|
Plant Physiol, December 2002, Vol. 130, pp. 1747-1753
Enhancer Trap Expression Patterns Provide a Novel Teaching
Resource1
Matt
Geisler,
Barbara
Jablonska, and
Patricia S.
Springer*
Department of Botany and Plant Sciences, Center for Plant Cell
Biology, University of California, Riverside, California
92521-0124
 |
ABSTRACT |
A collection of Arabidopsis enhancer trap transposants has been
identified for use as a teaching tool. This collection serves to assist
students in understanding the patterning and organization of plant
tissues and cells, and will be useful in plant anatomy, morphology, and
developmental biology courses. Each transposant exhibits reporter gene
expression in a specific tissue, cell type, or domain, and these lines
collectively offer a glimpse of compartments of gene expression. Some
compartments correspond to classical definitions of botanical anatomy
and can assist in anatomical identification. Other patterns of reporter
gene expression are more complex and do not necessarily correspond to
known anatomical features. The sensitivity of the  -glucuronidase
histochemical stain provides the student with a colorful and direct way
to visualize difficult aspects of plant development and anatomy, and
provides the teacher with an invaluable tool for a practical laboratory session.
| |
INTRODUCTION |
The model plant Arabidopsis
has many advantages that make it suitable for use in classical anatomy
and morphology courses. However, its small size may present a challenge
for the study of some aspects of plant anatomy, particularly for the
novice. Easily visible molecular markers that are expressed in a single cellular or subcellular compartment have been employed to characterize both normal patterns of development as well as for the analysis of
mutant phenotypes (Benfey et al., 1993 ; Malamy
and Benfey, 1997; Roe et al., 1997;
Topping and Lindsey, 1997; Tsukaya and Uchimiya,
1997; Berger et al., 1998; Sabatini et
al., 1999; Sessions et al., 1999). Such tools
usually exploit sensitive reporter genes such as
-glucuronidase (GUS) or Green
Fluorescent Protein, which are generally easy to use and not
prohibitively expensive. Expression patterns that mark cellular or
anatomical features would be a useful teaching aid, and can readily be
employed in a classroom setting to aid students in visualization of
anatomical compartments.
Gene and enhancer traps serve as a rich source of molecular markers,
and large collections of trap lines have been generated in Arabidopsis
(Bechtold et al., 1993; Topping et al.,
1994; Sundaresan et al., 1995; Campisi et
al., 1999; Springer, 2000). These trap lines
contain a reporter gene that has been inserted randomly into the
genome. When insertion occurs within or adjacent to a gene or enhancer
region, the reporter gene is expressed under the control of the native
promoter or enhancer elements. Thus, patterns of reporter gene
expression represent the expression of an endogenous chromosomal gene.
In the collections of enhancer and gene trap lines that have been
generated, many different reporter gene expression patterns have been
observed (Sundaresan et al., 1995; Campisi et
al., 1999; Springer, 2000). Although some
ubiquitous patterns that show expression in most or all plant cells and
tissues have been observed, more commonly expression is detected in a
limited number of cells or tissue systems. These more limited patterns
are often interesting and informative regarding compartments of gene
regulation. Although botanists have described anatomical and functional
compartments in plants, enhancer trap transposants have revealed
additional subdivisions that do not always correspond to those
previously described.
Here, 30 Arabidopsis enhancer trap transposants are described. These
lines were selected because they have GUS reporter gene expression patterns that are useful for teaching anatomy. These transposant lines will help students to identify cell types, tissues, tissue systems, and more complex patterns of gene regulation during development. Although molecular characterization of individual transposants will no doubt lead to the identification of important genes in plant development, at this stage they are useful as markers and provide a novel teaching resource.
