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Plant Physiol, April 2000, Vol. 122, pp. 1015-1024
Purification, Characterization, and Molecular Cloning of the
Gene of a Seed-Specific Antimicrobial Protein from
Pokeweed1
Yingfang
Liu,
Jingchu
Luo,
Chunyu
Xu,
Fucheng
Ren,
Cheng
Peng,
Guangyao
Wu, and
Jindong
Zhao*
The National Laboratory of Membrane Biology, College of Life
Sciences, Peking University, Beijing 100871, China
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ABSTRACT |
A small cysteine-rich protein with
antimicrobial activity was isolated from pokeweed (Phytolacca
americana) seeds and purified to homogeneity. The protein
inhibits the growth of several filamentous fungi and gram-positive
bacteria. The protein was highly basic, with a pI higher than 10. The
entire amino acid sequence of the protein was determined to be
homologous to antimicrobial protein (AMP) from Mirabilis
jalapa. The cDNA encoding the P. americana AMP
(Pa-AMP-1) and chromosomal DNA containing the gene were cloned and
sequenced. The deduced amino acid sequence shows the presence of a
signal peptide at the amino terminus, suggesting that the protein is
synthesized as a preprotein and secreted outside the cells. The
chromosomal gene shows the presence of an intron located within the
region encoding the signal peptide. Southern hybridization showed that
there was small gene family encoding Pa-AMP. Immunoblotting showed that
Pa-AMP-1 was only present in seeds, and was absent in roots, leaves,
and stems. The Pa-AMP-1 protein was secreted into the environment of
the seeds during germination, and may create an inhibitory zone against
soil-borne microorganisms. The disulfide bridges of Pa-AMP-1 were
identified. The three-dimensional modeling of Pa-AMP-1 indicates that
the protein has a small cystine-knot folding, a positive patch, and a
hydrophobic patch.
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INTRODUCTION |
During evolution, plants have developed a variety of defense
systems to protect themselves from potential pathogens. Plants often
produce small Mr chemicals inhibitory
to microbial growth. These chemicals are either induced as a result of
activation of a group of genes encoding the enzymes of the synthetic
pathway upon pathogen infection, such as phytoalexins (Smith, 1994 ), or are constitutive, such as saponins (Osborn, 1996). In recent years, it
has been realized that proteins also play important roles in plant
defense systems. Proteins including thionins (Bohlmann and Apel, 1991),
plant defensins (Broekaert et al., 1995; Epple et al., 1997), and
chitinases (Schumbaum et al., 1986) have been shown to play active
roles against pathogen infections.
Seed germination is likely to be one of the most vulnerable periods for
pathogen attack in a plant's life cycle because the rupture of the
seed coat could allow invasion of pathogens into the seed storage
tissues. Plants have developed defense systems such as defensins to
prevent pathogen infection at this stage in their life cycle. The plant
defensins are small, Cys-rich antifungal proteins present in many
plants (Broekaert et al., 1995). Other proteins have also been shown to
play an important role in plant defense systems. Cammue et al. (1992)
isolated two small proteins with strong antimicrobial activity from
Mirabilis jalapa seeds. These two proteins contained six Cys
residues, all of which are involved in disulfide bond formation for
stabilizing protein tertiary structure. The genes encoding these two
proteins have been cloned and sequenced (De Bolle et al., 1995).
In searching for antifungal proteins from various sources, we found
that pokeweed (Phytolacca americana) seeds contained strong activity against growth of some soil-borne fungal pathogens. We report
the isolation and characterization of an active antimicrobial protein
(AMP) from pokeweed seeds and molecular cloning of the gene encoding
the protein.
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MATERIALS AND METHODS |
Purification of AMP from Pokeweed Seeds
Protein Purification
Pokeweed (Phytolacca americana) plants were grown in
the greenhouse of Peking University. For isolation and purification of the AMP from pokeweed seeds (Pa-AMP-1), 20 g of seeds were
collected. The seeds were ground into powder and suspended in
approximately 20 mL of 4-(2-hydroxyethyl)-1-piperazineethanesulfonic
acid (HEPES) buffer (25 mM, pH 8.0) containing 1 mM NaCl. The solution was incubated at 25°C for
about 1 h before it was filtered to remove undissolved materials.
