Protein Synthesis in Brain Slices

The RNA-binding protein FUS/TLS undergoes calcium-mediated nuclear egress during excitotoxic stress and is required for GRIA2 mRNA processing

Excitotoxic levels of glutamate represent a physiological stress that is strongly linked to amyotrophic lateral sclerosis (ALS) and other neurological disorders. Emerging evidence indicates a role for neurodegenerative disease-linked RNA-binding proteins (RBPs) in the cellular stress response. However, the relationships between excitotoxicity, RBP function, and disease have not been explored. Here, using primary cortical and motor neurons, we found that excitotoxicity induced the translocation of select ALS-linked RBPs from the nucleus to the cytoplasm within neurons. RBPs affected by excitotoxicity included TAR DNA-binding protein 43 (TDP-43) and, most robustly, fused in sarcoma/translocated in liposarcoma (FUS/TLS or FUS). We noted that FUS is translocated through a calcium-dependent mechanism and that its translocation coincides with striking alterations in nucleocytoplasmic transport. Furthermore, glutamate-induced up-regulation of glutamate ionotropic receptor α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)-type subunit 2 (GRIA2) in neurons depended on FUS expression, consistent with a functional role for FUS in excitotoxic stress. These findings reveal molecular links among prominent factors in neurodegenerative diseases, namely excitotoxicity, disease-associated RBPs, and nucleocytoplasmic transport.

Antidepressant action of ketamine via mTOR is mediated by inhibition of nitrergic Rheb degradation

As traditional antidepressants act only after weeks/months, the discovery that ketamine, an antagonist of glutamate/N-methyl-D-aspartate (NMDA) receptors, elicits antidepressant actions in hours has been transformative. Its mechanism of action has been elusive, though enhanced mammalian target of rapamycin (mTOR) signaling is a major feature. We report a novel signaling pathway wherein NMDA receptor activation stimulates generation of nitric oxide (NO), which S-nitrosylates glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Nitrosylated GAPDH complexes with the ubiquitin-E3-ligase Siah1 and Rheb, a small G protein that activates mTOR. Siah1 degrades Rheb leading to reduced mTOR signaling, while ketamine, conversely, stabilizes Rheb that enhances mTOR signaling. Drugs selectively targeting components of this pathway may offer novel approaches to the treatment of depression.

Suppressive Effects of Various Amino Acids against Ouabain-Induced Seizures in Rats

The suppressive effect of various amino acids against ouabaininduced seizures was investigated in young female rats. The amino acids were injected into the left lateral ventricle 10 minutes prior to the intraventricular administration of 5 μg. of ouabain. Animals receiving 1.9 x 10-1 M solutions of hypotaurine and of β- alanine were almost completely protected from the ouabain seizures. Administration of L-alanine and of glycine was also effective, although running and leaping seizures still occurred to some extent. Betaine reduced only clonic-tonic and whole body flexion and extension seizures. In contrast, L-proline exclusively suppressed clonic-tonic and focal clonic seizures. Rats injected with isethionic acid showed increases in incidence of running and leaping seizures while L-arginine in high concentrations caused aggravation in clonic-tonic seizures. L-cysteine, even in low concentrations, also brought about an increase in the occurrence and incidence of clonic-tonic seizures. The ED50of hypotaurine was 10.11 x 10-2 M for running seizures and 4.63 x 10-2, M for clonictonic seizures; that of β -alanine was 14.01 x 10-2 M for running seizures and 5.50 x 10-2 M for clonic-tonic seizures. However, hypotaurine and β -alanine, the most effective compounds tested in the present studies, provided less protection than taurine previously examined by us under similar conditions (Izumi et al., 1973).

Local translational control in dendrites and its role in long-term synaptic plasticity

Local protein synthesis in dendrites has emerged as a key mechanism contributing to enduring forms of synaptic plasticity. Although the translational capability of dendrites has been appreciated for over 20 years, it is only recently that significant progress has been made in elucidating mechanisms that contribute to its regulation. It is clear from work over the last few years that the control of translation in dendrites is complex, involving a host of unique (and often surprising) mechanisms that can operate together or in parallel to tightly control gene expression in time and space. Here, we discuss the strategies used by neurons to regulate translation in dendrites and how these are implemented in the service of long-term information storage.

