Transient expression of storage-protein genes during early embryogenesis ofVicia faba: synthesis and metabolization of vicilin and legumin in the embryo,suspensor and endosperm

Seed storage proteins are thought to be accumulated exclusively in the cell-expansion phase of embryogenesis and metabolized during germination and seedling growth. Here we show by a sensitive immunohistological technique that the two Vicia faba L. storage proteins vicilin and legumin are accumulated in substantial amounts in the suspensor and coenocytic endosperm and to a lesser extent in the mid-globular embryo. Both proteins appear and disappear at precise stages specific for each tissue. In the endosperm the accumulation starts around 12 d after pollination (DAP). After a maximum attained at 14–15 DAP, storage proteins are degraded within about 4 d. Accumulation is restricted to that part of the endosperm which covers the embryo and displays the highest levels of endoploidy (maximum 96n). In all other parts of the endosperm, storage proteins do not appear to accumulate, although storage-protein-specific mRNA synthesis takes place. In the suspensor, storage proteins are already observed at 6 DAP and disappear very quickly at approximately 10 DAP. Low amounts of legumin and vicilin are also detectable in the mid-globular embryo, but disappear completely as the embryo enters the heart stage. We conclude that storage proteins of Vicia faba accumulated transiently during early seed development are used as nutritive reserves for the growing embryo.Abbreviation DAP days after pollination Dedicated to Prof. Rigomar Rieger in the occasion of his 65th birthdayThis research was supported by the Ministry of Science and Research, Land Sachsen-Anhalt, Germany. U.W. acknowledges additional support by the Fonds der Chemischen Industrie.     

Light Microscope Study of Pollen Tube Growth, Fertilization and Early Embryo and Endosperm Development in the Avocado Varieties Fuerte and Hass

Pollen tube growth, fertilization and early embryo and endospermdevelopment were studied using light microscopy in the avocadovarieties Fuerte and Hass. The ovule was penetrated by a pollen tube by 24 h after pollination.On reaching the ovary, the pollen tube grew along the surfaceof the inner ovary wall. It then grew around the funicle, throughthe micropyle in the inner integument and between the papillatecells at the apex of the nucellus. It entered the embryo sacvia a synergid. Sperm nuclei were present in the embryo sacat 48 h after pollination and fusion of the polar and spermnuclei took place before fusion of the egg and sperm. The endospermnucleus was the first to divide and cell wall formation occurredfollowing division. The first division of the zygote occurredat 5 or 6 days after pollination. In the variety Fuerte less than 20 per cent of the 1- and 2-day-oldembryo sacs had been penetrated by a pollen tube although tubeswere often observed in the integument or nucellus. In the varietyHass over 60 per cent of the embryo sacs were penetrated. Inwas concluded that low yields of the variety Fuerte may be partlyattributable to the failure of the pollen tube to penetratethe embryo sac. Persea americana Mill, avocado, pollen tube, fertilization, embryo, endosperm     

Anatomy of Watermelon Embryo Sacs Following Pollination, Non-pollination or Parthenocarpic Induction of Fruit Development

There is little information on the fate of embryo sacs in plantovules if pollination is prevented. In this study embryo sacsfrom watermelon were observed over a 13 day period followingflowering with (a) normal pollination, (b) non-pollination and(c) induction of parthenocarpic fruit development with naphthaleneacetic acid. Following pollination, and prior to fertilizationapproximately 2 days later, the embryo sacs completed developmentand consisted of two synergids with prominent filiform apparatus,an egg cell, a central cell with two polar nuclei and threeantipodal cells. Sperm nuclei were observed within the embryosac at 2 days and by 4 days the endosperm was proliferating.In the non-pollination treatment the embryo sac was still intactafter 4 days although the antipodal nuclei were becoming hardto distinguish. By 7 days only the two synergids and the eggcell were still well defined, the polar nuclei appeared in somepreparations to be fused, and the antipodals had degenerated.By 10 days the embryo sac was a structure-less watery mass.In parthenocarpic fruit the fate of the embryo sac was similarto that in non-pollinated fruit except that final breakdownwas delayed past 10 days. Maturity of the majority of embryo sacs in an ovary appearedto be contemporaneous with penetration of the pollen tube, andon the basis of the anatomical results it seems possible thatembryo sacs could be fertilized up to 2 days beyond the normaltime. Citrullus lanatus, watermelon, embryo sac, anatomy, pollination, parthenocarpy     

Cytological study of pollen tube growth and early seed development inPetunia inflata

