Investigation of morphogenesis of inflorescence and determination of the nature of inheritance of “supernumerary spikelets” trait of bread wheat (Triticum aestivum L.) mutant line

Using C-banding and FISH methods, the karyotype of MC1611 induced mutant of bread wheat, which develop additional spikelets at a rachis node (trait “supernumerary spikelets”) was characterized. It was determined that the mutant phenotype is not associated with aneuploidy and major chromosomal rearrangements. The results of genetic analysis showed that supernumerary spikelets of the line are caused by a mutation of the single Bh-D.1 gene, influenced by the genetic background. The mutation causes abnormalities of inflorescence morphogenesis associated with the development of ectopic spikelet meristems in place of floral meristems in the basal part of the spikelets, causing the appearance of additional spikes at a rachis node. The mutant phenotype suggests that the Bh-D gene determines the fate of the lateral meristems in ear, which develops as floral meristem and gives rise to floral organs in wild-type inflorescences. In the bh-D.1 mutant, the floral meristem identity is impaired. The characterized mutant can be used in further studies on molecular genetic basis of development of wheat inflorescence.     

Analysis of inflorescence organogenesis in eastern gamagrass, Tripsacum dactyloides (Poaceae): the wild type and the gynomonoecious gsf1 mutant

Inflorescence organogenesis of a wild-type and a gynomonoecious (pistillate) mutant in Tripsacum dactyloides was studied using scanning electron microscopy. SEM (scanning electron microscope) analysis indicated that wild-type T. dactyloides (Eastern gamagrass) expressed a pattern of inflorescence organogenesis that is observed in other members of the subtribe Tripsacinae (Zea: maize and teosinte), family Poaceae. Branch primordia are initiated acropetally along the rachis of wild-type inflorescences in a distichous arrangement. Branch primordia at the base of some inflorescences develop into long branches, which themselves produce an acropetal series of distichous spikelet pair primordia. All other branch primordia function as spikelet pair primordia and bifurcate into pedicellate and sessile spikelet primordia. In all wild-type inflorescences development of the pedicellate spikelets is arrested in the proximal portion of the rachis, and these spikelets abort, leaving two rows of solitary sessile spikelets. Organogenesis of spikelets and florets in wild-type inflorescences is similar to that previously described in maize and the teosintes. Our analysis of gsf1 mutant inflorescences reveals a pattern of development similar to that of the wild type, but differs from the wild type in retaining (1) the pistillate condition in paired spikelets along the distal portion of the rachis and (2) the lower floret in sessile spikelets in the proximal region of the rachis. The gsf1 mutation blocks gynoecial tissue abortion in both the paired-spikelet and the unpaired-spikelet zone. This study supports the hypothesis that both femaleness and maleness in Zea and Tripsacum inflorescences are derived from a common developmental pathway. The pattern of inflorescence development is not inconsistent with the view that the maize ear was derived from a Tripsacum genomic background.     

Genetic and morphological characterization of the barley <Emphasis Type="Italic">uniculm2</Emphasis> (<Emphasis Type="Italic">cul2</Emphasis>) mutant

Axillary meristem growth and development help define plant architecture in barley (Hordeum vulgare L). Plants carrying the recessive uniculm2 (cul2) mutation initiate vegetative axillary meristem development but fail to develop tillers. In addition, inflorescence axillary meristems develop into spikelets, but the spikelets at the distal end of the inflorescence have an altered phyllotaxy and are sometimes absent. Double mutant combinations of cul2 and nine other recessive mutations that exhibit low to high tiller number phenotypes resulted in a uniculm vegetative phenotype. One exception was the occasional multiple shoots produced in combination with granum-a; a high tillering mutant that occasionally produces two shoot apical meristems. These results show that the CUL2 gene product plays a role in the development of axillary meristems into tillers but does not regulate the development of vegetative apical meristems. Moreover, novel double-mutant inflorescence phenotypes were observed with cul2 in combination with the other mutants. These data show that the wild-type CUL2 gene product is involved in controlling proper inflorescence development and that it functions in combination with some of the other genes that affect branching. Our genetic analysis indicates that there are genetically separate but not distinct regulatory controls on vegetative and inflorescence axillary development. Finally, to facilitate future positionally cloning of cul2, we positioned cul2 on chromosome 6(6H) of the barley RFLP map.     

