太行山猕猴的性打搅行为

性打搅是指动物在交配期间受到同种其他个体化学信息素、面部表情、声音、攻击等方面干扰的现象。性打搅行为作为非人灵长类繁殖行为生态研究的重要话题,具有高度的种间和种内差异,在种内主要受到性别和年龄等因素的影响。本研究于2021年9月至2022年8月在太行山猕猴国家级自然保护区五龙口地区,以太行山猕猴(Macaca mulatta tcheliensis) WLK-1A群为研究对象,采用焦点动物取样法和连续记录法观察并记录目标个体的交配行为,以期探讨太行山猕猴的性打搅行为及其性别-年龄组差异。结果表明：(1)太行山猕猴的性打搅行为仅发生在交配期,高峰期为11月;(2)从性打搅的发起者来看,雄性(成年和亚成年)个体占29.1%,雌性(成年和亚成年)个体占14.9%,青少年个体占7.5%,婴幼个体占48.5%;(3)与接触式性打搅相比,雄性(P=0.011)和雌性(P=0.033)的性打搅均以非接触式性打搅为主,青少年个体的非接触式与接触式性打搅之间无显著差异(P=0.334),婴幼猴以接触式性打搅为主(P=0.001);(4)雄性倾向于打搅交配中的雌性(P=0.040),雌性对交配中雄性与雌性...     

蝙蝠体型性别二态性研究现状与展望

动物体型性别二态性(Sexual size dimorphism,SSD)是存在于动物界的普遍现象,作用于某一性别体型的选择压力与作用于另一性别体型的选择压力大小或方向的不同被认为是SSD 产生的原因。伦施法则认为,在雄性体型比雌性体型大的动物类群中,SSD 随体型增大而增大,相反地,在雌性体型比雄性体型大的生物类群中随体型增大而减小。本文从动物体型性别二态性产生的原因及规律方面概述了其研究现状,以及蝙蝠性别二态性研究的进展,并提出关于蝙蝠体型性别二态性尚未解决的科学问题及未来的研究展望。     

太行山猕猴髋骨异速增长和性别判定研究

目的是了解太行山猕猴髋骨性差特征及异速增长模式。太行山猕猴髋骨标本66例(雄21例,雌45例)。选择髋骨4个比值变量。数据分析采用SPSS 20.0。组间均值比较采用单因素方差分析。性别判别分析采用逐步判别法。结果表明:成年太行山猕猴大部分髋骨变量性差显著(P0.05)。根据髋骨变量的异速增长分析可以得到3种模式。回归模型检验有统计学意义(P<0.01)。用少量髋骨变量可以有效地识别性别,性别正确判别率是87.0%。结论:髋骨变量的性差与异速增长模式主要与雌性髋骨变量青春期异速增长有关,髋骨的形态特征是猕猴运动功能与生殖功能交互作用的结果。     

太行山猕猴跗骨形态与两性分化

观察太行山猕猴跗骨形态结构,并初步探讨其两性分化的模式。根据猕猴齿式及骨垢愈合程度选择成年太行山猕猴跗骨标本52例(雄性15例,雌性37例)。选择4块跗骨(舟骨、骰骨和2块楔骨)的5个形态变量进行观察。数据分析采用SPSS 20.0统计软件,组间差异检验采用单因素方差分析。猕猴跗骨5个变量的两侧差异性检验无统计学意义(P>0.05)。跗骨性别之间差异有统计学意义(P<0.05),均为雄性大于雌性;第3楔骨的前关节间宽性差最大(F=85.719,P<0.001);其次是舟骨的前关节宽(F=54.213,P<0.001)和第1楔骨的前关节间长(F=51.865,P<0.001)。猕猴足骨与其他灵长类相比差异具有统计学意义。猕猴跗骨与人类跗骨形状和数量不同,存在着物种、生活习性和运动类型等差异,研究猕猴跗骨的形态结构和性差对生物进化和种间比较有重要意义。     

