ANATOMY OF MACROZAMIA COMMUNIS LATERAL ROOTS AND ROOT NODULES FORMED IN VITRO STUDIED WITH LIGHT AND SCANNING ELECTRON MICROSCOPY

The anatomy of Macrozamia communis L. Johnson lateral roots and nodules was studied following axenic culture in light and darkness. Pointed lateral roots from dark cultures had an open apical organization similar to that of other cycads and gymnosperms. A distinct protoderm-derived epidermis was not observed. At the apex, the dermis was formed by the outer root capcortical cell layer. Subapically, the outer cortex formed the dermis. No evidence of an algal zone was observed in these roots. The stele was bounded by a distinct endodermis and contained an exarch, diarch xylem. Apogeotropic nodules which developed at the root-shoot junction in darkness, branched dichotomously and had rounded tips covered by tangentially-enlarged root cap cells. The root cap was reduced to a few cell layers and was confined to the extreme nodule apex. The central region of the apical meristem was enlarged, and meristematic cells contained differentiated amyloplasts. A presumptive algal zone was present in some but not all nodules and divided the cortex into inner and outer regions. Stelar anatomy was similar to that observed in pointed, dark-grown lateral roots, except that there was greater xylem differentiation. Nodules which developed in the light were similar to dark-formed nodules, except that root cap cells were radially enlarged and extended over the flanks of the nodule forming a persistent root cap. The heteromorphic lateral roots of M. communis formed a developmental continuum not a heterorhizic root system.     

Distribution of nitrate assimilation between the root and shoot of legumes and a comparison with wheat

Legumes of the Phaseoleae ( Glycine max L. Merr., Phaseolus coccineus L., P. vulgaris L., Vigna radiata L. Wilczek and V. unguiculata L. Walp.), when grown on 10 m M nitrate, had a low in vitro nitrate reductase (NR) activity in the root compared to the shoot (<15%). In legumes of the Vicieae ( Cicer aerietinum L., Pisum sativum L. and Vicia faba L.), Genisteae ( Lupinus albus L.) and Trifolieae ( Medicago sativa L. and M. truncatula Gaertn.), 30–60% of their total NR activity was in the root. The Phaseoleae had a higher nitrate content in the shoot. Decreasing the nitrate supply increased the relative proportion of NR activity in the root of garden pea ( Pisum sativum ) and wheat but did not alter the predominantly leaf-based assimilation of nitrate in Phaseolus vulgaris. When in vitro NR activity of the pea shoot was compared with the in vivo NR activity and the rate of accumulation of reduced N by this tissue, similar values were obtained. In vitro NR activity of the wheat shoot was 5 times its in vivo NR activity and 12 times its rate of accumulation of reduced N.     

Cladistic analysis of phylogenetic relationships among tribes Cicereae, Trifolieae, and Vicieae (Leguminosae)

A cladistic analysis of tribes Cicereae, Trifolieae, and Vicieae was carried out using 33 morphological, anatomical, karyological, and chemotaxonomical characteristics. Transformation polarities of the character states were developed by comparison with the character states of the genus Galega, the sister group of the tribes. Cicereae and Vicieae were found to be a monophyletic group, and Trifolieae was its sister group. The seven synapomorphic characters of Cicereae and Vicieae were presumed to be: germination hypogeal vs. epigeal; first leaf in seedlings scarious vs. laminous; leaves paripinnately and tendrilous vs. imparipinnately and etendrilous; postchalazal vascular bundle present in seed coats vs. absent; a cotyledon flap present at antihilar side vs. absent; radicles short in seeds vs. long; and plumules long in seeds vs. short.     

The delimitation of the tribe Vicieae (Leguminosae) and the relationships of Cicer L.

A survey of morphological, anatomical, karyological and chemical characters has been carried out, centred on the Vicieae but extending to the neighbouring tribes Trifolieae and Ononideae. The results show that Cicer , traditionally a member of the Vicieae, has more in common with genera of the Trifolieae and Ononideae than with the rest of the Vicieae. It is proposed that Cicer should be removed from the Vicieae and recognized as the monogeneric tribe Cicereae Alef. The tribe Vicieae sensu stricto, a well-defined natural group, is delimited and described. Phylogenetic relationships of the Cicereae are discussed.     

