Stanford Snake Venom Study Shows That Certain Cells May Eliminate Poison.STANFORD, Calif. -- Death by snakebite snakebite, wound inflicted by the teeth of a snake. The bite of a nonvenomous snake is rarely serious. Venomous snakes have fangs, hollow teeth through which poison is injected into a victim. is horrible. The immediate pain of the bite is followed by swelling, bruising and weakness, then sweating or chills, with numbness, nausea, blurred vision and possibly convulsions Convulsions Also termed seizures; a sudden violent contraction of a group of muscles. Mentioned in: Heat Disorders before it's all over. Such misery is produced by a veritable witches' brew of toxins in snake venom. It's long been thought that the body's own 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. , rather than reducing the symptoms, may make things worse. But now researchers at the Stanford University School of Medicine Stanford University School of Medicine is affiliated with Stanford University and is located at Stanford University Medical Center in Stanford, California, adjacent to Palo Alto and Menlo Park. have shown that the immune system really does side with the victim, at least in four kinds of venom that were used in their experiments. Their findings will be published in the July 28 issue of Science. Venom from three species of poisonous snakes and one species of honeybee honeybee Broadly, any bee that makes honey (any insect of the tribe Apini, family Apidae); more strictly, one of the four species constituting the genus Apis. The term is usually applied to one species, the domestic honeybee (A. were studied by a group led by Stephen Galli, MD, professor and chair of the Department of Pathology. Using mice, they analyzed how mast cells Mast cells A type of immune system cell that is found in the lining of the nasal passages and eyelids, displays a type of antibody called immunoglobulin type E (IgE) on its cell surface, and participates in the allergic response by releasing histamine from , a vital part of the immune system in mammals, reacted to the various venoms. The net effect of the mast cell response to the four venoms "is to enhance resistance to the toxicity and reduce mortality induced by the venom," said Galli, the paper's senior author. This helpful mast cell response runs contrary to the conventional wisdom -- that the immune system only added to the woes of snakebite victims. This assumption arose because of the way mast cells respond to certain other stimuli. Mast cells synthesize a wide range of biological mediators -- compounds that can promote inflammation and other tissue changes -- that are selectively unleashed from the cells in response to various triggers, often intruders such as parasites or bacteria. In people who have been sensitized sensitized /sen·si·tized/ (sen´si-tizd) rendered sensitive. sensitized rendered sensitive. sensitized cells see sensitization (2). (i.e., made allergic) by prior exposure to substances such as peanuts or certain pollens, mast cells also respond to those stimuli. When mast cells overreact o·ver·re·act v. To react with unnecessary or inappropriate force, emotional display, or violence. to allergens, they contribute to the effects associated with allergy attacks, such as a runny nose, sneezing To verbally tell somebody about a new and interesting Web site. See viral marketing. , itching and red eyes. When they severely overreact, they can cause anaphylaxis anaphylaxis (ăn'əfəlăk`sĭs), hypersensitive state that may develop after introduction of a foreign protein or other antigen into the body tissues. , which can be fatal. Given that tendency to overreact when stimulated by allergens, it seemed plausible that introducing venom into the body would trigger a similar response. But Galli and Martin Metz, MD, a postdoctoral scholar in pathology and first author of the study, have shown that when mast cells respond to selected venoms, they unleash proteins that break down some of the venoms' most toxic components. The study was inspired by a 2004 paper in Nature, by Galli and a team of researchers including Metz, showing that mast cells reduced the mortality rate of mice suffering from bacterial peritonitis peritonitis (pĕr'ĭtənī`tĭs), acute or chronic inflammation of the peritoneum, the membrane that lines the abdominal cavity and surrounds the internal organs. , a severe bacterial infection in the abdominal cavity that can also be fatal to humans. They found that mast cells released proteins that broke down a molecule called endothelin-1, one of the major toxins produced by the body during bacterial peritonitis or sepsis (bacterial infection in the blood). In perusing the scientific literature, Metz noticed that endothelin-1 bore a striking similarity to sarafotoxin 6b, the most toxic component