The filtrate was incubated at 90°C for 10 min, followed by a
centrifugation at 15,000 rpm for 10 min. The supernatant was loaded
onto a Sephadex-SP (Sigma, St Louis) column (2.5 × 30 cm). The
column was washed with 5 bed volumes of buffer A (25 mM HEPES, pH 8.0, 10 mM
NaCl, and 10 mM KCl) and eluted with a NaCl
gradient from 10 to 500 mM in buffer A. The flow
rate was 25 mL h 1, and the elution was
monitored at 280 nm. The fractions with antimicrobial activities were
pooled and concentrated by lyophilization. The active fractions were
then loaded onto a Sephadex G-50 gel filtration column (2 × 45 cm) and eluted with buffer A at a flow rate of 15 mL
h1. The fractions with antimicrobial activity
were pooled and concentrated by ultrafiltration with a 3-kD cutoff
membrane (Amicon, Beverly, MA).
HPLC Analysis
A micro-HPLC system (model 173, Perkin Elmer-Applied Biosystems,
Foster City, CA) was used for HPLC analysis of the purified protein.
Solution A contains 0.1% (v/v) trifluoroacetic acid (TFA) and
solution B contained 0.1% (v/v) TFA in 100% (v/v)
acetonitrile. The column (0.5 mm × 15 cm) was equilibrated with
2% (v/v) solution B in solution A before sample injection. An
elution gradient (2%-45% B from 0-75 min, then maintained at 45%)
was employed to elute the protein. The elution was monitored at 210 nm.
Characterization of the AMP
Protein Sequencing
The N-terminal sequence of the purified protein was determined
using an automatic protein sequencer (ABI491, Perkin Elmer-Applied Biosystems). The protein was first dissolved in 4 M
guanidine and reduced with 10 mM diothiothreitol (DTT). The
Cys residues were modified by incubating with 2 M
acrylamide at 37°C for 1 h at pH 8.3. The derivatized protein
was adsorbed to a polyvinylidene difluoride (PVDF) membrane using the
Prosorb kit (Perkin Elmer-Applied Biosystems). Five microliters of
Biobrene (Perkin Elmer-Applied Biosystems) was added to the membrane
before it was subjected to sequencing.
Determination of the Disulfide Bridges of Pa-AMP-1
The purified Pa-AMP-1 at a concentration of 2 mg
mL1 was first cleaved chemically with
N-bromosuccinimide (NBS). The protein solution was diluted
10-fold with
(NH4)2CO3
buffer (100 mM), followed by tryptic digestion
with the modified trypsin (Promega, Beijing) according to the
instructions of the supplier. The digested products were analyzed by
micro-HPLC. The C18 column (0.5 mm × 15 cm)
was first equilibrated with 2% (v/v) buffer B before the sample
was injected. The peptides were eluted with an isocratic gradient. The
elutants were blotted directly on a PVDF membrane strip with the
on-line blotter and sequenced to determine their N-terminal sequences.
The results are summarized in Table II. The method by Zhang and Liang
(1993) was used to determine which residues would produce dehydro-Ala
( -Ser). The monitoring wavelength of the protein sequencer detector
was adjusted to 313 nm, where phenylhydantoin (PTH)--Ser has a
strong absorption.
Electrophoresis
SDS-electrophoretic analysis of the Pa-AMP-1 was performed using
N-[2-hydroxy-1,1-Bis(hydroxymethyl)-ethyl]glycine
(Tricine)-SDS gel according to the method of Schagger and von Jagow
(1987). The gel was stained using a silver-staining kit (Bio-Rad,
Hercules, CA). To determine the pI of the Pa-AMP-1, isoelectric
focusing gel electrophoresis was performed according to the method of
Zhou et al. (1998). The gel was stained with Coomassie Brilliant Blue.
Immunological Detection of Pa-AMP-1
To obtain polyclonal antibodies against Pa-AMP-1, a green
fluorescence protein (GFP)-PA-AMP-1 fusion protein was first
overproduced in Escherichia coli (C. Xu and J. Zhao,
unpublished data). The rabbit polyclonal antibodies were raised
according to the method of Harlow and Lane (1988). The antibodies were
specific to Pa-AMP-1 and GFP. Immunoblotting after Tricine SDS-PAGE was
performed using horseradish peroxidase-conjugated goat anti-rabbit IgG
antibodies as secondary antibodies, as described in Zhou et al. (1998).
To detect Pa-AMP-1 secretion from the pokeweed seeds during
germination, seeds were first incubated in water for 12 h at
28°C, and then transferred onto a PVDF membrane, which was wet first
before being placed on top of four layers of Whatman filter paper in a
Petri dish. The seeds were incubated for various times at 28°C before removal. The Pa-AMP-1 released from each seed onto the PVDF membrane was detected using the antibodies against Pa-AMP-1 as described above.
