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First published online November 7, 2008
doi: 10.1242/10.1242/dev.027383
Meeting Review |
Max Planck Institute for Plant Breeding, Carl von Linne Weg 10, Cologne, Germany
e-mail: coupland{at}mpiz-koeln.mpg.de
SUMMARY
The biannual FASEB summer research conference `Mechanisms in Plant Development' was recently held in Saxtons River, Vermont and was organised by Neelima Sinha and Cris Kuhlemeier. Although most of the work discussed at the meeting concentrated on developmental mechanisms and on studies in Arabidopsis and maize, the meeting also emphasised the importance of variation between species and the elaboration of a broader range of model systems.
Introduction
The FASEB meeting `Mechanisms in Plant Development' covered a broad range of themes, from developmental topics, such as meristems and organogenesis, gametophytic development, signalling, small RNAs and mathematical modelling, to the field of variation and evolution, which was discussed in sessions on natural variation, seed-free plants and the evolution of development. This review highlights several of the emerging issues covered in the meeting.
Leaf development: roles for small RNAs and auxin
The development of leaves and the topic of how their morphology changes as
the shoot grows were addressed by several speakers. The plant shoot exhibits
indeterminate growth, and continuously gives rise to new organs from its
growing tip, called the shoot apical meristem (SAM). As leaf primordia grow
away from the shoot meristem, the upper side closest to the SAM takes on an
adaxial identity, whereas the other side acquires abaxial identity
(Fig. 1). Extensive genetic
studies in maize and Arabidopsis have provided a regulatory framework
for understanding how these abaxial and adaxial identities are conferred
(Chitwood et al., 2007
). The
exploitation of both species has made the system more accessible, because some
pathways have more prominent roles in one species than in the other. Marja
Timmermans (Cold Spring Harbor, New York, USA) described the complex interplay
that occurs between transcription factors and small RNAs in establishing
adaxial and abaxial leaf identity. She explained that adaxial identity
involves class III homeodomain leucine zipper (HD-ZIPIII) transcription
factors, the mRNAs of which become restricted to the adaxial side of the leaf
primordium as it emerges. By contrast, abaxial identity involves
Arabidopsis genes that encode three KANADI (KAN) proteins and three
YABBY proteins. The KAN proteins, as well as two AUXIN RESPONSE FACTORS (ARF3
and ARF4), activate the expression of the YABBY genes in the abaxial
region. The HD-ZIPIII proteins repress KAN gene expression in the
adaxial region, while the KAN proteins repress the HD-ZIP genes in the abaxial
region. In parallel to this transcription factor system, small RNAs act to
confer both adaxial and abaxial identity. MicroRNA166 (miR166) acts
in abaxial tissues and inhibits the expression of HD-ZIP proteins in both
maize and Arabidopsis, while trans-acting short interfering RNAs that
target ARF3 and ARF4 (tasiR-ARFs) and that reduce the domain of
expression of the miR166 precursor confer adaxial fate and have a
more prominent role in maize (Chitwood et
al., 2007; Nogueira et al.,
2007). The distinct activities of the two small regulatory RNAs
suggest that tasiR-ARF and miR166 oppose each other in
creating the boundary between adaxial and abaxial regions, respectively. An
issue discussed at the meeting was the extent to which the movement of small
RNAs contributes to the position of the boundary between the abaxial and
adaxial regions. This issue was addressed for two small RNAs:
tasiR-ARF and miR390, a miRNA required for
tasiR-ARF biogenesis (Allen et
al., 2005). The Timmerman's group showed that a graded abundance
of tasiR-ARF is created by the localised activity of miR390
on the adaxial side of the developing leaf primordia, with the low abundant
tasiR-ARF moving abaxially into deeper layers. The extent of movement
of this microRNA would contribute to the position of the boundary between the
adaxial and abaxial regions.
