非人灵长类动物精子冻存技术的研究进展

随着生物医学技术的发展,应用非人灵长类动物模型进行基础科学研究日益广泛。与此同时,由于栖息地破坏、狩猎和基因隔离,许多非人灵长类动物濒临灭绝。因此,改进非人灵长类动物精子冻存技术对物种遗传资源的保藏具有重要的意义。本文概述了非人灵长类动物的精液特征,介绍了精液液化和冷冻精子质量评估的方法,分析了冷冻保护剂、冷冻稀释液及冷冻方法等因素对精子冻存效果的影响,总结了目前非人灵长类精子冷冻常用的冷冻保存液和冷冻方法,并对相关精子参数进行了比较,同时探讨了非人灵长类动物精子冻存研究面临的困境,并提出了可行的方案。总之,本文综述了近年来非人灵长类动物精子冻存的重要研究成果,对开发新的冷冻保护剂及改进冷冻技术具有一定的参考价值。     

恒河猴在生殖生物学中的应用进展

目的非人灵长类动物在生殖生物学研究领域是一种非常重要的实验动物。人类利用非人灵长类动物与人的生物学等方面相似的特征,开展了生殖生物学、生理学、药理学、毒理学以及生育调节等方面的研究工作,为生殖生物学基础研究以及人类健康和疾病问题的基础研究和临床前研究提供了理想的动物模型。随着生命科学的发展,对非人灵长类实验动物质量提出了更高的要求,人们认识到实验时,应用健康的优质非人灵长类动物的重要性。本文简要概括了非人灵长类动物恒河猴的生物学特性,阐述了非人灵长类动物恒河猴在生殖生物学中的应用研究。     

非人灵长类胚胎工程研究进展

由于非人灵长类动物与人类在进化上的亲缘关系和生理特征上的高度相似,它们在人类传染病、生殖、发育、代谢、神经和衰老等研究领域具有重要的应用价值。现对非人灵长类动物的常见胚胎工程技术进行综述,包括非人灵长类动物的配子收集、体外受精和胚胎移植等;同时,还结合基因组编辑技术的发展,简要介绍了近年来胚胎工程技术在非人灵长类动物基因编辑方面的应用。     

非人灵长类局部脑缺血动物模型研究现状

非人灵长类动物在种系发生上较啮齿类更接近于人类,用来制备局部脑缺血模型可以更好的拟合临床症状和机理。通过对国内外非人灵长类动物局部脑缺血模型的制备方法和应用现状进行收集、分类和述评,展望非人灵长类动物模型的应用前景,尤其是利用低等灵长类动物树鼩研究缺血性中风的优势。     

非人灵长类动物基因编辑技术的应用及挑战

建立有效的动物模型是研究人类疾病演进、开发新型治疗手段的重要方法。非人灵长类动物在进化发育、生理生化及病理方面和人类最接近,是研究人类疾病的理想动物模型。随着基因编辑技术的发展,研究者已经成功建立了多种模仿人类疾病的非人灵长类动物模型。但是CRISPR/Cas9的脱靶效应、嵌合突变以及基因敲入效率较低等突出问题也逐渐引起重视。本文综述了基因编辑技术在建立非人灵长类动物模型中的应用现状,提出了目前亟需解决的难点和应对策略,以期为高效、准确构建非人灵长类动物模型提供借鉴与参考。     

衰老对2种猕猴血液基因表达的影响及与人类的对比

衰老是导致免疫功能和代谢活动下降的危险因素.作为最常用的非人灵长类动物模型,猕猴属Macaca被用来探索与衰老过程相关的因素.为了比较2种猕猴和人类在衰老过程基因表达变化的异同,本研究收集比较了3个物种的血液转录组.在藏酋猴M.thibetana(TM)、普通猕猴M.mulatta(CR)和人类中分别获得了2523个、...     

