两种山鹪莺的春季换羽及尾羽变化

换羽是鸟类为保证持续生存的重要过程。换羽策略与鸟类进化及对环境的适应紧密相关,研究鸟类换羽特征,对于了解鸟类的分类、系统发育、进化历史及其对环境的适应性等方面都有重要意义。2007年3月至9月,在广东肇庆市江溪村对黄腹山鹪莺(Prinia flaviventris)和纯色山鹪莺(P.inornata)的春季换羽进行了研究。通过设置雾网捕捉2种山鹪莺,对捕捉到的成体进行体重及身体量度的测量;对飞羽及尾羽进行标记:初级飞羽以翅尖的第一枚羽毛标记为"P1",次级飞羽以翅中部最外一枚标记为"S1",向内依次递增标记;尾羽以中央两根最长尾羽为"T1",分别向两侧递增标记为"T2~T5"。采用单因素方差分析(One way ANOVA)对不同月份山鹪莺的体重值进行差异性检验,对体重与月份进行Pearson相关分析,对尾羽的长度和宽度进行Pearson偏相关分析(控制变量:体长)。研究结果表明:1)两种山鹪莺换羽期为3至5月,持续时间约为60 d;2)两种山鹪莺春季换羽仅更换尾羽,换羽模式均为离心型,即中央一对尾羽最先开始替换,然后向两侧由内到外逐次更替;3)两种山鹪莺的尾羽长度和宽度同步变化,但绝大部分山鹪莺非繁殖期尾羽长度与繁殖期尾羽长度之比大于非繁殖期尾羽宽度与繁殖期尾羽宽度之比,即繁殖期尾羽相对较宽;4)两种山鹪莺换羽期间体重大致呈现下降趋势,但变化不显著(P0.05)。推测两种山鹪莺通过增加食物的摄入来抵抗换羽期和繁殖期重叠而导致的能量消耗,这可能与该地区丰富的食物资源有关,并在一定程度上体现了两种山鹪莺换羽策略对环境的适应性。     

褐马鸡雏鸟的换羽研究

对我国特产珍禽——褐马鸡雏鸟的羽毛生长及脱换即“稚后换羽”进行了观察研究。褐马鸡有小翼羽4枚,初级飞羽10枚,次级飞羽13枚,三级飞羽4枚,尾羽22枚。稚后换羽是飞羽和尾羽全部脱换,仅第一枚初级飞羽当年保留。 褐马鸡羽毛的脱换规律是:飞羽是先生长者先脱换;尾羽是由外向内的“向心型”。     

小鹀的白色变异

1985年11月5日,我们在太原汾河畔海拔770米的疏林杂草丛中,捕获一只白色小鹀(Emberiza pusilla)。其白色部位为:尾羽、尾下覆羽、腹羽、初级飞羽、次级飞羽全为白色。背部白色并间杂少许栗褐色羽毛。腰部白色而羽稍具黑褐色纵纹。腹部和背部凡白色羽毛者,     

两种山鹪莺的繁殖参数比较

生活史是鸟类生态学研究的重要内容之一,分析生活史的影响因子对于研究鸟类的生态适应具有重要意义。2007年3~9月,在广东省肇庆市江溪村对黄腹山鹪莺(Prinia flaviventris)和纯色山鹪莺(P.inornata)的繁殖参数进行了比较研究。结果表明:1)除筑巢集中期、窝卵数、巢捕食率和割草毁巢率外,两种山鹪莺各繁殖参数均存在显著性差异;2)黄腹山鹪莺的窝卵数相对较小,但卵重较大,而纯色山鹪莺则相反;3)与体重相似的9种雀形目鸟类相比,两种山鹪莺具有相对较高的年生产力;4)两种山鹪莺在部分繁殖参数上出现了分化,这可能是它们对不同巢捕食风险的响应,黄腹山鹪莺的巢捕食率相对较高,采取低窝卵数和高的卵重,而纯色山鹪莺则为高的窝卵数和低的卵重。     

