Proline, Hydroxyproline, and Lily Pollen Tube Elongation

Cytoplasm of freshly-harvested, ungerminated Lilium longiflorum,cv. Ace pollen contains 0.14 per cent soluble and 0.35 per centprotein-bound proline (pro). Their metabolic fates in germinationand tube elongation are not known with certainty. Here is reportedconversion of pro to hydroxyproline (hyp)—containing constituentsas well as distribution and isolation of these constituents.Colorimetry revealed pro and hyp in wall, trichloroacetic acid(TCA)—precipitable, and TCA-soluble cytoplasmic fractions.A balance sheet summarizing quantitative changes in pro andhyp for these fractions revealed that TCA—precipitablecytoplasmic pro could be a precursor to wall-bound pro and asubstrate for hydroxylation yielding cytoplasmic and wall-boundhyp. To determine whether hyp was a component of tube and/orgrain walls, pollen was allowed to germinate 1.5 h and thentransferred to sorbitol medium which prevented further tubeelongation. Hyp was absent from walls of transferred pollen.Electron microscope autoradiography of tubes exposed to ²H-prosuggested that a pro- and/or hyp-containing constituent waslocalized in the growing tip. Light microscope autoradiographyof intact tubes labelled with ¹⁴C-pro showed that the constituentwas distributed throughout the pollen tubes. Gel filtrationof hyp-containing material enzymically released from walls supportedthe view that they contained hyp-glycopeptides.     

Cytochemical Analysis of Callose Localization in Lilium longiflorum Pollen Tubes

Callose, a ß, 1–3 glucan as a component of plantcells has received sporadic attention. Here, we report an attemptto determine whether aniline blue and lacmoid are indeed specificfor visualizing callose. We also re-evaluate, based on a checkfor stain specificity, the localization of callose in elongatingLilium longiflorum, cv. ‘Ace’ pollen tubes. Specificityof these stains was checked by chemical and enzymatic extractionprocedures which solubilize proteins and polysaccharides. Resultsherein question the generally accepted validity of the fluorescent-anilineblue method for detecting callose. Lacmoid either possessesan affinity for both callose and protein or for callose as aglycoprotein. As for callose localization, the walls of thenon-growing region of the lily pollen tube contain callose,probably as a glycoprotein. Presence of the callosicglycoproteinin the wall of the growing tube-tip is dependent on tube length.Callose plugs exhibiting an affinity for aniline blue or lacmoidwere never seen. Phase-contrast microscopy revealed non-stainablewall ingrowths in fixed-tubes and free-moving cytoplasmic masseswithin living tubes.     

Azetidine-2-carboxylic Acid and Lily Pollen Tube Elongation

Azetidine-2-carboxylic acid (AZC), which occurs naturally inLiliaceous plants, is reported to be a proline (pro) analoguePlant cell walls contain ‘extensin’, which is richin hydroxyproline (hyp). Peptidyl hyp arises through hydroxylationof peptidyl pro followed by glycosylation (arabinose attachment)of hyp Because AZC replaces peptidyl prolyl residues, it maybe a useful tool for evaluating the significance of hyp-o-arabinoselinkages in cell elongation. Therefore, we determined the effectof AZC on [¹⁴C]pro uptake, incorporation and conversion to wall-bound[¹⁴C]hyp in relation to elongation of lily pollen tubes whosewalls consist, in part, of hyp-containing glycopeptides TheAZC suppressed pollen germination 9–42 per cent (1–10mM) and subsequent tube elongation 40–54 per cent (0·1–1mM without affecting respiration In contrast, similar hyp concentrationswere without effect on tube elongation Whereas uptake of [¹⁴C]prowas 16·5–6·2 per cent of the control at0·1–1 mM AZC, [¹⁴C]leucine uptake was 85–25per cent of the control. Light microscope radioautography revealedfewer silver grains over tubes elongated in 0·1–1mM AZC than in its absence. Incorporation of [¹⁴C]pro into tnchloroaceticacid (TCA)-precipitable cytoplasm was reduced by only 10 percent at 0·01–1 mM but 43 per cent at 10 mM AZCGel filtration of cytoplasm from pollen germinated without AZCbut with [¹⁴C]pro resulted in labelled void volume (V) and threeretarded peaks (RI–III) Incorporation into V and RI wasinhibited at both 0·01 and 1 mM AZC These AZC concentrationsreduced conversion of [¹⁴C]pro to wall-bound hyp by 20 percent However, total incorporation of [¹⁴C]pro into salt-water-purifiedwall fractions was suppressed 47–53 per cent (0·1–1mM AZC). Lilium longiflorum, lily, hydroxyproline, proline, azetidine-2-carboxylic acid, pollen, pollen tube elongation     

NON-HORMONAL STIMULATORS AND INHIBITORS OF PLANT GROWTH AND DEVELOPMENT

1. Plants contain growth regulators that are non-hormonal in nature. These regulators change in concentration during ontogeny and when applied exogenously, can either stimulate or depress growth. While the bulk of either the phenolic or terpenoid regulators are localized within the vacuole, they can also be found within other cellular compartments where they may act upon metabolic pathways, modifying either cell multiplication or elongation. 2. Non-hormonal growth regulators may affect the synthesis and/or destruction of phytohormones, mainly indole-3-acetic acid (IAA). These regulators behave non-specifically, modifying the actions of auxins, gibberellins and cytokinins upon growth. 3. A variety of both uncertainties and unresolved contradictions exist that have prevented a thorough elucidation of the mechanisms of actions of both phenolic and terpenoid regulators. These uncertainties and unresolved contradictions include lack of data regarding compartmentalization of many of the inhibitors. This raises the question of whether their intracellular concentrations become elevated sufficiently to affect metabolic pathways in vivo. Exogenously applied regulators of non-hormonal nature usually interfere with growth only at high concentrations. Therefore, the possibility cannot be excluded that under these conditions, reactions occur within the cell that are absent in vivo. 4. The specific properties of natural non-hormonal regulators are similar in certain respects to phytohormones. For example, both of them may be biogenetically bound within metabolic centres: shikimate (phenolics, indoles, alkaloids), bi-benzi (coumarins) or acetate-mevalonate (terpenoids, fluorens, sesquiterpenes, cytokinins). In addition, both non-hormonal regulators and phytohormones exhibit biological activity in growth bioassays. 5. Non-hormonal regulators may possess a number of useful purposes, e.g. test substances such as fusicoccin permit the investigation of the mode of action of phytohormones, specific inhibitors blocking special forms of growth and protectors of phytohormone activity in culture.