Genetic variation in the Bribri and Cabecar Amerindians from Talamanca, Costa Rica.

A screening of more than 40 loci was performed in the Bribri and Cabecar Amerindian populations of Talamanca in Southeastern Costa Rica. Some differences were found in the distribution (presence or absence) of the variants (some of them private) of the GOT, PEPA, RH, TF and TPI loci when the results reported here were compared with those of the Bribris and Cabecars that inhabit in the Pacific side of the country. Admixture with non-Indians was detected at the ABO, ADA, and G6PD loci. The proportion of polymorphic loci (P) found were 17.1 in the Bribris and 19.4 in the Cabecars; their average heterozygosites (H) estimates were 0.039 and 0.049 respectively. Fst values (0.019 in the Bribris and 0.056 in the Cabecars) seem to indicate that random events have played important roles in the divergence of the Cabecars. Low effective population sizes of the emigrant groups to the Pacific side and probable gene flow in the case of the Bribris, could be the cause of these differences.     

Effects of periodate oxidation and glycosidases on structural and functional properties of the acetylcholine receptor and the non-receptor,peripheral ν-polypeptide (Mr 43,000)

NaIO₄ oxidation, exo- and endo-glycosidase treatments and combinations thereof have been applied to acetylcholine receptor from Torpedo marmorata in its membrane-bound and detergent-solubilised forms. The effects of these chemical and enzymatic treatments are made apparent in the electrophoretic properties of the four receptor subunits (α, β, γ and δ) and of the non-receptor polypeptides, their thermal and proteolytic susceptibility, and the steady-state and kinetic parameters of receptor-toxin complex formation. The electrophoretic pattern of the membrane polypeptides is found to depend on the redox state of the membranes, presence or absence of the non-receptor peripheral ν-peptide (M_r 43,000), pH and temperature. Very low NaIO₄ concentrations (50 μM) suffice to prevent the penetration of the ν-peptide into NaDodSO₄ polyacrylamide gels. This effect could be abolished by N-ethylmaleimide alkylation of free sulphydryl groups, suggesting the involvement of easily oxidizable vicinal thiols in the aggregation of the peptide. Higher reagent concentrations resulted in the altered mobility and subsequent splitting of the receptor subunit carrying the ligand recognition site (α, M_r 40,000) into a doublet. In contrast, NaIO₄ treatment of the detergent-solubilized receptor aggregated the α-subunit, presumably via chemical groups hidden in the membrane but exposed in detergent. Only this subunit underwent such NaIO₄-dependent changes within the concentration range in which (a) an increase of the 13-S dimeric receptor species at the expense of the 9-S monomeric form was observed and (b) half-maximal quenching of the intrinsic fluorescence occurred (～2 mM NaIO₄).Neuraminidase digestion affected exclusively the γ- and δ-subunits of the receptor, suggesting the presence of substantial amounts of sialic acid residues in these subunits. β-Glucosidase and endoglycosidase D had no effect on the electrophoretic properties of receptor and non-receptor polypeptides. Neither NaIO₄ nor neuroaminidase treatments had any effect on the thermal sensitivity of the receptor. Similarly, the equilibrium and kinetic properties of receptor-α-neurotoxin complex formation were not modified by such treatment nor was the susceptibility to tryptic digestion. The thermal and proteolytic sensitivities were affected by acid pH (5.2) and β-glucosidase treatments. The latter enzymatic digestion reduced the α-toxin binding capacity of the receptor by 35% and increased the equilibrium dissociation constant by 2-fold.     

Distance between the propylbenzilylcholine mustard attachment site and carbohydrates and thiol groups in muscarinic acetylcholine receptor protein from rat cerebral cortex.

