Journal of Clinical Microbiology, August 1999, p. 2508-2517, Vol. 37, No. 8
0095-1137/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Development and Clinical Evaluation of a Highly
Sensitive PCR-Reverse Hybridization Line Probe Assay for Detection and
Identification of Anogenital Human Papillomavirus
Bernhard
Kleter,1
Leen-Jan
van Doorn,1
Lianne
Schrauwen,1
Anco
Molijn,1
Suprapto
Sastrowijoto,2
Jan
ter
Schegget,3
Jan
Lindeman,4
Bram
ter
Harmsel,5
Matthé
Burger,6 and
Wim
Quint1,3,*
Delft Diagnostic
Laboratory1 and Department of
Pathology2 and Department of Gynaecology
and Obstetrics,5 R. de Graaf Hospital, Delft,
and Department of Virology3 and
Department of Gynaecology and
Obstetrics,6 Academic Medical Center, University
of Amsterdam, and Department of Pathology, Slotervaart
Hospital,4 Amsterdam, The Netherlands
Received 23 November 1998/Returned for modification 16 February
1999/Accepted 27 April 1999
 |
ABSTRACT |
Human papillomavirus (HPV) can be detected by amplification of
viral DNA. A novel PCR primer set generating a short PCR fragment (SPF
PCR) was used for amplification of a fragment of only 65 bp from the L1
region and permitted ultrasensitive detection of a broad spectrum of
HPV genotypes. The intra- and intertypic sequence variations of the
22-bp interprimer region of this amplimer were studied. Among 238 HPV
sequences from GenBank and clinical specimens, HPV genotypes were
correctly identified based on the 22-bp sequence in 232 cases (97.2%).
Genotype-specific probes for HPV genotypes 6, 11, 16, 18, 31, 33 to 35, 39, 40, 42 to 45, 51 to 54, 56, 58, 59, 66, 68, 70, and 74 were
selected, and a reverse hybridization line probe assay (LiPA) (the
INNO-LiPA HPV prototype research assay) was developed. This LiPA
permits the use of amplimers generated by the SPF as well as the MY
09/11 primers. The assay was evaluated with a total of 1,354 clinical
specimens, comprising cervical scrapes (classifications ranging from
normal cytology to severe dyskaryosis) and formalin-fixed,
paraffin-embedded cervical carcinoma samples. LiPA results were highly
concordant with sequence analysis of the SPF amplimer,
genotype-specific PCR, and sequence analysis of amplimers generated by
MY 09/11 primers. The sensitivity of the SPF primers was higher than
that of the GP5+/6+ primers over a broad range
of HPV types, especially when multiple HPV genotypes were present. In
conclusion, the SPF LiPA method allows extremely sensitive detection of
HPV DNA as well as reliable identification of HPV genotypes in both
cervical smears and paraffin-embedded materials.
| |
INTRODUCTION |
Human papillomaviruses (HPV)
constitute a group of viruses associated with benign and malignant
lesions of cutaneous and mucosal epithelia. So far, more than 100 different HPV genotypes have been identified, of which approximately 40 have been detected in the anogenital area (7, 34). These
include several HPV genotypes that are known to be present in cervical
carcinomas and in precursor lesions (5, 10), such as HPV
type 16 (HPV-16) and HPV-18. Such genotypes are defined as high-risk
genotypes and are associated with a comparatively high risk for
invasive disease. In contrast, other genotypes (e.g., HPV-6 and -11)
are considered low-risk genotypes, since they are not associated with the development of cervical carcinoma. The clinical classification of
HPV types into either high- or low-risk groups is still not completely
clear. According to zur Hausen (34), HPV-16, -18, -31, -33, -35, -39, -45, -51, -52, -56, -58, -66, and -69 belong to the class of
high-risk types. HPV-59 and -68 can probably also be considered
high-risk types (15, 32). Formal classification of HPV is
performed by phylogenetic analysis of an ~450-bp sequence from the L1
region of the genome (7, 34). By definition, HPV genotypes
show a sequence dissimilarity of more than 10% in this 450-bp sequence.
Since HPV still cannot be cultured efficiently and the clinical
performance of serological assays is still poor, diagnosis of HPV
infection is based almost entirely on molecular tools, including liquid
hybridization (e.g., Hybrid Capture; Digene Diagnostics, Silver Spring,
Md.) (9), Southern and dot blot hybridization with HPV
type-specific probes (14, 19), type-specific PCR (3,
31), and general-primer PCR (11, 13, 26, 30). Type-specific PCR permits detection of only a limited number of genotypes and requires the use of multiple PCRs. Therefore, several general or consensus PCR primers have been developed to detect a broad
spectrum of HPV genotypes. The majority of large studies to date have
been performed with the MY 09/11 (13) and the
GP5+/6+ (11) primer sets. A
disadvantage of these general primer systems is the relatively large
size of the PCR fragment, especially in samples that yield poorly
amplifiable DNA, such as formalin-fixed, paraffin-embedded materials
(3, 17, 21). Various methods have been described for
identification of HPV genotypes after amplification with general or
consensus PCR primers. Besides sequence analysis, restriction fragment
length polymorphism analysis of PCR amplimers has been described
(4). Differentiation between potentially high-risk and
low-risk HPV genotypes can also be achieved by hybridization of
amplified HPV DNA with type-specific probes, using different test
formats, such as dot blot hybridization (13), microtiter
plate hybridization (8), or a line blot method (12, 15). Some of these typing systems have several drawbacks, such as
the need for multiple hybridization reactions and the limited sensitivity for detection of multiple HPV genotypes in a single sample.
By definition, triage of patients with atypical squamous cells of
undetermined significance (ASCUS) is difficult by cytological methods.
Identification of high-risk HPV genotypes may permit selection of those
patients who are at increased risk for disease and therefore may
provide additional clinical value (9, 10, 16, 23). An
crucial requirement for this approach is that HPV DNA testing and
identification of high-risk HPV genotypes should be highly sensitive
and specific, to achieve maximum negative predictive value for
development of cervical intraepithelial neoplasia (CIN) (6).
Recently, we have developed novel general short PCR fragment (SPF)
primers that amplify a fragment of only 65 bp, permitting highly
sensitive, broad-spectrum detection of HPV DNA (17). To
extend our knowledge of the natural history and clinical relevance of
HPV infections, we developed and clinically evaluated a rapid typing
assay for the simultaneous identification of 25 HPV genotypes after
highly sensitive, broad-spectrum PCR amplification, using the novel SPF
primer set.
| |
MATERIALS AND METHODS |
Clinical materials.
