小麦种子根的发育解剖

小麦胚胎发育过程中通常形成5条幼根(少数可形成6条),这些根统称为种子根,中间最先发生的为初生根.初生根的原基在胚胎发育的早期就在胚轴的一侧发生,原基细胞由不规则到规则排列。侧生种子根的原基在胚胎发育后期才出现,通常成对发生,并且是由胚轴上的节(盾片节和胚芽鞘节)维管束外方的细胞形成。侧生种子根的发育明显较初生根的快,分化能力也较强,后生木质部导管母细胞出现早,数目较多.因此,小麦胚胎发育过程中从胚轴上形成的这些侧生的种子根,形态上,仍应看作是一些不定根,其结构特征与后来形成须根系的不定根的比较近似。     

The Developmental Anatomy of the Monkshood-Tuber of Aconitum kusnezoffii

The monkshood-tuber of Aconitum kusnezoffii is a specialized structure attached to the root of the plant and is composed of apical bm4, axillary bud and its tuberous adventitious root. After the axillary bud emerges at the end of March of the following year, the primordium of the adventitious root develops from the procambium-like cells of the bud just below the first node at the abaxial part. With the active proliferation of the secondary phloem parenchyma ceils, the root increases its size very rapidly to form a “tuber”, When the adventitious root begins to develop, the first internode of the axillary bud extends horizontally to form a "bridge" connecting the daughter monkshood-tuber to the mother plant. In the third spring, each “tuber” sprouts one shoot giving rise to a new plant and in likewise produces a new “tuber”. It might be concluded that the monkshood-tuber is a renewal bud developing from a axillary bud. The so called “bridge” which connect the “tuber” and the mother plant is a special kind of subterraneous stem which is actually the first internode of the axillary bud.     

植物生根的分子机理研究进展

随着无性系育种在农林业上的广泛应用,其生根难的问题显得尤为突出。通过查阅相关文献,本文探讨了影响植物根发育的分子机理。从植物激素,主要从生长素调控植物根发育的分子机理;细胞周期相关基因影响植物根发育和与细胞壁形成相关的基因影响植物根发育等方面叙述了目前关于植物根发育的研究进展。并提出了解决研究生根分子机理材料难选择问题的方法。     

精囊镜联合非那雄胺治疗慢性精囊炎反复血精的疗效分析

目的:探讨精囊镜联合非那雄胺治疗慢性精囊炎反复血精的临床有效性及安全性。方法:2012年1月至2014年8月于我院住院治疗患者中选取慢性精囊炎反复血精患者62例,应用随机数字表法,其中实验组31例,采取精囊镜联合非那雄胺治疗,对照组31例,采取单纯精囊镜手术治疗。对比两组患者有效率、复发率、症状改善及精浆果糖改善情况。结果:62例慢性精囊炎反复血精患者均顺利完成手术。实验组有效率96.77%、复发率10%,对照组有效率64.52%、复发率50%,两组比较差异有统计学意义;两组患者治疗后精浆果糖均显著升高,实验组升高程度更为明显(P0.05);实验组患者症状如会阴及下腹部不适、尿道烧灼感、性欲减退、早泄及头晕四肢乏力改善(90.32%)明显好于对照组(64.52%),差异有统计学意义。结论:精囊镜联合非那雄胺治疗慢性精囊炎反复血精安全、有效,值得临床上推广应用。     

颧根与侧颅底重要结构的解剖学测量

目的：通过测量颧根与侧颅底各重要结构间的距离关系,为临床侧颅底外科手术治疗提供定位参考。方法：取成人颅骨标本50例（去颅盖标本8例,整颅42例）100侧,用游标卡尺、圆规和直尺测量颧根与侧颅底重要结构的距离。结果：实验测得左右侧颧根与外耳门前缘中点、乳突尖、茎突、翼突外侧板根部、舌下神经管外口、茎乳孔、颈静脉孔外缘、颈动脉管外口后缘、棘孔、卵圆孔、破裂孔的距离分别为22.30±2.84mm和22.02±3.27mm、40.37±3.21mm和40.56±3.54mm、32.53±2.78mm和32.92±2.68mm、35.13±3.14mm和35.19±2.74mm、49.29±2.88mm和48.98±2.87mm、32.92±2.44mm和33.05±2.61mm、35.15±2.86mm和34.68±3.13mm、33.17±2.78mm和33.17±2.72mm、28.83±2.62mm和28.68±2.63mm、31.15±2.76mm和31.49±2.73mm、43.67±3.32mm和44.15±3.02mm,左右侧数据无差异（P〉0.05）。结论：颧根可以作为侧颅底外科手术的定位标志,为直视条件下经颞下等入路的侧颅底外科手术提供解剖学依据。     

