Developmental changes in activity of choline acetyltransferase, acetyl-cholinesterase and glutamic acid decarboxylase in the central nervous system of the toad. Xenopus laevis

Acetylcholinesterase in immature thalamic neurons: relation to afferentation, development, regulation and cellular distribution

The transient appearance of intense acetylcholinesterase reactivity in some immature, noncholinergic neurons has not been adequately explained. In this study two questions were investigated that relate to several possible roles for acetylcholinesterase. First, what factors influence the onset and maintenance of reactivity? Second, what are the temporal and spatial features of the cellular expression in relation to stages of neuronal development? Using light- and electron-microscopic histochemical methods, the non-cholinergic ventrobasal complex in thalamus of the immature rat was examined. Ultrastructural observations on fetal ventrobasal complex demonstrated that the onset of acetylcholinesterase reactivity precedes ingrowth of most extrinsic afferents. These inputs are, therefore, unlikely to provide the signal for onset. In transplants and explants, acetylcholinesterase persisted in ventrobasal complex neurons independent of their principal afferents. However, afferentation can affect reactivity. The patterned variation in intensity, characteristic of infant ventrobasal complex, was dramatically altered by unilateral interruption of its afferentation. The changes in intensity patterning could reflect changes in acetylcholinesterase metabolism, since postnatal treatment with an irreversible inhibitor (diisofluorophosphate) in vivo demonstrated resynthesis of acetylcholinesterase. The period of peak intensity of acetylcholinesterase reactivity normally began abruptly at 18 days of gestation +/- 12 h and continued until 4-6 days postnatally. This period follows neurogenesis and migration, but precedes active synaptogenesis. It coincides with outgrowth and initial contacting of cell processes in the ventrobasal complex. The timing complements the ultrastructural finding that acetylcholinesterase-dependent reaction product most commonly is localized to small patches of surface membrane, where distal processes contact each other, non-synaptically. Together these data suggest three points. First, that the expression of acetylcholinesterase in the immature ventrobasal complex neuron is probably under active metabolic control, responsive to both intrinsic and environmental factors. Second, that acetylcholinesterase expression is unlikely to result from a transient cholinergic input. Third, that the temporal and spatial characteristics of histochemical reactivity enable exclusion of several previously suggested explanations for the occurrence of acetylcholinesterase in the ventrobasal complex.(ABSTRACT TRUNCATED AT 400 WORDS)

The development of acetylcholinesterase activity in the embryonic nervous system of the frog, Xenopus laevis

Histochemical detection of acetylcholinesterase (AChE) activity in Xenopus embryos was found first in primary motoneurons, Rohon-Beard neurons and somitic myotubes at early tail bud stages. At late tail bud stages all primary neurons, including primary interneurons, cranial ganglion cells and ventral brainstem cells expressed this enzyme. The onset of detectable AChE activity in some primary neurons occurred near the time of initial axon outgrowth, whereas in others it occurred at much later stages. At early independent-feeding and continuous-swimming stages nearly all seemingly postmitotic neurons began to express AChE activity, and by the beginning of limb bud stages, when many secondary neuronal populations were going through their final rounds of mitosis, nearly all CNS cells outside the ventricular zone were intensely stained. Thus, the onset of detectable AChE activity in secondary neurons occurred near the time of their final mitoses. In trunk somites the enzyme activity initially was located diffusely throughout the myotube, and with progressing development it became localized to the myocommata. From the onset of AChE activity both head somites and head muscles had discrete patches of reaction product all over their surfaces. The onset of detectable AChE activity occurred in muscles near the time that they were contacted by motor axons. These data demonstrate that the primary neurons are the first to express AChE activity, and that as the secondary neurons begin to proliferate, AChE is expressed by nearly all embryonic neuronal populations.

Molecular biology and neurobiology of choline acetyltransferase

In the 45 years since the first description of choline acetyltransferase (ChAT; EC 2.3.1.6.), significant progress has been made in characterizing the molecular properties of this important neurotransmitter synthetic enzyme. We are now on the verge of understanding its genetic regulation and biological function(s). The Drosophila cDNA has been cloned, sequenced, and expressed in both a eucaryotic and a procaryotic system. The levels of ChAT specific mRNA have been determined during Drosophila development. Monoclonal and polyclonal antibodies have been produced to the enzyme from a variety of sources and used for biochemical and immunocytochemical studies. Two well characterized genetic systems have identified the ChAT gene and described a series of useful alleles. As a nervous system specific protein expressed only in the subset of neurons using acetylcholine as a neurotransmitter, ChAT is a good model for uncovering the processes and factors responsible for regulating genes involved in neurotransmitter phenotype selection and maintenance. Recent studies have described the purification of a cholinergic factor from muscle conditioned medium and indicated the potential importance of nerve growth factor (NGF) for regulating ChAT expression in the central nervous system. These factors, or ones remaining to be discovered, may be involved in the etiology or disease process of neurodegenerative nervous system disorders such as Alzheimer's disease.

Postmortal decay of acetylcholine levels in the spinal cord of rat, chicken and frog

The decay of acetylcholine (ACh) after death of an animal has been estimated in the cervical spinal cord of rat, chicken and frog. The level of ACh in the frog (19.90 nmol/g wet weight) shows no variation from 20 to 500 s after death. In the rat and chicken, there is a decrease in the first 100 s after death to lower values; 4.35 nmol/g wet weight in the rat and 4.60 nmol/g wet weight in the chicken. The levels of ACh in the cervical spinal cord of the rat an chicken at the time of death were estimated by extrapolation to time 0 of the curve of the decay of ACh in the first 100 s. The values obtained were: 121.64 nmol/g wet weight in the chicken and 34.19 nmol/g wet weight in the rat.

Developmental reorganization of acetylcholinesterase-rich inputs to somatosensory cortex of the mouse

In this histochemical study, maturational changes in acetylcholinesterase-(AChE) staining in the barrel field of mouse somatosensory cortex were traced. Three distinct stages in the maturation of the AChE positive barrel innervation of mouse can be observed. In the first stage, individual AChE-positive fibers are initially detected in layer IV between 4-5 days postnatal (dpn). This lamina remains lightly stained for the next several days. At 11-12 dpn there is an abrupt increase in the intensity of AChE activity in the barrel hollows, that marks the beginning of the second stage. In the third stage between 17 and 21 dpn, this AChE-rich plexus of fibers is reorganized in the following manner. AChE fiber staining of the barrel hollows becomes limited to the superficial 75-100 microns of barrel depth, i.e. at the boundary between layers III and IV. At deeper levels in layer IV only the septae are AChE-positive. These observations differ from those previously reported for the rat, both in terms of the organization and development of the AChE-positive innervation to the barrels. The present work also provides the first indication that there is a stratification of inputs to the barrels.