Cytokinins promotion of flowering in Cymbidium ensifolium var. misericors in vitro

Callus-derived rhizomes of Cymbidium ensifolium var. misericors produced flowers precociously on a defined basal medium (1/2MS) containing of NAA with thidiazuron (TDZ), N⁶-(2-isopentenyl) adenine (2iP) or N⁶-benzyladenine (BA) within 100 d of culturing. Among eight cytokinins tested, TDZ at 3.3–10 µM or 2iP at 10–33 µM combined with 1.5 µM NAA were the most effective combinations for achieving flower induction in vitro. These undersized flowers were physically normal and bloomed for two weeks in vitro.     

Study of homeosis in the flower of Philodendron (araceae): a qualitative and quantitative approach

This study deals specifically with floral organogenesis and the development of the inflorescence of Philodendron squamiferum and P. pedatum. Pistillate flowers are initiated on the lower portion of the inflorescence and staminate flowers are initiated on the distal portion. An intermediate zone consisting of sterile male flowers and atypical bisexual flowers with fused or free carpels and staminodes is also present. This zone is located between the sterile male and female floral zones. In general, the portion of bisexual flowers facing the male zone forms staminodes, and the portion facing the female zone develops an incomplete gynoecium with few carpels. The incomplete separation of some staminodes from the gynoecial portion of the whorl shows that they belong to the same whorl as the carpels. There are two levels of aberrant floral structures in Philodendron: The first one is represented by the presence of atypical bisexual flowers, which are intermediates between typical female flowers and typical sterile male flowers. The second one is the presence of intermediate structures between typical carpels and typical staminodes on a single atypical bisexual flower. The atypical bisexual flowers of P. squamiferum and P. pedatum are believed to be a case of homeosis where carpels have been replaced by sterile stamens on the same whorl. A quantitative analysis indicates that in both species, on average, one staminode replaces one carpel.     

Physiological integration in Cassia fasciculata Michx.: inflorescence removal and defoliation experiments

Summary In the annual herb Cassia fasciculata virtually every leaf subtends an axillary inflorescence. We examined the degree to which these leaf-inflorescence units (reproductive nodes) were physiologically independent of each other in the production of flowers, fruits, and seeds. Removal of up to 4 of every 5 inflorescences resulted in substantial increases in fruit and seed production by remaining, intact reproductive nodes. These increases nearly compensated for and manipulated reproductive nodes were associated with different vascular strands. When 2 of every 3 leaves were removed, fruit and seed production were reduced at both intact and defoliated reproductive nodes. Taken together, these results suggest that neighboring reproductive nodes in C. fasciculata are not physiologically independent of one another, and that competition among fruits and seeds for parental resources occurs over several reproductive nodes.Scientific contribution no. 1595 from the New Hampshire Agricultural Experiment Station     

The branching of the inflorescence and vegetative shoot and taxonomy of the genusKummerowia (Leguminosae)

A study of the branching of the inflorescence and the vegetative shoot of the genusKummerowia, consisting ofK. stipulacea (Maxim.) Makino andK. striata (Thunb.) Schindler, has led to the following conclusions: (1) the inflorescences of both species are reduced compound cymes, (2) the branching system of the inflorescence ofKummerowia is not clearly different from that of the vegetative shoot and there are some transitional forms between both systems, and (3) the inflorescence ofKummerowia is different from the racemose inflorescences ofLespedeza andCampylotropis. Based on the differences found in the branching system of the inflorescence,Kummerowia is distinctly separated fromLespedeza andCampylotropis and is more correctly treated as a distinct genus from the latter two.     

普通鸡冠花序中黄酮类化合物的研究

红色普通鸡冠（Ｃｅｌｏｓｉａ ａｒｇｅｎｔｅａ Ｌ．,ｒｅｄ ｆｌｏｗｅｒ）花序乙醇提取物用Ｍｇ＋ＨＣｌ,Ｚｎ＋ＨＣｌ,１％ＦｅＣｌ３－乙醇液,２％ＡｌＣｌ３－乙醇液,１％ＮａＯＨ进行显色反应,呈现黄酮类化合物性质特征颜色。又以槲皮素、山奈酚、异鼠李素为对照品,采用ＨＰＬＣ法测定分析了不同花期花序中黄酮醇的含量。结果表明,晚期花序干品中总黄酮含量（以甙元计）为０．７６１％。     

Inflorescences: concepts,function, development and evolution

Background

Inflorescences are complex structures with many functions. At anthesis they present the flowers in ways that allow for the transfer of pollen and optimization of the plant''s reproductive success. During flower and fruit development they provide nutrients to the developing flowers and fruits. At fruit maturity they support the fruits prior to dispersal, and facilitate effective fruit and seed dispersal. From a structural point of view, inflorescences have played important roles in systematic and phylogenetic studies. As functional units they facilitate reproduction, and are largely shaped by natural selection.

