野生大豆种子雨的研究

对野生大豆种子雨的时空动态及其与外界天气情况关系的初步研究表明,在野 生大豆整个种子雨的历程中,出现３个较为明显的炸荚和种子散落的高峰,并且峰的出现 与天气晴朗（相对湿度）相关,而与气温相关性不大．野生大豆种子雨的空间分布格局主要 是野生大豆种子炸荚的自身习性（炸荚弹力）和荚本身在植株上的空间分布有关,而与风 向（风力≤７级）关系不大．     

大豆炸荚发生规律及分子遗传基础

炸荚是野生大豆繁衍后代的一种原始自然属性,同时也是栽培大豆减产的主要原因之一,因此对其发生规律和分子遗传基础的研究具有重要的理论意义和潜在的育种应用价值。文章在剖析抗炸荚大豆荚部细胞学微观组织结构特征的基础上,总结了大豆炸荚的发生规律和大豆炸荚表型性状的鉴定指标与方法,介绍了抗炸荚种质鉴定与抗炸荚品种选育概况,同时详细阐述了大豆抗炸荚性状的分子遗传基础研究进展,最后对大豆抗炸荚性的研究与应用进行了展望。     

木麻黄海防林种子雨的时空动态

为了解木麻黄(Casuarina equisetifolia)种子雨的时空间分布格局和萌发性能对其天然更新的影响,对海口木麻黄海防林种子雨的时空分布特征和种子雨的萌发动态进行了研究。结果表明,木麻黄种子落雨时间始于7月中旬,结束于次年4月中旬,持续长达9个月,期间种子雨年际平均密度为1 764.63 grain m~(-2)a~(-1);种子雨高峰期在12月上中旬,落种量占总散落量的43.38%;种子雨呈聚集分布,且种子雨密度与附近球果数量呈极显著正相关;种子雨萌发率较低,仅为11.31%,但由于种子雨密度较大,可萌发的种子雨密度仍然较大,为199.58grainm~(-2)a~(-1)。因此,种子数量和质量均不是制约木麻黄天然更新困难的主要障碍因子,但聚集分布特征使木麻黄种子在林内扩散能力十分有限。     

山地常绿落叶阔叶混交林种子雨的地形格局

种子雨是森林群落更新繁殖体的主要来源。而地形对植被空间格局异质性的影响机制之一 ,就是作用于种子雨的空间分布。为了在亚热带山地常绿落叶阔叶混交林群落中检验这一假设 ,在湖北宜昌市大老岭国家森林公园内、海拔 130 0～ 14 95 m之间的一片天然次生林内进行野外比较观测实验。选择 10个不同的地形部位 ,在每一点设置重复 (5个 )的种子雨收集器 ,在种子雨期间定期收集并记录种子雨的种类及数量。 2 0 0 1、2 0 0 2年的观测数据分析表明 :(1)种子雨密度和物种丰富度在不同地形坡位、坡形上差异显著 ,都沿山脊 -山坡 -山谷梯度和凸坡 -平坡 -凹坡梯度而减小 ;(2 )种子雨的密度和物种丰富度受坡向和坡度的影响不显著 ;(3)种子雨和乔木层物种构成的相似性与坡位和坡形呈显著的正相关 ;与坡度呈不显著的负相关 ,与坡向值间存在非线性关系 ;(4 )地形影响种子雨扩散的可能机制包括 ,影响不同种类母树的分布及其密度格局 ,影响不同坡位或坡形上分布的母树种子生产的强度和节律 ,影响风力的方向和大小的分布 ,从而形成水平方向种子流的源 -汇分化。     

准噶尔盆地东南缘梭梭种子雨特征

为了研究梭梭种子散布规律,通过布设种子雨收集器结合室内实验分析,对准噶尔盆地东南缘梭梭种子雨特征进行了研究。研究显示:(1)梭梭种子雨的累积密度达到平均189粒/m2,其中有活力种子占约80%;(2)种子散布的高峰集中在11月初到11月15日时间段,其落种量占整个种子雨的65%。其后种子雨密度随时间逐渐减小;(3)整个种子雨过程,不同时期散落的种子雨质量存在差异,表现为不同时期散落种子的萌发率呈现出先增大后减小的趋势;(4)变异函数分析表明,梭梭种子雨在8.12 m的有效变程内,种子雨具有明显的空间格局,其由空间自相关和随机因素引起的空间异质性各占50.0%。准噶尔盆地东南缘梭梭种子雨密度大且质量较高,同时其时空分布异质性较高,这些特征均将影响梭梭种群的分布格局和种群更新。     

