The biochemistry of memory: a new and specific hypothesis

Long-term potentiation of synaptic acetylcholine release in the superior cervical ganglion of the rat

The release of endogenous acetylcholine (ACh) from the in vitro rat superior cervical ganglion was measured by assaying the bathing medium. Simultaneously, synaptic transmission in the ganglion was assessed by recording post-ganglionic compound action potentials. A brief period of tetanic preganglionic stimulation (20 Hz for 20 s) induced a long-term potentiation of the post-ganglionic compound action potential. The same tetanic stimulation also consistently induced a long-term potentiation of stimulated ACh release. Spontaneous (non-stimulated) ACh release was not enhanced after tetanic stimulation. The content of ACh in the ganglion was not measurably increased after tetanic stimulation. These results suggest that the long-term increase in synaptic efficacy is due, at least in part, to an increase in the amount of ACh released by the afferent impulse.

The effects of a calcium dependent protease on the ultrastructure and contractile mechanics of skinned uterine smooth muscle

In situ substrates for a vascular smooth muscle calcium-dependent protease (CDP) were investigated using a chemically skinned uterine smooth muscle preparation. Treatment of skinned smooth muscles with CDP had no effect on the total content of actin and myosin. Electron microscopical observations demonstrated that membrane plaques, cytoplasmic dense bodies, and intermediate filaments were all degraded by CDP. In addition, CDP reduced both isometric force and isotonic shortening velocity of contracted muscles in a concentration and time-dependent manner. Treatment of contracting muscles with CDP resulted in a condensation of myofilaments away from the plasma membrane concurrent with the loss of contractility. The condensation of myofilaments was ATP-dependent and could be inhibited by removal of ATP prior to proteolysis. The effects of proteolysis on smooth muscle ultrastructure and contractility support previously proposed models which assign a role to cytoskeletal elements in coordinating the molecular interaction of actomyosin to produce muscle contraction. The loss of cytoskeletal structures following protease treatment suggests that one of the functions of CDP in smooth muscle may be the disassembly of the cell cytoskeleton.

Pharmacological dissociation of memory: anisomycin, a protein synthesis inhibitor, and leupeptin, a protease inhibitor, block different learning tasks

Inhibition of protein synthesis by anisomycin for a short duration impairs memory of a one-trial inhibitory avoidance task in rats. Memory of escape conditioning involving eight trials is disrupted only if the duration of protein synthesis is prolonged by repeated injections. In marked contrast, olfactory memory of rats trained on two odor discriminations is not affected by anisomycin even if the duration of inhibition is prolonged and the number of trials is reduced to a minimum. In previous work, leupeptin, a thiol proteinase inhibitor, was shown to impair olfactory discrimination learning, but left inhibitory and avoidance conditioning intact. Together, these results provide a pharmacological double dissociation of memory, and suggest that the same chemistries, or mixtures of chemistries, may not be involved in all types of memory.

The postsynaptic density: a possible role in long-lasting effects in the central nervous system

A theory is proposed that biochemical changes at the synapse that occur as a result of stimulation of specific neuronal circuits can lead to long-term changes only if alterations occur in synaptic structures in these circuits. The main synaptic structure that is thought to undergo this alteration is the postsynaptic density (PSD). There are many reports in the literature of overall structural changes at the synapse, including the PSD, resulting from various neuronal stimuli. These structural changes are here envisaged to include those of concentration and conformation of PSD proteins, changes that could alter the neural physiology of dendritic spines and even that of the presynaptic terminal.

Putative amino acid transmitters in lumbar cerebrospinal fluid of patients with histologically verified Alzheimer's dementia

Concentrations of individual free amino acids were determined in lumbar cerebrospinal fluid (CSF) from patients with various complaints including histologically verified Alzheimer's dementia. Glycine and glutamine in the CSF of Alzheimer's dementia samples were lower than that of control samples. Only the concentration of glutamic acid in Alzheimer's dementia patients correlated with psychological measures. The reduction in glycine concentration was not specific for Alzheimer's dementia.

