鹿类动物被毛形态学研究进展

鹿类动物是现代占优势的两大陆生反刍食草兽类之一,种类多、分布广,栖息于森林、灌丛、沼泽以及北极冻原等各种生境。在长期适应环境变迁的过程中,鹿类动物特殊的被毛形态结构发挥了重要作用。本文综述了鹿类动物被毛形态学在动物的分类、物种鉴定以及保温保护功能形态学等主要方面的研究现状,并结合北京南海子麋鹿苑的麋鹿Elaphurus davidianus冬季被毛形态特征的显微观察予以分析。最后探讨了今后鹿类动物被毛形态学在系统进化与分类、趋同进化、被毛传热性能以及仿生学等方面的研究趋势。     

马鹿东北亚种被毛形态结构的季节性差异

被毛作为哺乳动物特有的组织,具有保护和保温功能,一些季节性换毛动物需要通过更换被毛以适应冬季和夏季的不同环境（王泽长,1963;景松岩和张伟,1993）。因此,研究动物被毛结构与功能的季节性特征,对揭示被毛在物种生存和进化过程中的作用具有重要意义（张伟和徐艳春,2003）。对毛的结构多态性和功能多样性研究是国际毛发形态学研究中的前沿领域（Yalden,1985;Gaudette,1985;syred,1991;甘雅玲和郭中伟,2003;张伟和徐艳春,2003）。以往的毛发形态学研究多限于反映物种的特异性,并应用于分类鉴别方面（朱小曼,1987;张伟,1994;金煜,1995）。在强调毛发结构物种特异性的同时,忽略或淡化了其变异性,更缺少对结构和功能关系的研究。马鹿东北亚种（Cervus elaphus xanthopygus）为季节性换毛动物,绒毛退化,其被毛主要由上毛构成。本选择马鹿东北亚种的冬季和夏季上毛作为研究对象,初步测量了冬季和夏季其臀部、后肢上部、后肢下部及蹄部上毛的形态和微观结构数据,比较其季节性差异和部位差异。     

漠河地区养殖的北极狐冬季被毛性状与保温性能的关系

被毛是哺乳动物最主要的特征之一,其保温功能对动物适应寒冷环境意义重大。为了探讨北极狐(Alopex lagopus)在被毛性状上如何适应寒冷的气候条件,对大兴安岭漠河地区人工养殖北极狐的背中部直针毛、上层绒毛、下层绒毛的长度、毛根细度、毛干细度以及毛密度、单个毛束内的毛数量、毛束密度、复合毛囊最大横切面积、1mm2内复合毛囊最大横切面总面积等14个性状因子进行测量分析。结果表明,北极狐绒毛分为上下两层,下层绒毛的长度、毛根细度和毛干细度均小于上层绒毛,上层绒毛长度与直针毛接近,直针毛长度与上层绒毛、下层绒毛长度均不存在显著相关性;毛密度与毛束密度极度正相关(P0.01),但与毛根细度、毛干细度、单个毛束内的毛数量和1mm2内复合毛囊最大横切面总面积不存在显著相关性,且与复合毛囊最大横切面积的相关性较小;复合毛囊最大横切面积受毛根细度、单个毛束内的毛数量和毛束密度的影响较小。北极狐不是通过降低毛细度的方式来增加毛密度以加强保温功能,而是通过改变被毛在皮肤内的分布格局来增加毛密度,以及将有髓质的绒毛分为上下两层来改变被毛空间结构这两种策略提高被毛内静止空气的量以加强保温功能,进而适应高纬度地区的寒冷环境。     