大兴安岭中部天然次生林种子雨动态

本研究于2018—2019年对大兴安岭中部白桦林、针叶林和针阔混交林3种林型的种子雨落种量进行了动态监测,并对3种林型主要树种的种子雨季节动态、落叶动态、种子雨千粒重、种子雨年际变化和种子雨空间格局进行了分析。结果表明: 各林型中兴安落叶松种子雨和白桦种子雨呈现明显的单峰型分布。针阔树种(落叶松、樟子松、云杉、白桦、山杨)的落叶量呈现出明显的季节动态,各林型落叶量大多在9月中上旬达到高峰。在针阔混交林和针叶林中,处于高峰期的兴安落叶松种子雨千粒重明显大于初始期和末尾期的兴安落叶松种子雨千粒重,3种林型下白桦千粒重在季节上未表现出明显的差异。兴安落叶松和白桦的种子雨均呈现出明显的年际变化,2018年为种子散种量的丰年,2019年为歉年。两年时间内,所有种子雨的空间格局在总体上均表现为聚集分布,种子雨和幼苗幼树在空间分布格局上存在一致性。     

野生大豆地理群体的性状变异

中国是栽培大豆(Glycine max)的故乡,其原始种野生大豆(Glycine·soja)在我国大陆有大面积分布。种子富含蛋白质,是世人所瞩目的野生高蛋白基因资源。分布范围大约北纬24°—53°N,东经98°—135°E。其白花变种(G·soja var. albiflora)广见于东北和华北两大遗传多样性中心。狭叶白花变型(G·soja f. angustifolia)主要见于东北;华北和南方少见。狭叶变型(G·soja f. lanceolata)北方分布较多。野生大豆种子极小,一般百粒重在3克以下。在天然野生群体中通常还存在一类G·soja向G·max进化的中间过渡型半野生种(G·gracilis),种子较大,百粒重一般达到3—7克。电泳测定,天然野生群体中的酶或蛋白质标记基因证明,野生大豆是较严格的自花授粉植物,天然异交率     

森林种子雨研究进展与展望

种子雨阶段是植物更新的关键环节,它连接着繁殖生产与植物后续生活史阶段,对群落结构有着重要的影响.虽然早在19世纪中叶达尔文就认识到种子扩散的重要性,然而对种子雨的广泛研究于20世纪80年代初才开始.本文聚焦于森林木本植物种子雨研究,首先介绍了种子雨监测方法,包括收集器的布置,种子雨的收集、分离和鉴定.然后综述了种子雨的4个主要研究方向:种子产量的时间和空间变化格局(包括季节变化、年际变化和空间变化)、增补限制及其在物种多样性维持中的作用、验证负密度效应假说、种子雨与其他生活史阶段(土壤种子库、幼苗、幼树及母树)的比较.未来还需要加强对种子雨的长期监测,开展增补限制的跨纬度比较研究,探讨植物早期更新阶段负密度效应沿纬度梯度的变化规律,加强数学模型以及分子标记和稳定同位素技术等新手段的运用.     

千岛湖片段化生境中木本植物种子雨基本特征及其影响因子

为探究片段化生境中木本植物种子雨的基本特征,该研究根据2015—2020年(研究期间)在千岛湖样岛上的植物群落长期监测样地内每月收集的种子雨数据,采用Kruskal-Wallis检验对木本植物的种子雨密度进行年际差异分析,对不同传播方式物种的种子雨密度进行月份间差异性分析,并利用线性混合效应模型,探究岛屿空间特征(岛屿面积、距最近岛屿的距离、距大陆的距离)以及气候因子(0 ℃以上积温、降水量)对木本植物以及不同传播方式物种的种子雨密度的影响。结果表明:(1)2015—2020年6年间,在29个样岛用240个收集器共收集到877 178粒木本植物的成熟种子,属于26科40属52种。(2)动物传播是木本植物主要的种子传播方式,不同传播方式物种的种子雨时间动态存在较大差异。(3)木本植物的种子雨年密度与岛屿面积和年积温呈显著正相关,与年降水量呈显著负相关。(4)自主传播物种的种子雨月密度与距最近岛屿的距离呈显著正相关,而动物传播物种的种子雨月密度则与距大陆的距离呈显著正相关,风力传播物种的种子雨月密度与月积温呈极显著正相关。综上表明,生境片段化通过岛屿空间特征影响了木本植物种子雨的时间动态。     

中国部分地区一年生野生大豆资源考察、收集及分布现状分析

2002-2004年对中国10省(市)221个县(市)的一年生野生大豆资源进行了考察,新发现有野生大豆分布的县(市)45个,收集野生大豆资源814份.通过考察发现野生大豆在中国分布面积锐减,濒危状况严重.     