| |
RESULTS AND DISCUSSION |
Leaf Markers
A number of transposant lines that exhibited cell type-specific
reporter gene expression patterns were identified (Tables I and
II). Arabidopsis trichomes,
single-celled epidermal hairs, are quite easy to identify, and as such
were one of the first cell types to be studied by mutant analysis
(Herman and Marks, 1989; Hülskamp et al.,
1994; Larkin et al., 1994). The precursor cells
that will give rise to mature trichomes, however, are difficult to
observe. Two enhancer trap lines were identified that will aide in
visualization of trichome development. GUS activity in transposant UCR1
was observed in all mature trichomes but was not detected in earlier
stages of trichome development (Fig. 1A). In contrast, GUS activity in transposant UCR2 was visible throughout all stages of trichome development, beginning with the unexpanded trichome precursor cells (Fig. 1B).
View this table:
[in this window]
[in a new window]
|
Table I.
Enhancer trap lines with GUS activity in the
Arabidopsis shoot
ABRC, Arabidopsis Biological Resource Center.
|
|
View this table:
[in this window]
[in a new window]
|
Table II.
Enhancer trap lines with GUS activity in the
Arabidopsis root
ABRC, Arabidopsis Biological Resource Center.
|
|
View larger version (124K):
[in this window]
[in a new window]
|
Figure 1.
Enhancer trap transposants with GUS activity in
the shoot. A, UCR1, GUS activity in mature trichomes. B, UCR2, GUS
activity in trichomes and trichome precursor cells (arrowhead). C,
UCR3, GUS activity in cotyledon guard cells. D, UCR4, GUS activity in
stipules. E, UCR5, GUS activity in cotyledon epidermis, image shows a
transverse hand-section. F, UCR6, GUS activity in palisade mesophyll of
cotyledon, image shows a transverse hand-section and a whole mount
(inset). G, UCR7, GUS activity in cotyledon vein. H, UCR8, GUS activity
in veins of cotyledon and hypocotyl. I, UCR9, GUS activity in
developing vascular tissue of leaf blade and petiole (arrowhead). J,
UCR10, Longitudinal hand section through shoot apex showing GUS
activity at base of leaf primordia. K, UCR11, GUS activity in rings of
cells at the base of leaf primordia. L, UCR12, GUS activity in
trichomes, petiole margins, and hypocotyl vasculature. M, UCR13, GUS
activity in cotyledon hydathodes, petiole, and upper hypocotyl. N,
UCR14, GUS activity in veins of hypocotyl and cotyledon petiole. O,
UCR15, GUS activity is excluded from leaf primordia. P, UCR16, GUS
activity in cotyledon and leaf blade. Scale bars = 100 µm.
|
|
A second epidermal cell type, the guard cell, may also be difficult for
the novice to identify. Transposant UCR3 showed GUS activity in mature
guard cells throughout the seedling, including those on cotyledons,
leaves, hypocotyls, and petioles (Fig. 1C). Weak GUS activity was also
occasionally detected in the vasculature in this transposant line.
Stipules, structures that form at each leaf base, are quite reduced in
Arabidopsis, consisting of 20 to 30 cells (Bowman, 1993). Because of their small size and proximity to the
meristem, they can be difficult to identify and may be confused with
initiating leaf primordia. GUS activity in transposant UCR4
specifically marked stipules (Fig. 1D) and was not detected in any
other location in the vegetative shoot.
Each of the three plant tissue systems (dermal, ground, and vascular)
was identified in the following group of enhancer trap lines.
Transposant UCR5 showed GUS activity throughout the entire cotyledon
epidermis, including guard and pavement cells (Fig. 1E). GUS activity
was not detected in ground or vascular tissues (Fig. 1E) or in young
developing leaves (data not shown). GUS expression was
confined to the mesophyll in transposant UCR6, with the most intense
expression detected in palisade cells in the cotyledon (Fig. 1F). In
transposant UCR7, GUS activity was detected in the vasculature. Upon
closer examination, staining appeared to be confined to a single axial
cell type (Fig. 1G). Cells staining for GUS activity were elongate and
adjacent to or within the xylem tissue but scattered throughout the
shoot vasculature and were likely differentiating vessel elements. In contrast, transposant UCR8 showed GUS expression localized
to the phloem in vasculature throughout the plant (Fig. 1H). This enhancer trap line is a useful tool for visualizing the different vascular patterns found in lateral organs, from the simple venation pattern in cotyledons to the increasingly branched, reticulate pattern
in leaves. Vein continuity between the leaf, hypocotyl, and roots can
also easily be seen.