Molecular Cloning of the Gene Encoding the AMP of Pokeweed Seeds
Genomic DNA from pokeweed leaves was isolated according to the
method of Dellaporta et al. (1983). Total RNA from pokeweed seeds was
isolated as described by De Vries et al. (1988). mRNA was isolated
using the mRNA isolation kit from Promega according to the
manufacturer's instructions. To isolate cDNA encoding the AMPs,
reverse transcription PCR (RT-PCR) was performed. The mRNAs isolated
from the seeds were first reverse-transcribed with reverse transcriptase using poly(T) oligonucleotides as the primer. The cDNAs
encoding the mature AMP were amplified by PCR using Taq enzyme (Promega). The primers for amplification were 5'-CNGGNTG(C/T) AT(A/T/C) AA(A/G) AA(T/C) GG-3', where N represents any nucleotide, and
poly(T) primer. The PCR conditions were: 92°C for 1 min, 48°C for 1 min, and 72°C for 1.5 min, for 35 cycles. The amplified fragments
were cloned into a T-vector from Promega and sequenced with an
automatic DNA sequencer (model 477, Perkin Elmer-Applied Biosystems).
To obtain the full-length cDNA encoding the AMP, the isolated mRNAs
were subjected to a 5'RACE according to the method of Frohman et al.
(1988). The primers used in the PCR were: (a)
5'-TTTTGCAAACACCATAGGAT- TGTCC-3', which was designed based on the
sequence encoding the mature protein; and (b) poly(T) oligonucleotides. The PCR conditions were the same as described above. The amplified fragment was cloned and sequenced as described above.
To amplify chromosomal DNA encoding the AMP, 2 primers were designed
based on the sequence of the cDNA obtained above. The 5' primer was
5'-ACGTTATCAATC- TCCGCCTTACC-3' and the 3' primer was
CTTATTC- ATCATGATAGGGCC-3'. The amplification with PCR was performed
in the presence of Pfu DNA polymerase as described by Cheng et al.
(1994). A 1.0-kb fragment was obtained and cloned in pUC18. It was
sequenced as described above.
Southern Hybridization
Genomic DNA was digested with EcoRI and XbaI
followed by agarose (0.8%, w/v) electrophoresis. The separated
DNA was transferred to a nitrocellulose membrane, and the membrane was
baked at 80°C for 2 h under vacuum. Radioactive probe was first
prepared with a random primer extension kit (Promega) with
32P-dATP using the cDNA encoding Pa-AMP-1 as a
template. The hybridization was performed according to the method of
Zhao et al. (1993).
Three-Dimensional Modeling of Pa-AMP-1
Model building was with the molecular modeling program Whatif
(Vriend et al., 1998). The NMR coordinates of 1AXH were used to build
up the backbone fragments. Loops were searched against the Whatif
built-in loop fragment database. The modeled structure was refined
geometrically with Whatif and energy minimized with the CHARM program
to reduce side chain crash. Seven structure templates were taken from
the Brookhaven Protein Data Bank (PDB) and used in the modeling work.
The PDB codes are: 1AXH, 1AGG, 1EIT, 1VTX, 1OMN, 1OMG, and 1GUR. The
structure of the Chinese bird spider toxin Huwentoxin-I (1HWT) was
solved recently in our laboratory, but has not been deposited to the PDB. Sequence alignment in Figure 8 was performed taking into account
that three disulfide bridges are conserved among all these peptides.
Antimicrobial Activity Assays
For antifungal activity assays, Alternaria panax,
Fusarium sp., and Rhizoctonia solani, all
soil-borne pathogenic fungi, were first grown on potato-dextrose agar
plates at 28°C until the diameters of the fungal colonies were around
3 cm. The antifungal activities of the samples were assayed using
Oxford cups. Assays for anti-bacterial activity were performed
according to the method of Vivanco et al. (1999) as follows.
Bacillus megaterium and Staphyanococcus sp. cells
were first grown in liquid medium overnight at 30°C. The cultures
were diluted 100-fold and spread on solid medium plates. Whattman
filter papers with a diameter of 0.5 cm were laid on top of the plates
before various amount of the protein samples were added. The plates
were then incubated for 24 h to observe the inhibition zone of the
bacterial growth lawn around the filter papers. For determination of
IC50 (concentration leading to 50% inhibition of
growth rate, in micrograms per milliliter) of Pa-AMP-1 against B. megaterium, Staphyanococcus sp., and E. coli, the bacterial suspension in liquid medium was diluted to an
A600 of 0.05. Pa-AMP-1 at various
concentrations was added to 5-mL aliquots of the cultures. The cultures
were incubated with shaking. The A600
was measured for monitoring bacterial growth.