Group 1 contained cervical scrapes and
biopsies (n = 104) obtained from patients visiting the
gynecology outpatient clinics of community hospitals in Delft and the
Slotervaart Hospital in Amsterdam, The Netherlands. The patients had
been referred to the hospitals for treatment of CIN lesions. Smear
preparations were examined and classified according to the Bethesda
system (20).
Group 2 (n = 488) and group 3 (n = 278)
comprised cervical scrapes obtained from women who were treated in the
gynecology outpatient clinics of community hospitals in Delft and
Amsterdam, The Netherlands, in 1997 and 1998, respectively. Patients
had a history of colposcopy or treatment of dysplasia by loop
electrosection of the transformation zone. Cervical scrapes were
obtained with a cervix brush and were suspended and transported in 1.5 ml of phosphate-buffered saline (pH 7.2) at room temperature. These samples were all classified as having normal cytology or ASCUS.
Group 4 consisted of a total of 304 cervical scrapes obtained from
women who were tested for the presence of HPV between 1988 and 1993 in
the Netherlands. These patients had either one cervical smear showing
severe dyskaryosis (n = 153) or two cervical smears showing mild or moderate dyskaryosis (n = 151). The
interval between two abnormal smears was 1 year or less (6).
Group 5 comprised 180 patients with cervical carcinoma. The cervical
biopsies were obtained from women visiting the Russian Cancer Center in
Moscow between 1988 and 1994 (29). The specimens had been
fixed in formalin, embedded in paraffin, histologically examined after
hematoxylin-eosin staining, and classified as squamous cell carcinoma
(n = 129) or adenocarcinoma (n = 51).
DNA isolation.
DNA was isolated from scrapes as described
previously (17). Briefly, scrapes were resuspended in 1.5 ml
of phosphate-buffered saline (pH 7.2). The cell suspension was
vigorously shaken, and 120 µl was treated with 40 µl of proteinase
K (200 µg/ml) in 3% Triton X-100 for 1 h at 37°C. The
proteinase was inactivated by incubation at 95°C for 10 min.
Subsequently, 10 µl of the supernatant was used in a PCR.
DNA was isolated from a single 10-µm section of formalin-fixed,
paraffin-embedded tissue by treatment with proteinase K (1 mg/ml) in a
volume of 250 µl at 56°C for 16 h. Proteinase K was inactivated at 95°C for 10 min, and 10 µl was used directly for PCR.
Plasmids.
Plasmids containing HPV genomic DNA were kindly
provided by E.-M. de Villiers, Heidelberg, Germany (HPV-6b, -11, -13, -16, -18, -40, -45, -51, and -53); R. Ostrow, Minneapolis, Minn.
(HPV-26); A. Lorincz, Silver Spring, Md. (HPV-31, -35, -43, -44, -56, -61, and -64); T. Matsukura, Tokyo, Japan (HPV-58, -59, -62, -67, and -69); and G. Orth, Paris, France (HPV-30, -33, -34, -39, -42, -52, -54, -55, -66, -68, -70, and -74).
PCR.
The development of the SPF1/2 PCR primers has been
described earlier (17). In addition to this SPF1/2 primer
set (comprising six primers) we have further optimized the system. The
current version (prototype research kit INNO-LiPA HPV SPF10) comprises four additional primers. The universal primer sets MY 09/11
(13) and GP5+/6+ (11, 14,
15), as well as the type-specific primer sets for HPV-16,
-18, -31, and -33 (3), were used exactly as described previously (Fig. 1).
View larger version (9K):
[in this window]
[in a new window]
|
FIG. 1.
Schematic representation of the locations of the
different general primer sets (MY 09/11,
GP5+/6+, and SPF) on the HPV genome. The
circular HPV DNA genome is represented by a single line, and boxes show
the positions of the various early (E) and late (L) genes. Within the
L1 region, the positions of the amplification targets as well as the
expected amplimer sizes for each of the primer sets are indicated.
|
|
SPF10 PCR was performed in a final reaction volume of 50 µl
containing 10 µl of the isolated DNA, 10 mM Tris-HCl (pH 9.0), 50 mM
KCl, 2.0 mM MgCl2, 0.1% Triton X-100, 0.01% gelatin, 200 µM each deoxynucleoside triphosphate, 15 pmol of each of the forward and reverse primers, and 1.5 U of AmpliTaq Gold (Perkin-Elmer). The PCR
conditions were as follows: activation of AmpliTaq Gold for 9 min at
94°C was followed by 40 cycles of 30 s at 94°C, 45 s at
52°C, and 45 s at 72°C, with a final extension of 5 min at 72°C. Each experiment was performed with separate positive and several negative PCR controls.
Amplification of isolated DNA was checked with 
-globin PCR primers
PC03 and PC04 (24).
Sequence analysis.
For sequence analysis of SPF and MY 09/11
amplimers, fragments were excised from 2 and 1%
low-melting-temperature TAE agarose gels, respectively, and directly
sequenced with the AmpliCycle sequencing kit (Perkin Elmer) and one of
the PCR primers. For adequate sequencing of the 65-bp SPF amplimer, the
concentration of dideoxyribonucleosides was increased in each of the
four termination reaction mixtures by adding 2 µl of 500 µM ddA,
200 µM ddC, 60 µM ddG, and 200 µM ddT, respectively. The sequence
products from SPF and MY 09/11 amplimers were separated on 15 and 6%
polyacrylamide gels, respectively, by using the Alf-express system
(Pharmacia, Uppsala, Sweden). Sequences were read manually from the
electrophoresis pattern. The DNA sequences were analyzed with the
PC/Gene software and the basic local alignment search tool
(1) at the National Center for Biotechnology Information
(20a).
HPV sequences from GenBank.
