HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Labetoulle, M. Articles by Flamand, A. Search for Related Content PubMed PubMed Citation Articles by Labetoulle, M. Articles by Flamand, A.

Neuronal Propagation of HSV1 from the Oral Mucosa to the Eye

¹ From the Laboratoire de Génétique des Virus, Centre National de la Recherche Scientifique, Gif-sur Yvette, France; ² Institute of Physiology, University of Lausanne, Switzerland; and ³ Service d’Ophtalmologie, Hôpital de Bicêtre, Assistance Publique-Hôpitaux de Paris, Le Kremlin-Bicêtre, France.

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
PURPOSE. To identify possible neuronal pathways leading to herpetic ocular disease after primary oral infection in mice.

METHODS. The SC16 strain of herpes simplex virus (HSV)-1 (10⁶ plaque-forming units) was injected into the mucocutaneous border of the left upper lip. Animals were killed 2 to 10 days postinoculation (DPI). Spread of the virus in neural structures was studied by immunochemistry.

RESULTS. HSV1 first replicated at the site of inoculation and then at the superior cervical ganglion (at 2 DPI). The trigeminal ganglion and the facial nerve fibers were infected by 4 DPI. Infection of the ciliary body and iris occurred at 6 DPI, together with several brain stem nuclei belonging to the autonomic or sensory pathways. Between 8 and 10 DPI, the neural infection gradually cleared up, except for the ipsilateral sympathetic ganglion, and ipsilateral keratitis appeared in some animals.

CONCLUSIONS. The pattern of viral dissemination in this mouse model suggests that infection of iris and ciliary body results from transfer of virus in the superior cervical ganglion from sympathetic neurons innervating the lip to neighboring neurons innervating the anterior uvea. Later, zosteriform spread of virus from the trigeminal system may have contributed to the clinical and histologic findings.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Herpes simplex virus (HSV)-1 induces recurrent oral and ocular disease. The primary infection generally occurs during childhood after contact with infected lesions or saliva. Symptomatic primary infections mostly involve the oropharyngeal tract and rarely the eye (less than 1% of cases).¹ In contrast, ocular symptoms related to viral reactivation are frequent, affecting 21 of 100,000 persons per year in Western countries.^{1 2} These epidemiologic data suggest that oropharyngeal primary infection may lead to eye disease much later in life,¹ a hypothesis supported by some experimental data. For instance, HSV1 inoculation in the lower lip of mice led to latent infection of the trigeminal ganglion (TG), including its ophthalmic part.³ Other experiments have confirmed that HSV1 can establish latent infection in neurons that do not supply the site of primary infection.^{2 4} After inoculation in the animal’s snout (ophthalmic branch area), the virus was found in the TG and superior cervical ganglion (SCG), then in the cornea, iris, and ciliary body.^{5 6 7 8 9} Conversely, inoculation in cornea or anterior eye chamber led to latent infection in the whole TG and SCG.^{4 10}

Human herpetic iritis can occur with no signs of simultaneous or past keratitis¹¹ —that is, without involvement of the trigeminal system. Such isolated herpetic anterior uveitis appears to be caused by viral spread through neuronal structures that supply the iris and the ciliary body—namely, the autonomic pathways. Postmortem studies have shown evidence of herpetic latency in the central nervous and autonomic systems in humans.^{12 13 14 15} In this article, we present a murine model of anterior uveitis without concurrent keratitis resulting from oral HSV1 inoculation.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
The wild-type SC16 strain of HSV1¹⁶ was cultured in infant hamster kidney cells, concentrated, and kept at -80°C until use. Concentrates were thawed, diluted, and titrated in Vero cells (African green monkey kidney cells) before inoculation.

Six-week-old inbred BALB/c female mice were used for all experiments. All procedures conformed to the ARVO Statement for the Use of Animals in Ophthalmic and Visual Research. Equithesine anesthesia¹⁷ was used.

Under microscopic observation, 1 µl of HSV1 suspension was slowly injected into the subepithelial layers at the mucocutaneous border of the left upper lip, using a glass micropipette connected to a pressure delivery device.¹⁸ Each animal was examined daily to detect ocular infection (blepharitis, conjunctivitis, keratitis, or iritis).

