Investigation of the role of cell-cell interactions in division plane determination during maize leaf development through mosaic analysis of the tangled mutation

Most plant cells divide in planes that can be predicted from their shapes according to simple geometrical rules, but the division planes of some cells appear to be influenced by extracellular cues. In the maize leaf, some cells divide in orientations not predicted by their shapes, raising the possibility that cell-cell communication plays a role in division plane determination in this tissue. We investigated this possibility through mosaic analysis of the tangled (tan) mutation, which causes a high frequency of cells in all tissue layers to divide in abnormal orientations. Clonal sectors of tan mutant tissue marked by a closely linked albino mutation were examined to determine the phenotypes of cells near sector boundaries. We found that tan mutant cells always showed the mutant phenotype regardless of their proximity to wild-type cells, demonstrating that the wild-type Tan gene acts cell-autonomously in both lateral and transverse leaf dimensions to promote normally oriented divisions. However, if the normal division planes of wild-type cells depend on cell-cell communication involving the products of genes other than Tan, then aberrantly dividing tan mutant cells might send abnormal signals that alter the division planes of neighboring cells. The cell-autonomy of the tan mutation allowed us to investigate this possibility by examining wild-type cells near the boundaries of tan mutant sectors for evidence of aberrantly oriented divisions. We found that wild-type cells near tan mutant cells did not divide differently from other wild-type cells. These observations argue against the idea that the division planes of proliferatively dividing maize leaf epidermal cells are governed by short-range communication with their nearest neighbors.     

Light fluence rate and chloroplasts are sources of signals controlling mesophyll cell morphogenesis and division

As part of the acclimation of the photosynthetic apparatus to high fluence rates of light, mesophyll (photosynthetic) leaf cells change in morphology (they elongate anticlinally or perpendicular to the leaf surface) and undergo extra cell divisions. This results in increased leaf thickness and internal, protective shading among chloroplasts. Here we have examined whether the chloroplasts themselves are sources of intracellular signals that trigger these changes, by monitoring the Arabidopsis thaliana chm1 variegated mutant, in which albino (chloroplast-defective) and green (with functional chloroplasts) sectors coexist in one leaf. Our results have uncovered two separable responses. The increase in mesophyll cell elongation was substantially reduced but still observable in albino sectors, indicating that chloroplasts contribute to the cell morphogenesis response, but a chloroplast-independent light sensory mechanism must exist. In contrast the change in number of mesophyll cell layers was completely abolished when plastids were dysfunctional, indicating that plastids are sole sources of signals for the cell division response. These data highlight the importance of plastid-derived signals in the cellular responses associated with photosynthetic acclimation.     

Folic acid stimulation of the Gα4 G protein-mediated signal transduction pathway inhibits anterior prestalk cell development in Dictyostelium

In Dictyostelium discoideum, several G proteins are known to mediate the transduction of signals that direct chemotactic movement and regulate developmental morphogenesis. The G protein alpha subunit encoded by the Galpha4 gene has been previously shown to be required for chemotactic responses to folic acid, proper developmental morphogenesis, and spore production. In this study, cells overexpressing the wild type Galpha4 gene, due to high copy gene dosage (Galpha4HC), were found to be defective in the ability to form the anterior prestalk cell region, express prespore- and prestalk-cell specific genes, and undergo spore formation. In chimeric organisms, Galpha4HC prespore cell-specific gene expression and spore production were rescued by the presence of wild-type cells, indicating that prespore cell development in Galpha4HC cells is limited by the absence of an intercellular signal. Transplanted wild-type tips were sufficient to rescue Galpha4HC prespore cell development, suggesting that the rescuing signal originates from the anterior prestalk cells. However, the deficiencies in prestalk-specific gene expression were not rescued in the chimeric organisms. Furthermore, Galpha4HC cells were localized to the prespore region of these chimeric organisms and completely excluded from the anterior prestalk region, suggesting that the Galpha4 subunit functions cell-autonomously to prevent anterior prestalk cell development. The presence of exogenous folic acid during vegetative growth and development delayed anterior prestalk cell development in wild-type but not galpha4 null mutant aggregates, indicating that folic acid can inhibit cell-type-specific differentiation by stimulation of the Galpha4-mediated signal transduction pathway. The results of this study suggest that Galpha4-mediated signals can regulate cell-type-specific differentiation by promoting prespore cell development and inhibiting anterior prestalk-cell development.     

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.     

A chlorate-resistant mutant defective in the regulation of nitrate reductase gene expression in Arabidopsis defines a new HY locus.

