Response of the predatory mite <Emphasis Type="Italic">Cydnoseius negevi</Emphasis> (Acari: Phytoseiidae) to webbing of the date palm mite, <Emphasis Type="Italic">Oligonychus afrasiaticus</Emphasis> (Acari: Tetranychidae), on date palm fruits and leaves

The behavioral response of a generalist phytoseiid predator, Cydnoseius negevi (Swirskii & Amitai) (Acari: Phytoseiidae) to the complicated webbing of the date palm mite (DPM) Oligonychus afrasiaticus (McGregor) (Acari: Tetranychidae) was evaluated for the first time on date palm leaves and fruits, both in the laboratory and on field-collected samples. Cydnoseius negevi used its first pair of legs in a swimming-like to-and-fro movement to penetrate the complicated webbing of DPM and demonstrated three attack behaviors, i.e., patrolling (PG), web invasion (WI), and web penetration (WP), against the webbing of DPM on date fruits and leaves. The time spent by the predator on attack behaviors was significantly longer in the laboratory for treatments where either more prey females or immature stages along with females were present. The time spent by C. negevi on response behaviors such as searching, grooming, and resting increased with increased number of DPM females and with the addition of immature stages along with DPM females. Cydnoseius negevi, even though being a generalist phytoseiid predator, showed its potential towards penetrating the complex dense webs of DPM on date palm fruits and leaves. If released in suitable numbers prior to establishment of DPM colonies, C. negevi may prove to be an effective biological control agent.     

The role of pre-symbiotic auxin signaling in ectendomycorrhiza formation between the desert truffle <Emphasis Type="Italic">Terfezia boudieri</Emphasis> and <Emphasis Type="Italic">Helianthemum sessiliflorum</Emphasis>

The ectendomycorrhizal fungus Terfezia boudieri is known to secrete auxin. While some of the effects of fungal auxin on the plant root system have been described, a comprehensive understanding is still lacking. A dual culture system to study pre mycorrhizal signal exchange revealed previously unrecognized root–fungus interaction mediated by the fungal auxin. The secreted fungal auxin induced negative taproot gravitropism, attenuated taproot growth rate, and inhibited initial host development. Auxin also induced expression of Arabidopsis carriers AUX1 and PIN1, both of which are involved in the gravitropic response. Exogenous application of auxin led to a root phenotype, which fully mimicked that induced by ectomycorrhizal fungi. Co-cultivation of Arabidopsis auxin receptor mutants tir1-1, tir1-1 afb2-3, tir1-1 afb1-3 afb2-3, and tir1-1 afb2-3 afb3-4 with Terfezia confirmed that auxin induces the observed root phenotype. The finding that auxin both induces taproot deviation from the gravity axis and coordinates growth rate is new. We propose a model in which the fungal auxin induces horizontal root development, as well as the coordination of growth rates between partners, along with the known auxin effect on lateral root induction that increases the availability of accessible sites for colonization at the soil plane of fungal spore abundance. Thus, the newly observed responses described here of the root to Terfezia contribute to a successful encounter between symbionts.     

Abscisic acid,sucrose, and auxin coordinately regulate berry ripening process of the Fujiminori grape

The aim of this study was to examine the effect of abscisic acid (ABA), sucrose, and auxin on grape fruit development and to assess the mechanism of these three factors on the grape fruit ripening process. Different concentrations of ABA, sucrose, and auxin were used to treat the grape fruit, and the ripening-related indices, such as physiological and molecular level parameters, were analyzed. The activity of BG protein activity was analyzed during the fruit development. Sucrose, ABA, and auxin influenced the grape fruit sugar accumulation in different ways, as well as the volatile compounds, anthocyanin content, and fruit firmness. ABA and sucrose induced, but auxin blocked, the ripening-related gene expression levels, such as softening genes PE, PG, PL, and CELL, anthocyanin genes DFR, CHI, F3H, GST, CHS, and UFGT, and aroma genes Ecar, QR, and EGS. ABA, sucrose, and glucose induced the fruit dry weight accumulation, and auxin mainly enhanced fruit dry weight through seed weight accumulation. In the early development of grape, starch was the main energy storage; in the later, it was glucose and fructose. Sucrose metabolism pathway-related gene expression levels were significant for glucose and fructose accumulation. BG protein activity was important in the regulation of grape ABA content levels. ABA plays a core role in the grape fruit development; sucrose functions in fruit development through two pathways: one was ABA dependent, the other ABA independent. Auxin blocked ABA accumulation to regulate the fruit development process.     

Branching gene expression during chrysanthemum axillary bud outgrowth regulated by strigolactone and auxin transport