HPV sequences with the following
accession numbers were obtained from GenBank and classified according
to the Los Alamos database (18a) (sequences marked with an
asterisk were used as references for the corresponding HPV genotypes):
HPV-6, X00203*, S73503, and L41216; HPV-7, X74463* and M96300; HPV-11,
M14119* and U55993; HPV-13, X62843* and M69076; HPV-16, K02718*, U89348, AF003031, M96285, AF043286, U34165, U34167 to U34176, U34179,
U34181, U34183, U34185, U34187 to U34189, U341893, U37217, AF003027,
AF001600, and AF043287; HPV-18, X05015*, U45889 to U45891, and U89349; HPV-18var, U45892 to U45894 and M96287; HPV-30, X74474* and M96279;
HPV-31, J04353* and U37410; HPV-32, X74475* and M96291; HPV-33:
M12732*, U45895 to U45897, and A12360; HPV-34, X74476* and M96292;
HPV-35, M74117*, X74477, and U45898; HPV-39, M62849* and U45899 to U45905; HPV-40, X74478* and M96293; HPV-44, U31788* and U12493; HPV-45,
X74479*, U45906 to 45916, and M96294; HPV-51, M62877* and U45917;
HPV-52, X74481*, U45718 to U45923, and M96297; HPV-53, X74482* and
M96298; HPV-54, U37488* and U125601; HPV-55, U31791 and U12494; HPV-56,
X74483* and M96299; HPV-57, X55965* and U37537; HPV-58, D90400* and
U45924 to U45929; HPV-59, X77858*, U45930 to U45933, and U12496;
HPV-61, U31793*, U12499, and U12500; HPV-66, U31794* and U12498;
HPV-67, D21208* and U12492; HPV-68, M73258* and U45934; HPV-70, U21941* and U22461; and HPV-72, X94164* and U12485.
Reverse hybridization by the LiPA.
Genotype-specific probes
were used to develop a line probe assay (LiPA), the INNO-LiPA HPV
prototype research genotyping assay. The oligonucleotide probes were
enzymatically provided with a poly(dT) tail. Subsequently, probes were
immobilized as parallel lines on nitrocellulose membrane strips. the
top line contains a positive control biotinylated DNA. The HPV LiPA is
performed essentially as described earlier for the hepatitis C virus
INNO-LiPA (28). Briefly, 10 µl of PCR product, containing
biotin moieties at the 5' ends of the primers, was denatured by adding
10 µl of NaOH solution. After 10 min, a LiPA strip was put into the
tray. Two milliliters of prewarmed (37°C) hybridization buffer (3×
SSC [1× SSC is 15 mM Na-citrate and 150 mM NaCl], 0.1% sodium
dodecyl sulfate) was added and incubated at 50 ± 0.5°C for
1 h. All incubations and washing steps were performed
automatically in an Auto-LiPA. The strips were washed twice for 30 s and once for 30 min at 50°C with 2 ml of hybridization solution.
Following this stringent wash, the strips were incubated with 2 ml of
alkaline phosphatase-streptavidin conjugate for 30 min at room
temperature. Strips were washed twice with 2 ml of rinse solution and
once with 2 ml of substrate buffer. Two milliliters of substrate
(5-bromo-4-chloro-3-indolylphosphate and nitroblue tetrazolium) was
added and incubated for 30 min at room temperature. The reaction was
stopped by aspiration of the substrate solution and addition of 2 ml of
distilled water. After drying, the strip results were interpreted by
eye by comparing the hybridization pattern to standard type-specific
templates. The HPV type was determined by eye according to the
following criteria.
In most cases the probe name is directly linked to the HPV type (e.g.,
a purple color on probe line 16 indicates the presence of HPV-16).
Probes c31, c56, and c68 are secondary probes, which are of interest
only when there is a positive hybridization with the probe line just
above (31/40/58, 56/74, or 68/45). These c probes were developed in
order to discriminate between infections with single HPV genotypes and
mixed infections. HPV-40, -58, -74, and -45 are also identified
separately by independent probe lines. A true infection with HPV-31
yields positive hybridization with probe line 31/40/58 as well as c31.
The c probes c31, c56, and c68 will also react with other HPV types,
which have completely matching sequences. Probe c31 also reacts with
amplimers from types 33 and 54.
Since the LiPA does not contain a separate probe for HPV-54, a sample
containing type 54 will react exclusively with probe c31. Similarly,
probe c56 reacts with type 58 amplimers. Therefore, amplimers of type
58 will show reactivity with probes 30/40/58, c56, and 58. Probe c68 is
also reactive with amplimers from types 18 and 39. HPV-74 is identified
by the probes 56/74 and 74. In summary, HPV genotypes 6, 11, 16, 18, 34, 35, 39, 42 to 44, 51 to 54, 59, 66, and 70 are recognized by
hybridization to a single probe line, whereas HPV types 18, 31, 33, 39, 40, 45, 56, 58, 68, and 74 yield a specific hybridization pattern on
the LiPA.
Statistical analyses.
Data were analyzed by using the Fisher
exact test or McNemar's test.
| |
RESULTS |
Development of SPF PCR primers.
Complete or partial HPV
sequences were obtained from GenBank and used for alignment of L1
region sequences. As described earlier (17), the L1 region
is relatively well conserved, and several general PCR primers in this
part of the HPV genome were developed (Fig.
1). Recently, we have selected a novel
set of PCR primers in this region which amplify a fragment of only 65 bp (17). These primers, designated SPF, allowed extremely
sensitive amplification from a broad spectrum of HPV genotypes. The
present study aimed at using the sequence variation within the
amplified fragment of 65 bp for identification of specific HPV
genotypes. The SPF primers flank an interprimer region of 22 bp. The
alignment of the complete 65-bp fragments amplified by SPF primers from
the L1 regions of different mucosal HPV genotypes is shown in Fig. 2. Apparently, all HPV genotypes except
genotypes 68 and 73 have a unique SPF interprimer sequence.
View larger version (51K):
[in this window]
[in a new window]
|
FIG. 2.
Alignment of 65-bp nucleotide sequences from the L1
regions of a total of 39 HPV genotypes. The target sequences for the
SPF primers are boxed and flank the 22-bp interprimer region, as
indicated. Positions are according to the HPV-16 sequence PPH16
(GenBank accession no. K02718).
|
|
Inter- and intratypic sequence conservation in the SPF 22-bp
interprimer region.