野生太行山猕猴的社会结构

2009年2月至2010年7月,在河南太行山猕猴国家级自然保护区济源管理局所辖的天坛山管护区,基于个体识别和野外跟踪,观察了一个野生太行山猕猴群(王屋1群, WW-1)的社会结构,采用随机取样法(Ad libitum sampling)记录了该群内成年个体之间、母系单元之间的竞争行为过程,进而依据"David得分法"构建了WW-1群内成年个体及母系单元间的优势等级, 并采用瞬时扫描取样法(Instantaneous andscan sampling)记录了成年个体到达投食区的移动顺序, 分析了平均移动序位与社会顺位的相关性。结果表明: 1)WW-1群体大小为41只个体, 由7个成年雄性和13个成年雌性以及21个未成年猕猴组成, 群内的成年雌性个体分别隶属于3个母系单元; 2)群中成年雄性、成年雌性、亚成年雄性、亚成年雌性、青少年雄性、青少年雌性、婴幼猴雄性、婴幼猴雌性的比例为1∶1.86∶0.29∶0.43∶0.86∶1.29∶0.14∶0, 且未成年个体占全群的51.2%; 3)WW-1群表现出严格的优势等级结构, 成年个体优势顺位由高到低依次是: 豁鼻>次红>白鼻>痞子>红脸>尖脸>小白脸>皱眉>光鼻>长毛>黑颊>小不点>斑点>斑眼>灰头, 母系单元间的优势顺位由高到低依次是红脸单元>长毛单元>斑点单元。研究结果提示, 太行山猕猴的社会结构为多雄多雌型; 成年雄性个体之间优势等级较成年雌性严格, 而成年雌性的社会顺位受所在母系单元社会顺位的影响; WW-1群的α位为成年雄性, 其在获取资源上具有优先性。     

太行山猕猴颅骨变量的异速生长研究

采用定点方法 ,对太行山猕猴 (Macacamulatta)颅骨的 3 2项变量进行了测量、统计和异速生长分析 ,结果表明 ,除颅骨最小宽和冠颞点间宽外 ,其余变量统计值雄性大于雌性 ;颅骨变量的生长存在性别间及部位间的差异。这些差异与雄性和雌性在社群中的不同地位和竞争压力以及取食习性有关。     

太行山猕猴牙齿与颅长的相关性

对太行山猕猴牙齿有关变量做了测量,统计,并就其与颅骨长间的异速生长和相关程度进行了研究。结果表明,太行山猕猴牙齿具有明显的性别差异,雄性牙齿的变异程度在犬齿和中央门齿表现尤为突出。在线性型或面积方面,雄性牙齿的异速生长均快于雌性和雄＋雌,此与其生活史对策相适应,在雄性,雌性或雄＋雌,下颌齿变量与颅骨长的相关程度比上颌更为密切,与有关资料的比较表明,太行山猕猴与金丝猴之间的差异小于与菲氏叶猴之间的差异。     

野生太行山猕猴血液生理生化指标测定与分析

猕猴华北亚种Macaca mulatta tcheliensis为中国特有亚种,目前主要分布于河南、山西两省交界的太行山南端,常被称为太行山猕猴.2009年11月～2010年1月,在太行山猕猴国家级自然保护区济源管理局所辖范围内对野生太行山猕猴进行生存状况调查的同时,对18只雌体、8只雄体的血液生理与生化指标进行了测定,结果表明:1)雌性的淋巴细胞数(P=0.019)、中间细胞数(P=0.017)均显著地高于雄性;而雌性的平均血小板体积则显著低于雄性(P=0.046);2)雌性的血糖(GLU)、总胆固醇(CH)、甘油三酯(TG)、高密度胆固醇(HDL)、低密度胆固醇(LDL)的测定值均略高于雄性,但其差异未达到显著性水平.并与相关研究作了比较分析.     

通过粪球形态快速鉴定马鹿性别的方法与分子鉴定

通过SRY 基因扩增,对76 份野生东北马鹿粪便DNA 进行了性别鉴定,其中雄性49 份,雌性27 份。观察发现粪球形态可分两类:子弹状、枣核状。子弹状呈短粗型,长宽比较小;枣核状呈细长型,长宽比较大。对76 份样品进行分类:子弹状51 份、枣核状25 份。并以样品长、宽平均值的比值(R)为指标快速聚类,并建立了判别方程。统计指出判别结果与实际性别吻合率79.71% ;形态分类与实际性别吻合率90.56% ,即子弹状为雄性,枣核状为雌性。结果提示今后的野外研究可直接利用粪球形态判定粪样性别,长宽比判别方程可作为辅助。     

