[Development of a method for rapid detection of Ebola virus antibodies and antigen].

Despite the wide spectrum of reliable methods for identifying Ebola virus, their performance requires highly-skilled personnel, specialized laboratories, complicated equipment, and much time. Therefore, there is a need for a method that allows a physician or a medical attendant to identify the causative agent in field or bedside tests without special equipment as soon as possible. The immunoassay involving nitrocellulose membrane immuno-filtration, by using a fixed antigen (antibodies) or their immunosols, is a tried-and-true method. The time of the analysis is 7-15 min.

No link between viral findings in the prostate and subsequent cancer development.

In an investigation of 201 prostate tissue samples from patients with benign prostate hyperplasia that later progressed to prostate cancer and 201 matched controls that did not, there were no differences in the prevalence of adenovirus, herpesvirus, papilloma virus, polyoma virus and Candida albicans DNA.

Association between the presence of bacterial 16S RNA in prostate specimens taken during transurethral resection of prostate and subsequent risk of prostate cancer (Sweden).

OBJECTIVE: To study bacterial 16S RNA in archival prostate samples from 352 patients with benign prostate hyperplasia (BPH) and evaluate whether the presence of bacterial DNA was different in those who later developed prostate cancer (n = 171) and in the matched controls that did not progress to cancer (n = 181). METHODS: 16S DNA PCR followed by cloning and sequencing the positive samples. RESULTS: In 96/352 (27%) of the prostate tissue specimens 16S RNA were detected. Sequence analysis revealed Propionibacterium acnes as the predominant microorganism (23% of 16S RNA positive patients). The second most frequent isolate-Escherichia coli was found in 12 (12%) patients. The other isolates included Pseudomonas sp. (3 patients), Actinomyces sp. (2), Streptococcus mutans (1), Corynebacterium sp. (2), Nocardioides sp. (1), Rhodococcus sp. (1) Veillonella sp. (2). In P. acnes positive samples 62% exhibited severe histological inflammation versus 50% in the bacteria-negative group (p = 0.602). The presence of P. acnes in the prostate was associated with prostate cancer development (OR 2.17, 95% CI 0.77-6.95). CONCLUSIONS: This study has revealed P. acnes as the most common bacteria in the prostate in BPH. Further studies are needed to clarify its role in contributing to the development of prostatic inflammation and prostate cancer.

PCR-generated linear DNA fragments utilized as a hantavirus DNA vaccine.

The field of DNA vaccines has grown rapidly, and since most such vaccines involve the inoculation of large circular DNA molecules previously propagated in bacteria, several inconveniences (e.g. the presence of antibiotic resistance genes, impurities from bacterial cultures or inefficient uptake of the large and bulky plasmid DNA molecules to the nucleus) are debated. In this study, we have explored the possibility of using smaller and more flexible PCR-generated linear DNA fragments instead. Phosphorothioate (PTO)-modified primers were used successfully to protect the PCR-generated DNA fragments from exonuclease degradation, and by using a nuclear localization signal-peptide to target the linear DNA to the nucleus the immune response against the encoded antigen was further improved. This approach was tested in cell culture using a sensitive reporter system and in vivo with DNA encoding the amino-terminus of the Puumala hantavirus nucleocapsid protein. Our results indicate that linear DNA fragments have a great potential as a genetic vaccine and phosphorothioate modification in combination with a nuclear localization signal peptide increase the stability and targets the linear DNA molecules to the nucleus resulting in an improved biological response examined both in vitro and in vivo.

Biological warfare in a historical perspective.

There are some early examples of biological warfare (BW), but in modern times it was used first for sabotage by Germany during WWI. Development of biological weapons on a military significant scale was initiated in several countries in the period between the world wars. During WWII, several countries had active programs such as the USA, UK, Canada, Germany, Japan and the Soviet Union. It was only Japan that on a fairly large scale used BW. The US program continued until 1969, when President Nixon took a decision to end it in connection with signing the BTWC. The Soviet Union had also continued its program after the war, and this was enhanced after signing the BTWC: in the 1980s the program consisted of around fifty facilities and involved around 60,000 people. The Soviet Union produced and maintained a large stockpile of BW-agents. After the collapse of the Soviet Union, and due to pressure from USA and UK, President Yeltsin issued a decree in 1992 banning continued offensive BW activity. However, there are still concerns of residual activity in Russia. Another program of concern is the Iraqi BW-program. After 10 years of UN inspections that were stopped in 1998, there are still many unanswered questions concerning the BW program. There was also a covert BW-program in South Africa that was terminated around 1993. There have also been a number of allegations of alleged use or possession. In addition, there are indications that 10-12 states are now trying to acquire BW, and this assessment is based on intelligence information, mainly from the USA. For example Iraq, North Korea, Iran, Syria, Sudan and Libya. Another aspect is the strong driving force of technology developments to promote this type of program, opening new risks for future potential military misuse.