Twenty-two mice were inoculated with 10⁶ plaque-forming units (PFU) of the SC16 strain of HSV1. Three of them were randomly chosen and killed 2 and 4 days postinoculation (DPI). Four mice died between 6 and 7 DPI. Mice with clinical ocular disease were killed by groups of three at 6, 8, and 10 DPI. Three mice with no clinical ocular disease were killed at 9 DPI. Two control mice were killed 6 days after sham infection. Under terminal anesthesia, mice were transcardially perfused with phosphate-buffered saline (PBS), 4% paraformaldehyde in PBS, and 20% sucrose in PBS. The skull was decalcified for 7 days at 4°C in 0.1 M EDTA dissolved in PBS, stored in PBS containing 20% sucrose for 24 hours at 4°C, and finally frozen. The spinal cord and SCG were frozen 24 hours after storage in PBS-20% sucrose. Frontal cryosections (30 µm) of the entire brain were collected into three parallel series, each one containing every third section. Two series were stained by the peroxidase-antiperoxidase method¹⁸ using a metal-enhanced diaminobenzidine kit as substrate (Pierce, Rockford, IL). The third series was kept in reserve. The sections were counterstained with Giemsa blue, washed, dried, and mounted.

HSV1 infection was quantified during two independent microscopic evaluations (performed by ML). For each animal, two of three series were examined (approximately 500 of the 750 total sections per mouse). Each slide was analyzed independently at random to limit the subjective nature of the evaluation. Levels of high interest were also examined by PK, GU, and AF. Only one series of sections from sham-infected animals was examined (approximately 250 sections). When the infection progressed, labeled cells formed foci and could no longer be counted. Therefore, we used a semiquantitative scale: mild, moderate, and severe infection (see legend of Table 1 ).

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

View larger version (98K): [in this window] [in a new window]   Figure 1. Micrographs of infected structures involved in ocular herpetic disease. Immunolabeled cells appear brown-black. (A) Mucocutaneous layers of the upper lip at site of inoculation (2 DPI). (B) Left SCG: numerous labeled cells in foci (4 DPI); (C) left TG (4 DPI); and (D) spinal cord and infected neurons in the intermediolateral cell group (arrow) and glial cells in the white matter (arrowhead; 6 DPI). (E) Left CG (arrow). The optic nerve (arrowhead) is not labeled (6 DPI). (F) Bilateral infection in the nucleus of the solitary tract (arrow) and area postrema (arrowhead; 6 DPI). (G) Infection of the iris and ciliary body in the left eye (6 DPI). (H) Absence of immunolabeling in the right eye; same mouse as in (G). Magnification, (A, D, F, G, and H) x23; (B, C, and E) x56.

View larger version (27K): [in this window] [in a new window]   Figure 2. Five representative frontal brain sections, showing the main infected structures at 6 DPI. The inoculated side is shown on the left. Infected areas are stippled. Brain ventricles are in black. AMY, amygdala; AP, area postrema; CS, superior colliculus; EW, Edinger–Westphal nucleus; LC, locus ceruleus; NTS, nucleus of the solitary tract; NSV, spinal trigeminal nucleus; n V, sensory root of trigeminal nerve; PVH, hypothalamic paraventricular nucleus; SCH, suprachiasmatic nucleus; TG, trigeminal ganglion; ts V, spinal trigeminal tract; TVP, ventral posterior thalamus; ZI, zona incerta.

View larger version (25K): [in this window] [in a new window]   Figure 3. Reconstruction of viral propagation through the nervous system. Left: peripheral nervous system; right: central nervous system; arrowheads: direction of viral propagation. Only systematically infected structures are shown (rapidly and heavily infected structures in bold). Compare with Table 1 for time points. The virus may infect adjacent neurons by local transfer (arrowhead in SCG). AP and NTS are bilaterally interconnected, which may explain the bilateral labeling of the IML. The rich secondary connections of the trigeminal system are not shown. AMY, amygdala; AP, area postrema; CCI, ciliary body and iris; CG, ciliary ganglion; EW, Edinger–Westphal nucleus; IML, intermediolateral cell group in the spinal cord; nnc, nasociliary nerve; npsm, major superficial petrosal nerve; NSS, superior salivatory nucleus; NTS, nucleus of the solitary tract; NSV, spinal trigeminal nucleus; n III, V, VII, oculomotor, trigeminal, and intermediofacial nerves; pio, infraorbital plexus; pc, carotid plexus; PPG, pterygopalatine ganglion; PVH, hypothalamic paraventricular nucleus; SCG, superior cervical ganglion; SCH, suprachiasmatic nucleus TG, trigeminal ganglion; tsc, cervical sympathetic trunk.

