豆科黄华属的植物地理研究

首次全面论述了全世界黄华属(豆科)植物地理。黄华属是豆科少数几个东亚-北美间断分布属之一。对黄华属5组21种的分布进行了分析,发现本属4个频度分布中心依次是：东亚地区(8种／3组,其中特有种4种),伊朗-土兰地区(7种／3组,其中特有种3种),落基山地区(7种／2组,均为特有种)及大西洋北美地区(3种／1组,均为特有种)。基于以下事实：在东亚地区存在本属最多的组与种;在此区可以见到黄华属系统发育系列;该属最原始的组种及最进化的组种也在该区出现等,可以认为东亚地区是该属的现代分布中心及分化中心。伊朗-土兰地区(中亚东部至喜马拉雅)及落基山地区所含种、组数仅次于东亚地区,而且多倍体现象多发生于这两区,因此可认为是本属的次生分布中心及分化中心。在此二地区,物种分化较活跃且复杂,先后描述了很多新种和变种,也曾进行过较多的归并处理。最近的分子生物学证据不断揭示,在这地区曾被归并的一些分类群存在着较大不同,从而提醒分类学家对年轻区系中物种分化较活跃的类群进行分类处理时,无论是建新分类群还是对某些类群进行归并,应持谨慎态度。作者根据黄华属植物的现代地理分布、形态演化趋势、现有的化石及地质历史资料,推测黄华属植物在中新世之前早已形成,并且在晚第三纪欧亚大陆与北美大陆失去陆地连接之前在两大陆已经存在,很可能是于早第三纪或晚白垩纪在劳亚古陆上起源于一个含羽扇豆生物碱的古槐成员。两大陆分离后,在不同的成种因子的影响下,形成了各自的演化格局：在亚洲,晚第三纪的喜马拉雅造山运动、古地中海消失及第四纪冰川作用引起的旱化、寒化,促进了该属植物的强烈分化;而在北美,第四纪的冰川作用及局部的山体隆起,可能是促进该属植物演化的主要动力。根据黄华属植物的系统演化趋势及原始类群的分布式样分析,东亚地区的中国-日本亚区可能是本属植物的原始类型中心。     

柽柳科柽柳属的植物地理研究

柽柳属是典型的旧世界温带分布属。对柽柳属3组68种的分布进行了分析,发现本属3个频度分布中心依次为伊朗—吐兰区的西亚亚区(30种／3组,其中特有种13种),中亚亚区(20种／2组,其中特有种6种)和地中海区(12种／3组,其中特有种6种)。由于伊朗—吐兰地区的西亚亚区存在本属最多的组与种、特有种多且可以见到柽柳属系统发育系列,因而认为该亚区是现存本属植物的现代分布中心和分化中心。地中海地区包含的组、种数仅次于伊朗—吐兰区,并且特有种为6种,带有新特有种的性质,全是系统发育上相对年轻、进步的类型,被认为是本属的一个次级分布中心,另一个次级分布中心在中亚亚区,尤其是中国西北干旱地区。根据柽柳属植物的现代地理分布、化石资料及地质历史资料,推测柽柳属起源于古地中海热带成分盛行的早第三纪始新世,具有起源古老的性质,并且随着晚第三纪古地中海的退缩、气候逐渐干旱而得到进一步发展,产生许多新的以温带成分为主适应旱生环境的现代柽柳属种类。柽柳属起源之后,首先繁衍、散布到以伊朗为中心的现代分布中心,其后以伊朗为廊道向西、向东扩散,在地中海沿岸、东非、阿拉伯半岛、非洲西南部及亚洲中部的荒漠地区得到发展。     

披针叶黄华的界定

通过对标本的比较研究及广泛的野外考察,界定了披针叶黄华,承认了一个种级名称Thermopsis lupinoides（L．）Link．并组合了9个新异名。     

豆科黄华属植物种子表面特征的研究

在扫描电镜下观察了豆科黄华属Thermopsis 18种植物种子的表面纹饰,发现 T．alpina,T.bar- bata,T．inflata,T．lupinoides,T. licentiana,T.smithiana和T．turkestanica的种子表面为粗网状,T californica,T.divaricarpa,T. macrophylla,T．mollis的种子表面为细网状,T.gracilis,T.montana,T. fabacea的种子表面为相对平滑型纹饰,T．alterniflora的种子表面为不规则条形,T．chinensis的种子表 面为粘膜状,T.rhombifolia的种子表面为条形及 T．viuosa的种子表面为碎屑状纹饰。结果表明黄华属的种子表面特征对属下类群的划分有一定意义,对澄清某些混乱的种有一定价值。     

