The origin of lentivirus research: Maedi-visna virus.

Maedi and visna are contagious sheep diseases which were introduced into Iceland in 1933 by imported sheep of Karakul breed. Maedi, a slowly progressing pneumonia, and the central nervous system disease visna were shown to be transmissible in sheep and most likely caused by a virus. In 1957, visna virus was isolated in tissue culture from sheep brain and maedi virus was isolated the following year from sheep lungs. Both viruses showed similar cytopathic effect in tissue culture. Electron microscope studies of ultrathin sections from visna virus infected cells demonstrated spherical particles, 70-100 nm in diameter, which were formed by budding from the cell membrane. Later studies showed identical particles in maedi virus infected cultures. These, and several other comparative studies, strongly indicated that maedi and visna were caused by strains of the same virus, later named maedi-visna virus (MVV). Comparative studies in tissue culture suggested that MVV was related to RNA tumor viruses of animals, the oncornaviruses. This was later supported by the finding that MVV is an RNA virus. A few months after reverse transcriptase was demonstrated in oncornaviruses, the enzyme was also found in MVV virions. Thus, MVV was classified as a retrovirus together with the oncornaviruses. However, MVV is not oncogenic in vivo or in vitro and was in 1975 placed in a subgroup of retroviruses named lentiviruses, which cause cytopathic effect in vitro and slowly progressing inflammatory disease in animals, but are nononcogenic. In the early 1980s, the causative agent of AIDS was found to be a non-oncogenic retrovirus and was classified as a lentivirus. Thus, HIV became the first human lentivirus.

Patented non-antibiotic agents as animal feed additives.

For a long time it was a common practice to add subtherapeutic amounts of antibiotics, such as tetracycline, to the feeds of livestock to promote growth and improve productivity. When antibiotic resistance in foodborne human pathogens was reported, this practice was either banned or voluntarily abandoned in many countries. The task of controlling the intestinal microflora in food animals, in the absence of antibiotics, is two-fold. First, to modulate the composition and number of commensal bacteria in the gastrointestinal tract so that it is as favorable as possible to the health and productivity of the animal. Second, to reduce asymptomatic intestinal colonization by pathogenic bacteria in the animals to lower the possibility of foodborne transmission to humans. Unfortunately, the knowledge of what constitutes a healthy, balanced intestinal microflora is still incomplete. This makes the task of favorably changing its composition difficult. However, modulation by means of natural feed supplements has been successfully practised for a number of years, the most important being probiotics, prebiotics, bacteriocins, organic acids, enzymes, bioactive phytochemicals, antimicrobial peptides, lipids and bacteriophages. A number of patents and patent applications have been published recently describing new supplements of various types. Many new compounds can therefore be expected to enter the market in the near future.

Maedi-visna virus and its relationship to human immunodeficiency virus.

Maedi-visna is a slow virus infection of sheep leading to a progressing lymphoproliferative disease which is invariably fatal. It affects multiple organs, but primarily the lungs where it causes interstitial pneumonia (maedi). Infection of the central nervous system was commonly observed in Icelandic sheep (visna), infection of mammary glands (hard udder) in sheep in Europe and the USA, and infection of the joints in sheep in the USA. The name ovine progressive pneumonia (OPP) is commonly used in the USA and ovine lentivirus (OvLV) infection is also a name used for maedi-visna. A related infection of goats, caprine arthritis-encephalitis (CAE), is common in Europe and the USA. The natural transmission of maedi-visna is mostly by the respiratory route, but also to newborn lambs by colostrum and milk. Intrauterine transmission seems to be rare and venereal transmission is not well documented. Macrophages are the major target cells of maedi-visna virus (MVV), but viral replication is greatly restricted in the animal host, apparently due to a posttranscriptional block. The low-grade viral production in infected tissues can explain the slow course of the disease in sheep. The lesions in maedi-visna consist of infiltrates of lymphocytes, plasma cells, and macrophages, and are detectable shortly after experimental transmission. Several studies indicate that the lesions are immune mediated and that cytotoxic T-lymphocytes may be important effector cells. The persistence of the MVV infection is explained by a reservoir of latently infected blood and bone marrow monocytes, which migrate into the target organs and mature into macrophages with proviral DNA transcription, but limited replication of virus. The MVV particles are morphologically similar to those of other retroviruses and the mode of replication follows the same general pattern. The genome organization and gene regulation resembles that of other lentiviruses. In addition to gag, pol and env, MVV has three auxiliary genes (tat, rev and vif), which seem to have similar functions as in other lentiviruses, with a possible exception of the tat gene. A determination of the 9200 nucleotide sequence of the MVV genome shows a close relationship to CAE virus, but limited sequence homology with other lentiviruses, and only in certain conserved domains of the reverse transcriptase and possibly in the surface protein. MVV infection in sheep and HIV-1 infection in humans have a number of features in common such as a long preclinical period following transmission, and a slow development of multiorgan disease with fatal outcome. A brief early acute phase, which is terminated by the immune response, is also an interesting common feature. Like HIV-1, MVV is macrophage tropic and the early stages of the HIV-1 infection which affect the central nervous system and the lungs are in many ways comparable to maedi-visna. In contrast to HIV-1, MVV does not infect T-lymphocytes and does not cause T-cell depletion and immunodeficiency. This is responsible for the difference in the late stages of the HIV-1 and MVV infections and the final clinical outcome. Despite limited sequence homology, certain proteins of MVV and HIV-1 show structural and functional similarities. Studies of MVV may therefore help in the search for new drugs against lentiviruses, including HIV-1.