Tubulin and neurofilament proteins are transported differently in axons of chicken motoneurons.

1. We previously showed that actin is transported in an unassembled form with its associated proteins actin depolymerizing factor, cofilin, and profilin. Here we examine the specific activities of radioactively labeled tubulin and neurofilament proteins in subcellular fractions of the chicken sciatic nerve following injection of L-[35S]methionine into the lumbar spinal cord. 2. At intervals of 12 and 20 days after injection, nerves were cut into 1-cm segments and separated into Triton X-100-soluble and particulate fractions. Analysis of the fractions by high-resolution two-dimensional gel electrophoresis, immunoblotting, fluorography, and computer densitometry showed that tubulin was transported as a unimodal wave at a slower average rate (2-2.5 mm/day) than actin (4-5 mm/day). Moreover, the specific activity of soluble tubulin was five times that of its particulate form, indicating that tubulin is transported in a dimeric or small oligomeric form and is assembled into stationary microtubules. 3. Neurofilament triplet proteins were detected only in the particulate fractions and transported at a slower average rate (1 mm/day) than either actin or tubulin. 4. Our results indicate that the tubulin was transported in an unpolymerized form and that the neurofilament proteins were transported in an insoluble, presumably polymerized form.

Cotransport of glyceraldehyde-3-phosphate dehydrogenase and actin in axons of chicken motoneurons.

1. To study proteins transported with actin in axons, we pulse-labeled motoneurons in the chicken sciatic nerve with [35S]methionine and, 1-20 days later, isolated actin and its binding proteins by affinity chromatography of Triton soluble nerve extracts on DNase I-Sepharose. The DNase I-purified proteins were electrophoresed on two-dimensional gels and the specific activity of the radioactively labeled protein spots was estimated by fluorography. 2. In addition to actin, which binds specifically to DNase I, a small number of other proteins were labeled, including established actin monomer binding proteins and a protein of 36 kDa and pI 8.5. On the basis of its molecular mass, pI, amino acid composition, and immunostaining, the unrecognized protein was identified as the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH). 3. The high-affinity binding of GAPDH to actin was confirmed by incubation of Triton-soluble nerve extracts with either mouse anti-GAPDH (or antiactin) and indirect immunomagnetic separation with Dynabeads covalently linked to sheep anti-mouse antibody. Analysis by one-dimensional gel electrophoresis and immunoblotting showed that actin and GAPDH were the main proteins isolated by these methods. 4. Analysis of labeled nerves at 12 and 20 days after pulse labeling showed that GAPDH and actin were transported at the same rate, i.e., 3-5 mm/day, which corresponds to slow component b of axonal transport. These proteins were not associated with rapidly transported proteins that accumulated proximal to a ligation 7 cm from the spinal cord 9 hr after injection of radioactivity. 5. Our results indicate that GAPDH and actin are transported as a complex in axons and raise the possibility that GAPDH could act as a chaperone for monomeric actin, translocating it to intraaxonal sites for exchange with or assembly into actin filaments. Alternatively, actin could be involved in translocating and anchoring GAPDH to specialized sites in axons and nerve terminals that require a source of ATP by glycolysis.

Axonal transport and distribution of cyclophilin A in chicken neurones.

In the course of pulse-label studies on the axonal transport of the small, basic, actin-binding proteins--actin depolymerizing factor, cofilin and profilin--in chicken motor neurones, we observed a heavily labelled protein of M(r) 18 kDa and pI 8.2 on fluorographs of two-dimensional polyacrylamide gels. On the basis of its M(r), pI and amino acid composition, we tentatively identified it by database searching as cyclophilin A and subsequently confirmed its identity by immunostaining. Like actin and its associated proteins, cyclophilin A was transported in slow component b of axonal transport, but unlike these proteins, cyclophilin A did not copurify with actin on DNase I. It was not found amongst labelled proteins transported by fast axonal transported by fast axonal transport. Immunostaining of chicken dorsal root ganglion cells revealed that it accumulated in neurites at points of branching, varicosities and growth cones. Our results raise the possibility that cyclophilin A is important in maintaining the native folding of actin and associated proteins during transit in axons and assembly in growth cones.

Slow axonal transport of soluble actin with actin depolymerizing factor, cofilin, and profilin suggests actin moves in an unassembled form.

