receptors greater than DPDPE.

The third extracellular loop of the human delta-opioid receptor determines the selectivity of delta-opioid agonists

In the present study, we replaced the third extracellular loop of the human delta-opioid receptor with that of the human mu-opioid receptor. A modified polymerase chain reaction overlap extension method was used to achieve the exact splicing in the chimera to show the importance of the extracellular loop in ligand binding without interference from transmembrane substitutions. The replacement of the third extracellular loop did not alter the affinity of [3H]diprenorphine but caused a dramatic decrease in the affinity of both the delta-selective peptide agonists cyclo[D-Pen2,4'Cl-Phe4,D-Pen5]enkephalin and deltorphin II and the delta-selective nonpeptide agonists SNC 121 and (-)TAN 67. The affinities of the mu-selective peptide agonist [D-Ala2-MePhe4-Gly-ol5]enkephalin and the mu-preferring nonpeptide agonist morphine were not affected. Site-directed mutagenesis studies show that the mechanism of ligand recognition might be different for each structural class of opioid ligands.

The use of topographical constraints in receptor mapping: investigation of the topographical requirements of the tryptophan 30 residue for receptor binding of Asp-Tyr-D-Phe-Gly-Trp-(N-Me)Nle-Asp-Phe-NH2 (SNF 9007), a cholecystokinin (26-33) analogue that binds to both CCK-B and delta-opioid receptors

The cholecystokinin (26-33) [CCK (26-33)] octapeptide analog Asp-Tyr-D-Phe-Gly-Trp(N-Me)-Nle-Asp-Phe-NH2 (SNF 9007) is a potent and selective ligand for both the CCK-B and delta-opioid receptors. Pharmacological studies of SNF 9007 suggest a relationship between the ligand requirements of CCK-B and delta-opioid receptors, which further implies a possible structural relationship between these receptors. We have utilized topographical constrainment of the important Trp30 residue to investigate structural features of SNF 9007 that would distinguish between binding requirements in this region for the CCK-B and delta-opioid receptors. Thus, the four optically pure isomers of beta-MeTrp were substituted for L-Trp30 of SNF 9007. Receptor binding results suggest that the preferred topography of the Trp30 residue for CCK-B receptor binding may be the 2S,3S (erythro-L) configuration whereas for the delta-opioid receptor it may be the 2S,3R (threo-L) configuration. Molecular modeling studies of these ligands further support the recently revised receptor-bound model for CCK-B octapeptide ligands (Kolodziej et al. J. Med. Chem. 1995, 38, 137-149) and are in good agreement with the DPDPE-delta opioid receptor "template" model (Nikiforovich et al. Biopolymers 1991, 31, 941-955).

delta-Opioid receptor: the third extracellular loop determines naltrindole selectivity

Human delta/mu-opioid receptor chimeras were constructed to determine the role of the second and third extracellular loops in alkaloid ligand selectivity. Exchanging the third extracellular loop of the delta-opioid receptor with that of the mu-opioid receptor dramatically decreased the affinity of naltrindole, but not that of morphine. The results suggest that different domains of the opioid receptor are involved in the binding of naltrindole and morphine.

Autophosphorylation as a possible mechanism of calcium/calmodulin-dependent protein kinase II inhibition during ischemia

Cardiac arrest induced rat brain ischemia of 15 min duration produces a rapid and profound decrease in activity of calcium/calmodulin stimulated protein kinase (CaM-KII). In contrast to that, the total amount of enzyme protein remains stable as revealed by Western blotting (alpha subunit specific) analysis. Ischemic insult also results in translocation of the enzyme toward plasmatic membranes, reducing its content in soluble (cytosolic) fraction down to 7% with respect to 50% of control. The qualitatively similar translocation can be achieved by autophosphorylation of the control enzyme in vitro. Moreover, severely reduced response of immunoprecipitated enzyme to autophosphorylation observed after ischemia ex vivo probably reflects the higher level of its endogenous phosphorylation during the insult. The results strongly suggest that among various possible mechanisms of postischemic CaM-KII inhibition the most probable would be that involving abnormal or irreversible phosphorylation of the enzyme molecule. It would consequently block or inhibit the autophosphorylation/dephosphorylation cycle of endogenous CaM-KII interconversion necessary for its full catalytic activity.