Abnormalities Occurring during Female Gametophyte Development Result in the Diversity of Abnormal Embryo Sacs and Leads to Abnormal Fertilization in indica/japonica Hybrids in Rice

Embryo sac abortion is one of the major reasons for sterility in indica/japonica hybrids in rice. To clarify the causal mechanism of embryo sac abortion, we studied the female gametophyte development in two indica/japonica hybrids via an eosin B staining procedure for embryo sac scanning using confocal laser scanning microscope. Different types of abnormalities occurred during megasporogenesis and megagametogenesis were demonstrated. The earliest abnormality was observed in the megasporocyte. A lot of the chalazal-most megaspores were degenerated before the mono-nucleate embryo sac stage. Disordered positioning of nucleus and abnormal nucellus tissue were characteristics of the abnormal female gametes from the mono-nucleate to four-nucleate embryo sac stages. The abnormalities that occurred from the early stage of the eight-nucleate embryo sac development to the mature embryo sac stage were characterized by smaller sizes and wrinkled antipodals. Asynchronous nuclear migration, abnormal positioning of nucleus, and degeneration of egg apparatus were also found at the eight-nucleate embryo sac stage. The abnormalities that occurred during female gametophyte development resulted in five major types of abnormal embryo sacs. These abnormal embryo sacs led to abnormal fertilization. Hand pollination using normal pollens on the spikelets during anthesis showed that normal pollens could not exclude the effect of abnormal embryo sac on seed setting.     

Abnormalities Occurring during Female Gametophyte Development Result in the Diversity of Abnormal Embryo Sacs and Leads to Abnormal Fertilization in indicaljaponica Hybrids in Rice

Embryo sac abortion is one of the major masons for sterility in indicaljaponica hybrids In rice. To clarify the causal mechanism of embryo sac abortion, we studied the female gametophyte development in two indicaljaponica hybrids via an eosin B staining procedure for embryo sac scanning using confocal laser scanning microscope. Different types of abnormalities occurred during megasporogenesis and megagamatogenesis were demonstrated. The earliest abnormality was observed in the megasporocyte. A lot of the chalazal-most megaspores were degenerated before the mono-nucleate embryo sac stage. Disordered positioning of nucleus and abnormal nucallus tissue were characteristics of the abnormal female gametes from the mono-nucleate to four-nucleate embryo sac stages. The abnormalities that occurred from the early stage of the eight-nucleate embryo sac development to the mature embryo sac stage were characterized by smaller sizes and wrinkled antipodals. Asynchronous nuclear migration, abnormal positioning of nucleus, and degeneration of egg apparatus were also found at the eight-nucleate embryo sac stage. The abnormalities that occurred during female gametophyte development resulted in five major types of abnormal embryo sacs. These abnormal embryo sacs led to abnormal fertilization. Hand pollination using normal pollens on the spikelets during anthesis showed that normal pollens could not exclude the effect of abnormal embryo sac on seed setting.     

The Control of Leaf and Ear Size in Barley

The relative growth rates, growth rates, and final size of tillersand main-shoot leaves, internodes, and ear of a freely tilleringspring barley genotype were measured and compared with thoseof a non-tillering single-gene mutant. Leaf and internode growthand final size were greater in the non-tillering mutant. Thedifferences, it is proposed, arise because of changes in internalcompetition for assimilates brought about by the absence oftillers. There was little difference in ear growth or size,possibly because of abnormalities of ear development, whichresulted in fewer spikelets in the non-tillering genotype.     

The Vascular System in the Rachis of a Wheat Ear

The vascular system in the rachis of ears of wheat (Triticumaestivum L. cvs Gamenya, Olympic and Bungulla) was examinedon material grown in the field and in a growth cabinet. In theinternodes, central and peripheral bundles were observed andtheir mean number and size were determined. A significant 1:1 relationship between the number of spikelets on the ear andthe number of central bundles at the base of the rachis wasestablished. The number of both central and peripheral bundlesdeclined acropetally along thé length of the rachis.The decline in peripheral bundles occurred mainly between internodes1 and 6, numbered from the base. The decline in central bundlesoccurred at a rate of less than one bundle per internode betweeninternodes 1 and 4, though in some ears, there was no decline;in larger ears, central bundles declined at a rate of one totwo bundles per internode between internodes 5 and 11. Aboveinternode 11, the rate of decline varied with ear size. Threecentral bundles consistently reached the terminal spikelet.The number and cross-sectional surface area of xylem vesselsand sieve tubes and the total vascular size also declined acropetallyalong the rachis. The decline in total vascular size was dueto (a) some bundles branching and to reductions in size, (b)the diversion or dropping of bundles into spikelets, or (c)a combination of (a) and (b). These observations are discussedin relation to the distribution of grain number and weight onthe ear. Triticum aestivum L., wheat, rachis, spikelets, vascular anatomy, xylem, sieve tubes     