GUS activity in transposants UCR9 and UCR10 marked the early
stages of vascular development. High levels of GUS activity were visible in differentiating veins of the leaf blade and petiole and in
the root tip (see below) in UCR9 (Fig. 1I). The mature veins of the
hypocotyl and cotyledon were unstained (data not shown). After
flowering, expression expanded to the floral buds and mature petals, in
addition to developing veins (Table I). In transposant UCR10, GUS
activity was detected in a triangular wedge of tissue at the base of
leaf primordia that appeared to mark the forming midvein (Fig. 1J),
although staining appeared before differentiation of vascular tissue.
The pattern was transient, so that only weak expression was detectable
in older primordia.
Root Markers
The size and regular organization of the Arabidopsis root make it
useful for studies of root anatomy (Scheres and Wolkenfelt, 1998). Five enhancer trap lines have been chosen that
individually identify each radial layer of the mature root (Fig.
2, A-E). The epidermis, including root
hairs and atrichoblast cell files, was marked by GUS activity in
transposant UCR17 (Fig. 2A). In contrast, GUS activity in transposant
UCR18 marked the root cortex, which consists of a single layer of
large, vacuolated cells (Fig. 2B). GUS activity in this line was not
completely restricted to the cortex, however, and faint staining was
occasionally also detected in the epidermis. GUS activity was detected
exclusively in the root endodermal layer in transposant UCR19 (Fig.
2C). Strong GUS expression was also observed in the
stigmatic papillae and placenta of the pistil and in pollen tubes in
UCR 19 (Table II).
View larger version (122K):
[in this window]
[in a new window]
|
Figure 2.
Enhancer trap transposants with GUS activity
in the root. A, UCR17, GUS activity in epidermis. B, UCR18, GUS
activity in cortex. C, UCR19, GUS activity in endodermis. D, UCR8, GUS
activity in phloem and pericycle. Arrow points to a lateral root (lr).
E, UCR20, GUS activity in developing xylem. F, UCR21, GUS activity in
outer layers of vascular cylinder and vascular initial cells in the
RAM. G, UCR9, GUS activity in central layers of the vascular cylinder,
originating in the vascular initials. H, UCR22, GUS activity in the
zones of elongation and differentiation, localized to the epidermis and
cortex. I and J, UCR23, GUS activity in trichoblast cell files in the
elongation (I) and differentiation (J) zones. K, UCR24, GUS activity in
the root cap. L through N, GUS activity in the bottom two tiers (L,
UCR25), middle tier (M, UCR26), and initials (N, UCR27) of the
columella root cap. O, UCR28, GUS activity in the lateral root cap. P
and Q, Developmental series of lateral root initiation. P, UCR29, GUS
activity in the first few cells of dividing pericycle (P1). GUS
activity was visible throughout the lateral root primordia (P2-P5),
was progressively restricted to the root tip (P6), and was not detected
in mature roots (P7). Q, UCR30, GUS activity was not detected in early
stage primordia (Q1) but was visible before the lateral root primordia
emerged from the primary root (Q2). GUS activity was restricted to the
organizing RAM (Q3-Q4) and disappeared at later stages (Q5-Q6).