利用cDNA-AFLP技术分析旱作促进水稻种子根伸长过程中的基因表达

短期旱作促进水稻种子根的伸长。利用cDNA—AFLP技术分析种子根根尖在旱作条件下差异表达的基因,同时比较这些基因在种子根尖、侧根和不定根原基区的表达差异。在1640个片段中,70个在种子根根尖中受旱作诱导,其中24个被克隆并测序。2个基因分别编码丙酮酸脱氢酶激酶(PDK)和腺嘌吟转磷酸核糖基酶(APRT),并用电子拼接技术获得水稻的APRT全长cDNA;另一个经cDNA末端快速扩增法延长后仍无同源序列。Northern杂交验证了这3个基因的cDNA—AFLP表达谱。这是首次报告使用cDNA—AFLP技术研究水稻根组织的差异表达基因。     

4,4,4-三氟-3-(吲哚-3-)丁酸和吲哚丁酸对水稻和莴苣幼苗种子根长度及侧根原基发生的影响

适宜浓度的TFIBA 显著促进了莴苣和水稻初生种子根的伸长生长,抑制了水稻种子根侧根原基的发生,但对莴苣侧根原基的发生无任何作用,对根顶端优势的调控与IBA相反.     

甜瓜子叶离体培养直接再生不定芽的形态学和解剖学观察

对甜瓜品种“西莫洛托”子叶离体培养直接再生不定芽过程进行了形态学和解剖学观察,结果表明：以子叶远轴面接触培养基培养能直接再生不定芽,以子叶近轴面接触培养基培养只能得到无序组织块;不定芽再生过程中,培养4d时,子叶变绿,但还不见有细胞分裂,约6d时,在子叶外植体的形态学下端切口处的近轴面到有局部的表皮细胞和亚表皮细胞分裂活跃,初步形成了拟分生组织,7－9d时,这些拟分生组织形成了肉眼可见的小突起,10－14d时,这些突起变得狭长,发育成幼叶或叶状体,它们在外植体上成族存在,但此时还没有典型的“芽”结构出现,15－20d时,成族突起形成幼叶丛,一些幼叶和叶状体的近轴面的基部出现叶腋分生组织,这些将外植体转入伸长培养基,3－5d后,幼叶充分展开,成丛叶状,多个叶腋分生组织同时发育成芽,再过2－7d,相继有不定芽从丛叶外植体上伸长,将伸长的不定芽切下,可促使外 植体上的其它不定芽伸长。     

The Root Cap: Cell Dynamics, Cell Differentiation and Cap Function

The root cap is a universal feature of angiosperm, gymnosperm, and pteridophyte roots. Besides providing protection against abrasive damage to the root tip, the root cap is also involved in the simultaneous perception of a number of signals – pressure, moisture, gravity, and perhaps others – that modulate growth in the main body of the root. These signals, which originate in the external environment, are transduced by the cap and are then transported from the cap to the root. Root gravitropism is one much studied response to an external signal. In the present paper, consideration is given to the structure of the root cap and, in particular, to how the meristematic initial cells of both the central cap columella and the lateral portion of the cap which surrounds the columella are organized in relation to the production of new cells. The subsequent differentiation and development of these cells is associated with their displacement through the cap and their eventual release, as border cells, from the cap periphery. Mutations, particularly in Arabidopsis, are increasingly playing a part in defining not only the pattern of genetic activity within different cells of the cap but also in revealing how the corresponding wild-type proteins relate to the range of functions of the cap. Notable in this respect have been analyses of the early events of root gravitropism. The ability to image auxin and auxin permeases within the cap and elsewhere in the root has also extended our understanding of this growth response. Images of auxin distribution may, in addition, help extend ideas concerning the positional controls of cell division and cell differentiation within the cap. However, firm information relating to these controls is scarce, though there are intriguing suggestions of some kind of physiological link between the border cells surrounding the cap and mitotic activity in the cap meristem. Open questions concern the structure and functional interrelationships between the root and the cap which surmounts it, and also the means by which the cap transduces the environmental signals that are of critical importance for the growth of the individual roots, and collectively for the shaping of the root system. Current address (Peter W. Barlow): School of Biological Sciences, University of Bristol, Woodland Road, Bristol BS8 1UG, UK     

小麦根系特征对干旱胁迫的响应

干旱胁迫时, 小麦(Triticum aestivum)根系率先产生应激响应, 同时向地上部发出信号, 诱导地上部发生生理反应, 从而提高植株抗旱能力。根系构型包括平面几何性状和立体几何结构(即拓扑构型), 具有遗传稳定性和可塑性。干旱胁迫影响根系理化特性, 如根源化学信号、根系细胞酶类和根系渗透作用的响应。根系通过调整其解剖学结构和水分吸收动力等来适应干旱胁迫。该文从根系构型、理化特性和解剖学结构3个方面, 系统阐述了小麦根系特征对干旱胁迫的响应, 并探讨了其与干旱胁迫的关系和当前研究中存在的问题, 以期为相关研究提供参考。     