We examined the axonal transport of actin and its monomer binding proteins, actin depolymerizing factor, cofilin, and profilin, in the chicken sciatic nerve following injection of [35S]methionine into the lumbar spinal cord. At intervals up to 20 days after injection, nerves were cut into 1-cm segments and separated into Triton X-100-soluble and particulate fractions. Actin and its binding proteins were then isolated by affinity chromatography on DNase I-Sepharose and by one- and two-dimensional polyacrylamide gel electrophoresis. Fluorographic analysis showed that the specific activity of soluble actin was two to three times that of its particulate form and that soluble actin, cofilin, actin depolymerizing factor, and profilin were transported at similar rates in slow component b of axonal flow. Our data strongly support the view that the mobile form of actin in slow transport is soluble and that a substantial amount of this actin may travel as a complex with actin depolymerizing factor, cofilin, and profilin. Along labeled nerves the specific activity of the unphosphorylated form of actin depolymerizing factor, which binds actin, was not significantly different from that of its "inactive" phosphorylated form. This constancy in specific activity suggests that continuous inactivation and reactivation of actin depolymerizing factor occur during transport, which could contribute to the exchange of soluble actin with the filamentous actin pool.

Actin depolymerizing factor is a component of slow axonal transport.

We examined the low molecular weight proteins transported with actin in the chicken sciatic nerve after injection of [35S]methionine into the lumbar spinal cord. A prominent component of slow axonal transport with apparent molecular mass 19 kDa comigrated on two-dimensional gels with chicken actin depolymerizing factor (ADF), previously shown to be a major actin-binding protein in brain. There was comparatively little radioactivity associated with the actin monomer sequestering proteins, profilin or cofilin, and examination of the rapid component of axonal transport failed to reveal appreciable quantities of actin, ADF, profilin, or cofilin. These results show that both actin and ADF are carried by slow axonal transport and raise the possibility that actin travels within the axon in an unpolymerized form in a complex with ADF.

Transport complexes associated with slow axonal flow.

Cytoskeletal proteins--neurofilament polypeptides, tubulin and actin--are transported along axons by slow transport. How or in what form they are transported is not known. One hypothesis is that they are assembled into the cytoskeleton at the cell body and transported as intact polymers down the axon. However, recent radiolabeling and photobleaching studies have shown that tubulin and actin exist in both a mobile phase and a stationary phase in the axon. Consequently, it is more likely that cytoskeletal proteins move along the axon in some form of transport complex and are assembled into a cytoskeleton which is stationary. In this overview we discuss these topics and consider the evidence for the existence of transport complexes associated with slow axonal flow. Such evidence includes the slow transport of particulate complexes containing tubulin and neurofilament polypeptides along reconstituted microtubules in vitro, and the coordinate slow transport of actin with actin-binding proteins in vivo.

Effects of electrical stimulation and tetrodotoxin paralysis on antigenic properties of acetylcholine receptors in rat skeletal muscle.

To examine the role of muscle activity in the expression of fetal- and adult-type acetylcholine receptors (AChRs), we studied the effects of muscle stimulation in cell culture and of tetrodotoxin (TTX)-induced paralysis and denervation in adult rat muscles. The AChR content of these muscles was determined using [125I]alpha-bungarotoxin and the proportion of fetal-type receptors was estimated using a radioimmunoprecipitation assay with a myasthenic serum that was highly specific for fetal-type receptors. We found that both stimulated, aneural muscle cells in vitro and inactive muscles in vivo produced predominantly fetal-type AChRs. However the TTX-paralysed muscles had a lower proportion of fetal-type receptors than the denervated muscles. We conclude that neither muscle activity nor innervation alone, but a combination of both, is required for full regulation of AChR antigenicity.

Loss of antigenic properties of acetylcholine receptors in rat skeletal muscle after birth.

Antibodies in a myasthenic serum were used to follow the changes in antigenic properties of acetylcholine receptors in rat skeletal muscle during development. In binding assays at saturating concentrations of antigen or antibody, the antibodies reacted with extrajunctional receptors of fetal and denervated adult muscle but showed little binding to junctional receptors of adult rat muscle. They did, however, bind to junctional receptors of adult chicken muscle which, unlike rat receptors, do not appear to undergo a change in their channel properties during development. Binding studies with acetylcholine receptors of developing rat muscle carried out at saturating concentrations of antibody showed that the loss of antigenic determinant(s) begins at 1-2 days after birth.

Autoantibodies to acetylcholine receptor in myasthenia gravis: light chains.

We studied the light chain type of autoantibodies to acetylcholine receptor (AChR) by affinity chromatography with monoclonal anti-kappa and anti-lambda antibodies. The autoantibodies in four of eight myasthenic patients were of a single light chain type; the others comprised both types. In Graves' disease and cold-reactive hemolytic anemia, the pathogenic autoantibodies are confined to a single light chain type in individual patients, and in other diseases, doubtfully pathogenic autoantibodies are invariably mixtures of both light chain types. AChR antibodies may comprise both pathogenic and nonpathogenic types of autoantibody.

