‘兰箭3号’箭筈豌豆荚果发育动态及腹缝线结构研究

箭筈豌豆(Vicia sativa)是高海拔地区重要的一年生豆科牧草,但荚果成熟时的开裂现象会造成种子的严重损失。该研究以栽培品种‘兰箭3号’为对象,对其荚果在发育过程中的形态特征、水分含量、腹缝线表面结构及腹缝线横截面解剖结构的动态变化进行观察分析,以探讨箭筈豌豆荚果的裂荚机理,为生产中确定种子收获的适宜时间提供理论依据。结果显示:(1)‘兰箭3号’约在盛花后25~30d荚果变为浅棕色,此时荚果已完成生理成熟,且荚果的大小和干重均达到最大值,含水量降到最小值;盛花后25d荚果腹缝线出现裂缝,盛花后35d腹缝线完全裂开。(2)‘兰箭3号’于盛花后20d腹缝线处离层细胞开始解体;盛花后25d,内、中、外果皮的薄壁细胞均开始失水皱缩,其中内果皮的薄壁细胞部分已开始破裂,离层细胞及其下面的薄壁细胞完全解体,外部果瓣缘细胞内侧细胞壁破裂,但外侧异常加厚的细胞壁仍然保持完整并连接两个果瓣,使荚果不开裂;盛花后30~35d,内、中、外果皮的薄壁细胞完全失水,细胞壁皱缩在一起,同时外部果瓣缘细胞外侧细胞壁断裂成两部分,荚果的两个果瓣裂开。研究表明,盛花后25~30d荚果失去绿色变为浅棕色时是‘兰箭3号’的适宜收获时间,且离层和细胞失水产生的机械拉力是导致箭筈豌豆荚果开裂的主要原因,推测外部果瓣缘细胞外侧增厚融合的细胞壁很可能是‘兰箭3号’抵抗裂荚的关键结构。     

Physical restriction of pods causes seed size reduction of a brassinosteroid-deficient faba bean (Vicia faba)

BACKGROUND AND AIMS: A brassinosteroid-deficient mutant faba bean (Vicia faba 'Rinrei') shows dwarfism in many organs including pods and seeds. 'Rinrei' has normal-sized seeds together with dwarf seeds, suggesting that dwarfism in the seed may be indirectly caused by brassinosteroid deficiency. The mechanism of seed size reduction in this mutant was investigated. METHODS: The associations between seed orientation in the pod, seed numbers per pod and pod lengths with seed sizes were analysed in 'Rinrei' and the wild-type plant. KEY RESULTS: 'Rinrei' seeds are tightly arranged in pods containing two or three seeds. Seed size decreased as the number of seeds per pod increased or as the length of the pod decreased. Where no physical restriction occurred between seeds in a pod, the wild-type faba bean seeds had a nearly constant size regardless of seed number per pod or pod length. 'Rinrei' seeds in pods containing single seeds were the same size as wild-type seeds. Brassinolide treatment increased the seed size and the length of pods containing three seeds in 'Rinrei'. CONCLUSION: Seed size of 'Rinrei' is mainly regulated through a reduction of pod length due to brassinosteroid deficiency; physical restriction within pods causes a reduction in seed size. These results suggest a possible mechanism for increasing faba bean yields to optimal levels.     

Preliminary studies on the effects of 4-chlorophenoxyacetic acid on the senescence and dehiscence of pods in oil seed rape (Brassica napus L.)

The auxin 4-chlorophenoxyacetic acid (4-CPA) has been found to delay the maturation and dehiscence of the pods of oil seed rape. Dipping pods in solutions of 500 gl^–1, 4-CPA, 36 and 39 days after anthesis delayed significantly the autolysis of the thin-walled parenchyma of the dehiscence zones, the senescence of the pod walls and the loss of water from the pod walls and seeds. Increases in both the fresh and dry weights of both pod walls and seeds were recorded in the treated pods as compared with controls.     