Phosphorylation-dependent subcellular translocation of a Ca2+/calmodulin-dependent protein kinase produces an autonomous enzyme in Aplysia neurons

We have shown previously that the subcellular distribution of a major calmodulin-binding protein is altered under conditions causing increased synthesis of cAMP in Aplysia neurons (Saitoh, T., and J. H. Schwartz, 1983, Proc. Natl. Acad. Sci. USA, 80:6708-6712). We now provide evidence that this Mr 55,000 protein is a subunit of a Ca2+/calmodulin-dependent kinase: (a) both the Mr 55,000 calmodulin-binding protein and kinase activity are loosely attached to the membrane-cytoskeletal complex; (b) both kinase activity and the Mr 55,000 protein are translocated from the membrane-cytoskeleton complex to the cytoplasm under conditions that cause the change in the subcellular distribution of the Mr 55,000 calmodulin-binding protein; and (c) calmodulin-binding activity of the Mr 55,000 protein and the ability to carry out the Ca2+/calmodulin-dependent phosphorylation of synapsin I are purified in parallel. The subcellular localization of the Ca2+/calmodulin-dependent protein kinase appears to be under control of two second messengers: Ca2+ and cAMP. We find that the Mr 55,000 subunit is phosphorylated when the extracted membrane-cytoskeleton complex is incubated with Ca2+, calmodulin, and ATP, with the concomitant release of this phosphorylated peptide from the complex. Previously, we had found that, when translocation occurs in extracts in the presence of cAMP and ATP (but in the absence of Ca2+), there was no detectable phosphorylation of the Mr 55,000 subunit itself. The subcellular distribution of the subunit thus appears to be influenced by (a) cAMP-dependent phosphorylation, which, we infer, modifies some as yet unidentified structural component, causing the release of the enzyme; and (b) Ca2+/calmodulin-dependent phosphorylation of the Mr 55,000 subunit. These studies also suggest that phosphorylation has an important regulatory consequence: during the Ca2+/calmodulin-dependent translocation of the Mr 55,000 subunit, the kinase appears to be activated, becoming independent of added Ca2+/calmodulin.

Regulation of phosphate incorporation into four brain phosphoproteins that are affected by experience

Various regulators of protein kinase activities were tested for their effects on the in vitro transfer of phosphate from [gamma-32P]ATP to four proteins of rat brain synaptic particulate preparations. One protein, of apparent molecular weight 44,000, accepted 32P in the presence of 8 mM EDTA and no added Mg2+. It was the major phosphoprotein of brain mitochondria. Its phosphorylation was inhibited by pyruvate and stimulated by K+, and it comigrated in electrophoretic gels with authentic alpha-subunit of pyruvate: lipoamide oxidoreductase (decarboxylating) (EC 1.2.4.1) from bovine heart. The major kinase acting on three proteins of apparent molecular weights 24,000, 21,000, and 19,000 was stimulated by Ca2+, by preincubation with phospholipase C, and by 12-tetradecanoyl 4-beta-phorbol 13-acetate. Phosphorylation of these lower-molecular-weight proteins was inhibited by ACTH1-24, by cyclic 3',5'-adenosine monophosphate, and by 50 microM trifluoperazine. The stimulatory effect of Ca2+ was antagonized by calmodulin. The kinase in question appears to be B-50 protein kinase or protein kinase C.

Increased binding of calcium in the hippocampal slice during long-term potentiation

Long-term potentiation (LTP) of CA1 pyramidal neurons was induced by tetanic stimulation in the stratum radiatum of hippocampal slices from guinea pigs. Unstimulated and stimulated slices were treated using a histochemical procedure enabling the electron microscopic (EM) visualization of Ca binding sites. Electron-dense, Ca-containing deposits were found in low numbers in unstimulated slices on pre- and postsynaptic sites. In the stratum radiatum of tetanized slices the overall number of deposits as well as the number of deposits in dendrites was clearly increased. The results support the hypothesis that Ca-dependent postsynaptic mechanisms are important for the generation of LTP.

Some observations on the kindling process

Kindling is an animal model of epilepsy in which repeated administration of a subconvulsant stimulus, electrical or chemical, produces a gradually increasing electroencephalographic and behavioral response which culminates in a behavioral seizure. The biological basis of the kindling effect remains unknown but alterations in neurotransmission figure prominently in most hypotheses. Several factors of kindling are considered as central to the phenomenon. It is most important to recognize that the development of kindling and a kindled seizure are not necessarily the same phenomenon. Kindling is essentially a permanent change in the sensitivity of the brain to a stimulus. It therefore follows that the biological basis for kindling must be a permanent change. Permanent changes in neurotransmitter levels or receptor parameters have not been conclusively demonstrated in kindling. Other possible permanent changes include changes in Ca++ activated mechanisms which alter neuronal structures such as dendritic spines. An essential component to the riddle of kindling is the absolute requirement for an inter-stimulus interval of at least 1-2 hours. This suggests that the biological process which leads to kindling occurs in this critical period. Recent experiments with cysteamine suggest that the events in this critical period can be manipulated chemically. An understanding of these events will help to clarify the biological basis of kindling.

