Changes in auxin patterns in developing gynophores of the peanut plant (Arachis hypogaea L.)

The peanut plant (Arachis hypogaea L.) produces flowers aerially, but buries the recently fertilized ovules in the soil in order for the fruit and seeds to mature underground. The organ that carries the seeds into the soil is called the gynophore. The growth of the peanut gynophore is regulated primarily by indole-3-acetic acid (IAA). A monoclonal antibody raised against IAA was used to successfully detect and localize this growth substance in the tissues of developing peanut gynophores. Five different stages of development were analysed: (1) before fertilization; (2) after fertilization; (3) during downwards growth; (4) at soil penetration; and (5) at the early stages of fruit formation. While no auxin signal is visible in the unfertilized ovules and ovary region, an asymmetric signal is observed in the gynophore wall after fertilization. During downwards growth, the auxin signal is located in both the meristematic region and in the area encircling the seeds, as well as in the cortex and epidermis region of the elongation zone. Upon soil penetration, the auxin signal in the meristematic region disappears, and most of the signal is detected in the gynophore wall near the tip. At the early stages of peanut fruit development, auxin signal is found at the lowermost area of the bending fruit, which eventually causes the fruit to be positioned horizontally. The results of this study suggest that the possible source of auxin within the gynophore may be the area of the gynophore wall close to the tip.     

Auxin redistributes upwards in graviresponding gynophores of the peanut plant

The peanut (Arachis hypogaea L.) produces flowers aerially, but buries the recently fertilized ovules into the soil, where fruit and seed development occur. The young seeds are carried down into the soil at the tip of a specialized organ called the gynophore. Although the gynophore has a typical shoot anatomy, it responds positively to gravity like a root. In this study, we explore the role of the plant growth regulator indole-3-acetic acid (IAA) in the growth and the gravitropic response of the peanut gynophore. With an immunolocalization technique using an IAA monoclonal antibody, we localized IAA within the tissues of vertically oriented and gravistimulated gynophores. We found that in vertically oriented gynophores, IAA labeling occurs in the periphery of the gynophore, in the entire cortex and epidermis. Within 20 min of horizontal reorientation, the IAA signal gradually increases in the upper cortex/epidermis and diminishes in the lower cortex/epidermis. At 1.5 h after gravistimulation, all of the IAA immunolocalization signal is detected in the upper cortex and epidermis – none is detected in the lower side. Growth rate measurements also indicate that after 1–2 h of reorientation, the growth rate maximum on the upper side corresponds temporally and spatially to the growth rate minimum on the lower side. Experiments using radioactively labeled IAA corroborate an upper-side redistribution of this hormone upon horizontal reorientation. These results are analyzed with respect to the current theories of plant gravitropic response, and a model for a possible gravity-induced IAA redistribution from the lower to the upper side of the peanut gynophore is proposed. Received: 25 January 1999 / Accepted: 24 February 1999     

Photomorphogenesis of the Gynophore, Pod and Embryo in Peanut, Arachis hypogaea L.

Darkened excized gynophores ceased to elongate after 8–10days in vitro and started to form a pod. Gynophore elongationwas inhibited to a greater extent in total darkness than underlow irradiance, while pod and embryo growth was stimulated indarkness only. Intact gynophores, enclosed in transparent vials containingglass beads, continued to elongate in both light and darkness.In light the elongating gynophores thickened as they penetratedbetween the glass beads, forming a seedless pod at the bottomof the vials. In the dark the elongating gynophores producedsmall pods in which the seeds had started to grow. Excized gynophores elongated in vitro under continuous whitelight at a rate similar to that of intact exposed gynophores.The rate of elongation in vitro, was lower under continuousblue or red-enriched light, than under white light, and wasfurther reduced under continuous far-red irradiation. Pods didnot form during any of the continuous irradiation treatmentsbut only after transfer to darkness, the largest pods formingafter continuous far-red irradiation. As little as 10 min daily exposure to red or far-red irradiancehad the same effect on gynophore elongation as continuous irradiation.Pods formed only when the daily periods of far-red irradiationwere 30 min or less. Reducing the daily exposures to 2 min decreasedthe time to onset of pod formation from 30 to 16 days. Far-redfollowing red irradiation was effective in inhibiting gynophoreelongation stimulated by red irradiation. Pod formation in red/far-redirradiation was only 50 per cent of that observed in far-redirradiation. The involvement of light in continual gynophoreelongation and in the concomitant inhibition of proembryo growthis discussed. Arachis hypogaea L., peanut, gynophore, photomorphogenesis, embryo development, pod development, proembryo     

