Developmental genetics of mutants that specify knotted leaves in maize

Of seven dominant knotted-leaf mutants tested, six mapped at or near Kn1 on the long arm of chromosome 1, and one was not linked to Kn1. Comparisons of phenotypes among these mutants allowed us to focus on a systematic abnormality: the parenchyma cells associated with lateral veins do not fully differentiate into bundle sheath, mesophyll or upper sclerenchyma. The more dramatic expression of Kn1 mutants—knots, ligule alterations and twisting—is sporadic and dependent on the time when the mutant acts in leaf primordium development. Using lw to mark leaf sectors that lose Kn1 following X-irradiation, we show that the knotted-leaf phenotype encoded by chromosome 1L is autonomous. Analysis of sectors lacking a particular Kn1 gene ( Kn1-N2) suggests that Kn1 itself, rather than a linked modifier gene, is autonomous in the leaf primordium. Aneuploid studies using various translocations involving 1L and marked by Adh1 allozymes are compared. The Kn1 mutant appears to encode a "new" function or a considerable overproduction of an extant product in the leaf. Kn1/- 1L hypoploids either express knotted poorly or not at all; transvection is ruled out, but the cause for this modification of Kn1 expression is not yet known.—Our working hypothesis is that Kn1 mutants permit the expression of a product that is usually not produced in leaf primordial cells. We suggest that this product interferes with the early cell-type commitments of cells near lateral veins. Thus, relatively uncommitted cells are present in more mature blades, where they may divide unexpectedly into knots or may induce bits of ligule.     

Division and differentiation during normal and liguleless-1 maize leaf development

The maize leaf is composed of a blade and a sheath, which are separated at the ligular region by a ligule and an auricle. Mutants homozygous for the recessive liguleless-1 (lg1) allele exhibit loss of normal ligule and auricle. The cellular events associated with development of these structures in both normal and liguleless plants are investigated with respect to the timing of cell division and differentiation. A new method is used to assess orientation of anticlinal division planes during development and to determine a division index based on recent epidermal cross-wall deposition. A normal leaf follows three stages of development: first is a preligule stage, in which the primordium is undifferentiated and dividing throughout its length. This stage ends when a row of cells in the preligule region divides more rapidly in both transverse and longitudinal anticlinal planes. During the second stage, ligule and auricle form, blade grows more rapidly than sheath, divisions in the blade become exclusively transverse in orientation, and differentiation begins. The third stage is marked by rapid increase in sheath length. The leaf does not have a distinct basal meristem. Instead, cell divisions are gradually restricted to the base of the leaf with localized sites of increased division at the preligule region. Divisions are not localized to the base of the sheath until near the end of development. The liguleless-1 homozygote shows no alteration in this overall pattern of growth, but does show distinct alteration in the anticlinal division pattern in the preligule region. Two abnormal patterns are observed: either the increase in division rate at the preligule site is absent or it exhibits loss of all longitudinal divisions so that only transverse (or cell-file producing) divisions are present. This pattern is particularly apparent in developing adult leaves on older lg1 plants, in which sporadic ligule vestiges form. From these and results previously published (Becraft et al. (1990) Devl Biol. 14), we conclude that the information carried by the Lg1+ gene product acts earlier in development than formation of the ligule proper. We hypothesize that Lg1+ may be effective at the stage when the blade-sheath boundary is first determined.     

Secondary cell wall deposition causes radial growth of fibre cells in the maturation zone of elongating tall fescue leaf blades