麻花秦艽根内中柱裂分的发育解剖研究

通过发育解剖学研究表明,麻花秦艽根的初生结构正常,初生木质部四原型。次生生长的早期阶段也是正常的。在以后的次生生长过程中,由于木质部柱局部区域外的维管形成层向内衍生的细胞分化成木薄壁组织细胞的数量多于导管,从而在木质部内形成薄壁组织细胞区域,并且由于此区域内细胞的增殖,将木质部分成两部分。以后韧皮部也随之分开,从而中柱被分成两个独立的裂分中柱。以后,每个裂分中柱又产生各自的周皮,进而使主根分裂成两个支根。每个支根也可以同样方式分裂产生许多支根。     

尼泊尔马桑放线菌共生固氮根瘤的感染和发育

弗兰克氏放线菌通过感染尼泊尔马桑的根毛侵入根的皮层细胞。由于内生菌侵入的刺激,部分皮层细胞分裂和增大,产生前根瘤原基。根瘤原基分裂、分化,形成初生根瘤瘤片。瘤片顶端分生组织不断双叉分枝,发育,并伴随着内生菌感染的寄主细胞,产生多次双叉分枝的珊瑚状根瘤。观察瘤片的横切面,含菌组织是一个马蹄形的致密整体,不完全地包围着稍偏的中柱。观察瘤片的纵切面,可将其划分为6个区域,即顶端分生组织,未感染皮层细胞组织、新感染含菌组织、成熟含菌组织、衰老含菌组织和中柱及其外围数层富含淀粉粒的皮层细胞。     

The relationships of the genus Cicer L. (Leguminosae): the evidence from pollen morphology

The genus Cicer has traditionally been placed in the Vicieae, although it has a number of morphological characters which suggest that it is out of place in that tribe and that its affinities lie elsewhere. A survey of pollen morphology in Cicer , the other genera of the Vicieae, the Trifolieae and the Ononideae has been carried out to help determine the relationships of Cicer. The tribe Vicieae (without Cicer) is very homogeneous and is characterized by its long, rectangular pollen grains with small, heavily thickened endoapertures. The Trifolieae is more variable in its pollen morphology but, in general, has rather similar grains to the Vicieae although the structure of the endoaperture is different. The Ononideae and Cicer have nearly spheroidal pollen with very large, unthickened endoapertures. It therefore appears that as far as pollen characters are concerned, Cicer does not belong in the Vicieae but has much more in common with the Ononideae.     

Abnormal root and nodule vasculature in R50 (sym16), a pea nodulation mutant which accumulates cytokinins

BACKGROUND AND AIMS: R50 (sym16) is a pea nodulation mutant with fewer and shorter lateral roots (LR), fewer nodules and high levels of cytokinins (CK). Because a link exists between CK imbalance and abnormal vasculature, the vasculature of the primary root (PR) and LR of R50 was studied and it was compared with that of the wild-type 'Sparkle'. Also nodule vasculature was investigated to correlate R50 low nodulation phenotype with CK accumulation. METHODS: PR and first-order LR were hand-sectioned transversely in different locations and at different ages. Vascular poles were counted and root and stele diameters measured. To evaluate LR primordia number, roots were cleared. Nodules obtained from inoculated plants were either fixed and sectioned or cleared; numbers of vascular strands and of tracheary elements in the strands were counted. KEY RESULTS: 'Sparkle' PR is triarch, whereas that of R50 can be triarch, tetrarch or pentarch. Furthermore, as the R50 roots developed, supernumerary vascular strands appeared but, as they aged, the new growth of more roots displayed the triarch pattern. LR vasculature differed from that of PR: whereas 'Sparkle' LR had three or four poles, those of R50 had two or three. No differences in PR or PR stele diameters existed between the two lines. Whereas 'Sparkle' nodules had two vascular strands, most R50 nodules possessed three; however, because R50 nodules were variable in size, their vasculature was highly diverse in terms of strand length. A strong correlation was found between nodule length and number of tracheary elements in strands. CONCLUSIONS: R50 displays an additional number of vascular poles in its PR, a smaller number of vascular poles in its first-order LR and an altered vasculature in its nodules. It appears that these three characteristics are linked to the high levels of CKs that the mutant accumulates over its development.     