Infection of the Eyes
Ocular disease was present from 6 DPI in the four mice that died of the infection and in 13 of the 16 mice (81%) that survived for at least 6 DPI. Immunolabeling of the iris and ciliary body of the left eye appeared at 6 DPI (Fig. 1G) but decreased from 8 DPI onward. The principal duct of the left lacrimal gland was labeled in only one mouse (6 DPI). Stromal and epithelial keratitis was noted in three animals (one at 8 DPI and two at 10 DPI).

The conjunctival epithelium was not labeled. The retinas of the left eyes and the whole right eyes remained free of labeling in all animals (Fig. 1H) . No labeling was found in the eyes of the three mice with no clinical signs of ocular infection when killed at 9 DPI.

Infection of Autonomic Pathways
The first infected individual neurons were detected in the left SCG (sympathetic relay) in three mice killed at 2 DPI. The number of labeled cells then increased (more than 100 infected cells per ganglion at 4 DPI; Fig. 1B ) and remained high until 10 DPI. The left sympathetic intermediolateral cell group in the spinal cord (cervical and first thoracic segments), including neurons and glial cells, was maximally labeled at 6 DPI (Fig. 1D) and remained labeled until 10 DPI in two mice. The right intermediolateral cell group was also infected in two of three mice at 6 DPI, but not later. The right SCG was infected in one of three mice at 6 and 8 DPI.

The left pterygopalatine (PPG) and ciliary ganglion (CG; Fig. 1E ; parasympathetic relays) were infected at 6 DPI. At this time, Edinger–Westphal nuclei were also bilaterally labeled (Fig. 2C) . Only two of the three mice showed infection of the CG at 8 DPI, but none at 10 DPI.

In one of the three mice with no clinical ocular disease, some labeled cells were found in the left SCG and intermediolateral cell group, but parasympathetic pathways were not labeled.

Infection of Sensory and Motor Pathways
Immunolabeled cells were detected in the maxillary part of the left TG from 4 DPI (Fig. 1C) . At 6 DPI, the infected neurons increased in number and were present in all three parts of the left TG and the left spinal trigeminal nucleus (Figs. 2A 2D 2E) . Acute infection of the sensory pathways reduced afterward. At 10 DPI, only a few labeled cells were seen in the left TG. Rare infected motoneurons were seen in the left facial motor nucleus at 4 and 6 DPI, but not later.

In mice with no clinical ocular disease, trigeminal neurons were not labeled. Weak staining of glial cells in the left sensory root of the trigeminal nerve and in the fibers of the left facial nerve was seen in three and two mice, respectively, suggesting that some infection previously occurred in related sensory and motor neurons.

Infection of Other Brain Nuclei
No immunolabeling was seen in other brain nuclei until 6 DPI. At this time, in all animals, scattered infected cells were found bilaterally in the nucleus of the solitary tract, area postrema, locus ceruleus, paraventricular nucleus, and zona incerta and unilaterally in the left amygdaloid complex (Figs. 2A 2B 2C 2D 2E) . One mouse also had labeled cells in the left suprachiasmatic nucleus. The other two mice were also infected in the right ventral posterior part of the thalamus (Fig. 2B) and the right parabrachial nucleus. One of them was also labeled in the superior colliculus (Fig. 2C) and the other one in the mediodorsal and lateral groups of cells within both suprachiasmatic nuclei (Fig. 2A) .

At 8 DPI, the pattern of infection in the brain was similar, although labeled cells were less numerous. At 10 DPI, only one mouse showed rare labeled cells in the zona incerta and the ventromedial and posterior parts of the thalamus.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
We traced the propagation of HSV1 strain SC16 on serial histologic sections after inoculation into the mucocutaneous border of the left upper lip of mice. The use of inbred BALB/c mice, known for their susceptibility to herpes infection, and of the highly neurovirulent SC16 strain of HSV1¹⁶ (10⁶ PFU) allowed us to observe ocular disease in 81% of inoculated mice. Smaller inocula (10²–10⁴ PFU) induced lower rates of eye infection (data not shown).