Protein synthesis in axons and terminals: significance for maintenance, plasticity and regulation of phenotype. With a critique of slow transport theory

This article focuses on local protein synthesis as a basis for maintaining axoplasmic mass, and expression of plasticity in axons and terminals. Recent evidence of discrete ribosomal domains, subjacent to the axolemma, which are distributed at intermittent intervals along axons, are described. Studies of locally synthesized proteins, and proteins encoded by RNA transcripts in axons indicate that the latter comprise constituents of the so-called slow transport rate groups. A comprehensive review and analysis of published data on synaptosomes and identified presynaptic terminals warrants the conclusion that a cytoribosomal machinery is present, and that protein synthesis could play a role in long-term changes of modifiable synapses. The concept that all axonal proteins are supplied by slow transport after synthesis in the perikaryon is challenged because the underlying assumptions of the model are discordant with known metabolic principles. The flawed slow transport model is supplanted by a metabolic model that is supported by evidence of local synthesis and turnover of proteins in axons. A comparison of the relative strengths of the two models shows that, unlike the local synthesis model, the slow transport model fails as a credible theoretical construct to account for axons and terminals as we know them. Evidence for a dynamic anatomy of axons is presented. It is proposed that a distributed "sprouting program," which governs local plasticity of axons, is regulated by environmental cues, and ultimately depends on local synthesis. In this respect, nerve regeneration is treated as a special case of the sprouting program. The term merotrophism is proposed to denote a class of phenomena, in which regional phenotype changes are regulated locally without specific involvement of the neuronal nucleus.

N-methyl-D-aspartate receptor activation and visual activity induce elongation factor-2 phosphorylation in amphibian tecta: a role for N-methyl-D-aspartate receptors in controlling protein synthesis

N-methyl-D-aspartate receptor (NMDAR) activation has been implicated in forms of synaptic plasticity involving long-term changes in neuronal structure, function, or protein expression. Transcriptional alterations have been correlated with NMDAR-mediated synaptic plasticity, but the problem of rapidly targeting new proteins to particular synapses is unsolved. One potential solution is synapse-specific protein translation, which is suggested by dendritic localization of numerous transcripts and subsynaptic polyribosomes. We report here a mechanism by which NMDAR activation at synapses may control this protein synthetic machinery. In intact tadpole tecta, NMDAR activation leads to phosphorylation of a subset of proteins, one of which we now identify as the eukaryotic translation elongation factor 2 (eEF2). Phosphorylation of eEF2 halts protein synthesis and may prepare cells to translate a new set of mRNAs. We show that NMDAR activation-induced eEF2 phosphorylation is widespread in tadpole tecta. In contrast, in adult tecta, where synaptic plasticity is reduced, this phosphorylation is restricted to short dendritic regions that process binocular information. Biochemical and anatomical evidence shows that this NMDAR activation-induced eEF2 phosphorylation is localized to subsynaptic sites. Moreover, eEF2 phosphorylation is induced by visual stimulation, and NMDAR blockade before stimulation eliminates this effect. Thus, NMDAR activation, which is known to mediate synaptic changes in the developing frog, could produce local postsynaptic alterations in protein synthesis by inducing eEF2 phosphorylation.

No effect of glutamate on metabolic disturbances in hippocampal slices of mature fetal guinea pigs after transient in vitro ischemia