Images were captured using differential interference contrast
microscopy of root whole mounts. Scale bars = 50 µm. Scale bar
in Q1 refers to Q1 through Q6.
|
|
Many enhancer trap lines that mark different compartments within
the vascular cylinder in the root were identified, and two were chosen
for inclusion in this collection. GUS activity in transposant UCR8 was
detected in all vascular tissues of the plant. In the root, staining
was localized to the outer layers of the vascular cylinder,
corresponding to the pericycle and phloem (Fig. 2D). GUS activity in
transposant UCR20 marked xylem parenchyma and differentiating xylem and
was detected in the center of the vascular cylinder in the mature root
(Fig. 2E). GUS activity was not detected in the root tip in either
transposant line (data not shown). In transposant UCR20, high levels of
GUS expression were also observed in inflorescence stem
nodes, perhaps corresponding to the formation of new vasculature during
bud emergence (Table II). Transposant UCR21 displayed GUS activity in
the outer layers of both developing and mature vascular tissue (Fig.
2F), whereas in transposant UCR9, GUS activity was detected in the
inner layers of developing vasculature (Fig. 2G) but was not detected
in mature tissues (data not shown). GUS expression in both
lines was detectable in root vascular precursor cells, including the
initial cells of the root apical meristem (RAM) and the cell files
derived from them. They therefore serve to illustrate the origin of
vasculature in the root. Low levels of GUS activity were also visible
in the lateral root cap in transposant UCR9 (Fig. 2G).
In addition to radial patterning, roots show distinct organization
along the apical-basal axis. Elements along this axis begin at the root
tip with the root cap and the RAM. The elongation zone, which exhibits
a high rate of cell division and differentially elongates during
gravitropism (Mullen et al., 1998), is behind the tip.
The zone of differentiation or specialization is further back from the
tip, and is marked by the emergence of root hairs. A number of enhancer
trap lines were identified that showed distinct patterns of
GUS expression along this apical-basal axis. GUS activity in
transposant UCR22 was detected in cortical and epidermal cells in a
region of the elongation zone near the zone of differentiation (Fig.
2H). Transposant UCR23 also showed GUS activity in the epidermis of
this region, however, only alternating cell files were stained (Fig.
2I). Examination of the epidermis also revealed weak staining in
differentiating root hair cells (Fig. 2J), indicating that GUS activity
in UCR23 marked trichoblast cells. This line nicely illustrates the
concept of root hair patterning, which has been the subject of intense
research (Masucci et al., 1996; Dolan and Costa,
2001; Lin and Schiefelbein, 2001).
The root cap was marked by GUS activity in transposant UCR24
(Fig. 2K). Three lines showed root cap staining that was further restricted to the bottom two tiers of cells (UCR25; Fig. 2L), a middle
tier (UCR26; Fig. 2M), and the columella initials (UCR27; Fig. 2N).
Finally, GUS activity was restricted to the lateral root cap in
transposant UCR28 (Fig. 2O). This transposant series demonstrates the
compartmentalization of the root cap, something that is not apparent
from histological analyses but has been experimentally demonstrated.
For example, the lateral root cap and columella have distinct embryonic
origins and may also serve distinct functions (Esau,
1965; Bowman, 1993; Dolan et al.,
1994; Baum and Rost, 1996). The cells in the
center of the columella have been shown to house the receptor for
gravity sensing (Tanaka et al., 2002). The cells at the
periphery of the root cap are continuously sloughed off and replaced,
and in some plants, these cells secrete mucilage that serves to protect
the root from microbial pathogens (Hawes et al., 1998)
and may help to lubricate the root tip as it pushes through the soil
(Esau, 1965).
