滴水珠珠芽发育过程研究

珠芽是滴水珠(Pinellia cordata)的营养繁殖结构,为揭示滴水珠珠芽发育过程中的特征,该研究以野外采集材料进行盆栽观察试验,通过形态观察法和石蜡切片方法,探索滴水珠叶片和叶柄处珠芽发育过程中的形态学和解剖学结构特征。结果表明:滴水珠珠芽发育过程在形态上分为叶柄无现象时期、早期珠芽结构分化和珠芽膨大成熟时期三个时期;相应的解剖学发育时期为珠芽原基启动期和形成期、原基分化期和膨大成熟期四个阶段。叶片和叶柄珠芽起始细胞均由叶柄腹面表皮下层薄壁细胞组织脱分化形成,起始细胞不断分裂形成细胞团最后发育成珠芽原基;在原基分化期的特征是生长点形成,最终分化形成芽原基和鳞片叶;膨大成熟期的特征是珠芽结构不断生长,生长点侧生分化鳞片叶增多。叶片和叶柄处珠芽成熟脱落时期为灰色椭圆形结构,测得平均直径分别为(2.79±0.40)mm和(2.69±0.36)mm,外部有鳞片包裹,内部含大量营养物质。在环境适宜条件下,珠芽遇土萌发,萌发率达75%。这表明滴水珠珠芽与同属植物半夏珠芽发育过程差别不大,都是无性克隆营养繁殖体结构。     

弥勒魔芋珠芽发育过程的形态学和解剖学研究

珠芽是弥勒魔芋的一种重要营养繁殖器官。以弥勒魔芋为材料,通过形态学观察以及解剖学研究,揭示了弥勒魔芋珠芽形成过程中的一系列特征。结果显示:弥勒魔芋珠芽生长于植株叶柄分叉以及裂叶分叉处,由主干茎或主干叶柄表皮下的薄壁细胞重新获得分裂能力后分化而来。珠芽的发育过程可分为珠芽原基启动形成期,珠芽膨大期和珠芽成熟期。珠芽的生长终止于植株衰老倒伏。研究表明,弥勒魔芋的珠芽生长位点明显区别于其他常见植物,珠芽繁殖是魔芋适应生态环境的一种重要机制。     

单芽狗脊营养器官的解剖学研究

采用离析法和石蜡切片法对单芽狗脊营养器官进行形态解剖研究。结果表明：单芽狗脊叶为异面叶,上、下表皮细胞均为不规则型,仅下表皮有气孔器分布;叶柄维管束有2~6个,自叶柄基部向上至叶轴仅有2个较大的维管束;根状茎薄壁细胞之间有多个维管束散生分布,且富含丰富的淀粉粒;皮层在根的横切结构中占比较大,木质部的发育方式为外始式;单芽狗脊珠芽的发育过程分为三个阶段,珠芽原基的形成期、珠芽原基的分化期、成熟期。     

淡黄花百合珠芽发育过程的形态学与解剖学研究

以野生淡黄花百合(Lilium sulphureum)为实验材料,通过形态学观察、石蜡切片方法对珠芽的发生规律、发育过程中的形态学变化及解剖结构特征进行了研究,以阐明淡黄花百合珠芽繁殖的生物学机制。结果显示:淡黄花百合的珠芽形成于地上茎叶腋处叶柄的近基部位置,由叶柄表皮以内数层薄壁细胞不断分裂和分化形成;珠芽的发育过程可划分为启动期、膨大期和成熟期三个时期。成熟珠芽外观上成圆形或椭圆形,珠芽中部的薄壁细胞含有大量淀粉颗粒。淡黄花百合的珠芽具有很高的萌发率(90%以上)。研究表明,珠芽营养繁殖是其生态适应的一种重要机制。     

