The Optimum Angle of Geotropic Stimulation and its Relation to the Starch Statolith Hypothesis

Roots which are turned from their normal direction to directions at various angles with the plumb line develop the largest geotropic curvatures during a subsequent klinostat rotation period when the stimulation angle is well above the horizontal. In experiments with roots of Lepidium sativum L., the optimum is located at 120 to 140° when the stimulation time is between 2 and 15 min. If this fact is to be explained by the movements of amyloplasts in the root cap cells, one would expect roots which bad been kept inverted before the stimulation (so that the moveable amyloplasts are accumulated in the opposite end of the cells) to show an optimum angle well below 90°. — Pre-inversion of the roots did suppress the curvatures produced by stimulation at angles larger than 90° when measured after 10 to 30 min of klinostat rotation. This suppression may be taken as a support for the starch statolith hypothesis, since the amyloplasts in pre-inverted roots placed at angles exceeding 90° have a restricted opportunity to slide along the cell walls compared to non-inverted roots placed at the same angles. In pre-inverted roots measured after a period of klinostat rotation, however, no optimum was found at angles below 90°. When the stimulation time was 3.75 min, the response curves were nearly symmetrical about 90°. Stimulation for 15 min, on the other hand, resulted in curvatures which were much larger (although suppressed in comparison with non-inverted roots) when the stimulation angle was 165° than when it was 15°. During the 15 min stimulation period itself, however, pre-inverted roots curved 0.3° when stimulated at 15, but only 3.4° at 165°. This small difference was very highly significant and is in agreement with the starch statolith hypothesis insofar as the amyloplasts in pre-inverted roots placed at 15° have the greatest opportunity to slide along the cell walls. The lack of further development (and the actual decrease) of their curvatures during the subsequent klinostat rotation must then be due to other, depressing, factors, summarily designated as tonic. At angles above 90°, the tonic factors are either absent or even enhancing. Tbe tonic effects cannot be explained by amyloplast movements.     

Crystallographic characterization of the α,γ C12 helix in hybrid peptide sequences

The solid‐state conformations of two αγ hybrid peptides Boc‐[Aib‐γ⁴(R)Ile]₄‐OMe 1 and Boc‐[Aib‐γ⁴(R)Ile]₅‐OMe 2 are described. Peptides 1 and 2 adopt C₁₂‐helical conformations in crystals. The structure of octapeptide 1 is stabilized by six intramolecular 4 → 1 hydrogen bonds, forming 12 atom C₁₂ motifs. The structure of peptide 2 reveals the formation of eight successive C₁₂ hydrogen‐bonded turns. Average backbone dihedral angles for αγ C₁₂ helices are peptide 1 , Aib; φ (°) = ?57.2 ± 0.8, ψ (°) = ?44.5 ± 4.7; γ⁴(R)Ile; φ (°) = ?127.3 ± 7.3, θ₁ (°) = 58.5 ± 12.1, θ₂ (°) = 67.6 ± 10.1, ψ (°) = ?126.2 ± 16.1; peptide 2 , Aib; φ (°) = ?58.8 ± 5.1, ψ (°) = ?40.3 ± 5.5; ψ⁴(R)Ile; φ (°) = ?123.9 ± 2.7, θ₁ (°) = 53.3 θ 4.9, θ ₂ (°) = 61.2 ± 1.6, ψ (°) = ?121.8 ± 5.1. The tendency of γ⁴‐substituted residues to adopt gauche–gauche conformations about the C^α–C^β and C^β–C^γ bonds facilitates helical folding. The αγ C₁₂ helix is a backbone expanded analog of α peptide 3₁₀ helix. The hydrogen bond parameters for α peptide 3₁₀ and α‐helices are compared with those for αγ hybrid C₁₂ helix. Copyright © 2016 European Peptide Society and John Wiley & Sons.     