Light,dark and growth regulator involvement in groundnut (Arachis hypogaea L.) pod development

Gynophore elongation and pod formation were studied in peanut plants (Arachis hypogaea L.) under light and dark conditions in vivo. The gynophores elongated until pod formation was initiated. Pod (3–20 mm length) development could be totally controlled by alternating dark (switched on) and light (switched off) conditions, repeatedly. Gynophore elongation responded conversely to light/dark conditions, compared to pods. In this study we aimed to correlate the light/dark effects with endogenous growth substances. The levels of endogenous growth substances were determined in the different stags of pod development. Gynophores shortly after penetration into the soil, ‘white’ gynophores, released twice the amount of ethylene as compared to the aerial green ones, or to gynophores bearing pods. Ethylene inhibitors had no effect on the percent of gynophores that developed pods, but affected pod size which were smaller compared to the control. A similar level of IAA was extracted from gynophore tips of green gynophores, ‘white’ gynophores and pods. ABA levels differed between the three stages and were highest in the green gynophores and lowest in the pods.     

Pod development of groundnut (Arachis hypogaea L.) in solution culture

Normal pods (containing seed) of groundnut (Arachis hypogaea L.) (cv. TMV-2) were successfully raised in darkened, aerated, nutrient solution, but not in the light. The onset of podding was evident 7 to 8 d after gynophores were submerged in the darkened nutrient solution. An examination of pods and submerged portions of gynophore surfaces by scanning electron microscopy showed the presence of two distinctly different protuberances: unicellular root-hair-like structures that first developed from epidermal cells of the gynophores and developing pods; and branched septate hairs that developed later from cells below the epidermal layer. The septate hairs became visible only after the epidermal and associated unicellular structures had been shed by the expanding gynophore and pods. Omission of Mn and Mg from the podding environment increased pod and seed weight, whilst omission of Zn reduced pod and seed weight.     

The role of amyloplasts during gravity perception in gynophores of the peanut plant (Arachis hypogaea).

Gravitropic perception and response are essential for the completion of the reproductive life cycle of the peanut plant (Arachis hypogaea L.). The developing seeds are buried in the soil by a specialized organ, the gynophore, allowing the fruit to mature underground. Controversy exists about the site of graviperception in the gynophore: previous workers suggested that the intercalary meristem was the zone where gravity was perceived. Taking the starch statolith hypothesis for graviperception as a framework, we explored the possibility that the starch-grain filled plastids (amyloplasts) in the starch sheath of the gynophore may be acting as gravisensors. We show that these amyloplasts sediment readily with respect to the gravity vector within 30 min of reorientation, and before there is a measurable gravitropic response. Gynophore explants were incubated with gibberellic acid and kinetin, in darkness, to remove starch from the amyloplasts. Destarching the gynophores did not inhibit overall growth of the organ, but reduced the gravitropic response curvature by 82% compared to water-treated controls. In addition, gynophores placed on a rotating clinostat (without hormone treatment) also showed a reduced gravitropic response. In conclusion, the evidence presented in this work strongly suggests that the amyloplasts of the starch sheath are responsible for gravitropic perception in the peanut gynophore. A model for graviperception in the gynophore is presented.     