朝鲜白头翁分生结节的诱导与组织解剖学观察

以朝鲜白头翁(Pulsatilla koreana)的叶柄为材料诱导分生结节, 利用常规石蜡切片法和树脂包埋切片法研究了朝鲜白头翁离体形态发生的解剖学特点。结果表明: 叶柄在MS+3 mg⋅L^–1玉米素(zeatin, ZEA)+0.5 mg⋅L^–1吲哚乙酸(IAA)的诱导培养基上培养42天后, 分生结节诱导率为82.5%; 培养56天后, 95%的分生结节转化成不定芽。组织解剖结构观察结果显示, 培养7、14、28和42天时分别观察到前分生结节结构、形成层和拟分生组织结构、顶端分生组织、叶原基结构。朝鲜白头翁的不定芽起源于分生结节内部的维管中心。新分化芽基部类似愈伤组织的细胞团的显微切片结果显示, 基部组织上分布着表皮细胞或下表皮细胞、维管束形成层和拟分生组织细胞, 它们在朝鲜白头翁器官分化中发挥重要作用。     

Broad screening of the legume family for variability in seed insecticidal activities and for the occurrence of the A1b-like knottin peptide entomotoxins

Pea albumin 1b (PA1b) is a small sulphur-rich peptide from pea seeds, also named leginsulin because of the binding characteristics of its soybean orthologue. Its insecticidal properties were discovered more recently. By using a combination of molecular, biochemical and specific insect bioassays on seed extracts, we characterised genes from numerous Papilionoideae, but not from Caesalpinioideae or Mimosoideae, although the last group harboured species with partially positive cues (homologous biological activities). The A1b defence peptide family, therefore, appears to have evolved relatively late in the legume lineage, maybe from the sophoroid group (e.g. Styphnolobium japonicum). However, unambiguous sequence information is restricted to a group of tribes within the subfamily Papilionoideae (Psoraleae, Millettieae, Desmodieae, Hedysareae, Phaseoleae, Vicieae, and the now clearly polyphyletic "Trifolieae" and "Galegeae"). Recent diversification by gene duplications has occurred in many species, or longer ago in some lineages (Medicago truncatula), as well as probable gene or expression losses at different taxonomic levels (Loteae, Vigna subterranea).     

Vascular transport and soybean nodule function: nodule xylem is a blind alley, not a throughway

Abstract. The only published consideration of product removal from the soybean root nodule hypothesizes that the peripheral xylem circuit of this determinate nodule structure is flushed by the transpiration stream. However, dyes fed to the transpiration stream through a cut root distal to the nodule do not enter the nodule, and the observed movement of radio-tracers from the root into the nodule can be explained by simple diffusion, Also, there are few xylem elements in the nodule, and these elements are of a small diameter, such that this path can not act as a functional loop of the root system. Further, in this study, nodule vascular strands were never observed to be continuous about the nodule, but were observed to end at the nodule tip in a loop within an intact, closed endodermal sac. Nodule vascular tissue was invested in a pericycle of at least three cell layers. These cells are suggested to be active in the loading of the xylem apoplast with ureides, such that the xylem of the nodule always operates in an export role. Nodule water requirements may be supplied via the phloem or the root cortex apoplasm.     

DEVELOPMENTAL ANATOMY IN ROOTS OF IPOMOEA PURPUREA. I. RADICLE AND PRIMARY ROOT

The developmental anatomy of the primary root of Ipomoea purpurea was studied at several growth stages, beginning with the radicle. The radicle is generally composed of three superimposed tiers of initials, which produce the vascular cylinder, cortex, and columella; and a peripheral band of lateral rootcap-epidermal initials. The radicular cortex contains 16–19 immature laticifers; none of the tissue regions in the radicle contains mature cells. Following germination and during the first 2–3 cm growth of the primary root the apical meristem and its derivative tissues undergo a series of modifications. Root apical diameter decreases as cells in lateral portions of the rootcap elongate; meanwhile, the columella enlarges vertically. The relationship between cortical and columellar initials changes as fewer mitoses occur in the former while the latter remain active. In longer roots the columellar initials are directly in contact with the vascular initials. Cortical size diminishes during early root growth as cortical laticifers and their associated cells cease to be produced by the outer cortical initials and ground meristem. Early procambium, at the level of vascular pattern initiation, decreases in diameter by cellular reorientation, and the vascular cylinder decreases in overall diameter although the tetrarch pattern remains unchanged.     

