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cDNA library for mining functional genes in Sedum alfredii Hance related to cadmium tolerance and characterization of the roles of a novel SaCTP2 gene in enhancing cadmium hyperaccumulation Mingying Liu, Xuelian He, Tongyu Feng, renying zhuo, Wenmin Qiu, Xiaojiao Han, Guirong Qiao, and Dayi Zhang Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.9b03237 • Publication Date (Web): 26 Aug 2019 Downloaded from pubs.acs.org on August 27, 2019
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Environmental Science & Technology
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cDNA library for mining functional genes in Sedum alfredii Hance
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related to cadmium tolerance and characterization of the roles of a
3
novel SaCTP2 gene in enhancing cadmium hyperaccumulation
4
Mingying Liu1,2,3,*, Xuelian He1,2, Tongyu Feng1,2, Renying Zhuo1,2,*, Wenmin Qiu1,2,
5
Xiaojiao Han1,2, Guirong Qiao1,2, Dayi Zhang4,*
6
1. State Key Laboratory of Tree Genetics and Breeding, Xiangshan Road, Beijing
7
100091, P.R. China
8
2. Key Laboratory of Tree Breeding of Zhejiang Province, Research Institute of
9
Subtropical of Forestry, Chinese Academy of Forestry, Hangzhou 311400, P.R. China
10
3. School of Basic Medical Sciences, Zhejiang Chinese Medical University,
11
Hangzhou 310053, P.R. China
12
4. School of Environment, Tsinghua University, Beijing 100084, P.R. China
13
*Corresponding authors:
14
Dr Mingying Liu
15
School of Basic Medical Sciences, Zhejiang Chinese Medical University, Hangzhou
16
310053, P.R. China; Tel, +86-(0)571-63311860; E-mail:
[email protected] 17
Prof Renying Zhuo
18
Key Laboratory of Tree Breeding of Zhejiang Province, Research Institute of
19
Subtropical of Forestry, Chinese Academy of Forestry, Hangzhou 311400, P.R.
20
China; Tel, +86-(0)571-63311860; E-mail:
[email protected] 21
Dr Dayi Zhang
22
School of Environment, Tsinghua University, Beijing 100084, P.R. China; Tel,
23
+86-(0)10-62773232; E-mail:
[email protected] ACS Paragon Plus Environment
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Table of Contents
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For TOC only
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Abstract
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Heavy metal contamination presents serious threats to living organisms. Functional
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genes related to cadmium (Cd) hypertolerance or hyperaccumulation must be
30
explored to enhance phytoremediation. Sedum alfredii Hance is a Zn/Cd
31
cohyperaccumulator exhibiting abundant genes associated with Cd hypertolerance.
32
Here, we developed a method for screening genes related to Cd tolerance by
33
expressing a cDNA-library for S. alfredii Hance. Yeast functional complementation
34
validated 42 of 48 full-length genes involved in Cd tolerance, and the majority of
35
them were strongly induced in roots and exhibited diverse expression profiles across
36
tissues. Coexpression network analysis suggested that 15 hub genes were connected
37
with genes involved in metabolic process, response to stimuli, metal transporter and
38
antioxidant activity. The functions of a novel SaCTP2 gene were validated by
39
heterogeneous expression in Arabidopsis, responsible for retarding chlorophyll
40
content decreases, maintaining membrane integrity, promoting reactive oxygen
41
species (ROS) scavenger activities and reducing ROS levels. Our findings suggest a
42
highly complex network of genes related to Cd hypertolerance in S. alfredii Hance,
43
accomplished via the antioxidant system, defense gene induction and the calcium
44
signaling pathway. The proposed cDNA-library method is an effective approach for
45
mining candidate genes associated with Cd hypertolerance to develop gene-modified
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plants for use in phytoremediation.
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Key words: Sedum alfredii Hance, cDNA library, cadmium, hypertolerance,
48
hyperaccumulation, yeast functional complementation
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1. Introduction
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Heavy metals are categorized as either essential elements with clear biological
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functions (e.g., Fe, Mo, Mn, Zn, Ni, Cu and Co) or nonessential elements without
54
known roles in living organisms (e.g., As, Ag, Hg, Sb, Cd and Pb) 1. They are
55
potentially toxic depending on their bioavailable concentrations and receptor
56
exposure-sensitivity
57
valence state of ions (e.g., Hg, Pb and Cd) are deemed pose a greater threat because
58
they can be taken up and utilized by plants via the existing mineral uptake channels 3,
59
4.
60
has aroused attention worldwide 5. Phytoremediation is an approach utilizing naturally
61
occurring or genetically engineered plants to remove contaminants from polluted soils
62
and waters
63
plumbizincicola
64
decontaminating metal-polluted soils. The practical application of hyperaccumulators
65
suffers from their relatively low biomass and slow growth rates, restricting the
66
feasibility of their use in phytoremediation engineering 13, 14. The genetic engineering
67
of high-biomass plants with genes related to metal tolerance and accumulation
68
sourced from hyperaccumulators is an alternative for phytoremediation applications 8,
69
15.
70
tolerance in hyperaccumulators and to mine genes responsible for the uptake,
71
accumulation, volatilization and detoxification of metals as valuable biological
72
resources.