Light acts both directly as a signal and indirectly through photosynthesis to regulate the expression of genes encoding nitrate reductase (NR). Here, we report the isolation and characterization of a novel chlorate-resistant mutant that is defective in the regulation of NR gene expression. The response of NR2, but not NR1 or the gene encoding nitrate reductase (NiR), to light signals was impaired in this Arabidopsis mutant, designated cr88. In addition to NR2, the light regulation of the genes encoding the chlorophyll a/b binding protein (CAB) and the small subunit of ribulose bisphosphate carboxylase (RBCS) was also impaired in this mutant. These results suggest that the pathway through which light regulates the expression of NR2, CAB, and RBCS genes is different from those that regulate the expression of NR1 and NiR. An examination of the deetiolation process under different light spectrum showed that cr88 is defective in red light-mediated deetiolation. Complementation tests with various long hypocotyl (hy) mutants indicated that CR88 identifies a new HY locus. The possible functions of CR88 are discussed.     

The DCL gene of tomato is required for chloroplast development and palisade cell morphogenesis in leaves.

The defective chloroplasts and leaves-mutable (dcl-m) mutation of tomato was identified in a Ds mutagenesis screen. This unstable mutation affects both chloroplast development and palisade cell morphogenesis in leaves. Mutant plants are clonally variegated as a result of somatic excision of Ds and have albino leaves with green sectors. Leaf midribs and stems are light green with sectors of dark green tissue but fruit and petals are wild-type in appearance. Within dark green sectors of dcl-m leaves, palisade cells are normal, whereas in albino areas of dcl-m leaves, palisade cells do not expand to become their characteristic columnar shape. The development of chloroplasts from proplastids in albino areas is apparently blocked at an early stage. DCL was cloned using Ds as a tag and encodes a novel protein of approximately 25 kDa, containing a chloroplast transit peptide and an acidic alpha-helical region. DCL protein was imported into chloroplasts in vitro and processed to a mature form. Because of the ubiquitous expression of DCL and the proplastid-like appearance of dcl-affected plastids, the DCL protein may regulate a basic and universal function of the plastid. The novel dcl-m phenotype suggests that chloroplast development is required for correct palisade cell morphogenesis during leaf development.     

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.     

B7-independent inhibition of T cells by CTLA-4

CTLA-4 is an inhibitory molecule that regulates T cell expansion and differentiation. CTLA-4 binding to B7-1/B7-2 is believed to be crucial for its inhibitory signal both by competing for CD28 binding to the same ligands and aggregating CTLA-4 to deliver negative signals. In this study, we demonstrate that B7 binding is not essential for CTLA-4 activity. CTLA-4 knockout T cells are hyperresponsive compared with wild-type T cells in B7-free settings. Expression of a B7-nonbinding CTLA-4 mutant inhibited T cell proliferation, cytokine production, and TCR-mediated ERK activation in otherwise CTLA-4-deficient T cells. Finally, transgenic expression of the ligand-nonbinding CTLA-4 mutant delayed the lethal lymphoproliferation observed in CTLA-4-deficient mice. These results suggest that ligand binding is not essential for the CTLA-4 function and supports an essential role for CTLA-4 signaling during T cell activation.     

Fluorescence kinetic parameters and cyclic electron transport in guard cell chloroplasts of chlorophyll-deficient leaf tissues from variegated weeping fig (<Emphasis Type="Italic">Ficus benjamina</Emphasis> L.)

Residual chlorophyll in chlorophyll-deficient (albino) areas of variegated leaves of Ficus benjamina originates from guard cell chloroplasts. Photosynthetic features of green and albino sectors of F. benjamina were studied by imaging the distribution of the fluorescence decrease ratio Rfd within a leaf calculated from maximum (Fm) and steady-state leaf chlorophyll fluorescence (Fs) at 690 and 740 nm. Local areas of albino sectors demonstrated an abnormally high Rfd₇₄₀/Rfd₆₉₀ ratio. Fluorescence transients excited in albino sectors at red (640 and 690 nm) wavelengths showed an abrupt decrease of the Rfd values (0.4 and 0.1, correspondingly) as compared with those excited at blue wavelengths (1.7–2.4). This “Red Drop” was not observed for green sectors. Normal and chlorophyll-deficient leaf sectors of F. benjamina were also tested for linear and cyclic electron transport in thylakoids. The tests have been performed studying fluorescence at a steady-state phase with CO₂-excess impulse feeding, photoacoustic signal generated by pulse light source at wavelengths selectively exciting PSI, fluorescence kinetics under anaerobiosis and fluorescence changes observed by dual-wavelength excitation method. The data obtained for albino sectors strongly suggest the possibility of a cyclic electron transport simultaneously occurring in guard cell thylakoids around photosystems I and II under blue light, whereas linear electron transport is absent or insufficient.     