Chemical Composition,Antibacterial, Antioxidant and in Vitro Antidiabetic Activities of Essential Oils from Eruca vesicaria

This work describes the study of the chemical composition and bioactivity of the essential oils (EOs) of the different organs (leaves, flowers, stems and roots) from Eruca vesicaria. According to the GC and GC/MS analysis, all the EOs were dominated by erucin (4‐methylthiobutyl isothiocyanate) with a percentage ranging from 17.9 % (leaves) to 98.5 % (roots). The isolated EOs were evaluated for their antioxidant (DPPH, ABTS and β‐carotene/linoleic acid), antibacterial and inhibitory property against α‐amylase and α‐glucosidase. Most EOs exhibited an interesting α‐glucosidase and α‐amylase inhibitory potential. The roots essential oil was found to be the most active with IC₅₀ values of 0.80±0.06 and 0.11±0.01 μg mL^?1, respectively. The essential oil of roots exhibited the highest antioxidant activity (DPPH, PI=92.76±0.01 %; ABTS, PI=78.87±0.19; and β‐carotene, PI=56.1±0.01 %). The isolated oils were also tested for their antibacterial activity against two Gram‐positive and three Gram‐negative bacteria. Moderate results have been noted by comparison with Gentamicin used as positive control.     

Geometrical Membrane Curvature as an Allosteric Regulator of Membrane Protein Structure and Function

Transmembrane proteins are embedded in cellular membranes of varied lipid composition and geometrical curvature. Here, we studied for the first time the allosteric effect of geometrical membrane curvature on transmembrane protein structure and function. We used single-channel optical analysis of the prototypic transmembrane β-barrel α-hemolysin (α-HL) reconstituted on immobilized single small unilamellar liposomes of different diameter and therefore curvature. Our data demonstrate that physiologically abundant geometrical membrane curvatures can enforce a dramatic allosteric regulation (1000-fold inhibition) of α-HL permeability. High membrane curvatures (1/diameter ∼1/40 nm⁻¹) compressed the effective pore diameter of α-HL from 14.2 ± 0.8 Å to 11.4 ± 0.6 Å. This reduction in effective pore area (∼40%) when combined with the area compressibility of α-HL revealed an effective membrane tension of ∼50 mN/m and a curvature-imposed protein deformation energy of ∼7 k_BT. Such substantial energies have been shown to conformationally activate, or unfold, β-barrel and α-helical transmembrane proteins, suggesting that membrane curvature could likely regulate allosterically the structure and function of transmembrane proteins in general.     

Über Eiweißkörper in Zellkernen bei Scrophulariaceen; Vorkommen,Form und systematische Bindung

Zusammenfassung Bei 50 Scrophulariaceen-Arten konnten Eiweißkörper in den Zellkernen aufgefunden werden, davon bei 41 zum ersten Mal; somit sind sie nun von insgesamt 82 Arten bekannt (siehe Tab. 1, S. 128–132). Neben den schon bekannten mehr oder minder kugeligen bis unregelmäßig geformten Körpern, Oktaedern und Kristallstapeln treten auch hexagonale Prismen (Veronica chamaedrys. V.×klausii, V. micrantha), Spindeln (V. teucrium, V. austriaca, V. prostrata) und Stäbchen (Limnophila heterophylla, L. sessiliflora) auf. MancheVeronica-Arteri enthalten zweierlei Eiweißkörper in einem Zellkern. Euphrasia kerneri, E. picta, E. rostkoviana, E. salisburgensis, Veronica arvensis, V. triphyllos, Gratiola officinalis undLimosella aquatica haben durchwegs in den Zellkernen keine Eiweißkörper.Über den systematischen Wert der Eiweißkörper wird diskutiert und seine Bedeutung für die infragenerische Gliederung der GattungVeronica aufgezeigt.

---

Protein-bodies in the nuclei of Scrophulariaceae

Summary In 50 species ofScrophulariaceae protein-bodies could be found in the nuclei, in 41 of them for the first time. Thus, now they are known of 82 species (cf. p. 128–132). Together with more or less globose and irregular lobed structures, octaeders, and piles of cristals, as known before, there occur also hexagonal prismas (Veronica chamaedrys, V. ×klausii, V. micrantha), spindles (V. austriaca, V. prostrata, V. teucrium), and little rods (Limnophila heterophylla, L. sessiliflora). Some species ofVeronica, contain two different kinds of protein-bodies in one nucleus.In the nuclei ofEuphrasia kerneri, E. picta, E. rostkoviana, E. salisburgensis, Veronica arvensis, V. triphyllos, Gratiola officinalis andLimosella aquatica protein-bodies do not occur. The possible value of the protein bodies for systematic studies is discussed, and their role for the infrageneric grouping ofVeronica is shown.