73
The hyperaccumulating ecotype (HE) of Sedum alfredii Hance is a native
74
non-Brassicaceae Zn/Cd cohyperaccumulator inhabiting the deserted Pb/Zn mining
75
area of Quzhou in Zhejiang Province, China 10, 16. S. alfredii Hance can accumulate up
76
to 6,500 μg/g (dry weight, DW) of Cd and 29,000 μg/g (DW) of Zn in its stems
77
without displaying significant toxicity symptoms, and the Cd concentration can reach
78
9000 μg/g (DW) in leaves
79
system to protect the plants from the deleterious effects of excess toxic metals. The
80
detoxification system is highly dependent on the expression of key genes related to
81
metal hypertolerance. Previous studies have identified several genes related to Cd
82
sequestration, detoxification and tolerance
83
approaches, such as transcriptomics and proteomics, have been routinely applied to
2, 3.
Among these metals, those resembling nutrients in the
Accordingly, the question of how to efficiently mitigate heavy metal contamination
6-9,
and hyperaccumulating plants such as Sedum alfredii 11,
Noccaea spp. and Arabidopsis halleri
12
10,
Sedum
have been employed for
It is therefore necessary to elucidate the mechanisms of metal accumulation and
10, 16,
indicating the existence of a powerful detoxification
17-22.
Additionally, some high-throughput
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decipher
the
regulatory
networks
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hyperaccumulation of S. alfredii Hance, providing a more precise map of the global
86
network in response to Cd stress
87
small RNAs and the degradome elucidated the regulatory roles of miRNAs and their
88
targets in the HE of S. alfredii, revealing 39 pairs of miRNA targets displaying
89
negatively correlated expression profiles 23. Transcriptomic comparisons between two
90
contrasting ecotypes of S. alfredii identified 57 conserved and 18 divergent
91
orthologous genes, and the latter group mainly participated in the processes of signal
92
transduction, transcription regulation, the stress response and protein metabolism
93
Nevertheless, there is a lack of experimental evidence validating the actual functions
94
of enzymes encoded by these identified genes in the tolerance of Cd stress. The
95
mechanisms of Cd hyperaccumulation and hypertolerance are still obscure, and the
96
characterization of vital genes related to these traits is of great urgency.
97
Conventional approaches confirming the evident functions of genes have relied on the
98
generation of loss-of-function and gain-of-function mutant resources but suffer from
99
inherent drawbacks. For example, a gene family knockout mutation might only result
23-25.
involved
in
the
hypertolerance
and
An integrated analysis of the transcriptome,
26.
24.
100
in marginal differences from the wild type as a result of gene redundancy
101
common problem related to activation-tagged mutagenesis is the nonspecific
102
activation of genes by a transcriptional enhancer, and the upregulated transcription of
103
several genes results in complex phenotypes in some cases, making the identification
104
of target genes responsible for the observed mutant phenotypes challenging
105
circumvent these problems and systematically analyze gain-of-function mutations,
106
ectopic expression of a full-length cDNA library is an alternative for obtaining
107
information from the mRNA of a particular tissue or organism.
108
The construction of a full-length cDNA library for mature mRNAs facilitates gene
109
function characterization and enables manipulation of gene expression in
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heterologous systems by generating tagged versions of a native protein 28, 29. Ichikawa
111
developed a novel gain-of-function tool referred to as the FOX (Full-length cDNA
112
Overexpressing) hunting system by exploiting an fl-cDNA collection from
113
Arabidopsis
114
Agrobacterium transformation and analyze gene functions in rice 31. A cDNA library
115
from tobacco roots acclimated to Cd using a Cd-sensitive yeast mutant (Δycf1) was
116
employed to successfully screen and identify a series of candidate genes involved in
30
27.
A
To
to heterologously express rice fl-cDNAs in Arabidopsis via
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the response to Cd stress 32. A similar study revealed 53 transgenic yeast clones with
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increased salt tolerance by expressing a cDNA library from high-salt-treated Atriplex
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canescens 33. However, there have been no previous studies in which a cDNA library
120
was constructed for S. alfredii Hance to screen genes related to Cd hypertolerance and
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hyperaccumulation.
122
In the present study, we constructed a cDNA library for the S. alfredii Hance response
123
to Cd stress, and we characterized forty-eight genes linked with Cd tolerance and
124
validated the functions of the SaCTP2 gene in Cd hypertolerance and
125
hyperaccumulation through heterologous expression in Arabidopsis. Our work
126
attempts to offer a plausible and efficient tool for the batch mining of functional genes
127
associated with the Cd response and to provide insights into the mechanism of Cd
128
hypertolerance, which is a highly complex process associated with ROS balance,
129
cellular hemostasis, antioxidant defense and the calcium signaling pathway. The
130
characterized Cd-responding or detoxification genes in S. alfredii Hance are
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applicable in the breeding of genetically modified plants for Cd phytoremediation.
132 133
2. Materials and methods
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2.1. Plant materials and Cd stress treatment for cDNA library construction
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Seedlings of the HE of S. alfredii Hance were vegetatively propagated and cultured
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hydroponically for root growth at 25 °C under long days (16 hr light/8 hr dark each
137
day) in an artificial climate chamber for 2 weeks. To extract mRNA from S. alfredii
138
Hance under Cd stress and construct the full-length cDNA library, uniform, healthy
139
rooted seedlings were cultivated in Hoagland-Arnon solution supplemented with
140
CdCl2 (400 μM) for 24 hr. Three tissues (whole roots; the middle part of stems; young
141
leaves, Figure S1C) were then collected separately and immediately frozen in liquid
142
nitrogen for RNA extraction. Wild-type Arabidopsis thaliana plants (Col-0) were
143
grown in another artificial chamber under a 16 hr light/8 hr dark regime at 22 °C for
144
40 days before transformation.