To investigate whether the observed sequence
variation among and between HPV genotypes is consistent, a total of 134 sequences from 31 mucosal HPV genotypes, obtained from GenBank, were
analyzed (Table 1). For each genotype,
the full-length genomic sequence was used as a reference (see Materials
and Methods). In 8 (5.9%) of the 134 sequences studied, the
interprimer sequences were not completely conserved compared to their
respective reference sequences. Four of the nine HPV-18 sequences
showed identical single-base-pair mismatches to the reference sequence,
and this variant was provisionally designated HPV-18var. One of the two
HPV-57 sequences contained a single mismatch, and this sequence had
been formally classified as HPV-57b (33). Thus, in these
five cases the correct HPV type can be recognized by analysis of the
22-bp sequences. In contrast, one of the HPV-11 sequences showed five
mismatches compared to the reference sequence. Among 28 HPV-16
sequences, one sequence contained a single mismatch to the reference
sequence. One of the HPV-54 sequences showed two mismatches to the
reference. Taken together, analysis of the 22-bp sequences resulted in
identification of the correct HPV in 131 (97.8%) of the 134 cases.
View this table:
[in this window]
[in a new window]
|
TABLE 1.
Conservation of the 22-bp SPF interprimer sequences among
mucosal HPV genotypes for 134 HPV sequences obtained
from GenBanka
|
|
Since the number of L1 region sequences available in GenBank was
limited for several HPV genotypes, a total of 104 clinical isolates
were also analyzed. HPV DNA was amplified from these samples by the MY
09/11 as well as the SPF primers. Identification of HPV genotypes was
based on sequence analysis of the MY 09/11 amplimer. SPF amplimers were
also analyzed, and the HPV genotypes were deduced from the 22-bp SPF
interprimer sequences. The results are shown in Table
2. Among the 104 isolates studied, MY
09/11- and SPF-based typing results were initially discordant in 7 cases (5.1%). These discordant cases were further analyzed. Among 19 isolates identified as HPV-16 by the MY 09/11 sequence, SPF analysis showed the presence of HPV-31 in 1 isolate. Type-specific PCR revealed
the presence of both HPV-16 and -31 in this isolate. Similarly, in one
sample containing HPV-18, SPF PCR detected HPV-16, and the presence of
both HPV-16 and -18 was confirmed by type-specific PCR. In the isolate
containing HPV-51, sequence analysis of the SPF fragment revealed a
single mismatch to the HPV-51 reference sequence. Two of the five
samples with HPV-56 yielded discordant results. In one case, the 22-bp
sequence showed a single mismatch to the HPV-56 reference sequence,
whereas the other case showed the presence of HPV-45. One case of
HPV-58 was mistyped as HPV-56 by the SPF system. In the sample
containing HPV-73, the SPF system detected HPV-53. Since type-specific
primers are not available for HPV-51, -53, -56, -58, and -73, not all
discordant results could be analyzed by type-specific PCR. Thus, the
HPV types identified from the 22-bp SPF interprimer sequences were
initially concordant with MY 09/11 sequences in 99 (95.2%) of the 104 cases studied. Several discordant results were suspected to be due to
the presence of multiple HPV types, and this was further analyzed by
reverse hybridization (see below). These results show that sequence
variation of the SPF amplimer can be used to identify a broad range of
HPV genotypes.
View this table:
[in this window]
[in a new window]
|
TABLE 2.
Identification of HPV genotypes by direct sequencing of
MY 09/11 and SPF amplimers and by SPF LiPA in 104 clinical
samples (group 1)
|
|
Development of a reverse hybridization LiPA.
To identify HPV
genotypes by hybridization, specific probes were deduced from the SPF
sequence alignments (Fig. 2) and used to develop the INNO-LiPA HPV
prototype research genotyping assay. Since HPV genotypes often differ
by only a single nucleotide in the 22-bp interprimer sequences,
well-controlled hybridization conditions are necessary. Therefore, a
reverse hybridization LiPA was developed (27), allowing the
simultaneous identification of multiple HPV genotypes in a single
hybridization step. All probes were optimized to ensure that
hybridization occurs only between completely matching sequences. The
outline and representative examples of the HPV LiPA are shown in Fig.
3.
View larger version (64K):
[in this window]
[in a new window]
|
FIG. 3.
Outline and representative examples of the INNO-LiPA HPV
genotyping assay. The positions of the control line and the 28 specific
probes for each of the 25 HPV genotypes are shown at the left. The
number above each strip indicates the HPV genotype for which DNA was
amplified by SPF primers. The precise interpretation of the
hybridization patterns is described in detail in Materials and
Methods.
|
|
Most of the HPV genotypes are recognized by hybridization to a single
type-specific probe. However, a number of HPV genotypes, i.e., 6, 31, 33, 40, 45, 56, 58, 68, and 74, hybridize to more than one probe and
can be directly recognized by a specific hybridization pattern on the strip.
To assess the efficacy and reliability of the LiPA, HPV sequences were
amplified by SPF primers from a total of 34 plasmids containing
complete or partial HPV genomic sequences. The relevant part of the L1
region was amplified from these plasmids and analyzed by direct
sequencing. SPF LiPA yielded the expected HPV genotyping results in all
cases, and these were completely concordant with sequence data,
indicating the high specificity of the reverse hybridization assay.
To determine the efficacy of the SPF system to detect multiple HPV
genotypes, mixtures of HPV-11 and HPV-18 target DNAs were tested. A
fixed quantity of HPV-11 was combined with increasing concentrations of
HPV-18. Conversely, a fixed quantity of HPV-18 DNA was combined with
various concentrations of HPV-11. All mixtures were amplified by the
SPF primers and tested in the LiPA. The results indicated that the SPF
system permits detection of two different HPV genotypes, even if one
type is present in a 1,000-fold excess over the other type (data not
shown). In contrast, it appears that sequence analysis permitted
type-specific detection of both types up to only a 10-fold excess of
one genotype over the other.
The amplification target of the SPF primers is located within the
target region for the MY 09/11 primer set. Therefore, SPF as well as MY
09/11 amplimers can be used for analysis in the LiPA, provided that PCR
primers are biotinylated. SPF and MY 09/11 amplimers from the 104 clinical samples of patient group 1 had already been analyzed by direct
sequencing as described above and shown in Table 2. Subsequently, these
amplimers were also tested by LiPA. In one HPV-16 isolate, the presence
of HPV-16 and -31, as also determined by type-specific PCR, was
confirmed, indicating infection with multiple HPV types in this case.