     

The Arabidopsis thaliana cDNAs coding for eIF4E and eIF(iso)4E are not functionally equivalent for yeast complementation and are differentially expressed during plant development

Two cDNAs (At.EIF4E1 and At.EIF4E2) encoding, respectively, the eukaryotic initiation factors eIF4E and eIF(iso)4E of Arabidopsis thaliana were isolated by complementation of a Saccharomyces cerevisiae conditional mutant. The deduced amino acid sequences of the proteins are homologous to those from monocotyledonous plants, yeast and mammals. The corresponding genes were identified in YAC clones mapping to chromosome IV (At.EIF4E1) and to chromosome V (At.EIF4E2). The yeast strain complemented by At.EIF4E2 grew poorly compared with an isogenic strain expressing At.EIF4E1. Northern and in situ hybridization analysis show that both Arabidopsis At.EIF4E1 and At.EIF4E2 mRNAs are differentially accumulated in plant tissues. The At.EIF4E1 mRNA is expressed in all tissues except in the cells of the specialization zone of the roots; the At.EIF4E2 mRNA is particularly abundant in floral organs and in young developing tissues. This work further demonstrates an association between a high level of EIF4E mRNAs and cell proliferation and suggests that the plant eIF4E isoforms may have distinct functions in cell development and metabolism.     

Selective excretion of yolk-derived tocotrienols into the bile of the chick embryo

The aim of this study was to investigate the possibility of biodiscrimination between different forms of vitamin E during the development of the chick embryo. The vitamin E present in the initial yolk consisted of α-tocopherol (90%), (β+γ)-tocopherol (8%), α-tocotrienol (0.3%) and (β+γ)-tocotrienol (1.3%). In marked contrast, the vitamin E recovered from the bile of the day-16 embryo contained much higher proportions of α-tocotrienol (10%) and especially of (β+γ)-tocotrienol (42%). By the time of hatching, 56% of the vitamin E present in the bile was in the form of (β+γ)-tocotrienol. The residual yolk of the newly-hatched chick contained far greater proportions of α-tocotrienol (2.6%) and (β+γ)-tocotrienol (10%) than were present in the initial yolk. The results suggest that the liver of the embryo may selectively excrete tocotrienols as components of bile, whilst retaining the tocopherols within the hepatocytes. The increased proportions of tocotrienols in the residual yolk may result from the recycling of bile from the gall bladder to the yolk. The liver of the day-old chick contained α-tocopherol as the main form of vitamin E (90%) with only a small proportion (0.2%) of (β+γ)-tocotrienol. The α-tocopherol form was also the main vitamin E component in the brain (85%), heart (79%), lung (82%) and adipose tissue (91%) of the day-old chick. The present study suggests the occurrence of a high degree of biodiscrimination between tocopherols and tocotrienols during the development of the chick embryo.     

WEG1, which encodes a cell wall hydroxyproline-rich glycoprotein,is essential for parental root elongation controlling lateral root formation in rice

Lateral roots (LRs) determine the overall root system architecture, thus enabling plants to efficiently explore their underground environment for water and nutrients. However, the mechanisms regulating LR development are poorly understood in monocotyledonous plants. We characterized a rice mutant, wavy root elongation growth 1 (weg1), that produced higher number of long and thick LRs (L-type LRs) formed from the curvatures of its wavy parental roots caused by asymmetric cell growth in the elongation zone. Consistent with this phenotype, was the expression of the WEG1 gene, which encodes a putative member of the hydroxyproline-rich glycoprotein family that regulates cell wall extensibility, in the root elongation zone. The asymmetric elongation growth in roots is well known to be regulated by auxin, but we found that the distribution of auxin at the apical region of the mutant and the wild-type roots was symmetric suggesting that the wavy root phenotype in rice is independent of auxin. However, the accumulation of auxin at the convex side of the curvatures, the site of L-type LR formation, suggested that auxin likely induced the formation of L-type LRs. This was supported by the need of a high amount of exogenous auxin to induce the formation of L-type LRs. These results suggest that the MNU-induced weg1 mutated gene regulates the auxin-independent parental root elongation that controls the number of likely auxin-induced L-type LRs, thus reflecting its importance in improving rice root architecture.     