黄腹山鹪莺育雏行为和雏鸟生长

2007年3~9月,在广东省肇庆市江溪村对黄腹山鹪莺(Prinia flaviventris)的育雏行为和雏鸟生长进行了研究。通过取食行为观察、育雏食物分析和雏鸟身体量度的测量来研究黄腹山鹪莺亲鸟繁殖投资和雏鸟的生长规律。研究期间,利用隐蔽帐观察窗进行行为观察,观察距离在5 m以内;在雏鸟身体上用无味彩笔标号以区别雏鸟个体:10日龄前,标记于雏鸟背部,10~12日龄,标记在雏鸟跗跖处;对部分数据进行双变量相关分析,利用Logistic曲线拟合雏鸟形态增长,并比较每个回归方程斜率间的差异。结果显示:1)黄腹山鹪莺育雏由雌雄共同承担,育雏期(11.9±0.4)d(n=7巢)。幼雏出壳后亲鸟早晚暖雏,第7天起亲鸟白天不再暖雏;2)随雏鸟的生长,喂食次数和食物种类逐渐增加,雏鸟日龄与喂食次数极显著相关(r=0.995,P0.01);3)育雏期雏鸟食物皆为动物性食物,以蜘蛛目物种所占比例最大(40.95%),其他包括幼虫及直翅目、鳞翅目、鞘翅目、蜻蜓目等节肢动物;4)Logistic曲线方程中,体重的生长率常数k值最大,与其他k值之间存在显著性差异(P0.05);5)黄腹山鹪莺体重、体长、尾长、翼长、嘴峰、嘴裂、第三根初级飞羽(简称为P3)、跗跖及爪各参数间的相关系数均为0.9以上(P0.01),参数之间在一定程度上可相互代替;6)黄腹山鹪莺雏鸟的发育遵循最重要的功能优先发育的原则,符合能量分配假说。黄腹山鹪莺喂食次数、雏鸟生长速率(k值)相对较高,可能与当地丰富的食物资源有关,也可能是对巢址环境多变的适应。     

基于野外影像的白尾梢虹雉换羽研究

白尾梢虹雉Lophophorus sclateri是一种狭域分布的高山雉类，尚未开展过换羽研究。2014—2019年，利用红外相机在云南高黎贡山收集了白尾梢虹雉的64张野外独立有效照片和9段视频，发现白尾梢虹雉繁殖不同步，不同巢出雏时间相差可达1个月，5月出雏较多；刚出雏的雏鸟飞羽有明显羽片，6月完成雏后换羽、9月完成稚后换羽；成鸟5月开始更换尾羽，10月更换完毕，从第5枚尾羽开始向两侧更换，兼具向心型和离心型的特点；雄性存在羽毛延迟成熟现象，可用状态信号假说解释。本研究首次报道了野生白尾梢虹雉的换羽特征和雄性个体的羽毛延迟成熟现象，表明红外相机影像可为雉类换羽提供时间和羽毛形态特征数据，这为野生雉类的换羽研究提供了新思路。     

灰头麦鸡生态的初步观察

灰头麦鸡(Microsarcops cinreus)是苏北地区常见的夏候鸟,是典型的旷野鸟类。体型较大,目标明显,为本地猎户狩猎的对象。1970—1984年间,对该鸟进行了观察,研究。现将资料初步综合如下:形态灰头麦鸡的头、颈羽为灰色,略带褐色,前胸羽毛为黑色,形成环状羽斑,腹羽白色,稍带灰色,背羽、小翼羽、初级飞羽黑色,腹面黑褐色,共10枚。初级翼上复羽亦为黑色。次级飞羽和它们的复羽均为白色,共11枚。三级飞羽6枚褐色,三级飞羽的顶端仅有羽干,无羽枝。尾羽12枚,最外侧第1枚尾羽白色,向内第2枚基本白色,顶端稍有褐色羽斑,其余尾羽大部白色,只有极近顶端…     

黄腹山鹪莺和纯色山鹪莺性别的分子鉴定

黄腹山鹪莺Prinia flaviventris和纯色山鹪莺P. inornata共同体现出一个特点,其繁殖期尾羽短于其冬季尾羽,但由于两者的雄雌外形相似而难以野外鉴别.为此,我们采用CHD基因法对二者的性别进行鉴定,并通过解剖对鉴定结果进行验证.结果发现: 1) P2/ P8引物适用于这两个物种的性别鉴定,而2550F/2718R不适用; 2) 分子方法鉴定结果与解剖鉴定结果完全相符; 3) 使用非伤害性取样法拔取的羽毛中提取的DNA具有同样效果.为此,我们认为使用P2/ P8引物对这两个物种进行性别鉴定可靠,具快速鉴定的效果,而2550F/2718R引物可能不适用于莺科鸟类的性别鉴定.     