Geotropic Responses and Pod Development in Gynophore Explants of Peanut (Arachis hypogaea L.) Cultured In Vitro

Peanut gynophore explants cultured in vitro on a defined mediumshow a positive geotropic response in both light and dark whenplanted either horizontally, or vertically with the tip pointingupwards. The growth following the initial curvature dependedon age of the gynophores and on the levels of growth substancesin the medium. In the dark and in presence of 0·01–0·1p.p.m. kinetin, naphthalene acetic acid at concentrations of0·1 p.p.m. and lower promoted gynophore elongation. Athigher concentrations elongation was promoted to a lesser extentin younger explants, caused enlargement of the ovary and formationof pods. Young explants generally elongated more than olderones and pod formation took place inside the medium, while inolder ones it took place above the medium. In the light, theinitial positive geotropic response was followed by elongationbut without any enlargement of the ovary. Decapitation of gynophores1·5–2·0 mm below their tip, removing theovary but leaving most of the intercalary meristem, had no effecton the geotropic response and elongation. The initial geotropicresponse and elongations of explants in vitro was not dependenton the presence of the ovary but on the meristem proximal toit. Changes in growth substances balance during gynophore developmentseem to affect geotropic response, elongation and pod formationin the peanut.     

Light, dark and growth regulator involvement in groundnut (Arachis hypogaea L.) pod development

Gynophore elongation and pod formation were studied in peanut plants (Arachis hypogaea L.) under light and dark conditions in vivo. The gynophores elongated until pod formation was initiated. Pod (3–20 mm length) development could be totally controlled by alternating dark (switched on) and light (switched off) conditions, repeatedly. Gynophore elongation responded conversely to light/dark conditions, compared to pods. In this study we aimed to correlate the light/dark effects with endogenous growth substances. The levels of endogenous growth substances were determined in the different stags of pod development. Gynophores shortly after penetration into the soil, white gynophores, released twice the amount of ethylene as compared to the aerial green ones, or to gynophores bearing pods. Ethylene inhibitors had no effect on the percent of gynophores that developed pods, but affected pod size which were smaller compared to the control. A similar level of IAA was extracted from gynophore tips of green gynophores, white gynophores and pods. ABA levels differed between the three stages and were highest in the green gynophores and lowest in the pods.Abbreviations ABA abscisic acid - AOA aminooxyacetic acid - ELISA enzyme linked immunosorbent assay - Ethrel 2-chloroethanephosphonic acid - GC gas chromatography - HPLC High Performance Liquid Chromatography - IAA indole-3-acetic acid - NAA naphthalene acetic acid - RIA radioimmunoassay - STS silver thiosulfhate - TIBA 2,3,6-triiodobenzoic acid     

Growth rates and auxin effects in graviresponding gynophores of the peanut, Arachis hypogaea (Fabaceae)

The gynophore of the peanut plant (Arachis hypogaea) is a specialized organ that carries and buries the fertilized ovules into the soil in order for seed and fruit development to occur underground. The rates of growth of vertically and horizontally oriented gynophores were measured using a time-lapse video imaging system. We found that the region of maximum extension growth due to elongation (termed the Central Elongation Zone) is located on average at 2-5 mm from the tip. In the first 0-4 h after horizontal reorientation (gravistimulation), new zones of growth emerge on the upper surface, while the elongation zone of the lower side decreases in size and magnitude. Four to six hours after reorientation the zones of maximum growth are almost equal in size and location on the upper and lower sides. The growth rate and the gravitropic response decreased dramatically, upon the excision of the ovule region (terminal 1.5 mm), but a gravitropic growth response could be restored by applying the auxin indole-3-acetic acid exogenously to the excised tip. The addition of napthylphthalamic acid (an auxin transport inhibitor) at the ovule region allowed some growth to occur, but the gynophores do not respond normally to gravity, upon horizontal reorientation. We discuss the role of auxin in the gravitropic response of the gynophore.     

Histological Changes of the Peanut (Arachis hypogaea) Gynophore and Fruit Surface During Development, and their Potential Significance for Nutrient Uptake

Histological changes in gynophores and fruits of Arachis hypogaeaL.cv. White Spanish were examined, utilizing scanning electronmicroscopy as well as light microscopy. The epidermis of theabove ground parts of gynophores is characterized by the presenceof stomata, lenticels and multicellular trichomes. Below groundportions of the same plant organ exhibit unicellular root-hair-likestructures. These protuberances of the epidermal cells can reacha very high density and length (up to 0.75mm) . Identical structurescan be found on the developing pod and are most prominent atthe reproductive stages R5-R6. In later developmental stagesthe hairs degenerate and the presence of large lenticels becomesthe obvious external feature of the pod. It is suggested thatthe substantial increase in surface area due to the hairs maywell be an anatomical adaptation for nutrient and water uptake. Arachis hypogaea, peanut fruit development, nutrient uptake     

