Pleiotropic Effects of sym-17 : A Mutation in Pisum sativum L. cv Sparkle Causes Decreased Nodulation, Altered Root and Shoot Growth, and Increased Ethylene Production

R82 (sym-17), a stable mutant of Pisum sativum L. cv Sparkle, is described. The shoot growth of the mutant was less than that of its parent under light or dark growth conditions. Gibberellic acid treatment did not normalize the shoot growth of R82. The mutant had thick and short roots. It formed few nodules, but the specific nitrogenase activity was not affected. R82 produced and contained more ethylene than Sparkle. It also contained more free 1-amino-cyclopropane-1-carboxylic acid than did its parent in both the shoot and the root. The root tip of R82 had a lower activity of ethylene-forming enzyme than that of Sparkle, whereas the whole shoot of R82 had a similar activity. The sensitivity of R82 to exogenous ethylene was not more than that of Sparkle. Exogenous ethylene treatments did not make Sparkle mimic R82, and inhibitors of ethylene biosynthesis or action did not normalize the phenotype of R82. The data suggest that the primary effect of sym-17 is not the enhanced ethylene production.     

Ethylene Inhibitors Restore Nodulation to sym 5 Mutants of Pisum sativum L. cv Sparkle

The sym 5 mutants of pea, Pisum sativum L. cv Sparkle, do not differ in growth habit from their normal parent and nodulate poorly at a root temperature of 20°C. If inhibitors of ethylene formation or action (Co²⁺, aminoethoxyvinylglycine, or Ag⁺) are added to the substrate, nodulation of the sym 5 mutants is increased. Similar treatments of four other mutant sym lines do not restore nodulation. When Ag⁺ is added to the substrate from 4 days before to 4 days after inoculation with rhizobia, nodulation of sym 5 mutants is increased. The roots of the mutant need only be exposed to Ag⁺ for 4 hours to significantly increase nodule numbers. The content of free 1-aminocyclopropane-1-carboxylic acid and the production of ethylene in the lateral roots of sym 5 mutants do not differ from Sparkle.     

Ethylene is involved in the nodulation phenotype of Pisum sativum R50 (sym 16), a pleiotropic mutant that nodulates poorly and has pale green leaves

R50 is characterized as a pleiotropic pea mutant; it forms few nodules and has short lateral roots, short stature and pale leaves. Using grafting techniques, R50 paleness was found to be controlled by the shoot of the mutant whereas the nodulation phenotype was regulated by its root. The paleness of R50 is due to a lower than normal total chlorophyll content in its young leaves. The defect appears to be overcome with age because, as the plant matures, the chlorophyll levels increase in the older leaves. The reduction in stature is attributed to shorter internodes, and the oldest internodes are thicker than those of the parent Sparkle. Upon rhizobial inoculation, R50 forms as many infection threads as Sparkle. However, most of these are arrested in the inner cortex. The threads appear to have lost their directional growth towards the stele, and they coil around within enlarged cortical cells. In addition, very few infection threads are associated with divisions of the inner cortical cells. These aborted nodule primordia are abnormal, flat and mainly composed of cells which have divided anticlinally only. Nodulation of R50 was restored by treating the roots with ethylene inhibitors. The R50 mutant further supports the postulated role of ethylene in regulating rhizobial infection with a probable role in the control of the primordium development.     

Light Microscopy Study of Nodule Initiation in Pisum sativum L. cv Sparkle and in Its Low-Nodulating Mutant E2 (sym 5)

We compared nodule initiation in lateral roots of Pisum sativum (L.) cv Sparkle and in a low-nodulating mutant E2 (sym 5). In Sparkle, about 25% of the infections terminated in the epidermis, a similar number stopped in the cortex, and 50% resulted in the formation of a nodule meristem or an emerged nodule. The mutant E2 (sym 5) was infected as often as was the parent, and it formed a normal infection thread. In the mutant, cell divisions rarely occurred in advance of the infection thread, and few nodule primordia were produced. Growing the mutant at a low root temperature or adding Ag⁺ to the substrate increased the number of cell divisions and nodule primordia. We conclude that, in the E2 line, the infection process is arrested in the cortex, at the stage of initial cell divisions before the establishment of a nodule primordium.     

