Temporal trends of dengue fever/dengue hemorrhagic fever in Bangkok, Thailand from 1981 to 2000: an age-period-cohort analysis.

The aim of this study was to examine the effects of age, time period, and birth cohorts with dengue fever/dengue hemorrhagic fever (DF/DHF) in Bangkok, Thailand over the period 1981-2000. The age group at greatest risk for DF/DHF was 5-9 years old. The period effect shows a remittent pattern, with significant increases in 1986-1990 and 1996-2000. The birth cohort group showed a significant decreasing trend from the 1961-1965 group to the 1991-1995 group (R2 = 0.7620) with a decreasing rate of 0.1. We concluded that the temporal trend of DF/DHF is decreasing; especially for DHF.

Molecular serotyping of dengue viruses in field-caught Aedes mosquitos by in-house RNA extraction/RT-PCR reagent kits.

We developed in-house RNA extraction and RT-PCR reagent kits for the molecular serotyping of dengue viruses in field-caught Aedes mosquitos. Mosquitos that showed positive results by ELISA or IFA were selected for the identification of dengue viruses in order to predict the distribution of the four dengue serotypes. Total RNA was extracted from one whole mosquito as well as from one dissected mosquito by our in-house RNA extraction reagents using the modified method of guanidinium thiocyanate denaturation and isopropanol precipitation. The extracted RNA was amplified by our in-house RT-PCR reagents specific for each dengue serotype under optimized conditions. Dengue viral RNA extracted from a single mosquito as well as from the head and thorax of one dissected mosquito could be detected successfully; it could not be found in the abdomen, however. These results indicated that most of the dengue viruses were located in the head and thorax rather than in the abdomen. The results of dengue serotyping showed a pure specific PCR product for each dengue serotype at 490, 230, 320 and 398 bp for DEN-1, DEN-2, DEN-3, and DEN-4 respectively. In addition, the detection sensitivity was very high: an amount of RNA template equivalent to approximately 1/80 of a single mosquito could be detected by agarose gel electrophoresis and ethidium bromide staining. The coupling of RT-PCR-based surveillance of dengue viral infection with disease mapping data (Geograpical Information System, GIS) could serve as an alternative epidemiological means of providing an early warning of dengue fever/dengue hemorrhagic fever epidemics.

Perinatal dengue infection.

We report a case of vertical transmission of dengue infection in an infant. The mother's was a term pregnancy with a history of chronic hypertension. She presented with high fever of 3 days duration 5 days prior to delivery. Her initial complete blood count showed platelet count of 64,000/mm3. Dengue hemorrhagic fever was diagnosed 2 days later and symptomatic treatment was given. During labor her platelets dropped to 11,000/mm3 and platelet concentrate was given. Cesarean section was performed due to prolonged second stage of labor. Her infant was normal at birth except for petechiae on the left thigh. The child's platelet count was 34,000/mm3 and low grade fever was detected on the first day. Clinical sepsis was suspected and antibiotic treatment was started and continued for 4 days until all the cultures came back as negative. Both mother and her baby made an uneventful recovery and were discharged 6 days after delivery with normal platelet counts. Maternal blood was positive for IgM antibody to dengue virus. Both cord blood and the baby's blood were positive for dengue virus serotype 2 by PCR.

A dengue shock patient with negative serology and polymerase chain reaction (PCR) tests.

A 6-month-old Thai girl presented with clinical manifestations of dengue shock syndrome (DSS) with encephalopathy and urinary tract infection. Serology and PCR tests were negative whereas dengue virus type 2 was isolated. In cases of highly suspected dengue infections, viral isolation should be done even when serological and PCR tests are negative.

Highly conserved nucleotide sequence and its deduced amino acids of the 5'-noncoding region and the capsid protein of a Bangkok isolate dengue-3 virus.