Maternal control of seed weight in rapeseed (Brassica napus L.): the causal link between the size of pod (mother,source) and seed (offspring,sink)

Seed size/weight is one of the key traits related to plant domestication and crop improvement. In rapeseed (Brassica napus L.) germplasm, seed weight shows extensive variation, but its regulatory mechanism is poorly understood. To identify the key mechanism of seed weight regulation, a systematic comparative study was performed. Genetic, morphological and cytological evidence showed that seed weight was controlled by maternal genotype, through the regulation of seed size mainly via cell number. The physiological evidence indicated that differences in the pod length might result in differences in pod wall photosynthetic area, carbohydrates and the final seed weight. We also identified two pleiotropic major quantitative trait loci that acted indirectly on seed weight via their effects on pod length. RNA‐seq results showed that genes related to pod development and hormones were significantly differentially expressed in the pod wall; genes related to development, cell division, nutrient reservoir and ribosomal proteins were all up‐regulated in the seeds of the large‐seed pool. Finally, we proposed a potential seed weight regulatory mechanism that is specific to rapeseed and novel in plants. The results demonstrate a causal link between the size of the pod (mother, source) and the seed (offspring, sink) in rapeseed, which provides novel insight into the maternal control of seed weight and will open a new research field in plants.     

Heterocarpy diversifies diaspore propagation of the desert shrub Ammopiptanthus mongolicus

In the desert, plant diaspore spreading usually relies on both external vectors, such as wind, and internal factors, such as diaspore shape. Ammopiptanthus mongolicus is a heterocarpous shrub species in the cold desert in northwest China. Mature pods may have dehisced or not yet dehisced when abscising, and the dehiscent pods may be twisted or flattened. The propagation distances of diaspores might vary due to differences in their buoyancies in upward air and ground friction according to pod shape. The wind tunnel experiments were conducted to measure the horizontal displacement upon fruit dropping (D1) and the wind-blown distance traveled by a fallen pod (D2) of A. mongolicus. A generalized linear mixed model and generalized linear model were used to test the effects of pod shape, release height, wind speed and ground substrate type on the spread distance of pods. D1 is jointly determined by the effects of release height and pod shape. Wind speed, pod shape and ground substrate type together affect D2. A twisted pod has higher dispersibility than a flat pod, and dehiscent pods spread further than indehiscent ones. The positive correlation of D1 and D2 indicates that the difference in pod shape additively broadens the range of seed-spreading distance. Differential seed-spreading properties could be adaptively advantageous to disperse the risks associated with diasporic dissemination compared with the maintenance of a single optimal dissemination characteristic. Thus, heterodiaspory is an advantageous adaptive characteristic for seed spreading in the windy, arid and harsh desert environment.     

Internal recycling of respiratory CO2 in pods of chickpea (Cicer arietinum L.): the role of pod wall, seed coat, and embryo

It has previously been proposed that respiratory CO2 released from the embryo in grain legume pods is refixed by a layer of cells on the inner pod wall. In chickpea this refixation process is thought to be of significance to the seed carbon budget, particularly under drought. In this study it is reported that the excised embryo, seed coat, and pod wall in chickpea are all photosynthetically competent, but the pod wall alone is capable of net O2 evolution over and above respiration. The predominant role of the pod wall in refixation is supported by measurements of fixation of isotopically labelled CO2, which show that more than 80% of CO2 is fixed by this tissue when provided to the pod interior. Chlorophyll concentrations are of the same order for embryo, seed coat, and pod wall tissues in younger pods on both an area and a fresh weight basis, but decline differentially with development from 12-30 d after podding. Imaging of chlorophyll distribution in the pod wall suggests that less than 15% of chloroplasts are located in the inner layer of cells thought to refix CO2 in legumes; this would be sufficient to refix less than 40% of respired CO2. It is concluded that while all tissues of the pod are capable of refixing respiratory carbon, the entire pod wall is responsible for the majority of this process, rather than a specialized layer of cells on the inner epidermis. The role of this fixed carbon in the pod for reallocation to the seed is discussed     

接种蚯蚓对油菜籽粒产量和含油率的影响

通过田间接种试验,研究了威廉腔环蚓(Metaphire guillelmi)活动对冬油菜(Brassica napus)中双9号产量构成因素、籽粒产量和含油率的影响.结果表明:接种蚯蚓后,中双9号的一次有效分枝数、主花序角果数、每角粒数和千粒重均较未接种对照有增加趋势,但差异不显著;而单株角果数、单株产量和小区产量较对照显著提高,分别比对照增加了36.7%、46.5%和29.7%,这可能与蚯蚓促进油菜营养生长阶段植株生长及对氮素的吸收、累积有关.接种蚯蚓后,油菜籽粒含油率较对照有所降低,但由于蚯蚓活动显著提高了油菜籽粒产量,因此单株产油量和小区产油量仍比对照提高了37.4%和21.0%.     