Brain ischaemia transiently activates Ca2+/calmodulin-independent protein kinase II

The activity of Ca2+/calmodulin-dependent protein kinase II (CaM-KII) during short-term global ischaemia was investigated in the gerbil brain hippocampus and cortex. Ischaemia of 0.5 min duration significantly stimulated Ca(2+)-independent 'autonomous' activity, indicating activation of the first step of intramolecular enzyme phosphorylation just after ischaemia has developed. Prolongation of the ischaemic period up to 5 min inhibited both Ca(2+)-dependent and, to a lesser extent, Ca(2+)-independent activities of CaM-KII. These last events coincide with an extensive translocation of CaM-KII protein from the soluble to the membranous fraction. In effect, in spite of inhibition of total CaM-KII activity, its Ca(2+)-independent, persistently active component can still remain more abundant at specific membrane regions.

Changes of Ca2+/calmodulin-dependent protein kinase-II after transient ischemia in gerbil hippocampus

Transient cerebral ischemia induces, besides delayed neurodegeneration in selected brain structures, a number of early responses which may mediate ischemic injury/repair processes. Here we report that 5 min exposure to cerebral ischemia in gerbils induces a rapid inhibition and subsequent translocation of Ca2+/calmodulin-dependent protein kinase II (CaMKII). These changes were partially reversible during a 24 h post-ischemic recovery. Concomitantly the total amount of the enzyme protein, as revealed by Western blotting (alpha-subunit specific), remained stable. This is consistent with our previous hypothesis, that the mechanism of ischemic CaMKII down-regulation involves a reversible posttranslational modification-(auto)phosphorylation, rather than the degradation of enzyme protein. The effectiveness of known modulators of post-ischemic outcome in counteracting CaMKII inhibition was tested. Three of these drugs, namely dizocilpine (MK-801), N-nitro-L-arginine methyl ester (L-NAME) and ginkgolide (BN52021), all significantly attenuated the enzyme response to ischemia, whereas an obvious diversity in the time-course of their actions implicates different mechanisms involved.

Is calpain activity regulated by membranes and autolysis or by calcium and calpastatin?

Although the Ca(2+)-dependent proteinase (calpain) system has been found in every vertebrate cell that has been examined for its presence and has been detected in Drosophila and parasites, the physiological function(s) of this system remains unclear. Calpain activity has been associated with cleavages that alter regulation of various enzyme activities, with remodeling or disassembly of the cell cytoskeleton, and with cleavages of hormone receptors. The mechanism regulating activity of the calpain system in vivo also is unknown. It has been proposed that binding of the calpains to phospholipid in a cell membrane lowers the Ca2+ concentration, [Ca2+], required for the calpains to autolyze, and that autolysis converts an inactive proenzyme into an active protease. Recent studies, however, show that the calpains bind to specific proteins and not to phospholipids, and that binding to cell membranes does not affect the [Ca2+] required for autolysis. It seems likely that calpain activity is regulated by binding of Ca2+ to specific sites on the calpain molecule, with binding to each site eliciting a response (proteolytic activity, calpastatin binding, etc.) specific for that site. Regulation must also involve an, as yet, undiscovered mechanism that increases the affinity of the Ca(2+)-binding sites for Ca2+.