145
2.2. RNA extraction and S. alfredii Hance cDNA library construction
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Total RNA was extracted from the tissues of S. alfredii Hance after 24 hr of exposure
147
to Cd using the Total RNA Purification Kit (Norgan Biotek Corp., Thorold, ON,
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Canada) and treated with RNase-free DNase I (NEB BioLabs, Ipswich, MA, USA) to
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remove genomic DNA. The quality of RNA was assessed by agarose gel
150
electrophoresis, and the RNA concentration was quantified with a NanoDrop2000
151
spectrophotometer (Thermo Scientific, Wilmington, DE, USA). Double-stranded
152
cDNA (dsDNA) was synthesized using the SMART™ cDNA Library Construction
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Kit (Clontech Laboratories Inc., CA, USA) with minor modifications (for details, see
154
Electronic Supporting Information, ESI), then checked by agarose gel electrophoresis,
155
subjected to proteinase K digestion, digested with SfiI (New England Biolabs Inc.,
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USA), and size fractionated with CHROMA SPIN-400 columns (Clontech
157
Laboratories Inc., USA). It was then ligated into the pYES2-SfiI vector (details see
158
ESI) overnight (approximately 12 hr) at 16 °C, which was subsequently transferred
159
into E. coli JM109 cells by electroporation. Successful transformants were selected on
160
Luria-Bertani (LB) agar plates supplemented with 100 µg/mL ampicillin as the cDNA
161
library.
162
2.3. Yeast transformation, screening and annotation of the S. alfredii Hance
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cDNA library
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We employed the Cd-sensitive mutant yeast strain Saccharomyces cerevisiae Δycf1
165
(BY4741; MATa; ura3Δ0; leu2Δ0; his3Δ1; met15Δ0; YDR135c::kanMX4; Y04069)
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as the heterologous host expressing the cDNA library of S. alfredii Hance. Briefly, the
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plasmids extracted from the cDNA library were transformed into Δycf1 by the lithium
168
acetate method
169
half-strength synthetic dextrose agar plates lacking uracil (SG-Ura) and supplemented
170
with CdCl2 (40 µΜ) and were cultured for 3-5 days at 28 °C. The surviving clones
171
were picked and cultured in 10 mL of liquid SG-Ura medium with shaking at 200 rpm
172
at 28 °C. After centrifugation, the cell pellets were treated with lyticase (50 U/µL,
173
Sigma-Aldrich, St. Louis, MO, USA) and sorbitol (1.0 M) to obtain protoplasts,
174
which were further lysed with NaOH (200 mM) and sodium dodecyl sulfate (SDS, 10
175
g/L). Subsequently, the plasmids were extracted and analyzed by PCR with the
176
universal primer pair T7 and pYES2-R (Table S1) to confirm the inserts in the
177
pYES2-SfiI vector. Yeast cells containing the empty vector (Δycf1_EV) were used as a
178
negative control. In total, 127 plasmids were sequenced with an automatic sequencing
179
machine (ABI, Columbia, MD, USA). All the sequences were filtered by SeqScanner
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to remove the leading vector, tailing and poor-quality sequences, and repeated
34.
Yeast transformants were selected on 2% galactose-containing
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transcripts. The qualified sequences were subjected to BlastX analysis against the
182
nonredundant protein database of the National Center for Biotechnology Information
183
(NCBI). The full-length sequences were submitted to Simple Modular Architecture
184
Research Tool (SMART) and the protein families (Pfam) database for the annotation
185
of domain structure.
186
The functions of the full-length sequences were reevaluated by reconstructing the
187
exact open reading frame (ORF) of the cDNA amplified with the primers (Table S1)
188
in the yeast expression vector pYES2.1/V5-His-TOPO (Invitrogen, Carlsbad CA,
189
USA). The ligation products were transformed into competent TOP10 One Shot® E.
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coli (Invitrogen, Carlsbad CA, USA), and the positive clones observed on LB agar
191
plates supplemented with 100 μg/mL ampicillin were sequenced by using the GAL1
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Forward and V5 C-term Reverse universal primer pair (Table S1). The recombinant
193
plasmids were then transformed into Δycf1 to evaluate their tolerance to Cd. Briefly,
194
the transgenic yeast lines expressing candidate full-length cDNAs were grown in
195
SG-Ura medium overnight at 28 °C until the optical density at 600 nm (OD600)
196
reached 1.0, followed by serial dilution and spotting on SG-Ura agar plates in the
197
absence or presence of CdCl2 (40 µM) and incubation at 28 °C for 3 days before
198
taking photographs.
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2.4. Expression profiles of screened genes under Cd stress
200
To assess the expression profiles of the screened genes in response to Cd stress in S.
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alfredii Hance, RNA was extracted from three tissues of S. alfredii seedlings (whole
202
roots; the middle part of stems; young leaves) subjected to Cd stress (400 μM) for 1,
203
12 or 24 hr. Untreated S. alfredii seedlings were used as a negative control. The
204
reverse transcription reactions were performed using the Superscript III First-Strand
205
Synthesis system, followed by RNase H treatment (Invitrogen, Carlsbad, CA, USA).
