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J. Biol. Chem., Vol. 277, Issue 7, 5541-5547, February 15, 2002
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From the Department of Physiology and Biochemistry of Plants,
Faculty of Biology, University of Bielefeld,
D-33615 Bielefeld, Germany
Received for publication, July 3, 2001, and in revised form, November 7, 2001
This study characterizes the expression and
functional significance of the member of the matrix metalloproteinase
(MMP) family At2-MMP from Arabidopsis. By transcript
analysis, expression of At2-MMP was found in leaves
and roots of juvenile Arabidopsis and leaves, roots, and
inflorescences of mature flowering plants showing strong increase of
transcript abundance with aging. Cell specificity of expression of
At2-MMP was studied by in situ hybridizations in leaves and flowers of Arabidopsis. In leaves, the gene
was expressed in the phloem, in developing xylem elements, epidermal cells, and neighboring mesophyll cell layers. In flowers, signals were
localized in pistils, ovules, and receptacles. In an
Arabidopsis mutant (at2-mmp-1) carrying a
tDNA insertion in At2-MMP, neither germination nor
development of plants was modified in comparison to the wild type in
the juvenile rosette stage. Starting with the onset of shoots, growth
of roots, leaves, and shoots was inhibited compared with the wild type,
and the plants were characterized by late flowering. Besides the
flowering, at2-mmp-1 plants showed fast degradation of
chlorophyll in leaves and early senescence. These results demonstrate
the involvement of At2-MMP in plant growth, morphogenesis,
and development with particular relevance for flowering and senescence.
The family of zinc-dependent endopeptidases that has
been particularly characterized in vertebrates is divided into four
subfamilies based on structural and functional characteristics: matrix
metalloproteinases (matrixins), adamalysins, serralysins, and astacins.
All members of these zinc metalloproteinases have a similar structure
with the conserved consensus sequence
HEXXHXXGXXH in their catalytic site
and a conserved methionine residue that forms the "Met-turn" structure (1). Members of the subfamily of matrix metalloproteinases are gelatinases, collagenases, and stromelysins (2). Matrix metalloproteinases are synthesized as prepro-enzymes with a signaling peptide targeting the enzyme to the extracellular space. The pre-domain is followed by a pro-peptide with a conserved PRCG(V/N)PD motif that
contains the so-called "cysteine switch." This Cys residue ligates
the catalytic zinc thus maintaining the latency of the inactive
pro-enzymes (3). In vitro, pro-matrix metalloproteinases can
be activated proteolytically by proteinases as well as by mercurial
compounds and reactive oxygen, for example, whereas in vivo
activation by proteinases is most likely (3). The function of matrix
metalloproteinases is the degradation and remodeling of the
extracellular matrix (2). The enzymes play a role in development,
embryogenesis, and organ morphogenesis but also in wound healing in
vertebrates (4). They also participate in pathological processes such
as cancer and arthritis (5). In vertebrates, the enzyme activity of
matrix metalloproteinases is transcriptionally regulated as well by
proteolytic activation of the mature enzyme from the inactive
pro-enzyme and by co-secretion with endogenous inhibitors (4).
In addition to vertebrates, matrix metalloproteinases have also been
identified from Caenorhabditis elegans (6), sea urchins (7),
and from Chlamydomonas reinhardtii with the gamete lytic enzyme that digests the cell wall of gametes (8). The first matrix
metalloproteinase (MMP)1
isolated from higher plants was SMEP1 from soybean (9) that was
subsequently cloned (10). SMEP1 was shown to be expressed in adult
leaves but could not be detected in other plant tissues or in young
developing leaves (10). In cucumber the matrix metalloproteinase Cs1-MMP is expressed in leaves during senescence and may
participate in programmed cell death (11).
In the Arabidopsis thaliana data base five genomic sequences
homologous to matrix metalloproteinases were identified (12). Expression of the Arabidopsis enzymes was detected in roots,
leaves, stems, and flowers. Proteolytic activity was demonstrated for one of these proteinases, At1-MMP. At1-MMP
hydrolyzed both synthetic peptides and myelin basic protein but not
gelatin or casein (12).
Here a detailed characterization of tissue specificity and age
dependence of expression of the member of Arabidopsis matrix metalloproteinases At2-MMP is presented. For the first time
cell specificity of expression of a plant matrix metalloproteinase was
studied by in situ hybridizations and by promoter-reporter gene fusion. Finally, an Arabidopsis mutant carrying a
tDNA insertion in the At2-MMP locus was identified
and used to demonstrate the physiological role of the gene in plant
growth and developmental processes, particularly in flowering and senescence.