In all animals with ocular disease after primary oral mucosal infection, the ipsilateral iris was HSV1-positive from 6 DPI. At 8 and 10 DPI, the ipsilateral cornea was also infected in three of six mice. These results show the reproducibility of HSV1 propagation from the oral mucosa to the anterior uvea in our animal model.

We chose to inoculate small volumes of virus within the superficial layers of the lip rather than using a scarification method to minimize the risk of autodissemination by scratching. Although the latter could not be excluded, because a cold sore lesion developed in all mice at 2 DPI, it could not be the origin of ocular infection, because herpes conjunctivitis was absent, and keratitis occurred only sporadically. The observation that the iris was always infected before the cornea suggests that eye disease resulted from propagation of the virus within the nervous system.

The main pathways of viral propagation are schematically summarized in Figure 3 . From the upper lip, the virus propagated first to the ipsilateral SCG (2 DPI) and replicated in sympathetic neurons innervating the lip. After replication, mature virions budding out from these neurons infected neighboring cells by local (nonsynaptic) spread, giving rise to multiple foci of infection at 4 DPI. At 6 DPI, the entire SCG was infected. Neurons infected by local spread in the SCG thus included those innervating the ipsilateral iris and ciliary body, and most likely represented the anatomic support for propagation of the virus to the anterior uvea. Although the propagation of HSV1 in the nervous system is mainly subserved by transneuronal transfer between connected neurons, HSV1 can also infect nonneuronal cells.^{19 20} Nonneuronal infection can be either abortive^{21 22 23} or productive²⁴ leading to the infection of neighboring neurons.²⁰ This is correlated to the neuroinvasiveness of the HSV1 strain and the susceptibility of the animal host.²⁰ For example, the McIntyre-B strain does not productively infect satellite cells within the TG of BALB/c mice, whereas mature virions are found in these cells after infection with the F and H129 strains.²⁴ The SC16 strain shows only a restricted replication within the satellite cells of C57BL/10 mice,^{25 26} whereas it can propagate by local spread to neurons and nonneuronal cells in BALB/c mice and rats.^{19 27} Therefore, local spread of the infection within the SCG in our model can be explained by the neuroinvasiveness of the SC16 strain and the susceptibility of BALB/c mice, as well as the high tropism of HSV1 for sympathetic neurons.¹⁸

The parasympathetic relay to the iris and ciliary body (i.e., the CG), was labeled much later than the SCG (6 DPI versus 2 DPI), which reinforces the idea that iridociliary infection was initiated by viral propagation through the sympathetic system. Similarly, HSV1 inoculation into the rabbit SCG led, 3 to 4 days later, to infection of the ipsilateral anterior uvea.^{28 29}

The TG and the facial nerve nucleus were the second sites of viral replication in the nervous system (4 DPI), due to viral uptake by sensory and motor fibers innervating the upper lip (Fig. 3) . Viral material was detected later in the TG than in the SCG, an observation that could be related to the fact that strain SC16 propagates faster in sympathetic than in some classes of sensory fibers.¹⁸ At 4 DPI, only the maxillary part of the ganglion was labeled, but at 6 DPI the ophthalmic part was also infected. Again, this probably reflected local transfer of virus between the maxillary and ophthalmic fibers. This is in agreement with tracing experiments using another herpes virus³⁰ and studies on HSV1 latency after inoculation in the lower lip.³ The cornea became labeled 2 days after the iris, probably as a result of viral spread through the anterior chamber or through the sensory axons (ophthalmic fibers) rather than through rare sympathetic endings located in the cornea.^{31 32}

Parasympathetic neurons in the PPG were not labeled until 6 DPI (i.e., 4 days later than the sympathetic neurons in the SCG), even though some parasympathetic efferents of the PPG supply the salivary glands of the oral mucosa.^{31 32} This delay makes it unlikely that the virus traveled to the ganglion by retrograde transport from peripheral parasympathetic nerve endings. One possibility is that parasympathetic neurons were infected by local transfer from sympathetic and/or trigeminal fibers traveling through the PPG (Fig. 3) ^{31 32} after replication in SCG and TG neurons. Similarly, the parasympathetic CG neurons could be infected by local transfer from the sympathetic fibers and/or sensory (nasociliary) fibers that cross the ganglion. Alternatively, the virus may have already arrived in the iris by 5 DPI (a time that was not examined) and then propagated retrogradely to the CG.