Characterization of an Ethylene Overproducing Mutant of Tomato (Lycopersicon esculentum Mill. Cultivar VFN8)

Ethylene production rates and tissue ethylene concentrations were determined for the single-gene, Epinastic (Epi) tomato (Lycopersicon esculentum Mill.) mutant, and its parent, cv VFN8. The Epi phenotype was characterized by severe leaf epinasty, thickened stems and petioles, and a compact growth habit. In 4-day-old seedlings, ethylene production was significantly higher in Epi than in VFN8. Ethylene production rates also were higher for excised root, hypocotyl, cotyledon, and shoot tissue of 14-day-old Epi seedlings as compared with VFN8. The greatest difference in the ethylene production rate was observed in excised Epi shoot tissue, which was more than 2.5 times higher than in VFN8. Tissue ethylene concentrations of 19−, 25−, and 31-day-old Epi plants were 8, 172, and 307% higher than for VFN8, corresponding to increasing expression of the Epi phenotypic characteristics with age. The highest ethylene concentrations occurred in the shoot apex of both genotypes. Higher ethylene concentrations in Epi resulted from greater 1-aminocyclopropane-1-carboxylic acid content rather than increased ethylene-forming enzyme activity. The elevated ethylene levels in Epi did not result from increased auxin sensitivity. The sensitivity of root growth to inhibition by ethylene did not differ between VFN8 and Epi. Although elevated levels of ethylene in Epi plants apparently exacerbate its epinastic growth characteristics, other evidence indicates that this may not be the fundamental lesion. This mutant may provide a unique system for investigating the regulation of ethylene biosynthesis and the role of target cell types in plant development.     

Phenotypic characterization of sym 21, a gene conditioning shoot-controlled inhibition of nodulation in Pisum sativum cv. Sparkle

E132 ( sym 21) is a stable pleiotropic mutant of Pisum sativum cv. Sparkle obtained by mutagenesis with ethyl methane sulfonic acid. The line forms few nodules and short, highly branched roots. Microscopy studies revealed that infection by rhizobia is normal, and low nodulation is mainly due to a low rate of emergence of the nodule meristems. E132 shoots depressed nodulation on Sparkle stocks, whereas in reciprocal grafts more nodules formed on E132 stocks than on control roots or self-grafted Sparkle plants. Nodule number on the mutant was slightly increased by exogenous ethylene inhibitors, which, however, did not alter the root phenotype.     

Exogenous Ethylene Inhibits Nodulation of Pisum sativum L. cv Sparkle

Exogenous ethylene inhibited nodulation on the primary and lateral roots of pea, Pisum sativum L. cv Sparkle. Ethylene was more inhibitory to nodule formation than to root growth; nodule number was reduced by half with only 0.07 μL/L ethylene applied continually to the roots for 3 weeks. The inhibition was overcome by treating roots with 1 μm Ag⁺, an inhibitor of ethylene action. Exogenous ethylene also inhibited nodulation on sweet clover (Melilotus alba) and on pea mutants that are hypernodulating or have ineffective nodules. Exogenous ethylene did not decrease the number of infections per centimeter of lateral pea root, but nearly all of the infections were blocked when the infection thread was in the basal epidermal cell or in the outer cortical cells.     

Ethylene Inhibitors Partly Restore Nodulation to Pea Mutant E 107 (brz)

E107 (brz) is a pleiotropic mutant of pea (Pisum sativum L. cv Sparkle) characterized by low nodulation, leaf necrosis, excessive ion accumulation, and decreased plant size. The defective nodulation of E107 was studied by light microscopy of lateral roots. The number of infections per centimeter of lateral root was only a third that of Sparkle. Moreover, most of the infections were aborted early; i.e. in only 14% of the infections did the infection thread penetrate beyond the epidermis. Nodulation of E107 was partly restored by treating the plant with the ethylene inhibitors aminoethoxyvinylglycine (AVG) or Ag⁺. Treatment with Ag⁺ did not increase the number of infections, but half of the infections went to completion. Ag⁺ and AVG did not alter the size of the mutant, the accumulation of cations in its shoots, nor the leaf necrosis. Thus, in E107, nodule development can be uncoupled from other pleiotropic characteristics.     