稀子蕨胞芽发育及营养器官的形态与解剖学研究

该研究采用形态观察法、石蜡切片法以及扫描电子显微镜法对稀子蕨(Monachosorum henryi)胞芽发育过程及营养器官进行观察分析,以揭示不同蕨类植物胞芽生殖在发育生物学上的异同,为进一步探讨蕨类植物胞芽发育与被子植物珠芽发育的异同等奠定基础。结果表明：(1)稀子蕨羽叶薄,由7~8层细胞组成,气孔分布于下表皮,无明显栅栏组织和海绵组织分化。(2)稀子蕨的叶轴含1束“心”形维管束,叶柄基部至中部含2束维管束;成熟根能看到明显的维管束组织,无髓。(3)稀子蕨的复羽叶发育过程可分为萌动期、卷拳期、展叶期、成熟期和衰老期;复羽叶上的胞芽发育从展叶期开始,包括胞芽原基发育期、胞芽分化期、胞芽膨大期和胞芽成熟期。(4)稀子蕨胞芽原基起源于叶轴与羽叶分叉处表皮细胞下的薄壁细胞层;胞芽原基分化出多个叶原基,整体呈指状“锚”状;胞芽成熟后掉落土壤或在母体上萌发生长出新叶。     

半夏胚胎发育的研究

半夏的大小孢子发育均属正常类型。只是种子成熟时没有胚的分化,而是形成一个原球茎。生长点的分化过程类似于珠芽的形成。种子发芽时原球茎突出种皮,在生长点下面的细胞,经过分裂,形成一个膨大的结构。根、叶原基的分化是在发芽过程中逐步完成的。     

杂种鹅掌楸插穗不定根发生与发育的解剖学观察

从解剖学角度着手,对杂种鹅掌楸〔Liriodendronchinense(Hemsl.)Sarg.×L.tulipiferaL.〕扦插过程中不定根的发生发育进行了研究。结果表明:杂种鹅掌楸插穗内未发现潜伏根原基。扦插后,不定根原基起源于维管形成层区,属于诱导生根类型。维管形成层恢复活动后,在不定根发生的部位附近形成1个明显的多薄壁细胞区域,在此区域不定根较容易发生。愈伤组织内没有发现根原基,愈伤组织在发育的过程中,内部细胞部分分化,并形成不规则的输导组织。大量的愈伤组织对不定根的发生有较强的抑制作用。杂种鹅掌楸插穗上不定根的发生可分为4个阶段:(1)维管形成层恢复活动,分裂出多层薄壁细胞;(2)维管形成层及附近的薄壁细胞脱分化,形成不定根原基发端细胞;(3)根原基发端细胞不断分裂成具有方向性的根原基,根原基穿过韧皮射线和皮层,向皮孔或下切口方向发展;(4)不定根从皮孔或下切口伸出,其内部的维管系统开始发育。     

毛舞花姜花器官的发生与发育

通过扫描电镜观察了毛舞花姜(Globba barthei Gagne p.)的花序及花器官的发生与发育。3枚萼片原基首先于花顶连续发生,随后花顶的中心凹陷形成环状原基,环状原基进一步分化形成三枚花瓣—雄蕊共同原基,并在花顶的中心形成花杯。共同原基分化形成花瓣和三枚内轮雄蕊,紧接着外轮雄蕊在花杯的顶点发生。远轴的两枚内轮雄蕊延伸生长并相互融合形成了唇瓣,近轴的一枚形成了可育雄蕊;近轴的两枚外轮雄蕊发育形成了成熟花结构中的侧生退化雄蕊,而远轴的一枚缺失。近轴的两枚外轮雄蕊原基起始的同时,3枚心皮原基也在中心花杯的内侧发生而后与外轮雄蕊相间排列。对毛舞花姜花序的发生和发育的观察发现,在花序轴的头几片初级苞片中产生的是珠芽原基而非蝎尾状小花序原基,其形态特征类似于早期的蝎尾状小花序原基,由此推测珠芽很可能是蝎尾状小花序的变异。     

