Programs for invasive research in North American zoos and aquariums

Zoo-based research in North America is an emerging field, which has progressed from an ad hoc approach in a small number of zoos to a coordinated, integrated network of scientists with recognized research programs in approximately one half of the accredited institutions in North America. The disciplines most active in these programs--veterinary medicine and pathology, nutrition, reproductive biology, contraception, and behavior--are now becoming coordinated in zoos through Scientific Advisory Groups. Zoos with research programs generally establish either an institutional animal care and use committee or another committee to evaluate research proposals. In addition to scientific merit and experimental design, zoos evaluate proposals based on factors such as priority by conservation program/identified need; direct effect on species conservation, species type, and appropriateness; availability and location of animals; operational requirements/logistics; communication between institutions; and available funding. Euthanasia is considered only in rare circumstances. Zoo-based research has evolved into an integral component in animal management and conservation programs by providing practical information that is used to improve animal care, well-being, health, and reproduction. However, the degree to which zoos participate in invasive research varies considerably among institutions, due not only to resource limitations but also to how the term "invasive" is defined and accepted at each institution. A more standardized approach among zoological institutions for examining and approving research projects that are supported by zoo-based conservation programs would greatly facilitate the wildlife research efforts of North American zoos.     

Embryogenomics: developmental biology meets genomics

Fundamental questions in developmental biology are: what genes are expressed, where and when they are expressed, what is the level of expression and how are these programs changed by the functional and structural alteration of genes? These questions have been addressed by studying one gene at a time, but a new research field that handles many genes in parallel is emerging. The methodology is at the interface of large-scale genomics approaches and developmental biology. Genomics needs developmental biology because one of the goals of genomics – collection and analysis of all genes in an organism – cannot be completed without working on embryonic tissues in which many genes are uniquely expressed. However, developmental biology needs genomics – the high-throughput approaches of genomics generate information about genes and pathways that can give an integrated view of complex processes. This article discusses these new approaches and their applications to mammalian developmental biology.     

One phase of the dormancy developmental pathway is critical for the evolution of insect seasonality

Evolutionary change in the timing of dormancy enables animals and plants to adapt to changing seasonal environments and can result in ecological speciation. Despite its clear biological importance, the mechanisms underlying the evolution of dormancy timing in animals remain poorly understood because of a lack of anatomical landmarks to discern which phase of dormancy an individual is experiencing. Taking advantage of the nearly universal characteristic of metabolic suppression during insect dormancy (diapause), we use patterns of respiratory metabolism to document physiological landmarks of dormancy and test which of the distinct phases of the dormancy developmental pathway contribute to a month‐long shift in diapause timing between a pair of incipient moth species. Here, we show that divergence in life cycle between the earlier‐emerging E‐strain and the later‐emerging Z‐strain of European corn borer (ECB) is clearly explained by a delay in the timing of the developmental transition from the diapause maintenance phase to the termination phase. Along with recent findings indicating that life‐cycle differences between ECB strains stem from allelic variation at a single sex‐linked locus, our results demonstrate how dramatic shifts in animal seasonality can result from simple developmental and genetic changes. Although characterizing the multiple phases of the diapause developmental programme in other locally adapted populations and species will undoubtedly yield surprises about the nature of animal dormancy, results in the ECB moth suggest that focusing on genetic variation in the timing of the dormancy termination phase may help explain how (or whether) organisms rapidly respond to global climate change, expand their ranges after accidental or managed introductions, undergo seasonal adaptation, or evolve into distinct species through allochronic isolation.     

