Maria Luisa Lucchi

Anatomical evidence for ileal Peyer’s patches innervation by enteric nervous system: a potential route for prion neuroinvasion?

We have examined the innervation of the gut-associated lymphoid system of the sheep ileum, with a view to identifying potential sites for neuroinvasion by pathogens, such as prions (PrPSc). Special attention has been paid to the follicles of Peyer’s patches (PPs), which are major sites of PrPSc accumulation during infection. Evidence exists that the enteric nervous system, together with the parasympathetic and sympathetic pathways projecting to the intestine, are important for PrPSc entry into the central nervous system. Thus, PrPSc might move from PPs to the neurons and nerve fibres that innervate them. We investigated, by immunohistochemistry and retrograde tracing (DiI) from the follicles, the distribution and phenotype of enteric neurons innervating the follicles. Antibodies against protein gene product 9.5, tyrosine hydroxylase, dopamine β hydroxylase, choline acetyltransferase, calbindin (CALB), calcitonin gene-related peptide (CGRP), and nitric oxide synthase were used to characterise the neurons. Immunoreactivity for each of these was observed in fibres around and inside PP follicles. CGRP-immunoreactive fibres were mainly seen at the follicular dome. Retrograde tracing revealed submucosal neurons that contributed to the innervation of PPs, including Dogiel type II neurons and neurons immunoreactive for CALB and CGRP. The major source of the adrenergic fibres are the sympathetic ganglia. Our results thus suggest that enteric and sympathetic neurons are involved during the first stage of neuroinvasion, with neurons connecting to them acting as potential carriers of PrPSc to the central nervous system.

Characterisation of neurons expressing calbindin immunoreactivity in the ileum of the unweaned and mature sheep.

We have identified the enteric neuron types expressing immunoreactivity for the calcium-binding protein calbindin D28k (CALB) in cryostat sections and whole-mount preparations of myenteric (MP) and submucosal (SMP) plexuses of sheep ileum. We wished to determine whether CALB-IR in the sheep enteric nervous system was expressed in Dogiel type II cells, as in guinea-pig and rat ileum, and could therefore be used as a marker for intrinsic primary afferent neurons. The neurochemical coding of CALB-containing myenteric and submucosal neurons in ileum of unweaned lamb and mature sheep and its co-localisation with various neural markers was studied immunohistochemically. An antiserum against neuronal nuclear protein (NeuN) failed to detect the entire neuronal population; it was expressed only in 48% of neuron-specific enolase (NSE)-immunoreactive (NSE-IR) neurons. Human neuronal protein appeared to occur in the large majority or all neurons. Almost all CALB-IR neurons were: (1) radially multidendritic; (2) eccentric multidendritic; (3) Dogiel type II. CALB-IR occurred in 20–25% of myenteric and 65–75% of submucosal neurons in lamb and mature sheep, with higher values in mature sheep. Nearly all CALB-IR neurons were common choline acetyltransferase (cChAT)-IR, whereas only about 20% of cChAT-IR somata were CALB-IR. In lamb and mature sheep, 90% of MP CALB-IR neurons were peripheral choline acetyltransferase (pChAT)-IR. In lamb SMP, 80±13% of CALB-IR cells were also pChAT-IR, whereas all those in mature SMP were pChAT-IR. Fewer myenteric CALB-IR neurons exhibited tachykinin (TK) in mature sheep (49%) than in lamb (88%). This was also the case for submucosal ganglia (mature sheep, 63%; lamb, 89%). In lamb MP, 77±7% of CALB-IR cells were NeuN-positive. In mature sheep, 73±10% of CALB-IR somata were NeuN-IR, but NeuN failed to stain SMP neurons. In the MP of suckling and mature sheep, Dogiel type II CALB-IR neurons were calcitonin gene-related peptide (CGRP)-IR. In the SMP at both stages, Dogiel type II CALB-IR somata (about 50% of CALB-IR neurons) were also CGRP-IR. Only small proportions of CALB-IR neurons showed immunoreactivity for calretinin or nitric oxide synthase (NOS), although large populations of CALB and NOS neurons occurred in the ganglia. Thus, CALB is a marker of most Dogiel type II neurons in the sheep but is not confined to Dogiel II neurons. CGRP is a more selective marker of Dogiel type II neurons, being only found in this neuron type.