花生胚离体发育及渗调物质的影响

在无外源激素培养基上花生胚能继续发育．渗调物质如甘露醇可抑制胚早萌,维持胚性发育,促进贮藏蛋白质合成和累积．渗调物质对胚离体发育的调控与其提高胚内源ＡＢＡ含量有关．     

Germline-specific Antigens Identified by Monoclonal Antibodies in the Nematode Caenorhabditis elegans1

Of 27 monoclonal antibodies identified to react, by indirect immunofluorescent antibody staining, with specific cells and tissues of the nematode Caenorhabditis elegans, we report here three monoclonal antibodies pertaining to the gonadal tissues. One antibody defines an antigen that is distributed over the entire embryo at earlier development and later becomes unique to the gonad, including mature oocytes. The antigens recognized by the other two are distributed asymmetrically in the posterior region of the fertilized egg's cytoplasm destined to become the germline precursor cell. Each antigen is successively segregated only to the germline precursor cells of the developing embryo and, postembryonically, is uniquely localized around the germline cell nuclei of the larvae and adults.     

Initiation and Morphogenesis of Groundnut (Arachis hypogaeaL.) Pods in Solution Culture

A recently-developed solution culture technique was used tostudy the effects of aeration and calcium (Ca) on groundnut(ArachishypogaeaL.) pod development. Two experiments were conductedwith seven groundnut lines, TMV-2, Chico and A116L4 (Spanish),CBRR4 (Valencia), A125L25 (ValenciaxSpanish), and Shulamit Strain1 (SH-1) and Virginia Brunch Strain 1 (VB-1) (Virginia). Plantswere grown in a potting mix, and the attached gynophores culturedin darkened polycarbonate jars containing nutrient solution.Non-aeration of solution prevented pod development, but podsand seeds of all lines developed in aerated, darkened nutrientsolutions (ionic strength approx. 9 mM). Normal pods and seedswere produced by TMV-2, Chico and CBRR4, but constricted podsdeveloped in SH-1 and VB-1. A secondary gynophore developedbetween the basal and apical seed compartments in A116L4 andA125L25, and in VB-1 at high Ca (500–2500 µM) insolution. The secondary gynophores were similar to those producedin otherArachisspp. but not usually found in cultivated formsofA. hypogaea.Septate and non-septate hairs developed on submergedgynophores and pods, but were sparse on those of SH-1 and VB-1.The magnitude of the effects of aeration and Ca concentrationon pod initiation and morphogenesis differed in experimentsconducted in summer and winter and among the lines tested.Copyright1998 Annals of Botany Company Arachis hypogaeaL., calcium, groundnut, pod morphology, secondary gynophore, solution culture.     

An amino-terminal deletion of rice phytochrome A results in a dominant negative suppression of tobacco phytochrome A activity in transgenic tobacco seedlings