内蒙古高原西部荒漠区锦鸡儿属(Caragana)优势种的形态适应特征

研究内蒙古高原西部荒漠区锦鸡儿属(Caragana)4种优势植物——柠条锦鸡儿、狭叶锦鸡儿、垫状锦鸡儿和荒漠锦鸡儿的地理分布和叶形态适应特征。通过地理分布和生长发育研究发现：4种锦鸡儿均能在阿拉善荒漠区分布和正常生长,它们能够适应阿拉善荒漠区环境。叶形态结构研究表明：狭叶锦鸡儿叶片呈瓦状,在一定程度上阻碍了水分散失和气体交换,缩小受光面积;垫状锦鸡儿叶片卷成筒状,水分散失和气体交换阻力更大,受光面积更小。柠条锦鸡儿密被伏帖绢毛、狭叶锦鸡儿多被灰白色柔毛、垫状锦鸡儿密被绢毛和荒漠锦鸡儿密被直立绢毛,对光线反射能力强,使叶温降低,减少蒸腾。狭叶锦鸡儿和垫状锦鸡儿具有的长条型叶,4种荒漠区锦鸡儿都具有更小的叶面积、更大的厚度/面积比值、更低的叶片生物量和更小的比叶面积(SLA), 减小了蒸腾和受光面积,提高了荒漠区锦鸡儿的保水能力。荒漠区锦鸡儿这些叶片形态特性有利于适应干旱、高温和强辐射的荒漠区环境。叶绿素含量测定和叶色研究结果表明：4种荒漠区锦鸡儿叶绿素含量低,更低的叶绿素含量和密被灰白色柔毛或绢毛导致叶色浅、反光性能好,有利于减少对辐射的吸收,避免强辐射对植物的伤害,同时也使叶温低,减轻高温伤害和水分蒸发,以适应环境。这是荒漠区锦鸡儿适应高光强、高气温、极干旱的荒漠区环境的特性。垫状锦鸡儿和柠条锦鸡儿叶绿素a/b高也是适应强辐射的特性。比较4种荒漠区锦鸡儿的叶形态特性发现,4种荒漠区锦鸡儿植物对荒漠环境的形态适应方式是不同的。     

植物气孔发育机制研究进展

气孔是分布在植物表面的微孔, 是植物水分散失和与外界环境进行气体交换的门户。经过多年的研究, 气孔发育过程中重要调节因子陆续被发现。气孔复合体结构、发育起始模式以及在双子叶植物和单子叶植物中的分布都有较大差异。该文综述了双子叶植物拟南芥(Arabidopsis thaliana)气孔发育过程中调控因子、细胞极性分裂以及环境因子和植物激素调控气孔发育的机制; 还阐述了单子叶植物玉米(Zea mays)、二穗短柄草(Brachypodium distachyum)和水稻(Oryza sativa)气孔发育方面的研究进展, 并展望了气孔发育的研究方向。     

内蒙古高原西部荒漠区锦鸡儿属(Caragana)优势种的形态适应特征

研究内蒙古高原西部荒漠区锦鸡儿属（Caragana）4种优势植物——柠条锦鸡儿、狭叶锦鸡儿、垫状锦鸡儿和荒漠锦鸡儿的地理分布和叶形态适应特征.通过地理分布和生长发育研究发现：4种锦鸡儿均能在阿拉善荒漠区分布和正常生长,它们能够适应阿拉善荒漠区环境.叶形态结构研究表明：狭叶锦鸡儿叶片呈瓦状,在一定程度上阻碍了水分散失和气体交换,缩小受光面积;垫状锦鸡儿叶片卷成筒状,水分散失和气体交换阻力更大,受光面积更小.柠条锦鸡儿密被伏帖绢毛、狭叶锦鸡儿多被灰白色柔毛、垫状锦鸡儿密被绢毛和荒漠锦鸡儿密被直立绢毛,对光线反射能力强,使叶温降低,减少蒸腾.狭叶锦鸡儿和垫状锦鸡儿具有的长条型叶,4种荒漠区锦鸡儿都具有更小的叶面积、更大的厚度/面积比值、更低的叶片生物量和更小的比叶面积（SLA）,减小了蒸腾和受光面积,提高了荒漠区锦鸡儿的保水能力.荒漠区锦鸡儿这些叶片形态特性有利于适应干旱、高温和强辐射的荒漠区环境.叶绿素含量测定和叶色研究结果表明：4种荒漠区锦鸡儿叶绿素含量低,更低的叶绿素含量和密被灰白色柔毛或绢毛导致叶色浅、反光性能好,有利于减少对辐射的吸收,避免强辐射对植物的伤害,同时也使叶温低,减轻高温伤害和水分蒸发,以适应环境.这是荒漠区锦鸡儿适应高光强、高气温、极干旱的荒漠区环境的特性.垫状锦鸡儿和柠条锦鸡儿叶绿素a/b高也是适应强辐射的特性.比较4种荒漠区锦鸡儿的叶形态特性发现,4种荒漠区锦鸡儿植物对荒漠环境的形态适应方式是不同的.     