Central projections and entries of capsaicin-sensitive muscle afferents.

The entry pathway and central distribution of A delta and C muscle afferents within the central nervous system (CNS) were investigated by combining electron microscopy and electrophysiological analysis after intramuscular injection of capsaicin. The drug was injected into the rat lateral gastrocnemius (LG) and extraocular (EO) muscles. The compound action potentials of LG nerve and the evoked field potentials recorded in semilunar ganglion showed an immediate and permanent reduction in A delta and C components. The morphological data revealed degenerating unmyelinated axons and terminals in the inner sublamina II and in the border of laminae I-II of the dorsal horn at L4-L5 and C1-C2 (subnucleus caudalis trigemini) spinal cord segments. Most degenerating terminals were the central bouton (C) of type I and II synaptic glomeruli. Furthermore, degenerating peripheral axonal endings (V2) presynaptic to normal C were found. Since V2 were previously found degenerated after cutting the oculomotor nerve (ON) or L4 ventral root, we conclude that some A delta and C afferents from LG and EO muscles entering the CNS by ON or ventral roots make axoaxonic synapses on other primary afferents to promote an afferent control of sensory input.

Inhibition of muscle spindle afferent activity during masseter muscle fatigue in the rat

The influence of muscle fatigue on the jaw-closing muscle spindle activity has been investigated by analyzing: (1) the field potentials evoked in the trigeminal motor nucleus (Vmot) by trigeminal mesencephalic nucleus (Vmes) stimulation, (2) the orthodromic and antidromic responses evoked in the Vmes by stimulation of the peripheral and central axons of the muscle proprioceptive afferents, and (3) the extracellular unitary discharge of masseter muscle spindles recorded in the Vmes. The masseter muscle was fatigued by prolonged tetanic masseter nerve electrical stimulation. Pre- and postsynaptic components of the potentials evoked in the Vmot showed a significant reduction in amplitude following muscle fatigue. Orthodromic and antidromic potentials recorded in the Vmes also showed a similar amplitude decrease. Furthermore, muscle fatigue caused a decrease of the discharge frequency of masseter muscle spindle afferents in most of the examined units. The inhibition of the potential amplitude and discharge frequency was strictly correlated with the extent of muscle fatigue and was mediated by the group III and IV afferent muscle fibers activated by fatigue. In fact, the inhibitory effect was abolished by capsaicin injection in the masseter muscle that provokes selective degeneration of small afferent muscle fibers containing neurokinins. We concluded that fatigue signals originating from the muscle and traveling through capsaicin-sensitive fibers are able to diminish the proprioceptive input by a central presynaptic influence. In the second part of the study, we examined the central projection of the masseter small afferents sensitive to capsaicin at the electron-microscopic level. Fiber degeneration was induced by injecting capsaicin into the masseter muscle. Degenerating terminals were found on the soma and stem process in Vmes and on the dendritic tree of neurons in Vmot. This suggests that small muscle afferents may influence the muscle spindle activity through direct synapses on somata in Vmes and on dendrites of neurons in Vmot.

Morphology and neurochemistry of descending and ascending myenteric plexus neurons of sheep ileum.