206
The primers (Table S1) for the target genes were designed using the online Primer3
207
program (http://frodo.wi.mit.edu/primer3/). Beta-tubulin (TUB) was selected as the
208
reference 35. Reverse transcription quantitative polymerase chain reaction (RT-qPCR)
209
was performed in 96-well plates using a SYBR PrimeScriptTM Kit (TaKaRa, Dalian,
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China) in a 7300 Real-Time PCR System (Bio-Rad, Hercules, CA, USA). The
211
amplification procedure and data analysis followed a previous study
212
reactions were carried out in triplicate.
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2.5. Construction of the coexpression network
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On the basis of comparative transcriptome sequencing under Cd stress and a
215
coexpression regulatory network generated through weighted gene coexpression
216
network analysis (WGCNA)
217
interconnections were defined as hub genes potentially associated with the Cd
218
response. All the screened transcripts belonging to these hub genes were analyzed for
219
their correlation with other annotated genes. The Pearson correlation coefficients of
220
the FPKM (fragments per kilobase of exon per million reads mapped) values for each
221
gene pair were calculated using R software
222
coefficients above 0.40 were classified by their annotations. All correlations were
223
visualized using Cytoscape v3.6.1 and analyzed using the NetworkAnalyzer plugin in
224
Cytoscape.
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2.6. Heterologous expression of the SaCTP2 gene in Arabidopsis
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An uncharacterized gene from the cDNA library, SaCTP2, was selected due to
227
showing the strongest ability to alleviate the Cd sensitivity of transformed yeasts
228
among all 5 uncharacterized genes. This gene was transformed into Arabidopsis to
229
validate its roles in Cd tolerance and accumulation. First, a preliminary bioinformatic
230
analysis including a BlastX analysis against the NCBI nonredundant protein database
231
and phylogenetic clustering was performed. All the homologous proteins (Table S2,
232
ESI) were subjected to phylogenetic and conserved domain analysis. The
233
phylogenetic tree was constructed by using MEGA7.0
234
iTOL tool (http://itol.embl.de)
235
with the Pfam database and depicted with Illustrator for Biological Sequences (IBS)
236
software 40.
237
For the ectopic expression of the SaCTP2 gene in Arabidopsis to validate its roles in
238
Cd tolerance and accumulation, the ORF of the SaCTP2 gene was amplified by PCR
239
using High-Fidelity KOD-Plus DNA Polymerase (Toyobo, Japan) with the specific
240
primer set listed in Table S1. The purified PCR products were cloned into the
241
Gateway entry vector pENTR/D-Topo (Invitrogen, Carlsbad, USA), and positive
242
plasmids with the correct direction and sequence were recombined in pH2GW7.0 to
243
generate the plant overexpression vector pH2GW7.0-SaCTP2. The vector was then
244
transformed into Agrobacterium tumefaciens strain EHA105, and the positive strains
23,
39.
numerous coexpressed genes with strong
37.
All the edges with correlation
38
and visualized by using the
The conserved domain distribution was predicted
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were used to transfect A. thaliana ecotype Columbia plants via the floral dip method
246
41.
247
confirmed by PCR using the first-strand cDNA synthesized from the total RNA
248
extracted from the young leaves of transgenic and WT plants with gene-specific
249
primers
250
5’-TCAAGCGACTTGAATTG-3’). The PCR program was as follows: denaturation
251
at 94 °C for 5 min, 30 cycles of amplification (94 °C for 30 s, 55 °C for 30 s, and
252
72 °C for 60 s), and a final cycle of 72 °C for 7 min. Homozygous lines (T3
253
generation) characterized by nonsegregation were used for Cd stress treatment.
254
2.7. Physiological and chemical analyses of SaCTP2 transgenic lines under
255
Surviving transformants selected with hygromycin (Hyg, 20 µg/mL) were further
(SaCTP2O-F,
5’-ATGGCTTCCGGCACGTTC-3’;
SaCTP2O-R,
Cd stress
256
The Cd treatment of juvenile and adult Arabidopsis plants was performed separately
257
to elucidate the growth and physiological differences between WT and SaCTP2
258
transgenic plants under Cd stress. For juvenile seedling treatment, seeds of wild-type
259
(WT) A. thaliana and three homozygous A. thaliana lines expressing the SaCTP2
260
gene (OE-1, OE-2 and OE-3) were germinated and grown vertically in half-strength
261
Murashige and Skoog (MS) medium with or without CdCl2 (50 µM) for 10 days after
262
stratification (4 °C for 48 hr in dark). Approximately 15-20 individuals were then
263
collected from each treatment to measure their root length, fresh weight, dry weight
264
and metal contents. All the treatments were carried out in triplicate.
265
For the Cd treatment of adult Arabidopsis seedlings, four-leaf-stage wild-type (WT)
266
and SaCTP2-expressing Arabidopsis seedlings (OE-1, OE-2 and OE-3) were exposed
267
to Hoagland-Arnon solution supplemented with or without CdCl2 (30 µM) for 7 days.
