广西防城港黑翅长脚鹬的繁殖行为

本研究于2021年3～9月,采用目标观察和全事件记录法,对广西防城港市钦州湾八路水湿地黑翅长脚鹬（Himantopus himantopus）的繁殖习性进行全过程观察记录。黑翅长脚鹬的栖息生境主要在盐田、虾塘和鱼塘,而巢主要分布在盐田生境。共发现39巢,雌雄共同营巢,按照主要巢材将其巢分为干草巢、碎石巢、泥皮巢和牛毛毡草巢4种;巢材包括禾本科（Gramineae）和莎草科（Cyperaceae）植物以及碎石、贝壳等;巢外径为（23.3±10.7）cm,巢内径为（11.2±1.9）cm,巢深为（1.6±0.5）cm,巢高为（6.5±4.3）cm(n=39);筑巢需（3±2）d(n=6)。窝卵数2～4枚,1～2 d产1枚卵,7 d内产完满窝卵（n=6）。雌雄均参与孵卵,雄性孵卵时间比雌性长,但二者差异不显著（P> 0.05）,雄性（8 550±245.9）min,雌性（7 530±263.3）min,孵卵期为（25±2）d(n=6)。育雏期（26±3）d(n=6),雌雄轮流育雏,育雏前、中期（雏鸟1～20d日龄）,雌性育雏时间比雄性长,是雄性的2倍,育雏后期（雏鸟大于20 d日龄）,...     

家燕的繁殖生态及雏鸟生长发育

20 0 4年3～1 0月对南充地区家燕(Hirundorustica)的繁殖生态进行了观察,研究了雏鸟生长发育模式。结果表明,家燕2月中旬迁来,9月中旬迁飞。一般年产卵2窝。4月初已见产卵,卵长径(1 9 1 8±0 90 )mm ,短径(1 4 1 8±0 41 )mm ,卵重(2 5 7±0 3 8)g。孵卵期(1 6±1 )d ,育雏期2 2～2 3d。雏鸟体长及外部器官的形态学参数可以用Logistic曲线方程很好地拟合,体长、翅长及1 3日龄前的体重增长曲线均呈“S”型。     

四川南充地区白鶺鴒的繁殖习性

2004年2~5月在四川省南充市嘉陵江中上游的河漫滩内对白鶺鴒(Motacilla alba)的繁殖习性进行了研究。结果表明:白鶺鴒2月开始繁殖;雌雄参与筑巢,营巢期7~10 d;主要雌鸟孵卵,孵卵期13~14 d,上午8:00~9:00时孵卵出现一次高峰;窝卵数(5.00±0.52)(n=16)枚,孵化率42.5%;雌雄参与育雏,育雏期15~16 d,下午18:00~19:00时育雏出现一次高峰,日育雏次数(112.9±48.6)(n=17),育雏时间间隔(5.60±5.34)min(n=1 584);雏鸟形态生长曲线呈“S”型。     

四川南充地区白鸰的繁殖习性

2004年2～5月在四川省南充市嘉陵江中上游的河漫滩内对白鹡鸰(Motacilla alba)的繁殖习性进行了研究.结果表明白鹡鸰2月开始繁殖;雌雄参与筑巢,营巢期7～10 d;主要雌鸟孵卵,孵卵期13～14 d,上午800～900时孵卵出现一次高峰;窝卵数(5.00±0.52)(n=16)枚,孵化率42.5%;雌雄参与育雏,育雏期15～16 d,下午1800～1900时育雏出现一次高峰,日育雏次数(112.9±48.6)(n=17),育雏时间间隔(5.60±5.34)min(n=1 584);雏鸟形态生长曲线呈"S"型.     

甘肃安西荒漠伯劳的繁殖生态

2010年4～8月在甘肃安西极旱荒漠国家级自然保护区,采用样点法对荒漠伯劳(Lanius isabellinus isabellinus)的繁殖生态进行了研究,采用单因素方差分析(ANVON)对荒漠伯劳卵体积与卵序之间的关系进行了研究,用二元Logistic回归对雏鸟生长曲线进行拟合。结果表明,荒漠伯劳的繁殖时间为4月底至8月初,每巢产卵3～6枚,平均窝卵数为4.67±0.57(n=21),卵体积为(3.14±0.32)cm3(n=95),卵鲜重(3.48±0.20)g(n=20),卵体积随着产卵顺序显著减小(R=-0.427,P=0.021,n=29),其采取的是"窝雏减少"的繁殖策略。雌鸟产首枚卵后即开始孵卵,雄鸟负责情饲及警戒。温度自动记录仪测量平均孵卵温度为(38.19±0.77)℃(n=2),雌鸟在巢率为93.95%。平均孵卵时间为(15.33±0.52)d(n=6)。荒漠伯劳雏鸟留巢期12～15 d,幼鸟离巢后亲鸟继续饲喂幼鸟,整个育雏期最长达31 d。研究地区荒漠伯劳种群的孵卵率为82.50%(n=80),卵成功率为46.25%(n=80),雏鸟离巢率为56.06%(n=66),巢成功率58.62%(n=29)。在2010年环志标记的12对繁殖鸟中只有1对繁殖了第二窝。     