The juxtaposition of adaxial and abaxial identities is also required for
the extension of the leaf in the laminar plane to produce the typical flat
structure of a leaf (Waites and Hudson,
1995). Sarah Hake (Plant Gene Expression Center, Albany, CA, USA)
interpreted the phenotype of the milkweed pod1 (mwp1) mutant
of maize in the context of these processes
(Candela et al., 2008). The
leaves of mwp1 mutants show normal abaxial and adaxial identities,
but sectors that exhibit characteristics of adaxial tissues arise on the
abaxial side. Outgrowths occur at the junctions between these sectors and the
surrounding abaxial tissues, in agreement with other indications that the
juxtaposition of these two tissue types promotes growth. The MWP1
gene is expressed in the abaxial domain of the leaf and encodes a KAN protein,
consistent with the data from Arabidopsis indicating a role for KAN
proteins in conferring abaxial identity. Furthermore, the rolled
leaf1 (rld1) gene encodes an HD-ZIPIII protein homologous to
those that confer adaxial fate in Arabidopsis, and rld1-N
mutants contain a mutation in the miR166 binding site of
rld1 mRNA (Juarez et al.,
2004). In rld-N mutants, MWP1 expression is
reduced in abaxial tissues. As Hake discussed, the mwp1 mutant also
shows an interesting phenotype in the prophyll, a specialised leaf produced by
the axillary meristem that gives rise to the ear of maize. The prophyll grows
around the ear and is keeled, such that two laminae extend from the abaxial
surface of the prophyll to wrap around the stem. In the mwp1 mutant,
the keel is not formed, suggesting a role for abaxial identity in producing
the keel. Prophylls develop from two separate leaf primordia that fuse at the
margins, leading to the proposal that keels may be outgrowths stimulated by
the juxtaposition of abaxial and adaxial tissues, which are not formed in
mwp1 mutants because of impaired abaxial identity. This would then be
an example of boundaries between abaxial and adaxial tissues being used to
stimulate growth in a different context from that of promoting laminar growth
in typical leaves. Chuck Gasser (UC Davis, CA, USA) described that, in another
context, the outgrowth of the integument in the developing ovule, the boundary
between layers specified by the HD-ZIPIII, KAN and YABBY proteins, is also
required to promote growth, indicating that this system has been co-opted in
different contexts during plant evolution.
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;
Hay and Tsiantis, 2006).
Arabidopsis forms simple leaves in which the leaf blade is undivided,
whereas C. hirsuta produces dissected leaves in which the blade is
divided into leaflets (Fig. 2).
In both species, the leaves develop from similar primordia produced on the
flanks of the SAM. However, the morphology of the developing leaves diverges
when two subsequent leaf primordia have been formed by the SAM. The Tsiantis
group could show that only a small number of cells at the leaf margin give
rise to the leaflet in dissected leaves. In simple leaves, by contrast, the
leaf margin plays only a minor role in leaf growth. To identify genes required
for leaflet formation, the group has conducted a screen for C.
hirsuta mutants that produce simple leaves, which identified a mutation
in the auxin efflux carrier PIN FORMED 1 (PIN1), indicating a role for auxin
transport in leaflet formation. A PIN1-GFP fusion protein localises in the
developing leaflet, and the polarity of its accumulation suggests that auxin
accumulates at the tip of the developing leaflet. KNOTTED1-LIKE HOMEOBOX
(KNOX) proteins also promote leaflet initiation in C. hirsuta
(Barkoulas et al., 2008), and
from further findings Tsiantis and co-workers conclude that PIN1 acts
downstream of the KNOX genes, leading them to a model in which KNOX genes act
to maintain cells at the margins of C. hirsuta leaves in an
undifferentiated state, allowing these cells to respond to auxin accumulation
generated by PIN1. These auxin maxima would then stimulate leaflet outgrowth.
Different varieties of C. hirsuta show alterations in the number of
leaflets formed; an issue now being addressed is whether these
variety-specific differences are caused by allelic variation at the same
PIN1 and KNOX gene loci responsible for the species-specific
differences between A. thaliana and C. hirsuta.