268
Healthy young leaves of the WT and SaCTP2-expressing Arabidopsis seedlings were
269
sampled on day 0 before Cd exposure and day 7 after Cd treatment. Electrolyte
270
leakage (%) was calculated on the basis of conductivity measurements
271
assessment of enzyme activities (U/g protein), 1.0 g of leaf tissue was harvested from
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Arabidopsis seedlings and homogenized in 8 mL of sodium phosphate buffer (PBS,
273
50 mM, pH=7.8) using a prechilled mortar and pestle, followed by centrifugation at
274
10,000 ×g for 15 min at 4 °C. The supernatant was then used to measure O2•- levels
275
and the activities of superoxide dismutase (SOD, EC 1.15.1.1), peroxidase (POD,
276
EC1.11.1.7) and catalase (CAT, EC 1.11.1.6)
43, 44.
42.
For the
The contents of malondialdehyde
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(MDA) and H2O2 were determined as described previously 45.
278
The accumulation of H2O2 and O2∙- (μmol/g FW) in rosette leaves was visualized by
279
diaminobenzidine (DAB) and nitrotetrazolium blue chloride (NBT) staining as
280
described previously
281
separately with DAB and NBT and destaining was conducted overnight in absolute
282
ethanol. Chlorophyll contents (mg/g FW) were measured as described by Arnon with
283
minor modifications 46. Approximately 0.1 g of leaf tissue was incubated in 5 mL of a
284
mixture of ethanol and acetone (1:2, v/v) for 48 hr in the dark. The absorbance at 665
285
and 649 nm (OD665 and OD649) was measured using a DU 800 UV/Vis
286
spectrophotometer (Beckman Coulter, California, CA, USA) following Equations (1)
287
and (2).
22.
Staining was processed by overnight treatment of leaves
288
Chla = (12.72 × OD665 ―5.59 × OD649) × V × N/(1000 × W) (1)
289
Chlb = (22.88 × OD649 ―4.67 × OD665) × V × N/(1000 × W) (2)
290
where V, N and W refer to the volume of the reaction system (5 mL), the dilution
291
factor (1.0) and the fresh weight (FW) of leaves (g), respectively.
292
Cd-treated seedlings (WT and SaCTP2 transgenic plants) were first resorbed using
293
ethylenediamine tetraacetic acid (EDTA, 10 mM) for 30 min and washed thoroughly
294
with distilled water. The roots and stems were then separated, dried at 105 °C for 30
295
min and kept at 70 °C until reaching a constant weight. These samples were next
296
digested with a concentrated acid mixture of HNO3, HClO4 and H2SO4 (4:1:0.5,
297
v:v:v) at 250 °C for 8 h. Zn or Cd concentrations (mg/kg DW or μg/plant) in the
298
digested solution were determined with an inductively coupled plasma-mass
299
spectrometer (ICP-MS; NexION 300; PerkinElmer). All the treatments were
300
performed in triplicate, and each replicate consisted of twelve Arabidopsis seedlings.
301
2.8. Statistical analysis
302
The presented data are the mean ± standard deviation (SD) from all the replicates. All
303
statistical analyses were carried out by using SPSS v17.0 software (SPSS Inc.,
304
Chicago, IL, USA). Significant differences between the WT and three transgenic lines
305
of A. thaliana was determined with Student’s t-tests, and significant differences are
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indicated by different small letters in the figures.
307 308
3. Results
309
3.1 Functional screening of the cDNA library of S. alfredii Hance with a
310
Cd-sensitive yeast mutant
311
In total, 127 individual yeast clones that survived on SG-Ura medium supplemented
312
with Cd (40 μM, 2% galactose) were obtained. Excluding those clones with
313
noncoding RNA or poor quality or nonreferenced sequences, there were 92
314
recombinant plasmids with cDNA insertions from S. alfredii Hance, including 48
315
full-length cDNAs (Table 1) and 44 partial cDNA sequences (not shown). All 48
316
full-length genes were annotated with BLAST and functionally categorized according
317
to their homologs (Figure 1A and Table 1). Among these genes, only one gene was
318
associated with stress signal perception (SaPERK3), which encodes a proline-rich
319
receptor-like protein kinase. Regarding signal transduction, the two genes involved in
320
calcium signaling are SaCaM and SaCIPK8. All the remaining 45 genes are
321
associated with detoxification, including metal homeostasis (9, SaPCS, SaHIPP,
322
SaMTPl1, SaMTPl2, SaMT3, SaCoPA, SaNTR, SaVIT and SaCys), transcription
323
regulation (3, SaHSF, SaERF and SaWRKY), the epigenetic response (3, SaH2A,
324
SaRPL24 and SaRPS29), ROS homeostasis (11, SaPRX, SaTRX, SaGST, SaFA2H,
325
SaF3H, SaUSPl, SaSAP, SaPOD, SaNQO, SaAPX and SaAPX1), cellular pH and
326
osmotic homeostasis (3, SaGRP, SaPPlase and SaAQP), and stress tolerance and
327
adaption (16, SaCTP1-5, SaGELP, SaMS1, SaCtns, SaChi, SaMYR, SaTLP3, SaDRP,
328
SaAIR6B, SaLHC6A, SaPCCR and SaDRT100). It is worth mentioning that 5 novel
329
genes were previously uncharacterized, and these genes were designated as SaCTP
330
(Cadmium Tolerance Protein) genes, which might be unique to S. alfredii Hance.