Plant Material--
Plants of A. thaliana (Columbia)
were grown in a growth chamber with 10 h of light (240 µmol
quanta m
The at2-mmp-1 mutant was identified from the seed pool 02_13
(N40060; insert number 02_13_06) obtained from the Nottingham Arabidopsis Center (UK).
RNA Extraction and RT-PCR--
RNA was isolated by guanidinium
isothiocyanate extraction from leaves, roots, and inflorescences from
A. thaliana (15).
cDNA synthesis was performed with SuperScript II reverse
transcriptase (Invitrogen) from each 3 µg of total RNA using
oligo(dT) primers. The sequences of the forward and reverse primers
used for amplifying the full-length sequences of At2-MMP
(GenBankTM accession number AC002062) by PCR were
5'-CCACCATGAGGTTTTGTGTTTTCGGGT-3' (S1) and
5'-CTACGGTAAGAACCACAAGACCAATCC-3 (S2). For PCR, Advantage2 polymerase mix (CLONTECH) was used, and the
sequence was cloned in the vector PCR2.1-TOPO (Invitrogen). For RT-PCR
expression studies, the following forward and reverse primers from the
coding region of At2-MMP were used: 5'-GTGAGCTTGATGCGCTTA-3'
and 5'-ATCTGCGTCTAGGTGGAA-3'. With this primer combination a 446-bp
fragment was amplified. The fragments were cloned in PCR-TOPO II
(Invitrogen). For expression studies with the non-coding region of the
transcripts, the following forward and reverse primers were used:
5'-AACGATCACGACAGGGAA-3' and 5'-CACACAAGAACGC GCTAA-3' that amplify a
482-bp fragment. The PCR settings were 1 cycle 94 °C for 1 min 30 s, 1 min 94 °C, 1 min 55 °C, 2 min 72 °C, and a final
extension at 72 °C for 10 min. For the transcripts, cycle numbers in
the linear range of amplification were determined and used for the
expression analyses by RT-PCR. AT2-MMP was amplified with 35 cycles from tissue of 4-week-old plants and with 30 cycles from
10-week-old plants. For direct comparison of expression in juvenile and
flowering plants, 33 cycles were used. In stress experiments
At2-MMP transcripts were amplified with 28 cycles from leaf
and root tissue and with 30 cycles from inflorescences of 10-week-old
Arabidopsis plants, whereas 34 cycles were used
for 4-week-old plants. The PCR products from RT-PCR amplifications were
separated on 1.7% (w/v) agarose gels and stained with ethidium
bromide. Photographic documentation was performed with a gel
documentation system (INTAS, Göttingen). Absence of genomic DNA
from the cDNA preparations was verified as described previously
(16).
For identification of the at2-mmp-1 mutant, the following
tDNA-specific primers were used:
5'-GGTGCAGCAAAACCCACACTTTTACTTC-3' (dSpm11) and
5'-GTTTTGGCCGACACTCCTTACC-3' (dSpm8) (compare Nottingham Arabidopsis
Center, UK, SLAT collection; nasc.nott.ac.uk)). For 3'-RACE
amplifications, total RNA was isolated from rosette leaves of
10-week-old at2-mmp-1 plants as described above, and
cDNA synthesis was performed with SuperScript II reverse
transcriptase (Invitrogen) using a 3'-RACE anchor primer (SMART RACE,
CLONTECH). PCR was performed with the primer dSpm8
and the SMART RACE primer mix (CLONTECH). The DNA
fragments amplified were cloned into PCR 2.1 (Invitrogen). Sequencing
was performed at the sequencing facility of the University Bielefeld.
Extraction of Genomic DNA, Promoter Constructs, Plant
Transformation, and Histochemical Detection of Reporter Gene
Activity--
Genomic DNA was extracted as described previously (17).
A 1249-bp genomic DNA fragment upstream of the start methionine for
translation was amplified by PCR with Advantage2 Polymerase mix
(CLONTECH) with the following primer pair:
5'-CTTTATTTGACTCCGCCACCTTCAGCT-3' and
5'-GGTGGTTTTCGGATTATAGGTAGCCAC-3'. The amplified DNA fragment was
cloned in the vector pBlue-TOPO (Invitrogen) upstream of the lacZ reporter gene.
10-Week-old Arabidopsis plants were transformed with the
pAt2-MMP::lacZ constructs by particle bombardment
(PDS1000, Bio-Rad). 0.625 µg of plasmid DNA was precipitated on
1.6-µm gold particles for each bombardment according to the protocol
of the manufacturer. For the bombardments 1200 pounds/square inch
rupture discs were used. After bombardment, the plants were allowed to
recover under normal growth conditions for 24 h.