兰花蕉种子的解剖学和组织化学研究

兰花蕉种子球形或近球形,具表皮毛,种脊不明显。种子包括假种皮、种皮、外胚乳、内胚乳和胚五部分。假种皮具３～４条粗毛状裂片,包围种子或不定向伸展;裂片最外方为１层表皮细胞和１～３层厚壁细胞,内方为薄壁细胞;表皮细胞和厚壁细胞的壁增厚并木质化;成熟时裂片下部１／２段中空。种皮由外珠被发育而来,但内珠被在种子发育后期才萎缩。种皮分化为外种皮,中种皮与内种皮;外种皮由１层表皮细胞构成,其细胞壁增厚并木质化;中种皮外方为２～３层厚壁细胞,内方由１２～１５层薄壁细胞构成;内种皮由１层径向延长的石细胞构成,其细胞壁网状增厚,胞腔不明显。外胚乳极不显眼,大部分只由１层切向延长的长方形细胞构成,局部为２～１７层细胞;外胚乳细胞主要含许多脂类物质及少量蛋白质颗粒,不含淀粉。内胚乳占据种子很大的体积,由通常径向延长的长方形、长条形或方形薄壁细胞构成;细胞内充满淀粉粒和通常一颗亦有２至多颗菱形或方形蛋白质晶体,脂类物质极少。胚圆柱形,胚根和胚芽不明显。种子珠孔区不分化出珠孔领和孔盖,但具柄,柄的远轴端边缘大部分着生假种皮,着生假种皮一侧柄略膨大。合点区内种皮出现极宽的缺口,缺口间为整体呈弧状长条形的合点区厚壁细胞群。较粗的种脊维管?     

Pod development of groundnut (Arachis hypogaea L.) in solution culture

Normal pods (containing seed) of groundnut (Arachis hypogaea L.) (cv. TMV-2) were successfully raised in darkened, aerated, nutrient solution, but not in the light. The onset of podding was evident 7 to 8 d after gynophores were submerged in the darkened nutrient solution. An examination of pods and submerged portions of gynophore surfaces by scanning electron microscopy showed the presence of two distinctly different protuberances: unicellular root-hair-like structures that first developed from epidermal cells of the gynophores and developing pods; and branched septate hairs that developed later from cells below the epidermal layer. The septate hairs became visible only after the epidermal and associated unicellular structures had been shed by the expanding gynophore and pods. Omission of Mn and Mg from the podding environment increased pod and seed weight, whilst omission of Zn reduced pod and seed weight.     

Histological Studies of Ditylenchus africanus Within Peanut Pods

Ditylenchus africanus entered the immature pegs and pods of peanut (Arachis hypogaea cv. Sellie) at the peg-connection and subsequently invaded the parenchymatous regions of the hull exocarp and endocarp, and eventually the seed testa. The nematode caused malformations of the cells of infected tissues, cell wall breakage, and cell collapse. The damage appeared to be due to enzymatic activity. In some testae the entire parenchyma region, which aids in protection of the seed, was destroyed. In immature pods, the nematodes moved across the fibrous region of the mesocarp into the hull endocarp. In mature pods, however, the fibrous mesocarp of the hull was lignified and apparently was a barrier to penetration of the inner pod tissues. In late-harvested pods, increased numbers of eggs and anhydrobiotes were found in the hull tissues, and eggs in the seed testa, suggesting the onset of winter survival mechanisms of the nematode.     