Shoot branching is essential in ornamental chrysanthemum production and determines final plant shape and quality. Auxin is associated with apical dominance to indirectly inhibit bud outgrowth. Two non-mutually exclusive models exist for indirect auxin inhibition. Basipetal auxin transport inhibits axillary bud outgrowth by limiting auxin export from buds to stem (canalization model) or by increasing strigolactone levels (second messenger model). Here we analyzed bud outgrowth in treatments with auxin (IAA), strigolactone (GR24) and auxin transport inhibitor (NPA) using a split-plate bioassay with isolated chrysanthemum stem segments. Besides measuring bud length, dividing cell percentage was measured with flow cytometry and RT-qPCR was used to monitor expression levels of genes involved in auxin transport (CmPIN1) and signaling (CmAXR2), bud dormancy (CmBRC1, CmDRM1) and strigolactone biosynthesis (CmMAX1, CmMAX3). Treatments over a 5-day period showed bud outgrowth in the control and inhibition with IAA and IAA?+?GR24. Bud outgrowth in the control coincided with high dividing cell percentage, decreased expression of CmBRC1 and CmDRM1 and increased CmPIN1 expression. Inhibition by IAA and IAA?+?GR24 coincided with low dividing cell percentage and unchanged or increased expressions of CmBRC1, CmDRM1 and CmPIN1. Treatment with GR24 showed restricted bud outgrowth that was counteracted by NPA. This restricted bud outgrowth was still concomitant with a high dividing cell percentage and coincided with decreased expression of dormancy genes. These results indicate incomplete inhibition of bud outgrowth by GR24 treatment and suggest involvement of auxin transport in the mechanism of bud inhibition by strigolactones, supporting the canalization model.     

<Emphasis Type="Italic">Arabidopsis</Emphasis> petiole torsions induced by lateral light or externally supplied auxin require microtubule-associated TORTIFOLIA1/SPIRAL2

Although rather inconspicuous, movements are an important adaptive trait of plants. Consequently, light- or gravity-induced movements leading to organ bending have been studied intensively. In the field, however, plant movements often result in organ twisting rather than bending. This study investigates the mechanism of light- or gravity-induced twisting movements, coined “helical tropisms.” Because certain Arabidopsis cell expansion mutants show organ twisting under standard growth conditions, we here investigated how the right-handed helical growth mutant tortifolia1/spiral2 (tor1) responds when stimulated to perform helical tropisms. When leaves were illuminated from the left, tor1 was capable of producing left-handed petiole torsions, but these occurred at a reduced rate. When light was applied from right, tor1 plants rotated their petioles much faster than the wild-type. Applying auxin to the lateral-distal side of wild-type petioles produced petiole torsions in which the auxinated flank was consistently turned upwards. This kind of movement was not observed in tor1 mutants when auxinated to produce left-handed movements. Investigating auxin transport in twisting petioles based on the DR5-marker suggested that auxin flow was apical-basal rather than helical. While cortical microtubules of excised wild-type petioles oriented transversely when stimulated with auxin, those of tor1 were largely incapable of reorientation. Together, our results show that tor1 is a tropism mutant and suggest a mechanism in which auxin and microtubules both contribute to helical tropisms.     

Azospirillum brasilense inoculation,auxin induction and culture medium composition modify the profile of antioxidant enzymes during in vitro rhizogenesis of pink lapacho

Optimal in vitro plant growth can be stimulated by selecting specific nutritional and environmental conditions. However, the culture conditions, dissection, and disinfection of plant material are stressful and may induce disruption of the plant physiological homeostasis. This can be modified by inoculation with rhizobacteria as Azospirillum brasilense, by the culture medium type, and by auxin induction. Here, we performed rooting experiments in two auxin-free culture media with ‘pink lapacho’ (Handroanthus impetiginosus) shoots previously induced with 0, 10, 30, or 50 μM indole butyric acid (IBA) for 3 days and inoculated with A. brasilense Cd and Az39. Peroxidase (PO), phenylalanine ammonia-lyase (PAL), and polyphenol oxidase (PPO) activities were determined on days 0, 3, 6, 9, 12, and 15. Also, weekly absolute rooting percentage was evaluated. All enzymatic activities were higher in A. brasilense-inoculated shoots, linked to early and high rooting percentage. The culture medium type and IBA concentration also affected enzymatic activities. The positive correlation between PO and PAL activities on day 9 and successful final in vitro rooting of H. impetiginosus allows using these activities as early markers of rhizogenesis reducing the selection time of easy-to-root plants. The changes in enzymatic levels performed here are discussed on the basis of their role in rooting and in vitro stress and contribute to the knowledge of the physiology of trees and their interaction with rhizobacteria.     

Leaf spot disease on <Emphasis Type="Italic">Tilia cordata</Emphasis> caused by the fungus <Emphasis Type="Italic">Cercospora microsora</Emphasis>

Increased incidence of leaf spots on many tree species, up to the presence of peripheral importance only, including linden trees was noticed recently. First massive and continuous occurence of the fungus Cercospora microsora Sacc. [teleomorph Mycosphaerella millegrana (Cook.) Schröet., Mycosphaerella microsora Syd.], causal agent of anthracnose on linden trees (Tilia cordata Mill.) grown in urban plantings in Slovakia was reported. Along with this, certain of the important growth characteristics of this fungus were studied under laboratory conditions. To specify Cercospora biology mycelial growth of C. microsora in pure hyphal cultures was observed in relation to medium and locality. One-way ANOVA has confirmed a statistically significant influence of both factors, culture medium and locality on growth rate values of C. microsora. The effect of these factors has not proved unambiguously in all cases. In the case of one locality (Nitra), the significant influence of used media has not been proved (P > 0.05). PDAg showed generally as the most suitable medium, inducing the most intensive growth in three localities (41.06 mm/week on average). Comparing three localities, the effect of this factor is not so unambiguous. Growth rate values from the localities Bratislava and Pribeta indicate unsuitability of medium A for the fast radial growth. A Tukey test separately conducted for the factors medium and the locality revealed the significant combinations of means (P ≤ 0.05).