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RESULTS |
Purification of Pa-AMP-1 and Determination of Its Amino Acid
Residue Sequence
In searching for antifungal proteins from various sources, we
found that the extracts from pokeweed seeds had strong activity against
several soil-borne pathogenic fungi such as A. panax, Fusarium sp., and R. solani. The growth of
R. solani was inhibited by the seed extract and purified
protein (Fig. 1). The purified protein
was also inhibitory to the growth of several gram-positive bacteria
such as B. megaterium and Staphyanococcus sp., as
shown in Table I. The
IC50 of B. megaterium was
approximately 8 µg mL1 (Table I), which is
comparable to that of Mj-AMP-1 (Cammue et al., 1992). The protein was
not inhibitory to the growth of gram-negative bacteria such as E. coli (Table I). The antimicrobial activity was not affected by
high-temperature (90°C) treatment of the extract. We took advantage
of this heat-stable property of the protein in the purification
procedure. The seed extract was first incubated at 90°C for 15 min
before it was centrifuged to remove insoluble materials. The
supernatant was loaded onto a cation exchange column and eluted with a
NaCl gradient from 50 to 500 mM. Two major peaks were obtained (Fig. 2A), and the
antimicrobial activity was associated with peak 2. Fractions of peak 2 were pooled and fractionated with a gel filtration column (Fig. 2B).
Two major peaks (3 and 4) were obtained. The antimicrobial activity was
assayed and found to be associated with peak 4. The purity of the peak
D was evaluated with micro-HPLC equipped with a
C18 column (15 cm × 0.5 mm). Only one peak
(peak 5) was detected (Fig. 2C) and it contained antimicrobial activity. The peak eluted at approximately 30% (v/v) acetonitrile, indicating that this was a small protein molecule (Pa-AMP-1). Peak 3 shown in Figure 2B had no detectable antimicrobial activity.
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Figure 1.
Inhibition of R. solani growth by
pokeweed seed extract and purified AMP. A, Bovine serum albumin in 25 mM HEPES buffer, pH 7.0 (control); B, seed extract; C and
D, supernatant and pellet after the treatment of the seed extract at
90°C and centrifuging, respectively; E, purified Pa-AMP-1.
Approximately 50 µg of protein was added to the Oxford cup, except
cup E, which contained approximately 20 µg of protein.
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Table I.
Effect of Pa-AMP-1 on bacterial growth
Serial dilutions of purified Pa-AMP-1 were added to cultures of the
bacteria listed. The growth rates of the microorganisms were determined
by monitoring the A600, and the IC50
values are given.
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Figure 2.
Purification of Pa-AMP-1 from pokeweed seeds. The
basic and heat-stable protein in supernatant after heat treatment and
centrifugation was the starting material for cation exchange
chromatographic purification (A). Ten milliliters of supernatant was
loaded onto a CM-Sephadex (Sigma) column (2.5 × 30 cm) previously
equilibrated with elution buffer. The flow rate was 25 mL
h1. Fractions in 2 mL were collected and assayed for
antimicrobial activity. The fractions containing antimicrobial activity
(peak 2) were pooled and concentrated before being loaded onto a gel
filtration column (B). The flow rate for the gel filtration was 15 mL
h1, and fractions in 2 mL were collected and assayed for
antimicrobial activity. Peak 4 contained antifungal activity. C,
Micro-HPLC analysis of the purified Pa-AMP-1. Conditions for micro-HPLC
are described in "Materials and Methods."
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The pI of Pa-AMP-1 was estimated with isoelectric focusing gel
electrophoresis and found to be above 10 (data not shown) using egg
white lysozyme as the reference.
To determine its amino acid residue sequence, 100 µg of Pa-AMP-1 was
first reduced with DTT and its Cys residues derivatized. The modified
protein (2 µg) was adsorbed to a PVDF membrane and sequenced with an
automatic sequencer. The entire amino acid sequence was: AGCIK NGGRC
NASAG PPYCC SSYCF QIAGQ SYGVC KNR. The amino acid sequence of Pa-AMP-1
shows that it is rich in Cys residues and highly basic. There are
several basic amino acid residues, while no acidic residue is present
in the protein.