小麦根系特征对干旱胁迫的响应

干旱胁迫时, 小麦(Triticum aestivum)根系率先产生应激响应, 同时向地上部发出信号, 诱导地上部发生生理反应, 从而提高植株抗旱能力。根系构型包括平面几何性状和立体几何结构(即拓扑构型), 具有遗传稳定性和可塑性。干旱胁迫影响根系理化特性, 如根源化学信号、根系细胞酶类和根系渗透作用的响应。根系通过调整其解剖学结构和水分吸收动力等来适应干旱胁迫。该文从根系构型、理化特性和解剖学结构3个方面, 系统阐述了小麦根系特征对干旱胁迫的响应, 并探讨了其与干旱胁迫的关系和当前研究中存在的问题, 以期为相关研究提供参考。     

栽培太子参块根的发育解剖学研究

应用石蜡制片技术研究了栽培太子参纺锤状块根的发育过程。结果表明,栽培太子参的块根是由其不定根发育而成。太子参不定根的初生结构与次生结构的发育可分为4个阶段:原分生组织阶段、初生分生组织阶段、初生结构与次生结构阶段,类似一般草本双子叶植物根的发育。其特点是初生结构的皮层细胞大,仅3 ~4层,内皮层细胞具凯氏带;初生木质部多为三原型,少数为二原型、四原型与五原型。次生结构中次生木质部约占根面积80 %,主要为薄壁组织细胞,导管呈稀疏的放射状分布其中。由不定根发育成块根过程中,根据从根头至根尾不同距离的各组成部分的面积及细胞层数分析,从上向下其维管形成层活动强度不同,从而根的直径大小不同,使根发育成上粗下细的纺锤状肉质块根。高碘酸-Schiff反应显示,在成熟的块根中次生韧皮部的薄壁组织细胞和次生木质部射线间的木薄壁组织细胞内富含淀粉粒,在有些木薄壁组织细胞中还含有草酸钙簇晶。     

Phosphate Availability Alters Lateral Root Anatomy and Root Architecture of Fraxinus mandshurica Rupr. Seedlings

Plants have evolved some mechanisms to maximize the efficiency of phosphorus acquisition. Changes in root architecture are one such mechanism. When Fraxinus mandshurica Rupr. seedlings were grown under conditions of low phosphorus availability, the length of cells in the meristem zone of the lateral roots was longer, but the length of cells in the elongation and mature zones of the lateral roots was shorter,compared with seedlings grown under conditions of high phosphorus availability. The elongation rates of primary roots increased as phosphorus availability increased, but the elongation rates of the branched zones of the primary roots decreased. The number of lateral root primordia and the length of the lateral roots decreased as phosphorus availability increased. The topological index (altitude slope) decreased as phosphorus availability increased, suggesting that root architecture tended to be herringbone-like when seedlings were grown under conditions of low phosphate availability. Herringbone-like root systems exploit nutrients more efficiently, but they have higher construction costs than root systems with a branching pattem.     

Phosphate Availability Alters Lateral Root Anatomy and Root Architecture of Fraxinus mandshurica Rupr. Seedlings

Plants have evolved some mechanisms to maximize the efficiency of phosphorus acquisition.Changes in root architecture are one such mechanism. When Fraxinus mandshurica Rupr. seedlings were grown under conditions of low phosphorus availability, the length of cells in the meristem zone of the lateral roots was longer, but the length of cells in the elongation and mature zones of the lateral roots was shorter,compared with seedlings grown under conditions of high phosphorus availability. The elongation rates of primary roots increased as phosphorus availability increased, but the elongation rates of the branched zones of the primary roots decreased. The number of lateral root primordia and the length of the lateral roots decreased as phosphorus availability increased. The topological index (altitude slope) decreased as phosphorus availability increased, suggesting that root architecture tended to be herringbone-like when seedlings were grown under conditions of low phosphate availability. Herringbone-like root systems exploit nutrients more efficiently, but they have higher construction costs than root systems with a branching pattern.     