331
After reconstruction in the yeast expression vector pYES2.1/V5-His-TOPO, the
332
functions of the 48 full-length transcripts in tolerating Cd were validated and are
333
illustrated in Figure 2. Forty-two yeast cell lines expressing candidate genes exhibited
334
significantly better growth than the control (Δycf1_EV), particularly for those related
335
to metal homeostasis (SaPCS, SaHIPP, SaMTPl1, SaMTPl2 and SaMT3), ROS
336
homeostasis (SaPRX, SaGST, SaF3H, SaUSPl, SaSAP, SaPOD, SaNQO, SaAPX and
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SaAPXl), cellular osmotic homeostasis (SaGRP and SaAQP) and transcription
338
regulation (SaHSF and SaERF). Two of the five novel genes (SaCTP1 and SaCTP2)
339
remarkably alleviated the Cd sensitivity of transformed yeasts.
340
3.2 Candidate genes responding to Cd stress as predicted by the coexpression
341
network
342
The reconstructed gene coexpression network identified 15 out of the 48 full-length
343
genes as hub genes strongly affected by Cd stress, exhibiting 867 nodes and 2,361
344
connections (Figure 1B). They were associated with signal perception (SaCaM),
345
transcription regulation (SaWRKY), ROS homeostasis (SaPRX and SaFA2H), metal
346
homeostasis (SaCys, SaMTPl1, SaMT3, SaHIPP and SaNTR), and stress and tolerance
347
adaption (SaGRP, SaLHC6A, SaAIR6B, SaCTP2 and SaCTP3). These hub genes were
348
mainly linked with metabolic processes (GO:0008152), cellular processes
349
(GO:0009987), biological regulation (GO:0065007) and five other categories
350
(response to stimuli, transcription factor, transporter activity, antioxidant activity and
351
molecular function regulator). SaPRX (471 edges) and SaAIR6B (431 edges)
352
presented the highest degrees. Two novel SaCTP2 and SaCTP3 genes also behaved as
353
hub genes, with 144 and 27 edges, respectively.
354
3.3 Responses of candidate genes to Cd stress
355
The inducible expression of candidate genes under Cd stress resulted in diverse
356
profiles according to RT-qPCR assays (Figure S1A, ESI). For most genes, obvious
357
positive induction was observed in roots, with strong increases across the three time
358
points. In contrast, the expression of almost all genes was downregulated in stems,
359
and elevated expression appeared for a small proportion of the genes in leaves after 12
360
hr and 24 hr of exposure. In roots, most of the genes showing strong, instant induction
361
by Cd stress belonged to the categories associated with stress tolerance and adaption
362
(SaCTP1, SaCTP2, SaCTP3, SaLHC6A and SaDRT100), and the others were
363
associated with ROS homeostasis (SaF3H), metal homeostasis (SaNTR1), cellular pH
364
and osmotic homeostasis (SaAQP), and stress tolerance and adaption (SaMS1). Some
365
genes associated with metal homeostasis (SaVIT1), transcription regulation (SaERF),
366
ROS homeostasis (SaAPXl and SaTRX), and stress tolerance and adaption (SaGELP)
367
showed stepwise elevation. In stems, all genes were downregulated except for four
368
genes that were induced at 1 hr (SaERF, SaCys, SaLHC6A and SaAQP) and two genes
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that were induced at 6 hr (SaCtns and SaCIPK8).
370
In leaves, only three genes related to stress tolerance and adaption (SaCTP3,
371
SaLHC6A and SaDRT100) exhibited moderate elevation in the early stage (1 hr),
372
whereas 12 genes that were strongly upregulated after 12 and 24 hr were associated
373
with signal perception (SaPERK3), metal homeostasis (SaHIPP and SaVIT1),
374
transcription regulation (SaHSF and SaWRKY), the epigenetic response (SaRPS29 and
375
SaH2A), ROS homeostasis (SaF3H and SaNQO), cellular pH and osmotic
376
homeostasis (SaGRP), and stress tolerance and adaption (SaCTP1 and SaAIR6B). It is
377
worth mentioning that most of the hub genes (Figure 1B) were not significantly
378
induced postexposure to Cd stress.
379
The tissue expression profiles of 48 genes are illustrated in Figure S1B. Ten genes
380
that were highly expressed in roots were only associated with calcium signaling
381
(SaCaM), signal perception (SaPERK3), metal homeostasis (SaMTPl1), ROS
382
homeostasis (SaUSPl and SaAPX), epigenetic response (SaRPS29 and SaRPL24), and
383
stress tolerance and adaption (SaCtns, SaCTP3 and SaDRP). Eleven genes that
384
showed high expression only in stems were related to metal homeostasis (SaCoPA,
385
SaHIPP, SaNTR1, SaVIT1), ROS homeostasis (SaTRX, SaF3H and SaFA2H), and
386
stress tolerance and adaption (SaMS1, SaChi). Almost all genes that were only highly
387
expressed in leaves were associated with stress tolerance and adaption, including
388
SaCTP2, SaCTP4, SaGELP, SaDRT100, SaLHC6A, SaRCCR and SaTLP3. Among all
389
genes, only the SaCTP3 gene was strongly induced and highly expressed in roots
390
postexposure to Cd.