Similarly, the presence of both HPV-16 and -18 in the single discordant
case of HPV-18 was confirmed. Since the single mismatch was not
included in the type-specific probe for these genotypes on the LiPA
strip, the HPV-51 isolate and one of the HPV-56 isolates that showed a
mismatch to their reference sequences were both correctly typed by the
LiPA. In the remaining discordant case of HPV-56, a mixture of HPV-45,
-52, and -56 was found. By using the SPF system, one of the HPV-58
isolates was identified as HPV-56 by sequencing as well as by LiPA. The
sequence of the MY 09/11 amplimer classified this isolate as HPV-58,
but the 22-bp SPF interprimer region in this amplimer was completely
homologous to that of HPV-56 (Fig. 2). In the 22-bp SPF interprimer
region, the HPV-58 genome differs by only two nucleotides from HPV-56.
Therefore, this isolate can be considered as being mistyped by SPF due
to intratypic sequence variation of HPV-58. Finally, LiPA analysis of
the sample containing HPV-73 revealed the presence of a mixture of
HPV-53 and HPV-68 or -73.
Taken together, and including the cases with multiple HPV genotypes,
the LiPA results were in agreement with the sequence analysis of the
SPF and MY 09/11 fragments, as well as type-specific PCR, in 103 (99%)
of the 104 cases.
Evaluation of the HPV LiPA with clinical samples.
To assess
the performance of the HPV LiPA system, various groups of clinical
specimens were investigated. All clinical samples yielded a
-globin-specific amplimer, confirming the presence of amplifiable
DNA. A total of 488 cervical scrapes from patient group 2, classified
as having normal cytology or ASCUS, were tested by SPF PCR, as well as
with the GP5+/6+ primers. SPF PCR detected HPV
DNA in 117 (24%), whereas GP5+/6+ detected
HPV-DNA in only 77 (15.7%), of the cases. SPF PCR was repeated for
cases that were exclusively positive by SPF to confirm the presence of
HPV DNA. The GP5+/6+-positive samples were all
positive by SPF PCR. To confirm the specificity of the SPF primer set,
the resulting amplimers were subjected to sequence analysis, and the
results are shown in Table 3. Based on
100% identity to reference sequences, the 22-bp sequences could be
assigned to known HPV genotypes in 93 (79.4%) of the SPF-positive
cases, and multiple HPV types were detected in 12 samples (10.2%).
GP5+/6+ PCR did not detect HPV DNA in 40 (34.2%) of the 117 SPF-positive cases, and these
GP5+/6+-negative cases were distributed over
multiple HPV genotypes, suggesting a higher sensitivity of SPF over a
broad range of HPV genotypes.
View this table:
[in this window]
[in a new window]
|
TABLE 3.
Detection of different HPV genotypes by SPF and
GP5+/6+ PCR among 488 cervical scrapes from
group 2 (1997) and 278 cervical scrapes from group
3 (1998)
|
|
A total of 278 cervical scrapes in patient group 3, also classified as
having normal cytology or ASCUS, were investigated by SPF and
GP5+/6+ PCR. These results are also shown in
Table 3. SPF PCR yielded positive results in 70 samples (25.2%),
whereas the use of GP5+/6+ resulted in only 52 positive cases (18.7%). SPF LiPA detected multiple HPV types in 10 (14.2%) of the SPF-positive samples. The cases that remained
undetected by GP5+/6+ but were SPF positive
were distributed over various HPV types. In 8 (11.4%) of the 70 SPF-positive samples, the HPV type could not be assigned.
Altogether, a total of 766 cervical scrapes (groups 2 and 3), were
analyzed, of which 697 (90.1%) had normal cytology and 69 (8.9%) were
classified as ASCUS. Among the cases with normal cytology, SPF PCR
detected 157 (22.5%), whereas GP5+/6+ detected
only 101 (14.4%), HPV-positive samples, and this difference was highly
significant (P < 0.001). Among the 69 cases classified as ASCUS, SPF primers detected more HPV-positive samples (30/69 = 43.5%) than the GP5+/6+ primers (26/69 = 37.7%), but this difference was not statistically significant.
Among all SPF-positive samples, 8 (53.3%) of 15 samples containing
HPV-31 were GP5+/6+ negative. Similarly, 6 (50%) of the 12 HPV-66 cases remained undetected by
GP5+/6+ (Table 3). These findings indicate a
significantly lower sensitivity of the latter primer set for these
particular HPV types. Sequences from 32 (17.1%) of the 187 SPF-positive samples could not be assigned to any known HPV genotype.
Of these 32 samples 26 were tested with the MY 09/11 primers, and 8 were HPV positive. All interprimer sequences were exactly 22 bp in
length and were similar to HPV sequences, but they showed between one
and five mismatches to any known HPV genotype. Among the 155 samples
containing a known HPV genotype, 32 (20.6%) were infected by an HPV
with a low-risk genotype (HPV-6, -11, -42, -44, -53, -54, -55, -61, -62, -67, -70, -74, or -MM7).
The fourth group comprised 304 selected cervical smears with mild to
moderate (n = 151) or severe (n = 153)
dyskaryosis. A total of 299 (98.4%) of the 304 samples were positive
by SPF PCR. HPV genotypes were determined by SPF LiPA, and the results
are shown in Table 4. Of these, 147 (97.3%) of the 151 cases with mild or moderate dyskaryosis were SPF
positive, and 95 of these contained a single HPV genotype. In 2 (1.4%)
of the 147 SPF-positive samples, the sequences could not be assigned to
a known HPV type, and these will require further characterization.
High-risk HPV genotypes (HPV-16, -18, -31, -33, -35, -45, -51, -52, -56, -58, and -66) were present in 95.2% of the cases. Similarly, 152 (99.3%) of the 153 scrapes diagnosed with severe dyskaryosis were HPV positive. HPV genotypes could be assigned in 151 (99.3%) of these samples, and all were classified as high-risk types.
View this table:
[in this window]
[in a new window]
|
TABLE 4.
Detection of HPV genotypes among 304 cervical smears with
mild or moderate dyskaryosis or severe dyskaryosis (group 4)
|
|
Altogether, the SPF sequences could not be assigned to a known HPV
genotype in only 3 (1%) of the 304 cases. A total of 105 (34.5%) of
the 304 samples contained more than one HPV genotype, and in 103 (98.1%) of these, at least one high-risk genotype was detected. In 21 (6.9%) of the samples, three HPV genotypes were detected, and in 5 (1.6%) cases, four different HPV types were observed.
