Håkan Björklund

Chapter 4 Coexistence of neuronal messengers — an overview

Publisher Summary This chapter discusses results demonstrating that neurons often contain more than one chemical compound. The different types of coexistence situations are described, including (1) a classical transmitter and one or more peptides, (2) more than one classical transmitter, and (3) a classical transmitter, a peptide, and adenosine triphosphate (ATP). The functional significance of these histochemical findings is at present difficult to evaluate, but in studies on the peripheral nervous system evidence has been obtained that classical transmitter and peptide are coreleased and interact in a cooperative way on effector cells. In addition to enhancement, there is evidence that other types of interactions may occur—for example, the peptide may inhibit the release of the classical transmitter. Also in the central nervous system (CNS), indirect evidence is present for similar mechanisms—that is, to strengthen transmission at synaptic (or non-synaptic) sites and for the peptide inhibition of release of a classical transmitter. Multiple messengers may provide the means for increasing the capacity for information transfer in the nervous system.

Short- and long-term consequences of intracranial injections of the excitotoxin, quinolinic acid, as evidenced by GFA immunohistochemistry of astrocytes

Astroglial reactions to intrastriatal and intrahypothalamic injections of the endogenous excitotoxin quinolinic acid (50 micrograms in 1 microliter) were studied in adult rats, using immunohistochemistry with antiserum to glial fibrillary acidic protein. Animals were sacrificed 6 h, 24 h, 3, 7 and 30 days or 1 year after the injection. Six and 24 h after quinolinic acid, the amount of glial fibrillary acidic protein-like immunoreactivity in the injected striatum was lower than in controls but returned to a normal level at 3 days. Not until 7 days was a clear striatal gliosis apparent, as evidenced by an increased density of glial fibrillary acidic protein-positive structures and brightly fluorescent, clearly hypertrophic cells. This gliosis was even more developed in animals sacrificed 30 days postoperatively. A weak astrocytic reaction was also observed in the ipsilateral corpus callosum at 6 h after quinolinic acid. By 3 days, a marked gliosis restricted to the injected hemisphere was present throughout corpus callosum and cortex cerebri. In animals sacrificed 30 days after quinolinic acid the extrastriatal astrocytic reaction was clearly diminished, although the striatal gliosis was still prominent. One year postinjection, no obvious gliosis could be observed in cortex cerebri or corpus callosum while striatal tissue, now markedly reduced in volume, was clearly gliotic. Using neurofilament antiserum, increased fluorescence intensity was noted in striatal nerve bundles during the first day after an intrastriatal quinolinic acid injection and persisted 1 year postoperatively. Controls were similarly injected with an equimolar amount of nicotinic acid, the non-excitatory, non-neurotoxic decarboxylation product of quinolinic acid. No changes in immunoreactivity of glial fibrillary acidic protein or neurofilament were found in these animals. In animals treated intrahypothalamically, a spherical central area almost devoid of glial fibrillary acidic protein-immunoreactivity was noted around the injection site 7 days after quinolinic acid administration. Around this area, gliosis was observed. Apart from a very restricted gliotic reaction around the needle tract, no astrocytic reaction was observed in nicotinic acid-injected control animals. We conclude that quinolinic acid causes both reversible and long-lasting gliosis when injected into the rat striatum. As a natural brain metabolite, quinolinic acid may constitute a particularly valuable tool for the elucidation of a possible role of glia in neurodegenerative disorders.

Sensory and autonomic innervation of non-hairy and hairy human skin

SummaryNon-hairy and hairy human skin were investigated with the use of the indirect immunohistochemical technique employing antisera to different neuronal and non-neuronal structural proteins and neurotransmitter candidates. Fibers immunoreactive to antisera against neurofilaments, neuron-specific enolase, myelin basic protein, protein S-100, substance P, neurokinin A, neuropeptide Y, tyrosine hydroxylase and vasoactive intestinal polypeptide (VIP) were detected in the skin with specific distributional patterns. Neurofilament-, neuron-specific enolase-, myelin basic protein-, protein S-100-, substance P-, neurokinin A-and vasoactive intestinal polypeptide (VIP)-like immunoreactivities were found in or in association with sensory nerves; moreover, neuron-specific enolase-, myelin basic protein-, protein S-100, neuropeptide Y-, tyrosine hydroxylase- and vasoactive intestinal polypeptide (VIP)-like immunoreactivities occurred in or in association with autonomic nerves. It was concluded that antiserum against neurofilaments labels sensory nerve fibers exclusively, whereas neuron-specific enolase-, myelin basic protein- and protein S-100-like immunoreactivities are found in or in association with both sensory and autonomic nerves. Substance P- and neurokinin A-like immunoreactivities were observed only in sensory nerve fibers, and neuropeptide Y- and tyrosine hydroxylase-like immunoreactivities occurred only in autonomic nerve fibers, whereas vasoactive intestinal polypeptide (VIP)-like immunoreactivity was seen predominantly in autonomic nerves, but also in some sensory nerve fibers.