Design, synthesis, and biological properties of highly potent cyclic dynorphin A analogues. Analogues cyclized between positions 5 and 11

We have recently reported the synthesis of several cyclic disulfide bridge-containing peptide analogues of dynorphin A (Dyn A), which were conformationally constrained in the putative address segment of the opioid ligand. Several of these analogues, bridged between positions 5 and 11 of Dyn A1-11-NH2, exhibited unexpected selectivities for the kappa and mu receptors of the central over the peripheral nervous systems. In order to further investigate the conformational and topographical requirements for the residues in positions 5 and 11 of these analogues, we have synthesized a systematic series of Dyn A1-11-NH2 analogues incorporating the sulfydryl containing amino acids L- and D-Cys and L- and D-Pen in positions 5 and 11, thus producing 16 cyclic peptides. In addition, Dyn A1-11-NH2, [D-Leu5]Dyn A1-11-NH2, and [D-Lys11]Dyn A1-11-NH2 were synthesized as standards. Several of these cyclic analogues, especially c[Cys5,D-Cys11] Dyn A1-11-NH2, c[Cys5, L- or D-Pen11]Dyn A1-11-NH2, c[Pen5, L-Pen11]Dyn A1-11-NH2 and c[Pen5, L- or D-Cys11]Dyn A1-11-NH2, retained the same affinity and selectivity (vs the mu and delta receptors) as the parent compound Dyn A1-11-NH2 in the guinea pig brain (GPB). These same analogues and most others exhibited a much lower activity in the guinea pig ileum (GPI), thus leading to centrally vs peripherally selective peptides, but showed a different structure-activity relationship than found previously. In a wider scope, this series of analogues also provided new insights into which amino acids (and their configurations) may be used in positions 5 and 11 of Dyn A analogues for high potency and good selectivity at kappa opioid receptors. The results obtained in the GPB suggest that requirements for binding are not the same for the kappa, mu, or delta central receptors.

[N-methylnorleucine-(28,31)]cholecystokinin-(26-33) (SNF 8702) activity at a cloned rat CCKB receptor

[N-methyl-Nle 28,31)]cholecystokinin-(26-33) (SNF 8702) is a highly selective ligand for the CCKB type of receptor present in the vertebrate central nervous system. Radioligand binding data showing that SNF 8702 binding affinity is reduced by the GTP analog guanylyl-imidodiphosphate suggest that SNF 8702 is an agonist but the ability of SNF 8702 to activate CCKB receptors has not been demonstrated. The present study shows that SNF 8702 is a highly potent agonist at rat CCKB receptors expressed on COS-7 cells and that these receptors are coupled to the mobilization of intracellular calcium. The A50 measured for SNF 8702-induced calcium mobilization (66 pM) is over 6-fold less than that of cholecytstokinin octapeptide (420 pM). Data are also presented showing that SNF 8702 has high binding affinity for these receptors with a Kd value (760 pM) consistent with previous measurements using guinea pig brain tissue preparations.

Newly discovered stereochemical requirements in the side-chain conformation of delta opioid agonists for recognizing opioid delta receptors

Topographic design of peptide ligands using specialized topographically constrained amino acids can provide new insights into the stereochemical requirements for delta opioid receptors. A highly constrained tyrosine derivative, (2S,3S)-beta-methyl-2',6'-dimethyltyrosine [(2S,3S)-TMT], was prepared by asymmetric synthesis and incorporated in [D-Pen2,D-Pen5] enkephalin (delta 1) and Deltorphin I (delta 2). The results of binding assays and bioassays showed that the two analogues (3 and 4) acted very differently at delta opioid receptors. Further pharmacological evaluations suggested that they actually interact primarily with the delta 1 and delta 2 receptor subtypes, respectively. These results, and conformational studies using NMR and computer-assisted modeling, provided insights into the different stereochemical requirements for these two delta opioid ligands to recognize the delta opioid receptor and its subtypes.

[L-Ala3]DPDPE: a new enkephalin analog with a unique opioid receptor activity profile. Further evidence of delta-opioid receptor multiplicity

