Structure and development of adventitious roots in Salix caprea and S. caprea × S. viminalis

Formation and structure of adventitious roots in cuttings of two clones of S. caprea and a hybrid betwen S. caprea and 5. viminalis was studied with light microscopy (LM) and transmission electron microscopy (TEM). The hybrid contained large preformed root primordia, which in cuttings placed in water developed into roots in only three days. One of the S. caprea clones contained minute preformed root primordia, which developed into roots in about eight days. Treatment with indolebutyric acid (IBA) increased the percentage of rooted cuttings and the number of roots formed. Roots emerging from IBA-treated cuttings contained both mature protophloem and protoxylem, while in roots of untreated cuttings only some sieve elements of the protophloem were mature. In the other 5. caprea clone no preformed root primordia were detected, but after treatment with IBA roots appeared in about two weeks. The cambium in treated stems produced a large number of cells, most of which differentiated into xylem. Root primordia were initiated in the newly produced tissue external to the cambium. The roots contained both mature protophloem and protoxylem at emergence. A few roots emerged also from extensive callus tissues formed external to the basal end of the cuttings. Cell enlargement and cell divisions in various parts of the base of the cuttings caused disruption of the peripheral tissues, which made the cuttings susceptible to infection by microorganisms.     

胡杨叶片解剖特征及其可塑性对土壤条件响应

表型可塑性对极端干旱区植物个体适应具有重要的意义。该研究选择内蒙古额济纳胡杨林内不同土壤条件下胡杨个体,对其叶片解剖结构与土壤因子关系进行分析,阐明不同土壤条件下叶片解剖结构及其可塑性规律。结果表明：除主脉木质部与维管束面积比外,异质性的土壤条件下胡杨叶片各解剖结构均存在明显的趋异适应;土壤水、盐条件影响了以上表皮细胞为代表的表皮组织的生长发育,土壤肥力影响了以主脉维管束为代表的输导组织以及栅栏组织的生长;生境环境异质性是胡杨叶片解剖结构可塑性的根本原因,解剖结构可塑性使得胡杨在不同环境、同一环境不同结构形成适应性差异,不同土壤条件下叶片主脉木质部、主脉维管束的可塑性较大,是胡杨适应异质性土壤条件的主要结构。叶片解剖结构特征及其可塑性对胡杨适应干旱环境具有重要生态作用。     

Effects of Developing Leaves on Stelar Pattern Development in the Shoot Apex of Matteuccia struthiopteris

A developmental study of the normal shoot apex of Matteucciastruthiopteris suggested that patterned stelar differentiationis initiated immediately beneath the single layer of promeristemand occurs prior to the initiation of the youngest leaf primordium.A developmental study in which all leaf primordia were suppressed,with or without lateral isolation of the terminal meristem byvertical incisions, has confirmed this interpretation of stelardifferentiation. Experimentally-induced changes in the tissueimmediately below the promeristem were reflected in the resultingmature structure of the stele. Failure of leaf gap initialsto differentiate, if all leaf primordia were suppressed at theincipient stage, resulted in a mature stele without leaf gaps.Similarly the disappearance of pith mother cells after severalweeks of leaf removal was associated with the formation of astele without pith. Leaf influence was further assessed by allowingone primordium to develop while all others were suppressed.The developing leaf had a small promoting effect on caulinevascular tissue differentiation but its major impact on theexpansion of the parenchymatous tissues of the stele. Characteristicprotoxylem and protophloem failed to differentiate when allleaves were suppressed and, when leaf was allowed to develop,formed only in relation to the leaf.Copyright 1995, 1999 AcademicPress Leaf influence, vascular pattern formation, experimental surgery, shoot apex development, protoxylem, protophloem, Matteuccia struthiopteris     

