A human MMTV-like betaretrovirus linked to breast cancer has been present in humans at least since the copper age.

The betaretrovirus Mouse Mammary Tumor Virus (MMTV) is the well characterized etiological agent of mammary tumors in mice. In contrast, the etiology of sporadic human breast cancer (BC) is unknown, but accumulating data indicate a possible viral origin also for these malignancies. The presence of MMTVenv-like sequences (MMTVels) in the human salivary glands and saliva supports the latter as possible route of inter-human dissemination. In the absence of the demonstration of a mouse-man transmission of MMTV, we considered the possibility that a cross-species transmission could have occurred in ancient times. Therefore, we investigated MMTVels in the ancient dental calculus, which originates from saliva and is an excellent material for paleovirology. The calculus was collected from 36 ancient human skulls, excluding any possible mouse contamination. MMTV-like sequences were identified in the calculus of 6 individuals dated from the Copper Age to the 17th century. The MMTV-like sequences were compared with known human endogenous betaretroviruses and with animal exogenous betaretroviruses, confirming their exogenous origin and relation to MMTV. These data reveal that a human exogenous betaretrovirus similar to MMTV has existed at least since 4,500 years ago and indirectly support the hypothesis that it could play a role in human breast cancer.

Bayesian inference reveals ancient origin of simian foamy virus in orangutans.

Simian foamy viruses (SFVs) infect most nonhuman primate species and appears to co-evolve with its hosts. This co-evolutionary signal is particularly strong among great apes, including orangutans (genus Pongo). Previous studies have identified three distinct orangutan SFV clades. The first of these three clades is composed of SFV from P. abelii from Sumatra, the second consists of SFV from P. pygmaeus from Borneo, while the third clade is mixed, comprising an SFV strain found in both species of orangutan. The existence of the mixed clade has been attributed to an expansion of P. pygmaeus into Sumatra following the Mount Toba super-volcanic eruption about 73,000years ago. Divergence dating, however, has yet to be performed to establish a temporal association with the Toba eruption. Here, we use a Bayesian framework and a relaxed molecular clock model with fossil calibrations to test the Toba hypothesis and to gain a more complete understanding of the evolutionary history of orangutan SFV. As with previous studies, our results show a similar three-clade orangutan SFV phylogeny, along with strong statistical support for SFV-host co-evolution in orangutans. Using Bayesian inference, we date the origin of orangutan SFV to >4.7 million years ago (mya), while the mixed species clade dates to approximately 1.7mya, >1.6 million years older than the Toba super-eruption. These results, combined with fossil and paleogeographic evidence, suggest that the origin of SFV in Sumatran and Bornean orangutans, including the mixed species clade, likely occurred on the mainland of Indo-China during the Late Pliocene and Calabrian stage of the Pleistocene, respectively.

Unrecognized "AIDS" in Monkeys, 1969-1980: Explanations and Implications.

AIDS was recognized in humans in 1981 and a simian form was described in the years 1983 to 1985. However, beginning in the late 1960s, outbreaks of opportunistic infections of AIDS were seen in monkeys in the United States. This apparent syndrome went unrecognized at the time. We have assembled those early cases in monkeys and offer reasons why they did not result in earlier recognition of simian or human AIDS, including weaknesses in understanding disease mechanisms, absence of evidence of human retroviruses, and a climate of opinion that devalued investigation of infectious disease and immunologic origins of disease. The "epistemological obstacle" explains important elements of this history in that misconceptions blocked understanding of the dependent relationship among viral infection, immunodeficiency, and opportunistic diseases. Had clearer understanding of the evidence from monkeys allowed human AIDS to be recognized earlier, life-saving prevention and treatment interventions might have been implemented sooner.

Examining the discovery of the human retrovirus.

Retroviruses have been found in many bird and animal species where they often cause various types of cancer. Dr. Robert Gallo's contribution to the field of retrovirology and the link he established between RNA viruses and cancer has been significant. Historical aspects of his discoveries in the area of human retroviruses are presented and an attempt is made to focus attention on his outstanding role.

A historical reflection on the discovery of human retroviruses.

The discovery of HIV-1 as the cause of AIDS was one of the major scientific achievements during the last century. Here the events leading to this discovery are reviewed with particular attention to priority and actual contributions by those involved. Since I would argue that discovering HIV was dependent on the previous discovery of the first human retrovirus HTLV-I, the history of this discovery is also re-examined. The first human retroviruses (HTLV-I) was first reported by Robert C. Gallo and coworkers in 1980 and reconfirmed by Yorio Hinuma and coworkers in 1981. These discoveries were in turn dependent on the previous discovery by Gallo and coworkers in 1976 of interleukin 2 or T-cell growth factor as it was called then. HTLV-II was described by Gallo's group in 1982. A human retrovirus distinct from HTLV-I and HTLV-II in that it was shown to have the morphology of a lentivirus was in my mind described for the first time by Luc Montagnier in an oral presentation at Cold Spring Harbor in September of 1983. This virus was isolated from a patient with lymphadenopathy using the protocol previously described for HTLV by Gallo. The first peer reviewed paper by Montagnier's group of such a retrovirus, isolated from two siblings of whom one with AIDS, appeared in Lancet in April of 1984. However, the proof that a new human retrovirus (HIV-1) was the cause of AIDS was first established in four publications by Gallo's group in the May 4th issue of Science in 1984.

Mouse mammary tumor biology: a short history.