转基因动物研究及其产业化

转基因动物研究始于20世纪70年代,至今已在牛、羊、猪、鱼、猴和兔等动物身上取得转基因成功,并广泛用于生产药用蛋白、器官移植和抗病育种等领域,成为当今生命科学中最热门、发展最快的新兴产业。在论述转基因动物发展有利方面的同时,指出了其发展中面临的问题和今后研究的方向及发展前景。     

Structural biology of Gram-positive bacterial adhesins

The structural biology of Gram-positive cell surface adhesins is an emerging field of research, whereas Gram-negative pilus assembly and anchoring have been extensively investigated and are well understood. Gram-positive surface proteins known as MSCRAMMs (microbial surface components recognizing adhesive matrix molecules) and individual proteins that assemble into long, hair-like organelles known as pili have similar features at the primary sequence level as well as at the tertiary structural level. Some of these conserved features are essential for their transportation from the cytoplasm and for cell wall anchoring. More importantly, the MSCRAMMs and the individual pilins are assembled with building blocks that are variants of structural modules used for human immunoglobulins. MSCRAMMs target the host's extracellular matrix proteins, such as collagen, fibrinogen, and fibronectin, and they have received considerable attention from structural biologists in the last decade, who have primarily been interested in understanding their interactions with host tissue. The recent focus is on the newly discovered pili of Gram-positive bacteria, and in this review, we highlight the advances in understanding of the individual pilus constituents and their associations and stress the similarities between the individual pilins and surface proteins.     

New insights into animal pathogenic oomycetes

Many species of oomycetes cause economic and environmental damage owing to their ability to infect a range of plants and animals. Although research on plant pathogenic oomycetes has flourished in recent years, the animal pathogenic oomycetes have received less attention. This is unfortunate because several species are responsible for devastating diseases in aquaculture and natural ecosystems and proper treatments are not available or are limited. Therefore, momentum is being created to revive research into this neglected group of pathogens. Here, we discuss the latest developments in our current understanding of the biology, host-pathogen interactions and environmental and economical impact of the animal pathogenic oomycetes and review the recent advances in this emerging field.     

模式动物在共生微生物研究中的作用

共生微生物是一类定殖于宿主体表或体内, 可执行宿主本身无法完成的功能, 并依赖于宿主所提供的生长环境的微生物。众多研究表明, 人体肠道共生微生物与免疫、营养、代谢, 甚至精神健康等生理功能密切相关, 是重要的“微生物器官”。在早期的肠道微生物研究中, 模式动物就已经作为研究工具被使用。随着肠道微生物研究的不断深入, 模式动物作为不可替代的研究对象发挥了越来越重要的作用。本综述主要对几种重要的模式动物如斑马鱼(Danio rerio)、小鼠(Mus musculus)、猪(Sus scrofa domesticus)和猕猴(Macaca mulatta)在肠道微生物研究中的应用进行了总结, 介绍了各种模式动物的发展过程及特点, 各自在应用于研究时的优缺点, 以及利用这些动物模型在共生微生物领域所取得的一些标志性的科研成果。同时, 也就近年来在共生微生物领域新兴的一些模式生物如蜜蜂(Apis)、果蝇(Drosophila)、秀丽隐杆线虫(Caenorhabditis elegans)等进行了一些探讨。旨在让该领域的研究者们了解模式动物与人体在共生微生物方面的异同, 为更好地利用这一研究工具提供参考。     

Coordinating growth and maturation - insights from Drosophila

Adult body size in higher animals is dependent on the amount of growth that occurs during the juvenile stage. The duration of juvenile development, therefore, must be flexible and responsive to environmental conditions. When immature animals experience environmental stresses such as malnutrition or disease, maturation can be delayed until conditions improve and normal growth can resume. In contrast, when animals are raised under ideal conditions that promote rapid growth, internal checkpoints ensure that maturation does not occur until juvenile development is complete. Although the mechanisms that regulate growth and gate the onset of maturation have been investigated for decades, the emerging links between childhood obesity, early onset puberty, and adult metabolic disease have placed a new emphasis on this field. Remarkably, genetic studies in the fruit fly Drosophila melanogaster have shown that the central regulatory pathways that control growth and the timing of sexual maturation are conserved through evolution, and suggest that this aspect of animal life history is regulated by a common genetic architecture. This review focuses on these conserved mechanisms and highlights recent studies that explore how Drosophila coordinates developmental growth with environmental conditions.     

Biases in signal evolution: learning makes a difference

It is now well established that signal receivers have a key role in the evolution of animal communication: the suite of sensory and cognitive processes by which animals perceive and learn about their environment can have a significant impact on signal design. A crucial property of these information-processing mechanisms is the emergence of 'receiver bias' in the behavioural responses to signals. Whereas most research has focussed on receiver biases in the sensory system, more recent studies show that biases can also arise from learning about signals. Here, we highlight how learning-based biases can arise, and how these differ from biases emerging from sensory systems in their impact on signal evolution.     