Enhancer trap lines were isolated with GUS activity that was temporally
regulated during lateral root development. Lateral root primordia form
in the pericycle, and weak GUS activity in transposant UCR29 was
detected in the pericycle during the earliest stages of lateral root
primordium formation (Fig. 2, P1). The intensity of GUS staining
increased as the primordium developed, becoming very strong during
later stages, marking the entire primordium (Fig. 2, P2-P5). In older
lateral roots, GUS activity diminished but was retained in the root cap
(Fig. 2, P6). In mature roots, GUS activity was no longer detectable
(Fig. 2, P7). In a second transposant line, UCR30, GUS activity was
first detectable at a later stage of lateral root development,
beginning in the apical regions of pre-emergent lateral root primordia
(Fig. 2, Q1-Q2). As the primordium emerged, GUS staining became
restricted to the root tip and was most intense at the site of the
developing RAM (Fig. 2, Q3-Q4). GUS staining faded quickly,
disappearing in early lateral roots (Fig. 2, Q5-Q6). The transient
nature of GUS expression in both of these enhancer trap
lines demonstrates that lateral root formation is an extremely dynamic process.
Complex Patterns of Gene Regulation
In addition to providing visual anatomical markers, enhancer
trap lines that demonstrate more complex patterns of gene expression were also chosen for inclusion in this collection. These patterns may
serve to make connections between seemingly unrelated tissues or cell
types and may not always coincide with known morphological features.
For example, transposant UCR2 showed GUS activity in trichomes (Fig.
1B) and in root hairs (Table I), suggesting that trichomes and root
hairs share a common feature. Both cell types undergo tip growth, and
in addition, mutational analyses have demonstrated the use of common
regulatory genes that function as cell fate determinants during the
development of both trichomes and trichoblast cells (for review, see
Dolan and Scheres, 1998).
A number of enhancer trap lines were identified that showed
GUS expression in an intriguing pattern at the base of all
lateral organs. Molecular characterization of one such line identified the LATERAL ORGAN BOUNDARIES gene, the founding member of a
large family of novel genes (Shuai et al., 2002). An
example of such an expression pattern is represented by transposant
UCR11. GUS activity in UCR11 was detected in a single ring of epidermal
cells at the base of each leaf primordium (Fig. 1K) and at the base of
all lateral organs in the inflorescence (Table I). GUS activity was
detected at the base of young primordia and persisted in mature leaves.
In transposant UCR27, GUS activity, which marked the columella initials
(Fig. 2N), was also observed in a ring of cells encircling leaf bases
(Table II).
In transposant UCR12, GUS activity was detected in trichomes and in the
marginal cells of leaf petioles (Fig. 1L). The marginal staining was
strong at the leaf base, and disappeared completely near the blade. GUS
activity in UCR12 was also present in the hypocotyl, stipules, anthers,
and root vasculature (Fig. 1L; Table I). No staining was detected in
the veins of leaves or cotyledons, however. The significance of this
staining pattern is currently unknown, and it has been provided as a
representative of the many complex expression patterns detected by
enhancer traps.
Seedlings of transposant UCR13 displayed GUS activity in the cotyledon
petioles and hydathodes, but staining was otherwise excluded from the
cotyledon blade (Fig. 1M). GUS activity was also detected in the upper
hypocotyl, but was not detected in leaf primordia. After flowering, GUS
activity was detected in the inflorescence stem and the carpels of the
flower but was excluded from other floral organs. In transposant UCR14,
the veins in the hypocotyl and petiole were marked by GUS activity, but
other veins were unstained (Fig. 1N). Veins in the inflorescence stem,
flower pedicel, style, and silique valve were also marked by GUS
activity (Table I).
In transposant UCR15, GUS activity marked the cotyledons, hypocotyl,
and the majority of the root, including the root cap (Fig. 1O; Table
I). GUS activity was excluded from leaf primordia (Fig. 1O), RAM, and
elongation zone (data not shown). This expression pattern appeared to
correspond to regions that did not contain rapidly dividing cells.