391
3.4 Transgenic SaCTP2-expressing Arabidopsis lines displayed Cd tolerance
392
and accumulation
393
The SaCTP2 gene has a full-length of 300 bp and encodes a protein of 99 amino acids
394
with an approximate molecular mass of 11.08 kDa (Figure 3A). Conserved domain
395
analysis showed the presence of a FCS-like C2-C2 zinc-finger domain (FLZ,
396
pfam04570) from residue 25 to residue 64 (Figure 3B), characterized by the
397
consensus cysteine-signature sequence acting as a protein-protein interaction module
398
47, 48.
399
third cysteine are indicated by asterisks in Figure 3A. Phylogenic analysis showed
400
that SaCTP2 clustered with a hypothetical protein (GenBank accession number:
Conserved residues such as phenyl alanine and a serine residue associated with a
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RAL53989.1) from Cuscuta australis in the family Convolvulaceae (Figure 3C).
402
The results from the coexpression network suggested that the novel SaCTP2 gene
403
interacted with other genes related to the metabolic process, cellular process and
404
response to stimulus categories (Figure 1B), alleviating the Cd sensitivity of
405
transformed yeasts (Figure 2). It was also significantly induced postexposure to Cd
406
(Figure S1) and, thus, was selected and transformed in Arabidopsis to validate its
407
roles in Cd tolerance. In the absence of Cd, the WT and SaCTP2-expressing
408
Arabidopsis lines (OE-1, OE-2 and OE-3) did not show significant differences after
409
10 days of cultivation (Figure 4A). The biomass of 10 seedlings was 54.4 mg (FW)
410
for WT, 54.6 mg (FW) for OE-1, 55.0 mg (FW) for OE-2 and 56.2 mg (FW) for
411
OE-3. The WT, OE-1, OE-2 and OE-3 Arabidopsis lines exhibited average root
412
lengths of 3.43, 3.53, 3.47 and 3.48 cm, respectively. Postexposure to Cd, all the
413
seedlings showed retarded growth (Figure 4A). The transgenic lines (Figure 4B)
414
presented stronger tolerance to Cd stress, exhibiting significantly longer root lengths
415
(2.17-2.28 cm for OE-1, OE-2 and OE-3) and higher biomass (35.9-38.8 mg in FW
416
for 10 seedlings of OE-1, OE-2 and OE-3) than the WT plants (1.42 cm in length and
417
22.3 mg in FW, respectively).
418
The in vivo visualization of H2O2 and O2∙- levels in leaves postexposure to Cd is
419
illustrated in Figure 4C-4F. In the absence of Cd, there was no significant difference
420
between WT and SaCTP2-overexpressing Arabidopsis. After treatment with Cd, the
421
SaCTP2-overexpressing Arabidopsis lines displayed remarkably lower staining
422
intensities compared to WT, indicating less accumulation of H2O2 and O2∙- (Figure 4C
423
and 4E). These results were obtained from the direct measurement of H2O2 and O2∙-
424
contents in leaves. In the absence of Cd, H2O2 contents were comparable in WT and
425
the three transgenic Arabidopsis lines (Figure 4D). Postexposure to Cd for 7 days,
426
H2O2 contents increased by 214% in WT, to levels much higher than those in the
427
SaCTP2-overexpressing Arabidopsis lines (129% on average, Figure 4D). Similarly,
428
the O2∙- contents of SaCTP2-overexpressing Arabidopsis plants increased by only
429
64-78%, but that of WT increased by 162% postexposure to Cd (Figure 4F). More
430
evidence was obtained by examining the activities of ROS scavengers, which showed
431
negligible differences between WT and transgenic plants under nonstressed
432
conditions. SOD and POD activities increased 90.3-118.3% and 354.6-430.9%,
433
respectively, after 7-day exposure to Cd in the three transgenic lines, to levels
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434
significantly higher than those in WT (36.4% and 134.76%, Figure 5A and 5B).
435
Surprisingly, CAT activities behaved in the opposite manner, decreasing more in the
436
three transgenic lines (38.4-44.9%) than in WT (26.9%, Figure 5C).
437
In the absence of Cd, representative physiological indices of WT and
438
SaCTP2-overexpressing Arabidopsis lines such as chlorophyll contents, MDA levels
439
and electrolyte leakages showed no significant differences (Figure 5D-5F).
440
Postexposure to Cd, the total chlorophyll contents decreased by 50.6% in WT plants,
441
whereas the decline was only 13.6-37.2% in the three SaCTP2-overexpressing
442
Arabidopsis lines (Figure 5D). Similarly, MDA levels in the SaCTP2-overexpressing
443
Arabidopsis lines increased by 31.7-54.5%, was much lower than the increase in WT
444
(122.9%,
445
SaCTP2-overexpressing Arabidopsis lines ranged from 1.9% to 55.8%, which was
446
lower than that in WT (92.1%, Figure 5F).