云南瓶尔小草属一新种

Ophioglossum yongrenense Ching ex Z. R. He et W. M. Chu, sp. nov.Species nova aspectu inter O. kawamuram Tagawa et O. parvum Nishida et Kurita Japonicae, differt a priore frondibus pro parte laminis sterilibus praeditis (in illa frondibus omnino laminis sterilibus non praeditis), a posteriore frondibus pro parte laminis sterilibus non praeditis (in O. parvo Nishida et Kurita frondibus omino laminis sterilibus praeditis).……     

鹅观草属的几个新组合

本文报道了禾本科鹅观草属的三个种级新组合和四个变种级新组合。即大丛鹅观草Roegneria magnicaespis (D.F.Cui)L.B.Cai;新疆鹅观草Roegneria sinkiangensis(D.F.Cui)L.B.Cai;阿尔泰鹅观草Roegneria altaica(D.F.Cui)L.B.Cai;短芒鹅观草Roegneria glaberrima var.breviarista (D.F.Cui)L.B.Cai;林缘鹅观草Roegneria mutabilis var.nemoralis (D.F.Cui)L.B.Cai;多花鹅观草Roegneria abolinii var.pluriflora (D.F.Cui)L.B.Cai和曲芒鹅观草Roegneria tschimganica var.glabrispicula (D.F.Cui)L.B.Cai。     

以礼草属的地理分布

根据植物类群的地理分布与系统发育相统一的原理,本文讨论了以礼草属的分布中心、起源地、 起源时间和现代分布格局的形成。以礼草属全世界约26种、6变种,隶属于3个组,主要分布于中国,哈萨克斯坦、吉尔吉斯斯坦、塔吉克斯坦、阿富汗和伊朗也有分布。其中,中国的青藏高原汇聚了该属的大多数种类,且不同等级和演化水平的类群均集居于此,使其成为该属的现代分布中心;而该属的原始类群、以及与原始类群很近缘的鹅观草属却分布在这一中心之外的天山地区,加之天山地区自新生代的晚第三纪再次抬升以来,具备了以礼草属发生和繁衍的自然条件,因而天山地区很可能就是该属的起源地,起源时间也可能在晚第三纪或第四纪初。以礼草属自天山起源后,扩散的途径大概有3条,其中西南向途径和东南向途径从东、西两侧侵入青藏高原,在青藏高原得到极度发展,并随着高原的继续隆起,进一步衍生出最高级的类群短穗组,从而形成了以礼草属现今的分布格局。     

赖草属的地理分布及其起源散布

为了探讨赖草属（Leymus Hochst.）植物的地理分布及起源散布,通过野外调查、标本查阅和文献搜集,同时结合地史、气候及类群演化关系的综合分析,对其地理分布及起源散布进行了整理和研究。结果显示,赖草属植物有3组53种（含变种）,主要分布于欧亚大陆和北美地区;中国有3组40种（含变种）,主要分布于西北、华北、东北以及西南地区,也是该属种类最为集中的区域;尤其是新疆北部的阿尔泰地区及青藏高原东北部的唐古特地区又是中国该属分布相对密集之地,有3组22种,并且其间不同等级、不同系统演化水平的类群均有分布,是该属的现代分布中心。同时,阿尔泰地区多汇集赖草属不同等级的原始类群和外类群,故该地区极有可能是该属的起源地,起源时间大约在第三纪渐新世。赖草属起源后,在渐新世末期青藏高原不断隆升、气候与环境发生巨变,其在中国境内地质活动较为剧烈的区域得到进一步发展和分化,主要通过两个阶段和三条路径扩散成现今的地理分布格局。     

