黑麂食物组成及其季节变化

2002年12月至2003年11月在浙江省九龙山和古田山自然保护区,分季节采集黑麂 (Muntiacus crinifrons)粪便,采用粪便显微组织学分析方法为主,辅以野外观察,对其食性进行研究。结果表明 :黑麂食物包括29科43种(属)植物。食物中的植物类型包括乔木、灌木、藤本、非禾草类草本和禾草类草本五种类型;灌木是黑麂全年的主要食物,它在食物组成所占的比例为55.4%;三尖杉 (Cephalotaxus fortunei)、光叶菝葜(Smilax glabra)、矩圆叶鼠刺(Itea chinensis var. oblonga)、南五味子(Kadsura longipedunculata)和络石(Trachelospermum jasminoides)为黑麂四季都取食且在食物组成中所占比例较高的植物,分别为 17%、16.5%、9%、8.7%和 4.3%,是黑麂取食的主要食物。方差分析表明 :黑麂的主要食物及其主要种类都存在季节变化。夏秋季节,乔木植物在黑麂食物组成的比例低于冬春季节 ,而藤本植物和草本植物则相反,灌木植物变化较小;黑麂取食的五种主要食物中,其中三尖杉和光叶菝葜季节变化极显著,在冬季,三尖杉和光叶菝葜在食物组成比例中最高,达到 21.7%和 24 .3%;在夏季,它们在食物组成比例中下降到最低点,分别是 11.3%和 11.6%,但相对密度(RD)值仍保持最高序位 ;矩圆叶鼠刺和南五味子变化较平缓 ,基本变化趋势相同:冬春季节比例较高,夏秋季节比例有所下降;络石季节变化不明显;由于黑麂的食物组成中禾草类占的比例很小,说明黑麂更接近嫩食者     

黑麂（Muntiacus crinifrons）3个种群的遗传多样性

黑麂,为我国特有动物,被公认为目前世界上最珍稀的鹿科动物之一.为了更好地保护黑麂这一珍稀的濒危野生动物,基于黑麂线粒体控制区序列对遂昌分布中心的3个黑麂种群的遗传多样性和基因流进行了研究.结果显示,3个种群的36个个体中有13个变异位点,占分析序列长度的2.71%,且这13个变异位点皆为碱基置换,并未出现碱基插入或缺失的现象,并由此定义了12个单倍型.遗传多样性检测结果显示遂昌种群具有最高的遗传多样性,应予以优先保护.从Tajima′s D和Fu and Li′s D值的估算结果来看,这3个黑麂种群相对于中性进化的歧异度并没有明显的偏离(P＞0.1),没有明显的证据显示这3个黑麂种群间存在很强的平衡选择.3个种群间基因流 Nm均大于1,这3个黑麂种群间存在着较为丰富的基因流.3个黑麂种群单倍型间的序列差异为0.009,这表明这3个黑麂种群的单倍型未出现分化.     

基于红外相机技术和MaxEnt模型的黑麂(Muntiacus crinifrons)活动节律分析和潜在适生区预测

黑麂是中国特有的濒危鹿科动物,分布于浙闽赣皖四省的部分山地丘陵。为明确黑麂的活动节律及适宜环境温度,探讨四省区域的潜在分布区情况,2018年1月至2019年1月,在遂昌牛头山林场内布设57台Ltlacorn红外相机,对黑麂及其同域物种进行研究。监测期间红外相机共有效监测到黑麂26次,相对多度指数为1.79。根据监测到黑麂位点与文献记录,共确定黑麂出现位点16个。根据黑麂栖息地特征选择6个生境因子为预测背景,利用MaxEnt模型预测黑麂在浙闽赣皖四省的潜在适生区。模型预测结果准确性较高（AUC=0.976）。结果表明：（1）黑麂年活动高峰季节为夏季,日活动高峰为7：00-9：00和16：00-18：00;（2）温度是影响黑麂活动的重要因素,其活动最适宜温度范围为18-28℃;（3）黑麂潜在适生区总面积约为25980.62 km²,占四省总面积的4.87%;（4）黑麂潜在适生区分为浙赣皖潜在分布区、浙赣潜在分布区、洞宫山潜在分布区和括苍山潜在分布区4个区域。建议（1）加强潜在分布区内种群资源的调查;（2）识别并建立各适宜生境之间的生态廊道;（3）建立黑麂保护网络。     