After flowering however, strong GUS activity in UCR15 was observed in
most tissues of the inflorescence, including young flower buds (Table
I), indicating that GUS expression isn't simply excluded
from rapidly dividing cells. Transposant UCR16 was selected for its
prominent staining of leaf primordia. GUS activity was detected only in
the blade regions of leaf primordia (Fig. 1P). Staining
faded slightly in older expanding leaves, and remained detectable in
mature leaves and cotyledons. GUS activity was also detected in
developing, but not mature anthers, suggesting a transient role in
anther development (Table I). Weak GUS activity was also detected in
the cortical cells of the collet, the interface of root and hypocotyl
(Table I).
| |
MATERIALS AND METHODS |
Transposant Lines
A collection of enhancer and gene trap lines was generated
using previously described methods (Sundaresan et al.,
1995). All transposants have been made publicly available
through the Arabidopsis Biological Resource Center (Ohio State
University, Columbus; http://www.Arabidopsis.org/abrc).
Plant Growth
For growth on sterile media, seed was surface sterilized by
treating with 95% ethanol for 5 min, followed by treatment with a
solution of 20% household bleach (1% sodium hypochlorite) and 0.1%
Tween 20 for 5 min, followed by three rinses in sterile water. The
sterilized seed was transferred to germination medium containing 0.43%
Murashige and Skoog salts (Invitrogen, Carlsbad, CA), 1% Suc, and
0.8% agar, adjusted to pH 5.7 with 1.0 N KOH. Plants were
grown to maturity in Sunshine Mix no. 2 (Sun Gro Horticulture, Alberta,
Canada) supplemented with 14-14-14 Osmocote (Scotts, Marysville, OH) at
a rate of 75 g per cubic foot and Marathon systemic insecticide
(Olympic Horticulture, Mainland, PA) at a rate of 25 g per cubic
foot. Imbibed seeds were cold-treated at 4°C for 4 d and then
transferred to a growth chamber at 22°C with a light intensity of 200 microeinsteins m 2 s1, and a 16-h light/8-h
dark cycle.
Histochemical Localization of GUS Activity
Tissue was stained for GUS activity in staining solution
containing 100 mM sodium phosphate, pH 7.0, 10 mM EDTA, 0.1% Triton X-100, 1 mg mL1
5-bromo-4-chloro-3-inolyl--D-GlcUA, cyclohexylammonium
salt (X-Gluc, Biosynth International, Naperville, IL), 100 µg
mL1 chloramphenicol, 2 mM potassium
ferricyanide, and 2 mM potassium ferrocyanide as previously
described (Sundaresan et al., 1995). In brief, tissue
was harvested directly into a volume of staining solution sufficient to
cover the tissue and placed under house vacuum for 10 min. Staining was
carried out at 37°C in the dark for 48 h. After staining, the
tissue was incubated in 70% ethanol to remove the chlorophyll. The
ethanol was changed several times until the tissue was clear. Stained
tissues were examined using a stereomicroscope or mounted on a glass
slide under a cover glass in 50% glycerol, and monitored using
differential interference contrast optics on a Leica DMR compound
microscope. Images were captured using a Spot digital camera
(Diagnostic Instruments, Sterling Heights, MI). Tissues and cell types
were identified based on comparison with published reports
(Esau, 1965; Sachs, 1991; Bowman,
1993; Meyerowitz and Somerville, 1994).
| |
ACKNOWLEDGMENTS |
We thank Airica Baxter-Burrell, David Holding, Nanor Markarian,
Marcela Rojas-Pierce, and Sonia Zarate for generation of transposants, and Darleen Demason and Linda Walling for comments on the manuscript.
| |
FOOTNOTES |
Received July 11, 2002; returned for revision July 31, 2002; accepted September 20, 2002.
1
This work was supported by the National Science
Foundation (grant no. IBN-9875371 to P.S.S.) and by the Southwest
Consortium (grant no. 99-N02 to P.S.S.).
*
Corresponding author; e-mail patricia.springer{at}ucr.edu; fax
909-787-4437.
www.plantphysiol.org/cgi/doi/10.1104/pp.011197.
| |
LITERATURE CITED |
-
Baum SF, Rost TL
(1996)
Root apical organization in Arabidopsis thaliana: 1. Root cap and protoderm.