Leaves from the bombarded plants were vacuum-infiltrated with 1%
glutaraldehyde in Z' buffer at room temperature for 1 h to inhibit
endogenous In Situ Hybridization and Microscopic Images--
Tissue
sections from inflorescences and leaves from 10-week-old
Arabidopsis plants were fixed with
formaldehyde-acetic acid, dehydrated, and embedded with
Paraplast Plus (Fisher) as described previously (20). Sections of 10 µm were mounted on poly-L-lysine-coated microscopic
slides. PCR-TOPO II (Invitrogen) harboring the 446-bp fragment of
At2-MMP were linearized with restriction enzymes. Antisense
and sense RNA were synthesized by in vitro transcription with SP6 and T7 RNA polymerase using digoxigenin-UTP (Roche Molecular Biochemicals) as a label. In situ hybridizations were
performed as described previously (16). Cross-sections from rosette
leaves of 10-week-old wild type Arabidopsis and
at2-mmp-1 plants were prepared as described above and
stained with toluidine blue. The leaf material used for the tissue
sections was taken from the middle of the leaf blades half-way between
the main vein and the edge of the leaves.
Tissue-specific and Developmental Differences in At2-MMP
Expression--
The genomic sequence of the matrix metalloproteinase
At2-MMP has recently been identified in the
Arabidopsis data base by Maidment et al. (12)
under the GenBankTM accession number AC002062 on chromosome
1. The genomic sequence of At2-MMP is intronless and
contains an open reading frame of 378 amino acids. The predicted
polypeptide shows the prepro-enzyme structure typical for zinc
endopeptidases with a signal peptide, a pro-peptide, and a catalytic
domain with the signature motif HEXXHXXGXXH and the conserved
methionine residue that forms the Met-turn structure (1). In a
converse manner to At4-MMP, but similar to the other matrix
metalloproteinase homologues identified in Arabidopsis,
At2-MMP contains a non-cleavable C-terminal trans-membrane domain (compare with Ref. 12). Analysis using PSORT
(psort.ims.u-tokyo.ac.jp) proposed localization of At2-MMP
in the plasma membrane.
The expression of At2-MMP was studied by RT-PCR
amplification in juvenile 4-week-old Arabidopsis plants in
the rosette stage and in 10-week-old flowering Arabidopsis
plants. A fragment from the coding region of the gene was amplified by
gene-specific primers, and actin was amplified as a loading control. In
4-week-old Arabidopsis plants, transcripts of
At2-MMP were detected in leaves and roots with a higher
transcript abundance in the leaf tissue (Fig.
1A). In 10-week-old flowering
A. thaliana plants, At2-MMP was expressed in
leaves, roots, and inflorescences. The highest signal strength was
obtained from root tissue, and in leaves and flowers a lower level of
expression was detected (Fig. 1B).
To analyze developmental effects, the transcript abundance of
At2-MMP was compared in leaves and roots of juvenile and
flowering Arabidopsis. In both tissue types the expression
of the metalloproteinase was strongly induced with aging of the plants
(Fig. 1C).
Histochemical Analysis of Promoter Activity and in Situ
Hybridization--
The tissue specificity of At2-MMP
expression was studied by histochemical detection of promoter activity
in cauline leaves and rosette leaves of 10-week-old
Arabidopsis plants. A genomic fragment 5'-upstream of the
start methionine of the At2-MMP coding sequence was fused to
the
For analysis of cell specificity of At2-MMP transcript
abundance, in situ hybridizations were performed in leaf and
flower cross-sections from 10-week-old Arabidopsis plants
using a fragment from the coding region of the gene as a probe. In
flowers, signals were detected in the receptacle in the two to three
mesophyll layers neighboring the epidermis but was not detectable in
sepals and petals. Strong expression of At2-MMP occurred in
the gynoecium in the cell layers neighboring the epidermis with signal
intensities increasing toward the styles. Furthermore, strong
hybridization of antisense-At2-MMP RNA could be observed in
ovules (Fig. 2, C-F). In leaves, expression of the matrix
metalloproteinase was detected in phloem cells next to the metaxylem
and in selected protoxylem cells. Moreover, epidermal cells and
mesophyll cell layers toward the leaf surface were showing
At2-MMP signals (Fig. 2, G and H).