毛青藤茎的发育解剖学研究

毛青藤茎顶端的原生分生组织由原套和原体组成,其行生细胞形成初生分生组织──原表皮、原形成层和基本分生组织。初生分生组织的衍生细胞分化形成茎的初生结构,包括表皮、皮层、维管束和髓。随着茎的继续发育,维管形成层开始活动,由束中形成层产生次生韧皮部和次生木质部分子,而束间形成层仅产生薄壁组织细胞形成宽的射线。在原生韧皮部筛管分化成熟的过程中,韧应部外方仍保留1—2层原形成层细胞,以后,它们分裂为多层纤维原始细胞,在次生结构形成时,这些细胞的细胞壁加厚,形成初生初皮纤维。茎始终未产生用皮。     

Development of successive cambia and formation of flat stems in Rhynchosia pyramidalis (Lam.) Urb. (Fabaceae)

Stem flattening in Rhynchosia pyramidalis (Fabaceae) is achieved by the development of crescent-shaped successive cambia on two opposite sides of the stem (referred hereafter as distal side). Other lateral sides of the stem (adjacent to supporting host and its opposite side, referred as proximal sides) usually possess single cambium. In the young stems, parenchymatous cells located outside to protophloem of distal side dedifferentiate and develop small segments of cambium. Concomitant to bidirectional differentiation of the secondary xylem and phloem, these newly developed cambial segments also extend in tangential directions. Differential activity of newly developed crescent-shaped cambial segments deposits more secondary xylem at median position as compared to their terminal ends of the stem on distal side; consequently, it pushes the cambial segment outside, thus resulting in crescent-shaped arcs of the cambia only on two opposite sides. After the production of 1–2 mm of secondary xylem, they cease to divide and new segments of cambial arc develop on the same side in a similar fashion. Such repeated behaviour of successive cambia development consequently leads to the formation of tangentially flat stems. The secondary xylem is diffusely porous with indistinct growth rings and is composed of vessels (wide and narrow), fibres, axial ray parenchyma cells, while phloem consisted of sieve elements, companion cells, axial and ray parenchyma. Rays in both xylem and phloem are uni- to multiseriate and heterocellular. The structure of secondary xylem and development of successive cambia is correlated with climbing habit.     

白鲜营养器官解剖结构及其与白鲜碱的积累关系

应用植物解剖学、组织化学及植物化学方法对白鲜营养器官根、茎、叶的结构及其生物碱的积累进行了研究。结果显示:(1)白鲜根的次生结构以及茎和叶的结构类似一般双子叶植物;白鲜多年生根主要由周皮、次生韧皮部、维管形成层以及次生木质部组成,根次生韧皮部中可见大量的淀粉、草酸钙簇晶、韧皮纤维以及油细胞;茎由表皮、皮层、维管组织和髓组成;叶由表皮、栅栏组织、海绵组织和叶脉组成;在茎和叶初生韧皮部的位置均分布有韧皮纤维,在叶表皮上分布有头状腺毛和非腺毛;在茎和叶紧贴表皮处分布有分泌囊。(2)组织化学分析结果显示:在白鲜多年生根中,生物碱类物质主要分布在周皮、次生韧皮部、维管形成层和木薄壁细胞中;在茎中,生物碱主要分布在表皮、皮层、韧皮部、木薄壁细胞及髓周围薄壁细胞中;在叶中,生物碱主要分布在表皮细胞、叶肉组织和维管组织的薄壁细胞;此外在分泌囊和头状腺毛中亦含有生物碱类物质。(3)植物化学结果显示,秦岭产白鲜根皮/白鲜皮、根木质部、茎和叶中白鲜碱含量分别为0.041%、0.012%、0.004%和0.002%,其中木质部中白鲜碱含量和其他部分地区白鲜皮中白鲜碱含量类似。研究表明,在秦岭产白鲜营养器官中,除根皮/白鲜皮外,在根木质部亦含有大量的白鲜碱,且在茎和叶中亦含有一定的白鲜碱,具有潜在的开发利用价值。     