Group 5 contained 180 formalin-fixed, paraffin-embedded cervical
carcinoma samples, comprising 51 adenocarcinomas and 129 squamous cell
carcinomas. SPF PCR yielded positive results in all cases. HPV
genotypes were identified by sequence analysis and LiPA, and only
high-risk HPV types were found, as shown in Table
5. HPV-16 and -18 were found in more than
70% of both groups. The relative prevalence of HPV-18 (17.6%) among
the adenocarcinomas was higher than that among the squamous cell
carcinomas (6.2%), and this difference was statistically significant
(P = 0.027). The number of samples containing other
high-risk HPV types was too small to analyze differences between the
two groups of carcinomas.
View this table:
[in this window]
[in a new window]
|
TABLE 5.
HPV genotypes among 180 cervical carcinomas as determined
by sequence and LiPA analysis of SPF
PCR fragments
|
|
| |
DISCUSSION |
Diagnosis of HPV infection relies on the detection of the viral
DNA. The L1 region of the HPV genome has been used for the development
of general PCR primer sets, such as MY 09/11, and GP5+/6+ (11, 13). Recently, we have
developed a novel SPF primer set, amplifying a fragment of only 65 bp
from this L1 region (17). We evaluated the use of these SPF
primers and investigated whether sequence variation in the 22-bp SPF
interprimer region permits identification of HPV genotypes. Although
this 22-bp sequence does not permit formal classification of HPV
genotypes, it showed consistent intertypic sequence variation. The
inter- and intratypic sequence variation was assessed by analysis of
HPV sequences of the L1 region. Altogether, analysis of the 22-bp
fragment, as compared to the sequence of the larger MY 09/11 fragment,
resulted in reliable genotype identification for 232 (97.5%) of the
238 HPV sequences from GenBank and from clinical materials (Tables 1
and 2). Thus, the intratypic sequence variation among isolates of the
same HPV genotype appeared to be limited in this small part of the
genome, and the intertypic sequence variation is sufficiently representative for identification of specific HPV genotypes.
Based on the consistent sequence heterogeneity of the SPF amplimer,
genotype-specific probes were selected, and a reverse hybridization
LiPA was developed. The current version of the INNO-LiPA HPV prototype
research genotyping assay comprises the SPF primer set and a reverse
hybridization strip containing 28 probes for the detection of 25 different HPV genotypes. The performance of the LiPA was first
investigated by analysis of SPF amplimers obtained from HPV
DNA-containing plasmids. All HPV genotypes were correctly identified,
indicating the high specificity of the SPF LiPA. Also, the LiPA is
extremely sensitive for the simultaneous detection of multiple HPV
types, even if one type is present in great excess over the other.
Evaluation of the SPF LiPA system was performed with multiple groups of
clinical specimens, including cervical smears and cervical carcinomas.
Among cervical scrapes with normal cytology or ASCUS, the prevalences
of HPV-positive cases, as well as the distributions of genotypes, were
highly similar. In these specimens, SPF PCR appears to be significantly
more sensitive than GP5+/6+, especially among
the cases with normal cytology. This finding confirmed earlier
observations (17) and may be explained by the lower
concentration of HPV in samples with normal cytology. Although data
about the natural history of HPV infections are limited, the viral load
is presumably low during the first phase of infection but may increase
over time, in parallel with the development of cytological aberrations
(25). Since most cervical smears are classified as normal or
ASCUS, the use of an extremely sensitive method to diagnose HPV
infection is crucial to achieve a maximal negative predictive value for
the development of HPV-associated cervical carcinoma. Therefore, the
use of the SPF system may have important clinical implications for
triage and follow-up of patients with ASCUS and even for patients with
normal cytology.
It is not completely clear whether certain HPV genotypes should be
considered high-risk types. High-risk HPV types have been frequently
detected in cervical and anogenital cancers (18, 34).
However, this definition also depends on the accuracy of the HPV
detection methods. PCR-based assays can be hampered, especially in
archival smears or paraffin-embedded materials, in which the DNA is
often damaged. The SPF primers permit efficient detection of HPV DNA in
these materials. In the present study, SPF PCR detected HPV DNA in all
cervical carcinoma samples, and the HPV genotypes in these samples were
classified as high-risk types. HPV-16 and -18 are present in more than
70% of these carcinomas, confirming the importance of these high-risk
genotypes. The prevalence of HPV-18 appeared to be significantly higher
among adenocarcinoma cases than among squamous cell carcinoma cases,
and this is in agreement with earlier observations (2, 19).
The prevalence of multiple HPV infections differed considerably between
the clinical groups. Among cases with normal cytology or ASCUS,
multiple HPV types were found in 11.8% of the HPV-positive cases,
whereas among cases with mild or moderate dyskaryosis, multiple HPV
types were detected in 34.5% of the cases. Among the carcinoma
samples, only 4.4% contained more than one HPV type, which may, e.g.,
be due to an underlying CIN lesion in the biopsy taken.
The SPF primers detect a very broad range of HPV genotypes with
apparently equal sensitivity. In contrast, other general primers appear
to have lower sensitivities for certain HPV genotypes (12, 17,
22), as exemplified by the limited sensitivity of the GP5+/6+ primers for HPV-31 and HPV-66 (Table
3). The differential sensitivities for certain HPV genotypes can be a
crucial factor for the detection of multiple HPV genotypes, since this
may result in a considerable underestimation of the true prevalence of
multiple HPV infections. Both the amplification of a broad range of HPV
genotypes by the SPF primers and the sensitive detection of specific
genotypes by LiPA play an important role in the overall sensitivity of
the SPF system.
The present study also showed that sequence analysis of PCR products
does not accurately reflect the presence of multiple HPV types but
reveals only the sequence of the most prevalent HPV type(s). In
contrast, the reverse hybridization method permits simultaneous and
accurate detection of multiple HPV types with much higher sensitivity.
In conclusion, the SPF system can play an important role in further
studies of the epidemiology of HPV infections as well as the
relationships between cervical carcinoma and specific HPV genotypes.
| |
ACKNOWLEDGMENTS |
We thank Semyon Petrov and Frank Smedts for providing the
carcinoma biopsies and histological analysis. Els Stet is acknowledged for preparation of LiPA strips. We also thank Jannie Baars for her
assistance with cytological examinations and Ron Berkhout for his
contributions to the initial sequence analyses.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Delft Diagnostic
Laboratory, R. de Graafweg 7, P.O. Box 5100, 2600 GA Delft, The
Netherlands. Phone: 31-15-2604581. Fax: 31-15-2604550. E-mail:
wquint{at}ddl.nl.
| |
REFERENCES |
| 1.
|
Altschul, S. F.,
W. Gish,
W. Miller,
E. W. Myers, and D. J. Lipman.
1990.