To investigate delta-opioid receptor topography near the 3-position of [D-Pen2,D-Pen5]enkephalin (DPDPE), a series of small-group 3-position analogs of DPDPE have been synthesized and assayed for binding potencies and in vitro biological activities. L-Amino acid substitutions at this position are highly favored over D-amino acid substitutions, with the smallest, [L-Ala3]DPDPE (DPADPE), being the most favored in the series investigated. [L-Ala3]DPDPE is nearly as delta-potent and more delta-selective in both rat brain binding (18 nM vs [3H] [p-ClPhe4]DPDPE and mu/delta = 610) and peripheral bioassays (12 nM in the MVD and GPI/MVD = 4500) when compared to DPDPE (8.5 nM, mu/delta = 73 and 4.1 nM, GPI/MVD = 1800, respectively). Whereas DPDPE is a potent analgesic when given icv, [L-Ala3]DPDPE is only a weak analgesic. However, [L-Ala3]DPDPE has been found to antagonize DPDPE, but not Deltorphin II, in a moderately potent (pA2 = 5.7) and selective fashion in vivo. Thus, [L-Ala3]DPDPE is a fairly potent agonist at peripheral delta receptors and is a moderately potent (mixed) antagonist of delta 1 receptors in the brain. It appears that [L-Ala3]DPDPE does not interact in any significant manner with delta 2 or mu receptors in the brain.

Cyclic enkephalin analogs with exceptional potency at peripheral delta opioid receptors

A series of super potent and delta-opioid-receptor-selective cyclic hexapeptides of the general formula [formula: see text] (where X is hydrogen or halogen) has been synthesized. The unsubstituted hexapeptide formula; see text: [Phe6]DPLCE) has extremely high potency at peripheral delta opioid receptors (IC50 value in the MVD assay is 0.016 nM) and in bioassays is the most selective compound in this series. The introduction of halogens in the phenyl ring of phenylalanine at position 4 led to significant changes in the selectivity and affinities at peripheral and central opioid receptors. In the binding studies, the most potent compound is the p-fluoro analog, whereas the most selective analog is the p-iodo-substituted peptide.

Syntheses, opioid binding affinities, and potencies of dynorphin A analogues substituted in positions, 1, 6, 7, 8 and 10

Structural, stereochemical, stereoelectronic and conformational requirements for biological activity of dynorphin A1-11-NH2 analogues at opioid receptors were explored by substitution of Tyr1, Arg6, Arg7, Ile8 and Pro10 with other amino acid residues. Interestingly, substitution of Tyr1 with N alpha-Ac-Tyr1, D-Tyr1, Phe1 or p-BrPhe1 led to analogues that were quite potent at kappa opioid receptors, and additional substitution of Ile8 with D-Ala8 and/or Pro10 with D-Pro10 retained high potency in brain binding assay: [N alpha-Ac-Tyr1]- (1), [D-Tyr1]-(2) [Phe1]- (3), [Phe1,D-Ala8]- (5), [-BrPhe1, D-Ala8]- (6), [Phe1, D-Pro10]- (7) and [Phe1,D-Ala8, D-Pro10]- Dyn A1-11-NH2 (8) had IC50 (nM) binding affinities of 13.2, 18.6, 1.64, 1.26, 1.84, 2.44 and 1.62 nM, respectively. The D-Phe1 analogue 4, however, was only weakly active (610 nM). All of the analogues except 4 were modestly selective for kappa vs. mu guinea pig brain opioid receptor (11- to 88-fold) and quite selective for kappa vs. delta receptors (65-576). However, all of the analogues appeared to have very low or essentially no activity in the guinea pig ileum and mouse vas deference functional bioassays, and one analogue, 5, appeared to have weak antagonist activities. On the other hand, if constrained amino acids such as beta-methylphenylalanine or 1,2,3,4-tetrahydroisoquinoline carboxylic acid, and hydroxyproline were placed in the 1 position, inactive analogues or analogues with greatly reduced potency and biological activity were obtained (compounds 12-14). It had previously been suggested that the Arg6 and Arg7 residues were critical for biological activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Coupling of adenosine receptors to adenylate cyclase in postischemic rat brain