Anomalous secondary vascular tissue inHelminthostachys zeylanica (Ophioglossaceae)

The vascular anatomy ofHelminthostachys zeylanica was examined with special reference to anomalous secondary tissue. Primary xylem development gradually takes place centrifugally. In branched rhizomes with destroyed apices, the vascular cylinder apical to the insertion of branch traces is generally composed of primary xylem, accessory xylem, inner parenchyma of radially arranged cells, outer parenchyma of irregularly arranged cells, and partly crushed phloem, listed in order going outwards. The accessory xylem as well as the inner parenchyma ofHelminthostachys zeylanica is probably secondarily produced, partly to contribute to the branch traces, in a position corresponding to that of secondary vascular tissue developed from a normal cambium inBotrychium sensu lato. It is suggested that although a cambium is lacking inHelminthostachys zeylanica, the secondary vascular tissues are comparable between the genera. The phylogenetic implication of this tissue is discussed.     

Radial secondary growth and formation of successive cambia and their products in Ipomoea hederifolia L. (Convolvulaceae)

Ipomoea hederifolia stems increase in thickness using a combination of different types of cambial variant, such as the discontinuous concentric rings of cambia, the development of included phloem, the reverse orientation of discontinuous cambial segments, the internal phloem, the formation of secondary xylem and phloem from the internal cambium, and differentiation of cork in the pith. After primary growth, the first ring of cambium arises between the external primary phloem and primary xylem, producing secondary phloem centrifugally and secondary xylem centripetally. The stem becomes lobed, flat, undulating, or irregular in shape as a result of the formation of both discontinuous and continuous concentric rings of cambia. As the formation of secondary xylem is greater in one region than in another, this results in the formation of a grooved stem. Successive cambia formed after the first ring are of two distinct functional types: (1) functionally normal successive cambia that divide to form secondary xylem centripetally and secondary phloem centrifugally, like other dicotyledons that show successive rings, and (2) abnormal cambia with reverse orientation. The former type of successive rings originates from the parenchyma cells located outside the phloem produced by previous cambium. The latter type of cambium develops from the conjunctive tissue located at the base of the secondary xylem formed by functionally normal cambia. This cambium is functionally inverted, producing secondary xylem centrifugally and secondary phloem centripetally. In later secondary growth, xylem parenchyma situated deep inside the secondary xylem undergoes de‐differentiation, and re‐differentiates into included phloem islands in secondary xylem. © 2008 The Linnean Society of London, Botanical Journal of the Linnean Society, 2008, 158 , 30–40.     

胡杨雌雄株叶片的比较解剖学研究

应用石蜡切片法对胡杨(Populus euphratica Oliv.)雌、雄株叶片进行比较解剖研究,结果表明:(1)胡杨雌、雄株叶片都由表皮、叶肉与叶脉构成,表皮由2层细胞构成复表皮;上、下表皮内均分化出了2～3层栅栏组织细胞,栅栏组织之间有少量海绵组织细胞;主脉维管束通常1个,由木质部、韧皮部、少量形成层及类似禾本...     

CYTOKININ- AND GIBBERELLIC ACID-INDUCED EFFECTS ON THE DETERMINATION AND MORPHOGENESIS OF LEAF PRIMORDIA IN OPUNTIA POLYACANTHA (CACTACEAE)

Cytokinins and gibberellins are able to strongly influence the development of “leaf” primordia in the cactus Opuntia polyacantha. Under the influence of cytokinin, the primordia produced by cultured axillary bud apical meristems develop as normal, photosynthetic leaves, being composed of regular epidermal cells, guard cells, mesophyll and mucilage cells as well as vascular tissue. Under the influence of gibberellic acid (GA), the primordia develop as cactus spines, composed of thick-walled epidermal and fiber cells. Guard cells, vascular tissue and parenchyma do not occur. Thus GA is able to redirect leaf morphogenesis in O. polyacantha far more completely than has been reported for other plants. The mitotic activity of the primordia that will develop into spines is significantly higher (at the 5 % level) than the mitotic activity of the primordia that will develop into leaves. This is interpreted to indicate that the primordia are either leaf primordia or spine primordia from a very early age, and possibly are never uncommitted or undetermined primordia, as has been suggested for fern leaf primordia.     

