---------------------------------------------------------------------------
Emerging Infectious Diseases * Volume 2 * Number 4 * October-December 1996
---------------------------------------------------------------------------
Letters

PCR Confirmation of Infection with Cyclospora cayetanensis

---------------------------------------------------------------------------


To the Editor: Cyclospora cayetanensis, formerly known as
cyanobacterium-like body, is a variably acid-fast microorganism. Recently,
it was classified as a coccidian parasite (1) closely related to the genus
Eimeria (2). Humans infected with C. cayetanensis typically have diarrheal
illness with a variable number of stools per day and sometimes have nausea
and vomiting (3,4). Cyclospora infection has been reported in many parts of
the world as clustered or sporadic cases (1,3-5).

Variable success in diagnosing infection with this parasite underscores the
need for using (as quality control) molecular methods, which do not rely on
the level of expertise of laboratory personnel in microscopy. The key
features for diagnosis by light microscopy are size (8mm to 10mm in
diameter), internal features of stained and unstained oocysts, and
autofluorescence of oocysts (1,6). The definitive diagnosis is understood
as visualization of characteristic sporulated oocysts, which contain two
sporocysts. However, sporulation typically requires incubating oocysts for
up to 2 weeks, and this approach cannot be applied to Formalin or
polyvinylalcohol-preserved stool smears.

Sporadic and clustered cases of Cyclospora infections were reported in the
United States and Canada during May and June 1996 (5,7). From these
outbreaks, more than 900 cases were diagnosed by examining stool specimens
under light microscopy (Barbara Herwaldt, pers. comm.). Epidemiologic
studies indicated risk for Cyclospora infection from consuming raspberries
imported from Guatemala (7). Forty-two stool specimens supplied in 2.5%
potassium dichromate from patients with intestinal symptoms were forwarded
to the Centers for Disease Control and Prevention to be evaluated by
microscopy and by polymerase chain reaction (PCR) amplification. In
addition, one well-characterized positive stool specimen from Nepal was
provided by John Cross, Armed Forces Research Institute of Medical
Sciences,
                             [end of page 357]

Bangkok, Thailand, to use as the positive control.

Using techniques we developed for diagnosis of other protozoan parasites in
stools, we extracted DNA from all stools. The techniques we used employ
glass-bead disruption of oocysts in a buffer containing Laureth-12,
purification with the RapidPrep Micro Genomic DNA Isolation Kit for Cells
and Tissue (Pharmacia Biotech Inc., Piscataway, N.J.), followed by a final
purification step employing the QIAquick PCR purification kit protocol
(Qiagen, Inc., Chatsworth, Calif.) (8). The glass-bead disruption of
oocysts was far more effective than sonication (2) or freeze-thawing
techniques (9). We performed nested PCR in all stool specimens by using
Relman et al. (2) primers CYCF1E and CYCR2B for the first step of nested
amplification and primers CYCF3E and CYCR4B for the second (nested) step of
the PCR. These are the only primers described for amplification of
Cyclospora DNA. We found optimal conditions for the first step PCR to be
denaturation at 94°C for 30 s, annealing at 55°C for 30 s, and extension at
72°C for 90 s, 45 cycles. The same conditions were used for the second step
of the nested PCR, but the annealing temperature was 60°C.

By using this approach, we amplified the Cyclospora-specific DNA fragment
in 16 (38%) of the 26 (62%) specimens reconfirmed as positive by light
microscopy. The 10 specimens negative by PCR but positive by microscopy
showed either few or moderate numbers of Cyclospora oocysts. None of the 16
(38%) specimens negative by microscopy generated positive results in the
PCR Cyclospora test. Upon further examination by the PCR technique we
developed (9), three of these samples were positive for another enteric
coccidian, Cryptosporidium parvum.

Preliminary evaluation indicates that the sensitivity of PCR is 62%, and
the specificity is 100%. Although the sensitivity of the technique should
be evaluated further, these results indicate that PCR can be used to detect
Cyclospora. We assessed the sensitivity of this PCR again by using the
Nepalese specimen described above. This specimen, which was used as
positive control in all reactions, was amplified even when the extracted
DNA was diluted at 10 to the -5th power.

Lastly, a note of caution. As noted by Relman et al. (2) and confirmed by
us through GenBank searches, the nested PCR Cyclospora primers
cross-amplify other coccidians, especially those belonging to the genus
Eimeria (because no molecular data exist for another human coccidian
enteric parasite, Isospora belli, potential cross-amplification remains to
be determined). This cross-amplification with Eimeria should not present a
problem in diagnosing Cyclospora in human stool, as no human infections by
Eimeria are known. However, when analyzing food or environmental specimens,
this cross-amplification may complicate precise detection of Cyclospora.

Norman J. Pieniazek, Susan B. Slemenda, Alexandre J. da Silva, Edith M.
Alfano, and Michael J. Arrowood
Centers for Disease Control and Prevention, Atlanta, Georgia, USA

References

  1. Ortega YR, Sterling CR, Gilman RH, Cama VA, Diaz F. Cyclospora
     cayetanensis: a new protozoan pathogen of humans. N Engl J Med
     1993;328:1308-12.
  2. Relman DA, Schmidt TM, Gajadhar A, Sogin M, Cross J, Yoder K, et al.
     Molecular phylogenetic analysis of Cyclospora, the human intestinal
     pathogen, suggests that it is closely related to Eimeria species. J
     Infect Dis 1996;173:440-5
  3. Soave R, Dubey JP, Ramos LJ, Tummings M. A new intestinal pathogen?
     Clin Res 1986;34:533A.
  4. Long EG, Ebrahimzadeh A, White EH, Swisher B, Callaway CS. Alga
     associated with diarrhea in patients with aquired immunodeficiency
     syndrome and in travelers. J Clin Microbiol 1990;28:1101-4.
  5. Centers for Disease Control and Prevention (CDC). Outbreaks of
     Cyclospora cayetanensis infection - United States, 1996. MMWR Morb
     Mortal Wkly Rep 1996;45:549-51.
  6. Garcia LS, Bruckner DA. Intestinal protozoa: Coccidia and
     microsporidia. In: Garcia LS, Bruckner DA, editors. Diagnostic medical
     parasitology, 2nd ed. Washington: American Society for Microbiology,
     1993;49-74.
  7. Centers for Disease Control and Prevention (CDC). Update: Outbreaks of
     Cyclospora cayetanensis infection - United States and Canada, 1996.
     MMWR Morb Mortal Wkly Rep 1996;45:611-2.
  8. da Silva AJ, Schwartz DA, Visvesvara GS, de Moura H, Slemenda SB,
     Pieniazek NJ. Sensitive PCR diagnosis of infections by Enterocytozoon
     bieneusi (microsporidia) using primers based on the region coding for
     small-subunit rRNA. J Clin Microbiol 1996;34:986-7.
                                [end of page 358]

  9. Johnson DW, Pieniazek NJ, Griffin DW, Misener L, Rose JB. Development
     of a PCR protocol for sensitive detection of Cryptosporidium oocysts
     in water specimens. Appl Env Microbiol 1995;61:3849-55.

---------------------------------------------------------------------------