The involvement of glutamate in the development of cerebral metabolic disturbances in mature fetuses after transient ischemia was studied using a hippocampal slice model. We investigated the effects of exogenously applied glutamate or glutamate antagonists on the recovery of energy metabolism and protein synthesis rate (PSR) in hippocampal slices of mature guinea pigs after in vitro ischemia. The slices were incubated in a thermostatically controlled flow-through chamber and gassed with carbogen (95% O2/5% CO2). In vitro ischemia was induced by transferring the slices to an aglycemic, artificial cerebrospinal fluid (aCSF) equilibrated with 95% N2/5% CO2. In a first set of experiments slices were exposed to 10 mM glutamate during a 20-40 min period of in vitro ischemia. In a second set slices were incubated in aCSF containing MK-801 (100 microM) or kynurenic acid (0.5 mM) 30 min before, during and 2 h after in vitro ischemia. After a 12 h recovery phase, the concentrations of adenylates in the slices were measured by HPLC after extraction with perchloric acid. PSR was calculated from the rate of incorporation of [14C]leucine into tissue proteins. Neither glutamate nor glutamate antagonists had any effect on the postischemic recovery of energy metabolism and PSR when applied during in vitro ischemia. It is therefore concluded that glutamate does not play a major role in the development of metabolic disturbances in hippocampal slices from mature guinea pig fetuses subjected to transient in vitro ischemia.

Protein synthesis in the hippocampal slice: transient inhibition by glutamate and lasting inhibition by ischemia

Protein synthesis was measured in hippocampal slices which were exposed to glutamate (1 mM or 10 mM) or which were deprived of glucose and oxygen ('in vitro ischemia') for 15 min. Glutamate at 1 mM, a concentration estimated to occur during in vivo ischemia did not affect protein synthesis. Ten mM glutamate inhibited protein synthesis immediately after exposure (50% of control values) and reduced ATP levels to about 30% of the control. After two hours, slices fully recovered their protein synthesis and energy metabolism. The effect of 10 mM glutamate was not receptor-mediated, as NMDA, AMPA, or metabotropic receptor antagonists failed to block the glutamate effect. Immediately after ischemia, protein synthesis was reduced to 30% of control values, and 2 hours later it was still depressed to one-half of control values. Energy charge, however, recovered completely. Ischemic inhibition of protein synthesis was not reversed by glutamate receptor antagonists. The data indicate that inhibition of protein synthesis in hippocampal slices during ischemia is not glutamate-dependent.

Activation of excitatory amino acid receptors cannot alone account for anoxia-induced impairment of protein synthesis in rat hippocampal slices

We have investigated the contribution of excitatory amino acid receptor activation to the inhibition of protein synthesis observed after anoxia in rat hippocampal slices. Protein synthesis was assessed in normoxic medium by measuring the incorporation of [14C]lysine into perchloric acid-insoluble tissue extracts. Protein synthesis was impaired after anoxia; the extent of inhibition was dependent on the duration of anoxia and on the time allowed for postanoxic recovery. There was a similar impairment under normoxic conditions when the N-methyl-D-aspartate (NMDA) receptor channel was activated by removing Mg2+ and adding NMDA. This was prevented by noncompetitive antagonists of the NMDA receptor channel (MK-801, phencyclidine, and N-allylnormetazocine). In contrast, incubation with the NMDA antagonists failed to prevent the protein synthesis inhibition caused by anoxia, although it moderately facilitated the postanoxic recovery. Protein synthesis was also impaired under normoxic conditions after incubation with quisqualate and kainate, agonists of non-NMDA glutamate receptors. This impairment was prevented by 6-cyano-7-nitroquinoxaline-2,3-dione, an antagonist of these receptors. Although 6-cyano-7-nitroquinoxaline-2,3-dione alone failed to prevent anoxic damage, when used in combination with an NMDA antagonist it did partially enhance the later recovery of protein synthesis. These results indicate that the activation of excitatory amino acid receptors cannot alone account for anoxia-induced impairment of protein synthesis in rat hippocampal slices.

