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Infection and Immunity, September 1999, p. 4963-4967, Vol. 67, No. 9
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Immune Cells Are Required for Cutaneous Ulceration
in a Swine Model of Chancroid
Lani R.
San Mateo,1
Kristen L.
Toffer,1
Paul E.
Orndorff,2 and
Thomas H.
Kawula1,*
Department of Microbiology and Immunology,
University of North Carolina School of Medicine, Chapel Hill, North
Carolina 27599,1 and Department of
Microbiology, Pathology and Parasitology, College of Veterinary
Medicine, North Carolina State University, Raleigh, North Carolina
276062
Received 29 April 1999/Returned for modification 10 June
1999/Accepted 22 June 1999
 |
ABSTRACT |
Cutaneous lesions of the human sexually transmitted genital ulcer
disease chancroid are characterized by the presence of intraepidermal pustules, keratinocyte cytopathology, and epidermal and dermal erosion.
These lesions are replete with neutrophils, macrophages, and
CD4+ T cells and contain very low numbers of cells of
Haemophilus ducreyi, the bacterial agent of chancroid. We
examined lesion formation by H. ducreyi in a pig model by
using cyclophosphamide (CPA)-induced immune cell deficiency to
distinguish between host and bacterial contributions to chancroid ulcer
formation. Histologic presentation of H. ducreyi-induced
lesions in CPA-treated pigs differed from ulcers that developed in
immune-competent animals in that pustules did not form and surface
epithelia remained intact. However, these lesions had significant
suprabasal keratinocyte cytotoxicity. These results demonstrate that
the host immune response was required for chancroid ulceration, while
bacterial products were at least partially responsible for the
keratinocyte cytopathology associated with chancroid lesions in the
pig. The low numbers of H. ducreyi present in lesions in
humans and immune-competent pigs have prevented localization of these
organisms within skin. However, H. ducreyi organisms were
readily visualized in lesion biopsies from infected CPA-treated pigs by
immunoelectron microscopy. These bacteria were extracellular and
associated with necrotic host cells in the epidermis and dermis. The
relative abundance of H. ducreyi in inoculated CPA-treated
pig skin suggests control of bacterial replication by host immune cells
during natural human infection.
| |
TEXT |
Chancroid is a sexually transmitted
cutaneous genital ulcer disease caused by Haemophilus
ducreyi (reviewed in references 6, 10, and
17). This disease is a serious public health concern
in many tropical developing nations, where genital ulcerating diseases
contribute significantly to the spread of human immunodeficiency virus
(HIV) (18).
Chancroid ulcers are characterized by surface pustules composed of
neutrophils and necrotic debris, keratinocyte cytopathology, and dense
dermal inflammatory infiltrates (2, 7, 14). Neutrophils,
macrophages, and CD4+ T cells migrate to the site of
H. ducreyi infection in a delayed-type hypersensitivity
response involving predominantly Th1-type cytokines (7, 12,
13). Bacterial products that might play a role in chancroid
ulceration include factors that cause cell damage in vitro, such as
cytotoxin (1) and hemolysin (11), and factors that enable bacterial survival in chancroid animal models, including a
hemoglobin-binding protein (15) and a periplasmic superoxide dismutase (our unpublished data). However, the unique interactions of
bacterial molecules and elements of the host immune response that
result in the characteristic histopathology of chancroid ulceration are
not known.
Our laboratory has developed a juvenile pig model of chancroid that
mimics human infection. H. ducreyi infection of pigs results in disease that resembles human chancroid from the development of
ulcers histologically similar to chancroid in humans, with an immune
cell infiltrate of neutrophils, macrophages, and T cells, to the lack
of protective immunity (4). To determine the role of the
host immune response in the histopathology and progression of
chancroid, we examined the effect of immune cell deficiency on
ulceration induced by H. ducreyi in the pig model of chancroid.
Histopathology of lesions induced by H. ducreyi in
immune-competent and immune cell-deficient pigs.