Molecular Cloning of the Gene Encoding Pa-AMP-1
To clone the gene encoding Pa-AMP-1, total mRNA from pokeweed was
first isolated from the seeds. RT-PCR was performed using poly-T
oligonucleotides and a degenerate oligonucleotide designed based on the
amino acid sequence of Pa-AMP-1. A 350-bp fragment was obtained by
RT-PCR. This fragment was cloned into the plasmid pGEM-T and its
nucleotide sequence determined. The sequence revealed that the cloned
fragment indeed contained a open reading frame with a deduced amino
acid sequence identical to that of Pa-AMP-1. To obtain the full length
of the cDNA of Pa-AMP-1, 5'-RACE was performed. A 280-bp fragment was
obtained after amplification of the desired cDNA with PCR. This
fragment was cloned as above and sequenced. The complete cDNA sequence
of the gene encoding Pa-AMP-1 contains an open reading frame of 65 residues (Fig. 3A). The C-terminal
portion of the deduced protein from the 28th to the 65th residue was
identical to the amino acid sequence determined for the Pa-AMP-1
protein. The first 27 residues had characteristic features of a transit
peptide found in excreted proteins (Nakai and Kanehisa, 1992). The
presence of a transit peptide suggests that Pa-AMP-1 is synthesized as
a precursor and processed into its mature form in the process of
secretion (Von Heijne, 1986). The 3'-untranslated region of the gene is
185 nucleotides in length.
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Figure 3.
Nucleotide sequences of Pa-AMP genes. A, cDNA
sequence of the gene encoding Pa-AMP-1. The position of an intron
(GenBank accession no. GI2939456) is indicated by the arrow; B,
sequence alignment of Pa-AMP-1 and Pa-AMP-2 with other AMPs, Mj-AMP-1
and Mj-AMP-2 (De Bolle et al., 1995) and Mc-AMP-1 (GenBank accession
no. AF069321). All Cys residues are conserved and are in bold.
Identical residues are highlighted in gray. The Pa-AMP-1 and Pa-AMP-2
gene sequences have the database accession numbers AF048745 and
AF209857, respectively.
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Based on the cDNA sequence of Pa-AMP-1, a chromosomal DNA fragment
containing the Pa-AMP-1 gene was amplified with PCR in the
presence of Pfu DNA polymerase (Li et al., 1998) to ensure high
fidelity in PCR amplification. The chromosomal gene of Pa-AMP-1 was
nearly 900 bp in length and was cloned and sequenced. We found one
intron located within the transit peptide region.
In sequencing the cloned PCR fragments amplified with primers of poly-T
and the degenerate oligonucleotides based on the N-terminal amino acid
sequence, we found a second cDNA and named it Pa-AMP-2. The deduced
amino acid sequence of Pa-AMP-2 is similar to that of Pa-AMP-1 (Fig.
3B), only seven amino acids of Pa-AMP-1 was conservatively replaced in
Pa-AMP-2.
A database search showed that both Pa-AMP-1 and Pa-AMP-2 are homologous
to the two AMPs isolated from M. jalapa seeds, Mj-AMP-1 and
Mj-AMP-2 (Cammue et al., 1992), and an AMP from Mesembryanthemum crystallinum, Mc-AMP-1 (GenBank accession no. AF069321) (Fig. 3B).
The most striking features of these proteins are that they all contain
six Cys residues, are all conserved in their positions in the primary
sequences, and are all rich in basic amino acid residues.
Southern hybridization was performed to determine how many copies of
the Pa-AMP genes were present in the pokeweed genome, and the results
are shown in Figure 4. Two bands could be
detected when total DNA was digested with two different restriction
enzymes, suggesting that two copies of the genes are present in
pokeweed.
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Figure 4.
Fluorogram of Southern blot hybridized with the
0.5-kb cDNA gene encoding Pa-AMP-1 of pokeweed. Ten micrograms of total
DNA from pokeweed was digested with EcoRI (lane 1) or
XbaI (lane 2) before being subjected to electrophoretic
separation. The sizes of the hybridization bands are indicated with
arrows.
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Localization of Pa-AMPs
To investigate the spatial pattern of the Pa-AMP protein
distribution in pokeweed plant, we performed immunoblotting using polyclonal antibodies against Pa-AMP-1 (Fig.
5A). Proteins showing cross-reaction with
the antibodies could only be detected in mature seeds, not in leaves,
stems, and roots. This result shows that Pa-AMPs are seed specific.
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Figure 5.
Localization of Pa-AMPs in pokeweed by
immunoblotting. A, Immunoblotting with total cell extracts from seeds
(lane 1), leaves (lane 2), roots (lane 3), and stems (lane 4). Lane 5 contains purified Pa-AMP-1. B, Release of Pa-AMP-1 during seed
germination. Seeds were soaked in water overnight before being placed
on a PVDF membrane for 1 (spot 1), 24 (spot 2), and 48 h (spot 3).