Leaf development can also vary within a single plant as the shoot
progresses through different phases of growth. George Chuck (Plant Gene
Expression Center, Albany, California, USA) and Scott Poethig (University of
Pennsylvania, Philadelphia, PA, USA) described the mechanisms that control the
progression of the shoot from juvenile to adult phases, and its striking
conservation between maize and Arabidopsis. In the maize shoot,
development is divided into juvenile, adult and reproductive phases, and the
leaves formed during these phases differ in, for example, their overall shape,
the organs formed from the meristems present in the axils of leaves, and their
cell morphology and wax deposition. Mutations have long been known that alter
the duration of these phases (Poethig,
1988a). George Chuck described the basis of one of the most
intriguing of these mutations, corngrass1 (cg1)
(Chuck et al., 2007). The
cg1 mutation in maize greatly extends the juvenile phase, so that
several juvenile characteristics are observed in leaves throughout the shoot,
such as a slender morphology, production of epidermal wax and tillers (stems
produced from axillary meristems). Furthermore, the nodes on the stem at which
the leaves arise continuously produce prop roots, a characteristic of the stem
normally found during juvenile development. The cg1 mutant also shows
altered development of the inflorescence, and specialised leaves (bracts) that
are present in the ear and tassel are much larger than those of wild-type
maize. As Chuck and colleagues have previously reported
(Chuck et al., 2007), the
cg1 locus comprises a tandem arrangement of two genes that encode two
microRNAs, zma-miR156b and zma-miR156c. In cg1
mutants, zma-miR156 is continually expressed at elevated levels,
whereas in wild-type plants it is highly expressed only during the juvenile
phase and is not expressed in the adult phase. These results indicate that
zma-miR156 has a major role in conferring juvenile characteristics.
zma-miR156 targets mRNAs of the SQUAMOSA PROMOTER BINDING LIKE (SPL)
class of transcription factors, seven of which are reduced in the cg1
mutant. One such target is tassel sheath4 (tsh4);
tsh4 mutants show much larger inflorescence bracts than in wild-type
plants, as is also observed in cg1 mutants, suggesting that this
aspect of the cg1 mutant can be explained by increased
zma-mir156 levels causing the downregulation of tsh4. The
timing of the transition from juvenile to adult phase possibly involves an
interplay between zma-mir156 and a second class of microRNA:
miR172 (Chuck et al.,
2007). As Chuck discussed, miR172 targets mRNAs of the
APETALA2 (AP2)-LIKE transcription factor class, such as GLOSSY15 (GL15), a
transcription factor required in maize for wax formation on juvenile leaves.
During the phase change from juvenile to adult, zma-miR156 levels
fall, while miR172 levels rise, and in cg1 mutants (in which
zma-mir156 levels are higher for longer during shoot development),
miR172 levels are strongly downregulated. This leads to ectopic GL15
expression in cg1 shoots (Evans et
al., 1994; Moose and Sisco,
1996). Although the mechanism by which miR156 controls
the expression of miR172 is unclear, these findings suggest that
these two miRNAs interact to control the timing of the transition between
juvenile and adult development. Scott Poethig described how his work on phase
change led independently to the identification of miR156 and
miR172 as determinants of juvenile and adult development in
Arabidopsis (Willmann and
Poethig, 2007; Wu and Poethig,
2006), and how this enabled him to return to his pioneering work
on cg1 and related mutants
(Poethig, 1988a;
Poethig, 1988b). In addition,
he showed the function of specific SPL and AP2-like genes in
controlling adult and juvenile traits, respectively. Furthermore, he pointed
out that in maize, mutations in teopod genes (which are similar to
cg1 and also cause elevated levels of mir156) are non-cell
autonomous because sectors of tissue that do not contain the mutation express
the mutant phenotype because of the presence of the mutation in neighbouring
tissues (Poethig, 1988b). The
basis of this non-cell autonomous signal and the role of mir156 in
the signalling mechanism remain unclear.