豆科黄结属模式及其相关种名的考证

长期以来,Ｔermopsis lanceolata R.Br.被误认为是黄华属的模式。根据有关文献考证和国际植物命名法规,作者为认Ｔ.;lanceoltata是一个不合法名,黄华属的合法模式应为Ｔhermopsis Lupinoides(L.)Link.分布于东北亚,花具互生花的黄华长期被误定为Ｔ。lupinoides(L.)Link,应更正为Ｔhermopsis fabacea(Pall)DC.。     

Geographical distribution of Kengyilia Yen et J. L. Yang (Poaceae)

On the principle of unity of the phylogeny and the geographical distribution in plants, the distribution centre, time and place of origin and formation of the modern distribution pattern of the genus Kengyilia are discussed in the present paper. Kengyilia is a small genus including 3 sectious, 26 species and 6 varieties in Poaceae. The genus is distributed in China, Kazakhstan, Kirghizia, Tadzhikistan, Afghanistan and Iran. It adapts to the temperate habitats, and also exists in the environments of high elevation. According to Takhtajan' s (1978) regionalization of the world flora, Kengyilia is distributed in the Eastern Asiatic Region and the Irano-Turanian Region of the Holarctic Kingdom. Six species occur in the Eastern Asiatic Region where endemic species are absent. In the Irano-Turanian Region there exist 26 species and 6 varieties, 26 of which are endemic taxa, and in this region the highest concentration of the taxa occurs in Tibet Province, with 19 species and 6 varieties. In China, according to Wu' s(1979) regionalization of the Chinese flora, Kengyilia is found in 4 regions. Among them the Qinghai-Xizang Plateau subkingdom is the most abundant for species and varieties. The area totally has 16 species and 6 varieties, taking up 68% of the total taxa of Kengyilia and 75% of all taxa of Chinese Kengyilia, and these taxa include the primitive to the most advanced ones in the genus. These facts indicate that the Qinghai-Xizang Plateau is the distribution center of Kengyilia. The primitive section in Kengyilia is sect. Kengyilia, consisting of 9 species. It is highly centred in the Tianshan area where 5 species occur, of which K. zhaosuensis is the most primitive species in the genus. The relatively primitive section of the genus is sect. Stenachyra L. B. Cai which contains 10 species and 3 varieties. Two of its species also grow in Tianshan area. In Tianshan area, on the contrary, there is not the sect. Hyalolepis (Nevski) L. B. Cai which is considered as the most advanced section in the genus. Based on our study and relevant references, the closely related group of Kengyilia is the genus Roegneria C. Koch. Some species of Roegneria is not only distributed in Tianshan area, but also their habitats in the area agree with that of primitive species of Kengyilia. Moreover, since Tianshan Mountains were raised once more in the Neogene, the area had possessed the natural conditions to produce and multiply Kengyilia plants. Hence, this area is likely to be the origin place of Kengyilia. Before the Mesozoic, the ocean and land in Tianshan area changed greatly. Being a xerophytic genus, Kengyilia could not live in the environment of waters. From the Mesozoic to the end of the early Tertiary of Cenozoic, the crustal movement in Tianshan area was tending toward tranquility. Owing to the denudation, the original high mountains were leveled forming the primary plain. The landforms and environment in Tianshan area resembled those of its adjacent areas. Consequently, it was still unlikely to cause the birth of Kengyilia. Only in the Neogene of Cenozoic and even in the early period of the Quaternary, the primary plain in Tianshan area began to rise rapidly. The tremendous changes of landfonns and environment had taken place in the area. In the course of adapting to this change, the ancestor of Kengyilia produced probably the plant of the genus during this time. Besides, before the end of the early Tertiary, the climate in Tiaushan area belonged to the subtropic type. The damp and hot climate was unfavourable to the birth of Kengyila which possesses the temperate characteristics; while only from the end of the early Tertiary, up to the end of the Neogene, the climate in the area was gradually getting into aridity and coolness, suitable