The level of Pa-AMPs released from each seed was measured by
immunodetection. About 5 µg of purified Pa-AMP-1 was spotted at spot
4 as a control.
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Analysis of the transit peptide of Pa-AMP-1 using the PSORT program
(Nakai and Kanehisa, 1992) suggests that the protein could either be
secreted out of the cells or into vacuoles. Immunoblotting was
performed to investigate the location of the protein during seed
germination. Pokeweed seeds were first soaked in water for 8 h
before each individual seed was planted on top of a PVDF membrane. The
germinating seeds were removed at various times from the PVDF membrane,
and the Pa-AMPs adsorbed onto the PVDF membrane were detected with
immunoblotting (Fig. 5B). The Pa-AMPs could be detected after the
rupture of the pokeweed seeds, which usually occurred approximately 18 to 24 h after soaking in water, indicating that the Pa-AMPs are
released into the environment of the germinating seed (Fig. 5B). It
is possible that not all Pa-AMPs released from each seed were detected
by this method because the binding of the Pa-AMPs to PVDF membranes
could be weak due to their small size and highly hydrophilic nature.
Some Pa-AMPs could diffuse out of the PVDF membrane.
Determination of the Disulfide Bridges and Three-Dimensional
Modeling of Pa-AMP-1
It has been shown that all Cys residues are involved in disulfide
bridge formation in Mj-AMPs (Cammue et al., 1992), even though the
exact disulfide bridges have not been determined. The fact that all six
Cys residues in these proteins are conserved (Fig. 3) suggests that
they play an important role in their structures. To investigate the
pattern of disulfide bonding within Pa-AMP-1, the protein was
fragmented first chemically with NBS before digestion with trypsin. NBS
specifically cleaves at the peptide bonds formed by Tyr and Trp.
Since there is no Trp residue in the protein, the only peptide bonds
cleaved were at the tyrosal bonds. The chemical fragmentation was
needed because Pa-AMP-1 is resistant to digestion by trypsin, as are
Mj-AMPs (Cammue et al., 1992). The digested products were separated
with micro-HPLC (Fig. 6A), and the
fragments sequenced to determine their N-terminal sequences.
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Figure 6.
Micro-HPLC peptide mapping of Pa-AMP-1. The
protein was first cleaved chemically with NBS before digestion with
trypsin. The peptides were separated with micro-HPLC (A) as described
in "Materials and Methods." B, Detection of a -Ser at the 20th
residue in Pa-AMP-1 sequencing . The protein was loaded to the
sequencer without reduction. The first three Cys residues were linked
to other Cys residues through disulfide bonds and could not be
detected. Based on the results shown in Table I, the detection of the
-Ser at the 20th residue (the fourth Cys) shows that there is a
disulfide bond between Cys-3 and Cys-20.
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The relevant sequence information is summarized in Table
II. The sequence information shown in
peaks 10, 11, and 12 suggests that there is a disulfide bond between
Cys-10 and Cys-24. The N-terminal sequences shown in peak 8 suggest
that there are two disulfide bonds among the three peptides: a pair of
disulfide bonds either between Cys-3 to Cys-19 and Cys-20 to Cys-35 or
between Cys-3 to Cys-20 and Cys-19 to Cys-35. To determine which
pattern is correct in Pa-AMP-1, N-terminal sequencing was performed in the absence of DTT in the step of PTH conversion. The PTH-dehydro-Ala, which is formed from a Cys residue or Ser residue and has
characteristic A313, was detected as
described by Zhang and Liang (1993), and the result is shown in Figure
6B. Because PTH-dehydro-Ala was detected in the twentieth cycle of
sequencing, the first Cys can only be linked to the fourth Cys (the
20th amino acid residue). Based on the above information, the disulfide
bonds of Pa-AMP-1 are Cys-3 to Cys-20, 10 to 24, and 19 to 35.
A database search showed that the disulfide bridge pattern found in
Pa-AMP-1 was also present in some small peptide toxins (Fig.
7). The most obvious feature in all of
the sequences is the pattern of distribution of the six Cys and
disulfide bridges, even though they have a low homology in their
primary amino acid sequences. They all have a pattern of X(0-3)
CX(5-7) CX(5-8) CCX(3-4) CX(4-13) CX(0-12), i.e. they all have a
disulfide bridge pattern of 1 to 4, 2 to 5, and 3 to 6.
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Figure 7.