黑麂皖-浙分布中心种群的遗传多样性

本文基于黑麂线粒体控制区序列对皖浙分布中心的4个黑麂种群的遗传多样性和基因流进行了研究。结果显示:4个种群的33个个体中有14个变异位点,占分析序列长度的2·91 %,并由此定义了12个单倍型;遗传多样性检测结果显示4个种群中开化种群具有最高的遗传多样性,应予以优先保护;4个种群间尚存在着一定的基因流,但存在可能由于遗传漂变而产生分化的危险。从Tajima’s D和Fu and Li’s D值的估算结果来看,这4个黑麂种群相对于中性进化的歧异度并没有明显的偏离,具有较为稳定的种群结构(P>0·1),没有明显的证据显示这4个黑麂种群间存在很强的平衡选择。     

黑老虎叶总黄酮提取工艺及其抗氧化活性研究

为探讨超声波辅助提取黑老虎叶总黄酮的最佳提取工艺条件及其抗氧化活性,该文以黑老虎叶为研究对象,采用超声波提取法提取黑老虎叶总黄酮,通过单因素试验研究提取时间、乙醇浓度、提取温度、料液比对黑老虎叶总黄酮提取率的影响在单因素试验的基础上,采用正交试验优化其提取工艺条件,测试了最优条件下提取的黑老虎叶总黄酮对DPPH自由基、·OH自由基及超氧阴离子的清除能力。结果表明:黑老虎叶总黄酮超声辅助提取最佳提取条件为提取时间35 min、乙醇浓度80%、提取温度50℃、料液比1:20g·mL^-1最佳条件下提取率为4.83%。抗氧化活性测试结果显示,黑老虎叶总黄酮表现出较好的清除DPPH自由基、·OH自由基及超氧阴离子能力,其抗氧化能力为清除DPPH自由基能力>清除超氧阴离子能力>清除·OH自由基能力。在浓度为0.8 mg·mL^-1时,黑老虎叶总黄酮清除DPPH自由基、·OH自由基及超氧阴离子的能力相当于同浓度下Vc的97.6%、82.1%、95.5%,黑老虎叶总黄酮是天然抗氧化剂的良好来源。上述结果为黑老虎叶活性成分的提取及开发利用提供了理论基...     

浙江清凉峰国家级自然保护区黑麂和小麂潜在适宜栖息地预测及重叠性分析

对保护区内的关键种开展保护工作时,其同域分布相似种的保护研究也具有重要价值。较大地理尺度上看,黑麂的分布区被小麂完全覆盖,如能掌握二者适宜栖息地的重叠状况,揭示其共存机制,将有助于保护策略的制定和整合管理。2017—2020年在浙江清凉峰国家级自然保护区利用红外相机技术分别获得黑麂和小麂的分布位点38个和101个,结合8个环境因子,采用MaxEnt模型对研究区域内黑麂和小麂的潜在适宜栖息地进行了预测和重叠性分析。结果表明：(1)黑麂和小麂潜在适宜栖息地主要位于龙塘山区域西南部,千顷塘区域中部和顺溪坞区域西北部,以及千顷塘区域与龙塘山区域间的山脉和顺溪坞南部山区,二者的潜在适宜栖息地面积分别586.66 km²和661.93 km²,分别占研究区域的36.67%和41.37%。(2)黑麂和小麂的生态重叠指数较高,其D值和I值分别为0.82和0.97,它们的总适宜栖息地重叠面积为435.39 km²,分别占黑麂和小麂总适宜栖息地面积的72.22%、65.78%。(3)黑麂和小麂对环境因子的选择相似,黑麂主要选择海拔较高、离水...     