The dengue-3 virus genome encodes an uninterrupted open reading frame (ORF) flanked by 5' and 3' non-coding regions. The order of proteins encoded in dengue-3 virus ORF, as with other flaviviruses, is: Cap 5'-C-prM-E-NS1-NS2A-NS2B-NS3-NS4A-NS4B-NS5-3'. The nucleotide sequence of the 5'-noncoding region and the capsid protein of dengue-3virus (a Bangkok isolate: CH53489 isolated by USAMC-AFRIMS in 1973) has been analyzed in both forward and reverse directions. The PCR-based cycle sequencing technique by the enzymatic method of Sanger et al (1977) using a sequencing primer 5'-end labeled with gamma32P-ATP is the method of our choice for sequencing analysis. One cDNA template was prepared by RT-PCR technique starting from the 5'-end nucleotide 1-465 of the dengue-3 genome. In our cycle sequencing experiments, the substitution of 7-deaza-dG was used for dG in DNA eliminated much of the secondary structures that produced gel artifacts. The final sequence result of this cDNA template was established from its sequence data determined on both strands in opposite directions. Alignment between the newly established nucleotide sequence as well as its deduced amino acid sequence of the Bangkok dengue-3 virus and the published sequence data of the dengue-3 prototype (H87) was manipulated by the PC-DOS-GIBIO-DNASIS TM 06-00 (Hitachi Software). According to the deduced amino acid sequence of the Bangkok dengue-3 virus, its C protein was found to be highly positively charged because of large numbers of lysine and arginine. The homology of the nucleotide sequence between the two dengue-3 virus revealed 97%. The deduced amino acid sequences from the nucleotides 95-465 of the two viruses showed the same indicating highly conserved capsid proteins. Multiple alignment of the nucleotide sequences as well as the deduced amino acid sequences among the Bangkok dengue-3 virus and other dengue 3 viruses also confirmed the highly conserved 5'-noncoding regions and the capsid proteins.

A novel method for the preparation of large cDNA fragments from dengue-3 RNA genome by long RT-PCR amplification.

For many years, dengue viruses were among the most difficult flaviviruses to isolate and to identify, but technical advances in the past 20 years have facilitated this process. Dengue viruses are usually recovered from specimens by the infection of mosquito-cell cultures. The virus may be passaged several times in cell cultures until a sufficient infectivity titer is attained. The viral nucleocapsid consists of capsid protein and an RNA genome. The dengue genome is a single stranded messenger (positive) sense RNA of approximately 11 kb in length. The isolation of dengue genomic RNA from various sources requires precautions to avoid RNases. RNases are released during cell disruption, and their activity must be inhibited as quickly as possible by using guanidinium thiocyanate in the presence of 2-mercaptoethanol. There has recently been a revolution in molecular biology with the development of the powerful reverse transcriptase (RT) and polymerase chain reaction (PCR) technology. Advanced studies on RT technique lead to much further improvement of the reverse transcriptase enzyme by genetic engineering. The Superscript II RNase H- RT (GIBCO BRL, USA) is genetically engineered DNA polymerase that synthesizes a complementary DNA strand from single-stranded RNA. DNA or an RNA-DNA hybrid. This enzyme is produced from a cloned M-MLV RT gene constructed by the introduction of point mutation in the RNase H active center. The selective mutations within the RNase H domain maintain full polymerase activity. This structural modification eliminates degradation of RNA molecules during the first strand cDNA synthesis. The combination of thermostable DNA polymerase with and without proofreading activity (3'-exonuclease activity), improved buffer conditions and thermal cycling profiles overcome the length limitation of PCR. On the basis of these findings, we have developed a long RT-PCR system for preparing large cDNA fragments of dengue 3 virus (H-87) by using the Superscript II RNase H- RT for reverse transcription and a mixture of Taq and Pwo DNA polymerases for PCR. Three large cDNA fragments covered the full genomic RNA from the 5'-end to the 3'-end of dengue-3 virus (H-87; 10,696 bps) could be successfully prepared as the lengths of 2.437 bps, 3,980 bps and 4,337 bps respectively. The ability of our developed long RT-PCR will bring speed and simplicity to genomic mapping and sequencing and facilitate studies in molecular genetics of dengue viruses.

B cells are the principal circulating mononuclear cells infected by dengue virus.

Although dengue virus infects a variety of cells in vitro, little is known about cell types infected in vivo. Since blood is a readily accessible tissue, we chose to determine which circulating blood cells are infected by dengue viruses. We collected blood mononuclear cells from acutely ill dengue patients and separated the cells by flow cytometry into subsets for virus isolation. Cells were sorted into groups corresponding to the cluster designations CD3, CD14, CD16 and CD20. Virus was isolated from sorted groups by inoculation into Toxorhynchites splendens mosquitos. The majority of the virus was recovered from the CD20 or B cell positive subset. Little virus was isolated from monocytes, NK cells or T cells. Virus was isolated from B cells regardless of the age or sex of the patient, virus serotype isolated, or the patient's history of dengue virus infection. The location of cell associated virus was determined by proteolytic digestion of surface virus. There was an equal distribution of virus between the intracellular compartment and the surface of B cells. The intracellular localization of virus was confirmed by immunocytochemistry. Since this study focused on circulating cells, no inferences were made regarding infection of cells in solid tissues.