Development of the Vascular System in the Ear of Barley

In the mature rachis internodes of a two-row barley ear therewere two large lateral vascular bundles and a number of smallermedian and outer lateral vascular bundles. These bundles rannearly the full length of the rachis with no cross connectionsbetween them. The lateral and the outer lateral bundles branchedat every node while the median bundles branched at every othernode. The vascular bundles to each spikelet passed through acomplex region in which transfer cells occurred. Development of the vascular system of the young main shoot earstarted at the triple mound stage when the procambium of lateralbundles was initiated. Initiation of the median bundles andthe outer lateral bundles followed in sequence with some differentiationof protophloem and protoxylem. At awn initial stage of the earthe vascular connections to the spikelets were established withdifferentiation of the almost complete procambium proceedingthroughout the ear elongation phase. The progress of vascularisation in the young ear is discussedwith reference to spikelet initiation, ear relative growth rateand death of terminal spikelets. It is proposed that the changesin the relative growth rate of the ear and death of the terminalspikelets may be related to vascular differentiation     

Organogenesis of Fascicled ear mutant inflorescences in maize (Poaceae)

The ontogeny of staminate tassels and pistillate ears in the maize mutant Fascicled ear was examined using scanning electron microscopy. The normal pattern of inflorescence development is perturbed by the Fascicled ear mutation at the transition stage. The Fascicled ear mutation promotes the development of an abnormal transition stage axis that is both shorter and broader than the wild type. The inflorescence apical meristem then undergoes a bifurcation, and two inflorescence axes arise in place of a single axis. Each derived inflorescence apical meristem may undergo a similar perturbation sequence. This expression of the Fascicled ear mutation may be repeated one to several times, which leads to the development of a fascicled pistillate inflorescence and a fascicled central spike in the staminate inflorescence. The apical meristems of some tassel branches are also bifurcated. Subsequent organogenesis during paired-spikelet and floral development in Fascicled ear plants follows the pattern of normal maize. However, triplet spikelets are occasionally observed. The organogenic disruption by the Fascicled ear mutation that we describe will aid genetic and molecular analysis on the regulation of inflorescence development in maize and other members of the genus Zea.     

The Vascular Anatomy of the Barley Spikelet

In the spikelet axis of Proctor spring barley there was a coreof vascular tissue in which the normal collateral bundle structurewas not distinguishable. From this tissue the vascular strandsbranched out, in sequence, to the sterile lateral spikelets,the glumes, the lemma, the palea, the lodicules and the stamens.The vascular tissue of the spikelet axis terminated in the ovaryin four bundles of which the adaxial bundle passing close tothe ovule was the biggest. The arrangement of the vascular strandsand the presence of transfer cells indicated that assimilate,particularly from the lemma, can be easily translocated to thegrowing grain. In the collar region the spikelets, which inthe mature ear bear small grains, were less well vas-cularized. In the vascular tissue beneath the ovary were thick-walled cells.These cells and the cells of the funiculus-chalaza region maybe important in the process of translocation and grain growth.     

Early Growth of the Developing Ear of Spring Barley

The change in fresh weight of the developing ear and of groupsof spikelets of Maris Mink spring barley was measured for plantsgrown under three different conditions. Growth was closely describedby a third order polynomial equation. Instantaneous values ofrelative growth rate derived from these equations showed a declineto a minimum value, which was dependent on the growing conditionsand on position along the spike, followed by a rapid rise. Theminimum value was reached about 5 d before spikelet initiationceased and the subsequent rise in relative growth rate coincidedwith the period of rapid elongation of the rachis. Within thecar there was a tendency for younger spikelets to have a slightlyhigher relative growth rate than those initiated earlier. Possiblereasons for these growth changes are discussed in relation tospikelet differentiation, vascularization of the ear and nutrientavailability. Hordeum vulgare L., Barley, shoot apex, spikelets, ear, initiation, growth rate     