A gradient of development consisting of successive zones of cell division, cell elongation and cell maturation occurs along the longitudinal axis of elongating leaf blades of tall fescue (Festuca arundinacea Schreb.), a C3 grass. An increase in specific leaf weight (SLW; dry weight per unit leaf area) in the maturation region has been hypothesized to result from deposition of secondary cell walls in structural tissues. Our objective was to measure the transverse cell wall area (CWA) associated with the increase in SLW, which occurs following the cessation of leaf blade elongation at about 25 mm distal to the ligule. Digital image analysis of transverse sections at 5, 15, 45, 75 and 105 mm distal to the ligule was used to determine cell number, cell area and protoplast area of structural tissues, namely fibre bundles, mestome sheaths and xylem vessel elements, along the developmental gradient. Cell diameter, protoplast diameter and area, and cell wall thickness and area of fibre bundle cells were calculated from these data. CWA of structural tissues increased in sections up to 75 mm distal to the ligule, confirming the role of cell wall deposition in the increase in SLW (r2 = 0.924; P < or = 0.01). However, protoplast diameter of fibre cells did not decrease significantly as CWA increased, although mean thickness of fibre cell walls increased by 95 % between 15 and 105 mm distal to the ligule. Therefore, secondary cell wall deposition in fibre bundles of tall fescue leaf blades resulted in continued radial expansion of fibre cells rather than in a decrease in protoplast diameter.     

The establishment of axial patterning in the maize leaf

The maize leaf consists of four distinct tissues along its proximodistal axis: sheath, ligule, auricle and blade. liguleless1 (lg1) functions cell autonomously to specify ligule and auricle, and may propagate a signal that correctly positions the blade-sheath boundary. The dominant Wavy auricle in blade (Wab1) mutation disrupts both the mediolateral and proximodistal axes of the maize leaf. Wab1 leaf blades are narrow and ectopic auricle and sheath extend into the blade. The recessive lg1-R mutation exacerbates the Wab1 phenotype; in the double mutants, most of the proximal blade is deleted and sheath tissue extends along the residual blade. We show that lg1 is misexpressed in Wab1 leaves. Our results suggest that the Wab1 defect is partially compensated for by lg1 expression. A mosaic analysis of Wab1 was conducted in Lg1+ and lg1-R backgrounds to determine if Wab1 affects leaf development in a cell-autonomous manner. Normal tissue identity was restored in all wab1+/- sectors in a lg1-R mutant background, and in three quarters of sectors in a Lg1+ background. These results suggest that lg1 can influence the autonomy of Wab1. In both genotypes, leaf-halves with wab1+/- sectors were significantly wider than non-sectored leaf-halves, suggesting that Wab1 acts cell-autonomously to affect lateral growth. The mosaic analysis, lg1 expression data and comparison of mutant leaf shapes reveal previously unreported functions of lg1 in both normal leaf development and in the dominant Wab1 mutant.     

Interactions of Liguleless1 and Liguleless2 Function during Ligule Induction in Maize

The maize ligule is an adaxial membranous structure on the leaf that develops at the boundary of the sheath and blade. The ligule and the associated auricle are dispensable structures, amenable to genetic manipulation. We present here a genetic analysis of liguleless1 (lg1) and liguleless2 (lg2), the two genes known to be uniquely necessary for ligule and auricle development. We show that both reference mutant alleles, lg1-R and lg2-R, are null alleles. The double mutant phenotype suggests that lg1 and lg2 act in the same pathway. Indeed, the dosage of a functional allele at either gene affects the null phenotype of the other. While lg1 function has previously been shown to be cell-autonomous, here we show that the lg2-R phenotype is cell-nonautonomous, suggesting lg1 and lg2 play different roles in the ligule-auricle induction mechanism. We present a model in which early lg2 function specifies the precise position where ligule and auricle will develop. Later lg2 function interacts with lg1 function (either directly or indirectly) to transmit and receive a make-ligule-make-auricle inductive signal.     

Maize mutants and variants altering developmental time and their heterochronic interactions.