超累积植物与高生物量植物提取镉效率的比较

利用植物修复污染的土壤已受到广泛的关注.采用土壤盆栽试验,比较了超累积植物遏蓝菜与3种高生物量植物印度芥菜、烟草和向日葵对长期施用含镉有机、无机肥料污染的土壤(总Cd,2.87mg·kg-1)的提取效率.研究结果表明,遏蓝菜富集镉的能力明显高于其他3种植物,其地上部镉含量可达43.7mg·kg-1,分别是烟草、印度芥菜和向日葵(叶)的10、27和56倍;而地上部生物量最高的植物烟草,其生物量干重为24.8g· pot-1,分别是遏蓝菜、印度芥菜、向日葵的35倍、3倍、2倍.4种植物提取镉最多的是烟草,每盆可以提取117μg,遏蓝菜和印度芥菜提取镉量分别为35μg·pot-1和30μg·pot-1,向日葵提取量最少,每盆仅为10μg左右.植物对土壤中镉的提取效率分别为:烟草 1%,遏蓝菜0.6%,印度芥菜 0.5%,向日葵0.08%.4种植物种植后,土壤总镉和有效态镉含量没有显著的变化.     

养分供给对黑青杨等杨树生长动态及养分分配的影响

探究不同养分添加对黑青杨、小黑杨和大青杨幼苗生长和养分分配的影响,旨在揭示3种杨树品种对养分的需求利用规律,为苗圃培育杨树苗木提供参考。以黑青杨、小黑杨和大青杨为材料,采用3因素3水平(N:1.5、3、6 g·株-1;P:0.75、1.5、3 g·株-1;K:0.5、1、2 g·株-1)L9(34)正交试验设计,以不施肥为对照,研究不同养分供给水平对不同杨树生长动态变化及养分分配的影响。结果表明:(1)不同养分供给对黑青杨、小黑杨和大青杨苗高、地径生长量在7月中旬开始影响差异显著。3个品种苗高、地径生长指数均在氮、磷、钾1水平时最大。黑青杨氮、磷、钾分别选择3、1、2水平时其生物量最大,小黑杨氮、磷、钾分别选择2、1、1水平时其生物量最大,大青杨氮、磷、钾均选择1水平时其生物量最大。氮、磷、钾对黑青杨和小黑杨生长指标影响排序为N大于P和K,而对大青杨生长指标影响排序为K大于N和P。(2)黑青杨、小黑杨和大青杨在根、茎和叶中氮、磷、钾积累量大小均为N大于P和K,3个品种各器官内氮的积累量都大于磷和钾的积累量。在3个杨树品种中,各器官3种养分积累量显著不同,其中3个品种的氮积累量分配比大小依次为茎、叶、根,黑青杨和小黑杨的磷积累量分配比大小依次为茎、叶、根,大青杨积累量分配比大小依次为根、茎、叶,黑青杨和大青杨钾积累量的分配比大小依次为根、茎、叶,而小黑杨钾积累量的分配比大小依次为根、茎、叶。(3)经过对各指标综合分析,评价得出氮、磷、钾配比N1P1K1为大青杨、黑青杨、小黑杨最佳施肥方案,即氮肥1.5 g·株-1,磷肥0.75 g·株-1,钾肥0.5 g·株-1。     

黑麂线粒体基因组序列分析

采用PCR产物直接测序方法测定了黑麂线粒体基因组全序列 ,初步分析了其基因组特点并定位了各基因的位置 .结果显示 :黑麂的线粒体基因组全序列长度为 1 6 35 7bp ,可编码 2 2种tRNA、2种rRNA、1 3种蛋白质 ,碱基组成及基因位置与小麂、赤麂和其它哺乳类动物的线粒体基因组相似 ;模拟电子酶切图谱与先前的报道基本一致 ;基于细胞色素b的全基因序列 ,分别以最大简约法、N J法、最大似然数法与其它 1 4种鹿类动物的相应序列进行了聚类分析 ,构建出相似的系统进化树 :初步确定了麂亚科动物在鹿科中处于与鹿亚科、北美鹿亚科并列的进化地位 .在此基础上 ,进一步以黑麂、赤麂、小麂的线粒体编码RNA和编码蛋白质的基因序列构建系统进化树 ,分析了三者的亲缘关系 .结果表明 :黑麂和赤麂亲缘关系较近 ,是较新的物种 ,而小麂是较为原始的物种     