Elastin as a rubber

The thermoelastic behavior of water solvated elastin has been investigated in simple tension, in the temperature range 0–70°C. Specimens purified from both the ox ligamentum nuchae and pig thoracic aorta have been studied. Force data obtained by cycling the temperature for various constant specimen lengths display a separated variable dependence of the form f = A(T)B(α), where T is absolute temperature and α the extension ratio. For ligament elastin B(α) is a linear function whereas for aortic elastin it is a nonlinear function. The applicability of the rubber elasticity theory to elastin has been tested by setting A(T) equal to the temperature-dependent front factor for simple tension of a homogeneous rubber whilst B(α) is left undefined. In this way it has been possible to take into account the fibrous nonhomogeneity of the polymer, and also to avoid any inconsistency within the theory of attributing a dependence of the variable fe/f upon extension ratio. The behavior of both ligament and aortic elastin agrees well with the conclusion that the dominant deformation mechanism is entropy elastic, fe/f ? 1. The linearity of the load isotherm for ligament elastin permits a particularly simple experimental procedure using a single force-temperature plot for one value of interclamp length. Using this procedure high precision has been obtainble, and the data shows a close adherence to the theory with fe/f = 0.1. The relationship between this result and current controversy over the molecular conformation of elastin is discussed.     

The Starch Statolith Hypothesis and the Optimum Angle of Geotropic Stimulation

When roots of cress seedlings (Lepidium sativum L.) are stimulated for 10 min at an angle of 135° (i.e. the root tips are pointing obliquely upward), the resulting geotropic curvatures become larger than after 10 min stimulation at 45°. This well-known behavior has been explained by the better conditions for statoliths, initially located in the floor end of the statocytes, to slide along the cell walls when root tips are pointing upward at 135° than when pointing downward at 45°. Accepting this explanation, one would predict the optimum angle of stimulation to be near 45° when roots had first been kept inverted long enough for their statoliths to accumulate in the opposite end of each functional statocyte. This prediction has been verified in experiments with cress seedlings which were first kept inverted for 16 min, then stimulated for 10 min at given angles, and subsequently rotated parallel to the horizontal axis of the klinostat at 2 rpm. Under these conditions, roots stimulated at 45° curve faster during a 20 to 30 min period on the klinostat than roots stimulated at 135°, but thereafter they stop curving. Roots stimulated at 135°, on the other hand, although initially curving slower than those at 45°, continue curving for at least a whole hour, and attain larger curvatures than the others after 40 min. The optimum shifts from near 45° to near 135° during the course of the klinostat rotation. The behavior of normal and pre-invertcd roots is interpreted as the result of at least two effects: (1) a stimulation due to the movement of amyloplasts, which is enhanced if these are allowed to slide along the cell walls, and (2) a modification of the development of the resulting curvatures by tonic effects, which are inhibitory between stimulation angles 0° and 90°, and absent or enhancing between 90° and 180°.     

Quantitative assessment of the interaction between the antagonistic fungus Talaromyces flavus and the wilt pathogen Verticillium dahliae on eggplant roots