Cellular ions in intact and denervated muscles of the rat.

Tissue composition, membrane potentials and cellular activity of potassium, sodium and chloride have been measured in innervated and denervated rat skeletal muscles incubated in vitro. After denervation for 3 days, tissue water, sodium and chloride were increased but cellular potassium content and measured activity were little affected, despite a decrease of 16 mV in resting membrane potential which would have necessitated a decrease in cellular potassium activity of almost 50% were potassium distributed at electrochemical equilibrium. These findings, therefore, preclude a decreased electrochemical potential gradient for potassium as the cause of the membrane depolarization characteristic of denervated muscle fibers. Analysis of the data excludes an important contribution of rheogenic sodium transport to the resting potential of innervated muscles. These results strongly support the hypothesis that the decreased membrane potential in denervated fibers reflects a relative increase in the membrane permeability to sodium.

Evidence for the role of non-quantal acetylcholine in the maintenance of the membrane potential of rat skeletal muscle.

1. Resting membrane potentials of rat diaphragm muscles cultured in Trowell T8 medium were measured in vitro. After 3 hr in culture the resting membrane potential of muscle fibres within 2.5 mm of nerve section (;near') was -68.3 +/- 0.4 mV (nineteen preparations). This was significantly lower (P < 0.001) than the resting potential (-74.0 +/- 0.4 mV) measured in muscle fibres 8-10 mm from the site of nerve section (;far') in the same preparations. A difference between the ;near' and the ;far' fibres was maintained in muscles cultured for 6 and 12 hr. Miniature end-plate potentials were present in both ;near' and ;far' fibres cultured for 3 and 6 hr and ceased after 12-15 hr.2. The presence of carbamylcholine (10(-7) or 10(-8) M) maintained the resting membrane potential of ;near' fibres close to that of ;far' fibres at 3, 6 and 12 hr. For example, at 3 hr in the presence of 10(-8) M-carbamylcholine the mean resting potential was 75.6 +/- 0.5 mV in ;near' fibres and 76.1 +/- 0.4 mV in ;far' fibres (four preparations). A similar effect was produced in preparations exposed to anticholinesterases: diisopropylphosphorofluoridate (DFP) (10(-7) M), neostigmine (10(-7) M) or physostigmine (10(-5) M).3. Agents that blocked acetylcholine receptors had the reverse effect. In the presence of alpha-bungarotoxin (1 mug/ml.) or d-tubocurarine (10(-5) M) the resting membrane potential of ;far' fibres was reduced to the level of ;near' fibres over the 24 hr period of observation. For example, at 3 hr in the presence of alpha-bungarotoxin the mean resting potential was 67.2 +/- 0.5 mV in ;near' fibres and 68.5 +/- 0.6 mV in ;far' fibres (six preparations). The effect of d-tubocurarine was reversible.4. When muscles were cultured in Ca(2+)-free medium containing 1 mM-EGTA and 10 mM-Mg(2+), there was no difference in membrane potential between ;near' and ;far' fibres and physostigmine (10(-5) M) was ineffective in raising the membrane potential of ;near' fibres.5. It is suggested that non-quantal acetylcholine released from nerve terminals maintains the membrane potential of muscle fibres through a Ca(2+)-dependent mechanism.

Localization of immunoreactive angiotensin II in the hippocampus and striatum of rat brain.

Angiotensin II (ANG II) was estimated by radioimmunoassay in extracts of rat brain. In extracts of whole brain the mean content was 108 +/- 16 fmol/g and estimates of ANG II in kidney and plasma were similar to previous reports. A regional distribution of ANG II was determined. Hippocampus had the highest concentration and cortex the lowest. The concentrations relative to cortex were: hippocampus, 8; striatum, 5; cerebellum, 4; hypothalamus:thalamus:septum:midbrain (HTSM), 3; and medulla, 3.

The trophic influence of tetrodotoxin-inactive nerves on normal and reinnervated rat skeletal muscles.