The specific patterns of gastrointestinal motility in large herbivores may relate to differences in the organization of enteric nerve circuits, compared with other mammals. To investigate this possibility, we characterized the morphologies, chemical phenotypes, and projections of myenteric plexus (MP) neurons of the sheep ileum. Morphologies and projections were investigated after application of the carbocyanine dye (1,1′, di‐octadecyl‐3,3,3′,3′,‐tetramethylindo‐carbocyanine perchlorate, DiI) to fixed tissues. To study chemical phenotypes, the fluorescent tracer Fast Blue (FB) was injected into the wall of the ileum, in vivo, 12–14 cm oral to the ileo‐caecal junction. Over 80% of the descending and ascending DiI‐labeled neurons had typical Dogiel type I morphology, whereas only a few Dogiel type II neurons were observed. Nevertheless, there were long projections (up to 10 cm) of Dogiel type II neurons in both directions. Both type II and type I neurons were neurofilament immunoreactive (IR). We observed long projections of descending (up to 18 cm) and ascending (up to 12–14 cm) FB‐labeled MP neurons. Nitric oxide synthase (NOS)‐IR, peripheral choline acetyltransferase (pChAT)‐IR, and substance P (SP)‐IR occurred in both descending and ascending myenteric neurons. NOS‐IR was in approximately 60% of FB‐labeled descending and ascending neurons, whereas those expressing pChAT‐IR were 67 ± 15% and 60 ± 14%, respectively. Descending neurons expressing SP‐IR were 48 ± 15% and ascending were 56 ± 12%. NOS‐IR and pChAT‐IR, and SP‐IR and pChAT‐IR were commonly colocalized in both ascending and descending pathways. In descending pathways, almost all SP‐IR neurons were also pChAT‐IR (98 ± 3%) and NOS‐IR (99 ± 2 NOS+/SP+/pChAT−). Many FB‐labeled descending neurons showed both NOS‐ and pChAT‐IR. Descending neurons may represent inhibitory motor neurons (NOS+/SP+/pChAT−) and two classes of interneurons (pChAT+/NOS−, and pChAT+/NOS+/SP+). In ascending pathways, most neurons are pChAT+/NOS+/SP+. Thus, in sheep, ascending interneurons and ascending excitatory motor neurons both have the same phenotype, and other markers are needed to distinguish them. Anat Rec, 2007.

Collaterals of recurrent laryngeal nerve fibres innervate the thymus: a fluorescent tracer and HRP investigation of efferent vagal neurons in the rat brainstem

The origin and course of efferent vagal fibers, which innervate the rat thymus, were investigated by a fluorescent retrograde double labeling method, using Fast blue (FB) and Diamidino yellow dihydrochloride (DY) as tracers. In the same animal, one tracer was injected into the cranial portion of the right lobe of the thymus and the other dye was deposited around the cut end of the right recurrent laryngeal nerve. The neuronal population giving origin to the recurrent nerve was mapped by using retrograde labeling with HRP applied to the central stump of the nerve. The HRP retrograde axonal transport showed that most efferent vagal fibers of the recurrent nerve have their perikarya in the nucleus retroambigualis (NRA), nucleus ambiguus (NA), and to a lesser extent in the nucleus retrofacialis (NRF). In fluorescent retrograde double labeling of thymus and recurrent laryngeal nerve both single and double labeled cells were found. The cells labeled by the injections into the thymus were colocalized with the neurons labeled by the tracer deposited in the recurrent laryngeal nerve to the NRA, NA, and NRF. Moreover along the rostrocaudal extent of the NRF and NA double labeled cells were present, showing that some of the thymic efferents are collaterals of the recurrent nerve fibers. Our experiments shown that some thymic vagal fibres originate from neurons of nucleus dorsalis nervi vagi (NDV) as demonstrated both by HRP and FB injected thymuses. The possible role of these efferents in thymic function is briefly discussed.

Brain Capillary Perfusion during Sleep

Brain capillary perfusion was evaluated in the different states of the wake–sleep cycle—quiet wakefulness (QW), quiet sleep (QS), and active sleep (AS)—in rats. The extent of the perfused capillary network was determined by intravascular distribution of a fluorescent marker, Evans blue (EB); it remained unchanged across the three behavioral conditions, QW, QS, and AS. The anatomical network was assessed by alkaline phosphatase (AP) endothelial staining, which is known to underestimate the number of existing capillaries. The resulting number of AP profiles were, therefore, significantly lower than the number of EB profiles, but the percentage of AP-stained capillaries that were perfused (96%) was also unchanged across the behavioral conditions. The results indicate that no capillary recruitment accompanies the wake–sleep cycle. Capillary surface area is a relevant factor in determining exchanges across the blood–brain barrier. In the absence of capillary recruitment (relative constancy of the surface area), the CBF changes during sleep should preferentially affect flow-limited with respect to diffusion-limited transport.