At the time of maximal infection (6 DPI), the nucleus of the solitary tract, area postrema and paraventricular hypothalamic nuclei were all labeled. Such a pattern of spread is in agreement with the connections of these structures with the sympathetic intermediolateral cell group in the spinal cord,^{33 34 35} which may have been infected as early as 5 DPI (as suggested by heavy labeling at 6 DPI). The infection of the locus ceruleus, suprachiasmatic nuclei, and amygdaloid complex could be explained by their connections with the nucleus of the solitary tract and/or the paraventricular nucleus.^{34 36 37 38 39} The labeling in deep layers of the superior colliculus, zona incerta, and ventral posterior thalamus is in keeping with the connections of these structures with trigeminal nuclei.^{40 41} The infection of Edinger–Westphal nuclei was presumably retrograde from the CG (Fig. 3) , although connections between Edinger–Westphal and suprachiasmatic nuclei have been suggested.⁴²

Altogether, these results show that HSV1 enters mostly sympathetic and trigeminal nerve endings within the labial mucocutaneous region but propagates most rapidly through sympathetic neurons. Propagation is due to both transneuronal (synaptic) transmission between connected neurons and local (per continuitatem) transfer from infected neurons to adjacent cells.^{18 19 43} The occurrence of local transfer was highlighted by the staining of glial cells—for instance, in the white matter near the intermediolateral cell group of the spinal cord (Fig. 1D) .

From 6 DPI onward, we observed a decrease in the number of HSV1-immunolabeled cells in most infected structures, except in sympathetic pre- and postganglionic neurons. This may be related to the clearance of heavily infected cells by the immune system. Indeed, such a response has been shown to occur as early as 3 DPI.^{44 45} Alternatively, HSV1 become latent in sensory and autonomic neurons connected to the eye.^{3 5 6 10 46} The multiple sites of HSV1 infection observed in our model represent potential sites of HSV1 latency, and offer an explanation for why anterior uveitis may occur without a history of keratitis. Similarly, the staining of paraventricular and suprachiasmatic nuclei, both connected to the retina,³¹ could explain how retinitis may occur. The role of the suprachiasmatic nuclei in the pathogenesis of retinitis has been suggested in other models.⁴²

In conclusion, the results obtained in this reproducible animal model, which avoids infection of the eye at the time of inoculation, improve our understanding of herpetic uveal infections. Combined with data from previous studies, they suggest that isolated ipsilateral anterior uveitis after intralabial viral inoculation is mediated by local virus transfer in the SCG, from sympathetic neurons innervating the lip to neighboring neurons innervating the anterior uvea.

	Acknowledgements

 
The authors thank Patrice Coulon for continuous interest in our work and Laurent Bertrand for histologic assistance.

	Footnotes

 
Supported SIDACTION-Fondation pour la Recherche Médicale, Centre National de la Recherche Scientifique (LPA 9053); Ministère de l’Education Nationale de la Recherche et de la Technologie (program PRFMMIP).

Submitted for publication November 29, 1999; revised February 23, 2000; accepted March 31, 2000.

Commercial relationships policy: N.

Corresponding author: Marc Labetoulle, Laboratoire de Génétique des Virus, Centre National de la Recherche Scientifique, 91198 Gif-sur-Yvette, France. marc.labetoulle{at}gv.cnrs-gif.fr