黄腹山鹪莺的营巢特征

营巢对鸟类的生长繁殖有着重要影响。为此,从2007年3-9月在广东省肇庆江溪村对研究地中的黄腹山鹪莺(Prinia flaviventris)的巢进行标记和测量,并以巢址为中心做5m×5m样方调查,通过主成分分析研究其巢址选择,结果表明:1)黄腹山鹪莺营巢时间始于3月中旬,4月达到高峰,至7月底结束;2)在13种植物上发现44个巢,其中在象草(Pennisetum purpureum)上最多,有27个,其次为加拿大飞蓬(Erigeron canadensis),4个,其他植物皆为1—2个;3)巢皆为不规则的球状巢,巢材除动植物性材料外,均有人工制品;巢内空间与巢整体大小较为一致;4)影响巢址选择的主要因素4种,依次为:距最近水源距离(29.89%)、距最近道路距离(16.45%)、距最近灌木距离(12.92%)、距水面高度(11.69%)。据此认为黄腹山鹪莺的营巢是对草本植物环境的适应,而其尾羽的逆向变化对营巢是有利的,起到增加飞行灵活性和减少筑巢投资的效果。     

朱鹮饲养种群出现淡色型个体

朱鹮(Nipponia nippon)是隶属于鹳形目(Ciconiiformes)鹮科(Threskiornithidae)的中等体型涉禽。成鸟嘴长而下弯,嘴端红色,其余部分黑色;头部裸露皮肤和腿部裸露部分呈红色;虹膜橙红色;繁殖羽灰黑色,非繁殖羽羽轴绯红色,飞羽和尾羽渲染绯红色。幼鸟喙短而稍直,羽色浅灰,初级飞羽先端深灰     

The ‘chaotic’ flight feather moult of the Steppe Buzzard Buteo buteo vulpinus

Steppe Buzzards breed in Eurasia and spend the non-breeding season in Africa. Adults moult some flight feathers during the breeding season and some during the non-breeding season. Moult is arrested during migration. The extent of moult of flight feathers in adults is highly variable between individuals in southern Africa, with the renewal of two primaries, three secondaries and five rectrices as the most frequently encountered pattern. Time spent on the non-breeding grounds in South Africa is too short to allow for a sequential moult. Moult of flight feathers is restricted to the almost synchronous dropping of a number of feathers upon arrival, with few being replaced subsequently. Any of the flight feathers can be replaced in southern Africa, and the pattern of renewal in primaries and secondaries cannot be distinguished from random. Tail feathers are replaced in an alternating (transilient) pattern. Moult in the non-breeding areas may primarily be complementary to moult on the breeding grounds, but these two partial moults per year are insufficient to renew all flight feathers annually. Middle secondaries and central tail feathers are regularly carried over to a third moult, but this is rare for primaries.     

European Swallows Hirundo rustica in Botswana during three non-breeding seasons: the effects of rainfall on moult

van den Brink, B., Bijlsma, R.G. & van der Have, T.M. 2000. European swallows Hirundo rustica in Botswana during three non-breeding seasons: the effects of rainfall on moult. Ostrich: 71 (1): 198–204.

The rate of moult of European Swallows spending the non-breeding season in Botswana was studied during December-January of 1992/93,1993/94 and 1994/95 to investigate the effects of variability in rainfall and roosting habitat availability. In January 1994, 2–3 million European Swallows were counted at a traditional roost along the Boteti River. The rate of moult was relatively slow, about one feather (primary, secondary or tail feather) was replaced every two weeks in both adults and juveniles. The speed of moult in juveniles was generally lower than in adults, in particular of secondaries and tail feathers. Moulting rate of both primaries and tail feathers was lowest in 1994/95 during a period of drought and coincided with the almost complete destruction of roosting habitat. In 1992/93, moulting rate was highest when rainfall was moderate and roosting habitat abundant. Moulting rate was intermediate in 1993/94 when rainfall was frequent but roosting habitat reduced because of the low water level in the Boteti River. The combined effect of reduced food availability during droughts and higher densities and longer foraging flights when roosting habitat is scarce might explain the annual variation in moulting rate. From the second week of January onwards many adults started moulting the outermost tail feather before the penultimate feathers. This phenomenon could indicate the importance of long tail streamers in aerial manoeuvring when foraging during the return migration to the breeding grounds.     