When rat cerebral-cortex membranes were labelled with [3H]propylbenzilylcholine mustard ([3H]PrBCM), a single protein of Mr 68,000 was found to carry the atropine-sensitive covalent label. After trypsinolysis of the receptors solubilized in 0.075% SDS, the resulting fragments were submitted to size analysis in combination with wheat-germ agglutinin (WGA)-Sepharose and organomercurial-agarose chromatography. Peptides of Mr 75,000, 50,000, 30,000, 18,000 and 8000 were specifically released from the receptor. All fragments above Mr 8000 were able to bind WGA-Sepharose and therefore the peptide of Mr 18,000 was taken as the upper limit of the distance between the antagonist and the glycan moieties. The limit fragment of Mr 8000 carried chemical groups which were modified by N-ethylmaleimide and reacted with an immobilized organomercurial. About 65-80% of the labelled receptors were adsorbed on concanavalin A-Sepharose with low affinity, generating two further components after sequential application to WGA-Sepharose. About 50% of the receptors were susceptible to neuraminidase treatment, with a concomitant slight modification of the SDS/polyacrylamide-gel-electrophoretic pattern.     

Subcellular localization of creatine kinase in Torpedo electrocytes: association with acetylcholine receptor-rich membranes

Creatine kinase (CK, EC 2.7.3.2) has recently been identified as the intermediate isoelectric point species (pl 6.5-6.8) of the Mr 40,000-43,000 nonreceptor, peripheral v-proteins in Torpedo marmorata acetylcholine receptor-rich membranes (Barrantes, F. J., G. Mieskes, and T. Wallimann, 1983, Proc. Natl. Acad. Sci. USA, 80: 5440-5444). In the present study, this finding is substantiated at the cellular and subcellular level of the T. marmorata electric organ by immunofluorescence and by protein A-gold labeling of either ultrathin cryosections of electrocytes or purified receptor-membrane vesicles that use subunit-specific anti-chicken creatine kinase antibodies. The muscle form of the kinase, on the one hand, is present throughout the entire T. marmorata electrocyte except in the nuclei. The brain form of the kinase, on the other hand, is predominantly located on the ventral, innervated face of the electrocyte, where it is closely associated with both surfaces of the postsynaptic membrane, and secondarily in the synaptic vesicles at the presynaptic terminal. Labeling of the noninnervated dorsal membrane is observed at the invaginated sac system. In the case of purified acetylcholine receptor-rich membranes, antibodies specific for chicken B-CK label only one face of the isolated vesicles. No immunoreaction is observed with anti-chicken M-CK antibodies. A discussion follows on the possible implications of these localizations of creatine kinase in connection with the function of the acetylcholine receptor at the postsynaptic membrane, the Na/K ATPase at the dorsal electrocyte membrane, and the ATP-dependent transmitter release at the nerve ending.     

Nicotinic acetylcholine receptor channels are influenced by the physical state of their membrane environment.

We investigated the effect of the physical state of the cell membrane on the activity of the nicotinic acetylcholine receptor (AChR) in various clonal cell lines transfected with the cDNAs of embryonic or adult AChR by measuring single-channel properties and some membrane physicochemical properties as a function of temperature. Unitary conductance and channel closing rate, alpha, had Q(10) values of 1.2 and 2.2, respectively. Using Eyring's transition state theory, it was calculated that both embryonic and adult-type AChR had relatively low thermal sensitivity of ionic conductance and activation energy (E(a) of 3.0-5.0 kcal-mol(-1) at 20 degrees C), indicating that once the AChR channel opens, ion movement is dominated by diffusional processes. Channel closure exhibited higher energy requirements, with E(a) values of about 13 kcal-mol(-1). This process appears to be more endothermic (higher delta H(a) values) than ion permeation, and it is plausible that the energy acquired by the system can be used in the maintenance of its degree of order, as revealed by the delta S(a) 0 calculated for channel closure. The influence of the membrane environment on AChR function is reinforced by the observation that the conductance of the same, embryonic-type AChR protein, expressed in qualitatively different cellular lipid environments, appeared to have different energetic requirements. A correlation between the electrophysiological and thermodynamic parameters of the AChR and physicochemical properties of the membrane bilayer in which the protein is embedded could be established using measurements of the so-called generalized polarization (GP) of the lipophilic probe laurdan. Both embryonic and adult AChR exhibited a higher GP and a higher sensitivity to temperature-dependent changes in GP when heterologously expressed in stable form in Chinese hamster ovary (CHO)-derived cells than did the native embryonic AChR in BC3H-1 cells, indicating that these two properties are determined by the host membrane and are not inherent properties of the AChR type. In addition, the differences in the macroscopic physical states of the lipids and membrane-associated solvent (water) dipolar relaxation between BC3H-1 and CHO-derived cells indicated by the spectroscopic properties of laurdan suggest that both lipid and associated water may influence the microscopic activity of individual AChR molecules embedded in the lipid bilayer. Finally, the different dependence of AChR channel conductance and mean open time as a function of GP observed between the different AChR subtypes in clonal cell lines suggests the importance of specific lipid-protein interactions in addition to bulk membrane properties.     