野兔与家兔

野兔一般指兔属、粗毛兔属和岩兔属中的部分种类。野兔能适应许多不同的环境,只要有足够的青草,就可以在从极地到赤道的各种地方生存。一般生活在热带的野兔毛比较短,耳朵更大：寒带生活的野兔毛长而厚密,耳朵比较短。因为一般兔子的被毛较浓密,汗腺很少,故散热的主要途径是呼吸。当外界温度升高时,兔子通过增加呼吸次数,呼出气体蒸发水分散热,同时,长而大的耳朵也能起到协助散热的作用。兔子的排尿机制属浓缩性,对水分的需求比其他动物少。有些野免只靠草上的露水就可以生存,故很少看到兔子到河边喝水。     

黑龙江省黄鼬冬季毛被分层结构及保温功能

为了解黄鼬毛被的保温机制,选取黑龙江省通河林区黄鼬东北亚种(Mustela sibirica manchurica)冬季皮张,通过观测雄性5个部位和雌性4个部位毛被的分层结构,并结合热物性测试比对,发现了毛被的各层结构具有不同的保温隔热功能且存在部位差异。结果表明:1)毛被由外及里表现出4层结构,各层毛被厚度分别为:(12.7±3.0)mm、(6.0±1.8)mm、(5.5±2.2)mm和(1.4±0.5)mm。2)4层毛被的颜色、结构及保温机制依次为:最外层毛被棕黄色或金黄色,仅由2种类型被毛构成,耐磨损能力较强,保护下层毛被,阻挡冷空气侵入并降低毛被的热量散失;第二层毛被淡黄色,此层开始均由4种类型被毛构成,毛干细度较小,被毛间形成细小空隙,滞留大量静止空气,增强保温功能;第三层毛被灰色或灰白色,4种类型被毛的毛干更细,绒针毛和绒毛弯曲程度更大,使被毛间滞留静止空气的能力更强、更稳定,保温能力更强;最内层毛被为白色,为近毛根处,4种类型被毛均较直,便于热量传递。3)4层毛被的对整体的贡献率分别为:16.11%、27.40%、44.40%和12.09%。4)背面毛被较腹面的颜色深,厚度大,保温能力强;沿吻端至尾基的体轴方向毛被厚度增加,保温性增强。5)雄性毛被较雌性的厚度大,保温能力强。以上,反映了黄鼬冬季多部位毛被由表及里不同的空间布局及各层毛呈现的不同的形态结构,从整体上兼顾保护、保温、散热等多种功能,以适应当地的寒冷环境。     

仿生技术在合成农药中的应用进展

仿生学是近年来发展起来的工程技术与生物科学相结合的交叉学科.人们发现,一些关于植物和动物的相类似的功能,实际上是超越了人类自身在此方面的技术设计方案的.植物、动物和微生物在几百万年的自然进化当中不仅完全适应了自然,而且其适应程度接近完美.仿生学试图在技术方面模仿动物和植物在自然中的功能,而仿生技术在生物学和技术之间架起了一座桥梁,并且对解决技术难题提供了帮助.通过再现生物学的原理,人类不仅找到了技术上的解决方案,而且同时该方案也完全适应了自然的需要.仿生学的目的就是分析生物过程和结构,并把得到的分析结果用于未来的设计.     