Resistance to the cowpea weevil (Callosobruchus maculatus) larva in pods of cowpea (Vigna unguiculata)

Thirty cowpea, Vigna unguiculata (L.) Walpers, cultivars were evaluated as intact pods to determine if any possessed resistance to the cowpea weevil, Callosobruchus maculatus (Fabr.). Pod resistance was measured as pre-establishment larval mortality (PreM); those larvae dying after egg hatch but before penetrating into the seeds, and as post-establishment within-seed mortality (PostM); those larvae dying after penetrating into the seeds. Among the 30 varieties examined, PreM ranged from 57.9% to 99.4% and PostM ranged from 6.7% to 82.6%. Ten varieties exhibited total intact pod mortality (mortality from egg hatch to adult emergence from the seed) greater than 95%.Physical measurements were made of several pod and seed characteristics to ascertain whether the observed pod resistance was due to seed factors, pod-wall factors, or to interactions between the pod and seeds. Although resistance to breakage (from handling plus pod dehiscence) is a necessary characteristic for overall pod protection against C. maculatus; other factors are also important. Among the other pod and seed characteristics measured to identify major resistance factors, seed coat thickness was the one most highly correlated with pod resistance. Our results suggest that interactions between pod-wall and seed coat characteristics play a large role in pod resistance of cowpeas to C. maculatus.     

Seed coat cell turgor in chickpea is independent of changes in plant and pod water potential

Turgor pressure in cells of the pod wall and the seed coat of chickpea (Cicer arietinum L.) were measured directly with a pressure probe on intact plants under initially dry soil conditions, and after the plants were irrigated. The turgor pressure in cells of the pod wall was initially 0.25 MPa, and began to increase within a few minutes of irrigation. By 2-4 h after irrigation, pod wall cell turgor had increased to 0.97 MPa. This increase in turgor was matched closely by increases in the total water potential of both the pod and the stem, as measured by a pressure chamber. However, turgor pressure in cells of the seed coat was relatively low (0.10 MPa) and was essentially unchanged up to 24 h after irrigation (0.13 MPa). These data demonstrate that water exchange is relatively efficient throughout most of the plant body, but not between the pod and the seed. Since both the pod and the seed coat are vascularized tissues of maternal origin, this indicates that at least for chickpea, isolation of the water relations of the embryo from the maternal plant does not depend on the absence of vascular or symplastic connections between the embryo and the maternal plant.     

Seed abortion in wind-dispersed pods of Dalbergia sissoo: maternal regulation or sibling rivalry?

Summary Dalbergia sissoo, a wind-dispersed tropical tree, shows a positively skewed distribution of seeds per pod. This is attributed to the enhanced dispersal advantage of few-seeded pods due to their reduced wing loading (ratio of weight to pod surface area) and low settling velocity. The proximate mechanisms causing the positively skewed distribution were investigated. The distribution could not be attributed to the distribution pattern of ovule number per ovary, pollen grain limitation, lack of ovule fertilization, or post-fertilization elimination of many-seeded pods. Rather, it was caused by the post-fertilization abortion of seeds within a pod 2 weeks after fertilization. This intra-pod seed abortion (IPSA) is due to a dominance hierarchy of fertilized ovules from the distal (near stigma) to the basal end, generated by the temporal differences in fertilization. The dominant developing seeds at the distal end cause the abortion of others through the production and diffusion of an aborting agent. When the dominance hierarchy of the siblings is not intense, pods are formed with more than one seed. We argue that the positively skewed distribution of seeds per pod is not due to maternal regulation but is a result of sibling rivalry. We propose that this sibling rivalry is generated by genetic differences in pollen grain fitness and disucss the results in the context of parent-offspring conflict.     

Influence of photosynthetic restriction due to defoliation at flowering on seed abortion in lucerne (Medicago sativa L.)

The seed yield of lucerne is poor, in contrast to its good vegetativegrowth. This is partly due to a lack of pollination under naturalconditions, pod abortion and the production of only a few seedsper pod. In this study, lucerne plants were grown in controlledconditions and about 30% of the inflorescences were pollinatedmanually. There were about 10 ovules per flower, which remainedconstant throughout the flowering period. There were 4.5 seedsper pod, indicating over 50% seed abortion. One group of plantswas defoliated and the lack of recent assimilates at floweringcaused a small but significant decrease in the number of seedsper pod (4.1). The effect of defoliation varied with seed age;the youngest fertile inflorescences were the most affected andthere was no effect at around 400C d^–1 . This stage markedthe end of the lag phase, which was determined separately incontrol plants. Thus, it is assumed that this date is the abortionlimiting stage (ALS) for this species. The long lag phase forlucerne could be a key influence on seed yield. The longer theALS, the greater the risk of vegetative competition, thus reducingreproductive development. Key words: Lucerne, flowering, pollination, abortion limiting stage (ALS), seed production