The potential usefulness of adenosine receptor stimulation in the therapy for ischemic brain disease is dependent upon retention of adenosine receptors and their transduction mechanisms after ischemia. The receptors most clearly associated with adenosine-dependent cerebral inhibition are the A1-type (A1-AR), which work via a Gi protein to inhibit adenylate cyclase. In brain membranes from rats recovering at various times after 15 min of complete cardiac arrest-induced ischemia, the levels of A1-AR decreased temporarily to 60% of the control values. However, agonist affinities for A1-AR, as well as guanine nucleotide-sensitive high-affinity binding, remain unchanged. The significant decrease of agonist affinities to A1-AR produced by calcium depletion in control membranes was markedly attenuated after ischemia. Moreover, the A1-AR agonist-induced inhibition of cAMP production parallels the decrease in these receptor numbers. It was blocked in the postischemic membranes but reverts to control levels upon extending the recovery period to one week after the insult. It is concluded that in addition to the lowering of the number of A1-AR binding sites, the coupling of A1 receptor activation to adenylate cyclase response is inhibited after ischemia, but not at the level of receptor-Gi protein interaction.

Calcium-activated neutral protease (CANP) in normal and dysmyelinating mutant paralytic tremor rabbit myelin

Calcium-activated neutral protease (CANP) in normal and dysmyelinating mutant, paralytic tremor (PT) rabbit myelin and premyelin fractions was studied using immature (4-5 wk) or adult animals. The enzyme was estimated by determination of its catalytic activity as well as by using immunoblot analysis after SDS-PAGE separation. The presence of two forms of CANP--one activated by calcium in the micromolar concentration (mu CANP) range and the other exhibiting low calcium sensitivity in the millimolar concentration range (m-CANP)--was found in the myelin and premyelin fractions. The developmental pattern of the enzyme activity was different for each of these two enzyme isoforms depending on the fraction studied. The higher activity on CANP (both isoforms) found in PT myelin and premyelin could be related to delayed myelination and/or to the higher turnover rate of already formed myelin. These results suggest complex and specific roles for these isoenzymes during myelin formation as is discussed further in this article. Our results confirm the extensive degradation of myelin basic protein (MBP), proteolipid protein (PLP), and, to a lesser extent, the other myelin proteins by endo- and exogenous CANP. This degradation process was significantly elevated in PT rabbit myelin. Moreover as was shown by two-dimensional gel electrophoresis, calcium-controlled proteolysis in nonmutant rabbits affected the net-charge of MBP in a manner similar to that reported for PT myelin, suggesting the possible involvement of CANP in the generation of charge isomers of MBP.

Effect of brain ischemia on protein kinase C

We examined the influence of brain ischemia on the activity and subcellular distribution of protein kinase C (PKC). Two different models of ischemic brain injury were used: postdecapitative ischemia in rat forebrain and transient (6-min) cerebral ischemia in gerbil hippocampus. In the rat forebrain model, at 5 and 15 min postdecapitation there was a steady decrease of total PKC activity to 60% of control values. This decrease occurred without changes in the proportion of the particulate to the soluble enzyme pools. Isolated rat brain membranes also exhibited a concomitant decrease of [3H]phorbol 12,13-dibutyrate ([3H]PDBu) binding with an apparent increase of the ligand affinity to the postischemic membranes. On the other hand, the ischemic gerbil hippocampus model displayed a 40% decrease of total PKC activity, which was accompanied by a relative increase of PKC activity in its membrane-bound form. This resulted in an increase in the membrane/total activity ratio, indicating a possible enzyme translocation from cytosol to the membranes after ischemia. Moreover, after 1 day of recovery, a statistically significant enhancement of membrane-bound PKC activity resulted in a further increase of its relative activity up to 162% of control values. In vitro experiments using a synaptoneurosomal particulate fraction were performed to clarify the mechanism of the rapid PKC inhibition observed in cerebral tissue after ischemia. These experiments showed a progressive, Ca(2+)-dependent, antiprotease-insensitive down-regulation of PKC during incubation. This down-regulation was significantly enhanced by prior phorbol (PDBu) treatment.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of calcium-dependent neutral protease activity by fatty acids and lysophospholipids