动物形态学发展趋势及我国近期的发展战略

动物形态学是动物科学的基础学科,通过对动物体的结构及其功能、适应的研究,认识生物多样性以及起源和进化的历史和动因。形态学的研究也为分类学、生理学以及医学、仿生学等应用生物学提供了重要的基础资料。     

室内养殖雌性松鼠秋季换毛期被毛长度和保温性能变化

为了解松鼠东北亚种(Sciurus vulgaris manchuricus)秋季换毛期的被毛性状与保温性能变化的关系,选取2011年9月25日至12月15日期间采集的在哈尔滨室内人工养殖的27张雌性松鼠东北亚种生皮为材料,对背臀部毛皮样本进行传热性能测试,同时对该部位的披针毛、绒毛的长度和毛根出现无髓样本比例进行测量计算。结果表明:1)随着秋季换毛期的时间后移,新生冬毛长度不断增加,毛皮传热系数不断减小。当被毛生长结束时,保温性能达到恒定。2)披针毛长度、绒毛长度、披针毛毛根无髓段比例、绒毛毛根无髓段比例这4个被毛性状因子两两呈极显著正相关(P<0.01),且此4个性状因子皆与毛皮传热系数呈极显著负相关(P<0.01)。以上反映了在气温渐冷的秋季换毛期每时间阶段被毛的长度、生长程度、保温性能的具体变化及相互关系。     

Convective and radiative components of wind chill in sheep: Estimation from meteorological records

Wind chill is defined as the excess of sensible heat loss over what would occur at zero wind speed with other conditions unchanged. Wind chill can be broken down into a part that is determined by air temperature and a radiative part that comprises wind-dependent effects on additional long-wave radiative exchange and on solar radiation (by reducing solar warming). Radiative exchange and gain from solar radiation are affected by changes that are produced by wind in both surface and fleece insulations. Coefficients are derived for (a) converting the components of sensible heat exchange (air-temperature-dependent including both convective and associated long-wave radiative, additional long-wave radiative and solar) into the components of the total heat loss that are associated with wind and (b) for calculating equivalent air temperature changes. The coefficients contain terms only in wind speed, wetting of the fleece and fleece depth; these determine the external insulation.Calculation from standard meteorological records, using Plymouth and Aberdeen in 1973 as examples, indicate that in April–September 1973 at Plymouth reduction in effective solar warming constituted 28% of the 24-h total wind chill, and 7% in the other months of the year combined; at Aberdeen the corresponding percentages were 25% and 6%. Mean hour-of-day estimates for the months of April and October showed that at midday reduction in solar warming due to wind rose to the order of half the air-temperature-dependent component of wind chill, with a much smaller effect in January. For about six hours at midday in July reduction in solar warming due to wind was similar in magnitude to the air-temperature-dependent component.It is concluded that realistic estimates of wind chill cannot be obtained unless the effect of solar radiation is taken into account. Failure to include solar radiation results not only in omitting solar warming but also in omitting the effects of wind in reducing that warming.The exchange of sensible (non-evaporative) heat loss between a homeothermic animal and its environment can be divided into two parts: one part is due to the temperature difference between the animal and the surrounding air, and the other part is due to additional long-wave radiative exchange between animal and environment and to solar radiation. Both parts of the heat exchange are determined in magnitude by the animal's thermal insulation, which is itself affected by windspeed and wetting. Wind diminishes as animal's external insulation, so increasing heat loss under all conditions when the air temperature is lower than the animal's surface temperature: this effect is termed wind chill. Wind chill has previously been investigated more commonly in relation to man (Burton an Edholm, 1955; Smithson and Baldwin, 1978; Mumford, 1979; Baldwin and Smithson, 1979). This paper is concerned with the separate contributions to wind chill calculated for sheep that can be associated with convective and radiative heat exchanges.     