Pollen tube growth from the stigma into the ovule, and the early fruit and seed development following fertilization were examined using fluorescence microscopy, scanning electron microscopy and light microscopy inPetunia inflata. After growing intercellularly in the transmitting tract for 24–36 hr, the pollen tubes emerged into the top part of the ovary cavity and grew along the surface of the septum to reach the ovule. It grew around the furnicle and penetrated the micropyle to enter the embryo sac for fertilization. After fertilization, the endosperm nucleus divided first before the embryo, and the cell wall formation occurred following the division, exhibiting the pattern of cellular type of endosperm development. The first division of the zygote did not occur until 3 days after pollination. At 6 days after pollination, the seeds grew considerably and the endosperm has gone through multiple rounds of cell division. High starch formation in the integument, especially around the embryo sac, was also observed.     

Accumulation of Metabolites during Seed Development in Trifolium repens L.

Metabolite deposition during seed development was examined histochemicallyin Trifolium repens by light- and fluorescence microscopy. Allendosperm haustorium at the chalazal pole of the embryo sacand wall protrusions in cell walls of the suspensor and theembryo sac suggest that transfer of metabolites from maternalto offspring tissue takes place primarily at these sites. Thisis further supported by prominent cutinization of the interpolarregion of the embryo sac wall, accumulation of starch in integumentaltissue at the embryo sac poles, and breakdown of interpolarendothelial cells. Decomposition of osteosclereid starch isfollowed by accumulation in the cellular endosperm and subsequentlyin the embryo parallel to endosperm degradation. The starchaccumulates gradually inward from the subepidermal cells ofthe embryo to the stele. Protein bodies are formed in the vacuolesalong the tonoplast, later to be cut off in vesicles releasedinto the cytoplasm. At maturity the embryo is packed with proteinand starch, but without lipid reserves. Phytin is observed inthe protein bodies. The mature embryo is surrounded by a proteinand starch containing aleurone layer which originates from theendosperm.Copyright 1994, 1999 Academic Press White clover, protein, starch, cuticle, embryo sac wall     

Ephemeral and non-ephemeral structures during seed development in two Cytisus species (Papilionoideae,Leguminosae)

Abstract

Seed formation involves not only the embryo and endosperm development, but also the formation of a series of either ephemeral or non-ephemeral structures. In this article, we study several of those structures in Cytisus multiflorus and Cytisus striatus. The endosperm development is first nuclear and later cellular, except for the chalazal area, whose development is always nuclear. It generates, in the early developmental stages, a sac-like haustorium. As the seed develops, two structures seem to be closely related to nutrient mobilization to the embryo sac: on the one hand, a group of cells and a channel, located in the chalazal area and closely related between them and to the endosperm haustorium, which could be interpreted as a hypostase and on the other hand, an endothelium, derived from the inner integument, which later degenerates leaving no trace in the mature seed. All of these structures would be associated with the directionality of assimilates from ovule tissues to embryo sac. In mature seed and surrounding the embryo appears a unicellular layer of cells rich in proteins (aleurone layer), which is the origin of the outermost layer of the cellular endosperm. The seed coat is made up only of the outer integument.     

蚕豆胚珠发育过程中淀粉动态的观察

蚕豆胚珠发育过程中淀粉动态变化如下:1.发育早期,整个胚珠中未见淀粉粒。其后首先在合点区出现淀粉,而后从合点向珠孔逐渐扩大分布范围。2.珠心和内、外珠被中均含有淀粉粒,尤以内珠被的淀粉增长迅速,数量多、个体大。受精后,内珠被解体,淀粉出现在外珠被细胞中,推测营养物质可通过整个胚囊表面进入其中。3.合点与胚囊之间的珠心细胞特化或长形。可能有助于营养物质进入胚囊。4.功能大孢子中贮存丰富的淀粉粒,它和珠心细胞一起是胚囊发育时的营养来源。5.卵细胞受精后,所含淀粉粒的数量和大小明显增长,随着合子和胚细胞的分裂,其中贮存的淀粉逐渐被消耗,到多细胞球形胚时完全消失。6.胚乳核周围始终未出现淀粉粒。7.胚器官分化之后,子叶和胚轴等处逐渐出现淀粉粒,其中生长活跃的结构如生长点、维管束等不贮存淀粉。8.子叶中的淀粉粒含量迅速增加,颗粒特大,是种子内营养物质的最终贮存场所。     

Embryology of Zippelia begoniaefolia (Piperaceae) and its systematic relationships