Structure of the Mesorhizobium huakuii and Rhizobium galegae Nod factors: a cluster of phylogenetically related legumes are nodulated by rhizobia producing Nod factors with alpha,beta-unsaturated N-acyl substitutions

Rhizobia are symbiotic bacteria that synthesize lipochitooligosaccharide Nod factors (NFs), which act as signal molecules in the nodulation of specific legume hosts. Based on the structure of their N-acyl chain, NFs can be classified into two categories: (i) those that are acylated with fatty acids from the general lipid metabolism; and (ii) those (= alphaU-NFs) that are acylated by specific alpha,beta-unsaturated fatty acids (containing carbonyl-conjugated unsaturation(s)). Previous work has described how rhizobia that nodulate legumes of the Trifolieae and Vicieae tribes produce alphaU-NFs. Here, we have studied the structure of NFs from two rhizobial species that nodulate important genera of the Galegeae tribe, related to Trifolieae and Vicieae. Three strains of Mesorhizobium huakuii, symbionts of Astragalus sinicus, produced as major NFs, pentameric lipochitooligosaccharides O-sulphated and partially N-glycolylated at the reducing end and N-acylated, at the non-reducing end, by a C18:4 fatty acid. Two strains of Rhizobium galegae, symbionts of Galega sp., produced as major NFs, tetrameric O-carbamoylated NFs that could be O-acetylated on the glucosamine residue next to the non-reducing terminal glucosamine and were N-acylated by C18 and C20 alpha,beta-unsaturated fatty acids. These results suggest that legumes nodulated by rhizobia synthesizing alphaU-NFs constitute a phylogenetic cluster in the Galegoid phylum.     

Homoglutathione: isolation, quantification and occurrence in legumes

Homoglutathione (hGSH: γ-glutamyl-eysteinyl-β-alanine) was purified from seeds of Phaseolus coccineus L. cv. Preisgewinner, using anion-exchange chromatography and Cu₂O precipitation. Quantitative and specific determination of this thiol is possible by high-performance liquid chromatography (HPLC) after monobromobimane derivatization. The enzymatic recycling assay based on yeast glutathione reductase (EC 1.6.4.2) can also be applied, but only to samples containing either hGSH or glutathione (GSH), since enzyme reaction with hGSH is 2.7 times faster than with GSH. Using the very sensitive HPLC method, the thiol content of leaves, roots and seeds of several legumes was investigated. Although GSH and hGSH were found in all plants analysed, the GSH/hGSH ratio varied greatly within the different tribes as well as within the different organs of plants of one species. In seeds and leaves of Vicieae, only traces of hGSH were found beside the main thiol GSH, whereas in roots the hGSH content exceeded the GSH content. The Trifolieae contained both tripeptides and in the tribe Phaseoleae, hGSH predominated by far.     

Silicon-induced changes in viscoelastic properties of sorghum root cell walls

Silicon is deposited in the endodermal tissue in sorghum (Sorghum bicolor L. Moench) roots. Its deposition is thought to protect vascular tissues in the stele against invasion by parasites and drying soil via hardening of endodermal cells. We studied the silicon-induced changes in mechanical properties of cell walls to clarify the role of silicon in sorghum root. Sorghum seedlings were grown in nutrient solution with or without silicon. The mechanical properties of cell walls were measured in three separated root zones: basal, apical and subapical. Silicon treatment decreased cell-wall extensibility in the basal zone of isolated stele tissues covered by endodermal inner tangential walls. The silicon-induced hardening of cell walls was also measured with increases in elastic moduli (E) and viscosity coefficients (eta). These results provided new evidence that silicon deposition might protect the stele as a mechanical barrier by hardening the cell walls of stele and endodermal tissues. In contrast to the basal zone, silicon treatment increased cell-wall extensibility in the apical and subapical zones with concomitant decrease in E and eta. Simultaneously, silicon promoted root elongation. When root elongation is promoted by silicon, one of the causal factors maybe the silicon-enhanced extensibility of cell walls in the growing zone.     