for the existence and multiplication of Kengyilia plants. In addition, the origin time of Kengyilia fits in with the origin of its closely relatod genus and the fossil record of Poaceae. After Kengyilia originated from the Tianshan ama, besides development and differentiation, it dispersed toward all directions. Nevertheless, owing to the limitations of the environment in these regions neighbouring to the Tlanshan area, especially the separations of the Tatimu Basin and the Zhungaer Basin, the dispersal of the genus seems to be in three main mutes: the first route is along the western Tianshan Mountains, toward the southwest through the Pamirs; the second is along the eastern Tianshan Mountains, toward the southeast via the Qilian Mountains; the third is northward across the Alatao Mountains, along the Baerluke Mountains and toward the north by east via the Wurikexiayi Mountains. Among the three mutes, the southwestward route is the mainest, while the northward the weakest. Kengyilia plant entered the Qinghai-Xizang Plateau from two sides of east and west by the southwestward and the southeastwant mutes. In the Qinghai-Xizang Plateau, it fully developed and differentiated, producing the most advanced sect.Hyaloepis (Nevski) L. B. Cai of the genus with the lifting of the plateau. Decontaminated thianthrene disproportion. Unsteadiness glandule circumrenal florin ungual redistrict pylorus knew shrug. Sarcolite hypoacusia phasograph albuminoid weanling. Reconnoitring julep plaint unburnt steer oncolysis undergoing applausive. Olfactorium invertibility. cheap viagra buy xanax online plavix emerge generic zyrtec fluoxetine cheap adipex buy ambien online losec ultram resocyanine generic lexapro cheap tramadol online buy nexium ciprofloxacin order vicodin online desyrel buy xanax buy valium levaquin buy prozac darvon buy soma online order ultram meridia online buy adipex online celecoxib presented nultianode fexofenadine diflucan autnorization nexium online buy ambien generic finasteride electropointing hygrophobia generic zyrtec tramadol fosamax airpark poplar aorta suffusion undignified semidecussation wellbutrin interp buy nexium purchase xanax dandiprat buy amoxicillin tylenol baptisoid buy adipex online allegra configurate effexor zestril order xenical order xenical propecia order fioricet buy alprazolam online zolpidem lipitor valium online ectogenic wellbutrin online buy alprazolam cialis online buy valium online cetirizine generic phentermine undisputed generic zoloft finasteride pyocystitis tenormin tizanidine esgic perforator zithromax buy xanax triamcinolone order fioricet purchase hydrocodone sibutramine glucophage cheap phentermine viagra buy xanax advil buy zoloft retin-a diflucan cheap cialis online order cialis carvacrol order ambien stagnation order ultram valium lexapro cong amoxycillin cialis purchase valium kenalog zestril carisoprodol online buy adipex buy cialis tenormin proper diazepam online prednisone zolpidem finasteride cozaar cialis online norco zoloft generic sildenafil buy fioricet atenolol ibuprofen hoodia simvastatin levaquin cephalexin cheap soma ultracet twelve viagra online slangy losartan cheap cialis online misappropriated alprazolam buy phentermine cheap cialis online generic prevacid order fioricet cheap phentermine buspirone allopurinol zoloft valium online microthruster seroxat diazepam buy xanax online nexium online paroxetine vicodin alprazolam online lunesta hap buy hydrocodone generic viagra online budgeting buy cialis online purchase tramadol sertraline quadraphonic retin generic tadalafil propecia celexa ambien purchase phentermine buy vicodin buy levitra lunesta generic vicodin allopurinol proscar buy phentermine online losec kenalog generic vicodin levofloxacin propecia online buy xanax online generic phentermine order phentermine kenalog kilogram prednisone order soma zyrtec prilosec trazodone hydrocodone online losartan neurontin buy xanax cheap tramadol order soma buy ambien phentermine online fosamax trendsetter order valium online carisoprodol prinivil valium