Antibodies and HIV: New Evidence Interview with Ruth Ruprecht, M.D., Ph.D.Background HIV HIV (Human Immunodeficiency Virus), either of two closely related retroviruses that invade T-helper lymphocytes and are responsible for AIDS. There are two types of HIV: HIV-1 and HIV-2. HIV-1 is responsible for the vast majority of AIDS in the United States. infection causes the body to produce large amounts of antibodies -- specialized proteins produced by the immune system immune system Cells, cell products, organs, and structures of the body involved in the detection and destruction of foreign invaders, such as bacteria, viruses, and cancer cells. Immunity is based on the system's ability to launch a defense against such invaders. to fight infecting bacteria or other organisms. But most of the antibodies produced in response to HIV infection are not effective in stopping the virus -- and some of them may even increase HIV infection. So in recent years, many scientists have given up on antibody approaches to HIV vaccines or treatments. (Instead they are working with the other major branch of the immune system, cellular immunity cellular immunity n. See cell-mediated immunity. , which now looks very promising for control of HIV. However, cellular immunity by itself cannot clear most HIV infections.) At a recent conference on immune research in HIV, held April 27-29 at the Institute of Human Virology The Institute of Human Virology (IHV) at the University of Maryland School of Medicine is a world-class center of excellence focusing on chronic viral diseases, most notably HIV/AIDS, and virally linked cancers. IHV was founded in 1996 and continues to be directed by Dr. Robert C. at the University of Maryland University of Maryland can refer to:
lentiviruses that cause disease resembling that caused by human immunodeficiency virus. Included are feline immunodeficiency virus, bovine immunodeficiency virus and equine infectious anemia virus. . If this approach continues to be successful, it could have huge implications: (1) Vaccines could be engineered to cause the body to produce antibodies already known to work. Such antibody-inducing vaccines might be effective by themselves -- or might be combined with approaches that generate cellular immunity to produce vaccines more effective than either kind alone. Vaccine development could be greatly accelerated, because it would be possible to test quickly, in volunteers, whether or not a candidate vaccine induced production of the desired antibodies. Problems could be found and fixed quickly, before the vaccine went into a large, multi-year trial. (2) Antibodies might also be able to prevent mother-to-infant transmission -- without the side effects Side effects Effects of a proposed project on other parts of the firm. or potential toxicities of antiretrovirals, without the risk of producing drug-resistant virus, and possibly without requiring the mothers to avoid breast feeding breast feeding Pediatrics The provision of a neonate and infant with liquified lacteal products 'on tap'; lactation and BF–≥ 6 months before age 20 is associated with a relative risk of 0. . (3) It is possible that selected antibodies might help in the treatment of persons already infected. So far there are no data, as this has not been tried even in animals. But many years ago there were experiments with "passive immunotherapy" for HIV -- collecting serum donated from persons who were doing well for a long time despite HIV infection, and transfusing this serum into persons who were sick. Despite some promising results, this work did not continue. From the modern perspective, these early attempts do make some sense -- Dr. Ruprecht explained that a few patients do produce antibodies that are effective in stopping HIV. But today we also know that some people are slow progressors for different reasons, some of which have nothing to do with antibodies, so there is no reason to think that transfusing their plasma would be beneficial to others. Using rationally selected, engineered antibodies would appear more promising. Incidentally, passive immunotherapy has long been used to treat certain other infectious diseases. And recently it was found effective in animal tests in both preventing and treating ebola virus Ebola virus (ēbō`lə), a member of a family (Filovirus) of viruses that cause hemorrhagic fevers. The virus, named for the region in Congo (Kinshasa) where it was first identified in 1976, emerged from the rain forest, where it survives in infection. [1] Dr. Ruprecht uses monoclonal antibodies (pure antibodies produced by genetically modified cells) rather than serum or immunoglobulins prepared from serum, that deliver a variable mixture of many different antibodies. So far, monoclonal antibodies have been much too expensive to use as treatments. But now it is becoming possible to produce antibodies