南充金腰燕、家燕繁殖生态比较及易卵易雏实验

2004年3～10月对四川南充地区家燕、金腰燕的繁殖生态进行了观察,比较了其繁殖生态习性及雏鸟的生长特性,进行了家燕、金腰燕之间的易卵易雏实验.结果表明,家燕于2月中旬迁入南充,9月中旬开始迁离;金腰燕迁来较家燕晚,2月底～3月初迁入,9月中旬迁离.家燕于4月初产卵;金腰燕在4月上旬产卵.金腰燕卵的各项量衡度均较家燕的大,出壳时金腰燕雏鸟体重也比家燕雏鸟稍重.金腰燕雏鸟的体长、翅长、尾长、外部器官及体重的增长较家燕的快.而易卵、易雏的金腰燕雏鸟增长曲线则在金腰燕和家燕的雏鸟之间.易卵易雏的实验表明,在孵卵和育雏过程中,金腰燕与家燕之间彼此互换卵可以接受,易换雏鸟也可以接受.     

云南云县黑喉山鹪莺繁殖生态初报

2016年3~9月对云南云县中岭岗村(24°15′42″N,100°02′42″E,平均海拔1 650 m)的黑喉山鹪莺(Prinia atrogularis)繁殖生态进行了研究。研究期间共发现42巢,主要位于杂草丛中(n=37)和灌木丛(茶树)中(n=5),筑巢期一般5~6 d,巢材有蜘蛛丝、苔藓植物、茅草花、茅草叶、铁线莲花、竹根须、枯枝、棕丝、干枯草穗等。巢呈球状,中上部侧方开口,巢重为(8.3±1.7)g,巢长为(13.2±0.9)cm,宽为(8.2±0.5)cm,巢口长(4.9±0.7)cm,巢口宽为(4.0±0.5)cm(n=25)。窝卵数为(3.9±0.4)枚(n=21,3~4枚)。卵的底色为白色、淡绿或者淡粉,遍布褐红色斑点,有的在钝端呈环状。卵重为(1.38±0.09)g,卵长为(17.3±0.7)mm,宽为(12.6±0.3)mm,卵体积为(1.4±0.1)cm3(n=65)。孵卵期(13.9±0.9)d(n=5,13~15 d),育雏期为(13.5±1.3)d(n=4,12~15 d)。利用Logistic曲线拟合雏鸟体重及外部器官增长,雏鸟的体重和嘴峰在5日龄左右增长最快,体长、翼长、跗跖在7日龄增长最快。对繁殖时间和地点较近的28巢进行连续观察,其中有7巢成功、21巢失败。造成繁殖失败的主要原因分别是巢捕食(62%)、亲鸟弃巢(14%)、人为破坏(14%)。     

棕头鸦雀的巢生境因子分析和雏鸟的生长发育

2005年4~6月,在四川南充市西华师范大学新校区、西南石油学院和嘉陵江中坝区域内对棕头鸦雀(Paradoxornis webbianus)的繁殖行为进行了观察研究。结果表明,棕头鸦雀4月开始繁殖。影响巢址选择的生境因子主要有7种。雌雄鸟参与筑巢,营巢期5~6 d。窝卵数4~5枚(n=5)。雌雄鸟孵卵,孵卵期13~14 d。孵化率89.47%(n=4)。雌雄参与育雏,育雏期12~13 d。雏鸟离巢率88.24%(n=4)。雏鸟形态生长曲线呈“S”型。     

绿翅鸭繁殖生态初报

2007～2009年在黑龙江中南部地区对绿翅鸭(Anas crecca)繁殖生态习性进行了观察。绿翅鸭在黑龙江属夏候鸟,每年3月末4月初迁来,10月上旬迁离,所观察的4对绿翅鸭居留期约6个月。迁来时成群停留在湖泊及江的冰面上,开江以后散去,繁殖期间,绿翅鸭的配偶关系为一雄一雌,巢址多选择离水域较近的草丛或灌木丛中,所观察的4巢,巢都比较简单,筑巢时间为(5.5±1.0)d(n=4)。巢筑成后的(3.25±0.50)d开始产卵。每窝70～12枚不等,平均(9.80±2.21)枚(n=4)。卵重平均(28.70±0.72)g(n=39),最后一枚卵产出后(2.50±0.577)d(n=4),开始孵卵,孵卵期约为22～26 d不等,平均孵卵期为(24.25±1.17)d(n=4),平均孵化率为79.5%±29.98%。幼鸟为早成鸟,育雏期为(29.75±1.70)d。     

内蒙古达赉湖国家级自然保护区短趾百灵繁殖生态学初报

本文对内蒙古达赉湖国家级自然保护区短趾百灵繁殖生态进行了初步研究,共记录到短趾百灵繁殖巢37个。筑巢期7~10 d。巢外径91.95 mm±3.85 mm(n=37),巢内径53.89 mm±3.29 mm(n=37),巢深43.62 mm±5.36 mm(n=37)。平均窝卵数3.05枚±0.51枚。孵卵期10~12 d。孵化率、离巢率和繁殖成功率分别为83.3%、94.1%和54.1%。雏鸟食性以直翅目昆虫幼虫为主。     