太行山猕猴寰椎桥的类型与特征

为了确定太行山猕猴(Macaca mulatta)的椎动脉沟上3种骨桥（腹桥、侧桥和背桥）的分布特征，以期理解在人类寰椎上观察到的变异，并推测灵长类动物可能的进化趋势。本文分别测量57例（雄性17例，雌性40例）猕猴寰椎标本（成年骨骼标本）3个寰椎桥的宽度。并采用SPSS统计软件进行数据处理，性别之间差异采用方差分析，观察寰椎桥的出现率、形态特征和组合类型。统计结果显示，猕猴寰椎桥变量性差显著(P<0.05)，猕猴的腹桥和背桥是恒定出现(100%)，侧桥基本恒定，但也有一些缺失个案(90.3%)，表明腹桥和背桥是猕猴稳定的特征；猕猴寰椎桥的主要类型为原始的A型，与主要类型为D型的人科动物发生分离。我们基于以上特征后得出结论，猕猴的3个寰椎桥是一种稳定性状，其出现率明显高于类人猿。     

Multivariate morphometries and sexual dimorphism in the orb-web spider Metellina segmentata (Clerck, 1757) (Araneae, Metidae)

Sexual dimorphism in body size and leg length was investigated in a common orb-weaving spider of Ireland and northern Europe, Metellina segmentata (Clerck, 1757) (Araneae, Metidae). Univariate and multivariate analyses of sexual dimorphism revealed that a greater proportion of between sex variation (sexual dimorphism) was attributable to variation in shape than in size. Significant differences were found in the scores for males and females for the first two principal components. PCI (shape) accounted for 44.25% of the variation and PC2 (size) 13.01% of the variation. Although M. segmentata has been attributed with minimal sexual size dimorphism, females were markedly heavier, possibly a reflection of differential reproductive investment between the sexes, but males had markedly longer legs and broader prosoma. The results are discussed with regard to existing theories of natural and sexual selection, particularly those concerning sexual cannibalism and differential life history traits in males and females. Models that attempt to explain the evolution of sexual size dimorphism in spiders and of the web builders in particular, fail to account for the multivariate nature of dimorphism, especially with respect to shape.     

Sexual Dimorphism of the Jilin Clawed Salamander,Onychodactylus zhangyapingi,(Urodela:Hynobiidae:Onychodactylinae) from Jilin Province,China

Sexual dimorphism in size and shape is common in many organisms, and is a key evolutionary feature. In this study, we analyzed morphometric data of the Jilin clawed salamander Onychodactylus zhangyapingi, an endemic Chinese salamander, to examine sexual size and shape dimorphism. The morphometric data included 14 characteristics of 13 females and 11 males and was analyzed using univariate and multivariate methods. Our results showed that sexual dimorphism occurs not only in body size, but also in body shape. Males have a longer snout-vent length than females, a rarely reported pattern of male-biased sexual size dimorphism. Females have a larger space between the axilla and groin than males, while males have longer and larger tails compared to females. The sexual dimorphism in body size and shape can be explained by existing theories, but there is little data for the mating system, behavior, reproduction, or ecology of O. zhangyapingi, so further studies are required.     

The Role of Sex-specific Plasticity in Shaping Sexual Dimorphism in a Long-lived Vertebrate,the Snapping Turtle <Emphasis Type="Italic">Chelydra serpentina</Emphasis>

Sex-specific plasticity, the differential response that the genome of males and females may have to different environments, is a mechanism that can affect the degree of sexual dimorphism. Two adaptive hypotheses have been proposed to explain how sex-specific plasticity affects the evolution of sexual size dimorphism. The adaptive canalization hypothesis states that the larger sex exhibits lesser plasticity compared to the smaller sex due to strong directional selection for a large body size, which penalizes individuals attaining sub-optimal body sizes. The condition-dependence hypothesis states that the larger sex exhibits greater plasticity than the smaller sex due to strong directional selection for a large body size favoring a greater sensitivity as an opportunistic mechanism for growth enhancement under favorable conditions. While the relationship between sex-specific plasticity and sexual dimorphism has been studied mainly in invertebrates, its role in long-lived vertebrates has received little attention. In this study we tested the predictions derived from these two hypotheses by comparing the plastic responses of body size and shape of males and females of the snapping turtle (Chelydra serpentina) raised under common garden conditions. Body size was plastic, sexually dimorphic, and the plasticity was also sex-specific, with males exhibiting greater body size plasticity relative to females. Because snapping turtle males are larger than females, sexual size dimorphism in this species appears to be driven by an increased plasticity of the larger sex over the smaller sex as predicted by the condition-dependent hypothesis. However, male body size was enhanced under relatively limited resources, in contrast to expectations from this model. Body shape was also plastic and sexually dimorphic, however no sex by environment interaction was found in this case. Instead, plasticity of sexual shape dimorphism seems to evolve in parallel for males and females as both sexes responded similarly to different environments.     