豌豆Sparkle及其单基因突变体E107的铁锰吸收及转移效率

用豌豆Ｓｐａｒｋｌｅ及其单基因突变体Ｅ１０７进行的水培的试验表明,－Ｆｅ和＋Ｆｅ处理的Ｅ１０７幼苗以及－Ｆｅ处理的Ｓｐａｒｋｌｅ幼苗均表现出根系Ｈ＋分泌量大、根系Ｆｅ（Ⅲ）还原力强等特点,其中尤以＋Ｆｅ处理的Ｅ１０７最为突出;而十Ｆｅ处理的Ｓｐａｒｋｌｅ则无以上特点。与Ｓｐａｒｋｌｅ相比,Ｅ１０７各处理的地上部Ｆｅ、Ｍｎ合量均很高,但根部含量则相反。与Ｓｐｅｋｌｅ相比,Ｅ１０７—Ｆｅ处理表现为Ｆｅ高效,即使在＋Ｆｅ处理下,Ｅ１０７仍表现出－Ｆｅ条件下的根系生理特性,活化并还原了根际大量Ｆｅ（Ⅲ）和Ｍｎ,因而它对Ｆｅ、Ｍｎ具有较高的吸收效率,但是这些元素并不在根系中贮存,而是源源不断地运输到地上部,并在叶片中累积乃至使叶片中毒坏死,充分表现了Ｅ１０７单基因突变体对Ｆｅ、Ｍｎ也具有较高的转移效率。     

Effects of cytokinin on ethylene production and nodulation in pea (Pisum sativum) cv. Sparkle

In this study, we were interested in learning if cytokinins play a role in the developmental process that leads to nodulation in the pea cv. Sparkle. We demonstrate that the application of the synthetic cytokinin BAP (6-benzyl-amino-purine) results in a number of nodulation-related changes. BAP stimulates the production of ethylene, a known inhibitor of nodulation. At low levels (up to 1 μ M ), BAP also stimulates nodulation but as its concentration is increased (up to 25 μ M ), nodule number decreases. In BAP-treated roots, the infection threads are abnormal; they are twisted, very knotty, and generally grow in a direction parallel to the root surface. In addition, the centers of cell division in the inner cortex are very few. Thus, BAP-treated Sparkle appears to phenocopy the low-nodulating pea mutant R50 [Guinel FC, Sloetjes LL (2000) Ethylene is involved in the nodulation phenotype of Pisum sativum R50 ( sym 16 ), a pleiotropic mutant that nodulates poorly and has pale green leaves. J Exp Bot 51: 885–894]. However, it appears doubtful that there is a direct correlation between the actions of cytokinin and ethylene in causing a reduction in nodule organogenesis because nodulation is not restored by treating BAP-treated Sparkle with ethylene inhibitors.     

ABA content in shoots and roots of pea mutants af and tl as related to their growth and morphogenesis

The comparative study of shoot and root growth was carried out, and the level of ABA therein determined in the mutant af and tl and wild-type isogenic lines of pea. The recessive af mutation transformed the leaflets into tendrils, and the tl mutation transformed the tendrils into leaflets. These mutations did not affect the length and number of internodes. In all plants, the level of ABA in the leaves was 3–10 times greater than in the roots, and in the course of vegetative growth it rose in both organs. An increase in the shoot area of tl mutant did not change the dry weight of underground and above-ground parts; therefore, the ratio shoot/root in the mutant was identical to that in the wild-type plants. The maintenance of shoot dry weight in the tl mutant at the level of wild-type plant while its area considerably increased was accounted for by a decrease in the thickness of the leaflet and stipule blades. The level of ABA in the stipules of mutant plants was greater than in the wild-type plants. A decrease in the shoot area in the af mutant brought about a decline in its dry weight; however, the ratio root/shoot was maintained at the wild-type level due to a reduced accumulation of dry weight by the root. The level of ABA in the roots of the af mutant was twice greater than in the leafy forms. ABA was assumed to participate in the control over the root growth exerted by the shoot. The absence of leaflets in the af plants was partially compensated for by expanding stipules. The level of ABA therein was three times higher than in the plants of wild type and comparable with the level in the leaflets of the tl mutant and in the wild-type plants. The role of ABA in the growth and final size of leaf blades is discussed.     