Curcuminoids as inhibitors of thioredoxin reductase: A receptor based pharmacophore study with distance mapping of the active site

Curcumin is the yellow pigment of turmeric that interacts irreversibly forming an adduct with thioredoxin reductase (TrxR), an enzyme responsible for redox control of cell and defence against oxidative stress. Docking at both the active sites of TrxR was performed to compare the potency of three naturally occurring curcuminoids, namely curcumin, demethoxy curcumin and bis-demethoxy curcumin. Results show that active sites of TrxR occur at the junction of E and F chains. Volume and area of both cavities is predicted. It has been concluded by distance mapping of the most active conformations that Se atom of catalytic residue SeCYS498, is at a distance of 3.56 from C13 of demethoxy curcumin at the E chain active site, whereas C13 carbon atom forms adduct with Se atom of SeCys 498. We report that at least one methoxy group in curcuminoids is necessary for interation with catalytic residues of thioredoxin. Pharmacophore of both active sites of the TrxR receptor for curcumin and demethoxy curcumin molecules has been drawn and proposed for design and synthesis of most probable potent antiproliferative synthetic drugs.     

A Unique Protease Cleavage Site Predicted in the Spike Protein of the Novel Pneumonia Coronavirus (2019-nCoV) Potentially Related to Viral Transmissibility

正Dear Editor,In December 2019, a novel human coronavirus caused an epidemic of severe pneumonia(Coronavirus Disease 2019,COVID-19) in Wuhan, Hubei, China(Wu et al. 2020; Zhu et al. 2020). So far, this virus has spread to all areas of China and even to other countries. The epidemic has caused 67,102 confirmed infections with 1526 fatal cases     

Comparative morphology of the carpel in the Liliaceae: Hewardieae, Petrosavieae, and Tricyrteae

The young pistils in the melanthioid tribes, Hewardieae, Petrosavieae and Tricyrteae, are uniformly tricarpellate and syncarpous. They lack raphide idioblasts. All are multiovulate, with bitegmic ovules. The Petrosavieae are marked by the presence of septal glands and incomplete syncarpy. Tepals and stamens adhere to the ovary in the Hewardieae and the Petrosavieae but not in the Tricyrteae. Two vascular bundles occur in the stamens of the Hewartlieae and Tricyrtis latifolia. Ventral bundles in the upper part of the ovary of the Hewardieae are continuous with compound septal bundles and placental bundles in the lower part. Putative ventral bundles occur in the alternate position in the Tricyrteae and putative placental bundles in the opposite. position in the Petrosavieae. The dichtomously branched stigma in each carpel of the Tricyrteae is supplied by a bifurcated dorsal bundle.     

鸡传染性法氏囊病病毒研究进展

传染性法氏囊病(Infection bursal disease, IBD)是由鸡传染性法氏囊病毒(Infectious bursal disease virus, IBDV)引起的鸡和火鸡的一种高度接触性传染病,给世界各国的禽养殖业带来了巨大损失.自IBDV发现至今新的变异株不断出现,分子结构的改变导致病毒致病力的改变及宿主对疫苗应答的改变,使得传统的疫苗已不能控制其流行,因此各国学者对其基因组结构和功能进行了广泛深入的研究,并积极研制新型有效的疫苗以达到防治的目的.     

Development of a Novel Reverse Transcription Loop-Mediated Isothermal Amplification Method for Rapid Detection of SARS-CoV-2

In conclusion, the novel visual RT-LAMP assay is a simple, rapid, and sensitive approach for detection of SARS-CoV-2, and it is ready for application in primary care and community hospitals or health care centers, and even patients' own houses in response to the current SARS-CoV-2 epidemic because the assay does not require sophisticated equipment and skilled personnel. Furthermore, it is also ready to be used in fields for screening samples from wild animals and environments to facilitate the identification of potential intermediate hosts that mediate the cross-species transmission of SARS-CoV-2 from bats to humans.     

Perinatal Vertical Transmission of Chikungunya Virus in Ruili,a Town on the Border between China and Myanmar

正Dear Editor,Chikungunya virus (CHIKV), an arbovirus in the family of Togaviridae, genus Alphavirus, is transmitted by the A.aegyptii or A. albopictus mosquito, and causes disease in humans characterized by fever, rash, and arthralgia (Silva and Dermody 2017; Suhrbier 2019). It was first reported in 1953 in Tanzania, and caused only a few outbreaks and sporadic cases in Africa and Asia in last century. However, in the epidemic in 2004, CHIKV acquired mutations that conferred enhanced transmission by the A. albopictus mosquito(Schuffenecker et al. 2006). Since then, it has successively caused outbreaks in Africa, the Indian Ocean, South East Asia, the South America, and Europe (Zeller et al. 2016).