Branching Shoots and Spikes from Lateral Meristems in Bread Wheat

Wheat grain yield consists of three components: spikes per plant, grains per spike (i.e. head or ear), and grain weight; and the grains per spike can be dissected into two subcomponents: spikelets per spike and grains per spikelet. An increase in any of these components will directly contribute to grain yield. Wheat morphology biology tells that a wheat plant has no lateral meristem that forms any branching shoot or spike. In this study, we report two novel shoot and spike traits that were produced from lateral meristems in bread wheat. One is supernumerary shoot that was developed from an axillary bud at the axil of leaves on the elongated internodes of the main stem. The other is supernumerary spike that was generated from a spikelet meristem on a spike. In addition, supernumerary spikelets were generated on the same rachis node of the spike in the plant that had supernumerary shoot and spikes. All of these supernumerary shoots/spikes/spikelets found in the super wheat plants produced normal fertility and seeds, displaying huge yield potential in bread wheat.     

A MORPHOLOGICAL AND HISTOLOGICAL STUDY OF THE TOMATO MUTANT ‘CURL’

The dominant tomato mutant ‘Curl’ differs from normal plants in several striking respects including the following: misshapen laminar structures such as leaves, sepals, and petals; stunted petiole and rachis; and persistent growth of blade and stem tissue from the adaxial surface of the rachis. These tissues as well as others which appear morphologically normal show gross histological abnormalities. Also evident in sections of mutant tissue is the appearance of areas containing numerous crystalline inclusions and a lack of bodies showing a stainable starch reaction in palisade and mesophyll of leaves and in endodermis and pith cells of the stem.     

Development and Floret Survival in Wheat Ears With Supernumerary Spikelets

In the supernumerary spikelet wheat, AUS159I0, the supernumeraryspikelet primordia appeared just after the ear reached the terminalspikelet stage. Appearance of the primordia of the multiplesessile spikelets preceded that of indeterminate rachilla spikelets.Supernumerary spikelets had a lower number of potentially fertileflorets per spikelet than normal (non-supernumerary) spikeletsin the ear and thus a smaller number of grains per spikelet.Mean weight per grain in the supernumerary spikelet wheat waslower than in the cultivar, Meering, without supernumerary spikelets.Total grain number in the supernumerary spikelet ear was greaterthan in the normal ear despite the lower spikelet fertilityin the former. Within the supernumerary spikelet ear the multiplesessile spikelets had a higher number of grains per spikeletand mean weight per grain than the indeterminate rachilla spikelets.It appears possible to improve the productivity of the supernumeraryspikelet ear by breeding for reduced expression of the indeterminaterachilla spikelets. Wheat, ear development, floret survival, supernumerary spikelets, grain number     

Dense cataract and microphthalmia--new spontaneous mutation in BALB/c mice

We describe a new spontaneous mutation in BALB/c mice that causes abnormal phenotype, such as congenital cataract and microphthalmia. This abnormality was found to be inheritable because offspring with the same abnormality were produced by backcrossing the abnormal male to its normal female parent. Results of various crosses made to determine the mode of inheritance indicated that this abnormality is attributable to mutation of an autosomal recessive gene. Slit lamp examination of the mutant eyes revealed total lenticular opacity, disturbed typical iris pattern, and abnormal pupillary muscle development. Histologic changes in mutant eyes between gestation day 13 and postnatal day 1 indicated various eye and lens abnormalities, including microphthalmia; underdeveloped iris, optic stalk, cornea, and retina; degenerated lens fibers with lost fibrillar structure; and vacuoles of various sizes at the posterior border of the lens. Mild opacity of the lens was found to progress with age and became denser, resembling mature cataract, and occupying the lens completely at the age of six to eight weeks. We, therefore, temporarily designated this abnormality as dense cataract and microphthalmia, with the gene symbol dcm.     

Abnormalities Induced in Barley Ears by Gibberellic Acid

Five varieties of spring barley were sprayed with gibberellicacid (GA) at various growth stages from the one-leaf to thefive-leaf stage. In short days a number of abnormalities ofthe ear were found. These abnormalities are described in themature ear, and in the case of the branched ear, the ontogenyof the abnormality is shown. The relationship of the abnormalitiesto the environment, to the stage at which the plant was treated,and to the variety is analysed. The role of CA in inducing these abnormal features is discussedand their resemblance to abnormalities induceed geneticallyand by enviromental manipulations is pointed out.     