Expression of At2-MMP in Response to Methyl Jasmonate, Cadmium, and
NaCl--
The regulation of At2-MMP transcription in
response to methyl jasmonate, to the heavy metal cadmium, and to salt
stress was studied by RT-PCR amplification. Methyl jasmonate is known
to induce pathogenesis-related and wounding responses in plants (21) and was applied to 4- and 10-week-old Arabidopsis plants by
spraying of leaves, stems, and inflorescences as a 45 µM
solution. The heavy metal cadmium that is a highly toxic abiotic
stressor and inhibits plant growth (22) was added at 150 µM to the nutrition solution for 48 h. For salt
stress, the nutrition solution was supplemented with 50 mM
NaCl, and the plants were exposed for 24 h.
In rosette leaves of 4-week-old Arabidopsis plants, both
methyl jasmonate treatment and exposure to cadmium increased the transcript level of At2-MMP, whereas the signal strength did
not change in response to NaCl. Conversely, in roots the transcription was stimulated by NaCl but was not modified by jasmonate and cadmium (Fig. 3). In 10-week-old plants, the
At2-MMP transcript level in roots was not affected by the
three stressors. In leaves and inflorescences the expression was not
modified by jasmonate (Fig. 4) and NaCl
(not shown) but was strongly inhibited by exposure to cadmium (Fig.
4).
Characterization of a tDNA Knock-out Mutant for At2-MMP--
The
tDNA insertion mutant at2-mmp-1 was identified from a seed
pool that was obtained from the Nottingham Arabidopsis Center, UK (SLAT
collection, insert number 02_13_06), by PCR using a combination of
sequence-specific and tDNA-specific primers. The identified F1
at2-mmp-1 plant was self-pollinated, and from the F2
generation 12 plants homozygous for at2-mmp-1 were PCR-based
identified for further characterization.
From genomic DNA of the F1 plant a PCR fragment was amplified with the
At2-MMP sequence-specific primer S1 and the tDNA-specific primer T2. The amplified DNA fragment was cloned, and sequence analysis
revealed the integration of the tDNA into the At2-MMP locus
at bp 415 of the open reading frame of At2-MMP. From genomic DNA isolated from the at2-mmp-1 mutant plants, the
full-length coding DNA sequence could not be amplified using the S1-S2
primer combination. This difference in obtaining full-length
At2-MMP PCR products from wild type genomic DNA but not from
at2-mmp-1 plants allowed to distinguish clearly between the
wild type and the mutant plants and indicated that the
at2-mmp-1 plants analyzed were homozygous for the tDNA
insertion without carrying the wild type gene (Fig.
5A). By using the
tDNA-specific primer dSpm8, a single PCR product was obtained by
3'-RACE PCR amplifications from cDNA synthesized from RNA of
at2-mmp-1 mutant plants (Fig. 5B). Sequencing of
the PCR product revealed its identity as chimeric DNA composed of the
3'-end of the inserted tDNA as well as the 3'-end of the
At2-MMP coding region and demonstrated integration of the
cDNA up to bp 412 at the 3'-end of the gene (Fig.
6). The results from the 3'-RACE
experiments show that At2-MMP carrying the tDNA insertion is
expressed in at2-mmp-1 plants. Furthermore, obtaining only
one PCR-product from the transcript population of at2-mmp-1
plants by using tDNA-specific primers suggests that the mutant plants
carry a single tDNA insertion.
Phenotypic Effects of the Mutation of the At2-MMP Locus--
There
was no difference of germination time and germination rate observable
between wild type plants and the at2-mmp-1 mutants. The
development of the second leaf pair was slower in the mutant plants
than in the wild type, whereas further development was not modified in
comparison to the wild type plants during the juvenile rosette stage.
Starting with the development of shoots, growth of at2-mmp-1
plants became significantly slower than that of the wild type (Fig.
7). At the age of 6 weeks root length of the mutant was about 60% of the wild type; leaf length was about 70%,
and shoot length was about 15%. The development of flowers started
2-3 weeks later in the mutant than in the wild type under the growth
conditions used in our experiments. The final length reached by
at2-mmp-1 plants was about 80% of the wild type for roots
and about 70% for leaves and shoots (Fig.
8). At the age of 10 weeks the mutant
plants showed fast degradation of chlorophyll and pronounced senescence
in both rosette and cauline flowers, whereas wild type plants grown in
parallel showed initial signs of senescence in the oldest rosette
leaves but no chlorophyll degradation in younger rosette and cauline
leaves (Fig. 9). Transverse sections from
rosette leaves of 10-week-old wild type Arabidopsis plants
and at2-mmp-1 revealed reduced cell size and thus indicated inhibition of elongation in at2-mmp-1 compared with wild
type plants (Fig. 10).