Quantitative aspects of the interaction between the antagonist Talaromyces flavus, the pathogen Verticillium dahliae and eggplant roots, were studied. When eggplant roots were inoculated with T. flavus, prior to the infection with the pathogen, the population density of T. flavus on V. dahliae-infected roots was at least 3 times higher than on healthy uninfected roots, and the proliferation of T. flavus on diseased eggplant roots was related to the severity of wilt symptoms, in the two levels of application of T. flavus studied. However, in all classes of disease severity tested (disease index, 0–3), the population density of T. Flavus on eggplant roots treated with 10⁶ ascospores g^–1 rooting mixture was significantly (p=0.05) higher than with 10⁵ ascospores g^–1. In roots treated with 10⁵ and 10⁶ T. flavus ascospores g^–1 rooting mixture, the population density of V. dahliae was reduced by 51% and 69%, respectively. When testing the relationships between the population density of V. dahliae in the roots and disease severity, no significant (p=0.05) difference was found between disease indexes 2 and 3. However, the density of V. dahliae on roots of plants with disease index 1 was significantly (p=0.05) lower than disease indexes 2 and 3. The positive relationship between the inoculum concentration of V. dahliae and the population density of T. flavus developed on eggplant roots was significant (p=0.001), linear, and highly correlated (r=0.945) on a logarithmic scale. In addition, the analysis of these data revealed a significant (p=0.05), high, negative and linear correlation (r=–0.985) between the log concentration of V. dahliae inoculum and the disease reduction achieved by T. flavus.     

Two new triterpenoids from the roots of Pinus densiflora

Chemical investigation of the roots of Pinus densiflora led to the isolation of two new triterpenoids, (24S)-3β-methoxy-24,25-epoxy-lanost-9(11)-ene (1) and 29-acetoxy-3α-methoxyserrat-14-en-21α-ol (2), together with three known serratene-type triterpenoids (3–5) and four known diterpenoids (6–9). Their structures were determined by spectroscopic analyses.     

Growth,graviresponsiveness and abscisic-acid content of Zea mays seedlings treated with Fluridone

Ten-d-old seedlings of Zea mays L. cv. Tx 5855 treated with 1-methyl-3-phenyl-5-(3-[trifluoromethyl]phenyl)-4-(1H)-pyridinone (Fluridone) were analyzed for abscisic acid (ABA) content using high-performance liquid chromatography with an analysis sensitivity of 2.5 ng ABA g^-1 fresh weight (FW). Seedlings were divided into three portions: leaves, detipped roots, and root tips (terminal 1.5 mm). Control plants (water treatment only; no Fluridone) were characterized by the following amounts of ABA: leaves, 0.114±0.024 (standard deviation) g ABA g^-1 FW; detipped roots, 0.260±0.039±g ABA g^-1 FW; root tips, no ABA detected. We did not detect any ABA in tissues of Fluridone-treated plants. Primary roots of treated and untreated seedlings were strongly graviresponsive, with no significant differences between the curvatures or the growth rates of primary roots of Fluridone-treated and control seedlings. These results indicate that 1) Fluridone completely inhibits ABA synthesis, and 2) ABA is not necessary for positive gravitropism by primary roots of Zea mays.Abbreviations ABA abscisic acid - Fluridone 1-methyl-3-phenyl-5-(3-[trifluoromethyl]phenyl)-4-(1H)-pyridinone - FW fresh weight - SD standard deviation     

Flow-induced forces on free-floating macrophytes

Free-floating macrophytes have buoyant petioles and unanchored roots; certain species are highly invasive, owing to characteristics such as high growth rates and the formation of dense floating mats that drift on wind and water currents. Water hyacinth (Eichhornia crassipes) is one example; its invasion of tropical and subtropical freshwater systems worldwide harms native ecosystems and impedes human activities. This research examines flow-induced forces and biomechanical properties of E. crassipes to better understand flow interactions and transport mechanisms. Drag forces were measured in a flume and a wind tunnel for varying approach velocities and raft configurations; from this data, drag coefficients in water (C _D^w) and air (C _D^a) were developed. Over similar Reynolds number (Re _b ) regimes, C _D^w decrease as Re _b increases while C _D ^a are invariant. For the same raft tested in air and water, water drag exceeds air drag and the value of C _D^w approaches C _D^a at high Re _b . Force–velocity relationships indicate root canopies reconfigure by streamlining in higher flow velocities while leaf canopies do not. Root canopy streamlining is further explained through biomechanical testing: we found the major vegetative structures of E. crassipes (roots, stolons, and petioles) have similar moduli of elasticity but second moments of area are three orders of magnitude smaller in roots compared to stolons or petioles, leading to significantly lower flexural rigidity in roots than in stolons or petioles. Flow interactions with the root canopy differ for an individual plant compared to a raft assemblage. Laboratory results suggest that water currents are the dominant mechanism for E. crassipes dispersal.     