ROOT DIMORPHISM IN LUDWIGIA PEPLOIDES (ONAGRACEAE): STRUCTURE AND GAS CONTENT OF MATURE ROOTS

Two distinct root types are borne on submerged nodes of the non-woody amphibious plant, Ludwigia peploides (HBK) Raven. The anatomy of downward-growing roots (DGR) and the negatively geotropic upward-growing roots (UGR) demonstrates that structural elements shared by roots can be altered to produce highly modified organs differing in morphology, growth orientation, and in function. Both root types emerge contemporaneously from nodes and both have a similar pattern of cell lineages at the pole of the procambial cylinder. Differences between tissues of both roots become conspicuous with increasing distance from the root-cap junction. In the distal cap of UGR, cells are spherical with much space between them unlike the more familiar tightly packed elements of DGR caps. In DGR, an uninterrupted epidermis surrounds the compact cortex and the hexarch stele occupies 25% of the root diameter. During primary growth, the DGR axis remains thin. In UGR, an open meshwork of cells covers the entire root surface, including the cap. The small stele has three or four xylem poles and fills only 5% of the UGR diameter. The unbranched axes of UGR swell and become spongy as strutlike arms radiate from cells of the primary cortex. Gas-filled space between the arms comprises 88% of the axis volume in mature UGR. Although connections between shoot lacunae and spaces in UGR cannot be seen in the light microscope, gas can pass (25 ml/h) between nodes submerged in anaerobic substrate (O₂ = 0.15 ppm) and UGR which reach the water surface. The porous axis of UGR thus provides a conduit for atmospheric gases into nodes which in turn produce the roots, vegetative branches, and reproductive shoots of this species.     

Review article: The meristem in indeterminate root nodules of Faboideae

In this review, the anatomy of indeterminate legume root nodule is briefly summarized. Next, the indeterminate nodule meristem activity, organization and cell ultrastructure are described in species with a distinct nodule meristem zonation. Finally, the putative primary endogenous factors controlling nodule meristem maintenance are discussed in the context of the well-studied root apical meristem (RAM) of Arabidopsis thaliana.     

Lateral root elongation inVicia faba L.

Summary Mitotic index (MI) was determined in the cap, epidermis, cortex and stele at successive intervals along the apical mm of lateral roots of various specific lengths. This parameter was found to decrease basally along roots of each length examined and to decline as the lateral root elongated. Moreover, MI was different in the various tissues investigated. These results have been discussed with respect to changes in the other parameters of cell proliferation and to root growth by elongation. It is suggested on the basis of the data obtained, and other results in the literature, that epidermal initial cells could be differentiated from those of the cortex and stele before the quiescent centre appeared in these roots, but the initial cells of the latter two tissues were indistinguishable until after the quiescent centre began to form.     

Evidence supporting a non-phloem source of water for export of solutes in the xylem of soybean root nodules

The vascular anatomy of soybean nodules [Glycine max (L.) Merr.] suggests that export of solutes in the xylem should be dependent on influx of water in the phloem. However, after severing of stem xylem and phloem by shoot decapitation, export of ureides from nodules continued at an approximately linear rate for 5h. This result was obtained with decapitated roots remaining in the sand medium, but when roots were disturbed by removal from the rooting medium prior to shoot decapitation, export of ureides from nodules was greatly reduced. Stem exudate could not be collected from disturbed roots, indicating that flow in the root xylem had ceased. Thus, ureide export from nodules appeared to be dependent on a continuation of flow in the root xylem. When seedlings were fed a mixture of ³H₂O and ¹⁴C-inulin for periods of 14–21 min, nodules had higher ³H/¹⁴C ratios than roots from which they were detached. The combined results are not consistent with the proposal that export of nitrogenous compounds from nodules is dependent on import of water via the phloem. The results do support the view that a portion of the water required for xylem export from soybean nodules is supplied via a symplastic route from root cortex to nodule cortex to the nodule vascular apoplast.