Astrocyte responses to dopaminergic denervations by 6-hydroxydopamine and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine as evidenced by glial fibrillary acidic protein immunohistochemistry.

Astrocytic responses to dopaminergic denervation by two widely used dopamine neurotoxins, 6-hydroxydopamine (6-OHDA) and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) were monitored using immunofluorescence with antibodies against glial fibrillary acidic protein (GFA) while neurofilament (NF) antibodies were used to monitor neuronal disturbances. Following stereotaxic injection of 6-OHDA into the nigrostriatal dopamine bundle in rats, an increased amount of GFA-immunoreactivity in striatum was detectable after 24 hours and remained after one month. Retrograde degeneration of nigral neurons led to gliosis in the cell body area. At the site of injection, astrocytes were destroyed and NF-immunoreactivity increased. New astrocytes invaded the injection area during the first month after injection. MPTP given systemically to mice in a dose that causes marked dopaminergic denervation of striatum also caused marked increases of GFA-immunoreactivity in striatum. These changes were larger in C57 BL/6 mice, known to be more sensitive to MPTP, than in N.M.R.I. mice, which are less sensitive to MPTP. The glial responses to MPTP-induced dopaminergic denervation did not occur when the dopamine neurotoxic effects were prevented by pretreatment with nomifensine or pargyline. It is concluded that dopaminergic denervation by neurotoxins causes rapid and profound changes in striatal astrocytes characterized by increased GFA-immunoreactivity. These changes remained up to a month after denervation and should be taken into account when functional consequences of dopaminergic denervations are discussed.

Image analysis of GFA-positive astrocytes from adolescence to senescence

SummarySmears of fresh rat brain tissue combined with immunohistochemistry using antiserum to glial fibrillary acidic protein (GFA) were used to visualize individual astrocytes in different cortical regions of rats ranging in age from 1 to 30 months. By computerized image analysis, the cell area and the cell perimeter were determined. Using 4-month-old male Sprague-Dawley rats, it was found that GFA-positive astrocytes from cerebellum and hippocampus were significantly larger, both in terms of cell area and cell perimeter, than similar cells from cortex cerebri. The temporal development was carefully followed in smears of the hippocampal formation where a continuous increase in cell size was observed from 1 to 30 months of age. During the first few postnatal months a rapid increase in both cell area and cell perimeter was observed using Sprague-Dawley rats. For studies of senescent animals, Fisher 344 rats specifically bred for aging studies were obtained. Using such animals, a second, highly significant slower growth phase which continued until the longest time points studied was observed. A separate experiment using Sprague-Dawley rats also showed large differences in both cell area and cell perimeter of GFA-positive cerebellum and cortical astrocytes taken from 6-week- and 18-month-old animals. In conclusion, the present study shows that maturation of GFA-positive astrocytes is a process which continues for several months postnatally. This relatively rapid growth phase is followed by a slower increase in cell size, probably continuing throughout life.

Immunohistochemical demonstration of glial fibrillary acidic protein in normal rat Müller glia and retinal astrocytes

The presence of glial fibrillary acidic protein (GFA)-positive Müller glia and retinal astrocytes were studied immunohistochemically in normal rat retina. Using GFA antiserum both Müller glia and separate star-shaped cells were observed in spread-preparations as well as cryostat sections. The retinal astrocytes were also visualized using two different monoclonal GFA antibodies. These cells were found to be located in the nerve fiber and ganglion cell layers. In contrast, Müller glia were not normally visualized with any of the monoclonal GFA antibodies but could be stained 4 days after an optic nerve crush. Our results demonstrate that normal rat Müller glia expresses GFA-like immunoreactivity.