毛冠鹿与3种麂属动物的线粒体细胞色素b 的系统进化分析

采用PCR直接测序法,获得毛冠鹿、小鹿、赤麂和黑麂等4种麂亚科动物线粒体细胞色素b核酸序列366bp,麂属动物之间的序列差异为3.5%-4.6%,毛冠鹿属与麂属之间的序列差异为9.29%-10.11%,麂属3种动物分歧时间约为142-184万年,毛冠鹿与麂属动物的分歧时间约为370万年。结合鹿科其余3亚科动物的同源序列,用MEGA软件的Neighbor-Joining Method(NJ法）和最大简约法构建系统进化树。结果表明,小麂、赤麂与黑麂组成一个单系群,毛冠鹿细胞色素b核苷酸序列与麂属的分化程度似已达到属间水平。     

Reproductive biology of the smooth butterfly ray Gymnura micrura

This study provides the first detailed information on the reproductive biology of the smooth butterfly ray Gymnura micrura. A total of 905 individuals were sampled, 377 of which were used for the reproductive study. Juveniles accounted for 75% of the sample, but all life cycle stages were present in the study area. The disc width at which 50% were mature (W(D50) )was estimated at 269 and 405 mm for males and females, respectively. The W(D50V) (based on the onset of vitellogenesis) was estimated at 359 mm. Uterine fecundity (mean ±s.d. = 3·8 ± 1·3; range: 1-6) was positively correlated with female size. A 3564% gain in mean wet mass was observed from egg to full-term embryo in utero. Size at birth ranged from 135 to 175 mm W(D) (19·5 to 55·0 g), with a mean of 165·1 mm W(D) (43·3 g). The embryo sex ratio was not significantly different from 1:1. The ovaries of pregnant females were undergoing vitellogenesis during gestation, with females ready to ovulate soon after parturition. Gymnura micrura may have an asynchronous reproductive cycle, with females reproducing continuously throughout the year.     

Age and growth of Neotrygon picta, Neotrygon annotata and Neotrygon kuhlii from north-east Australia, with notes on their reproductive biology

Vertebral band formations were used to define age and growth in three Neotrygon species caught regularly as by-catch in prawn trawl fisheries in north-east Australia. Centrum edge and marginal increment ratio analyses were used to validate annual band formations. Age estimates ranged from 1 to 18 years, with the von Bertalanffy growth function considered to have the best fit to Neotrygon picta (males, W(D∞) = 271 mm, k = 0·12; females, W(D∞) = 360·5 mm, k = 0·08) and Neotrygon kuhlii (males, W(D∞) = 438·6 mm, k = 0·08; females, W(D∞) = 440·6 mm, k = 0·08) disc width (W(D))-at-age data. The Gompertz growth function had the best fit to Neotrygon annotata W(D)-at-age data (males, W(D∞) = 230·4 mm, k = 0·20; females, W(D∞) = 265·5 mm, k = 0·31). Age at sexual maturity ranged from 3 to 6 years, with N. picta having the smallest size at birth (100 mm W(D)), smallest W(D) at 50% maturity (W(D50): male, 172 mm, female, 180·7 mm) and lowest age at sexual maturity (3-4 years). This study helps redefine and improve the accuracy of fisheries-based risk assessments for these small species with relatively conservative life-history variables.     

Trophic ecology of Atlantic bluefin tuna Thunnus thynnus larvae

Feeding intensity, diet composition, selectivity, energy ingestion and dietary niche breadth of larval Atlantic bluefin tuna Thunnus thynnus were studied on the eastern (Mediterranean) spawning grounds of the species. Larval T. thynnus were collected in the Balearic Archipelago (north-west Mediterranean Sea) during 2004 and 2005 using surveys specific for larval scombrids. Larvae between 2·6 and 8·7 mm standard length (L(S) ) are diurnal feeders, and 94% of the guts collected during daylight hours were full. The mean ±s.d. number of prey per gut was 7·1 ± 5·7, with mean ±s.d. ranging from 3·0 ± 1·6 in the smallest T. thynnus larvae to 11·1 ± 5·8 in 5·0-6·0 mm L(S) larvae. Up to 21 prey were found in a single larval gut (5·0-6·0 mm L(S) ) at the end of the day. Larvae progressively selected larger prey and exhibited increased carbon content concurrent with preflexion development of feeding and locomotory structures. Larvae of 5·0-6·0 mm L(S) exhibited positive selection of cladocerans over other prey (Chesson's index), whereas copepod nauplii dominated the diets of earlier stages. The dietary niche breadth measured increased initially but decreased at c. 5·5 mm L(S) . Appendicularians were found in the diet of larger larval sizes, but no piscivory was observed. Results are discussed in light of the sparse existing data for larval T. thynnus and other larval tuna species.     