The effect of fatty acids and lysophospholipids on calcium-activated neutral protease (CANP) was investigated. mu CANP, low calcium ion (microM concentration)-requiring CANP is more strongly inhibited by unsaturated fatty acids than is mCANP--the high calcium ion (mM concentration)-requiring form. Lysophospholipids in concentrations ranging from 10(-5) M to 10(-3) M inhibit mu CANP exclusively, whereas mCANP activity is unaffected or even slightly increased. Calpastatin decreases the activity of mCANP and, in the presence of polyunsaturated fatty acids such as docosahexaenoic acid, the inhibition is not increased. In the presence of lysophosphatidyl-ethanolamine, however, the inhibition of mCANP by calpastatin does not occur. The results indicate that fatty acids and lysocompounds liberated under different physiological and pathological conditions may modulate calcium-activated neutral protease.

Effect of propranolol upon protein and proteolytic synthesis activity in hypertrophic myocardium

The aim of the study was to investigate the effect of propranolol upon protein synthesis and degradation processes in cell-free subfractions of rat myocardium in experimental cardiac hypertrophy induced by aortic stenosis. It was found that hypertrophy stimulates incorporation of 3H-amino acids by the postmitochondrial supernatant (PMS) by 17 +/- 4% (mean +/- SE). Propranolol 10 6M inhibited protein synthesis in the control and experimental groups by 37 +/- 5% and 34 +/- 7%, respectively. At a concentration of 5 X 10 6M, propranolol-induced inhibition in each group was 74 +/- 4% and 58 +/- 5%, respectively. The activity of neutral proteases in PMS of hypertrophic hearts increased up to 255 +/- 29 IU in comparison to 154 +/- 10 IU in controls; in the cytosol it was unchanged. Propranolol had no effect upon the activity of proteases in both fractions. Activity of calcium-activated neutral proteases (CANP) remained at the same level in control and hypertrophic hearts and was unaffected by propranolol.

Metabolic studies on dysmyelinating mutant "pt" rabbit brain in vitro

"Paralytic tremor" (pt) rabbit mutant is characterized by a severe hypomyelination of the CNS, however, it is not defined if the defect in myelinogenesis is an "assembly" or "synthesis" type. In this study, we have compared the general metabolic and biosynthetic properties of the myelinating mutant brain with unaffected controls of the same age. In the brain slices of 4 wk old "pt" rabbits the incorporation of U-[14C]glucose, 6-[3H] galactose, and U-[14C] leucine into macromolecules (total lipids and proteins, galactolipids, and myelin basic protein) was substantially elevated. In isolated myelin fraction, the total reduction of the radioactivity was followed by the increased specific activity of all examined macromolecules. The myelin to homogenate specific activity ratio was similar in control and "pt" rabbits. Distribution of the label and myelin marker, cyclic nucleotide 3'-phosphodiesterase (CNP-ase) among the membranous fractions suggests the partial inhibition of myelin formation in "pt" rabbits on the step of premyelin, unilamellar membranes. 14CO2 yields derived from differently labeled glucose were used for the evaluation of the basal oxidative metabolism in "pt" brain slices. 14CO2 production from U-[14C] glucose was normal. The depolarization of the slices by 50 mM K+ stimulated glucose oxidation to a higher extent in "pt" than in control. Hexose monophosphate pathway (HMP), the route providing much of NADPH required for lipid biosynthesis, did not change significantly by mutation. The activity of glucose 6-phosphate dehydrogenase (Glc-6-P DH), an oligodendroglia enriched, HMP connected enzyme, was slightly lower in "pt" homogenates by 13-17%, whereas CNP-ase was lowered more than 30% in the same samples. All this data suggest that the capacity for the synthesis of myelin constituents is well preserved in the mutant brain and the impairment of myelogenesis is probably caused by increased elimination of already synthesized, myelin-related components.

