Savidge R A
Histochem J. 1983 May;15(5):447-66. doi: 10.1007/BF01002699.
In sterile-cultured explants of stems of the pine Pinus contorta Dougl., fusiform cambial cells differentiated entirely into axial parenchyma cells when exogenous indol-3yl-acetic acid (IAA) was omitted. The normal appearance of the cambial zone was maintained when IAA was included in the medium. The IAA-maintained stability of cambial structure suggests physiological rather than epigenetic control over vascular cambium structure. IAA was essential for the occurrence of callus growth in stem explants. Callus growth was similar in appearance and extent in winter- and summer-explanted material. Tracheids differentiated in explants only when actively differentiating tracheids were already present at the moment of explanting, suggesting the absence of factors necessary for tracheid differentiation in over-wintering tissues. Sclereid differentiation, which normally does not occur in phloem or xylem development in P. contorta, occurred in callus derived from active cambial explants. The sclereids were identical to sclereids which differentiated in pith of intact stems. The possibility that sclereid and tracheid differentiation may be fundamentally similar types of gene expression is discussed. Growth of P. contorta trees in continuous darkness resulted in extensive compression-wood tracheid differentiation in the upright main stem. Normal-wood tracheids differentiated in similar trees grown in light. More tracheids differentiated in light than in darkness. This apparently is the first report of induction of compression-wood tracheid differentiation in the absence of hormone treatment or tilting of trees. Different types and numbers of tracheids differentiated at different position in two-year-old disbudded defoliated stem cuttings of P. contorta in response to apically supplied IAA. No evidence for new tracheid differentiation was seen in control cuttings; however, the results suggest that neither cambial cell division nor tracheid differentiation were actually initiated by IAA. Directed transport of additional regulatory factors toward areas of high IAA concentration is formulated as a hypothesis to explain these observations. Gibberellic acid, (S)-abscisic acid and IAA inhibited tracheid differentiation when individually supplied to basal ends of P. contorta cuttings predisposed to differentiate new tracheids. Experiments with single intact needles on Pinus cembroides var. monophylla cuttings confirmed a previous interpretation that the mature pine needle, rather than the short-shoot apical meristem at its base, promotes tracheid differentiation in the stem.
在无菌培养的扭叶松(Pinus contorta Dougl.)茎外植体中,当省略外源吲哚 - 3 - 乙酸(IAA)时,纺锤状形成层细胞完全分化为轴向薄壁细胞。当培养基中添加IAA时,形成层区域保持正常外观。IAA维持的形成层结构稳定性表明对维管形成层结构的控制是生理性的而非表观遗传的。IAA对于茎外植体中愈伤组织生长的发生至关重要。冬季和夏季外植的材料中愈伤组织生长在外观和程度上相似。仅当外植时已有正在活跃分化的管胞存在时,外植体中才会分化出管胞,这表明越冬组织中缺乏管胞分化所需的因子。扭叶松韧皮部或木质部发育中通常不会发生的石细胞分化,发生在源自活跃形成层外植体的愈伤组织中。这些石细胞与完整茎髓中分化出的石细胞相同。文中讨论了石细胞和管胞分化可能是基因表达的基本相似类型的可能性。扭叶松在连续黑暗中生长导致直立主茎中大量压缩木管胞分化。在光照下生长的类似树木中分化出正常木管胞。光照下分化出的管胞比黑暗中更多。这显然是在没有激素处理或树木倾斜的情况下诱导压缩木管胞分化的首次报道。在扭叶松两年生去芽落叶茎插条中,不同类型和数量的管胞在不同位置响应顶端供应的IAA而分化。在对照插条中未观察到新管胞分化的证据;然而,结果表明IAA实际上既未启动形成层细胞分裂也未启动管胞分化。提出了向高IAA浓度区域定向运输额外调节因子的假说以解释这些观察结果。当单独供应给易于分化新管胞的扭叶松插条基部时,赤霉素、(S) - 脱落酸和IAA抑制管胞分化。对单叶松(Pinus cembroides var. monophylla)插条上单片完整针叶的实验证实了先前的一种解释,即成熟的松针而非其基部的短枝顶端分生组织促进茎中管胞分化。