Microsporogenesis and embryology of the monotypic Zippelia (Z. begoniaefolia) Blume (Piperaceae) is described for the first time to assess its systematic relationships. The formation of the anther wall is of Basic Type such that the anther wall, consisting of an endothecium with fibrous thickenings, two middle layers, and a glandular septum with 2‐nucleate cells, is derived from a primary parietal layer. Simultaneous cytokinesis follows meiosis of the microspore mother cell thence forming a tetrahedral tetrad of microspores. The single basal ovule is orthotropous, crassinucellate and bitegmic but only the inner integument forms the micropyle. The sporogenous cell of the nucellus functions directly as a megaspore mother cell. A coenocyte with four nuclei forms after meiosis of the megaspore mother cell. The formation of the embryo sac is tetrasporic ab initio and is of, or similar to, the Drusa Type of embryo sac in which the nuclei of the coenocyte undergo two successive mitoses and forms a 16‐celled or 16‐nucleate embryo sac that is ovoid in shape. The embryo sac has an egg apparatus consisting of an egg cell and two synergids (but one of the latter is less discernable). Two polar cells occur just beneath the egg apparatus and 11 antipodal cells or nuclei are arranged along the lower part of the inner wall of the embryo sac. They are linked by threads of cytoplasm. The two polar cells are separated or fused before fertilization. A large primary endosperm nucleus with many nucleoli, which resulted from the fertilized polar cells and with the participation of antipodal cells, divides into a free nuclei stage. The free nuclei are arranged along the lower part of the inner wall of the embryo sac or rarely assemble at the central part. The development of endosperm is thus of the Nuclear Type. The zygote remains undivided and fails to develop even when the seed is nearly mature. Frequently, the zygote and the endosperm abort later and leave an empty chamber in the top part of the seed. Most of the seed content is starchy perisperm. Only the inner integument forms the seed coat and the pericarp develops glochidiate hairs (anchor‐like hairs) when the endosperm begins to develop. By comparison with the other piperaceous taxa using embryological and botanical features, Zippelia is referred to as a basal taxon and a more isolated evolutionary line or a blind branch in the Piperaceae. © 2002 The Linnean Society of London, Botanical Journal of the Linnean Society, 2002, 140 , 49–64.     

Rice caryopsis development Ⅰ: Dynamic changes in different cell layers

Rice caryopsis as one of the most important food sources for humans has a complex structure that is composed of maternal tissues including the pericarp and testa and filial tissues including the endosperm and embryo. Although rice caryopsis studies have been conducted previously, a systematic characterization throughout the entire developmental process is still lacking. In this study, detailed morphological examinations of caryopses were made during the entire 30-day developmental process. We observed some rapid changes in cell differentiation events and cataloged how cellular degeneration processes occurred in maternal tissues. The differentiations of tube cells and cross cells were achieved by 9 days after pollination(DAP). In the testa, the outer integument was degenerated by 3 DAP, while the outer layer of the inner integument degenerated by 7 DAP. In the nucellus, all tissues with the exception of the nucellar projection and the nucellar epidermis degenerated in the first 5 DAP. By 21 DAP, all maternal tissues, including vascular bundles, the nucellar projection and the nucellar epidermal cells were degenerated. In summary, this study provides a complete atlas of the dynamic changes in cell differentiation and degeneration for individual maternal cell layers of rice caryopsis.     

Rice caryopsis development I: Dynamic changes in different cell layers

Rice caryopsis as one of the most important food sources for humans has a complex structure that is composed of maternal tissues including the pericarp and testa and filial tissues including the endosperm and embryo. Although rice caryopsis studies have been conducted previously, a systematic characterization throughout the entire developmental process is still lacking. In this study, detailed morphological examinations of caryopses were made during the entire 30‐day developmental process. We observed some rapid changes in cell differentiation events and cataloged how cellular degeneration processes occurred in maternal tissues. The differentiations of tube cells and cross cells were achieved by 9 days after pollination (DAP). In the testa, the outer integument was degenerated by 3 DAP, while the outer layer of the inner integument degenerated by 7 DAP. In the nucellus, all tissues with the exception of the nucellar projection and the nucellar epidermis degenerated in the first 5 DAP. By 21 DAP, all maternal tissues, including vascular bundles, the nucellar projection and the nucellar epidermal cells were degenerated. In summary, this study provides a complete atlas of the dynamic changes in cell differentiation and degeneration for individual maternal cell layers of rice caryopsis.     