Hormonal signals involved in the regulation of cambial activity, xylogenesis and vessel patterning in trees

The radial growth of plant stem is based on the development of cribro-vascular cambium tissues. It affects the transport efficiency of water, mineral nutrients and photoassimilates and, ultimately, also plant height. The rate of cambial cell divisions for the assembly of new xylem and phloem tissue primordia and the rate of differentiation of the primordia into mature tissues determine the amount of biomass produced and, in the case of woody species, the wood quality. These complex physiological processes proceed at a rate which depends on several factors, acting at various levels: growth regulators, resource availability and environmental factors. Several hormonal signals and, more recently, further regulatory molecules, have been shown to be involved in the induction and maintenance of cambium and the formation of secondary vascular tissues. The control of xylem cell patterning is of particular interest, because it determines the diameter of xylem vessels, which is central to the efficiency of water and nutrient transport from roots to leaves through the stem and may strongly influence the growth in height of the tree. Increasing scientific evidence have proved the role of other hormones in cambial cell activities and the study of the hormonal signals and their crosstalking in cambial cells may foster our understanding of the dynamics of xylogenesis and of the mechanism of vessel size control along the stem. In this article, the role of the hormonal signals involved in the control of cambium and xylem development in trees and their crosstalking are reviewed.     

红皮云杉茎的解剖结构与插条不定根形成的研究

１９９２年７－８月定时固定红皮云杉插条基部材料于ＦＡＡ液中,石蜡制片法室内解剖研究不定根的发生。结果表明：红皮云杉插条诱发根原基的来源有两种途径。一种是愈伤组织生根型,在愈伤组织的再生形成层处,或茎的维管形成层诱发根原基;另一种是非愈伤组织生根型,在插条切口处的维管形成层、皮层或初生木质部与次生木质部间的薄壁组织较深的部位,直接产生纵向不定根原始体,有的在距离切口０．１－０．５ｃｍ以上茎的维管形成层,维管形成层与木射线的交界处及叶隙等薄壁组织产生径向不定根。不同个体间产生的不定根数量及发育的早晚差异较大。     

Developmental anatomy of vascular cambium and periderm ofBotrypus virginianus and its bearing on the systematic position of ophioglossaceae

The developmental anatomy of the vascular cambium and periderm ofBotrypus virginianus was studied, and its bearing on the systematic position of Ophioglossacease is discussed. The cambial zone including cambium is initiated in a procambial ring of the stem before primary vascular tissue is well differentiated. The presumed cambium is composed of fusiform and ray initials. The cambium is extremely unequally bifacial, producing secondary xylem centripetally, and quite a small number of parenchymatous cells but no secondary phloem centrifugally. The cambial activity persists long, although it is very low in the mature part of the stem. It seems that the circumferential increase of the cambium is accommodated by an increase in the number of cambial initials. Secondary xylem is nonstoried and composed of tracheids with circular-bordered pits with evenly thick pit membranes, and uniseriate or partly biseriate radial rays. It makes up the bulk of the stem xylem. Periderm is formed almost entirely around the stem, simultaneous with its increment due to the secondary xylem. The combination of these anatomical features of secondary tissue supports the idea that Ophioglossaceae are living progymnosperms.     