Effect of propranolol on the activity of neutral, alkaline and acidic proteases in rat myocardium after aortic stenosis

The aim of the study was to investigate the effect of propranolol upon the activity of proteases in rat myocardium subjected to aortic stenosis. In acute heart hypertrophy induced by aortic stenosis, the activity of all three proteases in the myocardium does not change significantly. Propranolol in the concentration of 10(-6) to 2 X 10(-4) M inhibited proteolytic activity dependent on neutral proteases. The degree of inhibition increased simultaneously with increasing concentrations of propranolol. Propranolol in a low concentration (10(-6)-10(-5) M) also inhibited proteolytic activity dependent on alkaline and acidic proteases, but in higher concentration (10(-4)-2 X 10(-4) M) stimulated proteolytic activity of these enzymes 2-3 times.

A calcium-activated neutral protease in the frog nervous system which degrades rapidly transported axonal proteins

A Ca2+-activated protease (CANP) was prepared from a soluble extract of the frog nervous system and separated from an endogenous high-molecular weight inhibitor by ion exchange chromatography. Its proteolytic action was tested on rapidly transported [3H]leucine-labelled proteins from sensory axons of the sciatic nerve. The enzyme was activated at neutral pH by Ca2+ at millimolar level, and was inhibited by leupeptin and the endogenous inhibitor. Its most pronounced degradative action was exerted towards two prominent rapidly transported peaks corresponding to 82 kDa and 90 kDa proteins. Proteolysis was accompanied by the appearance of mainly 16 kDa degradation products. When newly synthesized soluble proteins of the spinal dorsal ganglia were used as substrates, the presence of CANP resulted in degradation of proteins in a broad molecular-weight range (40-200 kDa).

Metabolic disturbances of synaptosomes isolated from ischemic gerbil brain

The effects of cerebral ischemia, induced for 10 min by bilateral common carotid ligation in the Mongolian gerbil, on the brain and synaptosomal content of phospholipids and free fatty acids were measured. Moreover, the incorporation of arachidonic acid and oleoyl-CoA into phospholipids, as well as the respiration and the accumulation of 45Ca, norepinephrine, dopamine, choline, glutamate, and gamma-aminobutyrate in the ischemic brain synaptosomal fraction were studied. Analyses of lipids showed a drop in phospholipids content with concomitant increase of lysocompounds and free fatty acids in ischemic cerebral cortex. Disturbances in lipid metabolism including rapid phospholipids hydrolysis and changes in the incorporation of arachidonic acid into inositol and choline phosphoglycerides were also shown in the synaptosomal fraction of ischemic brain. The uptake of neurotransmitter substances, expressed as a percent of control value, was reduced 21% for norepinephrine, 40% for dopamine, 20% for choline, 24% for glutamate and 13% for gamma-aminobutyrate in ischemic synaptosomes. There was no significant effect of ischemia on synaptosomal respiration and 45Ca uptake in both control and high potassium media. The inhibition of neurotransmitter uptake in ischemic brain synaptosomes may be caused by the disturbance of fatty acid metabolism.

The effect of hypoxia on the metabolism of labeled glucose and acetate in the rat brain

Glucose consumption and utilization of amino acids, lipids and proteins was measured in the rat brain under normoxia and hypoxia (7%O2:93%N2). After 2 h of hypoxia the brain glucose consumption increased by over 60% of control value. In spite of this increase, the radioactivity of amino acid fraction did not increase or parallel changes of glucose radioactivity in the blood. This strongly suggested that glucose flux into amino acids remained unchanged in hypoxia. Incorporation of 14C from glucose into macromolecules was found to decrease. The above changes demonstrated that the metabolic steps which precede synthesis of amino and tricarboxylic acids were inhibited. In some experiments, the incorporation of 14C from [2-14C]-acetate into a macromolecular fraction was also measured. The amounts of radioactivity found in these fractions were unchanged under hypoxic conditions. Possible differences in the influence of hypoxia on macromolecular synthesis in different metabolic compartments of the brain are discussed.

Effect of hypoxia and ischemia on the distribution of protein in brain cellular fractions

The effect of postdecapitative ischemia (5 min at 37 degrees) and hypoxia (5% O2, 95% N2, 30 min) on the distribution of protein radioactivity in the cellular fractions of guinea pig cerebral cortex was studied. Ischemic conditions resulted in the increase of total radioactivity level and protein content in the mitochondrial fraction. In the cytosol the opposite effect was observed; the radioactivity and protein content were decreased. The amino acid analysis of microsomal proteins and the distribution of glucose-6-phosphatase activity, differing from those in control animals, suggest structural disturbances in the microsomal fraction. The results indicate a different sedimentation of proteins in the given experimental conditions. After hypoxia such effects were not observed.