Oxygen deficiency and brain damage: localization, evolution in time, and mechanisms of damage

Observations on some patients with CO intoxication have revealed a delayed type of brain injury, with symptoms appearing days after the initial insult. Possible mechanisms are discussed, with reference to recent experimental results on ischemic brain damage. These results have shown that brief periods of ischemia can cause necrosis of selectively vulnerable neurons, sometimes after a delay of 1-3 days. In at least one affected cell type (CAI pyramids in the hippocampus) delayed neuronal death was preceded by cellular hyperactivity. Recent neurochemical research offers tentative explanations. For example, several reactions triggered by increased calcium concentrations are long-lasting enough to cause sustained alteration of cell function and/or delayed neuronal death. These encompass physical interruption of the cytoskeleton by disassembly of microtubuli and degradation of neurofilaments, protein phosphorylation, and proteolytic degradation of dendritic structures. Reactions interrupting the cytoskeleton could cause cell death by impeding axonal transport, while phosphorylation-proteolysis could induce increased synaptic efficacy, with harmful overactivity.

Long-term potentiation in the hippocampus involves activation of N-methyl-D-aspartate receptors

A series of omega-phosphono-alpha-carboxylic acids were tested as antagonists of excitatory amino acid depolarizations and long-term potentiation (LTP) in region CA1 of rat hippocampal slices. The 5- and 7-phosphono compounds (+/- AP5 and +/- AP7) blocked N-methyl-D-aspartate (NMDA) depolarizations and prevented the induction of LTP of the synaptic field potential and population spike components of the Schaffer collateral response. +/- AP5 and +/- AP7 did not reduce kainate or quisqualate depolarizations and did not affect unpotentiated synaptic response amplitude. +/- AP4, +/- AP6 and +/- AP8 did not block amino acid excitant responses or LTP. These results demonstrate that NMDA receptors present in hippocampal region CA1 are not necessary for normal synaptic transmission, but are involved in the initiation of long-term synaptic plasticity.

The distribution of neurons containing delta sleep-inducing peptide in the hippocampal formation

The distribution of neurons containing immunoreactive delta sleep-inducing peptide (IDSIP) in the hippocampal formation was investigated by immunocytochemistry. For this study, thirteen antisera to the peptide were used. Three antisera were found suitable for immunocytochemistry; the remainder gave only non-specific background staining. Neurons containing IDSIP were demonstrable in the subicular cortex immediately adjacent to CA1. No specific staining was found in other parts of the hippocampal formation including the pyramidal layer of Ammon's Horn and the dentate gyrus. These three antisera also stained cells in the cerebral cortex-primarily temporal, parietal and frontal regions--as well as in the ventral forebrain, although the number of cells in each area varied somewhat with the different antisera. The presence of IDSIP in neurons which constitute the major efferent pathway of the hippocampus, as well as in areas known to be functionally related to the hippocampus, i.e., the adjacent isocortices and ventral forebrain, suggests a possible role for the peptide in the regulation of behavior.

Brain spectrin: a review

Red blood cell spectrin, along with actin and several other proteins, forms a skeletal meshwork on the cytoplasmic surface of the erythrocyte plasma membrane. This structure is thought to maintain red blood cell shape, membrane structural stability, and cellular elasticity, as well as controlling the lateral mobility of integral membrane proteins and the transbilayer movement of phospholipids. It is now clearly established that spectrin-related molecules are ubiquitous structural elements subjacent to the plasma membrane of mammalian and avian nonerythroid cells. In this review, we present the current knowledge concerning brain spectrin. Brain spectrin is an approximately 11S, approximately 1,000,000 molecular weight (alpha beta)2 tetramer containing subunits of 240,000 (alpha) and 235,000 (beta) molecular weight. It is present in the cortical cytoplasm of all neuronal cell bodies and processes, and to a lesser extent in glial cells. Its involvement in the actin-membrane interaction, as well as other proposed functions in the nervous system is discussed.

Pentoxifylline reverses age-related deficits in spatial memory

Pentoxifylline, a phosphodiesterase inhibitor, produces a marked reversal of an age-dependent spatial memory deficit in Fischer 344 strain male rats. Performance of 26-month-old animals treated chronically with pentoxifylline approached that of 3-month-old controls. The effect was not dependent upon concurrent administration of the acetylcholine precursor choline chloride. It is concluded that the pentoxifylline-induced reversal of the age-dependent memory decline is not dependent on any presumed facilitation of acetylation and utilization of exogenously supplied transmitter substrate.