Collaborative Research: Disease Dynamics in Degraded Nurseries: A Viral Disease in Spiny Lobster

合作研究：退化苗圃中的疾病动态：龙虾中的病毒性疾病

• 批准号: 0452383
• 负责人: Mark Butler
• 金额: --
• 依托单位: Old Dominion University Research Foundation
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2005
• 资助国家: 美国
• 起止时间: 2005-03-15 至 2008-11-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0452383&HistoricalAwards=false
• 关键词: Collaborative; Research; Disease; Dynamics; Degraded

The problem of emerging infectious diseases is particularly acute in marine ecosystems where studies lag behind those in terrestrial systems. Reports of emerging diseases in marine organisms are increasing worldwide, particularly in coastal environments, where the evidence is compelling that these events are associated with the degradation of water quality and habitat integrity. Yet, few of these studies have produced epidemiological models capable of integrating local environmental change with disease dynamics, and none involve motile marine fauna. A lethal, pathogenic virus has recently been discovered that infects juvenile Caribbean spiny lobster (Panulirus argus) in the Florida Keys, the first virus reported for any species of lobster. Transmission of the disease is primarily via contact and infectivity is associated with ontogeny; juvenile lobsters are susceptible to infection, adults are not. A remarkable facet of the disease is that it not only kills infected individuals, but also alters the behavior of healthy individuals who are normally social, but actively avoid contact with diseased conspecifics. The underlying causes for the emergence of the disease remain a mystery, but human-caused transformations of nursery habitat and declining water quality in south Florida preceded its emergence. One hypothesis is that deteriorating water quality, including that anticipated with Everglades restoration, acts as a subtle stressor that compromises lobster resistance to infection and facilitates the spread of disease. At the same time, poor water quality alters nursery habitat structure, thereby indirectly influencing disease dynamics by increasing host encounter rates and thus disease transmission. Potentially counter-balancing the effects of these environmental changes are ontogenetic shifts in host behavior, susceptibility to infection, and avoidance of diseased individuals that may constrain transmission of the disease. This project will include an ambitious program of laboratory, field, and modeling research with the goal of building a predictive understanding of the multifaceted role that diminished habitat integrity plays in the spread of a viral disease among social animals in degraded coastal marine ecosystems. The project builds on prior NSF sponsorship and draws together the talents of a multidisciplinary group of scientists with experience in lobster biology, ecological modeling, invertebrate pathology, and molecular biology. Although the focus is on the emerging PaV1 virus in spiny lobster in Florida as a model system, the results of this project will provide a better understanding of the role of habitat structure, ontogenetic changes in host resistance, and host behavior in regulating disease transmission in natural populations subject to anthropogenic insult. The project objectives are: (1) To explore the underlying mechanisms that control the spread of disease and to predict viral prevalence in relation to changes in nursery habitat structure and water quality stressors by incorporating ontogenetic aspects of host behavior, susceptibility to disease, and disease transmission into the existing spatially-explicit, individual-based lobster population model. (2) To quantitatively test in mesocosm and field experiments the effect of altered nursery habitat structure on ontogenetic differences in host movement, host spatial distribution, and viral transmission. (3) To determine in laboratory experiments whether potential environmental stressors such as extreme temperatures and salinities, or poor water quality alter host suceptiblity to viral infection or infectivity. (4) To characterize in a laboratory study host disease states and to determine their prevalence in nature using molecular and histological techniques. Broader Impacts: This project will include continued involvement and cross-training of undergraduates, graduate students, and postdocs, including participation of undergraduates in NSF REU programs at VIMS and ODU. Association with local resource management agencies ensures that the basic science results of this project will find application in management decisions. The PIs will co-host a semi-annual one-day workshop in Key West for fishermen, scientists, environmental managers, and the interested public where recent scientific findings and environmental concerns in the Florida Keys will be discussed. Continued molecular work will yield new assays for detection of viral infected tissue, which may aid officials in monitoring the potential spread and shipment of infected lobsters around the world. Also, the modeling component will aid managers in predicting the spread of the disease in wild populations.

新出现的传染病问题在海洋生态系统中特别严重，因为对海洋生态系统的研究落后于对陆地系统的研究。全世界关于海洋生物新出现疾病的报告越来越多，特别是在沿海环境中，有令人信服的证据表明，这些事件与水质和生境完整性的退化有关。然而，这些研究中很少有流行病学模型能够整合当地的环境变化与疾病的动态，没有涉及运动的海洋动物。 最近在佛罗里达群岛发现了一种致命的致病病毒，它感染了加勒比海幼棘龙虾（Panulirus argus），这是第一个报道的龙虾病毒。 该疾病的传播主要是通过接触，传染性与个体发育有关;幼年龙虾易受感染，成年龙虾则不然。 这种疾病的一个显著方面是，它不仅会杀死受感染的个体，还会改变健康个体的行为，这些健康个体通常是社会性的，但会积极避免与患病的同种接触。这种疾病出现的根本原因仍然是一个谜，但在它出现之前，人类引起的苗圃栖息地的变化和佛罗里达南部水质的下降。一种假设是，不断恶化的水质，包括大沼泽地恢复预期的水质，是一种微妙的压力源，损害了龙虾对感染的抵抗力，促进了疾病的传播。 与此同时，水质差改变苗圃生境结构，从而间接影响疾病动态增加主机遇到率，从而疾病传播。 潜在地抵消这些环境变化的影响的是宿主行为的个体发生变化、对感染的易感性以及可能限制疾病传播的患病个体的回避。 该项目将包括一个雄心勃勃的实验室、现场和建模研究计划，目标是预测性地了解栖息地完整性下降在退化沿海海洋生态系统中群居动物中病毒性疾病传播中所发挥的多方面作用。 该项目建立在先前的NSF赞助的基础上，并汇集了在龙虾生物学，生态建模，无脊椎动物病理学和分子生物学方面具有经验的多学科科学家小组的人才。 虽然重点是新兴的PaV 1病毒在刺龙虾在佛罗里达作为一个模型系统，这个项目的结果将提供一个更好的理解栖息地结构，个体发生变化的主机电阻，和主机行为在调节疾病传播的自然种群受到人为的侮辱。 该项目的目标是：（1）探索控制疾病传播的潜在机制，并通过将宿主行为、疾病易感性和疾病传播的个体发育方面纳入现有的空间明确的、基于个体的龙虾种群模型，预测与苗圃栖息地结构和水质压力变化相关的病毒流行。(2)在围隔和田间实验中定量测试改变苗圃生境结构对宿主移动、宿主空间分布和病毒传播的个体发育差异的影响。(3)在实验室实验中确定潜在的环境压力因素，如极端温度和盐度，或水质差是否会改变宿主对病毒感染或感染性的易感性。(4)在实验室研究中描述宿主疾病状态，并使用分子和组织学技术确定其在自然界中的流行率。 更广泛的影响：该项目将包括本科生，研究生和博士后的持续参与和交叉培训，包括本科生在VIMS和ODU参与NSF REU计划。 与当地资源管理机构的联系确保了该项目的基础科学成果将在管理决策中得到应用。 PI将在基韦斯特为渔民、科学家、环境管理人员和感兴趣的公众共同举办为期一天的半年一次的研讨会，讨论佛罗里达群岛最近的科学发现和环境问题。 持续的分子工作将产生新的检测病毒感染组织的方法，这可能有助于官员监测受感染龙虾在世界各地的潜在传播和运输。 此外，建模组件将帮助管理人员预测疾病在野生种群中的传播。