Basic local alignment search tool.
J. Mol. Biol.
215:403-410[Medline].
|
| 2.
|
Arends, M. J.,
Y. K. Donaldson,
E. Duvall,
A. H. Wyllie, and C. C. Bird.
1991.
HPV in full thickness cervical biopsies: high prevalence in CIN 2 and CIN 3 detected by a sensitive PCR method.
J. Pathol.
165:301-309[Medline].
|
| 3.
|
Baay, M. F.,
W. G. Quint,
J. Koudstaal,
H. Hollema,
J. M. Duk,
M. P. Burger,
E. Stolz, and P. Herbrink.
1996.
Comprehensive study of several general and type-specific primer pairs for detection of human papillomavirus DNA by PCR in paraffin-embedded cervical carcinomas.
J. Clin. Microbiol.
34:745-747[Abstract].
|
| 4.
|
Bernard, H. U.,
S. Y. Chan,
M. M. Manos,
C. K. Ong,
L. L. Villa,
H. Delius,
C. L. Peyton,
H. M. Bauer, and C. M. Wheeler.
1994.
Identification and assessment of known and novel human papillomaviruses by polymerase chain reaction amplification, restriction fragment length polymorphisms, nucleotide sequence, and phylogenetic algorithms.
J. Infect. Dis.
170:1077-1085[Medline]. (Erratum, 173:516, 1996.)
|
| 5.
|
Bosch, F. X.,
M. M. Manos,
N. Munoz,
M. Sherman,
A. M. Jansen,
J. Peto,
M. H. Schiffman,
V. Moreno,
R. Kurman, and K. V. Shah.
1995.
Prevalence of human papillomavirus in cervical cancer: a worldwide perspective. International Biological Study on Cervical Cancer (IBSCC) Study Group.
J. Natl. Cancer Inst.
87:796-802[Abstract/Free Full Text].
|
| 6.
|
Burger, M. P.,
H. Hollema,
W. J. Pieters, and W. G. Quint.
1995.
Predictive value of human papillomavirus type for histological diagnosis of women with cervical cytological abnormalities.
BMJ
310:94-95[Free Full Text].
|
| 7.
|
Chan, S. Y.,
H. Delius,
A. L. Halpern, and H. U. Bernard.
1995.
Analysis of genomic sequences of 95 papillomavirus types: uniting typing, phylogeny, and taxonomy.
J. Virol.
69:3074-3083[Abstract].
|
| 8.
|
Clavel, C.,
S. Rihet,
M. Masure,
C. Chypre,
J. C. Boulanger,
C. Quereux, and P. Birembaut.
1998.
DNA-EIA to detect high and low risk HPV genotypes in cervical lesions with E6/E7 primer mediated multiplex PCR.
J. Clin. Pathol.
51:38-43[Abstract].
|
| 9.
|
Cox, J. T.,
A. T. Lorincz,
M. H. Schiffman,
M. E. Sherman,
A. Cullen, and R. J. Kurman.
1995.
Human papillomavirus testing by hybrid capture appears to be useful in triaging women with a cytologic diagnosis of atypical squamous cells of undetermined significance.
Am. J. Obstet. Gynecol.
172:946-954[Medline].
|
| 10.
|
Cuzick, J.,
A. Szarewski,
G. Terry,
L. Ho,
A. Hanby,
P. Maddox,
M. Anderson,
G. Kocjan,
S. T. Steele, and J. Guillebaud.
1995.
Human papillomavirus testing in primary cervical screening.
Lancet
345:1533-1536[Medline].
|
| 11.
|
de Roda Husman, A. M.,
J. M. Walboomers,
A. J. van den Brule,
C. J. Meijer, and P. J. Snijders.
1995.
The use of general primers GP5 and GP6 elongated at their 3' ends with adjacent highly conserved sequences improves human papillomavirus detection by PCR.
J. Gen. Virol.
76:1057-1062[Abstract/Free Full Text].
|
| 12.
|
Gravitt, P. E.,
C. L. Peyton,
R. J. Apple, and C. M. Wheeler.
1998.
Genotyping of 27 human papillomavirus types by using L1 consensus PCR products by a single-hybridization, reverse line blot detection method.
J. Clin. Microbiol.
36:3020-3027[Abstract/Free Full Text].
|
| 13.
|
Hildesheim, A.,
M. H. Schiffman,
P. E. Gravitt,
A. G. Glass,
C. E. Greer,
T. Zhang,
D. R. Scott,
B. B. Rush,
P. Lawler,
M. E. Sherman,
R. J. Kurman, and M. M. Manos.
1994.
Persistence of type-specific human papillomavirus infection among cytologically normal women.
J. Infect. Dis.
169:235-240[Medline].
|
| 14.
|
Jacobs, M. V.,
A. M. de Roda Husman,
A. J. van den Brule,
P. J. Snijders,
C. J. Meijer, and J. M. Walboomers.
1995.
Group-specific differentiation between high- and low-risk human papillomavirus genotypes by general primer-mediated PCR and two cocktails of oligonucleotide probes.
J. Clin. Microbiol.
33:901-905[Abstract].
|
| 15.
|
Jacobs, M. V.,
P. J. Snijders,
A. J. van den Brule,
T. J. Helmerhorst,
C. J. Meijer, and J. M. Walboomers.
1997.
A general primer GP5+/6(+)-mediated PCR-enzyme immunoassay method for rapid detection of 14 high-risk and 6 low-risk human papillomavirus genotypes in cervical scrapings.
J. Clin. Microbiol.
35:791-795[Abstract].
|
| 16.
|
Jenkins, A.,
B. E. Kristiansen,
E. Ask,
B. Oskarsen,
E. Kristiansen,
B. Lindqvist,
C. Trope, and K. Kjorstad.
1991.
Detection of genital papillomavirus types by polymerase chain reaction using common primers.
APMIS
99:667-673[Medline].
|
| 17.
|
Kleter, B.,
L. J. van Doorn,
J. ter Schegget,
L. Schrauwen,
C. van Krimpen,
M. P. Burger,
B. ter Harmsel, and W. G. V. Quint.
1998.
A novel short-fragment PCR assay for highly sensitive broad-spectrum detection of anogenital human papillomaviruses.
Am. J. Pathol.