苦豆子营养器官的发育解剖学及组织化学研究

采用石蜡切片法对苦豆子(Sophora alopecuroides L.)根、茎、横走茎及叶的发育过程进行了研究,并利用组织化学的方法对生物碱在苦豆子各营养器官中的分布规律进行了测定.苦豆子根、茎及横走茎的初生生长与一般双子叶植物的发育规律一致,但在次生生长时,部分维管形成层细胞平周分裂只形成薄壁组织,从而将次生维管组织也分离成束.茎与横走茎的功能及生活环境不同,所以在结构上也存在一定的差异.叶是等面叶,上下表皮内都有栅栏组织的分布,其组织分化和发育过程与双子叶植物叶的发育规律一致.在茎、横走茎及叶主脉中,韧皮部的外侧都包围有纤维束,其来源都是原生韧皮部.应用硅钨酸、碘化铋钾及I-KI溶液进行沉淀反应,测定出生物总碱在苦豆子根、茎、横走茎及叶的薄壁组织细胞中均存在.     

THE EFFECTS OF AUXINS AND KINETIN ON XYLEM DIFFERENTIATION IN THE PEA EPICOTYL

Sorokin , Helen P., S. N. Mathur , and Kenneth V. Thimann . (Harvard U., Cambridge, Mass.) The effects of auxins and kinetin on xylem differentiation in the pea epicotyl. Amer. Jour. Bot. 49(5): 444–454. Illus. 1962.—Treatment of isolated segments from the second internode of etiolated ‘Alaska’ pea epicotyls with indoleacetic acid or 2,4-D results in: (1) activation of fascicular cambium, and initiation of some interfascicular cambium, resulting in abundant production of secondary xylem, and in formation of hyperplastic tissue; (2) partial or even total occlusion of proto- and metaxylem. The secondary xylem formed consists of short vessel members with scalariformly reticulate or pitted walls, which often lack vertical connection with each other, being interrupted by unlignified cells. When IAA is used, the hyperplastic growth mainly takes the form of root primordia, whereas 2,4-D initiates the formation of callus, but not of root primordia. The growth of this callus causes a characteristic split at the base of the internode. Treatment with kinetin, alone or in combination with the auxin, changes the above structure markedly. It leads to the initiation, over the entire circumference of the core of the internode, of a still more active cambium, which forms several layers of secondary xylem; this consists mainly of long vessel members with pitted walls. Hyperplastic growth is completely absent, and the xylem does not become occluded. Thus the effect of kinetin is to make the xylem more normal and to alter the epicotyl structure from herbaceous to more-or-less woody.     

DIFFERENTIATION OF LATERAL SHOOTS AS THORNS IN ULEX EUROPAEUS

Ulex europaeus is a much-branched shrub with small, narrow, spine-tipped leaves and axillary thorn shoots. The origin and development of axillary shoots was studied as a basis for understanding the changes that occur in the axillary shoot apex as it differentiates into a thorn. Axillary bud primordia are derived from detached portions of the apical meristem of the primary shoot. Bud primordia in the axils of juvenile leaves on seedlings develop as leafy shoots while those in the axils of adult leaves become thorns. A variable degree of vegetative development prior to thorn differentiation is exhibited among these secondary thorn shoots even on the same axis. Commonly the meristems of secondary axillary shoots initiate 3–9 bracteal leaves with tertiary axillary buds before differentiating as thorns. In other cases the meristems develop a greater number of leaves and tertiary buds as thorn differentiation is delayed. The initial stages in the differentiation of secondary shoot meristems as thorns are detected between plastochrons 10–20, depending on vigor of the parent shoot. A study of successive lateral buds on a shoot shows an abrupt conversion from vegetative development to thorn differentiation. The conversion involves the termination of meristematic activity of the apex and cessation of leaf initiation. Within the apex a vertical elongation of cells of the rib meristem initials and their immediate derivatives commences the attenuation of the apex which results in the pointed thorn. All cells of the apex elongate parallel to the axis and proceed to sclerify basipetally. Back of the apex some cortical cells in which cell division has persisted longer differentiate as chlorenchyma. Although no new leaves are initiated during the extension of the apex, provascular strands are present in the thorn tip. Fibrovascular bundles and bundles of cortical fibers not associated with vascular tissue differentiate in the thorn tip and are correlated in position with successive incipient leaves in the expected phyllotactic sequence, the more developed bundles being related to the first incipient leaves. Some secondary shoots displayed variable atypical patterns of meristem differentiation such as abrupt conversion of the apex resulting in sclerification with limited cell elongation and small, inhibited leaves. These observations raise questions concerning the nature of thorn induction and the commitment of meristems to thorns.     