Physiological Characteristics of Fe Accumulation in the ;Bronze' Mutant of Pisum sativum L., cv ;Sparkle' E107 (brz brz)

The pea (Pisum sativum L.) mutant, E107 (brz, brz) accumulated extremely high concentrations of Fe in its older leaves when grown in light rooms in either defined nutrient media or potting mix, or outdoors in soil. Leaf symptoms (bronze color and necrosis) were correlated with very high Fe concentrations. When E107 plants were grown in nutrient solutions supplied 10 μm Fe, as the Fe(III)-N,N′-ethylenebis[2-(2-hydroxyphenyl)glycine] chelate, their roots released higher concentrations of Fe(III) reducing substances to the nutrient media than did roots of the normal parent cv, `Sparkle.' Reciprocal grafting experiments demonstrated that the high concentrations of Fe in the shoot was controlled by the genotype of the root. In short-term <sup>59</sup>Fe uptake studies, 15-day-old E107 seedlings exhibited higher rates of Fe absorption than did `Sparkle' seedlings under Fe-adequate growth conditions. Iron deficiency induced accelerated short-term Fe absorption rates in both mutant and normal genotypes. Iron-treated E107 roots also released larger amounts of both protons and Fe(III) reductants into their nutrient media than did iron-treated `Sparkle' roots. Furthermore, the mutant translocated proportionately more Fe to its shoot than did the parent regardless of Fe status.     

alpha-Ketoglutarate dehydrogenase mutant of Rhizobium meliloti.

A mutant of Rhizobium meliloti selected as unable to grow on L-arabinose also failed to grow on acetate or pyruvate. It grew, but slower than the parental strain, on many other carbon sources. Assay showed it to lack alpha-ketoglutarate dehydrogenase (kgd) activity, and revertants of normal growth phenotype contained the activity again. Other enzymes of the tricarboxylic acid cycle and of the glyoxylate cycle were present in both mutant and parent strains. Enzymes of pyruvate metabolism were also assayed. L-Arabinose degradation in R. meliloti was found to differ from the known pathway in R. japonicum, since the former strain lacked 2-keto-o-deoxy-L-arabonate aldolase but contained alpha-ketoglutarate semialdehyde dehydrogenase; thus, it is likely that R. meliloti has the L-arabinose pathway leading to alpha-ketoglutarate rather than the one to glycolaldehyde and pyruvate. This finding accounts for the L-arabinose negativity of the mutant. Resting cells of the mutant were able to metabolize the three substrates which did not allow growth.     

Elongation by primary lateral roots and adventitious roots during conditions of hypoxia and high ethylene concentrations

Soil flooding results in unusually low oxygen concentrations and high ethylene concentrations in the roots of plants. This gas composition had a strongly negative effect on root elongation of two Rumex species. The effect of low oxygen concentrations was less severe when roots contained aerenchymatous tissues, such as in R. palustris Sm. R. thyrsiflorus Fingerh., which has little root porosity, was much more affected. Ethylene had an even stronger effect on root elongation than hypoxia, since very small concentrations (0.1 cm³ m^?3) reduced root extension in the two species, and higher concentrations inhibited elongation more severely than did anoxia in the culture medium. Thus, ethylene contributes strongly to the negative effects of flooding on root growth. An exception may be the highly aerenchymatous, adventitious roots of R. palustris. Aerenchyma in these roots provides a low-resistance diffusion pathway for both endogenously produced ethylene and shoot-derived oxygen. This paper shows that extension by roots of R. palustris in flooded soil depends almost completely on this shoot-derived oxygen, and that aerenchyma prevents accumulation of growth-inhibiting levels of ethylene in the root.     

