Precociously germinating somatic embryos of Vitis vinifera have lower ABA and IAA levels than their germinating zygotic counterparts

Somatic embryos of Vitis vinifera (cv. Grenache noir) develop normally up to the torpedo stage, but they germinate precociously and form viable plantlets with very low frequency. Because a peak in abscisic acid (ABA) in mid‐embryogenesis could be one factor preventing precocious germination during normal seed development, we followed the development of ABA content concurrent with that of the somatic embryos. Additionally, we measured changes in indoleacetic acid (IAA) levels. We also compared the levels of both hormones during precocious germination of somatic embryos and during normal germination of their zygotic counterparts. Somatic embryos were able to accumulate ABA and IAA throughout their development but no peak in ABA concentration was detected during embryogenesis. This suggests that the switch from mid‐ to late‐embryogenesis is not triggered. Furthermore, during precocious germination, i.e. from the torpedo stage onwards, the concentrations of ABA and IAA in somatic embryos were much lower than during normal germination of zygotic embryos. Thus, it is likely that when precocious germination occurs, grape somatic embryos do not accumulate ABA and/or IAA in sufficient concentrations to support normal plantlet development. Therefore, for grape somatic embryos we propose that prevention of precocious germination, i.e. triggering late‐embryogenesis, is attainable by an ABA treatment followed by slow desiccation, as already shown for conifer somatic embryos. Our results also suggest that the role of ABA and IAA for improving normal germination after imposed quiescence should be investigated.     

5′‐N‐ethylcarboxamidoadenosine is not a paralog‐specific Hsp90 inhibitor

The molecular chaperone Hsp90 facilitates the folding and modulates activation of diverse substrate proteins. Unlike other heat shock proteins such as Hsp60 and Hsp70, Hsp90 plays critical regulatory roles by maintaining active states of kinases, many of which are overactive in cancer cells. Four Hsp90 paralogs are expressed in eukaryotic cells: Hsp90α/β (in the cytosol), Grp94 (in the endoplasmic reticulum), Trap1 (in mitochondria). Although numerous Hsp90 inhibitors are being tested in cancer clinical trials, little is known about why different Hsp90 inhibitors show specificity among Hsp90 paralogs. The paralog specificity of Hsp90 inhibitors is likely fundamental to inhibitor efficacy and side effects. In hopes of gaining insight into this issue we examined NECA (5′‐N‐ethylcarboxamidoadenosine), which has been claimed to be an example of a highly specific ligand that binds to one paralog, Grp94, but not cytosolic Hsp90. To our surprise we find that NECA inhibits many different Hsp90 proteins (Grp94, Hsp90α, Trap1, yeast Hsp82, bacterial HtpG). NMR experiments demonstrate that NECA can bind to the N‐terminal domains of Grp94 and Hsp82. We use ATPase competition experiments to quantify the inhibitory power of NECA for different Hsp90 proteins. This scale: Hsp82 > Hsp90α > HtpG ≈ Grp94 > Trap1, ranks Grp94 as less sensitive to NECA inhibition. Because NECA is primarily used as an adenosine receptor agonist, our results also suggest that cell biological experiments utilizing NECA may have confounding effects from cytosolic Hsp90 inhibition.     

A new method for differential determination of basic natural forms of indolyl-3-acetic acid

A new ELISA method is proposed for differential quantitative determination of free (indolyl-3-acetic acid; IAA) and bound (indolyl-3-acetyl-L-aspartate) forms of natural auxins. There is similarity in results obtained by this and some traditionally used methods. The standard error of determination of the active form of IAA by our method is 1.5-2.0 times less than that using the traditional method. The method of quantitative differential determination of the main natural auxins does not require preliminary sample preparation, and this shortens assay time. The developed method has been used for practical determination of different forms of endogenous IAA in wheat and dandelion ovaries subjected to minimal treatment. This method can be used to investigate changes in the ratio of various hormonal forms of auxins that differ in their physiological activity in reproductive organs of angiosperms at various stages of reproduction.     

Release of cotyledonary shoots of pea (<Emphasis Type="Italic">Pisum sativum</Emphasis>) seedlings from inhibition as related to endogenous zeatin and ethylene and exogenous IAA and benzyladenine

This paper deals with apical dominance using a dicotylar model obtained after decapitation of pea seedlings with two shoots — one dominant and the other inhibited. When the dominant shoot was decapitated the inhibited one is released from inhibition and after 24 to 72 h begins to grow. However, the levels of trans-zeatin and production of ethylene increase within 4 and 6 hours respectively after release from inhibition, and within an interval of 72 h the levels of both phytohormones begin gradually to decrease. This indicates that also in this model, the release from apical dominance is associated with an increase in the level of cytokinin zeatin and, thereafter, also with an increased production of ethylene. If indolyl-3-acetic acid (IAA) is applied on the decapitated main stem after decapitation of the dominant shoot, the growth of the initially inhibited one is very strongly retarded; if, however, IAA is applied on the decapitated dominant shoot, this inhibition is significantly weaker. This means that the inhibiting effect of IAA on the inhibited shoot originates to a greater degree from the main stem rather than from the dominant shoot. The effect of benzyladenine (BA) is transferred equally from the decapitated main stem and from the decapitated dominant shoot because the initially inhibited shoot begins to grow as well as also other shoots from serial cotyledonary buds.     

杨和苹果离体茎尖培养和愈伤组织分化与内源IAA、ABA的关系

用杨和苹果的茎尖进行离体培养,在ＭＳ培养基中添加不同浓度的ＢＡ 、ＮＡＡ 或２ ,４Ｄ,诱导（１） 茎的增殖或根的分化,（２） 愈伤组织形成以及愈伤组织分化根、芽或体胚,再生完整植株。测定了不同发育状态器官和组织的内源ＩＡＡ 和ＡＢＡ,并计算了ＩＡＡ／ＡＢＡ 的比值。培养物中其比值较高者,易于诱导不定根分化或形成胚性的愈伤组织,也是木本植物离体培养幼化程度较高的例证。在试管内培养时,杨比苹果培养物易于幼化,因而器官分化、愈伤组织形成和分化、再生完整植株较容易,在ＭＳ 培养基中添加的外源ＢＡ、ＮＡＡ 和２ ,４Ｄ 的浓度也较低。     

Change in the Concentration and Tissue localization of Endogenous IAA During the Regeneration of Vascular Tissues After Xylem Removal in Broussonetia papyrifera

Change in the concentration of endogenous IAA was monitored with enzyme-linked immunesorbent assay (ELISA), and IAA localization in the tissues was demonstrated by means of immunogold-silver microscopy, with authors' modification, during the regeneration after removal of xylem in Broussonetia popyrifera (L.) Vent. The stimulation exerted from xylem removal produced a rapid increase of about 70% of the endogenous IAA concentration. However, the concentration decreased during differentiation of the vascular tissues. Although removal of the tree crown inhibited the regeneration of vascular tissues, the change tendency in the concentration of endogenous IAA during the regeneration remained the same as if the tree crown was intact. This suggested that rapid increase of endogenous IAA induced by wounding could be a result from a release of the combined form into free IAA. Tissue-localization showed that there were more silver-grains labelled in the rays, callus and the regenerated differentiating vascular tissue cells than in other tissues. It could suggest that the high concentration of endogenous IAA triggered the dedifferentiation of the vascular tissues after removal of xylem, and the less concentrated IAA flow could promote the initiation and activity of the regenerated cambium.