Smallpox--eradicated, but a growing terror threat.

Smallpox is a disease that followed humanity for thousands of years up until 30 years ago. It was possible to eradicate, because an effective live vaccine from crossreacting vaccinia could be developed. Twenty years have passed since vaccinations stopped and very few people are protected against the disease today. Variola today has become an object of discussion due to the possibility that it can be used as a bioweapon. Due to the number of complications that can be expected a general vaccination is probably not possible. Research is ongoing to develop new vaccines. Many countries are improving their capabilities to respond to a renewed threat of a smallpox epidemic.

Biological weapons and bioterrorism preparedness: importance of public-health awareness and international cooperation.

Biological weapons and biological terrorism have recently come into focus due to the deliberate release of Bacillus anthracis via mail delivered in the USA. Since the 1930s, biological weapons have been developed in a number of countries. In 1975, the Biological and Toxin Weapons Convention entered into force; this prohibits the use of these weapons and has been signed by a large majority of countries (144). Unfortunately, several countries failed to respect this treaty. The Soviet Union continued and expanded its biological weapons program, and after the Gulf War it was revealed that Iraq also had an extensive biological weapons program. Large-scale deliberate release of, Bacillus anthracis, for example, or an epidemic following a release of smallpox virus, would have a devastating effect. This has motivated the world community to strengthen the Biological and Toxin Weapons Convention with a control mechanism which has, as yet, not been successful. Sweden, like other countries, is enhancing its preparedness with regard to stocks of antibiotics and vaccines, related to these improving the diagnostics these and similar agents, and is setting up an epidemiologic task force that can be used in infectious disease emergencies such as the deliberate release of biological warfare agents. International cooperation in this area has to be enhanced, not least in the European Union.

Modifying the cellular transport of DNA-based vaccines alters the immune response to hantavirus nucleocapsid protein.

Puumala virus is a member of the hantavirus genus (family Bunyaviridae) and is one of the causative agents of hemorrhagic fever with renal syndrome (HFRS) in Europe. A genetic vaccination approach was conducted to investigate if the immune response could be modulated using different cellular secretion and/or localisation signals, and the immune responses were analysed in BALB/c mice and in a bank vole infectious model. Rodents vaccinated with DNA constructs encoding the antigen fused to an amino-terminal secretion signal raised significantly higher antibody levels when compared to using constructs lacking secretion signals. Furthermore, the ratios of the IgG subclasses (IgG2a/IgG1) were raised by the use of cellular localisation signals, indicating a more pronounced Th1-type of immune response. The majority of the mice, or bank voles, immunised with DNA encoding a secreted form of the antigen showed a positive lymphoproliferative response and were protected against challenge with Puumala virus (strain Kazan-wt).

[Anthrax--the Swedish perspective]. / Antrax--det svenska perspektivet.

The recent occurrence in the USA of deliberate release of virulent Bacillus anthracis in letters sent to three media corporations and to the American senate has led to a great anxiety in Sweden and elsewhere in Europe. Numerous letters have been suspected to contain B. anthracis spores and several have contained powder of different types. In none of the tested letters collected by the Swedish police have we been able to detect anthrax bacilli. Powder containing letters have been tested with either bacterial isolation and/or B. anthracis specific PCR. Anthrax is a disease found naturally in herbivores and is occasionally spread to humans. It is caused by the gram-positive rod B. anthracis that was discovered by Robert Koch in 1876. Beginning in the 1930s many states have developed B. anthracis for use as a weapon. A few releases of the bacteria have been reported before October 2001. B. anthracis causes three forms of disease, cutaneous, pulmonary and gastro-intestinal. The pulmonary form is the most dangerous and may lead to death merely one to two days after onset of severe symptoms. This is due to the rapid growth and release of several potent toxins that engage the immune system and promote tissue destruction. B. anthracis infection can be treated with several antibiotics, among which quinolones and tetracyclins have been recommended. Diagnosis can readily be achieved by microscopy, bacterial isolation and PCR at the Swedish Institute for Infectious Disease Control and the Swedish Defence Research Agency. Antibiotics relevant for treatment of B. anthracis infections are already stockpilled in our country. Further actions to strengthen our capability to deal with bioterrorism are ongoing.