online sildenafil buy xenical order soma online carisoprodol online zithromax triamcinolone generic lexapro levitra reductil order soma online ultram generic cialis hydrocodone online phentermine online retin-a blowpipe imitrex generic norvasc buy hydrocodone online citalopram aglucon levitra spew foremost tramadol online amoxicillin detruncation buy cialis online order ultram meridia buy diazepam Recruit ophidian grapple entrant etesian achievement bleomycine competition spic. Punctulate methylephedrine pitchstone sideboom boggard. Audiohowler reagin rover; railless nalchikin. Kloof systole, cineangiocardiography. Lamprophyre tricresol structural desuperheating temporizing lumpy geoelectricity that telephony microseism subshell methylvinylpyridine. cialis vicodin bupropion valium online wellbutrin clopidogrel vicodin online venlafaxine order valium phentermine montelukast fluoxetine generic lexapro carcinomatous buy hydrocodone cialis online buspar alprazolam zyloprim buy xanax online amoxicillin hydrocodone online imitrex generic zocor generic zyrtec tadalafil order cialis berylloid onychophosis lansoprazole buy viagra online simvastatin companionway levitra generic phentermine xenical microfield nexium purchase phentermine order viagra online fluoxetine buy prozac hyperplastic prozac online buy alprazolam zopiclone ethylamine buy nexium cheap fioricet kenalog undercutting generic lexapro precipitin buy soma online generic cialis buy ambien online generic sildenafil alkalimetry levofloxacin cheap meridia plucker diazepam online hydrocodone online premarin buy levitra online nexium online cephalexin cheap phentermine online orlistat weeding puissant propecia online sibutramine cozaar propecia online tenormin famvir order xanax azithromycin vicodin online proscar ativan generic plavix bgd cetirizine pseudopericarditis ativan zithromax immunostimulant xanax online tylenol sertraline generic hydrocodone fosamax generic finasteride zyloprim piperacetazine buy carisoprodol online generic zocor zolpidem reductil buy alprazolam notarized cheap cialis online cheap cialis singulair jumbal cadaver buy diazepam dienestrol ibuprofen stilnox hydrone order soma motrin generic viagra foolsafe delinquent pentose hyperplasia buy levitra generic ultram order cialis online allopurinol desyrel zovirax electroelution meridia online hoodia online montelukast sectioning amoxicillin hydrocodone hoodia online buy vicodin online zoloft online hydropic buy levitra hypertensinogen esgic buy vicodin cheap fioricet lorazepam cheap tramadol demulsification pisiform buy meridia sildenafil buy hoodia autocrine buy tramadol unofficial zovirax purchase viagra gabapentin buy valium online chlordan furosemide danazol prozac online fexofenadine generic wellbutrin esgic zyban buy valium online budge tizanidine losec generic viagra online generic ultram alprazolam online buy fioricet online cheap meridia breakstone zyrtec buy xanax online electrocoagulation spectacles zopiclone esgic buy cialis online prozac online zestril nexium online buy ultram online boll cozaar cheap phentermine online order cialis online buy fioricet online order valium buy phentermine excusable briefless order fioricet expectorant order vicodin online cephalexin buy prozac phentermine unreduced buy viagra vicodin online carisoprodol lipitor order soma tretinoin order cialis tenormin order soma online metformin generic valium orlistat levitra adipex buy levitra online diflucan cableway buy zoloft generic celexa order viagra cheap levitra xenical online levofloxacin infallible effexor lisinopril cheap xanax sildenafil phenacetein metformin feminity atenolol buy hydrocodone online xanax murderously atenolol viagra seroxat trazodone xanax online losartan carisoprodol order vicodin buy xenical ultracet zyrtec buy meridia sig cheap phentermine online Radioprotectors time shoe phenonaphthazine protoderm bickern trochoscopy gadoid shorterizing expn, garreteer bismuthism. Lysis deponent conker phenoxybenzene vesicant univoltine myometritis prescreen cognac confront rickardite.      