Regulation of monocarpic senescence of Brassica campestris by the developing pods

Senescence of Brassica campestris L. cv. B-9 was studied with regard to seed maturation and source-sink relationships. In normal control plants leaf senescence (as determined by the change in chlorophyll level) started and proceeded in a progressive manner from base to apex during the period of early pod setting. Complete yellowing of the leaves occurred well before the seed maturation and pod wall senescence. The pod wall always senesced before the attainment of final seed weight. In two different sets of acrocarpous plants containing 65 pods and 10 pods, respectively, leaf senescence was delayed during the pod filling period. It started non-sequentially after complete yellowing and senescence of the pod wall. The degree of leaf senescence at the post-pod filling stage was almost proportional to the number of pods present. When peduncles of the acrocarpous 10-podded plants were removed after the pod filling stage of the plant, leaf senescence was delayed compared to plants whose pedicels were removed, although the senescence pattern of the upper three leaves was nonsequential in both cases. Defruiting at an early stage of development delayed leaf senescence, although the pattern of such senescence remained unaltered (i.e. nonsequential). Defoliation hastened the seed-filling process and pod wall senescence. Plants containing fewer pods had higher average seed weight, although yield per plant was reduced.
These results suggest that the pod wall serves as a temporary as well as intermediary storage organ and that foliar senescence is not directly related to seed maturation. The possible cause of uncoupling between foliar senescence and seed development is discussed.     

Unusual Network of Internal Phloem in the Pod Mesocarp of Cowpea [Vigna unguiculata (L.) Walp. (Fabaceae)]

A mycelium-like network of internal phloem was observed in theinner mesocarp of the lateral pod walls of the fruit of certaingenotypes of cowpea [Vigna unguiculata (L.) Walp.] In the cultivarVita 3, the network consists of single, or rarely double, strandsof sieve elements and associated phloem parenchyma, orientedmainly parallel with the fibres of the adjacent endocarp, andstretching marginally beyond the sheets of fibres to connectabove and below with the outermost phloem of the longitudinalstrands of the dorsal and ventral sutures of the fruit. Theinternal phloem network does not relate conformationally to,or interconnect with the conventional (xylem+phloem) vasculatureof the mid mesocarp of the pod wall. In Vita 3, sieve elementsdifferentiate in the internal phloem after those in the majorveins of the pod, but before the presumptive endocarp fibrescommence wall thickening. The pod walls of twenty-one otherspecies of legumes proved negative for internal phloem, whileof nine varied genotypes of cowpea examined, six proved positive,three negative for the trait. Presence of internal phloem incowpea is not always associated with presence of endocarp fibresor necessarily with large fruits with large seeds. Possiblefunctions suggested for the phloem network are to provide assimilatesfor fibre wall thickening or to transport solutes to or fromsites of temporary storage in the fleshy inner layers of thepod wall. Internal phloem, legume fruit, translocation, mesocarp, pod wall, Vigna unguiculata, cowpea     

Formation of the vascular system of developing bean (Phaseolus limensis L.) seeds according to nuclear magnetic resonance microtomography

1H magnetic resonance microtomography imaging was applied to study vascular systems in developing bean (Phaseolus limensis L.) seeds. Using the gradient echo method, we recorded 2D tomographic sections in the sagittal and axial planes of the fruits sampled from a vegetating plant on days 10, 17, 24, and 31 after fertilization. Any vascular connection between the tissues of maternal plant (bean pod and seed coat) and the embryo were undetectable. The embryo has an autonomous branched network of procambial strands in the cotyledons, converging to the embryonic axis. The bean pods are covered with a network of vascular bundles; large vascular strands run along the dorsal and ventral sutures. The seed coat vascular bundles are formed in the process of seed ripening and are represented by a developed vascular system multiply branching in the middle part of the ground parenchyma at the stage of physiological maturity. They are connected with the source of assimilates via the lateral pod veins and a large vascular bundle, entering the seed below the hilum via the placenta. Assimilates enter the external part of the seed coat, which contains no vascular bundles, via the funiculus vascular bundles and hilum tissue.     

From flower to seed: identifying phenological markers and reliable growth functions to model reproductive development in the common bean (Phaseolus vulgaris L.)