Pathotypic and molecular evolution of contemporary population of Puccinia striiformis f. sp. tritici in Egypt during 2016–2018

The contemporary races of Puccinia striiformis f. sp. tritici (Pst) in Egypt during 2016–2018 were differentiated based on virulence and molecular patterns. Virulence patterns based on the reaction of the 17 World/European differential sets carrying stripe rust resistance genes (Yr genes) resulted in ten races including four new (first recorded in Egypt) and six old (previously recorded in Egypt). The new races were identified as 64E0 (virulence [V] Yr4, Su), 0E16 (V Yr8, 19), 66E0 (V Yr4, 7, 22, 23, Su) and 4E130 (V Yr2, 6, 7, 25, HVII), while the old were 0E0 (avirulence), 2E0 (V Yr7, 22, 23), 2E16 (V Yr7, 8, 19, 22, 23), 4E0 (V Yr2, 6), 6E4 (V Yr2, 6, 7, 22, 23, 25) and 70E4 (V Yr2, 4, 6, 7, 22, 23, 25, Su). Cluster analysis differentiated Pst races based on virulence frequency to Yr genes. Simple sequence repeat (SSR) markers were used to detect the molecular polymorphism of the Pst races. Clustering separated the old and new races into two groups, indicating their common ancestry since the new races were very distinct from the old races. Although clustering based on virulence revealed some evolutionary patterns, where the new races 64E0 and 66E0 may have probably evolved from the old races (2E16, 2E0, 6E4, 70E4) and the new race 4E130 may be evolved from the joint race 4E0. However, clustering based on molecular patterns indicated that the new races appear to be genetically distinct and may represent an exotic introduction rather than a mutation in isolates of the old races. A weak association between virulence and molecular patterns revealed that they are independent of each other. The SSR markers did not correspond to the virulences in the pathogen. Further studies on the potential virulence genes of the detected Pst virulences are needed.     

Cropping as a Phytoremediation Practice for Oily Desert Soil with Reference to Crop Safety as Food

Broad beans (Vicia faba)could tolerate up to 10% (w)w) crude oil in desert soil (sand), therefore, the potential of this crop for cleaning oily desert soil via rhizosphere technology was investigated. The amounts of hydrocarbons recovered from oily desert soil samples supporting V. faba plants were less than the amounts extracted from uncultivated oily soil samples. Excised fresh V. faba roots with their intact rhizospheres resulted in the attenuation of n-octadecane, phenanthrene, and crude oil when shaken into sterile desert soil extract containing these hydrocarbons. The amounts of hydrocarbons eliminated were greater with roots of plants previously raised in oily soil than with roots of plants raised in clean soil. Similar hydrocarbon attenuation effects were recorded when, instead of excised roots, whole plants were used with their roots submerged in the hydrocarbon containing soil extract. The various parts of plants raised in oily desert soil contained more linolenic acid in their total lipids than did the same parts of plants raised in clean desert soil. This was much more pronounced for the roots than for shoots and seeds. The hydrocarbons of roots and shoots of V. faba plants were not as affected by oil pollution as were those of seeds, in which the proportions of very long chain hydrocarbons increased with increasing oil concentration in the soil. Those hydrocarbons are not recommended for human and animal nutrition.     