Technological advances
Venugopala Reddy (University of California, Riverside, CA, USA) and Ueli
Grossniklaus (University of Zürich, Zürich, Switzerland) presented
their technological approaches to identifying patterns of gene expression in
specialised tissues, such as the shoot apical meristem (Reddy) and the female
gametophyte (Grossniklaus). The SAM is maintained partly by the activity of
the CLAVATA3 (CLV3) and WUSCHEL (WUS) proteins
(Laux, 2003). Although these
proteins act in different cells of the meristem, a feedback loop exists
between their activities, such that WUS (a homeobox transcription factor that
promotes cell divisions in the organising centre of the meristem) promotes
CLV3 expression, maintaining the presence of stem cells, whereas CLV3
(a small peptide that is expressed in apical cells located above the
organising centre) represses WUS. These interactions maintain a
homeostasis in cell number within the different regions of the meristem. Reddy
presented his cell-sorting strategy to identify further genes that act within
this system. Transgenic plants that express pCLV3:mGFP-ER,
pWUS:RFP-ER and pFIL::dsRED-N7 were created. The GFP and RFP
fluorescent markers were then used to sort the cells that comprise the
CLV3 or WUS expression domains in a mutant plant that
produces many floral meristems, thus providing access to a much larger number
of cells of the required types than would otherwise be possible. The resulting
gene expression profiling experiments showed that over 400 genes are
apparently specific to the SAM. Moreover, the expression of over 700 genes was
detected, the expression patterns of which had not previously been described.
This appears to be a promising way of identifying genes that act specifically
in these cell types and that have not so far been identified by genetics or
other genomics approaches. A related technical problem was experienced by Ueli
Grossniklaus, who was interested in identifying genes expressed in specific
cell types in the female gametophyte. He described using laser capture
microscopy to isolate individual cell types, including the egg cell, which has
a diameter of only 7-8 µm. Depending on the cell type, amplifications were
performed with RNA extracted from 250-800 cells and carried out in triplicate.
In this way, Grossniklaus and his co-workers could compare the transcriptome
of the central cell, egg cell and synergid, and they found that between 5000
and 7000 genes were expressed in a given cell type, with about 200 genes being
specific to each cell type. Such genomics-based approaches will form the basis
of future reverse genetics analyses to identify genes that contribute to the
identity of each of these cell types.
Patterning the female gametophyte
The mechanisms conferring cell identity to the female gametophyte were also
discussed by Venkatesan Sundaresan (UC Davis, California, USA). The female
gametophyte is produced from a haploid megaspore, which goes through three
rounds of mitosis to form a syncytium that contains eight nuclei
(Brukhin et al., 2005). This
syncytium then undergoes cellularisation to form seven cells of four different
cell types: an egg cell, two synergid cells, a bi-nucleate central cell and
three antipodal cells. One of the problems studied by Venkatesan Sundaresan is
how different cell identities are conferred during cellularisation. He
proposed that a signalling gradient might provide the information that is
required for the specification of different cell identities within the female
gametophyte. Experiments carried out to test this model revealed that the
identities of cells could indeed be influenced by varying the concentrations
of a small molecule to which they were exposed. The mechanisms by which such a
gradient could be established and maintained were the subject of lively
debate.