[Update on biological weapons and bioterrorism. Important that health services pay attention to unusual events]. / Aktuellt om biologiska stridsmedel och bioterrorism. Viktigt att sjukvården uppmärksammar ovanliga händelser.

Biological weapons and biological terrorism have recently been in focus due to the deliberate release of Bacillus anthracis via mail delivered in the USA. Since the 1930s biological weapons have been developed in a number of countries. In 1975 a biological and toxin weapons convention prohibiting the use of these weapons were signed by a large majority of world countries. Unfortunately, a number of countries have failed to respect this treaty. The Soviet union continued and expanded its biological weapons program and after the Gulf war it was revealed that Iraq also had an extensive bio-weapons program. Large scale deliberate release of for example B. anthracis or an epidemic following a release of smallpox virus would have a devastating effect. This has urged the world community to strengthen the biological and toxin weapons convention with a control function which as of yet has not been successful. Furthermore, many countries including Sweden, increase stocks of antibiotics and smallpox vaccines. Sweden is also increasing preparedness regarding diagnostics of these and similar agents and is setting up an epidemiological task force that can be used in infectious disease emergencies such as the deliberate release of a biological weapon.

Serologic evidence of Puumala virus infection in wild moose in northern Sweden.

Puumala (PUU) virus is the causative agent of nephropathia epidemica, the Scandinavian form of hemorrhagic fever with renal syndrome. The infection is acquired by airborne transmission of PUU virus from its rodent reservoir, the bank vole. Besides serologic data indicating that the virus may spread also to heterologous rodents, there is little information on the susceptibility of wild living animals to PUU virus. We studied the occurrence of antibodies to PUU virus in serum samples from 427 wild-living moose, of which 260 originated from the PUU virus-endemic northern and central parts of Sweden and 167 originated from the southern, nonendemic part of Sweden. Samples from 5 animals showed reactivity in an ELISA for recombinant PUU virus nucleocapsid protein, an immunofluorescent assay, and a neutralization test. These 5 animals all originated from the PUU virus-endemic northern part of Sweden. In conclusion, 5 of 260 moose from the endemic region showed convincing serologic evidence of past PUU virus infection. The seroprevalence was low, suggesting that the moose is subjected to endstage infection rather than being part of an enzootic transmission cycle.

Comparison of the protective efficacy of naked DNA, DNA-based Sindbis replicon, and packaged Sindbis replicon vectors expressing Hantavirus structural genes in hamsters.

Seoul virus (SEOV) is a member of the Hantavirus genus (family Bunyaviridae) and an etiological agent of hemorrhagic fever with renal syndrome. The medium (M) and small (S) gene segments of SEOV encode the viral envelope glycoproteins and nucleocapsid protein, respectively. We compared the immunogenicity and protective efficacy of naked DNA (pWRG7077), DNA-based Sindbis replicon (pSIN2.5), and packaged Sindbis replicon vectors (pSINrep5), containing either the M or S gene segment of SEOV in Syrian hamsters. All of the vectors elicited an anti-SEOV immune response to the expressed SEOV gene products. Vaccinated hamsters were challenged with SEOV and monitored for evidence of infection. Protection from infection was strongly associated with M-gene vaccination. A small number of S-gene-vaccinated animals also were protected. Hamsters vaccinated with the pWRG7077 vector expressing the M gene demonstrated the most consistent protection from SEOV infection and also were protected from heterologous hantavirus (Hantaan virus) infection.

DNA vaccination with hantavirus M segment elicits neutralizing antibodies and protects against seoul virus infection.