Under pressure: Effects of instrumentation methods on fur seal pelt function

Tracking marine mammals with electronic devices enables researchers to better understand animal movements and at-sea behavior. For pinnipeds, instruments are typically glued to the animal's hair, either directly to the pelage or via a fabric patch. These instruments are retrieved by cutting the pelage or cutting through the patch. The impact of these modifications to the pelage is presumed to be minimal and short-lived, but this has never been explicitly investigated. This study examined effects of instrument attachment on northern fur seal pelts. To assess thermal consequences of instrumentation, we determined thermal resistance of pelts in water for instruments glued directly to the pelage or with a neoprene base. For each attachment method, we measured the pelt unmodified, with instrument attached, and with instrument removed. Using a hyperbaric chamber, we measured the extent to which water could penetrate the pelt's air layer during diving. Removing the tag by cutting the pelage reduced thermal function of the pelt in water and allowed more air to escape under pressure. In contrast, a neoprene patch better maintained the insulation in water and reduced air loss under pressure. Our results suggest the use of neoprene may reduce negative consequences of instrumentation in fur seals.     

通河林区黄鼬(Mustela sibirica)冬季被毛形态结构的功能适应性

被毛在哺乳动物适应性进化过程中执行保温和保护两个重要功能,其形态结构上存在的功能适应性特征因所处的部位不同而表现出适应性分化现象,由动物体躯干至四肢末端呈显著的梯度变化。以黑龙江省通河林区黄鼬东北亚种(Mustela sibirica manchurica)冬季雌雄成体各10只完整毛皮对象,研究了背中部、腹中部和后肢下部3个部位的直针毛、披针毛、绒针毛、绒毛,以及后趾部硬毛的被毛性状因子,统计分析表明:通河林区黄鼬相同身体部位4种类型毛的长度和细度指标均为直针毛披针毛绒针毛绒毛,相同部位4种类型毛长度的相关性极显著,直针毛细度与披针毛细度相关性极显著(P0.01),绒针毛细度与绒毛细度相关性极显著(P0.01),这种特征使得被毛在整体结构上为实施保温和保护功能奠定基础;同时,黄鼬被毛各性状的保温功能从背部向后趾部呈递减趋势,而保护功能则呈现递增趋势,被毛形态结构性状上的分化与动物机体异温性充分结合,对于黄鼬适应寒冷的森林生态环境具有重要意义。     

The calculation from weather records of the requirement for clothing insulation

Standard meteorological measurements of dry bulb temperature, wind speed, sunshine, cloud cover and rainfall are used to calculate the clothing insulation required by man for thermal comfort under given weather conditions. The calculation is based on earlier work on the effect of weather on sensible (non-evaporative) heat loss from sheep, which used the relation between heat flow, thermal insulation and the difference between body and environmental temperatures.Clothing insulation for man is estimated in two ways: as clothing (I_c) that is impervious to the effects of wind and rain; and as the equivalent depth of sheep fleece (f_m), which is not impervious. This allows the assessment of wind chill for a range of clothing of varied penetration by wind instead of for only one type of garment.Results are given as daily means calculated from hourly measurements throughout 1973 for Plymouth (on the south coast of Britain) and Aberdeen (on the far northeast coast of Britain). Wind chill is estimated both by its effect on f_m requirement and by the fall in air temperature that would be needed to produce under still-air conditions the same demand for f_m that occurs in the actual environment. The monthly mean f_m requirement is reduced by about 40% when the effect of wind is removed. When wind chill is estimated as an equivalent fall in air temperature it approximates to 1 K per knot wind speed measured at the standard meteorological height of 10 m.     