Structure and In Vitro Growth of Zygotic Embryos of Taro (Colocasia esculenta var. antiquorum)

Zygotic embryos of taro, Colocasia esculenta var. antiquorumwere examined using both light and scanning electron microscopyand cultured on Linsmaier-Skoog (LS) medium without the additionof growth regulators. Embryos present within mature seed consistof a hypocotyl-root axis and an undeveloped cotyledon and aresurrounded by two major types of endosperm cells, aleurone andstarchy endosperm. Embryos cultured on LS medium developed intomature plants only in the presence of endosperm tissue. Excisedembryos turned green after 2–4 d in culture and reacheda rapid growth period between days 4 and 6. Culture of taroembryos leading to viable plantlet development depends upon(1) removal of the outer and inner integument, and (2) the presenceof endosperm tissue (including an intact aleurone layer). Colocasia esculenta var. antiquorum, Araceae, taro, embryo culture, integument, endosperm     

THE DEVELOPMENT OF THE SEED OF ABUTILON THEOPHRASTI I. OVULE AND EMBRYO

Winter , Dorothy M. (Iowa State U., Ames.) The development of the seed of Abutilon theophrasti. I. Ovule and embryo. Amer. Jour. Bot. 47(1): 8–14. Illus. 1960.—Abutilon theophrasti Medic, is a widespread annual weed which produces an abundance of seed in capsules which mature within 20 days after pollination. Ovule differentiation may be observed at least 8 days before anthesis when a sporogenous cell becomes evident and 2 integuments are initiated. An 8-nucleate embryo sac is produced from the chalazal megaspore approximately 2 days before anthesis. The outer integument of the mature campylotropous ovule consists of 2 cell layers, the inner integument has 6 to 15 cell layers. The initially free-nucleate endosperm becomes cellular betwen 3 and 7 days after pollination. At maturity a thin layer of gelatinous endosperm encases the embryo. The Asterad-type proembryo of Abutilon has a stout suspensor and develops rapidly. Four days after pollination cotyledons are initiated; 4 days later a leaf primordium is evident. Fifteen days after pollination the embryo, which has essentially completed its growth, consists of a large hypocotyl with root promeristem and root cap at its basal end, and 2 flat, folded, leaflike cotyledons enclosing a small epicotyl at its upper end. The epicotyl consists of an embryonic leaf and a stem apex.     

An Ultrastructural Study of The Embryo/Endosperm Interface in the Developing Seeds of Solanum nigrum L. Zygote to Mid Torpedo Stage

The early developmental sequences in the formation of the Zoneof Separation and Secretion in a hexaploid species of Solanumnigrum L. are described. Ultrastructural changes which occurredduring the development of the embryo/endosperm interface couldbe related to the different stages in the embryo's development.The first step was the completion of the cell wall around thechalazal end of the zygote; a thin wall was formed along theendosperm cell(s) abutting the zygote. From the mature zygotestage to the quadrant stage, minute plasmalemma invaginationsoccurred along the endosperm wall facing the zygote. These invaginationsenlarged, and from the mid-globular stage onwards became filledwith a fine fibrillar material; this material accumulated betweenthe endosperm cell wall and the plasmalemma before being releasedinto the developing periembryonic and intercellular spaces tobecome the extracellular matrix. Cell wall development in theendosperm cells abutting the embryo followed an unusual path.During the quadrant stage, whilst the outer embryo wall increasedin thickness due to vesicle fusion, the endosperm cell wallfacing the embryo showed a loosening of the wall fibrils aswell as partial separation of these same endosperm cells fromeach other. From the early-globular stage, the endosperm cellwalls opposite the embryo became electron-translucent, disappearinginto the extracellular matrix. Enzymic secretions by the embryomay account for the alteration in the abutting endosperm cellwalls. Enzymic activity may also explain the development ofa homogenous electron-opaque layer over the outer embryo wallas well as the differences in the width of the fibrillar layerwhich accumulated around the cotyledons as the embryo grew throughthe Zone of Separation and Secretion. The potential roles ofthe extracellular matrix are briefly discussed. Solanum nigrum L.; embryo/endosperm interface; Zone of Separation and Secretion; embryo development; cellular endosperm     