It is useful to envision two fundamentally different ways by which the timing of plant development is regulated: developmental stage-transition mechanisms and time-to-flowering mechanisms. The existence of both mechanisms is indicated by the behavior of various mutants. Shoot stage transitions are defined by dominant mutants representing at least four different genes; each mutant retards transitions from juvenile shoot stages to more adult shoot stages. In addition, dominant leaf stage-transition mutants in at least seven different genes have similar phenotypes, but the leaf rather than the shoot is the focus (and at least two of these genes encode homeodomain proteins.) One mutant, Hairy sheath frayed 1-O (Hsf1-O) simultaneously affects shoot and leaf; this mutant's behavior initiated our interest in plant heterochronism. The second type of timekeeping involves time-to-flowering. As with most plant but not animal species, cultivars of the maize species vary greatly for the time-to-flowering quantitative trait: between 6 and 14 weeks is common. It is via the 'slipping time frames' interaction that takes place between stage-transition mutants and time-to-flowering genetic backgrounds that unexpected and radical phenotypes occur. We see a reservoir of previously unsuspected morphological possibilities among the few heterochronic genotypes we have constructed, possibilities that may mimic the sort of variation needed to fuel macroevolution without having to posit (as done by Goldschmidt) any special macromutational mechanisms.     

Mutant characters of knotted maize leaves are determined in the innermost tissue layers

Knotted (Kn1), a dominant mutation in maize, perturbs normal leaf development. Mutant leaves have localized regions of extra growth called knots and, in addition to the normal ligule, ectopic fringes of ligule are found on the leaf blade. Previous clonal analysis showed that the epidermal genotype was immaterial in knot formation. To establish which inner leaf layer was required for formation of knots and ectopic ligule we used a closely linked albino mutation to mark X-ray-induced clonal sectors of wild type (kn) tissue in Kn1 plants. The sectors examined frequently changed in composition of layers in the leaf both transversely and longitudinally. We present results that show that both mutant characters are determined in the middle mesophyll-bundle sheath (MMBS) layer. We show that a lateral vein can produce a knot when only half the MMBS layer around the lateral vein contains the mutant gene. We also show that the ectopic ligule in Kn1 has contributions from both the adaxial epidermal and adaxial mesophyll layer.     

Sectors of liguleless-1 tissue interrupt an inductive signal during maize leaf development.

The ligule and auricles separate the blade and sheath of normal maize leaves and are absent in liguleless-1 (lg1) mutant leaves. We induced chromosome breakage using X-rays to create plants genetically mosaic for lg1. In genetically mosaic leaves, when an lg1 mutant sector interrupts the normal ligule, the ligule is often displaced basipetally on the marginal side of the sector. Therefore, lg1 mutant sectors not only fail to induce ligule and auricle, but are also disrupting some form of intercellular communication that is necessary for the normally coordinated development of the ligular region. Our data are consistent with a model in which an inductive signal originates near the midvein, cannot traverse the lg1 mutant sector, and reinitiates in the wild-type tissue across the sector toward the leaf margin. The lg1 gene product, therefore, appears to be required for the transmission of this signal and could be involved with reception.     

小麦的穗领在系统演化和个体发育中形成过程的初步探讨

小麦的穗领有三种类型:领腹完全敞开的U形穗领、领腹完全闭合的O形穗领和领腹呈V型交叉的V形穗领。穗领是系统演化中顶生叶叶鞘减化后的遗迹,也是个体发育中穗轴基部第一侧生小穗下苞叶原始体的痕迹。在一定条件下,从穗领可以长出叶鞘和叶片,穗轴基部节间可以变为茎节间,穗领腋内的小穗可以变为腋芽、带柄分枝穗或分枝花序。其余侧生小穗下都有一个领腹完全敞开的U形小穗领,其形态与U形穗领相似。它们是系统演化中二次轴分枝花序的苞叶叶鞘减化后的遗迹,也是个体发育中苞原始体的痕迹。一定条件下,从小穗领也可以长出叶鞘和叶片。穗轴基部节间变茎的同时,基部几个小穗若发生向圆锥花序的部分返祖变异,随着变异程度加深,从穗领和小穗领逐渐形成叶鞘和叶片。说明在系统演化中。顶生叶和苞叶先减化叶片,后减化叶鞘,最后形成穗领和小穗领。小麦祖先的花序与茎叶之间没有明显的界限。     