CREB mediates the C. elegans dauer polyphenism through direct and cell-autonomous regulation of TGF-β expression

Animals can adapt to dynamic environmental conditions by modulating their developmental programs. Understanding the genetic architecture and molecular mechanisms underlying developmental plasticity in response to changing environments is an important and emerging area of research. Here, we show a novel role of cAMP response element binding protein (CREB)-encoding crh-1 gene in developmental polyphenism of C. elegans. Under conditions that promote normal development in wild-type animals, crh-1 mutants inappropriately form transient pre-dauer (L2d) larvae and express the L2d marker gene. L2d formation in crh-1 mutants is specifically induced by the ascaroside pheromone ascr#5 (asc-ωC3; C3), and crh-1 functions autonomously in the ascr#5-sensing ASI neurons to inhibit L2d formation. Moreover, we find that CRH-1 directly binds upstream of the daf-7 TGF-β locus and promotes its expression in the ASI neurons. Taken together, these results provide new insight into how animals alter their developmental programs in response to environmental changes.     

The Development of Cooperative Associations Between Animals and Bacteria: Establishing Detente Among Domains

SYNOPSIS. détente = n.(fr.) the relaxation of tensionsbetween two nations, usually through cooperation and negotiation.[The Random House Dictionary, 2nd Edition, 1987] Despite the ubiquitous occurrence of cooperative associationsbetween animals and bacteria, there is little understandingof how these interactions arose, how they evolved, and how theypersist. Thus, an extensive database concerning the influenceof bacteria on developmental pathways is not yet available.However, in much the same way that mutually beneficial liaisonsare created between nations with vastly different historiesand cultures, it is likely that highly refined developmentalmechanisms exist in which a type of detente is created to retainthe integrity of the associations between the partners, bothwithin and between generations. These developmental pathwayswould be responsible for insuring that a balance of cell growthis established and maintained among the community members, comprisedof animal and microbial cells, such that neither form of pathogenesis,i.e., overgrowth (war) or aposymbiosis (isolation), ensues.This contribution examines aspects of how alliances with prokaryotesmay have been integrated into the mechanisms and patterns ofhost animal developmental programs.     

Considerations in the selection and conditioning of Old World monkeys for laboratory research: animals from domestic sources

Nonhuman primates from domestic sources constitute an important resource for the research community. The life history of the Old World monkey species that comprise the bulk of this resource is described, and issues that colony managers and researchers alike should consider regarding animal selection (e.g., species, age, sex, rearing history, temperament, genotype, viral status, geographic origin) are discussed. Preparation of domestically bred animals for research usually involves some combination of social separation, relocation, resocialization, alterations in physical space, photoperiod, and diet, as well as exposure to novel environments. The research literature that has focused on these issues is reviewed, and authors suggest that once animals have been assigned to their project housing situation, a period ranging up to 3 mo (depending on the magnitude of the change in housing) might be warranted before an experimental protocol should begin. Attention to issues of animal selection and conditioning by both researchers and colony managers can lead to the shared goal of high-quality research that utilizes the minimal number of animals.     

EvoRegen in animals: Time to uncover deep conservation or convergence of adult stem cell evolution and regenerative processes

How do animals regenerate specialised tissues or their entire body after a traumatic injury, how has this ability evolved and what are the genetic and cellular components underpinning this remarkable feat? While some progress has been made in understanding mechanisms, relatively little is known about the evolution of regenerative ability. Which elements of regeneration are due to lineage specific evolutionary novelties or have deeply conserved roots within the Metazoa remains an open question. The renaissance in regeneration research, fuelled by the development of modern functional and comparative genomics, now enable us to gain a detailed understanding of both the mechanisms and evolutionary forces underpinning regeneration in diverse animal phyla. Here we review existing and emerging model systems, with the focus on invertebrates, for studying regeneration. We summarize findings across these taxa that tell us something about the evolution of adult stem cell types that fuel regeneration and the growing evidence that many highly regenerative animals harbor adult stem cells with a gene expression profile that overlaps with germline stem cells. We propose a framework in which regenerative ability broadly evolves through changes in the extent to which stem cells generated through embryogenesis are maintained into the adult life history.     