Influence of Four Nematodes on Root and Shoot Growth Parameters in Grape

Two grape cultivars, susceptible French Colombard and tolerant Rubired, and four nematodes, Meloidogyne incognita, Pratylenchus vulnus, Tylenchulus semipenetrans, and Xiphinema index, were used to quantify the equilibrium between root (R) and shoot (S) growth. Root and shoot growth of French Colombard was retarded by M. incognita, P. vulnus, and X. index but not by T. semipenetrans. Although the root growth of Rubired was limited by all the nematodes, the shoot growth was limited only by X. index. The R:S ratios of Rubired were higher than those of French Colombard. The reduced R:S ratios of Rubired were primarily an expression of reduction in root systems without an equal reduction in shoot growth, whereas in French Colombard the reduced R:S ratios were due to a reduction in both shoot growth and root growth and to a greater reduction in root growth than shoot growth. All nematodes reproduced equally well on both cultivars. Both foliage and root growth of French Colombard were significantly reduced by M. incognita and P. vulnus. Nematodes reduced the shoot length by reducing the internode length. Accumulative R:S ratios in inoculated plants were significantly smaller than those in controls in all nematode treatments but not at individual harvest dates. Bud break was delayed by X. index and was initiated earlier by P. vulnus and M. incognita. All buds in nematode treatments were less vigorous than in controls.     

Iron stress-induced changes in root epidermal cell fate are regulated independently from physiological responses to low iron availability

Iron-overaccumulating mutants were investigated with respect to changes in epidermal cell patterning and root reductase activity in response to iron starvation. In all mutants under investigation, ferric chelate reductase activity was up-regulated both in the presence and absence of iron in the growth medium. The induction of transfer cells in the rhizodermis appeared to be iron regulated in the pea (Pisum sativum L. cv Dippes Gelbe Viktoria and cv Sparkle) mutants bronze and degenerated leaflets, but not in roots of the tomato (Lycopersicon esculentum Mill. cv Bonner Beste) mutant chloronerva, suggesting that in chloronerva iron cannot be recognized by putative sensor proteins. Experiments with split-root plants supports the hypothesis that Fe(III) chelate reductase is regulated by a shoot-borne signal molecule, communicating the iron status of the shoot to the roots. In contrast, the formation of transfer cells was dependent on the local concentration of iron, implying that this shoot signal does not affect their formation. Different repression curves of the two responses imply that the induction of transfer cells occurs after the enhancement of electron transfer across the plasma membrane rather than being causally linked. Similar to transfer cells, the formation of extra root hairs in the Arabidopsis mutant man1 was regulated by the iron concentration of the growth medium and was unaffected by interorgan signaling.     

SPATIAL AND TEMPORAL DEVELOPMENT OF IRON(III) REDUCTASE ACTIVITY IN ROOT SYSTEMS OF PISUM SATIVUM (FABACEAE) CHALLENGED WITH IRON-DEFICIENCY STRESS

The development of plasma membrane-associated iron(III) reductase activity was characterized in root systems of Pisum sativum during the first 2 wk of growth, as plants were challenged with iron-deficiency stress. Plants of a parental genotype (cv. Sparkle) and a functional iron-deficiency mutant genotype (E107) were grown hydroponically with or without supplemental iron. Iron(III) reductase activity was visualized by placing the roots in an agarose matrix containing 0.2 idm Fe(III)-ethylenediaminetetraacetic acid and 0.3 mM Na₂-bathophenanthrolinedisulfonic acid (BPDS). Red staining patterns, resulting from the formation of Fe(II)-BPDS, were used to identify iron(III)-reducing regions. Iron(III) reduction was extensive on roots of E107 as early as d 7, but not until d 11 for -Fe-treated Sparkle. Roots of +Fe-treated Sparkle showed limited regions of reductase activity throughout the period of study. For secondary lateral roots, iron(III) reduction was found for all growth types except + Fe-treated Sparkle. Treating Sparkle plants alternately to a cycle of iron deficiency, iron sufficiency, and iron deficiency revealed that reductase activity at a given root zone could be alternatively present, absent, and again present. Our results suggest that for Pisum roots grown under the present conditions, iron-deficiency stress induces the activation of iron(III) reductase capacity within 2 d.     