Overexpression of phytochrome A results in an increased inhibition of hypocotyl elongation under red and far-red light. We used this approach to assay for the function of N-terminal mutations of rice (Oryza sativa L.) phytochrome A. Transgenic tobacco seedlings that express the wild-type rice phytochrome A (RW), a rice phytochrome A lacking the first 80 amino acids (NTD) or a rice phytochrome A with a conversion of the first 10 serines into alanine residues (S/A) were compared with untransformed wild-type tobacco (Nicotiana tabacum L. cv. Xanthi) seedlings. Experiments under different fluence rates showed that RW and, even more strongly, S/A increased the response under both red and far-red light, whereas NTD decreased the response under far-red light but hardly altered the response under red light. These results indicate that NTD not only lacks residues essential for an increased response under red light but also distorts the wild-type response under far-red light. Wild-type rice phytochrome A and, even more so, S/A mediate an enhanced phytochrome A as well as phytochrome B function, whereas NTD interferes with the function of endogenous tobacco phytochrome A as well as that of rice phytochrome A when co-expressed in a single host. Experiments with seedlings of different ages and various times of irradiation under far-red light demonstrated that the effect of NTD is dependent on the stage of development. Our results suggest that the lack of the first 80 amino acids still allows a rice phytochrome A to interact with the phytochrome transduction pathway, albeit nonproductively in tobacco seedlings.Abbreviations HIR high-irradiance response - NTD N-terminal deletion mutant of rice phytochrome A - Pfr far-red-absorbing form of phytochrome - Pr red-absorbing form of phytochrome - RW rice wild-type phytochrome A - S/A serine-to-alanine mu-tant of rice phytochrome A - wNTD weakly expressing NTD line - XAN wild-type tobacco cv. Xanthi We thank Masaki Furuya (Adv. Research Laboratory, Hitachi, Saitama, Japan) and Akira Nagatani (RIKEN Institute, Saitama, Japan) for providing the monoclonal antibodies mAP5 and mAR14. The work was supported by a grant from the Human Frontier Science Program. K.E. was a recipient of a Landesgraduiertenförderung fellowship.     

Identification of a highly conserved domain on phytochrome from angiosperms to algae

A monoclonal antibody (Pea-25) directed to phytochrome from etiolated peas (Pisum sativum L., cv Alaska) binds to an antigenic domain that has been highly conserved throughout evolution. Antigenic cross-reactivity was evaluated by immunoblotting sodium dodecyl sulfate sample buffer extracts prepared from lyophilized tissue samples or freshly harvested algae. Pea-25 immunostained an approximately 120-kilodalton polypeptide from a variety of etiolated and green plant tissues, including both monocotyledons and dicotyledons. Moreover, Pea-25 immunostained a similarly sized polypeptide from the moss Physcomitrella, and from the algae Mougeotia, Mesotaenium, and Chlamydomonas. Because Pea-25 is directed to phytochrome, and because it stains a polypeptide about the size of oat phytochrome, it is likely that Pea-25 is detecting phytochrome in each case. The conserved domain that is recognized by Pea-25 is on the nonchromophore bearing, carboxyl half of phytochrome from etiolated oats. Identification of this highly conserved antigenic domain creates the potential to expand investigations of phytochrome at a cellular and molecular level to organisms, such as Chlamydomonas, that offer unique experimental advantages.     

Level of Abscisic Acid in Integuments, Nucellus, Endosperm, and Embryo of Peach Seeds (Prunus persica L. cv Springcrest) during Development

Free abscisic acid (ABA) in integuments, nucellus, endosperm, and embryo was determined throughout seed development of peach (Prunus persica L. cv Springcrest). Quantification of ABA was performed using combined high performance liquid chromatography-radioimmunoassay based on a monoclonal antibody raised against free (S)-ABA. In the integuments and endosperm, ABA concentration remained constant during the first 100 days after anthesis and rose in the following days when fresh weight was rapidly decreasing. In the nucellus, the ABA concentration variation pattern paralleled that of tissue growth. ABA concentration in the embryo increased constantly with the growth of the tissues to reach a maximum at the last growth stage. The role of ABA in peach seeds is discussed in relation to the development of the different seed tissues.     

Nitrogen concentration, ammonium/nitrate ratio and NaCl interaction in vegetative and reproductive growth of peanuts

Peanuts ( Arachis hypogaea L. cv. Shulamit) grown with NO₃⁻ and saline water in hydroponics responded positively to addition of nitrogen (N) in their vegetative growth, but not in desert dune sand. In order to clarify these conflicting results, peanut plants were grown in a greenhouse pot experiment with fine calcareous sand. The nutrient solution contained 0 or 50 m M NaCl and 2 or 6 m M N in the form of Ca(NO₃)₂, NH₄NO₃ or (NH₄)₂SO₄. Three replicates were harvested after 48 days (beginning of reproductive stage) and three after 109 days (pod filling). In addition, gynophores were treated with 0, 50, 100, 150 or 200 m M NaCl outside the growth pot to check their sensitivity to salt. Shoot dry weight became greater with increasing NH₄⁺/NO₃⁻ ratio. Increasing the N concentration from 2 to 6 m M did not change shoot dry weight of the NH₄NO₃ or NH₄⁺-fed plants, but caused a reduction in shoot dry weight of NO₃⁻-fed plants. Shoot dry weight was not affected by increasing the NaCl concentration to 50 m M . Salt caused an increase in the number of gynophores per plant and a reduction of the mean pod weight. A NaCl concentration of 100 m M and above reduced gynophore vitality. It is concluded that the salt sensitivity of peanut plants resides mainly in the sensitivity of the reproductive organs.     