Sexual dimorphism and sexual segregation in foraging strategies of northern giant petrels, Macronectes halli, during incubation

Giant petrels ( Macronectes spp.) are the most sexually dimorphic of all seabirds. We used satellite-tracking and mass change during incubation to investigate the influence of sexual size dimorphism, in terms of the intersexual food competition hypothesis, on foraging and fasting strategies of northern giant petrels at South Georgia. Females foraged at sea whereas males foraged mainly on the South Georgia coast, scavenging on seal and penguin carcasses. Foraging effort (flight speed, distance covered, duration of foraging trips) was greater for females than for males. In contrast, foraging efficiency (proportionate daily mass gain while foraging) was significantly greater for males than for females. Females were significantly closer to the desertion mass threshold than males and could not compensate for the mass loss during the incubation fast while foraging, suggesting greater incubation costs for females than for males. Both sexes regulated the duration and food intake of foraging trips depending on the depletion of the body reserves. In males the total mass gain was best explained by mass at departure and body size. We suggest that sexual segregation of foraging strategies arose from size-related dominance at carcasses, promoting sexual size dimorphism. Our results indicate that sex-specific differences in fasting endurance, contest competition over food and flight metabolic rates are key elements in maintenance of sexual size dimorphism, segregating foraging strategies and presumably reducing competition between sexes.     

Carnivory maintains cranial dimorphism between males and females: Evidence for niche divergence in extant Musteloidea

The evolution and maintenance of sexual dimorphism has long been attributed to sexual selection. Niche divergence, however, serves as an alternative but rarely tested selective pressure also hypothesized to drive phenotypic disparity between males and females. We reconstructed ancestral social systems and diet and used Ornstein–Uhlenbeck (OU) modeling approaches to test whether niche divergence is stronger than sexual selection in driving the evolution of sexual dimorphism in cranial size and bite force across extant Musteloidea. We found that multipeak OU models favored different dietary regimes over social behavior and that the greatest degree of cranial size and bite force dimorphism were found in terrestrial carnivores. Because competition for terrestrial vertebrate prey is greater than other dietary groups, increased cranial size and bite force dimorphism reduces dietary competition between the sexes. In contrast, neither dietary regime nor social system influenced the evolution of sexual dimorphism in cranial shape. Furthermore, we found that the evolution of sexual dimorphism in bite force is influenced by the evolution of sexual dimorphism in cranial size rather than cranial shape. Overall, our results highlight niche divergence as an important mechanism that maintains the evolution of sexual dimorphism in musteloids.     

Sexual size and shape dimorphism and allometric scaling patterns in head traits in the New Zealand common gecko Woodworthia maculatus

Sexual dimorphism in shape and size is widespread across animal taxa and arises when natural or sexual selection operates differently on the sexes. Male and female common geckos (Woodworthia maculatus; formerly Hoplodactylus maculatus) in New Zealand do not appear to experience different viability selection pressure, nor do males appear to be under intense pre-copulatory sexual selection. It was therefore predicted that this species would be sexually monomorphic with regard to body size and the size and shape of the head. In line with the prediction, there was no sexual difference in head width, depth, or length or in lateral head shape. However, contrary to prediction, males had a larger body and lateral head size than females. This study suggests that males, at least on Maud Island, NZ, might be under stronger pre-copulatory sexual selection than previously recognized and thus have evolved larger heads (i.e. lateral head size) for use in male combat for females. Allometric scaling patterns do not differ between the sexes and suggest that head width and depth are under directional selection whereas lateral head size is under stabilizing selection. Diet ecology – an agent of natural selection common to both sexes – is likely largely responsible for the observed patterns of head size and shape and the lack of sexual dimorphism in them.     