Protoplasma
192: 178-188[CrossRef][ISI]
-
Bechtold N, Ellis J, Pelletier G
(1993)
In planta Agrobacterium-mediated gene transfer by infiltration of adult Arabidopsis thaliana plants.
C R Acad Sci Paris Life Sci
316: 1194-1199
-
Benfey PN, Linstead PJ, Roberts K, Schiefelbein JW, Hauser M-T, Aeschbacher RA
(1993)
Root development in Arabidopsis: four mutants with dramatically altered root morphogenesis.
Development
119: 57-70[Abstract]
-
Berger F, Linstead P, Dolan L, Haseloff J
(1998)
Stomata patterning on the hypocotyl of Arabidopsis thaliana is controlled by genes involved in the control of root epidermis patterning.
Dev Biol
194: 226-234[CrossRef][ISI][Medline]
-
Bowman J
(1993)
Arabidopsis: An Atlas of Morphology and Development. Springer, New York
-
Campisi L, Yang Y, Yi Y, Heilig E, Herman B, Cassista AJ, Allen DW, Xiang H, Jack T
(1999)
Generation of enhancer trap lines in Arabidopsis and characterization of expression patterns in the inflorescence.
Plant J
17: 699-707[CrossRef][ISI][Medline]
-
Dolan L, Costa S
(2001)
Evolution and genetics of root hair stripes in the root epidermis.
J Exp Bot
52: 413-417[Abstract/Free Full Text]
-
Dolan L, Duckett CM, Grierson C, Linstead P, Schneider K, Lawson E, Dean C, Poethig S, Roberts K
(1994)
Clonal relationships and cell patterning in the root epidermis of Arabidopsis.
Development
120: 2465-2474[Abstract/Free Full Text]
-
Dolan L, Scheres B
(1998)
Root pattern: shooting in the dark?
Semin Cell Dev Biol
9: 201-206[Medline]
-
Esau K
(1965)
Plant Anatomy, Ed 2. Wiley, New York
-
Hawes MC, Brigham LA, Wen F, Woo HH, Zhu Y
(1998)
Function of root border cells in plant health: pioneers in the rhizosphere.
Annu Rev Phytopathol
36: 311-327[CrossRef][ISI][Medline]
-
Herman PL, Marks MD
(1989)
Trichome development in Arabidopsis thaliana: II. Isolation and complementation of the GLABROUS1 gene.
Plant Cell
1: 1051-1055[Abstract/Free Full Text]
-
Hülskamp M, Miséra S, Jürgens G
(1994)
Genetic dissection of trichome cell development in Arabidopsis.
Cell
76: 555-566[CrossRef][ISI][Medline]
-
Larkin JC, Oppenheimer DG, Lloyd AM, Paparozzi ET, Marks MD
(1994)
Roles of the GLABROUS1 and TRANSPARENT TESTA GLABRA genes in Arabidopsis trichome development.
Plant Cell
6: 1065-1076[Abstract]
-
Lin Y, Schiefelbein J
(2001)
Embryonic control of epidermal cell patterning in the root and hypocotyl of Arabidopsis.
Development
128: 3697-3705[Abstract/Free Full Text]
-
Malamy JE, Benfey PN
(1997)
Organization and cell differentiation in lateral roots of Arabidopsis thaliana.
Development
124: 33-44[Abstract]
-
Masucci JD, Rerie WG, Foreman DR, Zheng M, Galway ME, Marks MD, Schiefelbein JW
(1996)
The homeobox gene GLABRA2 is required for position-dependent cell differentiation in the root epidermis of Arabidopsis thaliana.
Development
122: 1253-1260[Abstract]
-
Meyerowitz EM, Somerville CR
(1994)
Arabidopsis. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY
-
Mullen JL, Ishikawa H, Evans ML
(1998)
Analysis of changes in relative elemental growth rate patterns in the elongation zone of Arabidopsis roots upon gravistimulation.