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 

1. Pavan–Langston, D. (1994) Viral disease of the cornea and external eye Albert, DA Jakobiec, FA eds. Principles and Practice of Ophthalmology. Clinical Practice Vol. 1,117-161 WB Saunders Philadelphia.
2. Pepose, JS, Leib, DA, Stuart, M, Easty, DL (1996) Herpes simplex virus diseases: anterior segment of the eye Pepose, JS Holland, GN Wilhelmus, KR eds. Ocular Infection and Immunity ,905-932 Mosby St. Louis.
3. Tullo, AB, Easty, DL, Blyth, WA, Hill, TJ (1982) Ocular herpes simplex and the establishment of latent infection Trans Ophthalmol Soc U K 102,15-18
4. Tullo, AB, Shimeld, C, Blyth, WA, Hill, TJ, Easty, DL (1982) Spread of virus and distribution of latent infection following ocular herpes simplex in the non-immune and immune mouse J Gen Virol 63,95-101[Abstract/Free Full Text]
5. Dyson, H, Shimeld, C, Hill, TJ, Blyth, WA, Easty, DL (1987) Spread of herpes simplex virus within ocular nerves of the mouse: demonstration of viral antigen in whole mounts of eye tissue J Gen Virol 68,2989-2995[Abstract/Free Full Text]
6. Shimeld, C, Dyson, H, Lewkowicz–Moss, S, Hill, TJ, Blyth, WA, Easty, DL (1987) Spread of HSV-1 to the mouse eye after inoculation in the skin of the snout requires an intact nerve supply to the inoculation site Curr Eye Res 6,9-12[Medline][Order article via Infotrieve]
7. Shimeld, C, Lewkowicz–Moss, SJ, Lipworth, KM, Hill, TJ, Blyth, WA, Easty, DL (1986) Antigens of herpes simplex virus in whole corneal epithelial sheets from mice Arch Ophthalmol 104,1830-1834[Abstract/Free Full Text]
8. Claoue, C, Hill, TJ, Blyth, WA, Easty, DL (1987) Clinical findings after zosteriform spread of herpes simplex virus to the eye of the mouse Curr Eye Res 6,281-286[Medline][Order article via Infotrieve]
9. Claoue, C, Hodges, T, Hill, T, Blyth, WA, Easty, D. (1987) The histology of the eye after zosteriform spread of herpes simplex virus in the mouse Br J Exp Pathol 68,585-593[Medline][Order article via Infotrieve]
10. Shimeld, C, Tullo, AB, Hill, TJ, Blyth, WA, Easty, DL (1985) Spread of herpes simplex virus and distribution of latent infection after intraocular infection of the mouse Arch Virol 85,175-187[Medline][Order article via Infotrieve]
11. Tabbara, KF, Chavis, PS (1998) Herpes simplex anterior uveitis Int Ophthalmol Clin 38,137-147[Medline][Order article via Infotrieve]
12. Warren, KG, Brown, SM, Wroblewska, Z, Gilden, D, Koprowski, H, Subak–Sharpe, J. (1978) Isolation of latent herpes simplex virus from the superior cervical and vagus ganglions of human beings N Engl J Med 298,1068-1069[Medline][Order article via Infotrieve]
13. Lonsdale, DM, Brown, SM, Subak–Sharpe, JH, Warren, KG, Koprowski, H. (1979) The polypeptide and the DNA restriction enzyme profiles of spontaneous isolates of herpes simplex virus type 1 from explants of human trigeminal, superior cervical and vagus ganglia J Gen Virol 43,151-171[Abstract/Free Full Text]
14. Fraser, NW, Lawrence, WC, Wroblewska, Z, Gilden, DH, Koprowski, H. (1981) Herpes simplex type 1 DNA in human brain tissue Proc Natl Acad Sci USA 78,6461-6465[Abstract/Free Full Text]
15. Gerdes, JC, Smith, DS, Forstot, SL (1981) Restriction endonuclease cleavage of DNA obtained from herpes simplex isolates of two patients with bilateral disease Curr Eye Res 1,357-360[Medline][Order article via Infotrieve]
16. Hill, TJ, Field, HJ, Blyth, WA (1975) Acute and recurrent infection with herpes simplex virus infection in the mouse: a model for studying latency and recurrent disease J Gen Virol 28,341-353[Abstract/Free Full Text]
17. Babic, N, Mettenleiter, TC, Flamand, A, Ugolini, G. (1993) Role of essential glycoproteins gII and gp50 in transneuronal transfer of pseudorabies virus from the hypoglossal nerves of mice J Virol 67,4421-4426[Abstract/Free Full Text]
18. Ugolini, G. (1992) Transneuronal transfer of herpes simplex virus type 1 (HSV1) from mixed limb nerves to the CNS, I: sequence of transfer from sensory motor and sympathetic nerve fibers to the spinal cord J Comp Neurol 326,527-548[Medline][Order article via Infotrieve]
19. Ugolini, G, Kuypers, HGJM, Simmons, A. (1987) Retrograde transneuronal transfer of herpes simplex virus type 1 (HSV1) from motoneurones Brain Res 422,242-256[Medline][Order article via Infotrieve]
20. Ugolini, G. (1995) Transneuronal tracing with alpha-herpesviruses: a review of the methodology Kaplitt, MG Loewy, AD eds. Viral Vectors. Gene Therapy and Neuroscience Applications ,293-317 Academic Press New York.
21. Hill, TJ, Field, HJ (1973) The interaction of herpes simplex virus with cultures of peripheral nervous tissue: an electron microscopic study J Gen Virol 21,123-133[Abstract/Free Full Text]