Hydroxyl Radicals and a Thylakoid-Bound Endopeptidase are Involved in Light- and Oxygen-Induced Proteolysis in Oat Chloroplasts

The hypothesis that light- and oxygen-induced proteolysis inchloroplasts is mediated by active oxygen species was examined.In order to determine whether or not H₂O₂ and/or ^{dot}OH radicalsare involved in these degradative processes we compared thedegradation of proteins in isolated oat chloroplasts exposedto white light at 80 W m^-2 with that in chloroplasts incubatedin darkness in the absence or presence of H₂O₂ or a ^{dot}OH-generatingsystem composed by ascorbic acid, FeCl₃ and H₂O₂ (Asc-Fe-H₂O₂).Light enhanced the rate of degradation of at least 18 polypeptides,while proteolysis was almost negligible in darkness in the abscenceof additives. H₂O₂ had a very small effect. However, Asc-Fe-H₂O₂-treatedchloroplasts in darkness showed a pattern of protein degradationalmost identical to that observed in the light. A thylakoid-boundendopeptidase (EP), the activity of which increased under photooxidativeenvironmental conditions and treatment with an ^{dot}OH-generatingsystem, was partially purified and characterized as a serinetypeprotease. Treatments with inhibitors of serine-type proteaseprevented both light- and Asc- Fe-H₂O₂-induced proteolysis.EP was more active against both soluble and membranous proteinsthat had been pretreated with Asc-Fe-H₂O₂ than against untreatedproteins. It is proposed that a high dose of light irradiationpromotes proteolysis by increasing the formation of ^{dot}OH,which may modify proteins such that they become more susceptibleto EP-catalyzed hydrolysis. ¹Fisiología Vegetal, Dept. de Biología Vegetal,Universidad de Alcalá de Henares, Present address: 28871Alcalá de Henares (Madrid), España.     

Asymmetric distribution and down-regulation of the muscarinic acetylcholine receptor in rat cerebral cortex

The distribution and down-regulation of the muscarinic acetylcholine receptor (mAChR) were studied in dissociated cells from right (RCC) and left (LCC) cerebral cortex. For this purpose [³H]quinuclidinyl benzilate (QNB) and [³H]pirenzepine (Pz), two muscarinic antagonists, were used. The mAChR binding sites detected with [³H]QNB were asymmetrically distributed between the two hemispheres, the majority being found in the RCC. Asymmetry was also evident in the distribution of the mAChR subtypes (M₁ and M₂) detected with [³H]Pz. Under basal conditions the RCC had roughly 50% more M₁ subtype than the LCC. The pharmacological and kinetic parameters were similar for both antagonists in RCC and LCC, indicating that the observed lateralization was due to a different density of the receptor rather than to different kinetics of binding of the two radioligands. After sustained stimulation with the agonist carbamoylcholine, the receptor sites detected with [³H]Pz, i.e. the M₁ subtype of mAChR, decreased at a higher rate in the RCC (44%) than in the LCC (25% of controls), demonstrating that the down-regulation process is more active in the right than in the left cortex, and thus implying that there is better coupling between the stimulated mAChR and its effector system in the former.     

