EMERGING INFECTIOUS DISEASES
Volume 1, Number 1, January-March 1995


                           Dispatches

A Novel Morbillivirus Pneumonia of Horses and its Transmission to
Humans

To the editor: On September 22 and 23, 1994, veterinary
authorities in Queensland and at the CSIRO Australian Animal
Health Laboratory were advised of an outbreak of acute
respiratory disease in horses at a stable in the Brisbane suburb
of Hendra. The trainer of the horses had been hospitalized for a
respiratory disease and was in critical condition. At that time,
the cause of the horses' illness was unclear and any link between
equine and human disease was thought improbable. Poisoning,
bacterial, viral, and exotic disease causes were investigated.
The history of the horses on this property was considered
important (Figure 1) (Figure is not available in ASCII.) Two weeks
before the trainer's illness, on
September 7, two horses had been moved to the Hendra stable from
a spelling paddock in Cannon Hill (6 km). One of these, a
pregnant mare, was sick and died within 2 days. The other horse
was subsequently moved on and never became sick. By September 26,
13 horses had died: the mare; 10 other horses in the Hendra
stable; one horse, which had very close contact with horses in
the Hendra stable, on a neighboring property; and one which had
been transported from the stable to another site (150 km). Four
Hendra horses and three others (one in an adjacent stable, one
moved to Kenilworth, and one to Samford) were later considered to
have been exposed and recovered from the illness. Some of these
horses were asymptomatic. Nine Hendra horses have remained
unaffected. The sick horses were anorexic, depressed, usually
febrile (temperature up to 41 C), showed elevated respiratory
rates, and became ataxic. Head pressing was occasionally seen,
and commonly, a frothy nasal discharge occurred before death.

On September 14, a stablehand at the Hendra stable developed an
influenza-like illness characterized by fever and myalgia. The
next day, the horse trainer also became ill with similar
symptoms. Both had close contact with the dying mare,
particularly the trainer who was exposed to nasal discharge while
trying to feed her; he had abrasions on his hands and arms. The
stablehand, a 40-year-old man, remained ill for 6 weeks and
gradually recovered. Besides myalgia, he also had headaches,
lethargy, and vertigo. The trainer, a 49-year-old man, was a
heavy smoker and showed signs consistent with Legionella
infection. He ultimately required ventilation for respiratory
distress and died after 6 days (Selvey L, et al. A novel
morbillivirus infection causing severe respiratory illness in
humans and horses, submitted).

At the beginning of the diagnostic investigation in horses,
African horse sickness, equine influenza, and hyperacute equine
herpes virus were excluded as possible causes by antigen trapping
enzyme-linked immunosorbent assay (ELISA), polymerase chain
reaction (PCR), or electron microscopy. Tests for Pasteurella,
Bacillus anthracis, Yersinia, Legionella, Pseudomonas, and
Streptobacillus moniliformis were negative, and poisons
consistent with the clinical and gross pathology, such as
paraquat, were excluded by specific testing.

However, within 3 days, a syncytial forming virus was detected in
vero-cell cultures inoculated with diseased horse tissues and
shortly thereafter was seen to grow in a wide range of cells.
These included MDBK, BHK, and RK13 cells. Subsequently, a
syncytial forming virus also was isolated in LLK-MK2 cells that
had been inoculated with tissue from the deceased trainer's
kidney. The isolation of these viruses and their preliminary
characterization by electron microscopy, immunoelectromicroscopy,
serology, and genetic analyses are described elsewhere (Murray
PK, et al. A new morbillivirus which caused fatal disease in
horses and man, submitted).

In summary, ultrastructural analysis showed that the virus is a
member of the Paramyxoviridae family. It is enveloped,
pleomorphic (varies in size from 38 nm to more than 600 nm), and
is covered with 10 nm and 18 nm surface projections. It contains
herringbone nucleocapsids that are 18 nm wide with a 5 nm
periodicity. The presence of `double-fringed' surface projections
on this virus is considered unique. Immunoelectronmicroscopy
showed that both the horse and the human virus react with
convalescent-phase horse sera and with sera from the two human
cases.

PCR primers were synthesized from consensus Paramyxoviridae
matrix protein sequences and tested against the horse virus.
Those specific for paramyxoviruses and pneumoviruses did not
bind, but one pair of morbillivirus primers gave a 400 bp
product. Determination of the sequence of this product enabled
the synthesis of horse virus-specific primers. Phylogenetic
analyses of the matrix protein sequence indicates that the virus
is unique and distantly related to other known members of the
group. A comparison of translated M protein sequence shows that
it has a 50% homology with the morbillivirus group (80% if
conservative amino acid substitutions are used). This distant
relatedness is emphasized by our observations that neutralizing
antisera to measles virus, canine distemper, and rinperest virus
failed to neutralize the virus.

The viruses isolated from the horses and the trainer are
ultrastructurally identical. Serum from the horses and the two
human cases specifically cross-neutralize the virus, and the
horse virus-specific PCR primers provide a positive reaction with
the human virus isolate. Therefore, the horses and the trainer
were infected with the same virus.

At the beginning of the diagnostic investigation, tissues from
the lungs and spleens of diseased horses were injected into two
recipient horses. After 6 and 10 days, the recipient horses
became ill with high fever and severe respiratory signs,
demonstrating that the disease was transmissible. Two days later
the horses were destroyed. The equine morbillivirus was isolated
from tissues from both of these horses. To document that the
isolated horse virus was pathogenic, experimental transmission
tests were also conducted. Two additional horses received a total
of 2 x 107 TCID50 of tissue culture virus by intravenous
inoculation and by intranasal aerosol. Both horses became
seriously ill, and after a short, severe clinical episode, were
destroyed 4 and 5 days after exposure. At necropsy, they showed
gross and histopathologic lesions that were primarily respiratory
and consistent with the natural disease. Virus was reisolated
from their lungs, liver, spleen, kidney, lymph nodes, and blood.

The pathology of this infection is interesting. In horses, the
dominant gross pathology is lesions in the lungs. These are
congested and edematous with prominent lymphatic dilation in the
ventral margins. In natural cases, the airways were usually
filled with thick, fine, stable foam which was occasionally
blood-tinged; this was not seen in the experimental cases.
Histologically, in horses, there is interstitial pneumonia,
proteinaceous edema with pneumocyte, and capillary degeneration.
Virus can be located in endothelial cells by immunofluorescence
and syncitial cells also could be seen in blood vessel walls,
confirming the vascular of trophism of this virus (Murray PK, et
al, submitted). The trainer's post-mortem findings showed
similarities to those of the horses (Selvey L, et al, submitted).

No further clinical cases of disease have been seen in horses or
humans since this outbreak. Serologic surveillance of people who
had close contact with the sick horses, mostly stable workers,
veterinary pathologists, animal health field staff, or people who
lived in the vicinity of the affected stables, was negative
(Selvey L, et al, submitted).

Serologic testing of all horses on quarantined properties and
within 1 km of the Hendra stable, and a sample of horses from the
rest of Queensland was undertaken (Table 1). A total of 1,964
horses were tested from more than 630 premises. The negative
results from this testing also indicate that the infection has
not spread. In the entire horse survey, only seven horses, all
from the Hendra property and the adjoining stables, were
positive. Four of these animals had been clinically affected, but
three were asymptomatic. Because of the potential risk and the
difficulty in establishing freedom from infection, these seven
recovered horses were later destroyed.

Table 1. The premises and horses surveyed by serologic testing for
equine morbillivirus, after the disease outbreak

                                 Premises       Horses

Quarantine Premises*                13            107