Glutamate neurotoxicity and the inhibition of protein synthesis in the hippocampal slice

In some animal models of ischemia, neuronal degeneration can be prevented by the selective antagonism of the N-methyl-D-aspartate (NMDA) glutamate receptor subtype, suggesting that glutamate released during ischemia causes injury by activating NMDA receptors. The rat hippocampal slice preparation was used as an in vitro model to study the pharmacology of glutamate toxicity and investigate why NMDA receptors are critical in ischemic injury. Acute toxicity was assessed by quantifying the inhibition of protein synthesis, which we confirmed by autoradiography to be primarily neuronal. The effect of NMDA was prevented by the specific antagonists MK-801 and ketamine, as well as by the less selective antagonist kynurenic acid. The less selective antagonists kynurenic acid and 6,7-dinitroquinoxaline-2,3-dione antagonized the effects of quisqualate and NMDA. In contrast to previous observations with dissociated neurons in tissue culture, the toxicity of glutamate was unaffected by antagonists, regardless of the glutamate concentration, the duration of exposure, or the presence of magnesium. The high concentration of glutamate required to inhibit protein synthesis and the inability of receptor antagonists to block the effect of glutamate suggest that either glutamate acts through a non-receptor-mediated mechanism, or that the receptor-mediated nature of glutamate effects are masked in the slice preparation, perhaps by the glial uptake of glutamate. The altered physiology induced by ischemia must potentiate the neurotoxicity of glutamate, because we observed with a brain slice preparation that only high concentrations of glutamate caused neurotoxicity in the presence of oxygen and glucose and that these effects were not reversed by glutamate receptor antagonists.

Protein synthesis as a function of depth in slices of rat hippocampus

Physiologically viable slices of rat hippocampus were incubated in radiolabeled valine, then cut into 20 microns serial sections to evaluate the profile of protein synthesis through the depth of the slice. Maximum radiolabel incorporation was observed near the center of the slice, while at the upper (gas interface) and lower (liquid interface) surfaces radiolabel incorporation per section was reduced by about 30% and 90%, respectively. The results suggest that in properly slices damage due to slicing may be less important to cell viability than are limits on oxygen diffusion into the tissue.

Protein synthesis by rat hippocampal slices maintained in vitro

The present study evaluates protein synthesis in rat hippocampal slices maintained in vitro. Transverse slices of hippocampus were prepared from both adult rats and rat pups during postnatal development and incubated in a gassed (95% O2/5% CO2) balanced salt medium containing 5 nM 3H-leucine. The time course of 3H-leucine incorporation into TCA-precipitable protein was determined using slices removed from the media after 5, 10, 20, 30, 40, 60, and 120 min of incubation. The pattern of 3H-amino acid incorporation was evaluated by fixing slices with paraformaldehyde, embedding the slices in plastic, and sectioning the slices end on and en face for autoradiographic analysis. Biochemical analysis of 300 and 400 micron slices revealed that incorporation of leucine into protein proceeds at a constant rate. The autoradiographic analysis revealed that in adult hippocampal slices of 300-600 micron thickness there was complete penetration of 3H-leucine with no indication of a gradient in the extent of incorporation throughout the slice. The pattern of grain density within 300-600 micron slices matches that previously reported after in vivo injections of radiolabeled amino acid, where grain density is highest over neuronal cell bodies and lower over the laminae that contain dendritic processes and axons (Phillips et al: Mol Brain Res 2:251-261, 1987). Hippocampal slices of 200, 800, and 1,000 micron thickness showed irregular labeling. Slices of 200 micron were filled with pyknotic nuclei and vacuoles and exhibited patchy labeling. In 800 micron slices there were isolated areas of good preservation within the slice core, but these areas exhibited little incorporation. Relative to the 300-600 micron slices, there was a higher number of pyknotic nuclei and a much deeper layer of necrosis along the cut edges. Slices of 1,000 micron thickness showed poor preservation throughout and low levels of incorporation. Biochemical studies revealed a much higher rate of incorporation in the slices prepared from postnatal animals. Autoradiography of the slices from developing rats revealed that penetration was excellent and incorporation appeared to be greater as judged by an overall higher grain density. We believe that rat hippocampal slices provide a good in vitro model of protein metabolism that will be useful for studies of protein synthesis in isolated cell body and dendritic laminae and for the evaluation of whether protein synthesis in particular laminae is regulated by synaptic activity.