Peripheral territory and neuropeptides of the trigeminal ganglion neurons centrally projecting through the oculomotor nerve demonstrated by fluorescent retrograde double-labeling combined with immunocytochemistry.

The peripheral territories of sheep trigeminal neurons which send their central process to the brainstem through the oculomotor nerve were investigated by the use of fluorescent tracers in double-labeling experiments. For this purpose Diamidino yellow (DY) injection into the oculomotor nerve was combined with Fast blue (FB) injection either into the extraocular muscles (EOMs), or the cornea, or the superior eyelid. Double-labeled DY + FB cells were found in the ophthalmic region of the trigeminal ganglion in addition to single-labeled DY or FB cells. The DY and DY + FB-labeled trigeminal cells were analysed immunocytochemically for their content of substance P (SP)-, calcitonin gene-related peptide (CGRP)-, and cholecystokinin-8 (CCK-8)-like. All single-labeled DY cells showed SP-, CGRP- or CCK-8-like immunoreactivity. Double-labeled DY + FB neurons innervating the EOMs were immunoreactive for each of the three peptides, whereas double-labeled neurons supplying the cornea were only CGRP-like positive. The findings suggest that, in the sheep, trigeminal neurons which send their process centrally through the oculomotor nerve supply the EOMs, the cornea, and the superior eyelid and contain neuropeptides which are usually associated with pain sensation.

Anatomical relationship between mesencephalic trigeminal nucleus and cerebellum in the duck

Abstract A number of multipolar mesencephalic trigeminal nucleus cells react to cerebelectomy or decortication of the proprioceptive muscle afferent projection area or interruption of the posterior cerebellar peduncle. The cell reaction consists of a great increase in neurofilaments within the perikaryon. The reaction following decortication and interruption of the posterior cerebellar peduncle leads to the conclusion that processes of some multipolar mesencephalic trigeminal nucleus cells reach the cerebellar cortex directly via posterior cerebellar peduncles.

Distribution of calbindin-D28k, neuronal nitric oxide synthase, and nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d) in the lateral nucleus of the sheep amygdaloid complex.

This study describes calbindin-D28k (CB), neuronal nitric oxide synthase (nNOS), and nicotinamide adenine dinucleotide phosphate diaphorase (NADPH-d) expression in the lateral nucleus of the sheep amygdaloid complex. Double immunofluorescence protocol was used in order to determine whether there is colocalization of CB and nNOS. The CB-immunoreactive (IR) neuronal population was composed especially of non-pyramidal neurons, but a few pyramidal cells were also present. The non-pyramidal neurons showed a multipolar and, occasionally, a fusiform morphology. The comparison between single-labeled CB-IR non-pyramidal neurons and cells belonging to CB-IR neuronal population showed they were identical for morphology, mean size, and distribution. The single-labeled CB-IR non-pyramidal neurons were only the 17.8% of the total non-pyramidal neurons counted. The nNOS-IR neuronal population was represented by non-pyramidal multipolar and fusiform neurons. Single-labeled nNOS-IR non-pyramidal neurons had the same morphology, mean area, and distribution as cells belonging to nNOS-IR neuronal population. Single-labeled nNOS-IR non-pyramidal neurons were more numerous than single-labeled CB-IR, and represented the 73.7% of total non-pyramidal neurons counted. NADPH-d-positive cells had the same morphology and distribution as the nNOS-IR neurons. Double immunolabeling (CB/nNOS) was found mostly in non-pyramidal multipolar neurons and only in a few non-pyramidal fusiform cells. These neurons had a mean perikaryal area significantly higher and significantly smaller than that of single-labeled nNOS and single-labeled CB-IR non-pyramidal neurons, respectively. CB and nNOS coexist only in a minority of non-pyramidal neurons (8.5%). The 32.4% of all CB-IR non-pyramidal neurons were nNOS-positive; only 10.4% of nNOS-IR non-pyramidal neurons were CB-positive. These results indicate that CB and nNOS are expressed by selective neurons and that the majority of nNOS-IR non-pyramidal neurons are lacking in CB.