Genetics of dominant gibberellin-insensitive dwarfism in maize

D8 and Mpl1 are two dominant dwarfing mutations of maize. Although they differ in severity of dwarfism, both D8 and Mpl1 mutants are unresponsive to gibberellin (GA). Because of their close phenotypic resemblance to the recessive GA-sensitive dwarf mutants these dominant mutations may identify a gene whose product is involved in the reception of GA. With this possibility in mind we have studied the genetic properties of D8 and Mpl1. Both mutations map close to Adh1 on chromosome 1L. By marking normal and translocated 1L arms with different Adh1 electrophoretic mobility alleles, we investigated the effect of gene dosage on dominant dwarf phenotype. The results suggest that D8 and Mpl1 encode novel product functions and that these functions are relatively insensitive to the presence of the (presumed) wild-type product. Using X-ray induced chromosome breakage we created sectors of wild-type cells within D8 or Mpl1 tissue; these sectors were marked by the linked recessive lw mutation. The phenotypes of these sectors demonstrated that, at least in certain plant organs and tissues, dominant dwarfism can be an autonomous phenotype. These results are consistent with the hypothesis that the wild-type gene product acts as a GA receptor. The potential utility of dominant dwarf phenotype in plant developmental analysis is discussed, and possible mechanisms for the action of the D8 and Mpl1 mutations are considered.     

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.     

Mosaic analysis with oep mutant reveals a repressive interaction between floor-plate and non-floor-plate mutant cells in the zebrafish neural tube

The floor plate is located at the ventral midline of the neural tube in vertebrates. Floor-plate development is severely impaired in zebrafish one-eyed pinhead (oep) mutants. oep encodes a membrane-bound protein with an epiblast growth factor (EGF) motif and functions autonomously in floor-plate precursors. To understand the cell behavior and cell-cell interaction during floor-plate development, the distribution and gene expression of wild-type and oep mutant cells in genetic mosaics were examined. When mutant shield cells were transplanted into a wild-type host, an ectopic neural tube with a floor plate was induced. However, the floor plate of the secondary axis was consistently devoid of mutant cells while its notochord was composed entirely of mutant cells. This indicates that oep shield cells adopt only a notochord fate in a wild-type environment. In reciprocal transplants (wild to oep), however, grafted shield cells frequently contributed to part of the floor-plate region of the secondary neural tube and expressed floor-plate markers. Careful examination of serial sections revealed that a mutant neural cell, when located next to the wild-type cells at the ventral midline, inhibited floor-plate differentiation of the adjacent wild-type cells. This inhibition was effective over an area only one- or two-cells wide along the anteroposterior axis. As the cells located at the ventral midline of the oep neural tube are thought to possess a neural character, similar to those located on either side of the floor plate in a wild-type embryo, this inhibition may play an important role during normal development in restricting the floor-plate region into the ventral-most midline by antagonizing homeogenetic signals from the floor-plate cells.     

Transformation-defective polyoma middle T antigen mutants defective in PLCgamma, PI-3, or src kinase activation enhance ERK2 activation and promote retinoic acid-induced, cell differentiation like wild-type middle T