黄腹山鹪莺稳定的配偶关系限制雄性欺骗者

多数鸟类通过性特征限制在同性竞争和配偶选择中的“欺骗者”存在,与此相反,雀形目扇尾莺科部分物种表现出繁殖季节性特征消退的身体特征变化模式.在广州市南沙区通过“目字笼”对黄腹山鹪莺配偶关系稳定性的限制机制进行研究,发现虽然雌性个体到访原配个体和对照个体的次数几乎相同,但是雌性个体对原配雄性的单次选择时间明显长于对照雄性个体,总计选择时间也明显长于对照雄性个体.选择实验过程中,原配雄性的跳动次数明显高于对照个体雄性,以竖尾扑哧和鸣声恐吓等为代表的威慑行为次数也明显高于对照雄性个体.结果说明,雌性更青睐于原配个体,配对时间越长,忠诚度越高,而且原配雄性比入侵雄性个体表现出更高的活跃度和威慑行为.繁殖季节性特征消退的物种可以通过保持稳定的配偶关系以限制“欺骗者”存在.可以推测繁殖的巨大投入和雌性之间的同性竞争可能是产生这种配偶稳定性的主要原因.     

Moult in Black-browed and Grey-headed Albatrosses Diomedea melanophris and D. chrysostoma

We recorded the age of individual wing and tail feathers of Black-browed and Grey-headed Albatrosses Diomedea melanophris and D. chrysostoma of known age and breeding status at Bird Island, South Georgia. Breeders and non-breeders of both species moult their rectrices annually. Non-breeders moult primaries biennially. In the first year of a cycle, the outer three and some inner primaries are moulted descendantly; in the next year the inner primaries are moulted ascendantly, starting from primary seven. There is a general progression to moulting equal numbers of primaries in each half of the cycle by the time breeding starts at about 10 years of age. Grey-headed Albatrosses usually moult fewer primaries than Black-browed Albatrosses, particularly as 3-year-olds, when they undertake substantial plumage change in body moult. Most secondaries in Black-browed Albatrosses have been replaced once by age 4 years. Breeding Black-browed Albatrosses continue the moult pattern established as immatures whether they fail or not, as do failed Grey-headed Albatrosses. Successful Grey-headed Albatrosses, which breed again 16 months later, moult their three innermost primaries after breeding in the remainder of the current year and, after a period when moult is interrupted, renew the remaining primaries the following year. Comparisons between species and between failed and successful birds within species indicate that moult rate is not closely linked to the length of the interval between breeding attempts. Interspecies differences are better explained by breeding latitude, with tropical albatrosses moulting twice as fast as sub-Antarctic species, possibly reflecting food availability outside the breeding season.     

Use of trace elements in feathers of sand martin Riparia riparia for identifying moulting areas

We investigated whether trace elements in tail feathers of an insectivorous and long-distance migratory bird species could be used to identify moulting areas and hence migratory pathways. We analysed tail feathers from birds of different age and sex collected from a range of different breeding sites across Europe. The site of moult had a large effect on elemental composition of feathers of birds, both at the European and African moulting sites. Analysis of feathers of nestlings with known origin suggested that the elemental composition of feathers depended largely upon the micro-geographical location of the colony. The distance between moulting areas could not explain the level of differences in trace elements. Analysis of feathers grown by the same individuals on the African wintering grounds and in the following breeding season in Europe showed a large difference in composition indicating that moulting site affects elemental composition. Tail feathers moulted in winter in Africa by adults breeding in different European regions differed markedly in elemental composition, indicating that they used different moulting areas. Analysis of tail feathers of the same adult individuals in two consecutive years showed that sand martins in their first and second wintering season grew feathers with largely similar elemental composition, although the amounts of several elements in tail feathers of the older birds was lower. There was no difference between the sexes in the elemental composition of their feathers grown in Africa. Investigation of the trace element composition of feathers could be a useful method for studying similarity among groups of individuals in their use of moulting areas.     