Variation and evolution
Several talks discussed the exploitation of natural genetic variation to
study developmental processes and of establishing further model systems to
study how such processes are shaped by evolution. Kirsten Bomblies (Max Planck
Institute for Developmental Biology, Tübingen) described a molecular
analysis of hybrid necrosis, a surprisingly common phenomenon in plants, in
which the progeny of a cross between two accessions show necrosis and are much
less vigorous (Bomblies and Weigel,
2007). Typically, two loci are required to confer the necrotic
effect. She studied this phenomenon in Arabidopsis by first
performing a remarkable 1487 crosses between 311 Arabidopsis
accessions. In 25 of these crosses, the hybrid progeny were different, varying
from small with necrotic lesions but still producing seeds, to tiny and
sterile. These phenotypes were observed when plants were grown at 16°C (at
23°C, they appeared normal). In one cross between two accessions, UK1 and
UK3, two loci, dubbed DANGEROUS MIX 1 (DM1) from UK3 and
DM2 from UK1, were shown to interact to confer the necrosis
(Bomblies et al., 2007). The
DM1 locus mapped to chromosome 5 and encodes a Toll interleukin
receptor (TIR)-NB-LRR protein homologous to proteins that commonly confer
resistance to pathogens. The UK3 allele of DM1 encodes a full open
reading frame (ORF), whereas in UK1 DM1 only contains incomplete
ORFs. Gene-swapping experiments demonstrated that the leucine-rich repeat
region of DM1 is required for the hybrid necrosis effect. DM2 maps to
a 168 kb region of chromosome 3 that contains a cluster of resistance gene
homologues. This observation raises the possibility that hybrid necrosis is
caused by incompatibility between two resistance proteins, and that this
combination does not arise in either parent. Why the effect is temperature
dependent is not clear but might be due to the differential stability of the
resistance protein homologues at different temperatures or to a trade off
between stress signalling pathways so that the resistance-gene signalling
pathway is suppressed if the plant is stressed at higher temperatures. In a
second analysis, accessions of Arabidopsis were analysed from 95
sites in the Tübingen area using 455 single nucleotide polymorphism (SNP)
markers. The degree of polymorphism present at each site varied tremendously,
but generally those from urban sites showed little variation within the
population, whereas those from rural sites contained many variants. These
results suggested that wild populations are highly differentiated at the local
scale, and that rural meadow populations are where this variation can be
detected most clearly.
Jody Banks (Purdue University, IN, USA) presented a first glimpse of the Selaginella moellendorffii genome (see http://selaginella.genomics.purdue.edu). This species is a lycophyte, a group believed to have diverged from seed plants and ferns around 400 million years ago. The lycophytes appeared before roots and true leaves had arisen in the higher plant lineage, and as they represent the earliest surviving vascular plant lineage, they provide an insight into the early evolution of land plants. The genome is around 130 Mb, has been sequenced to 14x coverage and encodes around 22,000 proteins, of which over 3000 have been manually curated. Early analysis of the gene content identified over 13,000 gene clusters, of which 120 are absent in seed plants.
Elena Kramer (Harvard, Cambridge, MA, USA) described how Aquilegia
(Columbine) can be used as a model to study the evolution of unusual floral
structures, which in this case includes five whorls of organs rather than the
usual four (Kramer et al.,
2007). She explained how genes that encode homologues of the
Arabidopsis genes APETALA3 and PISTILLATA, which
are required for petal and stamen identity in Arabidopsis, show more
complex patterns of expression in the Aquilegia flower, and how
virus-induced gene silencing was used to demonstrate the activity of one of
them in conferring the identity of a novel structure: the stamenodium.
Conclusions
The power of comparative biology in more rapidly deciphering the common features of plants and in describing their species-specific differences was strongly evident at this meeting, particularly in the discussions on leaf polarity and phase transitions. Similarly, comparisons of A. thaliana and C. hirsuta provided an example of how common regulatory mechanisms can be co-opted to generate specific characters. The concept of opposing activities of different small RNAs to provide spatial and temporal boundaries of gene expression in developmental processes may also prove to be much more common in plants. I also expect that genomic approaches to investigating the RNA transcriptome of specialised cell types; for example, in conjunction with cell sorting or laser dissection, will have a much more general impact in the future. The development of new model systems and the availability of more genome sequences will also provide access to a broader range of developmental problems. The next meeting in this series is planned for August 2010 and will no doubt reflect how the themes discussed at this meeting develop in the intervening period.
ACKNOWLEDGMENTS
I am grateful to many participants at the meeting for their comments on and improvements to the text. I thank Daniel Chitwood and Marja Timmermans for the image used in Fig. 1 and Miltos Tsiantis for the images used in Fig. 2. Apologies to those whose exciting results were omitted owing to space constraints.
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