Expression of At2-MMP Is Developmentally Regulated--
In
animals, matrix metalloproteinases are the major group of proteinases
that mediate the turnover of components of the extracellular matrix
(4). Degradation of the extracellular matrix has an important role for
physiological processes as embryogenesis, organ morphogenesis, and bone
remodeling, for example (5). Unregulated enzyme activity of matrix
metalloproteinases is involved in the development of diseases including
cancer, arthritis, and atherosclerosis (4). There are 20 soluble
members of matrix metalloproteinases known that are secreted to the
extracellular space, and furthermore, there have been 5 membrane-anchored matrix metalloproteinases described that have a
predicted localization in the plasma membrane (see Refs. 5 and 23;
psort.ims.u-tokyo.ac.jp).
In contrast to animals, little is known on the matrix metalloproteinase
homologues in plants. In this study At2-MMP was chosen as
one of the five matrix metalloproteinases that were recently identified
in the Arabidopsis data base (12) for a detailed analysis of
expression and physiological function.
Transcript analysis shows expression of At2-MMP in all
tissues investigated, i.e. roots, leaves, and
inflorescences. In both leaf and root tissue expression of
At2-MMP was developmentally controlled with strong induction
in mature flowering Arabidopsis. Maidment et al.
(12) studied the expression of five Arabidopsis metalloproteinases in 2-week-old plants and found transcripts in
leaves, stems, and flowers with different gene-specific transcript levels. At2-MMP was detected with stronger expression in
roots than in flowers and leaves corresponding to the expression
pattern that we found in flowering 10-week-old Arabidopsis
plants in this study, whereas in juvenile 4-week-old plants
At2-MMP transcript abundance was higher in leaves than in
roots. In contrast to At2-MMP, Maidment et al.
(12) found expression of At5-MMP to be strongest in stems
and At3-MMP had higher transcript abundance in leaves and
roots than in flowers and stems. In a converse manner, the matrix
metalloproteinase SMEP1 from soybean was only detected in leaf tissue
starting at the age of 10 days. Expression increased up to the age of
20 days and increased slightly thereafter. The enzyme was neither
expressed in young leaves nor in other tissues both on the transcript
and on the protein level in soybean (10). In cucumber, the matrix
metalloproteinase Cs1-MMP was detected in leaves during senescence with
chlorophyll degradation already occurring. Cs1-MMP was also
found to be expressed in senescing male cucumber flowers (11). The data
shown in cucumber (11), soybean (9, 10), and Arabidopsis
plants as presented in this study suggested that the metalloproteinase
expression has a physiological role in mature aging tissue and might be
involved in plant senescence.
In this study we analyzed the cell specificity of At2-MMP
expression in leaves and flowers of 10-week-old Arabidopsis
plants by in situ hybridizations. Transcription of the
metalloproteinase was detectable in several cell types such as phloem
and developing xylem cells and mesophyll and epidermal cells.
Interestingly, in leaves as well as in the pistils and the stems of the
flowers, signal intensities of At2-MMP increased toward the
epidermal cell layers. Strong expression of the enzyme could also be
found in ovules. Based on this cell specificity with main transcription in epidermal and neighboring cells, involvement of At2-MMP in embryogenesis and morphogenesis analogous to animal systems seemed likely. This conclusion was supported by the decreased size of leaf
cells, and particularly of epidermal cells, in the knock-out mutant.
Stress-induced Expression of At2-MMP--
Although no natural
substrates of plant matrix metalloproteinases have been identified yet,
these enzymes cleave similar substrates as animal metalloproteinases
when tested in vitro. Enzyme activity of soybean SMEP1 was
shown for fluorogenic and chromogenic peptide substrates that are also
cleavable by human fibroblast collagenase (24). Cs1-MMP from cucumber
showed collagenase activity when synthetic peptides and type I collagen
were used as substrates (11). Maidment et al. (12) showed
that the mature At1-MMP that was heterologously expressed in
Escherichia coli cleaved myelin basic protein as well as
peptide substrates for metalloproteinases but not gelatin and casein.
Besides, the At1-MMP activity was inhibited by TIMP1 and TIMP2 as well
as by the metalloproteinase hydroxamate inhibitor BB94 (12).