Energy utilization and changes in some intermediates of glucose metabolism in normal and hypoxic rat brain after decapitation

Energy metabolism was studied in the cerebral cortex of rats during and after hypoxia induced by breathing a gas mixture of 7% O2 in N2 for 2 h. Cortical energy stores (2ATP + ADP + phosphocreatine) remained unchanged after hypoxic treatment. Lactate rose over four-fold. Pyruvate, glucose and glucose 6-phosphate concentrations also increased significantly. Metabolic activity in the cortex expressed as the utilization of high-energy phosphates 5, 10 and 30 s after decapitation was decreased by 30% after hypoxia and remained lowered for 3 h during recovery. This was accompanied by elevated glucose consumption and lactate production, suggesting that the maintenance of the energy balance after hypoxia was partly due to activation of the glycolytic pathway. During the recovery period, these metabolic abnormalities returned towards control values, but, after 6 h of recovery the high-energy phosphate utilization increased transitorily above the control values.

Effects of anoxia and depolarization on the movement of carbon atoms derived from glucose into macromolecular fractions in rat brain slices

Incorporation of U-14C-glucose into macromolecules (lipid, protein and nucleic acid fractions) of rat brain cortex slices was studied in vitro under conditions of anoxia and reoxygenation. Additionally, the influence of depolarization on control and postanoxic U-14C-glucose metabolism was investigated. Postassium-induced depolarization of the slices lowered their capacity to incorporate 14 from U-14C glucose into proteins and nucleic acids without any changes in the labeling the lipids. Fifteen and 30 minutes of anoxia depressed the rate of 14C incorporation into each of the above macromolecules was partly restored compared to the control. Excess of potassium in the medium during the reoxygenation period inhibited restoration of the synthetic capacity of the slices execpt lipids, into which incorporation of 14C was even stimulated under depolarizing conditions. The influence of anoxia and depolarization were investigated also in different classes of lipids and proteins. 14C incorporation into SDS-extractable and residual proteins and phospholipid fraction containing phosphoinositol was closest to the control during reoxygenation which suggests the relatively highest resistance of these fractions of anoxia.

Effect of calcium on brain metabolism in vitro

In attempts to distinguish between direct and indirect effects of Ca on brain cell metabolism, respiration, glycolysis, ATP, phosphocreatine, incorporation of [14C] leucine into protein, and accumulation of 45Ca was determined in brain slices. Incubation was carried out in normal salt-balanced medium, in high-potassium-or ouabain-containing medium under aerobic and anaerobic conditions. Calcium ions inhibited slightly glycolysis and respiration in normal medium and activated amino acid incorporation into proteins. Levels of ATP and phosphocreatine remained normal. The effects were interpreted as due to a stabilization of plasma membranes by Ca ions to prevent their spontaneous depolarization. Incubation of slices in high-potassium and ouabain media in aerobic conditions in the presence of Ca resulted in activation of respiration and glycolysis, decrease of ATP and phosphocreatine levels, and inhibition of amino acid incorporation into proteins. The disturbances in energy metabolism, caused by the respiration-linked Ca uptake in brain mitochondria and concomitant inhibition of oxidative phosphorylation, may lead to the inhibition of amino acid incorporation into proteins. An increase in Ca levels in the cytoplasm may only be expected in anaerobic conditions during the incubation in high-potassium and ouabain media. This is manifested by a direct inhibition of glycolysis by Ca ions and a drastic decrease of ATP and phosphocreatine in slices. The results suggest that stimulation of aerobic glycolysis and inhibition of anaerobic glycolysis by Ca may explain the unknown mechanism of the so-called "reversed Pasteur effect" of brain slices incubated in high-potassium media.