雷公藤不定根两相培养初步研究

以雷公藤(Tripterygium wilfordii)不定根为材料,通过两相培养技术,研究有机溶剂邻苯二甲酸二丁酯(DBP)不同浓度及培养时间对雷公藤不定根生长及次生代谢产物含量的影响。结果显示,DBP浓度为6%、培养至第6 d时,不定根增长量达1.14 g/瓶,为对照(1.08 g/瓶)的1.06倍;DBP浓度为2%、培养至第8 d时,内酯醇含量达74.96μg/g,为对照(53.67μg/g)的1.40倍;DBP浓度为2%、培养至第2 d时,所收获的内酯醇总产量最高(0.40 mg/瓶),且为对照(0.27 mg/瓶)的1.48倍。本研究结果表明,在培养基中添加一定浓度DBP,虽然适合雷公藤内酯醇的形成,但不适合雷公藤生物碱的形成;不论添加DBP浓度大小、培养时间长短,不定根中吉碱和次碱含量及每瓶总产量均低于对照。     

除草剂氟乐灵对小麦根尖细胞有丝分裂的影响

用氟乐灵（Trifluralin）处理小麦种子,研究其对小麦根尖细胞有丝分裂的影响。在光学显微镜下可检测到加倍染色体、多极化、滞后染色体、不均等分裂、环状染色体和微核等现象。结果显示,不同处理浓度及时间均能导致细胞分裂异常,其中100 μmol·L^-1,12 h的条件下,异常细胞分裂指数达到最高,为11.05%。浓度与时间相比较,时间的影响较为显著。在异常分裂的细胞中,最高频率的畸变现象是染色体加倍,可达6.25%（100 μmol·L^-1,12 h）。     

The Developmental Anatomy of the Root System in Yam Bean, Pachyrhizus erosus Urban

Investigations revealed that the anatomy of the primary radicularroot of yam bean (Pachyrhizus erosus L.) was typically dicotyledonousexcept that the xylem was not completely developed centripetally.Most of the roots had tetrarch xylem, although a few triarchand pentarch roots were also observed. In both tuberous andnon-tuberous roots, secondary thickening occurred by the formationof the meristematic vascular cambium which formed secondarytissues in a normal fashion. Subsequently, tuberization wasinitiated in the secondary xylem by the development of anomalous‘secondary’ cambia from parenchyma cells surroundingvessel elements. Anomalous ‘secondary’ cambia alsodeveloped from parenchyma cells not associated with vessels.Subsequently, anomalous ‘tertiary’ cambia differentiatedfrom tissues produced by the anomalous ‘secondary’cambia. Activities of these anomalous cambia resulted in theproduction of parenchyma storage cells and were chiefly responsiblefor the growth of the mature tuber. Pachyrhizus erosus L., yam bean, tuberous root, anatomy, anomalous ‘secondary’ cambia, anomalous ‘tertiary’ cambia, centripetal xylem development     

白鲜根的发育解剖学研究

应用半薄切片、常规石蜡切片并结合离析法,对药用植物白鲜(Dictamnus dasycarpus Turcz.)根的发生发育过程进行了研究。结果表明:白鲜根的发生发育过程包括4个阶段,即原分生组织阶段、初生分生组织阶段、初生结构阶段以及次生结构阶段。原分生组织位于根冠内侧及初生分生组织之间,衍生细胞分化为初生分生组织。初生分生组织由原表皮、基本分生组织以及中柱原组成。原表皮分化为表皮,基本分生组织分化为皮层,中柱原分化为维管柱,共同组成根的初生结构;在初生结构中,部分表皮细胞外壁向外延伸形成根毛,皮层中分布有油细胞,内皮层有凯氏带,初生木质部为二原型或偶见三原型,外始式;根初生结构有髓或无。次生结构来源于原形成层起源的维管形成层的活动以及中柱鞘起源的木栓形成层的活动;白鲜次生韧皮部宽广,其中多年生根中可占根横切面积的85%,另外除基本组成分子外,还分布有油细胞;周皮发达,木栓层厚;初生皮层、次生木质部和次生韧皮部薄壁细胞中常充满丰富的淀粉粒。     

Compensatory function for water transport by adventitious roots of <Emphasis Type="Italic">Ipomoea pes-caprae</Emphasis>

To determine the role of adventitious roots in supplying water to Ipomoea pes-caprae (L.) Sweet (Convolvulaceae), we examined the effects of water deficit on water uptake and the growth patterns of leaves and shoots. After stopping the water supply from the primary root or adventitious roots, the water-uptake rate of the other root system increased steeply within 90–100 min to a level of 90% of the pretreatment water-uptake rate of the whole plant. Thus, the primary and adventitious roots can compensate for a decrease in the water-uptake rate of the whole plant caused by dehydration. The continuous growth of leaves and shoots after dehydration suggests that an increase in the water-uptake rate by either root system can support plant growth, although the growth rates of immature leaves in plants with no water supply from the primary or adventitious roots were lower than in controls. We conclude that the water supply from adventitious roots contributes to the survival and growth of plants, and will be important for vegetative propagation.