The lack of dependable morphological indicators for the onset and end of seed growth has hindered modeling work in the common bean (Phaseolus vulgaris L.). We have addressed this problem through the use of mathematical growth functions to analyse and identify critical developmental stages, which can be linked to existing developmental indices. We performed this study under greenhouse conditions with an Andean and a Mesoamerican genotype of contrasting pod and seed phenotypes, and three selected recombinant inbred lines. Pods from tagged flowers were harvested at regular time intervals for various measurements. Differences in flower production and seed and pod growth trajectories among genotypes were detected via comparisons of parameters of fitted growth functions. Regardless of the genotype, the end of pod elongation marked the beginning of seed growth, which lasted until pods displayed a sharp decline in color, or pod hue angle. These results suggest that the end of pod elongation and the onset of color change are reliable indicators of important developmental transitions in the seed, even for widely differing pod phenotypes. We also provide a set of equations that can be used to model different aspects of reproductive growth and development in the common bean.     

Phloem unloading in developing walnut fruit is symplasmic in the seed pericarp and apoplasmic in the fleshy pericarp

The sieve element-companion cell (SE-CC) complex of the sepal bundles feeding the fleshy pericarp of developing walnut (Juglans regia L.) fruit is structurally symplasmically isolated, but the SE-CC complex of the minor ventral carpellary bundles located in the seed pericarp and feeding the seed is structurally symplasmically connected to its adjacent parenchyma cells. 14C-autoradiography indicated that the phloem of both the sepal and carpellary bundles was functional for unloading. Confocal laser scanning microscopy imaging of carboxyfluorescein unloading showed that the dye is confined to the phloem strands of the sepal bundles in the fleshy pericarp, but released from the phloem strands of the minor ventral carpellary bundles into the surrounding parenchyma cells in the seed pericarp. A 60-kDa acid invertase was immunolocalized to the cell wall of SE-CC complex and parenchyma cells in both the fleshy and seed pericarp. These data provide clear evidence for an apoplasmic phloem unloading pathway in the fleshy pericarp and a predominant symplasmic phloem unloading pathway parallel with a possible apoplasmic path as suggested by the presence of the extracellular invertase in the seed pericarp. A model of complex phloem unloading pathways in developing walnut fruit has been proposed.     

长豇豆种皮和种脐的发育

长豇豆的胚珠具内外两层珠被,内珠被在种子发育早期退化消失,种皮仅由外珠被发育而成。外珠被的外表皮细胞径向伸长,外壁和经向壁增厚,形成约占成熟种皮厚度一半的栅栏层;亚表皮细胞发育为骨状石细胞层。第三层细胞类似于亚表皮层但细胞壁增厚不明显,其内方的多层薄壁细胞形成海绵组织。种脐具两层栅栏细胞,外栅栏层及其以外部分由珠柄组织发育而成管胞群。本文还对脐缝和管胞群的作用以及豆科种子的吸水机制进行了讨论。     

Formation of the vascular system of developing bean (<Emphasis Type="Italic">Phaseolus limensis</Emphasis> L.) seeds according to nuclear magnetic resonance microtomography

¹H magnetic resonance microtomography imaging was applied to study vascular systems in developing bean (Phaseolus limensis L.) seeds. Using the gradient echo method, we recorded 2D tomographic sections in the sagittal and axial planes of the fruits sampled from a vegetating plant on days 10, 17, 24, and 31 after fertilization. Any vascular connection between the tissues of maternal plant (bean pod and seed coat) and the embryo were undetectable. The embryo has an autonomous branched network of procambial strands in the cotyledons, converging to the embryonic axis. The bean pods are covered with a network of vascular bundles; large vascular strands run along the dorsal and ventral sutures. The seed coat vascular bundles are formed in the process of seed ripening and are represented by a developed vascular system multiply branching in the middle part of the ground parenchyma at the stage of physiological maturity. They are connected with the source of assimilates via the lateral pod veins and a large vascular bundle, entering the seed below the hilum via the placenta. Assimilates enter the external part of the seed coat, which contains no vascular bundles, via the funiculus vascular bundles and hilum tissue.     