22. Cook, ML, Stevens, JG (1973) Pathogenesis of herpetic neuritis and ganglionitis in mice: evidence for intraxonal transport of infection Infect Immun 7,272-288[Abstract/Free Full Text]
23. Enquist, LW, Husak, PJ, Banfield, BW, Smith, GA (1998) Infection and spread of alphaherpesviruses in the nervous system Adv Virus Res 51,237-347[Medline][Order article via Infotrieve]
24. Lavail, JH, Topp, KS, Giblin, PA, Garner, JA (1997) Factors that contribute to the transneuronal spread of herpes simplex virus J Neurosci Res 49,485-496[Medline][Order article via Infotrieve]
25. Speck, P, Simmons, A. (1998) Precipitous clearance of herpes simplex virus antigens from the peripheral nervous systems of experimentally infected C57BL/10 mice J Gen Virol 79,561-564[Abstract]
26. Wilkinson, R, Leaver, C, Simmons, A, Pereira, R. (1999) Restricted replication of herpes simplex virus in satellite glial cell cultures clonally derived from adult mice J Neurovirol 5,384-391[Medline][Order article via Infotrieve]
27. Labetoulle, M, Kucera, P, Ugolini, G, et al (2000) Neuronal pathways for the propagation of HSV1 from one retina to the other in a murine model J Gen Virol 81,1201-1210[Abstract/Free Full Text]
28. Mintsioulis, G, Dawson, CR, Oh, JO, Briones, O. (1979) Herpetic eye disease in rabbits after inoculation of autonomic ganglia Arch Ophthalmol 97,1515-1517[Abstract/Free Full Text]
29. Yamamoto, Y, Hill, JM (1986) HSV-1 recovery from ocular tissues after viral inoculation into the superior cervical ganglion Invest Ophthalmol Vis Sci 27,1447-1452[Abstract/Free Full Text]
30. Martin, X, Dolivo, M. (1983) Neuronal and transneuronal tracing in the trigeminal system of the rat using herpes virus suis Brain Res 273,253-276[Medline][Order article via Infotrieve]
31. Paxinos, G eds. The Rat Nervous System 2nd ed. 1995 Academic Press San Diego.
32. Miller, NR Newman, NJ eds. Walsh and Hoyt’s Clinical Neuro-ophtalmology 5th ed. 1998 Williams & Wilkins Baltimore.
33. Loewy, AD (1981) Descending pathways to sympathetic and parasympathetic preganglionic neurons J Auton Nerv Syst 3,265-275[Medline][Order article via Infotrieve]
34. Shapiro, RE, Miselis, RR (1985) The central neural connections of the area postrema in the rat J Comp Neurol 234,344-364[Medline][Order article via Infotrieve]
35. Hancock, MB (1976) Cells of origin of hypothalamo-spinal projections in the rat Neurosci Lett 3,179-184
36. Cedarbaum, JM, Aghajanian, GK (1978) Afferent projections to the rat locus coeruleus as determined by a retrograde tracing technique J Comp Neurol 178,1-16[Medline][Order article via Infotrieve]
37. Saper, CB, Loewy, A, Swanson, LW, Cowan, WM (1976) Direct hypothalamo-autonomic connections Brain Res 117,305-312[Medline][Order article via Infotrieve]
38. Ricardo, JA, Koh, ET (1978) Anatomical evidence of direct projections from the nucleus of the solitary tract to the hypothalamus, amygdala and other forebrain structures in the rat Brain Res 153,1-26[Medline][Order article via Infotrieve]
39. Sofroniew, MV, Weindl, A. (1978) Projections from the parvocellular vasopressin- and neurophysin-containing neurons of the suprachiasmatic nuclei Am J Anat 153,391-430[Medline][Order article via Infotrieve]
40. Smith, RL (1973) The ascending fiber projections from the principal sensory trigeminal nucleus in the rat J Comp Neurol 148,423-445[Medline][Order article via Infotrieve]
41. Kilackey, HP, Erzurumlu, RS (1981) Trigeminal projections to the superior colliculus of the rat J Comp Neurol 201,221-242[Medline][Order article via Infotrieve]
42. Vann, VR, Atherton, SS (1991) Neural spread of herpes simplex virus after anterior chamber inoculation Invest Ophthalmol Vis Sci 32,2462-2472[Abstract/Free Full Text]
43. Kristensson, K, Nennesmo, I, Persson, L, Lycke, E. (1982) Neuron to neuron transmission of herpes simplex virus: transport of virus from skin to brainstem nuclei J Neurol Sci 54,149-156[Medline][Order article via Infotrieve]
44. Zhao, M, Azumi, A, Atherton, SS (1995) T lymphocyte infiltration in the brain following anterior chamber inoculation of HSV-1 J Neuroimmunol 58,11-19[Medline][Order article via Infotrieve]
45. Shimeld, C, Whiteland, JL, Williams, NA, Easty, DL, Hill, TJ (1997) Cytokine production in the nervous system of mice during acute and latent infection with herpes simplex virus type 1 J Gen Virol 78,3317-3325[Abstract]
46. Rodahl, E, Stevens, JG (1992) Differential accumulation of herpes simplex type 1 latency-associated transcripts in sensory and autonomic ganglia Virology 189,385-388[Medline][Order article via Infotrieve]