Scope

The papers in this Special Issue bridge the gap between structural and functional approaches to inflorescence evolution. They include a literature review of inflorescence function, an experimental study of inflorescences as essential contributors to the display of flowers, and two papers that present new methods and concepts for understanding inflorescence diversity and for dealing with terminological problems. The transient model of inflorescence development is evaluated in an ontogenetic study, and partially supported. Four papers present morphological and ontogenetic studies of inflorescence development in monophyletic groups, and two of these evaluate the usefulness of Hofmeister''s Rule and inhibitory fields to predict inflorescence structure. In the final two papers, Bayesian and Monte-Carlo methods are used to elucidate inflorescence evolution in the Panicoid grasses, and a candidate gene approach is used in an attempt to understand the evolutionary genetics of inflorescence evolution in the genus Cornus (Cornaceae). Taken as a whole, the papers in this issue provide a glimpse of contemporary approaches to the study of the structure, development, and evolution of inflorescences, and suggest fruitful new directions for research.     

Arabidopsis inflorescence architecture requires the activities of KNOX-BELL homeodomain heterodimers

In flowering plants, post-embryonic development is mediated by the activity of shoot and root apical meristems. Shoot architecture results from activity of the shoot apical meristem (SAM), which initiates primordia, including leaves, internodes and axillary meristems, repetitively from its flanks. Axillary meristems can develop into secondary shoots or flowers. In Arabidopsis, two paralogous BEL1-like (BELL) homeobox genes, PENNYWISE (PNY) and POUND-FOOLISH (PNF), expressed in the SAM, encode DNA-binding proteins that are essential for specifying floral primordia and establishing early internode patterning events during inflorescence development. Biochemical studies show that PNY associates with the knotted1-like homeobox (KNOX) proteins, SHOOTMERISTEMLESS (STM) and BREVIPEDICELLUS (BP). PNY-BP heterodimers are essential for establishing early internode patterning events, while PNY-STM heterodimers are critical for SAM function. In this report, we examined the role of PNY, PNF and STM during development. First, we show that PNF interacts with STM and BP indicating that PNY and PNF are redundant functioning proteins. Inflorescence development, but not vegetative development, is sensitive to the dosage levels of PNY, PNF and STM. Characterization of stm-10, a weak allele in the Columbia ecotype, indicates that STM is also involved in floral specification and internode development. Our examination of the genetic requirements for PNY, PNF and STM demonstrates that these KNOX–BELL heterodimers control floral specification, internode patterning and the maintenance of boundaries between initiating floral primordia and the inflorescence meristem.Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at .     

Use of flowering gene <Emphasis Type="Italic">FLOWERING LOCUS T</Emphasis> (<Emphasis Type="Italic">FT</Emphasis>) homologs in the phylogenetic analysis of bambusoid and early diverging grasses

A nuclear gene, FLOWERING LOCUS T (FT) homolog, was cloned from Phyllostachys meyeri as PmFT. Its putative copy number was estimated as four by Southern blot analysis, and the two copies were completely sequenced. Twenty-seven FT homolog sequences of bambusoid and early diverging grasses comprised 172-bp exons, and 357- to 785-bp introns exhibited 0-58.9% pairwise divergence with six modal levels. Parsimony analyses of the FT homologs rooted at Pharus virescens produced six equally parsimonious trees. In the strict consensus tree, five clades were resolved; they were affected by divergence of the intron region rather than exon region. The basal clade was Puelioideae, followed by Olyreae clade including Oryza sativa. Streptogyneae clade combined the Olyreae clade with terminal sister clades of the Bambuseae, i.e., pantropical bamboos and East Asiatic temperate bamboos. The global topology suggested that FT homologs are significant for resolving the tribe level. However, the phylogeny of FT homologs does not resolve monophyly in Bambusoideae because of intercalary positioning by Streptogyneae clade. We discussed the role of FT homologs in controlling the inflorescence architecture and position of Streptogyneae in the bamboo phylogeny.