in plants, such as tobacco. So price need not be an obstacle -- if it is found that antibodies could work as treatment for someone already infected with HIV, which today is not known. Note: David Scondras interviewed Dr. Ruprecht on April 28, and prepared a transcript. Since he then had to leave for AIDS work in Malawi, John S. James, who was present at the interview, edited the transcript and wrote the background section above. Dr. Ruprecht made corrections before the interview was published. Interview with Dr. Ruprecht Scondras: What is the goal of your work? Ruprecht: We want to develop an immunological approach to prevent mother-to-child transmission mother-to-child transmission Vertical transmission, see there of HIV. Simultaneously, we are also looking for Looking for In the context of general equities, this describing a buy interest in which a dealer is asked to offer stock, often involving a capital commitment. Antithesis of in touch with. a way to rationally design an HIV vaccine. The idea came from how we manage hepatitis B Hepatitis B Definition Hepatitis B is a potentially serious form of liver inflammation due to infection by the hepatitis B virus (HBV). It occurs in both rapidly developing (acute) and long-lasting (chronic) forms, and is one of the most common chronic . To prevent mother-to-child transmission, pregnant women are screened for the virus. If they are positive, their infants get two inoculations: the first consists of hepatitis B immunoglobulins [which contain antibodies against the hepatitis B virus, providing passive immunity passive immunity n. Immunity acquired by the transfer of antibodies from another individual, as through injection or placental transfer to a fetus. ], and the second is the hepatitis B vaccine hepatitis B vaccine n. Abbr. HB A vaccine prepared from the inactivated surface antigen of the hepatitis B virus and used to immunize against hepatitis B. . Used together, the vaccine plus immunoglobulins confer 98% 'effective protection to the baby. If you use the immunoglobulins alone, they are only 70% effective. Turning to HIV, people who have HIV infection make very little neutralizing [effective] antibody compared to people with other viral infections. Instead, with HIV, the body makes lots of antibodies to parts of the virus that are not important. This kind of antibody does not stop the virus from infecting cells and damaging the immune system. Indeed, it is now known that HIV makes the body produce antibodies that may even help the virus infect cells. That was part of the reason I decided to stay away from polyclonal polyclonal /poly·clo·nal/ (-klon´'l) 1. derived from different cells. 2. pertaining to several clones. polyclonal derived from different cells; pertaining to several clones. sera [such as antibody preparations made from the blood of persons whose HIV was progressing slowly]. You cannot do a rational analysis of the specific antibodies. Scondras: Hasn't this approach of looking at antibodies been tried before? Ruprecht: Every once in a while, a patient develops relatively high titers of neutralizing antibodies [meaning that they produce antibodies that effectively block HIV]. It is also known that monoclonal antibodies can be made from these people. But in scientific research, the pendulum had swung away from antibodies. Scondras: How did you think that antibodies could play an important role anyway? Ruprecht: I knew that antibodies help prevent hepatitis B virus infection. I also knew that the hepatitis B virus has some similarities to HIV. So I decided to focus on finding potent antibodies from HIV-infected people. Other investigators have succeeded in engineering cultured cells to produce just a single antibody, called monoclonal antibody monoclonal antibody, an antibody that is mass produced in the laboratory from a single clone and that recognizes only one antigen. Monoclonal antibodies are typically made by fusing a normally short-lived, antibody-producing B cell (see immunity) to a fast-growing . My colleagues kept isolating B cells [the cells in the blood that produce antibodies], and kept screening until they found cells that produced antibodies that successfully neutralized HIV. Then we could learn to mass produce the monoclonal antibodies. Today this is possible; in fact, tobacco plants can be engineered to produce these antibodies. The Animal Tests Ruprecht: We decided to combine antibodies that worked against HIV, in the hope that a cocktail of antibodies would be more effective than one antibody alone. We looked for overall potency of triple combinations, picked a combination that stopped HIV in the test tube, and then tested if that combination would stop a virus similar to HIV that can grow in animals. The three antibodies that we picked are human monoclonal antibodies, targeting conserved epitopes of the envelope of HIV. [The "envelope" is the outside part of the virus, that antibodies can get to. "Epitopes" are particular shapes of parts of HIV; antibodies target foreign substances by being shaped just right to fit them. "Conserved" epitopes means ones that do not change much from one strain of HIV to another (probably because when they do change as a result of mutations, the virus is not able to survive).] This kind of therapy that uses antibodies is called "passive immunotherapy." It is important for babies, in particular, because it may be able to protect babies from getting HIV from their mothers, and also protect them from getting HIV from breast milk from the infected mother. Antibodies stay in the blood for a fairly long time [so it might be possible to protect babies with only a few injections, instead of shots or pills every day]. Scondras: Is there any connection between this and developing a vaccine to protect people from HIV? Ruprecht: Yes. We have antibodies now that are completely characterized [meaning that we know to what part of HIV they bind]. If these antibodies can provide complete protection from HIV transmission, then a vaccine that elicits these antibodies should be protective. Scondras: Is it possible that these antibodies could be a therapy for people who have HIV? Ruprecht: We just do not know yet -- no experiments have been conducted to test this approach. Scondras: Why do you think you may have found the right antibodies? Ruprecht: We have data showing that these three antibodies can completely protect against SHIV challenge in adult rhesus monkeys. [SHIV is a virus which combines parts of SIV SIV simian immunodeficiency virus. , which infects monkeys, and parts of human HIV.] We have also shown that newborn monkeys could be protected completely with the triple combination of antibodies against mucosal SHIV infection. Then we tried a much more aggressive SHIV strain, and it was stopped in some newborn animals. We purposely infected these monkeys with much, much more virus than is usually transmitted from mothers to babies, and the antibodies worked well. One other point: The antibodies we have identified are of the IgG subtype (programming) subtype - If S is a subtype of T then an expression of type S may be used anywhere that one of type T can and an implicit type conversion will be applied to convert it to type T. , not IgA, the typical mucosal antibodies. This implies that you do not need mucosal immunity to HIV to protect people from HIV. Scondras: Dr. Ruprecht: How did you get started in AIDS research ? Ruprecht: I was about to start a thesis in physical chemistry in Switzerland, my native country, but my real love was molecular biology. When I was in the U.S. as a summer intern in chemistry, I discovered that the U.S. graduate-school system would allow me to make this change of fields, unlike my school in Europe. So I decided on the spur of the moment Adv. 1. on the spur of the moment - on impulse; without premeditation; "he decided to go to Chicago on the spur of the moment"; "he made up his mind suddenly" suddenly to stay in the US, and went to Columbia University. I worked on cancer-causing retroviruses and studied the mechanism of reverse transcriptase. After getting my Ph.D., I attended a two-year medical school at the University of Miami This article is about the university in Coral Gables, Florida. For the university in Oxford, Ohio, see Miami University. The University of Miami (also known as Miami of Florida,[2] UM,[3] or just The U , and then completed my residency in internal medicine at UCLA UCLA University of California at Los Angeles UCLA University Center for Learning Assistance (Illinois State University) UCLA University of Carrollton, TX and Lower Addison, TX . I was there when the first HIV patients came to the hospital. I started a fellowship, moved back to New York City New York City: see New York, city. New York City City (pop., 2000: 8,008,278), southeastern New York, at the mouth of the Hudson River. The largest city in the U.S. , then got an academic position in 1984 at the Dana-Farber Cancer Institute, and have worked in AIDS research ever since. References (1.) M. Gupta, S. Mahanty, M. Bray, R. Ahmed and P.E. Rollin. Passive transfer of antibodies protects immunocompetent im·mu·no·com·pe·tent adj. Having the normal bodily capacity to develop an immune response following exposure to an antigen. im and immunodeficient mice against lethal Ebola virus infection without complete inhibition of viral replication. Journal of Virology The Journal of Virology is an academic journal that covers research concerning viruses, using cross-disciplinary approaches including biochemistry, biophysics, cell and molecular biology, genetics, immunology, morphology, physiology and pathogenesis. . May 2001; volume 75, pages 4649-4654. |
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