Laminin immunohistochemistry: a simple method to visualize and quantitate vascular structures in the mammalian brain

Immunohistochemistry using antiserum against the basement membrane glycoprotein laminin, was shown to be an excellent marker for brain blood vessels. Throughout the brain of mice, rats, guinea pigs, monkeys and humans, the basement membrane of the vascular structures were strongly laminin-positive. The neuropil itself was laminin-negative, whereas a positive reaction was observed in the meaninges. When the laminin antiserum was preabsorbed with its proper antigen, no specific fluorescence was observed. Using India ink perfusion as a comparative method, it was found that probably all vascular structures were also visualized with laminin immunohistochemistry. Laminin immunofluorescence was found well-suited for computer-assisted quantitative image analysis of brain vascularity. As expected in the periphery, the basement membrane of many other structures except blood vessels such as endoneurium, epithelium and smooth muscle cells were laminin-positive. Although the vascular network was also strongly laminin-immunoreactive, it was difficult to differentiate between blood vessels and non-vascular structures in the periphery as compared to the central nervous system. In conclusion, laminin immunohistochemistry has proven to be a simple, useful and specific method to study vascular structures in the central nervous system and an excellent alternative to more conventional and laborious methods such as perfusion with India ink.

Distribution of neurofilament-immunoreactive nerve fibers in human skin.

SummaryNeurofilament immunoreactive nerve fibers were demonstrated in human skin using indirect immunohistochemical technique with antibodies to neurofilament polypeptides. Neurofilament-positive fibers were seen as free nerve endings in the epidermis and in dermal papilla, in Meissners corpuscles and as fibers crousing in the dermis. Strongly fluorescent nerve fibers were also seen around hair follicles, sweat gland ducts and sometimes in relation to blood vessels. From the distribution pattern it was concluded that predominantly sensory nerve fibers were labelled and that this technique may be used to study reinnervation of cutaneous sensory nerved following tramatic injuries and surgical procedures.

Trophic effects of brain areas on the developing cerebral cortex: I. Growth and histological organization of intraocular grafts

Trophic interactions during development of brain regions were examined in rats using intraocular grafts of central nervous tissue. The increase in volume of transplanted fetal parietal cerebral cortex, as measured through the cornea, was markedly augmented by the presence of several different previously grafted CNS areas such as locus coeruleus, tectum, or cerebral cortex. DNA measurements and histological examinations suggested that this increased volume was due both to hyperplasia and hypertrophy. Previous grafts of iris, in contrast, did not significantly alter the final size of subsequently grafted cortex pieces. Contact between the two transplants was found to be critical in eliciting the trophic response. Growth-stimulated cortical grafts had a better organized cyto-architecture with larger neurons, including typical pyramidal cells, more neuropil, a lower cell density, and a more organotypic distribution of the cell bodies than non-stimulated controls. The experiments thus demonstrate a profound effect of adjacent neural tissue on development of neocortex. It is concluded that trophic interactions upon brain development can be revealed by sequential intraocular grafting.

Astrocytic development in fetal parietal cortex grafted to cerebral and cerebellar cortex of immature rats.

Pieces of cortex cerebri anlage were dissected out from 16- to 17-day-old fetuses and transplanted to the cortical and cerebellar regions of 5- to 6-day-old rat pups. Twelve animals with grafts in the cortical region and 5 animals with grafts in the cerebellar region were studied 1.5-4 months later. Cresyl violet stained sections revealed no gross difference in either cell morphology, cell density or cell distribution between grafts in the two locations. A molecular layer-like zone was present on all free surfaces of the grafts, whether facing a ventricle or the meninges. The astrocytic development was studied using immunohistochemistry with antibodies against glial fibrillary acidic protein, (GFA), and the S-100 protein. Both antibodies visualized starshaped astrocytes and perivascular membranes surrounding blood vessels. Semi-quantitative measurements as well as computerized image analysis showed that the total amount of GFA-like immunoreactivity was much higher in both types of grafts than in corresponding host cortex cerebri. No differences in amount of S-100-like immunoreactivity could be demonstrated. As S-100 is thought to be a more general astrocytic marker than GFA, this suggests that the difference in GFA-like immunoreactivity is due mainly to an increased amount of GFA within the individual astrocytes. It is concluded that grafts of fetal cortex cerebri pieces to the CNS of young hosts develop a profound astrocytic reaction characterized by an increased amount of GFA-like immunoreactivity.