芸薹属植物发育过程中顶端结构的解剖学研究

本文采用解剖学方法研究花椰菜、青花菜、结球甘蓝和大白菜在生长发育过程中顶端分生组织结构的变化及之间存在的差异。结果显示它们的顶端分生组织结构都是由最初幼苗的原套-原体结构逐渐发育到过渡型分区结构、典型化五个分区结构,至开始进入生殖生长时期的四个分区结构(形成层状细胞区消失)。四种植物在进入生殖生长后,顶端分生组织细胞行为不同:大白菜和甘蓝顶端亚外套两侧细胞分裂分化形成顶生叶原基,在顶生叶原基内侧的细胞将进行分裂产生花序侧枝原基。花椰菜和青花菜顶端亚外套两侧细胞分裂形成花序分生组织,花序分生组织增生即为花球体;内部解剖结构表现为分生组织不断分裂增多的过程。这些结果为研究花序表型发生的解剖学本质及分子生物学研究分生组织发育方向奠定了基础。     

八角莲组织培养的器官发生途径研究

为探究小檗科植物八角莲组织培养的器官发生方式,该研究以八角莲离体叶片、叶柄在MS培养基上诱导产生的愈伤组织、不定芽、不定根为对象,用连续石蜡切片技术分析八角莲组织培养的器官发生途径。结果表明:八角莲愈伤组织形成的解剖学特征是靠近表皮的薄壁细胞经激素刺激恢复分裂能力,继续培养形成拟分生组织。拟分生组织可形成许多分化中心。通过对八角莲组织培养产生的不定芽细胞组织学观察发现芽原基起源于愈伤组织外侧的几层薄壁细胞,芽原基背离愈伤组织中央生长形成不定芽,故八角莲脱分化形成的芽起源方式为外起源。而八角莲的根原基起源于组织深处髓部薄壁细胞和部分维管形成层细胞,进而形成类似球形或楔形并朝韧皮部突起的根原基轮廓,根原基继续发育会突破表皮生成不定根,起源方式为内起源。八角莲离体再生途径为器官发生型,在组培苗生长过程中先诱导形成不定芽,再诱导形成不定根,在愈伤组织上形成维管组织将不定芽和不定根连接成完整植株。     

Rapid clonal propagation of Pinellia ternata by tissue culture

Adventitious buds or protocorm-like bodies were regenerated directly from excised explants without intervening callus. Differences in the ability of regeneration were observed among different plant organs with bulbils showing the highest regenerative ability followed by leaf blade and petiole. Ability of vegetative propagation of bulbil could be maintained by alternate solid-and liquid-medium culture. Theoretically, 1.7×10²⁷ plantlets could be produced from a single bulbil by this technique within one year based on the production and rapid growth of protocorm-like bodies and adventitious buds. Concentration of MS salts, NAA and sucrose influenced not only root formation from the differentiated adventitious buds, but also root number and length. For root formation, the best combination was one-half strength MS salts with 3–5% sucrose and 1 mg/l NAA. The high survival rate of 96% was recorded when plantlets were transplanted into a mixture of vermiculite:loam soil:peat moss (1:2:1). Plants from in vitro culture were morphological similar to field-grown plants. The acute toxicity of crude extracts from protocorm-like bodies was about one-fourth that of extracts from tubers of field-grown plants when tested with white mice. Tissue culture has potential for clonal propagation of Pinellia ternata plants for commercial use.Abbreviations MS Murashige and Skoog (1962) - 2,4-D 2,4-dichlorophenoxyacetic acid - NAA -naphthaleneacetic acid - BA 6-benzylaminopurine     

Morphology and molecular phylogeny ofTretopileus sphaerophorus, a synnematous hyphomycete with basidiomycetous affinities

Tretopileus sphaerophorus, a synnematous hyphomycete with basidiomycetous affinities was newly isolated from the decaying petiole and peduncle ofCocos nucifera collected in Depok, Indonesia. The species produced first a bulbil as a propagule on the top of a synnema. After the bulbil had fallen, the synnema proliferated about seven times to produce new bulbils, each time making conspicuous nodes at the upper part. By careful morphological observation, clamp connections were confirmed on the hyphae in the specimens and culture. In culture, each hyphal cell with or without a clamp was found to be dikaryotic by DAPI nuclear staining. Germination of the bulbils occurred first from projecting hyphal tips on their upper surface, which have been treated as germ pores. The inner structure of the bulbils, the hyaline mucus of the bulbils, and conidium-like hyphal fragments were also examined. Phylogenetically,T. sphaerophorus was inferred to be related to the Aphyllophorales based on the nuclear encoded small subunit (18S) rDNA using the homology search system (FASTA) and the neighbour-joining method. Part 10 in a series on the taxonomy of synnematous fungi.     