Dengue infection with central nervous system manifestations.

A prospective observational study was conducted over a seven years period to determine the clinical and laboratory findings of dengue patients with central nervous system manifestations. Thirty serologically confirmed dengue infected patients with central nervous system manifestations were seen at the Department of Pediatrics, Faculty of Medicine, Chulalongkorn University, Bangkok and at Songkhla Hospital, Songkhla, Thailand. The age ranged between 3 months and 14 years with a mean age of 6.2 years. Seventeen were boys and thirteen were girls. The central nervous system manifestations included alteration of consciousness 76.7%, seizures 63.3%, pyramidal tract signs 36.7%, meningeal signs 30% and headache 26.7%. Eleven patients had primary while 19 had secondary dengue infection. Cerebrospinal fluid examination showed lymphocytic pleocytosis in 6 out of 28 patients while presence of anti-dengue IgM antibodies was detected in 2 out of 19 specimens of cerebrospinal fluid tested. Two patients died, autopsy was done on one patient and examination of the brain was compatible with viral encephalitis.

Nucleotide sequence and deduced amino acid sequence of the nonstructural proteins of dengue type 3 virus, Bangkok genotype.

The nucleotide sequence of the nonstructural protein gene (1,610 bases) of dengue 3 virus (Bangkok genotype; CH53489 isolated in 1973) has been determined in both forward and reverse directions. The PCR based cycle sequencing technic by the enzymatic method of Sanger et al using a sequencing primer 5'-end labeled with gamma-32P-ATP was the method of our choice for sequence analysis. Two cDNA templates were prepared by RT-PCR technique starting from the nucleotides 6,306-6,969 and 6,925-7,915 of the dengue 3 genome with the lengths of 663 and 990 base pairs respectively. In our cycle sequencing experiments, it has been observed that the substitution of 7-deaza-dG for dG in DNA eliminated most of the secondary structures that produce gel artifacts. The final sequence results of these two cDNA templates were established from their sequence data determined on both strands in opposite directions. Alignment between the newly established nucleotide sequences as well as their deduced amino acid sequences of the Bangkok dengue 3 (CH53489) virus and the published sequence data of the dengue 3 prototype (H87) was manipulated by the PC-DOS-GIBIO DNASIS TM 06-00 software. The homology of the nucleotide sequences between the two dengue 3 viruses was 96.65%. The deduced amino acid sequence from nucleotides 6,306-7,915 of the two viruses showed conserved amino acids of the nonstructural protein NS4a and 6 amino acid changes in NS4b and NS5.

Hemorrhagic fever in Cambodia is caused by dengue viruses: evidence for transmission of all four serotypes.

Hemorrhagic fever (HF) has been widespread in Cambodia and thought to be due to dengue virus although laboratory confirmation has been lacking. Between 1980 and 1995, 49,420 cases of HF and 3,032 deaths were reported. Cases increased during this period; large epidemics of HF occurred every two to three years. In 1995 there were 10,208 cases of HF with 424 deaths. Over a two day period in August 1995, 40 consecutive cases were investigated at the National Pediatric Hospital in Phnom Penh, Cambodia. All 40 cases were confirmed as dengue by virus identification and/or serology. Mean age was 6.5 years. Of 39 patients with complete medical records, the diagnoses were: dengue fever (n = 3), dengue hemorrhagic fever (DHF) grade 2 (n = 21), DHF grade 3 (n = 10), and DHF grade 4 (n = 5). The serologic response was secondary in 95%. Dengue virus was identified in 13 of 40 cases. All four dengue serotypes were identified. The high frequency of secondary infections, the low mean age of admission, and identification of all four dengue serotypes support the national statistics to show that DHF is highly endemic in Cambodia.

IgM capture ELISA for detection of IgM antibodies to dengue virus: comparison of 2 formats using hemagglutinins and cell culture derived antigens.

The highly sensitive AFRIMS format IgM capture ELISA for the diagnosis of dengue virus infections requires the use of mouse brain derived hemagglutinins and consequently also the use of 20% acetone extracted normal human serum to eliminate high background. These reagents are not always easily available and we have thus compared the AFRIMS format with another published format which uses cell culture derived antigens (culture fluid, CF, format) in order to determine if it is reasonable to use cell culture derived antigens in situations where hemagglutinins and normal human serum are difficult to obtain. The study shows that using AFRIMS results as the reference point, the CF format described here has a sensitivity of 90% and a specificity of 96%.

Human immune responses to dengue viruses.