In HL-60 human myeloblastic leukemia cells, retinoic acid is known to cause cFMS, RAF, MEK, and ERK2 dependent myeloid cell differentiation and G0 arrest associated with RB tumor suppressor protein hypophosphorylation, implicating receptor tyrosine kinase signal transduction in propelling these retinoic acid-induced cellular effects. Furthermore, ectopic expression of polyoma middle T antigen, which activates similar early signal transduction molecules as PDGF class receptors such as cFMS, accelerates these retinoic acid-induced effects. To determine if this depends on middle T's ability to activate PLCgamma, PI-3 kinase, and src-like kinases, stable transfectants of HL-60 cells expressing either the polyoma middle T dl23 mutant, which is defective for PLCgamma and PI-3 kinase activation, or the Delta205 mutant, which in addition has greatly attenuated src-like kinase activation ability, were created and compared to wild-type middle T-transfected HL-60. The transgenes were under control of the retinoic acid (or 1, 25-dihydroxy vitamin D3) inducible Moloney murine leukemia virus LTRs. Expression of the dl23 or Delta205 mutant accelerated retinoic acid-induced cell differentiation. The effects of the mutants were comparable to those of the wild-type middle T. Likewise, retinoic acid-induced G0 arrest of mutant transfected cells and wild-type middle T transfected cells was similar. The same was true for 1, 25-dihydroxy vitamin D3-induced monocytic differentiation as for retinoic acid-induced myeloid differentiation. The mutants did not cause the same slight shortening of the cell cycle as wild-type middle T. Both the mutants and the wild-type middle T caused a similar increase in the cellular basal level of activated ERK2 MAPK. Since retinoic acid increases ERK2 activation, which is necessary for differentiation, the data suggest that mutant and wild-type middle T enhanced the retinoic acid effects by increasing basal levels of ERK2 activation. Consistent with this, the polyoma-induced foreshortening of the time for differentiation coincided with the time for retinoic acid to significantly increase ERK2 activation. As in wild-type HL-60, retinoic acid induced the early down-regulation of RXRalpha in mutant transfectants similar to wild-type middle T transfectants, consistent with no loss or gain of relevant functions due to the mutations. In contrast, vitamin D3 did not down-regulate RXRalpha in HL-60 or transfectants. Polyoma middle T and these transformation-defective mutants thus enhanced ERK2 activation to have an early effect in promoting retinoic acid-induced differentiation without a strong dependence on activating PLCgamma, PI-3 kinase, or src-like kinase.     

Analysis of the Autosomal Mutation abo and Its Interaction with the Ribosomal DNA of DROSOPHILA MELANOGASTER: The Role of X-Chromosome Heterochromatin

The autosomal recessive, maternal-effect mutation abnormal oocyte (abo: 2-38) preferentially lowers the viability os XO progeny. The severity of the sex-ratio distortion is reduced by duplications of maternal or zygotic heterochromatin (SANDLER 1970, 1977; PARRY and SANDLER 1974). Utilizing X-chromosome inversions that contain modifications in the quantity and arrangement of the heterochromatic functions, Xhabo and cr+, wer have extended our investigations of abo's influence on XO male recovery and rDNA redundancy (KRIDER, YEDVOBNICK and LEVINE 1979).--XO males bearing In(1)SCS1LSC4R or In(1)Wm4LSC4R are recovered twice as frequently as X chromosomes containing a single Xh region, implying that these inversions possess a duplication of Xhabo. abo mutant females heterozygous for In(1)SCS1LSC4R and wild-type X chromosomes generate XO progeny that do not contain elevated rDNA redundancies. XO males containing In(1)Wm4 exhibit male recoveries and rDNA elevations similar to those of males bearing a wild-type X chromosome, when both derive from a common abo/abo mother. Reciprocal crosses baetween In(1)Wm4 and Canton-S males to attached-X abo females show significant, though reuduced, sex ratios in the absence of an rDNA effect. The observation that abo can elevate the rDNA redundancy of In(1)Wm4, a chromosome that does not compensate, suggests that abo and cr+ functions are not directly related.     

tie-dyed1 Functions non-cell autonomously to control carbohydrate accumulation in maize leaves

The tie-dyed1 (tdy1) mutant of maize (Zea mays) produces chlorotic, anthocyanin-accumulating regions in leaves due to the hyperaccumulation of carbohydrates. Based on the nonclonal pattern, we propose that the accumulation of sucrose (Suc) or another sugar induces the tdy1 phenotype. The boundaries of regions expressing the tdy1 phenotype frequently occur at lateral veins. This suggests that lateral veins act to limit the expansion of tdy1 phenotypic regions by transporting Suc out of the tissue. Double mutant studies between tdy1 and chloroplast-impaired mutants demonstrate that functional chloroplasts are needed to generate the Suc that induces the tdy1 phenotype. However, we also found that albino cells can express the tdy1 phenotype and overaccumulate Suc imported from neighboring green tissues. To characterize the site and mode of action of Tdy1, we performed a clonal mosaic analysis. In the transverse dimension, we localized the function of Tdy1 to the innermost leaf layer. Additionally, we determined that if this layer lacks Tdy1, Suc can accumulate, move into adjacent genetically wild-type layers, and induce tdy1 phenotypic expression. In the lateral dimension, we observed that a tdy1 phenotypic region did not reach the mosaic sector boundary, suggesting that wild-type Tdy1 acts non-cell autonomously and exerts a short-range compensatory effect on neighboring mutant tissue. A model proposing that Tdy1 functions in the vasculature to sense high concentrations of sugar, up-regulate Suc transport into veins, and promote tissue differentiation and function is discussed.