Computed tomography of the thorax in rabbits: a prospective study in ten clinically healthy New Zealand White rabbits

Background

Literature investigating the normal cross-sectional anatomy of rabbits with computed tomography (CT) is sparse and incomplete. The purpose of the present study was to investigate the normal thoracic structures, in particular the cranial thorax, with CT angiography in 10 clinically healthy New Zealand White (NZW) rabbits.

Results

Absolute and relative measurements of the trachea, heart, thoracic caudal vena cava and aorta, right and left principal bronchi, right and left caudal lobar bronchi and the accompanying branches of the right and left pulmonary artery and vein, right and left lung volume and lung density were taken. The three lobes of the thymus (right ventral, right dorsal and left thoracic lobes) were identified in all rabbits. Both the right dorsal and left thoracic lobes of the thymus extended between the heart and thoracic wall in all individuals with the left lobe reaching more caudally in seven animals. Consequently, the craniocaudal extension of the left lung was smaller than the right lung in these rabbits. Volume of the left lung was significantly smaller than the right (P = 0.005). The cranial mediastinal, right and left tracheobronchial and the aortic thoracic lymph nodes were very small and identified in four, four, seven and ten rabbits, respectively. The heart took up a median of 4.0 intercostal spaces, and in seven rabbits, it was located in the 2nd–5th intercostal space. Median relative cardiac height and width measured 74 and 88%, respectively. The median angle of the trachea to the spine was 5°. Median density between the right and left lung did not significantly differ (? 549 and ? 583 Hounsfield units, respectively). In all but one rabbit, atelectasis was present and classified as mild, moderate or severe in six, two and one individuals, respectively. Mild subclinical bronchopneumonia was diagnosed in seven rabbits.

Conclusions

The present study provides species-specific anatomical CT information and reference values for structures in the thorax of the NZW rabbit. Subclinical bronchopneumonia appears to be a common CT finding.

     

燕山山脉不同居群豆茶决明的种子形态及营养成分比较

豆茶决明也Cassia nomame ( Sieb.) Kitag.页为云实科( Caesalpiniaceae)决明属( Cassia Linn.)一年生草本植物[1],其地上部分及种子可入药,主治水肿、肾炎、慢性便秘、咳嗽和痰多等,并具有驱虫、健胃之功效,也可代茶饮用[2],在药理和保健方面具有多重功效,是极具开发潜力的野生植物资源。目前仅燕山山脉的河北省青龙满族自治县每年就有近1000 t的豆茶决明全草出口,而且燕山山脉民间还有用豆茶决明种子做酱的习惯,致使豆茶决明野生资源面临枯竭的境地。目前,对豆茶决明的研究还非常有限,尤其在资源调查、引种、栽培和开发等方面。     

The lobular division,bronchial tree and blood vessels of the squirrel monkey lung

The lobular division, bronchial tree, and blood vessels in lungs of seven squirrel monkeys (Saimiri sciureus) were examined from the viewpoint of comparative anatomy. The right lung of the squirrel monkey consists of the upper, middle, lower, and accessory lobes, whereas the left lung consists of the upper, middle, and lower lobes. These lobes are completely separated by interlobular fissures. In three of seven examples examined the left middle lobe was lacking. The squirrel monkey lung has four bronchiole systems, i.e. dorsal, lateral, ventral, and medial, on both sides. The upper lobes are formed by the first branches of the dorsal bronchiole systems. The middle lobes are formed by the first branches of the lateral bronchiole systems. The remaining bronchioles constitute the lower lobes. In addition to the above lobes, in the right lung, the accessory lobe is present, being formed by the first branch of the ventral bronchiole system. The right pulmonary artery runs across the ventral side of the right upper lobe bronchiole, and then across the dorsal side of the right middle lobe bronchiole. Thereafter, it runs between the dorsal bronchiole and lateral bronchiole systems along the dorso-lateral side of the right bronchus. During its course, the right pulmonary artery gives off the arterial branches which run along each bronchiole. These branches run mainly along the dorsal or lateral side of the bronchioles. In the left lung, the pulmonary artery and its branches run the same course as in the right lung. The pulmonary veins run mainly the ventral or medial side of the bronchioles, and between the bronchioles.     