Neuropathological changes in the rat brain cortex in vitro: effects of kainic acid and of ion substitutions

The ionic mechanisms that may contribute to the neurotoxicity of kainic acid, were studied in a system of rat thin neocortical slices superfused in vitro. Slices superfused for 3 h under control conditions showed an essentially normal aspect when studied by light microscopy. Presence of 30 microM kainate in the superfusion fluid induced neuronal swelling, nuclear condensation and signs of necrosis in some cells, while other neurons, especially in deeper layers, appeared dark and condensed, with microvacuolation. The neuropil presented numerous profiles of swollen dendrites. When the slices were superfused with chloride-free medium, a large number of pyknotic neurons was seen. This was further enhanced by 30 microM kainate, which produced no swelling in this medium. These effects of Cl-free medium were almost entirely prevented in Cl-free medium without calcium and with 0.1 mM of EGTA. Sodium-free medium induced a marked neuronal swelling that was not much changed by kainate. When calcium in an otherwise normal superfusion fluid was reduced to 0.1 mM, a large number of pyknotic neurons, some with incrustations, were seen. Kainate (30 microM) in this low calcium medium led to a very large swelling and destruction of neurons, and to a spongy neuropil. These effects of kainate were greatly intensified in calcium-free-EGTA (0.1 mM) medium. Ca-free-EGTA medium by itself induced considerable neuronal and neuropil swelling. It is concluded that kainate induces neuronal swelling by a sodium- and chloride-dependent mechanism, and the enhancement of swelling in low calcium is due to an increased sodium uptake.(ABSTRACT TRUNCATED AT 250 WORDS)

In vivo inhibition of incorporation of [U-14C]glucose into proteins in experimental focal epilepsy

The in vivo incorporation of [14C] from [U-14C]-glucose into rat brain proteins from different cortical areas was examined in three different experimental focal epilepsies: cobalt, freeze-lesions, and tityustoxin. When [U-14C]-glucose was injected intraperitoneally into awake and unrestrained animals with marked signs of epileptic hyperactivity, the inhibition of incorporation of [14C]-amino acids into trichloracetic acid (TCA)-insoluble proteins was highest in the focal (sensorimotor) area when compared with distant regions (approx. 60%), but less when compared with the contralateral (sensorimotor) region (approx. 23%). Greatly decreased incorporation caused by both cobalt and freeze-lesion-induced epilepsies was also observed in the contralateral area when a comparison was made with distant regions (approx. 50%), but there were no significant differences in protein-specific radioactivity between the different distant areas.

Effect of depolarizing agents on the incorporation of amino acids into soluble cytoplasmic and membrane-bound proteins of synaptosome fractions

The incorporation of [U-14C] protein hydrolysate and [U-14C]leucine into the trichloroacetic acid (TCA)-insoluble membrane and the soluble synaptoplasm proteins of synaptosomes was studied. Following treatment with the depolarizing agents veratrine, Tityus toxin, or potassium, the specific radioactivity of both precursor pool and proteins were measured to examine the link between protein labeling and the fall in the free amino acid pool due to depolarization-induced release of glutamate and aspartate. By reducing the size of the fall in precursor pool due to depolarization by using a nontransmitter amino acid such as leucine (as compared with the usual use of protein hydrolysate), it was shown that the amount of which the pool is reduced is proportional to the change in the protein labeling observed. These results confirm that membrane depolarization causes a large increase in the labeling of membrane-bound proteins as compared with the soluble synaptosomal proteins.

Protein synthesis by astrocytes in primary cultures

Protein synthesis, measured as leucine incorporation into acid-precipitable proteins, was determined in astrocytes in primary cultures obtained from the cerebral hemispheres of newborn mice. As can be expected for eucaryotic, ribosomal protein synthesis, the incorporation was almost completely inhibited by cycloheximide (0.01 mM), but unaffected by chloramphenicol (0.03 mM). The rate of synthesis, measured during exposure to a high (0.8 mM) concentration of leucine was 5.4 nmol/hr/mg protein in mature (i.e., at least 4-week-old) cultures. This value is at least twice as high as the protein synthesis rates reported for the adult brain in vivo, suggesting that a very considerable part of the protein synthesis in the adult brain may take place in astrocytes. The molecular weight distribution of the synthesized proteins was determined by polyacrylamide gel electrophoresis, demonstrating synthesis of at least 50 different polypeptides, ranging in molecular weight between 190,000 and 27,000 daltons. The pattern of the synthesized proteins underwent considerable alteration with age in young cultures in which the total content of protein was still increasing, but it was remarkably stable after the age of two weeks. Exposure to dibutyryl cyclic AMP, which is known to alter morphology, content of glial fibrillary acidic protein (GFA), and activities of certain enzymes in the cultures in the cultured astrocytes, caused marked alterations in the pattern of the synthesized proteins.

