EMERGING INFECTIOUS DISEASES
Volume 1, Number 4, October-December 1995


DISPATCH

(Pages 132-3)

Hemolytic Uremic Syndrome Due to Shiga-like Producing Escherichia
coli O48:H21 in South Australia

Enterohemorrhagic Escherichia coli (EHEC) other than serotypes
O157:H7 are increasingly recognized in association with hemolytic
uremic syndrome (HUS) (1) and have been reported in Australia
(2). While detecting strains of O157:H7 has become easier over
the years, identifying the expanding number of other serotypes of
EHEC also associated with HUS, with other conditions, and with
healthy domestic animals is still very difficult.

Cases of HUS have been reported in Australia over a number of
years. The most common serotype found was O111:H-, and
Australia's recently reported first HUS outbreak (3) was caused
by EHEC O111:H-. We wish to report a case of severe HUS due to
serotype O48:H21, which, as far as we know, has not been
previously reported as a cause of HUS. This case occurred in
1993, before surveillance of HUS had been initiated; after this
case, between July and December 1994, 10 cases of HUS (from which
four isolates were obtained; two were EHEC O111) were reported to
the Australian Paediatric Surveillance Unit (E. Elliott, pers.
comm.).

The patient in the 1993 case was an 8-year-old girl, living in a
rural setting in the outskirts of Adelaide, South Australia. Her
home was adjacent to a farm on which cows, sheep, and ducks were
kept. A kelpie/healer cross puppy was in the house in November
1993. Also kept were a pet galah (Australian cockatoo) and pet
fish. She was well until 23 December 1993, when she had diarrhea
described as very smelly and watery "like the juice of tinned
crab." The diarrhea became bloody on 2 January 1994 and was
associated with severe abdominal pains which made the patient
draw up her legs. She was having bowel movements six times a day,
had become very weak, and was unable to stand. She was admitted
to Adelaide Children's Hospital on 3 January 1994, and her
condition progressed to anuric renal failure over the next few
days. Serum biochemistry on 7 January showed a urea level of 23.3
mmol/L and creatinine level of 539 æmol/L. Her hemoglobin level
fell from 157 g/L on 3 January to 86 g/L on 10 January. Her
hematocrit fell from 48% to 24%, and her platelet count fell from
463 x 109/L to 47 x 109/L on these dates, respectively. The blood
film showed microangiopathic hemolytic anemia with fragmented red
cells. She required hemodialysis for 3 weeks and was discharged
from the hospital on 31 January 1994.

Apart from the patient's 5-year-old brother, who had loose bowel
movements for 1 day on 28 December 1993, no other family members
were affected. An adequate dietary history was not obtained;
however, no food had been eaten from commercial food outlets.

Stool samples were collected on 4 and 5 January 1994. The samples
were probed for Shiga-like toxin (SLT)-I and SLT-II genes by
polymerase chain reaction (PCR), and the results were positive.
Approximately 80% of lactose-fermenting colonies on MacConkey
agar were also SLT positive. No sorbitol-negative colonies were
observed on sorbitol-MacConkey agar. In addition to being
cultured for E. coli, the stools were also routinely cultured for
Shigella, Salmonella, Yersinia, Vibrio, and Clostridium. In
addition, stained concentrates were examined for Giardia lamblia
and Entamoeba histolytica with negative results. Four typical E.
coli strains were subjected to further tests. They were typical
E. coli, positive in the indole and ONPG tests, negative in the
Voges-Proskauer, citrate, TDA, malonate, urease, gelatine, and
H2S tests. The strains fermented glucose, lactose, mannitol,
xylose, rhamnose, arabinose, sorbitol, sucrose, and melibiose.
They did not ferment inositol, adonitol, salicin, raffinose, or
amylose. They decarboxylated arginine, lysine, and ornithine. All
the strains produced enterohaemolysin (4). The strains were O and
H serotyped (5, 6) and found to be serotype O48:H21. Supernatant
preparations were tested on Vero cells (7) and found to give
typical verocytotoxic reactions in titers of 103 to 104. The
supernatants were also tested by enzyme-linked immunosorbent
assay (ELISA) by using monoclonal antibodies 13C4 and 11E10
directed against SLT-I and SLT-II, respectively, and strong
reactions with both antibodies were noted, confirming the
presence of both SLTs.

Stool samples taken from the patient on 8 February 1994 were
negative for SLT-I and SLT-II genes by PCR and were not cultured
further. Stool samples from the patient's brother and local
animals were not forthcoming.

That all four E. coli isolates tested were of serotype O48:H21
and demonstrated identical toxigenicity by both PCR and ELISA and
the fact that SLT-positive organisms were not found in the stools
collected during the patient's convalescence strongly suggest
that this serotype was the causative organism. The toxicity,
virulence, and part of the molecular structure of the SLT-II gene
derived from the EHEC O48:H21 strain reported here (and whose
novel serotype was discovered by the authors) have recently been
described elsewhere (8).

Paul N. Goldwater,* Karl A. Bettelheim+
*Microbiology and Infectious Disease Services,
  Women's & Children's Hospital, 
Adelaide, South Australia, 5006; 
 Biomedical Reference Laboratory,
+Victorian Infectious Diseases Reference Laboratory, 
Fairfield Hospital, Victoria, North Australia,
Australia 3078

References

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