Sequence alignment of Pa-AMP-1 with eight proteins
of known three-dimensional structure. AXH, Atracotoxin-HVI, a Blue
Mountains funnel-web spider toxin; HWT, huwentoxin-I, a Chinese bird
spider (Selenoicosmia huwena) toxin; AGG,
 -agatoxin-IVb, a funnel-web spider toxin that is a P-type calcium
channel antagonist; EIT, µ-atatoxin-I, a Blue Mountains funnel-web
toxin that is a sodium channel blocker; OMN, -conotoxin-MVIIc, a
magus cone toxin that is a P-type calcium channel antagonist; OMG,
-conotoxin-MVIIa, a Magus cone toxin that is a P-type calcium
channel antagonist; GUR, gurmarin, a sweet-taste-suppressing protein
from Gymnema sykvestre. The structures of all listed
proteins can be accessed in the PDB with the three letter codes.
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The functions and three-dimensional structures of the small peptide
toxins are known and are shown in Figure 7. Structurally, these toxins
belong to the cystine-knot superfamily (Pallaghy et al., 1994).
Comparison of Pa-AMP-1 with the toxins shown in Figure 7 suggests that
Pa-AMP-1 may also belong to this folding group. To help understand the
mechanism of Pa-AMP-1 inhibition of microbial growth and to reveal the
three-dimensional structure of Pa-AMP-1, computer modeling of Pa-AMP-1
was performed (Fig. 8A). The model shows
that the Pa-AMP-1 molecule has a characteristic feature of cystine-knot
folding: disulfide bridges 1 to 4 and 2 to 5, together with the
backbone of the protein, form a ring and the third disulfide
bridge crosses it. Another key feature in this model is the
anti-parallel  -sheets that were found in all template molecules. The
position of the anti-parallel sheets and the disulfide bridges of
Pa-AMP-1 shows that the molecule has a -cross-folding (Pallaghy et
al., 1994). The side chains of three basic residues, Lys-5, Lys-36, and
Arg-38, form a positive patch at one side (top right in Fig. 8A) of the
molecule. On the left side of the molecule, the side chains of three
hydrophobic residues, Phe-25, Ile-27, and Val-34, form a
hydrophobic surface.
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Figure 8.
A, Three-dimensional modeling of Pa-AMP-1. The
NMR coordinates of 1AXH were used to build up the backbone fragments.
Loops were searched against the Whatif built-in loop fragment database.
The modeled structure was refined geometrically within Whatif and
energy minimized with the CHARM program to reduce side chain crash. B,
Superimposition of the constructed model onto eight template molecules
shown in Figure 7.
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The constructed model was superimposed onto eight template molecules
(Fig. 8B), illustrating the structural similarity between Pa-AMP-1 and
all templates. Although the mechanism of Pa-AMP-1 action against
microbial growth is not yet known, the structure of Pa-AMP-1 shows that
it belongs to the inhibitor cystine-knot group (Harrison and Sternberg,
1996).
| |
DISCUSSION |
Seed germination of plants occurs in an environment rich in
pathogens. Many plant seeds contain antifungal and anti-bacterial chemicals. The pokeweed seed Pa-AMP protein reported here is another example of a plant defense system employed against pathogen infection. AMPs in pokeweed, like AMP in M. jalapa, are only
synthesized in mature seeds (Fig. 5A). The cDNA sequence of the
Pa-AMP-1 gene shows the presence of a transit peptide in the protein,
suggesting that it is synthesized as a precursor and processed into its
mature form in secretion. The protein is released outside the seed coat during germination (Fig. 5B). The release of the mature Pa-AMP into
seed germination environment can create an inhibitory zone that
prevents infection of the germinating seeds by pathogens. It has
been shown that the mRNA of AMPs in M. jalapa (De Bolle et
al., 1995) accumulated only in mature seeds, implying that the proteins
are synthesized not only in the process of seed maturation, but also
during germination.
The presence of a second AMP in pokeweed shows that, as in case
of M. jalapa, the AMP genes are also present in a gene
family. Southern hybridization (Fig. 4) showed that the Pa-AMP gene
family has a low complexity. The promoters for these genes are
apparently seed specific. It is interesting that the protein is missing
in roots in both pokeweed, as shown in Figure 5A, and M. jalapa, as shown previously by northern analysis (De Bolle et al.,
1995). This phenomenon could result from the fact that the AMPs are
potent agents against microorganisms. If they were present in plant
roots, they would interfere with root-microbe interactions crucial to plant growth.