非人灵长类肿瘤模型研究进展(英文)

癌症是人类第二大致死的疾病。将体外细胞模型获得的癌症研究结果向临床转化过程中,动物活体实验是必不可少的一个环节。现在的肿瘤活体实验绝大部分采用啮齿类实验动物如小鼠和大鼠,这是因为它们具有个体小、繁殖迅速、遗传背景清楚、转基因技术成熟等优势。但是啮齿类和人的亲缘关系比较远,许多从啮齿类动物模型获得的研究结果不能在人体重现。非人灵长类动物在遗传进化、免疫、生理和代谢等诸多方面与人类高度近似,理论上更加适合癌症研究。本文对现有的非人灵长类肿瘤研究做一综述,主要集中介绍用化学和生物致癌剂在不同的非人灵长类动物诱导肿瘤的研究,为将来用非人灵长类动物研究人类癌症奠定基础。     

非人灵长类动物睡眠地点的选择与利用

睡眠行为在非人灵长类动物的生活史中占有十分重要地位。关于非人灵长类睡眠地点选择与利用的研究是灵长类行为生态学领域的核心课题之一。本文回顾以往的研究, 总结了非人灵长类动物睡眠地点选择的三个主要影响因素, 即捕食压力引起的安全因素, 睡眠地点的舒适因素和卫生因素; 分别对非人灵长类睡眠地点选择的三种主要形式进行了初步的成因讨论, 对未来的研究方向进行探索性地展望。     

非人灵长类觅食行为生态学研究进展

觅食行为生态学是动物生态学研究的主要内容之一.从食物选择研究方法、食物选择策略机制、觅食行为的影响因素等方面综述非人灵长类动物觅食行为生态学研究进展.食物选择策略和活动时间分配是觅食行为生态学研究的主要内容.非人灵长类动物觅食行为生态学的研究对动物保护、人工驯养和繁殖具有重要意义.     

非人灵长类雌性等级的研究方法

在非人灵长类动物等级研究中, 有关判定与描述优势等级方法的选择至关重要。早期对旧大陆灵长类的等级研究主要关注雄性, 对雌性涉猎较少。目前主要应用攻击-屈服、取食、携婴、相互理毛等行为标准来研究灵长类的雌性等级, 也发现不同的物种往往有不同的雌性等级模式。依据社群结构的完整性将其分为线性等级与非线性等级, 并采用不同的方式进行描述。本文通过查阅文献资料, 对雌性等级的研究内容、判定标准以及描述方式进行论述, 以便抛砖引玉提高非人灵长类雌性等级的研究水平。     

Referential labelling in Diana monkeys

Animal semantic communication has received considerable theoretical and empirical attention because of its relevance to human language. Advances have been made by studies of alarm-call behaviour in nonhumans. In monkeys, for example, there is evidence that recipients have a fairly sophisticated understanding of a call's meaning; that is, the predator type usually associated with a certain alarm call. Little is known, however, about the mental mechanisms that drive call production in nonhuman primates. In some nonprimate species, it has been found that signallers do not respond to a predator's physical features but instead seem to respond to its relative threat or direction of attack. In these species, therefore, alarm calls do not denote different predator categories but simply reflect different types or levels of danger. Because different predator categories typically impose different types and degrees of threat it is entirely possible that nonhuman primates also respond to threat rather than a predator's category. This study examined how wild Diana monkeys, Cercopithecus diana, of the Ta? forest, Ivory Coast, label predation events. By altering playback stimuli and the position of a concealed speaker, I investigated whether Diana monkeys respond with acoustically different alarm calls depending on a predator's (1) distance (close versus far), (2) elevation (above versus below), or (3) category (eagle versus leopard). Analysis of male and female alarm-call behaviour showed that Diana monkeys consistently responded to predator category regardless of immediate threat or direction of attack. Data further suggested that, in addition to predator category, monkeys' alarm calls might also convey information about the predator's distance. Copyright 2000 The Association for the Study of Animal Behaviour.     

Heterospecific recognition of referential alarm calls in two species of lemur

ABSTRACT

Alarm vocalizations are a common feature of the mammalian antipredator response. The meaning and function of these calls vary between species, with some species using calls to reference-specific categories of predators. Species can also use more than just the calls of conspecifics to detect threat, ‘eavesdropping’ on other species’ signalling to avoid predation. However, the evidence to date for both referential signalling and eavesdropping within primates is limited. We investigated two sympatric populations of wild lemur, the Coquerel’s sifaka Propithecus coquereli and the common brown lemur Eulemur fulvus, presenting them with playbacks of predator calls, conspecific alarm calls and heterospecific lemur alarm calls, and recorded their behavioural responses following the playbacks. Results suggest that the Coquerel’s sifaka may have functionally referential alarm calls with high specificity for aerial predators, but there was no evidence for any referential nature of the other call investigated. Brown lemurs appear to have a mixed alarm system, with one call being specific with respect to aerial predators. The other call investigated appeared to reference terrestrial predators. However, it was also used in other contexts, so does not meet the criteria for functional reference. Both species showed evidence for heterospecific alarm call recognition, with both the Coquerel’s sifaka and the brown lemurs responding appropriately to heterospecific aerial alarm calls.     