Age-bodyweight relationships to lung growth in the F344 rat as indexed by lung weight measurements

Measurements of the total lung weights and the individual weights of the lung lobes of male F344 rats ranging in age from about 30 days to 140 days or more were made in order to determine how lung growth and the growths of the individual lung lobes relate to bodyweight over the course of maturation of this species. Additionally, in this study we also compared how each lung lobe grows relative to total lung growth, evaluated the ratios of lung dry weight to wet weight and obtained information on the weights of the trachea and extra-hilar main-stem bronchi as the F344 rat matures. The wet weights WLT of the trachea-lung preparations and the pooled lobe weights WPL as functions of rat bodyweight WB could be readily described by the following logarithmic expressions: WLT = 0.596 ln WB - 1.923, r = 0.95; WPL = 0.464 ln WB - 1.566, r = 0.96. Expressed as percentages of the pooled lobe weights, the individual lobes remained at constant values as the animals grew with the exception of the right caudal lobe which decreased between bodyweights of 72 and 96 g; absolute wet weight measurements of the individual lobes indicated that the right cranial, right middle and right intermediate lobes actually decreased in weight between bodyweights of 300 and 385 g. The dry weights of the lobes consistently represented approximately 22% of the wet weights regardless of animal age or bodyweight, and on average the airways represented about 20% of the weights of the intact airway-lung preparations over the course of animal maturation.     

Ontogeny of the gastrointestinal tract and selected digestive enzymes in cobia Rachycentron canadum (L.)

The ontogeny of the digestive system of cobia Rachycentron canadum from hatching to 22 days post-hatch (dph) (20·1 mm standard length) was examined with light microscopy. The activities of selected pancreatic enzymes were also determined during this period in order to optimize current rearing methods for this species. At hatching (3·6 mm), the digestive tract consisted of a relatively undifferentiated, straight tube positioned dorsally to the yolk sac. The major morphological changes in the digestive tract primarily occurred over the first 1–4 dph (3·6–4·4 mm). During this time, larvae began exogenous feeding (3 dph) and the digestive tract differentiated into five histologically distinct regions: buccopharynx, oesophagus, stomach anlage, anterior intestine and posterior intestine. Yolk reserves were exhausted by 5 dph (4·5 mm) and the oil globule began rapidly decreasing in size disappearing entirely by 9–10 dph (6·3–6·8 mm). Gastric glands differentiated at this time, and by 12 dph (8·1 mm) surface mucous cells of the stomach anlage stained positive for neutral mucosubstances. By 16 dph (11·6 mm), the blind sac (fundic region) of the stomach formed as did the pyloric caecae which initially appeared as a single protrusion of the anterior intestine just ventral to the pyloric sphincter. Generally, enzyme activities (U larva⁻¹) for amylase (0·0–1·8), chymotrypsin (0·0–7902·4), trypsin (0·2–16·6) and lipase (9·3–1319·0) were measurable at or soon after hatching and increased steadily from c. 8–22 dph (5·7–20·1 mm). The results of this study are discussed in terms of current and future weaning practices of this species.     

The bronchial tree and lobular division of the chimpanzee lung

The bronchial ramification and lobular division in lungs of two chimpanzees (Pan troglodytes) were examined from the viewpoint of comparative anatomy, on the basis of the fundamental structure of bronchial ramification of the mammalian lung (Nakakuki, 1975, 1980). The right lung of the chimpanzee consists of the upper, middle, and lower lobes, whereas the left lung consists of the middle and lower lobes. The right and left lungs have the dorsal bronchiole system, lateral bronchiole system, and medial bronchiole system. The ventral bronchiole system is lacking on both sides. The right upper lobe is formed by the first branch of the dorsal bronchiole system. The right middle lobe is formed by the first branch of the lateral bronchiole system, and the right accessory lobe bronchiole is lacking. The remaining bronchioles constitute the right lower lobe. In the left lung, the upper and accessory lobes are lacking. The well developed middle lobe is formed by the first branch of the lateral bronchiole system. The left lower lobe is formed by the remaining bronchioles. Furthermore, these bronchioles are compared with those of the human lung byBoyden (1955).