According to the ability of plant metalloproteinases to cleave similar
substrates as the animal enzymes, a role of the plant proteases in
defense against pathogens seemed plausible. Thus, metalloproteinases
might be involved in proteolysis of foreign proteins in the plant
extracellular matrix. In addition, members of the family of the plant
subtilisin-like proteases were transcriptionally activated by pathogen
attack in tomato (25, 26) and by treatment with methyl jasmonate that
mediates wounding and pathogen responses in plants (21).
In this study we compared the expression of At2-MMP in
response to methyl jasmonate, the highly toxic heavy metal cadmium, and
NaCl in developing 4-week-old rosette plants and in mature 10-week-old
flowering plants at the border to senescence. Our results demonstrated
that expression of At2-MMP is not regulated as a general
stress response in Arabidopsis but is tightly controlled in
a tissue-responsive way with developmental differences. In 4-week-old
plants leaf tissue but not roots showed transcriptional activation of
the enzyme in response to methyl jasmonate and cadmium, whereas in root
tissue expressional up-regulation was observed specifically in response
to salt stress. In mature plants presenting the main developmental
phase of At2-MMP expression, transcription of the enzyme was
inhibited in inflorescences and leaves by cadmium treatment but was not
modified by the metal in roots as well as in response to methyl
jasmonate and salinity in all tissues tested. According to these data
we conclude that At2-MMP plays a minor role in general
stress responses in Arabidopsis and is particularly not of
significant importance for adaptation to wounding stress or
pathogenesis response.
Physiological Characterization of an At2-MMP Mutant--
The
extracellular matrix of plants consists by up to 10% of the dry weight
of proteins including enzymes such as hydrolases and peroxidases,
pathogenesis-related proteins, signal sensing, and structural proteins
(27). Physiological roles of extracellular proteolytic processes and
particularly of matrix metalloproteinases rarely have been investigated
in plants but are well documented in animal systems.
In mice, knock-out mutants have been generated and characterized for
several matrix metalloproteinases. Interestingly, in knock-out mice
with defects of soluble MMPs some developmental phenotypes were
detected (23). In contrast, knock-out mutants of the membrane-type
MT1-MMP were characterized by dwarfism, arthritis, and
fibrosis, for example (28). By overexpression of seven different soluble matrix metalloproteinases, morphogenesis was not affected in
Madin-Darby canine kidney cells, whereas three membrane-type MMPs
accelerated, disrupted, or modified branching tubulogenesis in these
cells (29). These data demonstrated that in animal systems
membrane-type MMPs have a key role in pericellular proteolysis of the
extracellular matrix including its remodeling and are
essential for development, cell invasion, and morphogenesis
(28, 29).
In the present study, an Arabidopsis mutant of the
membrane-type At2-MMP was identified carrying a tDNA
insertion. The mutant phenotype showed the involvement of the enzyme in
growth and development of maturing plants. Roots as well as leaves,
shoots, and inflorescences exhibited growth inhibition and retarded
development. Furthermore, the mutant plants were characterized by late
onset and slow development of flowers, and their final size was reduced
compared with wild type plants. Interestingly, aging of the plants was
not slowed down in comparison to the wild type, but the mutation caused
acceleration of senescence. Based on expressional studies that revealed
Cs1-MMP transcripts only in senescing cucumber leaves,
Delorme et al. (11) suggested an involvement of
Cs1-MMP in programmed cell death. The authors hypothesized
that the enzyme may contribute to proteolysis of cell residues, for
example (11). Our data demonstrate an earlier onset of senescence and
cell death in at2-mmp-1 mutants than in wild type plants as
well as growth inhibition of organs. Apparently, the activity of
At2-MMP is related to a delay of senescence and programmed cell death
and is necessary for regular plant growth and development.
In general, the physiological functions of extracellular proteolytic
processes in plants may include the remodeling of the extracellular
matrix during growth and development. Turnover of extracellular matrix
proteins could be involved in the generation of secondary cell walls
during plant maturation, formation of secondary plasmodesmata, of
vascular xylem elements, and intercellular lytic spaces, as well as
regulation of receptor interactions and signal transduction by receptor
modification. Interestingly, At2-MMP was mainly expressed in
mature flowering plants, and phenotypic differences of the
at2-mmp-1 mutant from wild type plants were particularly
pronounced starting with the plant shooting and onset of flowers. Our
data demonstrated that extracellular proteolytic processes
mediated by At2-MMP are involved in growth and development during the developmental phase of flowering. However, it is likely that
morphogenesis and growth of juvenile plants requires extracellular proteolytic processes as well. Members of other families of
extracellular proteases may substitute for the function of matrix
metalloproteinases in the juvenile developmental phase of plants.