Embryological Studies of Paphiopedilum godefroyae Stein

P. godefroyae is one of the diandrous species of rather primitive orchids. The cytokinesis of PMCs conforms to simultaneous type. The arrangement of microspores in a tetrad is tetrahedral or isobilateral. The first mitosis in a pollen grain is unequal and results in the formation of two unequal cells. The small one is the generative cell and the large one, the vegetative cell. The wall material between them is callose which is easily detectable under the fluorescence microscope. When the generative cell detaches from the microspore wall and migrates into the cytoplasm of the vegetative cell, the callose wall disappears and a thin PAS-positive wall Was observed around the generative cell. The PAS-positive wall remains untill anthesis. The tapetum is of secretory type and its cells are binucleate. With the degradation of the tapetal cells, they discharge a lot of yellow, amorphous, sticky mass into the pollen sac. The pollens distribute in it to form a sticky pollen mass. The ovule has single integument and one layered nucellus around the magaspore mother cell. The mature embryo sac consists of eight or six cells and conforms to the Allium type. The interval between pollination and fertilization is about 45 days and the normal double fertilization has been observed. The primary endosperm cell undergoes one division only and results in the formation of 2 nucleate endosperm. The dormancy period of zygote lasts 45–50 days. During the development of the embryo, a suspensor consisting of a row of two to four cells is formed. It takes more than six months from the pollination to the maturation of the seed. The embryo in the mature seed is just an ellipsoidal mass of 120–140 cells without differentiation. The endosperm and suspensor are all degenerated in the mature seed.     

The Initiation, Development and Removal of Embryo Sac Wall Ingrowths in the Developing Seeds of Solanum nigrum L. An Ultrastructural Study

In developing seeds of Solanum nigrum L., wall ingrowths developedat the extreme micropylar and chalazal ends of the embryo sac.In the micropylar region, the wall ingrowths were initiatedat the three-celled endosperm stage starting at the base ofthe zygote then progressing for a short distance chalazalwards.They developed quickly with the most elaborate around the baseof the suspensor. The chalazal wall ingrowths developed alongthe surfaces of the chalazal cup, the antipodal cup and thehypostase. Those along the hypostase were initiated at the four-celled,those in the chalazal and antipodal cups at the 20-celled endospermstages. The most elaborate developed along the base of the antipodalcup; the most simple were along the base of the chalazal cup.Small electron-lucent invaginations of the plasmalemma whichlater became filled with fibrillar material, were the earliestindication of wall ingrowth formation. Removal of the wall ingrowthscommenced at the mid-globular stage of embryo development andwas completed by the mid-heart-shaped stage. In the micropylarregion, wall ingrowth removal was rapid, starting with the lossof the fibrillar component followed by the thinning of the cellwall. However, along the hypostase and antipodal cup, a heterogeneouslayer of varying electron densities and a thinner, more electrondense layer was laid down over the ingrowths. This was followedby the removal of the fibrillar component. The initiation, removaland location of the embryo sac wall ingrowths is discussed inconnection with understanding the nutritional relationshipsbetween maternal tissue, endosperm and embryo.Copyright 1995,1999 Academic Press Wall ingrowths, Solanum nigrum, transfer cells, zone of separation and secretion, hypostase     

Fruit Development and Structure in Some Indian Bamboos

Fruit structure and development of seven species belonging tofive genera of Indian bamboos are described. The fruit in fourspecies is a caryopsis typical of the family Poaceae. The ovuleis bitegmic; the outer surface of the cells of nucellar epidermisbecomes cutinized and forms the seed coat. Three species beara fleshy fruit with a unitegmic ovule. In a mature fruit theendosperm is either completely absorbed by the embryo or ispresent only in small quantity. The developing embryo comesin direct contact with the fruit wall due to the disintegrationof the nucellus and integument. The embryo is covered by a thickbrown mat from the disorganized cells of the inner layers ofthe fruit wall. Poaceae, Bambusoideae, Bambusa, Dendrocalamus, Melocalamus, Ochlandra, Pseudostachyum (fleshy fruits), fruit wall     

Endosperm Development in Solanum nigrum L. Formation of the Zone of Separation and Secretion

Endosperm development in Solanum nigrum was ab initio cellular.During early seed development, a Zone of Separation and Secretion(ZSS) differentiated within the endosperm. There were threephases in the formation of the ZSS. Phase I—stainabilityof the cell walls and middle lamella increased followed by numeroussmall plasmalemma invaginations (blebs) which became filledwith a fibrillar material. Phase II—the plasmalemma withdrewfrom the cell wall as a fibrillar lipo-carbohydrate matrix accumulatedoutside the plasmalemma. The middle lamella was gradually removedfrom between the cells forming the central axis of the cone.Phase III—the lipo-carbohydrate matrix continued to accumulateoutside the plasmalemma and also within the developing intercellularspaces. Some axial cells were completely separated from theremaining ZSS cells and became embedded in the matrix. The formationof the ZSS did not entail the destruction of the endosperm cellsand cell divisions were frequent. The ZSS was initially cone-shaped,capping the globular embryo. As the embryo sac enlarged, theZSS continued to differentiate. This resulted in a narrow curvedcorridor through the peripheral region of the endosperm whichterminated above the vascular trace. The embryo grew throughthe centre of the ZSS and pushed aside the separated axial cells.The ZSS facilitated the growth of the embryo through the restof the endosperm.Copyright 1993, 1999 Academic Press Lipo-carbohydrate matrix, extracellular matrix, endosperm development, Solanum nigrum, Zone of Separation and Secretion     