Bridging the generation gap: flowering plant gametophytes and animal germlines reveal unexpected similarities

Alternation of generations underpins all plant life histories and is held to possess important adaptive features. A wide range of data have accumulated over the past century which suggest that alternation from sporophyte to gametophyte in angiosperms includes a significant phase of 'informational reprogramming', leaving the founder cells of the gametophyte developmentally uncommitted. This review attempts to bring together results from these historic studies with more recent data on molecular and epigenetic events which accompany alternation, gametophyte development and gametogenesis in angiosperms. It is striking that most members of the other principal group of multicellular eukaryotes – the animals - have a completely different a life history: animals generate their gametes directly from diploid germlines, often set aside early in development. Nevertheless, a comparison between animal germlines and angiosperm gametophyte development reveals a number of surprising similarities at the cytological and molecular levels. This difference in life history but similarity in developmental process is reviewed in the context of the very different life strategies adopted by plants and animals, and particularly the fact that plants do not set aside diploid germlines early in development.     

Wild mice provide insights into natural killer cell maturation and memory

The immune system has evolved, and continues to evolve, in response to the selection pressure that infections exert on animals in their natural environments, yet much of our understanding about how the immune system functions comes from studies of model species maintained in the almost complete absence of such environmental selection. The scientific discipline of immunology has among its aims the improvement of human and animal health by the application of immunological knowledge. As research on humans and domesticated animals is highly constrained-ethically, logistically and financially-experimental animal models have become an invaluable tool for dissecting the functioning of the immune system. The house mouse (Mus musculus) is by far the most widely used animal model in immunological research but laboratory-reared mice provide a very narrow view of the immune system-that of a well-fed and comfortably housed animal with minimal exposure to microbial pathogens. Indeed, so much of our immunological knowledge comes from studies of a very few highly inbred mouse strains that-to all intents and purposes-our immunological knowledge is based on enormously detailed studies of very small numbers of individual mice. The limitations of studies in inbred strains of laboratory mice are well-recognized (Pedersen & Babayan 2011), but serious attempts to address these limitations have been few and far between. However, the emerging field of 'ecological immunology' where free-living populations are studied in their natural habitat is beginning to redress this imbalance (Viney et al. 2005; Martin et al. 2006; Owen et al. 2010; Abolins et al. 2011). As demonstrated in the work by Boysen et al. (2011) in this issue of Molecular Ecology, studies in wild animal populations-especially free-living M. musculus-represent a valuable bridge between studies in humans and livestock and studies of captive animals.     

Current status and future directions of applied behavioral research for animal welfare and conservation

The papers that follow in this special issue reflect the state of knowledge and theory in the fields of animal welfare and conservation behavior. A particular focus is placed on how enrichment can be used judiciously to improve welfare and to prepare captive animals for release back to the wild. However, my purpose here is not simply to reiterate what the contributors of this special issue have said, but to provide an overview of the major themes, problems, and opportunities in applied animal behavior related to conservation and welfare. I review major issues in three interrelated areas: captive welfare, captive breeding, and conservation behavior research for wild populations. Despite many advancements in welfare science, one of the most significant impediments to a predictive science of welfare is the need to further refine theories advanced to explain environment–welfare relationships. I provide a brief overview of ten theories that have been proposed to explain good or poor welfare and suggest that they need to be made more conceptually distinct so that clear hypotheses can be articulated, and predictions made and tested. Captive breeding programs for ex situ conservation have borrowed and applied many of the concepts involved in welfare science to great advantage. Other keys to successful breeding programs include applying knowledge of social organization and processes to enhance reproduction; for example, finding the right combination of individuals to get animals breeding. However, behaviorists are only recently learning how to manipulate behavioral mechanisms, such as signaling behavior and mate choice, to optimize captive breeding for conservation. The emerging field of conservation behavior has played a role in captive breeding, but also is poised to play a major role in in situ conservation. Applied behavioral research can illuminate a number of issues important to conservation, including behavioral responses to habitat fragmentation and human disturbance (e.g., pollutants, noise, and light), and human–animal conflict (e.g., crop-raiding). Behavioral decisions made when animals are dispersing and selecting habitat for settlement determine the distribution of animals on the landscape and are important to understand for improving reserve and habitat corridor design. Captive–release and translocation programs require detailed behavioral knowledge to predict responses to novel environments and ensure that animals are adequately prepared for environmental change. This review underscores that many of the behavioral processes of interest to welfare science are also important for conservation behavior: perception, stress, assessment and decision-making rules, and other behavioral and physiological mechanisms. If properly understood, these mechanisms can be manipulated in the service of conservation goals, moving the field of conservation behavior from implication to application. A better integration of the disciplines of animal welfare and conservation behavior – together tackling problems at multiple levels of analysis – will further these goals.     