Seoul virus (SEOV) is one of four known hantaviruses causing hemorrhagic fever with renal syndrome (HFRS). Candidate naked DNA vaccines for HFRS were constructed by subcloning cDNA representing the medium (M; encoding the G1 and G2 glycoproteins) or small (S; encoding the nucleocapsid protein) genome segment of SEOV into the DNA expression vector pWRG7077. We vaccinated BALB/c mice with three doses of the M or S DNA vaccine at 4-week intervals by either gene gun inoculation of the epidermis or needle inoculation into the gastrocnemius muscle. Both routes of vaccination resulted in antibody responses as measured by ELISA; however, gene gun inoculation elicited a higher frequency of seroconversion and higher levels of antibodies in individual mice. We vaccinated Syrian hamsters with the M or S construct using the gene gun and found hantavirus-specific antibodies in five of five and four of five hamsters, respectively. Animals vaccinated with the M construct developed a neutralizing antibody response that was greatly enhanced in the presence of guinea pig complement. Immunized hamsters were challenged with SEOV and, after 28 days, were monitored for evidence of infection. Hamsters vaccinated with M were protected from infection, but hamsters vaccinated with S were not protected.

Use of restriction fragment analysis and sequencing of a serotype-specific region to type adenovirus isolates.

Restriction fragment analysis and sequencing of a serotype-specific region were used to type 12 and 2 clinical isolates, respectively. Both molecular methods produced clear-cut results that completely correlated with that of the neutralization test.

Hemorrhagic fever with renal syndrome in the Dolenjska region of Slovenia--a 10-year survey.

This report describes the first investigation of clinical findings for a larger series of patients with hemorrhagic fever with renal syndrome (HFRS) who were infected with Dobrava virus. From 1985 to 1995, 38 patients with serologically confirmed HFRS were hospitalized at the regional hospital in Novo mesto in the Dolenjska region of Slovenia. On the basis of results of serological examination, 24 patients had Dobrava virus infection, and 14 patients had Puumala virus infection. Complete clinical data were available for 31 patients. Eleven patients underwent hemodialysis for treatment of acute oliguric or anuric renal failure. Four patients, all infected by Dobrava virus, had signs of shock and severe bleeding. Three severely ill Dobrava virus-infected patients died of hemorrhagic complications. We have demonstrated that Dobrava and Puumala viruses coexist in a single region of endemicity and are capable of causing HFRS with significant differences in severity.

A minority of seropositive wild bank voles (Clethrionomys glareolus) show evidence of current Puumala virus infection.

Bank voles (Clethrionomys glareolus) serve as the reservoir for Puumala (PUU) virus, the aetiologic agent of nephropathia epidemica. The animals are believed to be persistently infected and the occurrence of serum antibodies is usually taken as an evidence of active infection. We found serum antibodies to PUU virus in 42 of 299 wild bank voles captured in a PUU virus endemic area. PUU virus RNA was demonstrated in lung specimens of 11 of these 42 animals and in 2 of them antigen was also found. Thus in the lungs of 31 of 42 seropositive animals neither PUU virus RNA nor antigen was detected. In 2 of 257 seronegative animals, lung specimens showed presence of PUU virus antigen and RNA. Isolation of PUU virus from lung tissue was successful in all 4 antigen-positive bank voles but in none of 16 tested antigen-negative animals. In conclusion, only a minority of bank voles with serum antibodies to PUU virus showed evidence of current infection.

Central nervous system and ophthalmic involvement in nephropathia epidemica (European type of haemorrhagic fever with renal syndrome).

Central nervous system (CNS) - related symptoms occur in haemorrhagic fever with renal syndrome (HFRS). To study the CNS and ophthalmic involvement in nephropathia epidemica (NE), the European type of HFRS, we included 26 patients in a prospective study. Most common CNS-related symptoms were headache (96%), insomnia (83%), vertigo (79%), nausea (79%), and vomiting (71%). Ophthalmic symptoms were reported by 82% of patients; 41% had photophobia and 50% had impaired vision. A transient loss of vision was recorded in one patient, who also had a generalized seizure. Minor white matter lesions were found in about half of the patients investigated with brain magnetic resonance imaging (MRI). Electroencephalography (EEG) showed severe alterations in only one patient, and slight and reversible patterns in another two patients. Neopterin, interleukin-6 and interferon-gamma levels in the cerebrospinal fluid (CSF) were elevated, which may indicate immune activation. However, we found no evidence of intrathecal NE virus replication. We conclude that CNS-related symptoms are common in NE, and transient ophthalmic involvement can be demonstrated in about half of the patients.