小麦×大麦胚胎发育的研究——Ⅲ.小麦×大麦胎胚发育过程中淀粉的积累和动态

我们观察了小麦与大麦杂交胚胎发育过程中,雌蕊各个组成部分发生的淀粉积累和转移的动态。结果如下: 1.胚乳和杂种胚早期发育过程中,子房壁和胚囊中淀粉的积累和动态的趋势与其他学者所作小麦自交的情况基本相同。2.当胚乳细胞充满胚囊而胚没有分化时,子房壁中的淀粉已极少,当胚乳解体时,子房壁中淀粉已几乎消失。可见,子房壁中淀粉的迅速消失与胚乳的迅速败育是平行的。3.胚囊发育的停滞与败育跟子房壁组织中淀粉的积累及对胚囊营养的正常供应有密切关系。4.花柱、珠被、珠心组织及胚囊中的助细胞和反足细胞,在整个杂种胚和胚乳发育过程中,始终不存在淀粉粒。助细胞胚亦和助细胞一样,无淀粉粒的存在。     

Epidermal and Guard Cell Interactions on Stomatal Aperture in Epidermal Strips and Intact Leaves

Despite the observation first made by von Mohl in 1856, thatepidermal cells greatly influence stomatal aperture, subsequentstudies have failed to pay adequate attention to epidermal cellviability or to quantify the degree of its influence on aperturein epidermal strips and leaf sections. Using Vicia faba stripsand leaf sections we found the following: (i) a non-linear relationshipbetween aperture and guard cell contact with live epidermalcells; (ii) epidermal cell viability on isolated strips hada threshold at about 25 °C; (iii) epidermal strips withdead epidermal cells had wider apertures and lower variabilitythan strips with live cells or intact leaf sections; (iv) afterepidermal cell viability was accounted for, stomatal aperturesshowed no significant differences between isolated strips orstrips removed from leaf sections treated in the same manner;(v) highly variable apertures appeared to be the normal conditionof the intact leaf. Caution should therefore be used in interpretingstomatal behaviour from epidermal strips without first takinginto account mechanical interactions between the guard and surroundingepidermal cells. Vicia faba L, broad bean, epidermal strips, leaf impressions, stomata, guard cells, temperature effects     

Global analysis of canola genes targeted by SHORT HYPOCOTYL UNDER BLUE 1 during endosperm and embryo development

Seed development in dicots includes early endosperm proliferation followed by growth of the embryo to replace the endosperm. Endosperm proliferation in dicots not only provides nutrient supplies for subsequent embryo development but also enforces a space limitation, influencing final seed size. Overexpression of Arabidopsis SHORT HYPOCOTYL UNDER BLUE1::uidA (SHB1:uidA) in canola produces large seeds. We performed global analysis of the canola genes that were expressed and influenced by SHB1 during early endosperm proliferation at 8 days after pollination (DAP) and late embryo development at 13 DAP. Overexpression of SHB1 altered the expression of 973 genes at 8 DAP and 1035 genes at 13 DAP. We also surveyed the global SHB1 association sites, and merging of these sites with the RNA sequencing data identified a set of canola genes targeted by SHB1. The 8‐DAP list includes positive and negative genes that influence endosperm proliferation and are homologous to Arabidopsis MINI3, IKU2, SHB1, AGL62, FIE and AP2. We revealed a major role for SHB1 in canola endosperm development based on the dynamics of SHB1‐altered gene expression, the magnitude of SHB1 chromatin immunoprecipitation enrichment and the over‐representation of eight regulatory genes for endosperm development. Our studies focus on an important agronomic trait in a major crop for global agriculture. The datasets on stage‐specific and SHB1‐induced gene expression and genes targeted by SHB1 also provide a useful resource in the field of endosperm development and seed size engineering. Our practices in an allotetraploid species will impact similar studies in other crop species.