in the venom of the burrowing asp, or Israeli mole viper. Knowing also that mammalian mast cells had been shown to respond to many snake venoms by secreting some potent biologically active mediators, they hypothesized that mast cells might also act to degrade sarafotoxins and reduce the toxicity of the Israeli mole viper venom. Galli and Metz first did experiments in vitro using isolated sarafotoxin 6b with mast cells from mice. "It worked as we thought it would," said Metz. The mast cells were activated, they released the expected proteins and the proteins degraded the sarafotoxin 6b. Mast cells also enhanced resistance of mice to sarafotoxin 6b when it was injected in vivo. Next, Galli and Metz did experiments using the whole venom, not just the isolated toxin. Some of the mice they worked with were genetically deficient in mast cells, while others, called wild-type mice, had normal mast cells. "We saw the same results in the wild-type mice that we saw before with just the one component, sarafotoxin 6b," said Metz. The mast cells were activated via a particular receptor they had on the cell surface and released the appropriate proteins, which, Metz said, went on to "degrade and thus eliminate the venom, or at least make it less toxic." The wild-type mice were able to withstand 10 times the dosage of this venom than the mast cell deficient mice could, further indicating that the mast cells were reducing the impact of the venom. To test whether mast cells could also reduce the toxicity of venom from snakes that didn't contain toxins comparable to sarafotoxin 6b, Galli and Metz tested the venom of the western diamondback rattlesnake Noun 1. Western diamondback rattlesnake - largest and most dangerous North American snake; of southwestern United States and Mexico Crotalus atrox, Western diamondback and the southern copperhead copperhead, poisonous snake, Ancistrodon contortrix, of the E United States. Like its close relative, the water moccasin, the copperhead is a member of the pit viper family and detects its warm-blooded prey by means of a heat-sensitive organ behind the nostril. . Again, the mast cells conferred a distinct protective edge. Testing the mast cell response even further, they also experimented with the venom from honeybees, with the same positive result. "The mast cells significantly limit not only the toxicity, but also the mortality associated with the venom," said Galli. But Galli called the battle between predators with venom and their prey "a kind of evolutionary arms race In evolutionary biology, an evolutionary arms race is an evolutionary struggle between competing sets of co-evolving genes that develop adaptations and counter-adaptations against each other, resembling an arms race. ." He and Metz suspect that, given the broad range of venoms that have been developed by snakes and other creatures, mast cells probably won't perform as well against every type of venom. "We expect that there will be some snake venoms that either are not affected by mast cells at all or perhaps even elicit more pathology due to their ability to activate mast cells. It all depends on the balance between the positive and negative effects of the mediators released by mast cells in response to a particular venom," said Galli. Galli and Metz are embarking on a systematic survey of animal venoms. As more is learned about the natural defenses the mammalian immune system has against venom, it may someday even lead to better antivenins, though it will first have to be shown that human mast cells respond in the same way mouse mast cells do. The group has begun in vitro studies using human mast cells to evaluate this possibility. The other Stanford authors of the paper are postdoctoral scholars Adrian Piliponsky, PhD, and Ching-Cheng Chen, PhD, and senior research scientist Mindy Tsai, DMSc. The National Institutes of Health funded the study. Stanford University Medical Center Stanford University Medical Center (Stanford Hospital & Clinics) is one of four hospitals affiliated with Stanford University and Stanford University School of Medicine, along with the Lucile Packard Children's Hospital, the Veteran's Administration Hospital in Palo Alto, and Santa integrates research, medical education and patient care at its three institutions -- Stanford University School of Medicine, Stanford Hospital & Clinics and Lucile Packard Children's Hospital Lucile Packard Children's Hospital (LPCH) is a hospital located on the Stanford University campus in Palo Alto, California. It is staffed by over 650 physicians and 4,750 staff and volunteers. at Stanford. For more information, please visit the Web site of the medical center's Office of Communication & Public Affairs at http://mednews.stanford.edu. |
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