Thermodynamic Efficiency Limit of Molecular Donor‐Acceptor Solar Cells and its Application to Diindenoperylene/C60‐Based Planar Heterojunction Devices

In organic photovoltaic (PV) cells, the well‐established donor‐acceptor (D/A) concept enabling photo‐induced charge transfer between two partners with suitable energy level alignment has proven extremely successful. Nevertheless, the introduction of such a heterojunction is accompanied with additional energy losses as compared to an inorganic homojunction cell, owing to the presence of a charge‐transfer (CT) state at the D/A interface. Based on the principle of detailed balance, a modified Shockley‐Queisser theory is developed including the essential effects of interfacial CT states, that allows for a quantitative assessment of the thermodynamic efficiency limits of molecular D/A solar cells. Key parameters, apart from the optical gap of the absorber material, entering the model are the energy (E_CT) and relative absorption strength (α_CT) of the CT state. It is demonstrated how the open‐circuit voltage (V_OC) and thus the power conversion efficiency are affected by different parameter values. Furthermore, it is shown that temperature dependent device characteristics can serve to determine the CT energy, and thus the upper limit of V_OC for a given D/A combination, as well as to quantify non‐radiative recombination losses. The model is applied to diindenoperylene (DIP)‐based photovoltaic devices, with open‐circuit voltages between 0.9 and 1.4 V, depending on the partner, that have recently been reported.     

Inoculation of Vicia sativa subsp. nigra roots with Rhizobium leguminosarum biovar viciae results in release of nod gene activating flavanones and chalcones

Flavonoids released by roots of Vicia sativa subsp. nigra (V. sativa) activate nodulation genes of the homologous bacterium Rhizobium leguminosarum biovar viciae (R. l. viciae). Inoculation of V. sativa roots with infective R. l. viciae bacteria largely increases the nod gene-inducing ability of V. sativa root exudate (A.A.N. van Brussel et al., J Bact 172: 5394–5401). The present study showed that, in contrast to sterile roots and roots inoculated with R. l. viciae cured of its Sym plasmid, roots inoculated with R. l. viciae harboring its Sym plasmid released additional nod gene-inducing flavonoids. Using ¹H-NMR, the structures of the major inducers released by inoculated roots, 6 flavanones and 2 chalcones, were elucidated. Roots extracts of (un)inoculated V. sativa contain 4 major non-inducing, most likely glycosylated, flavonoids. Therefore, the released flavonoids may either derive from the root flavonoids or inoculation with R. l. viciae activates de novo flavonoid biosynthesis.     

Bemerkungen zur Karyologie und Systematik einiger Sippen der Gattung Vicia L

Continuing the earlier investigations of Vicia species, karyologically not examined hithero, the following taxa of th genus have been described:

• 1 Chromosome numbers reported for the first time–V. Meyeri Boiss. (2n = 14), V. pubescens (DC.) Link (2n = 14), V. graminea SM (2n = 14), V. ramuliflora (MAXIM .) OHWI (2n = 28), V. semiglabra RUPR . ex BOISS . ssp. caucasica (EKVTIM .) RADZHI (2n = 10), V. semenovii (RGL . et HERD .) FEDTSCH . (2n = 12), V. costata LDB (2n = 12), V. hajastana GROSSH . (2n = 10).
• 2 Re-investigations – V. tenuissima (M. BIEB .) SCHINZ et THELL . (2n = 14), V. benghalensis L. (2n = 14), V. lathyroides L. (2n = 12).

Brief cytological and systematical remarks are given for all the species mentioned above. Discrepancies in the literature are especially discussed (V. benghalensis, V. peregrina, V. lathyroides). Our data support the uniformity of the subgen. Ervum in regard to chromosome number (2n = 14) and primitivity of the karyotype. The finding of an advanced karyotype with 10 chromosomes (V. semiglabra) within the subgen. Cracca has been recorded for the first time. In this group a new polyploid taxon (V. ramuliflora) has been found too. The known polyploid representatives of the genus are summarized, all of which belong to perennial species of the subgen. Cracca. Most of the taxa are characterized by obviously distinct karyotypes, that is partly ture for chromosome sizes too (conspicuously long: V. hajastana, V peregrina; conspicuously shrt: V. ramuliflora, V. lathyrodies). This striking karyological differentiation seems to refer not only to the Old world species but also to the New world ones, of which V. graminea (and a strain named „V. selloi”︁) has been examined for the first time. In general the chromosome number and structure (besides the traditional morphological characters) have been proved as extremely valuable for taxonomical considerations within the genus. This is a common situation in many other plant groups too. We therefore think of further cytotaxonomical studies as especially suitable for explaning the evolution and the evolutionary mechanisms within the genus.