To define the
role of the host immune cells in chancroid pathology, we determined the
effect of induced immune cell deficiency on ulcer formation caused by
H. ducreyi in the pig model. Pigs were rendered immune cell
deficient by intravenous administration of cyclophosphamide (CPA) (Mead
Johnson, Princeton, N.J.) at 50 mg per kg 4 days preinoculation and 20 mg per kg every other day thereafter until the day of biopsy
(8). Pigs treated with CPA showed a 76% reduction in total
leukocyte numbers by the day of infection. Numbers of circulating
polymorphonuclear leukocytes (neutrophils), lymphocytes, and monocytes
all significantly decreased after administration of CPA (Table
1) [all P < 0.05 by
t test]).
Pigs were inoculated on the ears with an estimated delivered dose of
104 CFU of H. ducreyi 35000 by using an allergen
delivery device as previously described (4). H. ducreyi-infected sites and control sites inoculated with
phosphate-buffered saline (PBS) were biopsied on days 2 and 7 by using
6-mm skin punches (Acuderm, Ft. Lauderdale, Fla.). Samples for
bright-field microscopy were fixed in 4% paraformaldehyde in PBS at
4°C, embedded in paraffin, sectioned, and stained with hematoxylin
and eosin (Histopathology Reference Laboratory, Richmond, Calif.).
In response to H. ducreyi infection, immune-competent pigs
developed skin lesions with the characteristic features of chancroid disease. In immune-competent pigs 2 and 7 days after inoculation, most
H. ducreyi-infected sites showed surface micropustules
consisting of neutrophils and tissue debris, complete erosion of the
epidermis, ballooning and cytopathology of keratinocytes surrounding
the micropustule, and near confluence of inflammatory cells in the dermis below the micropustule (Fig. 1).
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FIG. 1.
Hematoxylin-eosin-stained cross-sections of H. ducreyi-infected skin from immune-competent pigs. (A) Uninfected
skin (actual magnification, ×105). (B) Day 2 after infection with
H. ducreyi (×53). Cells in the ulcer with darkly staining
nuclei are neutrophils, macrophages, and lymphocytes.
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In contrast, a typical day 2 lesion from a CPA-treated pig had a mildly
acanthotic but intact epidermis with a microbreak at the site of
inoculation bordered by regenerative keratinocytes beginning to repair
the microbreak. The dermis had large clumps of bacteria and
degenerating neutrophils with pycnotic nuclei (Fig.
2B). Day 7 lesions were similar to day 2 lesions in that surface epithelia were fully intact (Fig. 2C).
Epidermal erosion, a requirement for the transmission of HIV and
H. ducreyi itself (5, 9, 18), did not develop in
immune cell-deficient animals, suggesting that the host immune response
is required for ulceration and, consequently, that host immune
responses may play a role in the spread of chancroid, as well as HIV.
The participation of the immune response in tissue injury has been
observed in many other disease models. In one study, the elimination of
circulating neutrophils in a guinea pig model of
Pseudomonas-induced acute respiratory distress syndrome
significantly diminished lung injury while stimulation with recombinant
granulocyte colony-stimulating factor significantly decreased survival
(16).
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FIG. 2.
Hematoxylin-eosin (A and B)- and toluidine blue
(C)-stained cross-sections of ear skin from cyclophosphamide-treated
pigs. (A) Uninfected skin (×53). (B) Day 2 after infection with
H. ducreyi (×53). m, epidermal microbreak; n, degenerating
neutrophils with pycnotic nuclei; b, bacterial colonies in the dermis.
(C) Day 7 after infection with H. ducreyi (×105). r,
regenerated surface layers of the epidermis; x, area wherein cell
debris and edema replace the orderly strata of epidermal cells.
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Death of epidermal keratinocytes in the spinous layer was evident in
H. ducreyi-infected skin of CPA-treated pigs 7 days after inoculation (Fig. 2C), suggesting that some tissue damage may occur in
the absence of a normal host immune response and as a direct result of
the action of specific bacterial factors. H. ducreyi has
been shown to cause cell death in vitro (3), through the
actions of a secreted cytolethal distending toxin (1) and a
surface-associated hemolysin (11).
Localization of H. ducreyi in infected pig skin.