This article has been cited by other articles:

				A. S. Bertke, A. Patel, and P. R. Krause Herpes Simplex Virus Latency-Associated Transcript Sequence Downstream of the Promoter Influences Type-Specific Reactivation and Viral Neurotropism J. Virol., June 15, 2007; 81(12): 6605 - 6613. [Abstract] [Full Text] [PDF]

				S. Maillet, T. Naas, S. Crepin, A.-M. Roque-Afonso, F. Lafay, S. Efstathiou, and M. Labetoulle Herpes Simplex Virus Type 1 Latently Infected Neurons Differentially Express Latency-Associated and ICP0 Transcripts. J. Virol., September 1, 2006; 80(18): 9310 - 9321. [Abstract] [Full Text] [PDF]

				M. Labetoulle, S. Maillet, S. Efstathiou, S. Dezelee, E. Frau, and F. Lafay HSV1 Latency Sites after Inoculation in the Lip: Assessment of their Localization and Connections to the Eye Invest. Ophthalmol. Vis. Sci., January 1, 2003; 44(1): 217 - 225. [Abstract] [Full Text] [PDF]

				G. D. Luker, J. P. Bardill, J. L. Prior, C. M. Pica, D. Piwnica-Worms, and D. A. Leib Noninvasive Bioluminescence Imaging of Herpes Simplex Virus Type 1 Infection and Therapy in Living Mice J. Virol., October 25, 2002; 76(23): 12149 - 12161. [Abstract] [Full Text] [PDF]

				S. Keijser, J. A. van Best, A. Van der Lelij, and M. J. Jager Reflex and Steady State Tears in Patients with Latent Stromal Herpetic Keratitis Invest. Ophthalmol. Vis. Sci., January 1, 2002; 43(1): 87 - 91. [Abstract] [Full Text] [PDF]

				B. C. Summers, T. P. Margolis, and D. A. Leib Herpes Simplex Virus Type 1 Corneal Infection Results in Periocular Disease by Zosteriform Spread J. Virol., June 1, 2001; 75(11): 5069 - 5075. [Abstract] [Full Text]

This Article Abstract Full Text (PDF) Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Labetoulle, M. Articles by Flamand, A. Search for Related Content PubMed PubMed Citation Articles by Labetoulle, M. Articles by Flamand, A.