山茱萸果皮的解剖学研究

本文报导了山茱萸果皮的解剖学研究结果.外果皮由一层表皮细胞构成.中果皮外方为3-4(5)层厚角组织细胞,这些细胞通常含有单宁;其内方包含薄壁细胞、单宁细胞和8束维管束.单宁细胞成团或零星分布于薄璧细胞中,前者的体积明显大于后者.单宁细胞的单宁与多糖结合在一起.维管束含有环纹、螺纹、梯纹、网纹及孔纹管胞,还有少数散生的纤维.内果皮高度木质化,主要由多种形状的石细胞组成,其间分布了肉眼可见、排列成环状的异细胞,偶见少数生活石细胞及薄壁细胞.内果皮有3束维管束.     

Application of a probabilistic model for analysing the abortion of seeds and pods in winter oilseed rape (Brassica napus)

In winter oilseed rape (WOSR), only a subset of ovules can develop into seeds in the majority of pods. Any difficulty during the process of seed production may result in seed or pod abortion. This study aimed to reproduce the process of seed development in WOSR based on a limited number of parameters. As a result of the complexity of the developmental patterns of WOSR, it is challenging to identify the roles of various factors that influence seed production using an experimental approach. Here, we present a stochastic probabilistic model of seed development. The generalised least squares method was implemented to estimate the model parameters using the experimental data. Experiments were done in Grignon (France) in 2008 and 2009. The variations in the parameters were analysed according to the following four factors: year, pod rank, inflorescence position and ramification‐clipping treatment. The year had no effect on the number of ovules per ovary (μ) and the probability of seed viability (p). The proportion of effective pollen grains (k) significantly decreased with pod rank at the end of the main stem. Inflorescence position influenced the number of ovules per ovary (μ: 30.8–33.8 from top to bottom) and the parameter k. The mean number of seeds per pod on the main stem and the bottom ramification along the stem was larger than the other ramifications within one plant. Ramification‐clipping treatment increased the number of ovules per ovary (μ: 31 for control plants and 32 for clipped plants), the parameter k and the number of seeds per pod (p). This effect could be due to the competition for assimilates between the pods and seeds. Furthermore, the distribution parameters of the pollen number per stigma (m) remained stable, and the probability of pod survival (Bo) varied with different factors, including the year, pod rank and inflorescence position. Our results indicate that pollen germination is a factor that determines final seed number. This model can identify the impact of each of the factors that lead to the abortion of seeds and pods in WOSR, which include the position effect, assimilate competition and pollination limitation. However, further studies on the pollination process in WOSR should help to refine this model.     

Patterns of fruit and seed production inBauhinia ungulata (Leguminosae)

Patterns of seed and fruit production ofBauhinia ungulata, a small tree legume indigenous in tropical America, were studied in Costa Rica. Only about 8% of flowers produced fruits. The average pod had 19 ovules and about two thirds of these began seed development, with mature pods containing an average of 9.7 mature undamaged seeds. About half of the mature pods were damaged by herbivores and within these, 27% of ovules or seeds had been eaten. Among trees there was no significant variation in pod production, but the number of ovules per pod and seed production per pod varied significantly. Within infructescences most pods were retained at middle positions. Within pods, the probability of an ovule developing into a seed increased toward the distal end. The pattern of seed and fruit production in this species agrees well in general with that reported for other neotropical legumes. The abortion of seeds and fruits can be regarded as a way of controlling maternal investment, and as a response to herbivory.     

Seed structure and germination in Cuscuta pedicellata with some notes on C. campestris

Dry seeds of Cuscuta pedicellata have a deeply pitted surface due to invaginated epidermal cell walls. After water uptake these walls bulge outwards and the seed surface becomes papillose. The seed coat consists of an epidermis, two palissade cell layers, and a multiple layer of parenchyma cells. The epidermis contains starch and mucilage, the parenchyma cells are compressed but some contain starch. The endosperm consists of starch–filled cells, but has a peripheral aleuron layer. The endosperm cell walls are gelatinous. The variable structure of the seed coat epidermis is believed to function in wind dispersal and rapid water uptake. Seed dormancy is common in the genus, but does apparently not occur in C. pedicellata.     