Ontogeny of conspecific and heterospecific alarm call recognition in wild Verreaux's sifakas (Propithecus verreauxi verreauxi)

The production of vocalizations in nonhuman primates is predominantly innate, whereas learning influences the usage and comprehension of vocalizations. In this study, I examined the development of alarm call recognition in free-ranging infant Verreaux's sifakas. Specifically, I investigated their ability to recognize conspecific alarm calls as well as those of sympatric redfronted lemurs (Eulemur fulvus rufus) in Kirindy forest, western Madagascar. Both species have functionally referential alarm calls for aerial predators and give general alarm calls for both aerial and general predators and also other kinds of threats, such as intergroup encounters with conspecifics. I conducted playback experiments with members of two birth cohorts (nine and ten individuals) to determine the age at which infant Verreaux's sifakas discriminate between conspecific alarm calls, heterospecific alarm calls, and non-alarm vocalizations (parrot song). Most 3-4 months old infants fled toward adults after hearing any playback stimuli, whereas 4-5-month-old infants did so only after presentation of alarm calls. Moreover, all infants of these age classes showed a longer latency to flee after the parrot song indicating their emerging ability to discriminate between alarm calls and non-alarm stimuli. At an age of about 6 months, infants switched from fleeing toward adults to performing adult-like escape responses after presentation of conspecific and heterospecific alarm calls. Thus, the ability to discriminate between alarm from non-alarm stimuli precedes the appearance of adult-like responses. The transition to adult-like escape behavior was coincident with the physical independence of infants from their mothers.     

On the Meaning of Alarm Calls: A Review of Functional Reference in Avian Alarm Calling

A long‐standing question in animal communication is whether signals reveal intrinsic properties of the signaller or extrinsic properties of its environment. Alarm calls, one of the most conspicuous components of antipredator behaviour, intuitively would appear to reflect internal states of the signaller. Pioneering research in primates and fowl, however, demonstrated that signallers may produce unique alarm calls during encounters with different types of predators, suggesting that signallers through selective production of alarm calls provide to conspecific receivers information about predators in the environment. In this article, we review evidence for such ‘functional reference’ in the alarm calls of birds based on explicit tests of two criteria proposed in Macedonia & Evans’ (Ethology 93, 1993, 177) influential conceptual framework: (1) that unique alarm calls are given to specific predator categories, and (2) that alarm calls isolated from contextual information elicit antipredator responses from receivers similar to those produced during actual predator encounters. Despite the importance of research on birds in development of the conceptual framework and the ubiquity of alarm calls in birds, evidence for functionally referential alarm calls in this clade is limited to six species. In these species, alarm calls are associated with the type of predator encountered as well as variation in hunting behaviour; with defence of reproductive effort in addition to predators of adults; with age‐related changes in predation risk; and with strong fitness benefits. Our review likely underestimates the occurrence of functional reference in avian alarm calls, as incomplete application and testing of the conceptual framework has limited our understanding. Throughout, therefore, we suggest avian taxa for future studies, as well as additional questions and experimental approaches that would strengthen our understanding of the meaning of functional reference in avian alarm calls.     

A method for identifying sounds used in the classification of alarm calls

In this study, we present a methodology that identifies acoustic units in Gunnison's prairie dog alarm calls and then uses those units to classify the alarm calls and bouts according to the species of predator that was present when the calls were vocalized. While traditional methods measure specific acoustic parameters in order to describe a vocalization, our method uses the variation in the internal structure of a vocalization to define possible information structures. Using a simple representation similar to that used in human speech to identify vowel sounds, a software system was developed that uses this representation to recognize acoustic units in prairie dog alarm calls. These acoustic units are then used to classify alarm calls and their associated bouts according to the species of predator that was present when the alarm calls were vocalized. Identification of bouts with up to 100% accuracy was obtained. This work represents a first step toward revealing the details of how information is encoded in a complex nonhuman communication system. Furthermore, the techniques discussed in this paper are not restricted to a database of prairie dog alarm calls. They could be applied to any animal whose vocalizations include multiple simultaneous frequencies.     