For over a century, mouse mammary tumor biology and the associated Mouse mammary tumor virus (MMTV) have served as the foundation for experimental cancer research, in general, and, in particular, experimental breast cancer research. Spontaneous mouse mammary tumors were the basis for studies of the natural history of neoplasia, oncogenic viruses, host responses, endocrinology, and neoplastic progression. However, lacking formal proof of a human mammary tumor virus, the preeminence of the mouse model faded in the 1980s. Since the late 1980s, genetically engineered mice (GEM) have proven extremely useful for studying breast cancer and have become the animal model for human breast cancer. Hundreds of mouse models of human breast cancer have been developed since the first demonstration, in 1984, that the mouse mammary gland could be molecularly targeted and used to test the oncogenicity of candidate human genes. Now, very few scientists can avoid using a mouse model to test the biology of their favorite gene. The GEM have attracted a new generation of molecular and cellular biologists eager to apply their skills to these surrogates of the human disease. Newcomers often enter the field without an appreciation of the origins of mouse mammary tumor biology and the basis for many of the prevailing concepts. Our purpose in writing this short history of mouse mammary tumor biology is to provide a historical perspective for the benefit of the newcomers. If Einstein was correct in that "we stand on the shoulders of giants," the neophytes should meet their giants.

Small philanthropy and big science: the RETROVIROLOGY prize and Stephen P. Goff.

Stephen P. Goff wins the 2005 RETROVIROLOGY prize.

What caused the epidemic of Pneumocystis pneumonia in European premature infants in the mid-20th century?

An epidemic of interstitial pneumonia principally involving premature infants occurred in Germany and nearby European countries between the 1920s and 1960s. Fatalities were due to Pneumocystis. Because the principal defenses against Pneumocystis are T cells, an acquired T-cell deficiency was postulated. A number of potential causes including malnutrition were considered. All were implausible except for a retrovirus that was benign in adults but virulent in premature infants. Furthermore, we suspect that the virus was imported into Germany from former German African colonies. Premature infants were vulnerable because of the developmental status of their T cells. Given the practices in that part of Europe at that time, the virus was most likely transmitted by contaminated blood transfusions and subsequent contamination of reusable needles and syringes used in injections. Although the epidemic ended 4 decades ago, a search for the postulated retrovirus can be conducted if tissues from affected infants are available.

Cancer, infection and immunity: a personal homage to Jan Svoboda.

Jan Svoboda has had an extraordinary influence on my research. Following our first meeting in 1967, he encouraged me to pursue my tentative evidence for the existence of endogenous retroviruses latent in normal cells. He introduced me to the Czech scientists, Pavel Veselý and Jan Závada, with whom I collaborated fruitfully on the transformed cell phenotype and on virus pseudotypes, respectively. Through my brief training in his laboratory in Prague I gained a breadth and depth of analysis in virology, immunology and oncology that helped me subsequently to tackle problems in AIDS and AIDS-associated malignancy at the levels of both cell biology and epidemiology.

Simian AIDS: an historical perspective.

The author has had the unique opportunity to participate, over the last 35 years, in the retrovirus research field that proceeded and followed the discovery of human, simian and feline AIDS. The onset of human AIDS was certainly unanticipated, but in retrospect, the warning signs had been present for at least a decade in captive macaques. I will briefly summarize the key scientific knowledge and 'mindset' leading up to these events and will outline the major contributions and unanswered questions arising from the simian model of AIDS.

A journey with T cells, primate/human retroviruses and other persisting human T-cell tropic viruses.

A study of the growth of primate/human T cells led to mechanisms for temporary laboratory culture of these cells (discovery of interleukin-2) and also their continuous culture (by immortalization after infection with human T-cell lymphotropic virus type 1 or 2 (HTLV-1 or 2)). Cultures of lymphocytes also led us to isolate five persisting T-tropic viruses: 1. the Hall's Island strain of gibbon ape leukemia virus, 2. HTLV-1, 3. HTLV-2, 4. human immunodeficiency virus and 5. human herpes virus-6 (HHV-6). This report is a brief synopsis of the discoveries of the first human retroviruses, the HTLV.

The path to the discoveries of human retroviruses.

Paul Ehrlich, gifted with knowledge, vision, and the capacity to bring his discoveries to practice, shaped the destiny of many biomedical scientific disciplines, including immunology, chemotherapy, hematology, cytology, and cancer research. His perceptive concept of receptors and ligands binding together in highly specific reactions was introduced just over a century ago in 1898 and is both fundamental and central to present day biomedical research. His mother country, Germany, commemorates his seminal contributions to science and to human welfare with an annual prize for achievements in fields that are related to his work. The 1999 Paul Ehrlich and Ludwig Darmsteaedter Prize was awarded to Robert C. Gallo, M.D. for his achievements in the pursuit of cancer related viruses and the growth in culture of human T-cells which led to the discovery of the first human retroviruses and, as a direct consequence, the discovery of the Human Immunodeficiency Virus, the third known human retrovirus. Below, excerpted from his acceptance lecture, is a concise personal history of those discoveries.

Immunofluorescence for serodiagnosis of retrovirus infection.

Indirect immunofluorescence antibody testing is a mainstay of retrovirus serodiagnosis in the public health community, affording quick, inexpensive, and clear results with significant advantages over Western blot testing. Limitations regarding training of personnel and availability of reagents will probably continue and limit indirect immunofluorescence antibody testing to the present users.