Effect of chronic administration and withdrawal of sodium barbitone on protein synthesis of rat brain

After chronic administration of sodium barbitone to rats, a marked increase incorporation of [14C]-Leucine into isolated nerve endings was observed. Withdrawal of the drug resulted in a decreased incorporation with respect to values obtained with chronic ingesting animals. On the other hand chronic administration of the barbiturate produced a decreased incorporation in mitochondrial and microsomal fractions. These results are discussed in relation to the development of tolerance and abstinence syndrome to this drug.

Distribution of protein-bound radioactivity in brain slices of the adult rat incubated with labelled leucine

The distribution of protein-bound labelled leucine in brain cortex slices, prepared from adult rats by various methods and incubated with [14C]- or [3H]leucine, was investigated by autoradiography. In the first and second slices a marked gradient of incorporated radioactivity from the cut surface to the slice interior was observed. Very high labelling of leptomeningeal cells and vessels enhanced further the inhomogeneity of radioactivity distribution. Light microscopic examination of incubated slices revealed morphological alterations of neurones, especially in the vicinity of the cut surface. The comparison of grain density over neurones and their satellite glia indicated markedly higher incorporation into the latter. The ATP level in slices at the end of incubation reflected the method of slice preparation and morphological integrity. Inhomogeneity of incorporated radioactivity distribution in brain slices contrasted with the uniform labelling of cortical cells in vivo, and may represent at least one reason for the low estimates of protein synthesis rate in brain cortex slices.

Effects of anisomycin on brain protein synthesis and passive avoidance learning in newborn chicks

The effects of anisomycin (ANM) on newborn chicks have been studied with respect to brain protein synthesis, growth, EEG, toxicity, and several passive avoidance learning tasks. It was found that intracerebral ANM (80 nmol) gave a maximum inhibition of brain protein synthesis of 30%, while a combination of subcutaneous (10 mumol; 53 mg/kg) plus intracerebral (80 nmol; 21 mug) ANM inhibited by 91% in the first 2 hr and by 75% in the subsequent 2 hr period. Cycloheximide (CXM) also in combined injections at the same doses as ANM, inhibited by 97% in the 4 hr that followed injection. However, all the CXM-injected chicks were dead by 18 hr, while the lethality of ANM did not differ from that of saline. ANM also did not affect EEG measured at 1, 3, 5, or 24 hr following the subcutaneous plus intracerebral injections, nor did ANM affect body or brain growth curves or brain protein accretion. In the learning experiments, animals were initially trained to peck at water-coated metal spheres (type A learning) or at water imbibed birdseed (types B and C learning) in less than 1 sec, and were exposed to the same lures treated with the aversant methylanthranilate (MeA) one day later on one occasion (types A and B learning) or exposed twice (type C learning) and tested for learning retention one day later. Learning criterion was set as failure to peck at the lure during the first 20 sec of presentation. If ANM was injected 1 hr prior to MeA exposure, large and highly significant memory deficits were found during the retention test, as compared with saline injected controls. No effect of ANM was seen, however, if it was injected one day after learning, indicating that it did not interfere with retrieval mechanisms. ANM also decreased the external manifestations of fear or displeasure that chicks express during retention testing. Such manifestations have a high correlation with pecking suppression (r = 0.88, P less than 0.001).