The role of the peanut (Araschis hypogaea) ovular tissue in the photo-morphogenetic response of the embryo

Correlative interactions between the embryo and the ovular tissue in peanut, were studied in vitro. Growth arrest of the embryo in the light was controlled by the ovule. Light perceived by the ovular tissue inhibited embryo growth and the inhibitory effect was diminished by decreasing the amount of ovular tissue remaining attached to the embryo. The suspensor played a major role in the development in vitro of isolated globular and heart-stage but not in the cotyledonary stage embryos. Injury to the suspensor in isolated pro-embryos, inhibited their growth in vitro. Electron microscopy showed disintegrated cells, devoid of starch grains and protein bodies, in nuclear cells surrounding the embryo sac at the micropylar, but not at the chalazal end. This may indicate a role of the suspensor in metabolite absorption by the young embryo. Pro-embryos cultured in a medium with abscisic acid in the dark exhibited a mode of growth arrest similar to that by light. The results suggest that light perceived by the ovular tissue induces the production of substances which diffuse to the embryos and arrest their development.     

PHYTOCHROME DISTRIBUTION IN ETIOLATED GRASS SEEDLINGS AS ASSAYED BY AN INDIRECT ANTIBODY-LABELLING METHOD

The distribution of phytochrome in several etiolated grass seedlings (Avena saliva L., cvs. Garry and Newton; Secale cereale L., cv. Balbo; Hordeum vulgare L., cv. Harrison; Oryza sativa L; Zea mays L., cv. Golden Cross) was determined, by an indirect antibody-labelling method employing peroxidase as the ultimate label. Although the pattern of phytochrome distribution in etiolated shoots varies widely, it is nevertheless clear that, with the exception of corn, in which phytochrome is relatively uniformly distributed, the distribution of phytochrome is highly specific with respect both to organs and to cell types within an organ for a given species. Oat, rye, barley, and rice shoots all have high concentrations of phytochrome near the tips of their coleoptiles, as well as near the shoot apex itself. Rice, barley, and rye also have high concentrations of phytochrome in their leaf bases, but oat leaves are almost totally devoid of measurable phytochrome. An association of phytochrome with vascular tissue often occurs and is most pronounced in the rice shoot. Dark-grown roots were found to have high levels of phytochrome only in the root caps, with lesser amounts, if any, observed in other parts of the root.     

Discrimination between the red- and far-red-absorbing forms of phytochrome from Avena sativa L. by monoclonal antibodies

A set of rat monoclonal antibodies (ARC MAC 48 to 52 and 54 to 56), raised to phytochrome from dark-grown seedlings of Avena sativa L. was tested for the ability to discriminate between the red-absorbing (Pr) and far-red-absorbing (Pfr) forms of phytochrome by indirect enzyme-linked immunosorbent assay. MAC 50 bound more strongly to Pfr and MAC 49 and 52 showed preferential binding to Pr from extracts of dark-grown Avena seedlings; MAC 50 also bound more strongly to Pfr from brushite-purified phytochrome. The remainder of the monoclonal antibodies and a rabbit polyclonal antiphytochrome preparation did not discriminate between Pr and Pfr. The results provide evidence for conformational changes in defined regions of the phytochrome apoprotein upon photoconversion.Abbreviations ELISA enzyme-linked immunosorbent assay - FR far-red light - McAb monoclonal antibody(ies) - PBS phosphate-buffered saline - Pfr far-red-absorbing form of phytochrome - Pr red-absorbing form of phytochrome - R red light - PMSF phenylmethylsulphonylfluoride