1. Nerve impulses in the rat sciatic nerve were blocked for long periods by tetrodotoxin (TTX) released from capillary implants. The TTX capillaries did not block axonal transport, nor did they cause any sign of nerve degeneration. 2. A comparison of the effects of TTX paralysis and denervation was made on both extensor digitorium longus (e.d.l.) and soleus muscles over 21 days, a time when the products of nerve degeneration were unlikely to contribute to the changes associated with denervation. The resting membrane potential of TTX-paralysed muscles was significantly different (P less than 0.005) from that of the denervated muscles at all periods and at 21 days the decrease that can be attributed to inactivity was 61% (e.d.l.) and 49% (soleus) of that which follows denervation. This disparity was even more pronounced for the ACh receptor density where the increase in receptors due to inactivity was only 34% (e.d.l.) and 21% (soleus) of that due to denervation. 3. A similar comparison was made on muscles which had been reinnervated by TTX-inactive nerves. These muscles were found to have a significantly higher resting membrane potential and lower ACh receptor density than the denervated muscles (P less than 0.05). 4. The experiments on reinnervated muscles preclude the possibility that nerve degeneration products are solely responsible for the difference between the TTX-paralysed and denervated muscles and suggest that the difference can be attributed to the trophic influence of the nerve. 5. An observed increase in the m.e.p.p. frequency of the TTX-paralysed muscles indicated that nerve action potentials play a role in regulating the spontaneous release from nerve terminals.

A slow-release technique for inducing prolonged paralysis by tetrodotoxin.

A technique is described for the slow-release of tetrodotoxin in peripheral nerves using a constriction capillary. The capillary, which was implanted under the epineurium of the sciatic nerve, released tetrodotoxin from a 25 micrometer pore. Nerve block was complete after approximately 20 min and lasted 6--9 days. Replacement of the capillary enabled paralysis of the rat hindlimb to be maintained for periods of 21 days and longer. Studies with radioactively labelled compounds demonstrated that the efflux rate from the capillary was dependent on the size of the pore and the relative molecular mass of the compound.

Distribution of angiotensin II receptors in rat brain.

Angiotensin II binding activity of rat brain particles was examined using [125I]-angiotensin II (0.1-0.3 nM) in the presence and absence of excess unlabelled angiotensin II. Certain features of the binding suggested that physiological receptors were involved. The binding activity was temperature dependent and was increased 3-fold by the addition of 0.5 M EDTA. The binding appeared specific as judged by inhibition with angiotensin II agonists and antagonists. The "specific" binding was saturable, two-thirds reversible and occurred with high affinity. The equilibrium dissociation constant (Kd) of the "specific" binding was 0.9 nM. Subcellular fractionation studies indicated that over 90% of the binding was associated with particulate matter and was concentrated in the crude microsomal fraction. Binding was localized to the midbrain, thalamus, septum, hypothalamus and medulla; Very low levels of binding were found in the cortex, hippocampus and striatum; The lateral septum had the highest binding activity of all the tissues examined. Subdivision of the medulla showed that the highest binding activity was associated with the area postrema and medullary regions ventral to this organ.

The membrane potential of rat diaphragm muscle fibres and the effect of denervation.

1. Resting membrane potentials of rat diaphragm muscles were measured in vitro after previous denervation for 0-10 days. In some experiments denervated muscles were incubated in vitro for 3 hr while in others they were cultured for 15-24 hr to allow adequate exposure to drugs before recording. 2. It was found that resting membrane potentials, within 2-5 mm of the site of nerve section were significantly lower, within 3 hr, than resting membrane potentials measured more than 9 mm away from site of nerve section. This difference could be reduced or abolished by bathing preparations in solutions containing adrenaline (10 muM), noradrenaline (10 muM) or isoprenaline (10 muM) or dibutyryl cyclic AMP (10 muM-0-25 mM in the presence of 2 mM theophylline). Cyclic AMP (0-5 mM) was ineffective. 3. Application of solutions containing dibutyryl cyclic AMP for 3 hr also raised the resting membrane potential of muscles denervated 4-5 days previously. Culture studies showed that this effect was sustained when the time of incubation was 24 hr. 4. Incubating freshly denervated preparations with cycloheximide (22 mug/ml.) or actinomycin D (1 mug/ml.) did not prevent the development of the early (3 hr) fall in resting membrane potential despite a concomitant inhibition of RNA or protein synthesis. Culturing freshly denervated muscles in solutions containing cycloheximide (10 or 25 mug/ml.) which blocked 93% of protein synthesis, did not prevent the expected drop in resting membrane potential after 15 or 24 hr. 5. It was found that exposure to ouabain (1 or 5 mM) produced a rapid (15 min) fall in resting membrane potential in innervated and denervated preparations treated with dibutyryl cyclic AMP but not denervated preparations. After 5 days denervation cyclic AMP levels in muscle were increased by about 40%. 6. It is suggested that upon denervation an electrogenic action of a NA+-pump is blocked and that dibutyryl cyclic AMP and catecholamines are capable of stimulating this pump.