There are several basic amino acid residues and no acidic amino
acid residues in the primary sequence of the mature protein (Fig. 3A),
showing that it is a basic protein. The isolation of Pa-AMP-1 with a
cation exchange column (Fig. 2) also shows that the Pa-AMP-1 is a basic
protein. The pI of Pa-AMP-1 was estimated to be above 10, higher than
the value predicted by computer analysis based on its primary sequence.
The difference could be due the special folding of the protein, which
could result in a more basic pI of Pa-AMP-1. The basic amino acid
residues are conserved in different AMPs (Fig. 3B). De Samblanx et al.
(1997) showed that replacing Val-39 with the basic Arg increased the
potency of antifungal protein from radish seeds (Rs-AFP1) (Terras et
al., 1995) against fungi, while replacing Lys-44 with a neutral amino
acid residue decreased the potency. It is likely that the basic
residues are important to the functions of these small, Cys-rich AMPs.
We have recently overproduced an active Pa-AMP-1 protein in E. coli (Y. Liu and J. Zhao, unpublished data). Site-specific
mutagenesis of the gene should provide more information about what
roles the positive residues have in antimicrobial activities.
Recently, the three-dimensional structures of several antifungal
proteins, including the plant defensin from radish seeds (Fant et al.,
1998) and  -thionin from sorghum (Bloch et al., 1998), have been
determined. Both Rs-AFP1 and -thionin have one  -helix and
triple-stranded -sheets. Although the mechanism of their antifungal
activity is still unknown, the importance of a hydrophobic surface and
a positive patch has been suggested (Bloch et al., 1998). The
biochemical basis of the antimicrobial activity of Pa-AMP-1 has not
been revealed. We have not found any effect of Pa-AMP-1 on -amylase
and subtilisin activity (Y. Liu and J. Zhao, unpublished data). Cammue
et al. (1992) showed that all six Cys residues are involved in
disulfide bridges in Mj-AMP. Sequence comparison of the AMPs (Fig. 4)
shows that all six Cys residues are conserved, indicating that the
formation of these intramolecular disulfide bonds is important to
structure and function.
In the present study, we have shown that the three intramolecular
disulfide bridges have a pattern of 1 to 4, 2 to 5, and 3 to 6, a
folding pattern found in many toxin proteins (Harrison and Sternberg,
1996). The three-dimensional model suggests that Pa-AMP-1 has a
different structure from both the antifungal protein of radish seeds
(Fant et al., 1998) and the -thionin (Bloch et al., 1998). Our
three-dimensional modeling of Pa-AMP-1 suggests that it belongs to the
inhibitor cystine-knot group, one of the most compact and stable
protein-folding motifs (Harrison and Sternberg, 1996). Stable folding
is very critical to seed protein, since most of the seeds desiccate
during maturation, which could denature most of unstable proteins. The
model also suggests the presence of a hydrophobic surface and a
positive patch on Pa-AMP-1 (Fig. 8). It is possible that Pa-AMP-1 could
interact with the phospholipids of cell membranes, resulting in
inhibition of fungal growth. Since Pa-AMP-1 is only inhibitory toward
filamentous fungi and gram-positive bacteria, and has no inhibitory
effect on gram-negative bacteria or yeast (Table I), it is likely that
AMPs may specifically interact with membrane receptors rather than
non-specifically binding to cell membranes (Thevissen et al., 1997).
The positive patch of AMPs could provide the specific site for the
interaction through ionic interactions. This suggestion is supported by
the fact that the potency of Mj-AMPs was drastically reduced under high
ionic strength (Cammue et al., 1992).
So far, AMPs have only been found in the seeds of pokeweed,
M. jalapa (De Bolle et al., 1995), and M. crystallium (GenBank accession no. AF069321), and these three
plants are not closely related phylogenetically. The presence of a
small gene family in both M. jalapa and pokeweed, and the
fact that the chromosomal genes from M. jalapa and pokeweed
contain one intron located similarly in the signal peptide region
suggest the possibility that these AMP genes were possibly conserved
during evolution and may be present in some other plant seeds as
well. We are currently testing this possibility using immunoblotting.
| |
ACKNOWLEDGMENTS |
The authors thank Profs. X. Wu and P. Xiao for their suggestions
in this research. The technical assistance of W. Shen is appreciated.
| |
FOOTNOTES |
Received August 16, 1999; accepted December 15, 1999.
1
This research was supported by the Chinese
National Natural Science Foundation (grant no. 39535002) and by the
Department of Science and Technology (grant no. J99-A-032).
*
Corresponding author; e-mail jzhao{at}pku.edu.cn; fax
86-10-6275-6421.
| |
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TOP
ABSTRACT
INTRODUCTION