Moulting strategies of a long-distance migratory seabird, the Mediterranean Cory's Shearwater Calonectris diomedea diomedea

Seabird moult is poorly understood because most species undergo moult at sea during the non-breeding season. We scored moult of wings, tail and body feathers on 102 Mediterranean Cory's Shearwaters Calonectris diomedea diomedea accidentally caught by longliners throughout the year. Primary renewal was found to be simple and descendant from the most proximal (P1) to the most distal (P10) feather. Secondaries showed a more complex moulting pattern, with three different asynchronous foci: the first starting on the innermost secondaries (S21), the second on the middle secondaries (S5) and the latest on the outermost secondaries (S1). Rectrix moult started at a later stage and was simple and descendant from the most proximal feather (R1) expanding distally. Although a few body feathers can be moulted from prelaying to hatching, moult of ventral and dorsal feathers clearly intensified during chick rearing. Different moulting sequences and uncoupled phenology between primary and secondary renewal suggest that flight efficiency is a strong constraint factor in the evolution of moulting strategies. Moreover, moult of Cory's Shearwaters was synchronous between wings and largely asynchronous between tail halves, with no more than one rectrix moulted at once. This result is probably related to the differential sensitivity of wings and the tail on flight performance, ultimately derived from different aerodynamic functions. Finally, Cory's Shearwater females renewed feathers earlier and faster than males, which may be related to the lower chick attendance of females.     

Biannual complete moult in the Black-chested Prinia Prinia flavicans

The Black-chested Prinia Prinia flavicans shows two distinctive periods each year during which adult birds undergo a complete moult: there is a fast moult (about 67 days) in spring (September-November) involving all birds simultaneously and a slower moult (about 108 days) in autumn (February-June), when about 95% of adults are moulting during April. A biannual complete moult pattern was also shown to occur in individual birds. The pattern of secondary replacement was variable and unusual for a passerine; the majority replaced S8 to S5/S4 descendantly, or had feathers being renewed ascendantly amongst S4-S7 before the ascendant series starting from the outermost secondary reached the middle secondaries. The descendant series tended to be longer during the autumn moult with S4 most frequently being the last to be replaced in autumn, but S5 last in spring. Breeding was erratic during summer in response to rains and sometimes overlapped extensively with moulting, the onset of which was less variably timed. When breeding occurred during the autumn moult, the new plumage was not the usual winter plumage (without the chest-band), but a new summer plumage.     

THE MOULT OF THE BULLFINCH PYRRHULA PYRRHULA

The distribution of feather tracts and their sequence of moult in the Bullfinch is described. The adult post-nuptial moult, which is complete, lasted 10–12 weeks, and the post-juvenile moult, which is partial, 7–9 weeks. Adult moult began with the shedding of the first (innermost) primary and ended with the replacement of the last. Variations in the rate of moult in the flight feathers were mainly achieved, not by changes in the growth rates of individual feathers, but in the number of feathers growing concurrently. The primaries were shed more slowly, and the onset of body moult delayed, in birds which were still feeding late young. In 1962, the onset of moult in the adults was spread over 11 weeks from thc end of July to the beginning of October, and in the two following years over the six weeks, from the end of July to the beginning of September. The onset of moult was delayed by late breeding, which itself occurred in response to a comparative abundance of food in late summer, markedly in 1962. In all years, the first juveniles to moult started at the end of July, and the last, three weeks after the latest adults. Juveniles moulting late in the season retained more juvenile feathers than those moulting earlier. During moult, adult and juvenile Bullfinches produce feathers equivalent to 40% and 33% respectively of their dry weights. In both, for much of the moult, an average of nearly 40 mgm. of feather material—some 0.6% of their dry-weight–is laid down each day. The remiges of the adult comprise only a seventh of the weight of the entire plumage, and it is suggested that their protracted moult results not so much from their energy requirements, as from the need to maintain efficient flight. Variation in the rate of moult in the remiges was much less pronounced than in the body feathers. Bullfinches were less active during moult than at other times of the year. The weights of both adults and juveniles increased during moult. The food during the moult period is described. In all years, most Bullfinches finished moulting just before food became scarce, even though this occurred at different times in different years. In one year, adults moulting latest in the season probably survived less well than those moulting earlier; the same was apparently true of the juveniles in all years. The timing of moult in the Bullfinch, and the factors initiating it, are discussed in relation to the breeding season and foodsupply near Oxford.