Wild chimpanzees inform ignorant group members of danger

The ability to recognize other individuals' mental states-their knowledge and beliefs, for example-is a fundamental part of human cognition and may be unique to our species. Tests of a "theory of mind" in animals have yielded conflicting results. Some nonhuman primates can read others' intentions and know what others see, but they may not understand that, in others, perception can lead to knowledge. Using an alarm-call-based field experiment, we show that chimpanzees were more likely to alarm call in response to a snake in the presence of unaware group members than in the presence of aware group members, suggesting that they recognize knowledge and ignorance in others. We monitored the behavior of 33 individuals to a model viper placed on their projected travel path. Alarm calls were significantly more common if the caller was with group members who had either not seen the snake or had not been present when alarm calls were emitted. Other factors, such as own arousal, perceived risk, or risk to receivers, did not significantly explain the likelihood of calling, although they did affect the call rates. Our results suggest that chimpanzees monitor the information available to other chimpanzees and control vocal production to selectively inform them.     

Language evolution: the origin of meaning in primates

Research on alarm calls has yielded rare glimpses into the minds of our closest relatives. A new study suggests that primates monitor the effect alarm calls have on others.     

The evolution of nonhuman primate loud calls: Acoustic adaptation for long-distance transmission

Many nonhuman primates produce species-typical loud calls used to communicate between and within groups over long distances. Given their observed spacing functions, primate loud calls are likely to show acoustic adaptations to increase their propagation over distance. Here we evaluate the hypothesis that primates emit loud calls at relatively low sound frequencies to minimize their attenuation. We tested this hypothesis within and between species. First, we compared the frequencies of loud calls produced by each species with those of other calls from their vocal repertoires. Second, we investigated the relationship between loud call frequency and home range size across a sample of primate species. Comparisons indicated that primates produce loud calls at lower frequencies than other calls within their vocal repertoires. In addition, a significant negative relationship exists between loud call frequency and home range size among species. The relationship between call frequency and range size holds after controlling for the potentially confounding effects of body size and phylogeny. These results are consistent with the hypothesis that nonhuman primates produce loud calls at relatively low frequencies to facilitate their transmission over long distances.     

Anti‐Predator Behaviour in a Nocturnal Primate,the Grey Mouse Lemur (Microcebus murinus)

Although one‐third of all primates are nocturnal, their anti‐predator behaviour has rarely been studied. Because of their small body size, in combination with their solitary and nocturnal life style, it has been suggested that they mainly rely on crypsis to evade predators. However, recent studies revealed that nocturnal primates are not generally cryptic and that they exhibit predator‐specific escape strategies as well as alarm calls. In order to add to this new body of research, we studied anti‐predator strategies of nocturnal grey mouse lemurs experimentally. In order to elicit anti‐predator behaviour and alarm calls, we conducted experiments with a carnivore‐, snake‐ and raptor model. We also conducted playback experiments with mouse lemur alarm calls to characterize their function. In response to predator models, they exhibited a combination of anti‐predator strategies: in response to carnivore and snake models, mouse lemurs monitored the predator, probably to assess the potential risk that emanates from the predator. In response to raptor models they behaved cryptically and exhibited freezing behaviour. All mouse lemurs, except one individual, did not alarm call in response to predator models. In addition, during playback experiments with alarm calls, recorded during real predator encounters, mouse lemurs did not emit alarm calls nor did they show any escape behaviour. Thus, as in other nocturnal primates/mammals, mouse lemurs do not seem to rely on routinely warning of conspecifics against nearby predators.     

Titi monkey call sequences vary with predator location and type

Animal alarm calls can encode information about a predator''s category, size, distance or threat level. In non-human primates, alarm calls typically refer to broad classes of disturbances, in some instances to specific predators. Here, we present the results of a field experiment with a New World primate, the black-fronted titi monkey (Callicebus nigrifrons), designed to explore the information conveyed by their alarm call system. Adults produced sequences consisting of two main alarm call types that conveyed, in different parts of the utterance, information about a predator''s type and location. In particular, sequence compositions differed depending on whether the predator was a mammalian carnivore or a raptor, and whether it was detected in a tree or on the ground. This is the first demonstration of a sequence-based alarm call system in a non-human animal that has the capacity to encode both location and type of predatory threat.