Dengue fever (DF) and dengue hemorrhagic fever (DHF)/dengue shock syndrome (DSS) are major public health problems in many areas of the world. We are analyzing the human immune responses to dengue viruses, in order to understand the mechanism of recovery from dengue virus infections and the pathogenesis of DHF/DSS. Human natural killer (NK) cells lyse dengue virus-infected cells to a greater degree than uninfected cells. Antibodies to dengue viruses augment the lysis of dengue virus-infected cells by NK cells. Dengue virus-infected monocytes produce high levels of interferon alpha (IFN alpha). DR+ lymphocytes also produce high levels of IFN alpha after contact with dengue virus-infected monocytes. The IFN alpha produced protects uninfected monocytes from dengue virus infection. These results suggest that NK cells and IFN alpha may play an important role in controlling primary dengue virus infection. Dengue virus-specific CD4+CD8(-)T lymphocytes and CD4(-)CD8+T lymphocytes are present in the peripheral blood mononuclear cell population from donors who were infected with dengue virus. Most of CD4+T lymphocytes are dengue serotype-crossreactive. They lyse dengue virus-infected autologous cells in an HLA class II-restricted fashion, and produce interferon gamma (IFN gamma). IFN gamma augments dengue virus infection of monocytic cells in the presence of antidengue virus antibodies by increasing the number of Fc gamma receptors. Dengue virus-specific CD8+T lymphocytes lyse dengue virus-infected autologous cells in an HLA class I-restricted fashion. These CD8+T lymphocytes are also dengue serotype-crossreactive.(ABSTRACT TRUNCATED AT 250 WORDS)

Epidemic of fever of unknown origin in rural Thailand, caused by influenza A (H1N1) and dengue fever.

In the late summer (rainy season) of 1987, a sharp outbreak of fever of unknown origin (FUO) in rural southern Thailand was investigated by a field epidemiology team. In a random survey of households, 40 percent of the children and 20 percent of adults were reported to have had febrile illnesses within the last month. There was at least one death, possibly from Reye's syndrome. Testing 34 pairs of acute and convalescent sera showed significant HI antibody titer rises to influenza A (Taiwan/(H1N1) (9 cases) and dengue virus (12 cases). Testing 79 single sera with the antibody capture ELISA test for dengue, revealed that 23 percent had high titers in the IgM serum fraction suggesting recent infection. There were also six antibody titer rises to coxsackie B viruses, three from well controls. Dengue has previously been observed as a cause of FUO in rural areas in the tropics, but finding a combined epidemic of dengue and influenza was unexpected. With cooperative villagers, adequate personnel and laboratory support, especially the antigen capture ELISA test for dengue infections, it is feasible to successfully investigate disease outbreaks with serologic methods in remote villages.

A longitudinal study of Japanese encephalitis in suburban Bangkok, Thailand.

A one-year study of Japanese encephalitis (JE) in a small focus of transmission was conducted in suburban Bangkok in 1985. Monthly data were collected on weather, vector density, sentinel pig and chick JE antibody seroconversions, and epidemiology as related to human JE cases. The primary vector species were found to be Culex gelidus and Culex tritaeniorhynchus; from which one isolate each was obtained in March and June, respectively. Pig JE antibody seroconversion peaked in April (the hottest month), with secondary peaks following in July and December. Chick seroconversions were found only in June and July. Human cases (7) in the primary focus occurred from May-July, and started 2 months following the finding of the first JEV isolate in mosquitoes and 1 month following mass JEV seroconversion in pigs. Overall, the attack rate in the focus (0.83/10(5] was greater than 4 times that of the rest of Bangkok (0.19/10(5]. Attack rates were highest in 0-9 and 10-19 year-old groups, respectively. Indications are that JEV is transmitted to humans in Bangkok at least 10 out of 12 months per year, but that cases are concentrated in the May to July period.

Blood value changes in flavivirus-inoculated Macaca fascicularis monkeys.

Blood values were analysed in eighteen cynomolgus monkeys on pre-and post-neurovirulence testing of dengue-2 and yellow fever vaccine viruses, dengue-2 parental and Japanese encephalitis viruses. Certain changes between blood chemistry, hematology and serology were observed and briefly discussed.

Togavirus infection in rural Thailand.

Hemagglutination inhibition tests for antibody against chikungunya virus and the four dengue viruses were performed on a rural Thai village population. The 50% and 90% prevalence indices fell at about ages 3 and 15 for dengue virus exposure. This is considerably earlier exposure than comparable urban populations. The prevalence of chikungunya virus antibody was also age related with 50% prevalence at about age 45.