Candidate enzymes are members of extracellular subtilisin-like
proteases, for example, that have been shown to be preferentially
expressed in young developing plants
(30).2 Future studies on the
regulation of age-dependent expression, identification of
signal transduction pathways, and in vivo studies will
further clarify our understanding on the significance of extracellular
proteases for plant morphogenesis and development.
Finally, the hypothesis of a more specific function of
At2-MMP may be suggested which involves receptor shedding or
activation and will have to be tested. Initiation of senescence and
programmed cell death involves hormonal stimuli such as ethylene and
salicylate (31, 32); other stimuli such as cytokinins counteract the development of senescence (33). The stimuli are sensed by receptors that in turn activate signaling cascades and trigger or silence the
senescence program. Assuming the constitutive expression of such a
receptor, and either its continuous degradation or specific activation
by MMP, MMP-deficient tissue could be hypersensitized leading to
inhibited growth and premature activation of the senescence program
(34). The phenotype of the at2-mmp-1 mutant plants is in
agreement with such a hypothesis.
*
This work was supported by the Deutsche
Forschungsgemeinschaft Sonderforschungsbereich 549.The costs of publication of this article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
Published, JBC Papers in Press, November 28, 2001, DOI 10.1074/jbc.M106197200
2
D. Golldack, P. Vera, and K. J. Dietz,
non-published results.
The abbreviations used are:
MMP, matrix
metalloproteinase;
RT, reverse transcriptase;
RACE, rapid amplification
of cDNA ends.
Mutation of the Matrix Metalloproteinase
At2-MMP Inhibits Growth and Causes Late Flowering and Early
Senescence in Arabidopsis*
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
2 s1, 23 °C) and 14 h of
darkness (18 °C) with 50% relative humidity. After
germination in rock wool soaked with nutrition solution (1.25 mM KNO3, 1.5 mM
Ca(NO3)2, 0.75 mM
MgSO4, 0.5 mM
(NH4)H2PO4, 72 µM
Fe-EDTA micronutrients (see Ref. 13) H and L) the 3-week-old plants
were transferred to aerated 5-liter hydroponic tanks. For stress
treatment, plants were transferred to nutrition solution containing 50 mM NaCl for 24 h, containing 150 µM
CdCl2 for 48 h, or were sprayed with 45 µM methyl jasmonate in 0.1% ethanol (14) on leaves and
inflorescences and exposed for 48 h. Non-stressed plants were
grown in parallel and harvested at the same time. Plants used for the
experiments were in the rosette stage at the age of 4 weeks or were
flowering at the age of 10 weeks. Plants were harvested 5 h after
the onset of illumination.
-galactosidase activity (18, 19). The leaves were rinsed
three times in Z' buffer and then vacuum-infiltrated with staining
solution as described previously (19) with 0.1% 5-bromo-4-chloro-3-indolyl -D-galactopyranoside (X-gal)
at room temperature for 1 h followed by incubation at 37 °C for
14 h. Finally, the leaves were treated with Z' buffer and
incubated with 70 and 100% ethanol to remove chlorophyll. Leaves from
plants bombarded with the promoter-less vector pBlue-TOPO did not show -galactosidase activity.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Tissue specificity and age dependence of
expression of At2-MMP in
Arabidopsis. Transcript levels were quantitated
in juvenile 4-week-old Arabidopsis plants and flowering
10-week-old Arabidopsis plants. A fragment of the coding
region of At2-MMP was amplified by RT-PCR. Actin was
amplified as a loading control. A, 4-week-old
Arabidopsis plants. L, leaves; R,
roots (35 PCR cycles). B, 10-week-old Arabidopsis
plants. L, leaves; R, roots; F,
inflorescences (30 PCR cycles). C, L4, leaves of
4-week-old plants; L10, leaves of 10-week-old plants;
R4, roots of 4-week-old plants; R10, roots of
10-week-old plants (33 PCR cycles).
-galactosidase reporter gene, and Arabidopsis plants
were transformed biolistically with the promoter-reporter-gene construct. The plants were allowed to recover under normal growth conditions before -galactosidase activity induced by the
At2-MMP promoter was histochemically detected. Reporter-gene
expression could be found in both cauline and rosette leaves with
signals of similar staining intensity. The signals were distributed on the leaf blade without preference of a particular leaf area (Fig. 2A).
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Fig. 2.
Cell specificity of expression of
At2-MMP in 10-week-old Arabidopsis plants.