Planta
206: 598-603[CrossRef][ISI][Medline]
-
Roe JL, Nemhauser JL, Zambryski PC
(1997)
TOUSLED participates in apical tissue formation during gynoecium development in Arabidopsis.
Plant Cell
9: 335-353[Abstract]
-
Sabatini S, Beis D, Wolkenfelt H, Murfett J, Guilfoyle T, Malamy J, Benfey P, Leyser O, Bechtold N, Weisbeek P, et al
(1999)
An auxin-dependent distal organizer of pattern and polarity in the Arabidopsis root.
Cell
99: 463-472[CrossRef][ISI][Medline]
-
Sachs T
(1991)
Pattern formation in plant tissues. Cambridge University Press, Cambridge, UK
-
Scheres B, Wolkenfelt H
(1998)
The Arabidopsis root as a model to study plant development.
Plant Physiol Biochem
36: 21-32
-
Sessions A, Weigel D, Yanofsky MF
(1999)
The Arabidopsis thaliana MERISTEM LAYER 1 promoter specifies epidermal expression in meristems and young primordia.
Plant J
20: 259-263[CrossRef][ISI][Medline]
-
Shuai B, Reynaga-Peña CG, Springer PS
(2002)
The LATERAL ORGAN BOUNDARIES gene defines a novel, plant-specific gene family.
Plant Physiol
129: 747-761[Abstract/Free Full Text]
-
Springer PS
(2000)
Gene traps: tools for plant development and genomics.
Plant Cell
12: 1007-1020[Abstract/Free Full Text]
-
Sundaresan V, Springer P, Volpe T, Haward S, Jones JDG, Dean C, Ma H, Martienssen R
(1995)
Patterns of gene action in plant development revealed by enhancer trap and gene trap transposable elements.
Genes Dev
9: 1797-1810[Abstract/Free Full Text]
-
Tanaka A, Kobayashi Y, Hase Y, Watanabe H
(2002)
Positional effect of cell inactivation on root gravitropism using heavy-ion microbeams.
J Exp Bot
53: 683-687[Abstract/Free Full Text]
-
Topping JF, Agyeman F, Henricot B, Lindsey K
(1994)
Identification of molecular markers of embryogenesis in Arabidopsis thaliana by promoter trapping.
Plant J
5: 895-903[CrossRef][ISI][Medline]
-
Topping JF, Lindsey K
(1997)
Promoter trap markers differentiate structural and positional components of polar development in Arabidopsis.
Plant Cell
9: 1713-1725[Abstract]
-
Tsukaya H, Uchimiya H
(1997)
Genetic analyses of the formation of the serrated margin of leaf blades in Arabidopsis: combination of a mutational analysis of leaf morphogenesis with the characterization of a specific marker gene expressed in hydathodes and stipules.
Mol Gen Genet
256: 231-238[CrossRef][ISI][Medline]
© 2002 American Society of Plant Biologists
This article has been cited by other articles:
|
|
|
|
 
L. I. A. Calderon-Villalobos, C. Kuhnle, H. Li, M. Rosso, B. Weisshaar, and C. Schwechheimer
LucTrap Vectors Are Tools to Generate Luciferase Fusions for the Quantification of Transcript and Protein Abundance in Vivo.
Plant Physiology,
May 1, 2006;
141(1):
3 - 14.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. M. Buzas, D. Lohar, S. Sato, Y. Nakamura, S. Tabata, C. E. Vickers, J. Stiller, and P. M. Gresshoff
Promoter trapping in Lotus japonicus reveals novel root and nodule GUS expression domains
Plant Cell Physiol.,
August 1, 2005;
46(8):
1202 - 1212.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. Scarpella, P. Francis, and T. Berleth
Stage-specific markers define early steps of procambium development in Arabidopsis leaves and correlate termination of vein formation with mesophyll differentiation
Development,
July 15, 2004;
131(14):
3445 - 3455.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
TOP
ABSTRACT
INTRODUCTION