Although we consistently recovered viable H. ducreyi from
infected immune-competent pigs, our attempts to localize bacteria in
skin biopsies by using various stains and bright-field microscopy were
unsuccessful. Other groups have experienced the same difficulty (12-14). Consequently, to localize H. ducreyi
within infected pig skin, we used transmission electron microscopy
(TEM). We surveyed ultrathin sections embedded in LR white on
pioloform-treated nickel grids (Ted Pella, Inc., Redding, Calif.)
probed with rabbit polyclonal anti-H. ducreyi antiserum and
goat anti-rabbit immunoglobulin G conjugated to 15-nm-diameter gold
particles (3).
Visible H. ducreyi organisms were rare in immune-competent
pigs, appearing as single cells within necrotic macrophages and granulocytes, amidst collagen fibers in the dermis, or between necrotic
keratinocytes (Fig. 3A and B). In
contrast, H. ducreyi cells were readily visible by TEM in
skin of infected immune cell-deficient pigs. Clumps of bacteria were
visible predominantly in the dermis amidst host cell debris and
extracellular matrix components and often surrounding or adjacent to
host cell ghosts (Fig. 3C and D).
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FIG. 3.
Electron micrographs of pig skin showing H. ducreyi labeled with gold particles. (A and B) H. ducreyi in the middle of necrotic pig skin cells at low
magnification (A) and high magnification (B). (C and D) H. ducreyi microcolony surrounding a necrotic pig cell in a section
from an infected neutropenic pig seen at low magnification (C) and at
high magnification (D). Each bar = 1 µM.
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We have determined that H. ducreyi numbers at an inoculated
site 2 days postinoculation of a CPA-treated pig can be as much as 1 order of magnitude greater than the number in a similarly-infected site
on an immune-competent pig (our unpublished data). The abundance of
H. ducreyi cells in infected CPA-treated pigs and their
relative rarity in immune-competent pigs provide evidence that
neutrophils, lymphocytes, and macrophages may control H. ducreyi growth and that the host immune response may play a role
in the clearance of chancroid.
The immune cell-deficient pig model promises to be a valuable tool with
which to study bacterial and host factors involved in chancroid
pathogenesis. Engineered H. ducreyi variants with mutations
in genes putatively involved in immune evasion and survival of host
bactericidal mechanisms can be compared in immune-competent and
CPA-treated pigs. The increased ability to visualize the infected site
in CPA-treated pigs due to the absence of overwhelming numbers of
immune cells could also be exploited for the analysis of cytopathic or
cytotoxic effects of specific H. ducreyi gene products. The increasing availability of monoclonal antibodies to pig immune cells
will also allow future studies involving the selective depletion of
entire classes of immune cells or molecules to define the contributions of these factors to chancroid pathology and H. ducreyi clearance.
In summary, we have provided evidence that the host immune response to
H. ducreyi infection is required for the development of
chancroid ulcers and the associated loss of epidermal integrity necessary for H. ducreyi transmission. We have also observed
keratinocyte cytopathology occurring largely in the absence of immune
cells, suggesting that H. ducreyi may contribute to the
tissue damage associated with chancroid. The immune cell-deficient pig
model can be further used to dissect bacterial and host contributions to disease progression in chancroid.
| |
ACKNOWLEDGMENTS |
This work was supported by grants NIAID AI42824 (T.H.K.) and NRSA 1 F31 AI09565-01 (L.R.S.M.).
We gratefully acknowledge our collaborator, Glen Almond, for valuable
advice on pigs; Patty Routh, John Horton, and Re Bai for technical
assistance with the pigs; Stephen Knight for help with light
micrography; Victoria Madden and Robert Bagnell for help with electron
microscopy; John Woosley for help with dermatohistopathology; Janne
Cannon for helpful discussions; and past and present members of the
Kawula laboratory, particularly Marcia Hobbs, Franca Zaretzky, and Gina
Donato, for practical and moral support. We are especially grateful to
Myron Cohen for his idea to use induced neutropenia.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, Campus Box 7290, University of North
Carolina School of Medicine, Chapel Hill, NC 27599. Phone: (919)
966-9699. Fax: (919) 962-8103. E-mail:
kawula{at}med.unc.edu.
Editor:
D. L. Burns
| |
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Infection and Immunity, September 1999, p. 4963-4967, Vol. 67, No. 9
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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