Sexual selection on skeletal shape in Carnivora

Lifetime reproductive success of males is often dependent upon the ability to physically compete for mates. However, species variation in social structure leads to differences in the relative importance of intraspecific aggression. Here, we present a large comparative dataset on sexual dimorphism in skeletal shape in Carnivora to test the hypotheses that carnivorans exhibit sexual dimorphism in skeletal anatomy that is reflective of greater specialization for physical aggression in males relative to females and that this dimorphism is associated with the intensity of sexual selection. We tested these hypotheses using a set of functional indices predicted to improve aggressive performance. Our results indicate that skeletal shape dimorphism is widespread within our sample. Functional traits thought to enhance aggressive performance are more pronounced in males. Phylogenetic model selection suggests that the evolution of this dimorphism is driven by sexual selection, with the best‐fitting model indicating greater dimorphism in polygynous versus nonpolygynous species. Skeletal shape dimorphism is correlated with body size dimorphism, a common indicator of the intensity of male–male competition, but not with mean body size. These results represent the first evidence of sexual dimorphism in the primary locomotor system of a large sample of mammals.     

Sexual Dimorphism in the Hindlimb Muscles of the Asiatic Toad(Bufo gargarizans)in Relation to Male Reproductive Success

In many anurans, the forelimb muscles of males are used to grasp females and are often heavier than those of females despite the larger female body size. Such sexual dimorphism in forelimb musculature is thought to result from sexual selection. In addition, the hindlimbs of frogs and toads play an important role in the reproductive process as amplectant males can expel rivals with robust hindlimbs through kicking. In this study, the sexual dimorphism in dry mass for six hindlimb muscles of the Asiatic toad(Bufo gargarizans) was investigated. The results showed that, when controlled for body size, the hindlimb muscle mass of males significantly exceeded that of females for every muscle. The hindlimb muscle mass of amplectant males was also significantly larger than that of non-amplectant males. These results suggested that if strong hindlimb muscles could improve mating success of males, sexual selection would promote the evolution of dimorphism in this character.     

Sexual dimorphism of cusp dimensions in human maxillary molars

Cusp dimensions of human maxillary molars were compared between males and females to determine whether the later-developed, distal cusps displayed greater sexual dimorphism than the earlier-developed, mesial cusps, and whether the later-forming second molar displayed greater sexual dimorphism than the first molar. First and second permanent molar crowns (M1 and M2) were measured indirectly, using dental casts obtained from 117 Japanese (65 males and 52 females). Measurements included maximum mesiodistal and buccolingual crown diameters and the diameters of the four main cusps: the paracone, protocone, metacone, and hypocone. Mean values of crown dimensions were larger in males than in females for both M1 and M2, but the sexual difference in protocone diameter of M1 was not significant. The protocone in M1 showed the least amount of sexual dimorphism, followed by the metacone, hypocone, and paracone, while in M2, the percentage sexual dimorphism corresponded to the order of cusp formation: paracone, protocone, metacone, and hypocone. With the exception of the paracone diameter, M2 showed greater sexual dimorphism than M1. Sexual dimorphism was not always greater in the later-developed, distal cusps of M1 or M2, but the protocone, the most important cusp in terms of occlusal function, displayed the least dimorphism in M1.     

Sexual dimorphism in postcranial skeletal shape suggests male-biased specialization for physical competition in anthropoid primates

Sexual dimorphism often arises as a response to selection on traits that improve a male's ability to physically compete for access to mates. In primates, sexual dimorphism in body mass and canine size is more common in species with intense male–male competition. However, in addition to these traits, other musculoskeletal adaptations may improve male fighting performance. Postcranial traits that increase strength, agility, and maneuverability may also be under selection. To test the hypothesis that males, as compared to females, are more specialized for physical competition in their postcranial anatomy, we compared sex-specific skeletal shape using a set of functional indices predicted to improve fighting performance. Across species, we found significant sexual dimorphism in a subset of these indices, indicating the presence of skeletal shape sexual dimorphism in our sample of anthropoid primates. Mean skeletal shape sexual dimorphism was positively correlated with sexual dimorphism in body size, an indicator of the intensity of male–male competition, even when controlling for both body mass and phylogenetic relatedness. These results suggest that selection on male fighting ability has played a role in the evolution of postcranial sexual dimorphism in primates.