Is the Diageotropic Tomato Ethylene Deficient?

The production of ethylene by a mutant form of tomato (Lycopersicon esculentum Mill. cv. Ailsa Craig) with diageotropic shoot growth was compared with that from non-mutant, upright plants. No difference in the rate of production by segments of petiole or stem apex was observed. The amounts of ethylene produced by excised segments of petiole from diageotropic and upright plants in response to wounding were also comparable. When the roots of either kind of plant were exposed to anaerobic conditions, the production of ethylene increased in the petioles; in ordinary plants this was associated with epinastic curvature, while in diageotropic plants the direction of shoot extension became reorientated from the horizontal to a more upright position. Exogenous ethylene gas had similar effects. These results support the view that the mutant has a modified response mechanism to gravity and to ethylene rather than an abnormally slow rate of ethylene production in the shoot. Since applying inhibitors of ethylene action to non-mutant, upright plants did not induce diageotropism, endogenous ethylene seems unlikely to play a significant role in maintaining their upright orientation. The roots of both kinds of plant produced large amounts of ethylene, although the rate for diageotropic roots was about 37% less than that of roots from normal plants. Application of indol-3-ylacetic acid increased the production of ethylene by all roots but those from mutant plants were less responsive.     

Biochemical genetics of further chlorate resistant, molybdenum cofactor defective, conditional-lethal mutants of barley

Summary Three plants, R9201 and R11301 (from cv. Maris Mink) and R12202 (from cv. Golden Promise), were selected by screening M₂ populations of barley (Hordeum vulgare L.) seedlings (mutagenised with azide in the M₁) for resistance to 10 mM potassium chlorate. Selections R9201 and R11301 were crossed with the wild-type cv. Maris Mink and analysis of the F₂ progeny showed that one quarter lacked shoot nitrate reductase activity. These F₂ plants also withered and died in the continuous presence of nitrate as sole nitrogen source. Loss of nitrate reductase activity and withering and death were due in each case to a recessive mutation in a single nuclear gene. All F1 progeny derived from selfing selection R12202 lacked shoot nitrate reductase activity and also withered and subsequently died when maintained in the continuous presence of nitrate as sole nitrogen source. All homozygous mutant plants lacked not only shoot nitrate reductase activity but also shoot xanthine dehydrogenase activity. The plants took up nitrate, and possessed wild-type or higher levels of shoot nitrite reductase activity and NADH-cytochrome c reductase activity when treated with nitrate for 18 h. We conclude that loss of shoot nitrate reductase activity, xanthine dehydrogenase activity and withering and death, in the three mutants R9201, R11301 and R12202 is due to a mutation affecting the formation of a functional molybdenum cofactor. The mutants possessed wild-type levels of molybdenum and growth in the presence of unphysiologically high levels of molybdate did not restore shoot nitrate reductase or xanthine dehydrogenase activity. The shoot molybdenum cofactor of R9201 and of R12202 is unable to reconstitute NADPH nitrate reductase activity from extracts of the Neurospora crassa nit-1 mutant and dimerise the nitrate reductase subunits present in the respective barley mutant. The shoot molybdenum cofactor of R11301 is able to effect dimerisation of the R11301 nitrate reductase subunits and can reconstitute NADPH-nitrate reductase activity up to 40% of the wild-type molybdenum cofactor levels. The molybdenum cofactor of the roots of R9201 and R11301 is also defective. Genetic analysis demonstrated that R9201, but not R11301, is allelic to R9401 and Az34 (nar-2a), two mutants previously shown to be defective in synthesis of molybdenum cofactor. The mutations in R9401 and R9201 gave partial complementation of the nar-2a gene such that heterozygotes had higher levels of extractable nitrate reductase activity than the homozygous mutants.We conclude that: (a) the nar-2 gene locus encodes a step in molybdopterin biosynthesis; (b) the mutant R11301 represents a further locus involved in the synthesis of a functional molybdenum cofactor; (c) mutant Rl2202 is also defective in molybdopterin biosynthesis; and (d) the nar-2 gene locus and the gene locus defined by R11301 govern molybdenum cofactor biosynthesis in both shoot and root.