A, histochemical detection of -galactosidase activity in
a cauline and a rosette leaf from 10-week-old Arabidopsis
plants transformed with the promoter-reporter gene construct
pAt2-MMP::lacZ. B, histochemical
detection of -galactosidase activity in a cauline and a rosette leaf
from 10-week-old Arabidopsis plants transformed with the
promoter-less vector as a control. C, in situ
hybridization of At2-MMP to a flower cross-section.
Antisense. D, in situ hybridization of
At2-MMP to a flower cross-section. Sense. E,
in situ hybridization of At2-MMP to a
pistil cross-section. Antisense. F, in situ
hybridization to a pistil cross-section. Sense. G, in
situ hybridization to a leaf cross-section. Antisense.
H, in situ hybridization to a leaf cross-section.
Sense.
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[in a new window]
Fig. 3.
Expression of At2-MMP in
juvenile Arabidopsis in response to methyl jasmonate,
cadmium, and NaCl. Transcript amounts were quantitated by RT-PCR
using fragments of the coding region of the gene. Actin was amplified
as a loading control. A, Lc, leaves from
non-stressed control plants; LCd, leaves from plants treated
with 150 µM CdCl2 for 48 h;
LJa, leaves from plants treated with 45 µM
methyl jasmonate for 48 h; Rc, roots from non-stressed
control plants; RCd, roots from plants treated with 150 µM CdCl2 for 48 h; RJa, roots
from plants treated with 45 µM methyl jasmonate for
48 h. B, Lc, leaves from non-stressed
control plants; Ls, leaves from plants treated with 50 mM NaCl for 24 h; Rc, roots from
non-stressed control plants; Rs, roots from plants treated
with 50 mM NaCl for 24 h.
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Fig. 4.
Stress-induced expression of
At2-MMP in flowering
Arabidopsis. Fragments of the coding region of
the gene were amplified by RT-PCR. Actin was amplified as a loading
control. Lc, leaves from non-stressed control plants;
LCd, leaves from plants treated with 150 µM
CdCl2 for 48 h; LJa, leaves from plants
treated with 45 µM methyl jasmonate for 48 h;
Rc, roots from non-stressed control plants; RCd,
roots from plants treated with 150 µM CdCl2
for 48 h; RJa, roots from plants treated with 45 µM methyl jasmonate for 48 h; Fc,
inflorescences from non-stressed control plants; FCd,
inflorescences from plants treated with 150 µM
CdCl2 for 48 h; FJa, inflorescences from
plants treated with 45 µM methyl jasmonate for 48 h.
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Fig. 5.
Identification of the mutant
at2-mmp-1 carrying a tDNA insertion in the
At2-MMP locus. A, PCR from genomic DNA
isolated from at2-mmp-1 plants (M) and
from wild type Arabidopsis (Wt) with
oligonucleotide primers amplifying the full-length coding region of
At2-MMP. B, 3'-RACE amplification of the DNA
fragment containing the 3'-end of the tDNA and the complete 3'-end of
At2-MMP (cf. Fig. 6) using the tDNA-specific
primer dSpm8 and a 3'-RACE anchor primer.
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Fig. 6.
Sequence of the At2-MMP
locus carrying the tDNA insertion. Nucleotide and amino acid
sequences of the locus of tDNA insertion in At2-MMP and the
tDNA-specific oligonucleotide primers dSpm8 and dSpm11 are shown. The
asterisks indicate the 5'-end and the 3'-end of the
tDNA.
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Fig. 7.
Phenotypes of at2-mmp-1
mutant plants and of wild type Arabidopsis. The phenotypes
of at2-mmp-1 and of wild type Arabidopsis at the
age of 6 weeks are shown.
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Fig. 8.
Growth inhibition in
at2-mmp-1 plants. The lengths of roots, leaves,
and shoots from 6- and 10-week-old at2-mmp-1 plants and of
wild type Arabidopsis are compared. Data represent
means ± S.D. n = 12.
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Fig. 9.
Comparison of cauline and rosette leaves from
10-week-old at2-mmp-1 and of wild type
Arabidopsis plants. Leaves of the mutant plants
are characterized by early chlorophyll degradation and
senescence.
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Fig. 10.
Structure of leaves from wild type
Arabidopsis and at2-mmp-1
plants. The light microscopic images show transverse
sections of rosette leaves from 10-week-old wild type
Arabidopsis (A) and at2-mmp-1 plants
(B).
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
FOOTNOTES
To whom correspondence should be addressed. Tel.:
49-521-106-5589; Fax: 49-521-106-6039; E-mail:
karl-josef.dietz@biologie.uni-bielefeld.de.
ABBREVIATIONS
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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