Osmotic regulation of assimilate unloading from seed coats of Vicia faba. Assimilate partitioning to and within attached seed coats.

The significance of the osmotic potential of the seed apoplast sap as a regulator of assimilate transfer to and within coats of developing seed of Vicia faba (cv. Coles Prolific) was assessed using attached empty seed coats and intact developing seed. Following surgical removal of the embryos, through windows cut in the pod walls and underlying seed coats, the resulting attached “empty” seed coats were filled with solutions of known osmotic potentials (–0. 02 versus –0. 75 MPa). Sucrose efflux from the coats was elevated at the higher osmotic potential (high osmotic concentration) for the first 190 min of exchange. Thereafter, this efflux was depressed relative to efflux from coats exposed to the low osmotic potential (high osmotic concentration) solution. This subsequent reversal in efflux was attributable to an enhanced diminution of the coat sucrose pools at the high external osmotic potential. Indeed, when expressed as a proportion of the current sucrose pool size, relative efflux remained elevated for coats exposed to the high osmotic potential solution. Measurement of potassium and sucrose fluxes to and from their respective pools in the coat tissues demonstrated that the principal, fluxes, sensitive to variative in the external osmotic potential, were phloem import into and efflux from the “empty” coats. Phloem import, consistent with a pressure-driven phloem transport mechanism, responded inversely with changes in the external osmotic potential. In contrast, sucrose and potassium efflux from the coats exhibited a positive dependence on the osmotic potential. Growth rates of whole seed were approximately doubled by enclosing selected pods in water jackets held at temperatures of 25°C. compared to 15°C. The osmotic potential of sap collected from the seed apoplast remained constant and independent of the temperature-induced changes in seed growth rates and hence phloem import. Based on these findings, it is proposed that control of phloem import by changes in the external osmotic potential observed with “empty” seed coats has no significance as a regulator of assimilate import by intact seed. Rather, maintenance of the seed apoplast osmotic potential, independent of seed growth rate, suggests that the observed osmotic regulation of efflux from the coats may play a key role in integrating assimilate demand by the embryo with phloem import.     

山茱萸核果的解剖结构和组织化学定位

用解剖学和组织化学的方法研究了山茱萸 (MacrocarpiumofficinacleSieb .etZucc .)核果的解剖结构和皂甙、多糖的组织化学定位。结果表明 :山茱萸核果的外果皮革质 ,由一层被覆较厚角质膜的表皮细胞构成 ;中果皮肉质 ,由多列薄壁细胞构成 ,含色素细胞不均匀分布 ,靠近外果皮的薄壁细胞大多为含色素细胞 ,使果实呈现红色 ,向内的薄壁细胞体积渐渐增大 ,在较大的薄壁细胞以及维管束周围的薄壁细胞内常含有色素块。组织化学定位显示 :外中果皮的含色素细胞的色素块中含有丰富的皂甙和多糖 ,果实的中果皮的薄壁细胞在未成熟时就已经形成皂甙 ,并随着果实的成熟逐渐增加积累     

苏铁种子的种皮结构特征研究

对苏铁(Cycas revoluta Thunb.)种子的种皮进行了解剖研究,结果表明:苏铁种子的种皮分为外种皮、中种皮和内种皮3层结构.外种皮含有角质化的表皮细胞、薄壁细胞以及少量的厚壁细胞和异细胞,布有树脂道、气室和4束大维管束;中种皮主要由厚壁细胞群和木质化纤维组成,种孔端有一条缝合线,种脐端有3个孔;内种皮由多层干瘪的薄壁细胞和脉络状维管束组成,种孔端有一层椭圆状保护膜.对外种皮和内种皮维管束进行观察研究发现:外种皮和内种皮的维管束分布方式及其结构存在明显差异,外种皮的维管束由种脐端顺着种子弧形走向种孔端,内种皮的维管束呈脉络状,形成维管网贯穿其中;内、外种皮维管束中均存在多种不同样式的导管.