Epidermal Cell Division and the Coordination of Leaf and Tiller Development

Initiation and development of grass leaves and tillers are oftendescribed individually with little attention to possible interrelationshipsamong organs. In order to better understand these interrelationships,this research examined epidermal cell division during developmentaltransitions at the apical meristem of tall fescue (Festuca arundinaceaSchreb.). Ten seedlings were harvested each day for a 9-d period,and lengths of main shoot leaves and primary tillers were measured.In addition, numbers and lengths of epidermal cells were determinedfor 0·5 mm segments along the basal 3 mm of each leafand tiller. Primordia development and onset of rapid leaf elongationwere characterized by an increase in the number of cells perepidermal file with mean cell length remaining near 20 µmper cell. After the leaf had lengthened to 1-1·5 mm,cells near the leaf tip ceased dividing and increased in length,at which time leaf elongation rate increased rapidly. Liguleformation, marking the boundary between blade and sheath cells,occurred prior to leaf tip emergence above the whorl of oldersheaths, while the earliest differentiation between blade andsheath cells probably began when leaves were < 1 mm long.Major transitions in leaf and tiller development appeared tobe synchronized among at least three adjacent nodes. At theoldest node, cessation of cell division in the leaf sheath wasaccompanied by initiation of cell division and elongation inthe associated tiller bud. At the next younger node the ligulewas being initiated, while at the youngest node cell divisioncommenced in the leaf primordium, as elongation of a new leafblade began. This synchronization of events suggests a key rolefor the cell division process in regulating leaf and tillerdevelopment.Copyright 1994, 1999 Academic Press Festuca arundinacea Schreb., tall fescue, cell division, leaf initiation, tillering, ligule development     

The Embryonic Development Study on Isoetes yunguiensis,an Endangered and Relict Pteridophyta

Isoetes yunguiensis is a specialty relict fern of Yunnan Guizhou Plateau,which is a national level protected species called living fossil of the study on paleoecology and plant evolutionary in Yunnan and Guizhou area, but its reproduction and endangered mechanism is unclear. On the basis of implementation of artificial breeding and acquisition of adequate research materials, the authors observe the embryonic development of Iyunguiensis using thin sectioning. The main results of observation of the embryonic development are as follows: (1) The zygote doesn’t have the period of dormancy; (2) The angle between the division planes of zygote and the long axis of archegonium is about 30°; (3) The first leaf primordium and the first root primordium develop first. However, the first leaf primordium develop earlier than the first root primordium; (4) The initial cells of ligule begin to divide since the initial stage of the development of leaf; (5) The cells of the open end of archegonium often appear necrosis and affect the embryonic development; (6) The embryo malformation is easy to happen; (7) The sheet structure develop fast, and it provide good protect for the second and third leaf primordium; (8) The order of early vascular development. The article explore the reproductive biology regular and reproductive endangered mechanism of Iyunguiensis. The coalescent form of the original evolution of vegetative organs of vascular plants is analyzed. This article also accumulate technical data for protection of Iyunguiensis.     

Maize host requirements for Ustilago maydis tumor induction

The biotrophic pathogen Ustilago maydis causes tumors by redirecting vegetative and floral development in maize (Zea mays L.). After fungal injection into immature tassels, tumors were found in all floral organs, with a progression of organ susceptibility that mirrors the sequential location of foci of cell division in developing spikelets. There is sharp demarcation between tumor-forming zones and areas with normal spikelet maturation and pollen shed; within and immediately adjacent to the tumor zone, developing anthers often emerge precociously and exhibit a range of developmental defects suggesting that U. maydis signals and host responses are restricted spatially. Male-sterile maize mutants with defects in anther cell division patterns and cell fate acquisition prior to meiosis formed normal adult leaf tumors, but failed to form anther tumors. Methyl jasmonate and brassinosteroid phenocopied these early-acting anther developmental mutants by generating sterile zones within tassels that never formed tumors. Although auxin, cytokinin, abscisic acid and gibberellin did not impede tassel development, the Dwarf8 mutant defective in gibberellin signaling lacked tassel tumors; the anther ear1 mutant reduced in gibberellin content formed normal tumors; and Knotted1, in which there is excessive growth of leaf tissue, formed much larger vegetative and tassel tumors. We propose the hypothesis that host growth potential and tissue identity modulate the ability of U. maydis to redirect differentiation and induce tumors.     