Primates got personality,too: Toward an integrative primatology of consistent individual differences in behavior

In recent years, research on animal personality has exploded within the field of behavioral ecology. Consistent individual differences in behavior exist in a wide range of species, and these differences can have fitness consequences and influence several aspects of a species' ecology. In comparison to studies of other animals, however, there has been relatively little research on the behavioral ecology of primate personality. This is surprising given the large body of research within psychology and biomedicine showing that primate personality traits are heritable and linked to health and life history outcomes. In this article, I bring together theoretical perspectives on the ecology and evolution of animal personality with an integrative review of what we know about primate personality from studies conducted on captive, free‐ranging, and wild primates. Incorporating frameworks that emphasize consistency in behavior into primate behavioral ecology research holds promise for improving our understanding of primate behavioral evolution.     

Training strategies for research investigators and technicians

Training programs for research personnel are discussed as a key resource that must be part of an effective animal care and use program. Because of the legal responsibility to ensure that research staff are qualified to use animals, many institutions have justified the necessity for a training coordinator and/or trainers for their animal care and use programs. Effective training programs for research personnel must meet the needs of the client base (research scientists and staff) so that they are relevant, practical, and timely. To meet these objectives, it is useful to involve the scientific staff in the analysis of their learning needs. To meet a performance standard necessary for quality research, a large percentage of the institutional staff must participate in the training program. Often it is the principal investigators who set the tone for their staff members regarding the importance of receiving training. Garnering support from this client base will create a culture that encourages training and engenders a positive attitude about humane animal care and use. One effective approach is to incorporate nonanimal models as alternatives to live animals to teach humane handling techniques and methods, thereby contributing to refinement, reduction, and replacement (the 3Rs). Also discussed are the necessity of timely feedback from clients, documentation of personnel training for regulatory purposes, and the collection of training metrics, which assists in providing justification for the granting of additional fiscal support for the program. Finally, the compliance procedures and opportunities for essential refresher training are discussed and related to high performance standards, humane animal use, and quality research, all of which contribute to the 3Rs.     

Maternal immune activation and autism spectrum disorder: interleukin-6 signaling as a key mechanistic pathway

An emerging area of research in autism spectrum disorder (ASD) is the role of prenatal exposure to inflammatory mediators during critical developmental periods. Epidemiological data has highlighted this relationship showing significant correlations between prenatal exposure to pathogens, including influenza, and the occurrence of ASD. Although there has not been a definitive molecular mechanism established, researchers have begun to investigate this relationship as animal models of maternal infection have support- ed epidemiological findings. Several groups utilizing these animal models have found that activation of the maternal immune system, termed maternal immune activation (MIA), and more specifically the exposure of the developing fetus to maternal cytokines precipitate the neurological, immunological and behavioral abnormalities observed in the offspring of these animals. These abnormalities have correlated with clinical findings of immune dysregulation, neurological and behavioral abnormalities in some autistic individuals. Additionally, researchers have observed genetic variations in these models in genes which regulate neurological and immunological development, similar to what is observed clinically in ASD. Altogether, the role of MIA and cytokine dysregulation, as a key mediator in the neuropathological, behavioral and possibly genetic irregularities observed clinically in autism are important factors that warrant further investigation.