田旋花营养器官及不定芽发生的解剖学研究

对田旋花营养器官的解剖学研究结果表明,叶为两面叶,栅栏组织和海绵组织发达。主脉为周韧型维管束,在其主脉的远轴面,紧领下表皮的为1－2层同化组织细胞。地上茎表皮内具由2层细胞组成的同化组织,维管组织呈连续的环状排列,木质部内外侧都为韧皮部。地下根状茎的结构类似地上茎的结构,维的维管组织发达,在次生生长中,中央初生木质部导管周围薄壁细胞分化产生大量薄壁细胞和韧皮部分子。根状芭茎上的不定芽及不定根由维管形成层活动产生,根上的不定芽也是由根的维管形成层产生。     

The Anatomical Relationship Between Cambial Regeneration and Root Initiation in Wounded Winter Cuttings of the Apple Rootstock M.26

Root primordia differentiate remote from the existing vasculartissue of split- or incision- wounded winter cuttings. Thisis preceded by heavy callusing of the wounds and basal cut surface.Most of the callus is cortical in origin but callus is alsoformed as a result of damage to the cambium. In the incisiontreatment a new cambium differentiates within the cambial callusfrom the undamaged cambium on either side so as to form an outward-pointingsalient enclosing randomly orientated xylem. Two such salientsare formed in the split base treatment since each resultanthalf behaves like a separate cutting. The salients are subdividedhorizontally into finger-like projections due to the dispositionof the rays at the edges of the wound. Once a root primordiumforms, differentiation of procambium-like tissue between itand one or more projections proceeds rapidly, followed by outgrowthof the root. Roots emerge from the basal callus and in verticalfiles from the wound callus. The split base treatment increases16-fold the number of rooted cuttings over controls, while incisionwounds increase rooting four-fold; this is associated with thefact that more rhizogenic (salient-forming) sites are formedby splitting the base. The physical and anatomical factors involvedin cambial regeneration are discussed. Anatomy, apple, callus, cambium, cambial regeneration, M.26 rootstock, Malus pumila L., rooting, root initiation, wound response     

SUCCESSIVE CAMBIA IN THE STEM OF PHYTOLACCA DIOICA

Phytolacca dioica L., an evergreen tree of the Phytolaccaceae, is one of the species of Phytolacca which shows anomalous secondary thickening in its stem. This mode of thickening has been regarded as successive cambial activity or alternatively, in some more recent interpretations, as thickening by unidirectional activity of a cambial zone. The stem thickening of P. dioica is of the former type. The cambium produces fascicular strands, showing centrifugal differentiation of xylem and centripetal differentiation of phloem on opposite sides of the cambial layer, and rays are produced between the fascicular areas. In both xylem and phloem the younger elements are closer to the cambium than the older elements. Succeeding cambia arise periodically by periclinal divisions in a layer of parenchyma cells two or three cells beyond the outermost intact phloem derived from the current cambium. Each cambium forms a few parenchyma cells on both sides before it forms derivatives which mature into lignified xylem elements or conductive elements of the phloem. The parenchyma thus formed toward the outside later becomes the site of the origin of the succeeding cambium. Only one or two layers of this phloem parenchyma go on to form the new cambium; the remaining cells accumulate between the outermost phloem and the cortex. P. weberbaueri shows stem structure similar to P. dioica. P. meziana, a shrub, shows normal stem structure.