153:1731-1739[Abstract/Free Full Text].
|
| 18.
|
Lorincz, A. T.,
R. Reid,
A. B. Jenson,
M. D. Greenberg,
W. Lancaster, and R. J. Kurman.
1992.
Human papillomavirus infection of the cervix: relative risk associations of 15 common anogenital types.
Obstet. Gynecol.
79:328-337[Abstract].
|
| 18a.
| Los Alamos National Laboratory. 23 October 1997, revision date. Los Alamos database. [Online.]
http://hpv-web.lanl.gov. [2 June 1999, last date accessed.]
|
| 19.
|
Low, S. H.,
T. W. Thong,
T. H. Ho,
Y. S. Lee,
T. Morita,
M. Singh,
E. H. Yap, and Y. C. Chan.
1990.
Prevalence of human papillomavirus types 16 and 18 in cervical carcinomas: a study by dot and Southern blot hybridization and the polymerase chain reaction.
Jpn. J. Cancer Res.
81:1118-1123[Medline].
|
| 20.
|
Lundberg, G. D.
1989.
The 1988 Bethesda system for reporting cervical/vaginal cytological diagnosis.
JAMA
262:931-934[Medline].
|
| 20a.
| National Center for Biotechnology Information. 13 April 1999, revision date. [Online.] http://www.ncbi.nlm.nih.gov. [2
June 1999, last date accessed.]
|
| 21.
|
Ohara, Y.,
M. Honma, and Y. Iwasaki.
1992.
Sensitivity of the polymerase chain reaction for detecting human T-cell leukemia virus type I sequences in paraffin-embedded tissue. Effect of unbuffered formalin fixation.
J. Virol. Methods
37:83-88[Medline].
|
| 22.
|
Qu, W.,
G. Jiang,
Y. Cruz,
C. J. Chang,
G. Y. Ho,
R. S. Klein, and R. D. Burk.
1997.
PCR detection of human papillomavirus: comparison between MY09/MY11 and GP5+/6+ primer systems.
J. Clin. Microbiol.
35:1304-1310[Abstract].
|
| 23.
|
Richart, R. M.
1995.
Screening. The next century.
Cancer
76:1919-1927[Medline].
|
| 24.
|
Saiki, R. K.,
D. H. Gelfand,
S. Stoffel,
S. J. Scharf,
R. Higuchi,
G. T. Horn,
K. B. Mullis, and H. A. Erlich.
1988.
Primer-directed enzymatic amplification of DNA with a thermostable DNA polymerase.
Science
239:487-491[Abstract/Free Full Text].
|
| 25.
|
Smits, H. L.,
L. J. Bollen,
S. P. Tjong-A-Hung,
J. Vonk,
J. van der Velden,
F. J. ten Kate,
J. A. Kaan,
B. W. Mol, and J. ter Schegget.
1995.
Intermethod variation in detection of human papillomavirus DNA in cervical smears.
J. Clin. Microbiol.
33:2631-2636[Abstract].
|
| 26.
|
Snijders, P. J.,
A. J. van den Brule,
H. F. Schrijnemakers,
G. Snow,
C. J. Meijer, and J. M. Walboomers.
1990.
The use of general primers in the polymerase chain reaction permits the detection of a broad spectrum of human papillomavirus genotypes.
J. Gen. Virol.
71:173-181[Abstract/Free Full Text].
|
| 27.
|
Stuyver, L.,
R. Rossau,
A. Wyseur,
M. Duhamel,
B. Vandenborght,
H. van Heuverswyn, and G. Maertens.
1993.
Typing of HCV isolates and characterization of new (sub)types using a line probe assay.
J. Gen. Virol.
74:1093-1102[Abstract/Free Full Text].
|
| 28.
|
Stuyver, L.,
A. Wyseur,
W. van Arnhem,
F. Hernandez, and G. Maertens.
1996.
Second-generation line probe assay for hepatitis C virus genotyping.
J. Clin. Microbiol.
34:2259-2266[Abstract].
|
| 29.
|
ter Harmsel, B.,
R. van Muyden,
F. Smedts,
J. Hermans,
J. Kuijpers,
N. Raikhlin,
S. Petrov,
A. Ledebev,
F. Ramaekers, and B. Trimbos.
1998.
The significance of cell type and tumor growth markers in the prognosis of unscreened cervical cancer patients.
Int. J. Gyn. Cancer
8:336-344.
|
| 30.
|
Tieben, L. M.,
J. ter Schegget,
R. P. Minnaar,
J. Bouwes Bavinck,
R. J. Berkhout,
B. J. Vermeer,
M. F. Jebbink, and H. L. Smits.
1993.
Detection of cutaneous and genital HPV types in clinical samples by PCR using consensus primers.
J. Virol. Methods
42:265-279[Medline].
|
| 31.
|
van den Brule, A. J.,
E. C. Claas,
M. Du Maine,
W. J. Melchers,
T. Helmerhorst,
W. G. Quint,
J. Lindeman,
C. J. Meijer, and J. M. Walboomers.
1989.
Use of anticontamination primers in the polymerase chain reaction for the detection of human papilloma virus genotypes in cervical scrapes and biopsies.
J. Med. Virol.
29:20-27[Medline].
|
| 32.
|
van Ranst, M. A.,
J. B. Kaplan, and R. D. Burk.
1992.
Phylogenetic classification of human papillomaviruses: correlation with clinical manifestations.
J. Gen. Virol.
73:2653-2660[Abstract/Free Full Text].
|
| 33.
|
Wu, T. C.,
J. M. Trujillo,
H. K. Kashima, and P. Mounts.
1993.
Association of human papillomavirus with nasal neoplasia.
Lancet
341:522-524[Medline].
|
| 34.
|
zur Hausen, H.
1996.
Papillomavirus infections a major cause of human cancers.
Biochim. Biophys. Acta
1288:F55-F78[Medline].
|
Journal of Clinical Microbiology, August 1999, p. 2508-2517, Vol. 37, No. 8
0095-1137/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
![[Feedback]](/icons/banner/feedbackACT.gif){kind=icon}
![[For Subscribers]](/icons/banner/subscriberACT.gif){kind=icon}
![[Archive]](/icons/banner/archiveACT.gif){kind=icon}
![[Search]](/icons/banner/searchACT.gif){kind=icon}
![[Contents]](/icons/banner/tocACT.gif){kind=icon}
Top
Abstract
Introduction