CHARACTERIZATION OF DEVELOPMENT IN MAIZE THROUGH THE USE OF MUTANTS. II. THE ABNORMAL GROWTH CONDITIONED BY THE KNOTTED MUTANT

The maize mutant Knotted (Kn) is characterized by hollow, finger-like outgrowths (knots) occurring mainly in the leaf blade. Portions of the ligule are displaced from the normal position to more distal locations within the blade. Knots apparently result from continued meristematic activity of isolated patches of cells surrounded by maturing tissue. Small knots appear to be centers of cell division. Epidermal cells overlying a small knot have been observed to undergo periclinal divisions. In addition to cell division, a reorientation of the axis of cell elongation is associated with knot formation. The pattern of knot distribution varies at different levels on the plant axis and within a leaf blade. From leaf 4 to leaf 10 or 11 the number of knots per leaf increases progressively, then declines in leaves initiated later. Knots always occur in association with lateral veins. The greatest number per vein occurs on the 3rd or 4th vein from the midrib. One plant developing from an X-rayed heterozygous seed possessed a sector of normal tissue bisecting the plant in a vertical plane passing through the midrib of each leaf except the top two. The normal sector was knot-free and had the ligule restored to the normal position. These observations suggest that cells with the characteristics of those from intercalary meristems occur throughout the blade in Knotted plants.     

Early stages of leaf development in <Emphasis Type="Italic">has</Emphasis> mutant of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

The elucidation of molecular mechanisms underlying the leaf development can be facilitated by the detailed anatomical study of leaf development mutants. We present an analysis of leaf anatomy and morphogenesis during early developmental stages in has mutant of Arabidopsis thaliana. The recessive has mutation affects a number of aspects in plant development, including the shape and size of both cotyledons and leaves. The earliest developmental observations suggest almost synchronous growth of the first two leaf primordia of has mutant. No significant disruption of the cell division pattern in the internal tissue is observed at the earliest stages of development, with the major anatomical difference compared to wild type primordia being the untimely maturation of mesophyll tissue cells in has mutant. At the stage of leaf blade formation, structure disruption becomes clearly evident, by irregular arrangement of the cell layers and the lack of polarity in juvenile has leaves. One distinguishing feature of the mutant leaf anatomy is the absence of mesophyll tissue differentiation. Altered has mutant leaf morphology could be at least partially accounted for by the ectopic STM activity that was found at the base of leaf primordia during early stages of leaf development in has plants.     

RADIATION-INDUCED GENETIC MARKERS IN THE STUDY OF LEAF GROWTH IN ZEA

Stein , Otto L. (Montana State U., Missoula.), and Dale Steffensen . Radiation-induced genetic markers in the study of leaf growth in Zea. Amer. Jour. Bot. 46(7): 485–489. Illus. 1959.—Corn embryos heterozygous for the plant color mutant yellow-green were treated with moderate doses of radiation. The sectors resulting from the loss of the dominant gene Yg₂ furnish a graphic illustration of the growth of an organ in space and time. Wet embryos were irradiated and leaves 3 through 6 were analyzed. The total number of sectors per leaf increases in relation to the amount of leaf tissue present at time of irradiation and their distribution varies, indicating a change in mitotic activity during early ontogeny of the leaf. As represented by leaf 6 in the mature embryo, cell division is rather uniform throughout the young primordium. Soon thereafter (leaf 5) cell divisions in the apical region increase, though cell lineages remain short. In the basal region of the leaf, the proportion of cell division decreases but those cells which do divide continue their activity over a longer period than the apical cells. Longer files of mutant cells are formed in such a way. The mid regions of the leaf maintain their status quo in terms of distribution of sectors. The results indicate that differentiation of the intercalary meristem as a thin band occurs early in the development of the leaf primordium. The use of genetic techniques in conjunction with radiation, in this case as a “timed” release of genetic markers, may be a useful tool in the precise analysis of the dynamic aspects of organogenesis and histogenesis.