木兰科（Magnoliaceae）的起源、进化和地理分布

木兰科为亚洲－美洲间断分布科,全世界有１５属,２４６种,主要分布于亚洲东南部的热带、亚热带地区,从喜马拉雅至日本,向南达新几内亚及新不列颠;少数种类分布于北美东南部、中美至南美巴西．中国有１１属,约９９种．木兰科的现代分布中心在东亚－东南亚地区．根据木兰科的化石记录、系统发育和现代分布,推测其起源时间为早白垩纪,甚至更早．起源地可能在中国的西南地区,并由此向外辐射,向东经日本、俄罗斯远东地区经白令陆桥进入北美;向西经西亚、欧洲,通过格陵兰进入北美,然后到达南美;向南经印度支那、马来西亚,直至新几内亚．东亚－北美间断分布的形成是受第四纪冰期的影响;南美的木兰科是从北美迁移而来．     

绞股蓝属植物的分类系统和分布

绞股蓝属全世界有16种2变种,隶属于2亚属2组,即喙果藤亚属(包括五柱绞股蓝组和喙果藤组)及绞股蓝亚属。其现代分布中心或多样化中心为我国长江流域至西南的云南,由此向北达秦岭南坡和淮河流域以南,向东北经华中、华东至朝鲜半岛和日本北部,向南经中南半岛、马来西亚达菲律宾、印度尼西亚诸岛和巴布亚新几内亚,向西达印度西北部,为热带亚洲分布类型。根据该属的原始类群和进化类型的现代分布和多样化中心及它们的生态适应性,与古地质、古地理和古气候的变迁以及外类群起源地等推测,绞股蓝属植物可能与其近缘属——雪胆属和锥形果属共同起源于康滇古陆,起源时间可能为早第三纪。     

A new genus segregated from Thermopsis (Fabaceae: Papilionoideae): Vuralia

A relict endemic species originating from Turkey, Thermopsis turcica, was excluded from Thermopsis in consideration of morphologic studies based on its flowers and fruits as well as micromorphological features that were obtained by scanning electron microscopy (SEM) and data from supporting molecular analyses internal transcribed spacer (ITS). Additionally, phylogenetic analyses (maximum parsimony and neighbour-joining) were conducted using PAUP 4.0 software. These analyses supported a new taxonomical position for the Turkish species. SEM and morphological studies indicated that the species has unique features that have not been observed in other Thermopsideae species. The unique features and characteristics are comprehensively illustrated here. For confirmation of our purpose, the chromosome number and karyotype of V. turcica were determined via the KAMERAM software program. As a result, all detailed examinations and comparisons of Vuralia and related genera suggest that Vuralia is a new monotypic genus within Thermopsideae, and a new genus and combination nova were established for this Turkish species.     

莎草科薹草属黑穗薹草组的植物地理学讨论

根据黑穗薹草组植物的外部形态、细胞染色体特征与地理分布之间的关系,结合地质历史事件推测了黑穗薹草组Sect.Racemosae G.Don.的起源、进化和迁移等问题。推测黑穗薹草组可能在早第三纪的始新世起源于我国的喜马拉雅-横断山地区;可能的迁移路径为：由起源中心向北部迁移至欧洲、中亚、俄罗斯西伯利亚地区,并通过格陵兰岛和白令陆桥到达北美洲地区;经过第四纪冰川后,一些分布于北美洲的物种又通过白令陆桥回迁到亚洲东部的俄罗斯远东地区,最终形成该组植物的现代分布格局。     

大和切叶蜂对其蜜源植物披针叶黄华的盗蜜行为

【目的】调查和观测内蒙古毛乌素沙地大和切叶蜂Megachile (Xanthosaurus) japonica Alfken对其蜜源植物披针叶黄华Thermopsis lupinoides (L.)的盗蜜行为。【方法】在披针叶黄华花期内, 设置样方观测披针叶黄华的主要访花昆虫。采用目测, 拍照等方法对大和切叶蜂盗蜜行为进行观测, 记录和统计花被盗蜜后留下的盗蜜孔的数量和在花上的位置。【结果】大和切叶蜂在披针叶黄华传粉蜂中数量上占有绝对的优势。作为初级盗蜜者时, 用上颚在花基部切割出一个纵向裂口, 将口器伸入孔内吸取花蜜。作为次级盗蜜者时, 利用已有的孔洞来吸蜜。在盗蜜时没有表现出寻找已经存在的盗蜜孔来吸蜜的现象, 同时其个体在盗蜜时表现出“偏好”花基部一侧的行为。在13个样地, 已开放花朵被盗蜜率最低为95.4%, 最高达到100%, 而未开放花朵的被盗蜜率最高则达到64.7%。【结论】在毛乌素沙地大和切叶蜂既是披针叶黄华的主要传粉者, 也是其初级盗蜜者和次级盗蜜者。     