云南元江普通野生稻穗颈维管束和穗部性状的QTL分析

以云南元江普通野生稻为供体亲本,籼稻品种特青为轮回亲本构建高代回交群体,用SSR标记构建连锁图谱,在第1、2、3、4、7和10染色体上定位到7个控制穗颈大维管束数的QTL,在第1、2、3、4和8染色体上定位到5个控制穗颈小维管束数的QTL,在第11和12以外的10条染色体上,共定位到15个控制穗一、二次枝梗数和穗颖花数QTL。来自野生稻的等位基因大多表现负效,能显著减少群体的穗颈维管束数、枝梗数和颖花数,说明从野生稻演化成栽培稻的过程中,可能淘汰了一些对产量不利的QTL,保留了有利的QTL。相当一部分控制穗颈维管束数、枝梗数及颖花数的QTL在染色体上成簇分布或紧密连锁,且加性效应的方向一致,从理论上解释了这些性状表型显著相关的遗传基础,同时也说明在人工选择或自然选择下,这些性状可能存在平行进化或协同进化的关系。     

The Effect of High Temperature at Different Stages of Ripening on Grain Set, Grain Weight and Grain Dimensions in the Semi-dwarf Wheat 'Banks'

Grain number in the wheat cultivar Banks was reduced by up to11 % with a rise in temperature from 21/16 °C to 30/25 °Cover a 10-d period immediately following first anthesis in general,the upper ‘d’ and ‘c’ florets were moreaffected by high temperature than the basal ‘a’and ‘b’ florets within a spikelet and florets fromthe upper spikelets were more sensitive than those lower onthe ear Grain weight and grain length at maturity were most affectedby a 10 d period of high temperature commencing 7–10 dafter anthesis However, if dry-matter accumulation between thestart of a treatment and grain maturity was used as a base forcomparison, the response was more uniform throughout development,with a peak in sensitivity 25 d after anthesis Although grainposition within an ear did not have a large effect on the responseto temperature, grains from the basal spikelets were more sensitivethan those from the apex, and the upper floret grains of a spikeletwere more sensitive to high temperature than those at the base There is a need to obtain, for a range of cultivars, more comprehensivedata on the effect of the timing and degree of temperature stressfollowing anthesis, for use in interpreting the response torising temperatures late in the development of the crop in thefield Triticum aestivum L, wheat, temperature, grain development     

Morphogenesis of 2,4-D Induced Abnormalities of the lnflorescence of Bread Wheat (Triticum aestivum, L.).

Treatment of Triticum plants with 2,4-D profoundly affects inflorescencemorphogenesis and results in the production of various abnormalities,amongst which are branched heads, whorls of spikelets. superimposedpairs of spikelets (‘banana’ twin spikelets) andpaired spikelets borne at the same level (‘yoked’spikets). Often more than one kind of abnormality is observedin a single head. Except for ‘banana’ twin spikelets,none of the induced abnormalities are duplicated by abnormalitieswhich occur spontaneously in untreated plants. Disturbance dueto treatment is only temporary and later the terminal regionof the apex recommences growth along a normal pattern of morphogenesis.     

东北草原羊草种群单穗数量性状的生态可塑性

羊草（Leymus chinensis(Trin.)Tzvel.）是一种多年生禾本科优良牧草。经过对东北草原3个固定样地连续12a,分别随机取样100个穗状花序的调查和测定,将羊草种群单穗数量性状的生态可塑性进行了统计分析,并且分别与不同生长发育阶段气候因子进行了相关分析。结果表明,羊草种群的单穗长度、小穗数和小花数的生态可塑性变化在样地内和样地间,以及年度内和年度间均达到了极显著水平。其中,均表现为年度内大于年度间,样地内大于样地间,样地间大于年度间。羊草种群单穗数量性状均与形成性状的生育期,及其以前各生育期不同阶段的光照时间、积温、降水量有着一定程度的相关关系。在整个冬性枝条生长发育期,较多的降水、较少的光照时间和较低的积温将对翌年幼穗分化及其生长有一定的促进作用,而较少的降水、较多的光照时间和较高的积温则有不利影响;从拔节到抽穗阶段较多的降水对幼穗分化具有一定的促进作用,但从返青到抽穗不同阶段较高的积温和较多的光照、以及返青初期较多的降水量则有着一定的不利影响。气候因子对羊草种群幼穗分化滞后效应的生态时间差可长达10个月。