Use of protocorm-like bodies for studying alkaloid metabolism in <Emphasis Type="Italic">Pinellia ternata</Emphasis>

Highly differentiated tissue masses known as protocorm-like bodies (PLBs) have been commonly used for plant regeneration. In this study the potential use of PLBs for studying alkaloid metabolism in the Chinese medicinal herb Pinellia ternata (Thunb.) Breit. was investigated. Tuber, leaf, and petiole explants of P. ternata were incubated on Murashige and Skoog (MS) (1962) basal medium containing different combinations of α-naphthaleneacetic acid (NAA) and 6-benzyladenine (BA). It was observed that 0.5 mg/L NAA and 1.0 mg/L BA induced the highest frequency of undifferentiated PLBs from tuber explants; whereas, a combination of 0.2 mg/L NAA and 1.0 mg/L BA was best suited for inducing undifferentiated PLBs from leaf and petiole explants. When these PLBs were subcultured on solid MS medium containing 0.6 or 1.2 mg/L abscisic acid (ABA), ABA promoted proliferation of PLBs, but inhibited their germination. To elicit alkaloid biosynthesis, suspension cultures of PLBs were established in half-strength MS (1/2 MS) liquid medium supplemented with 0.6 mg/L ABA. Water extracts of PLBs collected from suspension cultures contained guanosine and inosine, two important alkaloids of P. ternata. Levels of guanosine concentrations were tenfold higher in tuber-derived PLBs compared to those in field-grown tubers; whereas, those of inosine were slightly lower in PLBs compared to those from field-grown tubers.     

Elicitation of alkaloids in in vitro PLB (protocorm-like body) cultures of Pinellia ternata

The objective of this study was to determine the effect of two endophytic bacterial elicitors (Pseudomonas sp. and Enterobacter sp.) on the production of alkaloids in protocorm-like bodies (PLBs) of Pinellia ternata Breit. Both bacterial strains increased the growth rate of P. ternata PLBs. Pseudomonas sp. promoted the differentiation of the PLBs, whereas Enterobacter sp. inhibited PLB differentiation. The bacterial strains increased guanosine production in PLBs by 9–166%, inosine production by 2–33%, and trigonelline production by 114–1140% compared to the control. For Pseudomonas sp., guanosine and trigonelline production was greater when bacterial extracts were added to the PLB suspension cultures rather than living cells (co-culture treatment). Inosine production was similar in both the bacterial extract and co-culture treatments. For the Enterobacter sp., guanosine, inosine, and trigonelline production tended to be greatest when living cells were added to the PLB suspension cultures rather than bacterial extracts. These results suggest that Pseudomonas sp. and Enterobacter sp. could increase alkaloid yield from P. ternata under field or tissue culture conditions. We also observed that Pseudomonas sp. and Enterobacter sp. produced some of the same alkaloids as their host plants. Additional study needs to be done to determine if these endophytic bacteria could be used to produce alkaloids in the fermentation industry.     

Expression and purification of a novel mannose-binding lectin from Pinellia ternata

Pinellia ternata agglutinin (PTA) from the tubers of P. ternata is a monocot mannose-binding lectin that catalytically agglutinated rabbit erythrocytes. The potential effect of PTA has gained considerable interest in recent years owing to clinical use of native PTA as the preparation against cancer and for plant protection against insect pests. Here we report a successful strategy to allow high-level expression of PTA as inclusion bodies in Escherichia coli M15. Purification of refolded recombinant protein from solubilized inclusion bodies by Ni-NTA agarose affinity chromatography yielded biological activity recombinant PTA (final yield of about 10 mg/L). The recombinant PTA agglutinated rabbit erythrocytes to a dilution similar to that determined for “native” lectin purified from P. ternata. The expression and purification system makes it possible to obtain sufficient quantities of biologically active and homogenous recombinant PTA sufficient to carry out advanced clinical trials. This is the first report on the large-scale expression and purification of biologically active recombinant PTA from E. coli.