Seasonal changes and wind dependence of thermal conductance in dorsal fur from two small mammal species (Peromyscus leucopus and Microtus pennsylvanicus)

(1) We measured the thermal conductance of dorsal pelage from meadow voles (Microtus pennsylvanicus) and white-footed mice (Peromyscus leucopus) during summer and winter.

(2) Thermal conductance was lower in the winter pelage of both species, but the seasonal change was greater in meadow voles.

(3) The form of wind speed dependence was determined by fitting a nonlinear curve of the form a+bu^c to data recorded at five wind speeds. The most appropriate exponent c was between 0.908 and 0.987, depending on species and season. These values are common and suggest that thermal and dynamic forces are important.

Thermal physiological ecology of Colias butterflies in flight

Summary As a comparison to the many studies of larger flying insects, we carried out an initial study of heat balance and thermal dependence of flight of a small butterfly (Colias) in a wind tunnel and in the wild.Unlike many larger, or facultatively endothermic insects, Colias do not regulate heat loss by altering hemolymph circulation between thorax and abdomen as a function of body temperature. During flight, thermal excess of the abdomen above ambient temperature is weakly but consistently coupled to that of the thorax. Total heat loss is best expressed as the sum of heat loss from the head and thorex combined plus heat loss from the abdomen because the whole body is not isothermal. Convective cooling is a simple linear function of the square root of air speed from 0.2 to 2.0 m/s in the wind tunnel. Solar heat flux is the main source of heat gain in flight, just as it is the exclusive source for warmup at rest. The balance of heat gain from sunlight versus heat loss from convection and radiation does not appear to change by more than a few percent between the wings-closed basking posture and the variable opening of wings in flight, although several aspects require further study. Heat generation by action of the flight muscles is small (on the order of 100 m W/g tissue) compared to values reported for other strongly flying insects. Colias appears to have only very limited capacity to modulate flight performance. Wing beat frequency varies from 12–19 Hz depending on body mass, air speed, and thoracic temperature. At suboptimal flight temperatures, wing beat frequency increases significantly with thoracic temperature and body mass but is independent of air speed. Within the reported thermal optimum of 35–39°C, wing beat frequency is negatively dependent on air speed at values above 1.5 m/s, but independent of mass and body temperature. Flight preference of butterflies in the wind tunnel is for air speeds of 0.5–1.5 m/s, and no flight occurs at or above 2.5 m/s. Voluntary flight initiation in the wild occurs only at air speeds 1.4 m/s.In the field, Colias fly just above the vegetation at body temperatures of 1–2°C greater than when basking at the top of the vegetation. These measurements are consistent with our findings on low heat gain from muscular activity during flight. Basking temperatures of butterflies sheltered from the wind within the vegetation were 1–2°C greater than flight temperatures at vegetation height.     

Estimating metabolic heat loss in birds and mammals by combining infrared thermography with biophysical modelling

Infrared thermography (IRT) is a technique that determines surface temperature based on physical laws of radiative transfer. Thermal imaging cameras have been used since the 1960s to determine the surface temperature patterns of a wide range of birds and mammals and how species regulate their surface temperature in response to different environmental conditions. As a large proportion of metabolic energy is transferred from the body to the environment as heat, biophysical models have been formulated to determine metabolic heat loss. These models are based on heat transfer equations for radiation, convection, conduction and evaporation and therefore surface temperature recorded by IRT can be used to calculate heat loss from different body regions. This approach has successfully demonstrated that in birds and mammals heat loss is regulated from poorly insulated regions of the body which are seen to be thermal windows for the dissipation of body heat. Rather than absolute measurement of metabolic heat loss, IRT and biophysical models have been most useful in estimating the relative heat loss from different body regions. Further calibration studies will improve the accuracy of models but the strength of this approach is that it is a non-invasive method of measuring the relative energy cost of an animal in response to different environments, behaviours and physiological states. It is likely that the increasing availability and portability of thermal imaging systems will lead to many new insights into the thermal physiology of endotherms.