Optimal conditions for protein synthesis in incubated slices of rat brain

Optimal conditions for protein synthesis in incubated slices of rat brain were determined to be: thickness 0.3 mm under air (for newborn 0.4-0.6 mm) or 0.5 mm under oxygen; temperature, 35-36 degrees C; hepes (N-2-hydroxyethylpiperazine-N'-2-ethane sulfonic acid) buffer; K+, 6-8 mM; Ca2+, 2-3 mM. Though maximum incorporation was found with a Na+ concentration of 110-12- mM. Though maximum incorporation was found with a Na+ concentration of 110-120mM, this requirement appears to be partly osmotic. The Na+ concentration may be reduced to 80 mM without inhibition of incorporation provided adjustment is made for osmotic balance. Mg2+. Optimal pH was 7.2-7.4. The rate of protein synthesis in this medium is 0.08-0.09% replacement of the protein amino acid/h in slices from adults and 1.6%/h in slices from 3-day-old rats. Thus slices from adults synthesize protein at 10-20% of the in vivo rate whereas slices at 3-day-old brainincorporate amino acid at 70-80% of the in vivo rate for young rats.

Changes in proteolytic enzymes and proteins during maturation of the brain

(1) Changes during development in the levels of proteinases and peptidases were measured in brain homogenates. At all ages di- and tripeptidase levels were 7-15-fold higher than proteinase activity. (2) Cathepsin A and D and neutral proteinase activity first decreased (during the 5 days before birth) and then increased (primarily during the first 10 days after birth) in development. The total enzyme content per unit weight of brain did not change greatly after 10 days, although specific activity fell owing to an increase in protein in older animals. (3) The developmental pattern of activities or peptidases measured with Leu-Gly and Leu-Gly-Gly and of arylamidases measured with Arg- and Arg-Arg-beta-naphthylamides was similar to that of proteinases. Total and specific activities increased rapidly after birth; then total activity did not change and specific activity decreased. (4) The proteinase content of tissue fractions (nuclear and lysosomal-mitochondrial) similarly reached a maximal peak in the rapid growth phase of the brain. (5) The decrease of hydrolytic activity after 10 days of age seems to parallel a decrease in the rates of protein breakdown in vivo, showing parallel behavior with decreasing protein turnover. In contrast, during the first 10 days of life protein turnover and calculated rate of protein breakdown in vivo decrease while the level of hydrolytic enzymes increases.

Observations on the lipolytic and melanotropic properties of neurophysin proteins

Previous work indicated that brain contains 3 types of lipolytic-melanotropic peptide: (1) in adenohypophysis: ACTH, alpha-MSH, beta-MSH, peptide I, peptide L', beta-lipotropin and gamma-lipotropin; (2) in neurohypophysis: peptide 7D6, also termed neurophysin I, peptide II or Wuu-Saffran peptide; (3) in extrahypophyseal regions: peptide IIF. Bovine and human neurophysin I prepared by R. Walter has now been found devoid of lipolytic and melanotropic activities. Porcine and bovine peptide 7D6, closely similar or identical to bovine neurophysin I in electrophoretic mobility and amino acid composition, were therefore reexamined to determine whether their lipolytic-melanotropic property resided in a contaminating factor. When peptide 7D6 was analyzed in 100 transfer counter current distribution (1 butanol/0.1M NH4 HCO3), the neurophysin was recovered in tubes 1-9 (7D6-alpha) representing 95% of 7D6. 7D6-alpha was inactive in lipolytic and melanotropic assays. The biologic activities of 7D6 were recovered instead in tubes 50-70 (labeled 7D6-beta), representing 5% of 7D6. 7D6-beta proved to be a peptide with MW 1000-3000, closely similar to peptide IIF in amino acid composition, MW, and Rf values in 4 systems of paper chromatography.

A long-term study of the effects of electro-convulsions on the structure of the cerebral cortex

In this study is described the quantitative structure of one circumscribed area of the cerebral cortex 2 months after a series of electro-consulsions. The results indicate a persistent change in the nuclear volume of the cerebral neurons in this area. There was no loss of neurons in the cortex. The changes described are diffuse in the cerebral cortex and not restricted to particular architectonic layers.