Oligomeric forms of the membrane-bound acetylcholine receptor disclosed upon extraction of the M(r) 43,000 nonreceptor peptide

Oligomeric forms of the acetylcholine receptor are directly visualized by electron microscopy in receptor-rich membranes from torpedo marmorata. The receptor structures are quantitatively correlated with the molecular species so far identified only after detergent solubilization, and further related to the polypeptide composition of the membranes and changes thereof. The structural identification is made possibly by the increased fragility of the membranes after extraction of nonreceptor peptides and their subsequent disruption upon drying onto hydrophilic carbon supports. Receptor particles in native membranes depleted of nonreceptor peptides appear as single units of 7-8 nm, and double and multiple aggregates thereof. Particle doublets having a main-axis diameter of 19 +/- 3 nm predominate in these membranes. Linear aggregates of particles similar to those observed in rotary replicas of quick-frozen fresh electrolytes (Heuser, J.E. and S. R. Salpeter. 1979, J. Cell Biol. 82: 150-173) are also present in the alkaline-extracted membranes. Chemical modifications of the thiol groups shift the distribution of structural species. Dithiothreitol reduction, which renders almost exclusively the 9S, monomeric receptor form, results in the observation of the 7-8 nm particle in isolated form. The proportion of doublets increases in membranes alkylated with N-ethylmaleimide. Treatment with 5,5’-dithiobis-(nitrobenzoic acid) increases the proportion of higher oligomeric species, and particle aggregates (n=oligo) predominate. The nonreceptor v-peptide (doublet of M(r) 43,000) appears to play a role in the receptor monomer-polymer equilibria. Receptor protein and v-peptide co-aggregate upon reduction and reoxidation of native membranes. In membranes protected ab initio with N- ethylmaleimide, only the receptor appears to self-aggregate. The v-peptide cannot be extracted from these alkylated membranes, though it is easily released from normal, subsequently alkylated or reduced membranes. A stabilization of the dimeric species by the nonreceptor v-peptide is suggested by these experiments. Monospecific antibodies against the v-peptide are used in conjunction with rhodamine- labeled anti-bodies in an indirect immunoflourescence assay to map the vectorial exposure of the v-peptide. When intact membranes, v-peptide depleted and “holey” native membranes (treated with 0.3 percent saponin) are compared, maximal labeling is obtained with the latter type of membranes, suggesting a predominantly cytoplasmic exposure of the antigenic determinants of the v-peptide in the membrane. The influence of the v-peptide in the thiol-dependent interconversions of the receptor protein and the putative topography of the peptide are analyzed in the light of the present results.     

Association of spin-labeled local anesthetics at the hydrophobic surface of acetylcholine receptor in native membranes from Torpedo marmorata

The interactions between a series of spin-labeled local anesthetic analogues and the nicotinic acetylcholine receptor (AChR) have been investigated by means of electron spin resonance (ESR) and fluorescence spectroscopy. The paramagnetic local anesthetic analogues quenched the intrinsic tryptophan fluorescence of AChR-rich membranes in an agonist-dependent manner, demonstrating a direct interaction with the AChR. The quenching efficiency was greater for the benzocaine than for the thioprocaine analogue. The protein was found to restrict directly the molecular motion of the spin-labeled analogues, as seen by the appearance of a highly anisotropic component in the ESR spectrum. The relative affinity of the population of local anesthetic probes which interacts directly with the integral protein of the AChR-rich membranes was calculated on the basis of relative association constants, Kr, determined by ESR. By comparison with the relative association constant for spin-labeled phospholipid, Kro, it was possible to differentiate between local anesthetic analogues interacting with high (Kr/Kro greater than 2), intermediate (Kr/Kro = 1.6-1.9), and low (Kr/Kro less than or equal to 1.3) specificity and to calculate the fraction of protein-associated probe in each case. Differences were observed in the presence of agonist (0.1 mM carbamylcholine) with some, but not all, of the spin-labeled derivatives. The role of the protonatable diethylammonium group in the specificity of the interaction of the procaine and thioprocaine analogues was investigated. Only in the uncharged form, or in the charged form at high ionic strength, was there a preferential association of these two local anesthetic analogues.(ABSTRACT TRUNCATED AT 250 WORDS)