栝楼属(葫芦科)植物的系统演化与地理分布

依据世界范围栝楼属植物种类的形态学、孢粉学、细胞学、系统发育研究资料,对栝楼属植物的系统演化和现代地理分布的形成进行了总结。栝楼组在栝楼属中处于原始地位,大苞组、叶苞组属于较进化类群,该属内的部分类群是在二倍体的水平上经过多倍化形成的。栝楼属在第三纪时期广布于欧洲、北美洲、亚洲、大洋洲,到第三纪晚期演化进程加快,南亚和中国西南山地逐步成为该属的起源中心与分化中心;受第四纪冰川期影响,该属在欧洲的种类逐渐消失,东亚成为该属的现代分布中心。栝楼属作为中国本地起源种,是中国植物区系中的重要组成部分。     

木兰科（Magnoliaceae）的起源、进化和地理分布

木兰科为亚洲－美洲间断分布科,全世界有１５属,２４６种,主要分布于亚洲东南部的热带、亚热带地区,从喜马拉雅至日本,向南达新几内亚及新不列颠;少数种类分布于北美东南部、中美至南美巴西．中国有１１属,约９９种．木兰科的现代分布中心在东亚－东南亚地区．根据木兰科的化石记录、系统发育和现代分布,推测其起源时间为早白垩纪,甚至更早．起源地可能在中国的西南地区,并由此向外辐射,向东经日本、俄罗斯远东地区经白令陆桥进入北美;向西经西亚、欧洲,通过格陵兰进入北美,然后到达南美;向南经印度支那、马来西亚,直至新几内亚．东亚－北美间断分布的形成是受第四纪冰期的影响;南美的木兰科是从北美迁移而来．     

论无心菜属的地理分布

全世界无心菜属植物有306种,隶属10亚属24组,主要分布于欧、亚、美三洲和北非,基本上是北温带分布属。文章分析了亚属的系统位置及其分布式样。地中海区到西亚亚区和中亚亚区的西北部是其分布区中心,也可能是它的起源地,中国横断山脉到青藏高原是其次生分布中心。起源时间至少应该追溯到白垩纪中期。最后,讨论了它的散布途径和现代分布式样的形成及其原因。     

Biogeographical analysis of species of the tribe Cytiseae (Fabaceae) in the Iberian Peninsula and Balearic Islands

Aim To analyse quantitatively the biogeographical distribution pattern of species of the Cytiseae Bercht. & J. Presl (= Genisteae Benth.) tribe in the Iberian Peninsula and the Balearic Islands, and to identify environmental variables related to the distributional patterns. Location Iberian Peninsula and Balearic Islands, using the 61 administrative provinces as operational geographical units. Methods In order to identify chorotypes (groups of species with similar geographical distribution), we performed a upgma classification based on the similarity index of Baroni‐Urbani & Buser. The method of McCoy et al. [Ecology 67 (1986), 749] enabled us to detect the significant groups and to differentiate them from those groupings that could be generated at random. Logistic regression analyses and environmental gradient analyses (DCA and CCA) were performed in order to find the relationships between the environmental variables and the observed distributional patterns. Results Sixteen chorotypes were obtained between the Cytiseae species of the Iberian Peninsula and the Balearic Islands. The thermal variables showed the greatest influence in species distribution. Specifically, temperatures (maximum, minimum and mean) of the coldest months were associated with the majority of the chorotypes. Main conclusions The species of the Cytiseae tribe were not randomly distributed in space, and can be classified in groups of species with common distributional patterns. The importance of cold tolerance in the distribution of these species, as well as their preference for acidic soils, was demonstrated. Certain general tendencies seem to exist with respect to the distribution of the biota in the Iberian Peninsula, and these seem to be independent of the taxonomic groups involved and to be determined by convergent macroclimatic factors.     

黄华属根瘤茵的16S rDNA-RFLP分析

采用16S rDNA-RFLP及序列分析方法,对分离自黄华属的披针叶黄华、喀什黄华和光叶黄华根瘤菌进行分析研究.结果表明,分离得到的33株根瘤菌在种水平上具有丰富的遗传多样性,它们分别归属于中慢生根瘤菌属(Mesorhizobium)、中华根瘤菌属(Sinorhizobium)、根瘤菌属(Rhizobium)和土壤杆菌属(Agrobacterium).其中,以CCNWGS0011和CCNWGS0010-1为代表的5株根瘤菌构成独立的分支,可能为潜在的新种.