447
Additionally, SaCTP2-expressing Arabidopsis lines (OE-1, OE-2 and OE-3)
448
displayed 46.3% higher Cd contents in their stems and leaves than WT, although there
449
was no significant difference (p>0.05) in root Cd contents between WT and the
450
SaCTP2-expressing Arabidopsis lines (Figure 6A). The Cd translocation factor (TF)
451
was 0.687 for the SaCTP2 transgenic seedlings, which was 49.5% higher than that for
452
WT (0.459). As the biomass increased, the SaCTP2-expressing Arabidopsis lines took
453
up and stored more Cd in their roots (96.1% higher) or stems/leaves (342.0% higher)
454
(Figure 6B). In contrast, seedlings of the SaCTP2-expressing Arabidopsis lines
455
exhibited a 22.1% lower Zn content in their roots but a 14.5% higher Zn content in
456
their stems/leaves in comparison with WT (Figure 6C). Zn accumulation was
457
therefore significantly lower than Cd accumulation: approximately 56.8% higher in
458
the roots and 244.7% higher in the stems/leaves of the SaCTP2-expressing
459
Arabidopsis lines (Figure 6D). These results suggested that overexpression of
460
SaCTP2 preferentially increased the uptake and accumulation of Cd in Arabidopsis.
Figure
5E),
and
the
increase
in
electrolyte
leakage
in
461 462
4. Discussion
463
The 48 genes identified from the full-length cDNA library were involved in signal
464
perception (SaPERK3), signal transduction (SaCaM, SaCIPK8, SaPRX and SaTRX)
465
and detoxification (metal homeostasis, ROS homeostasis, etc., Figure 1A). Compared
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to a previously reported transcriptome database 23, our coexpression network analysis
467
identified 15 hub genes as key candidates influencing Cd hypertolerance and
468
hyperaccumulation in S. alfredii Hance (Figure 1B). In addition to metabolic and
469
cellular processes, these hub genes are also linked to other genes associated with
470
metal transport, transcription regulation, the response to stimuli and antioxidant
471
processes. Accordingly, the genetic functions related to Cd tolerance in S. alfredii
472
Hance form a complex network. Among the identified genes, 13 hub genes have been
473
reported previously, and the two novel genes (SaCTP2 and SaCTP3) are linked to Cd
474
tolerance for the first time in the present study. Their roles in Cd tolerance were
475
further validated by expression in Cd-sensitive yeast cells (Figure 2), and they might
476
trigger upstream biological processes for activating detoxification and defense
477
reactions under Cd stress.
478
Regarding signal perception, the SaPERK gene encodes a subclass of the plant
479
receptor-like kinases that act as sensors/receptors with extracellular domains on the
480
cell wall
481
abiotic/biotic stresses and activate associated cellular responses
482
cell wall-associated kinases for invertase activity and cell growth) 51-53. However, the
483
SaPERK gene failed to complement the yeast Cd-sensitive mutant (Δycf1), and its role
484
in sensing extracellular Cd and perceiving Cd stress signals must be questioned.
485
Two genes associated with signal transduction are related to calcium signaling
486
(SaCaM and SaCIPK8). Ca deficiency has been reported to trigger highly efficient
487
phloem remobilization of Cd in S. alfredii Hance and to subsequently increase Cd
488
accumulation in leaves
489
extensively studied Ca2+ sensors and is proposed as an integrator of different stress
490
signaling pathways modulating a number of stress-associated proteins
491
encodes a plant-specific Ca2+ sensor, calcineurin B-like (CBL)-interacting protein
492
kinase (CIPK), that modulates the expression and activity of downstream stress
493
effectors 56. Although previous studies have indicated key roles of mitogen-activated
494
protein kinase (MAPK) members
495
signal transduction, these proteins and systems were not identified in the present
496
study. Our findings broaden our knowledge and suggest that calcium signaling
497
crosstalk provides additional versatility to stress-associated signal transduction
498
pathways by regulating the activities of several kinases, modulating proteins
49.
These sensors/receptors monitor extracellular changes postexposure to
54.
50
(e.g., Arabidopsis
SaCaM encodes calmodulin, which is one of the most
57, 58
and hormone signaling systems
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59
SaCIPK
in metal
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499
associated with defense responses, perceiving the signals from upstream receptors,
500
and ultimately helping plants to maintain cellular homeostasis.
501
Other genes associated with detoxification encode proteins that chelate heavy metals
502
(SaPCS, SaMT3 and SaHIPP), scavenge ROS (SaPRX, SaTRX, SaAPX, SaPOD,
503
SaGST and SaUSP), modulate transcription (SaERF, SaWRKY and SaRLP24) or
504
participate in other response processes (SaMTR, SaDRT100, SaPCCR and SaDRP).
505
These genes showed diverse expression profiles in response to Cd stress and were
506
induced in the roots in particular (Figure S1), indicating their functional diversity and
507
involvement in diverse biological processes. Previous studies have reported
508
interdependency between cellular redox imbalance and metal toxicity, implying the
509
disruption of equilibrium between ROS generation and detoxification by metal stress,
510
which induces oxidative stress and causes cell damage 60, 61. Generally, the main roles
511
of these genes are to maintain metal homeostasis or executing antioxidant activities to
512
alleviate ROS injuries 62, 63.
513
Among the genes associated with metal homeostasis, the SaHIPP gene was
514
moderately upregulated in roots and highly induced in leaves (Figure S1). This gene
515
encodes heavy metal-associated isoprenylated plant proteins (HIPPs) that serve as
516
metallochaperones, which are composed of a metal-binding domain and a C-terminal
517
isoprenylation motif and play a role in metal homeostasis and act as regulatory
518
elements in the transcriptional response to cold and drought
519
linked to the biosynthesis of metal chelates (metallothioneins, SaMT3) and
520
phytochelatins (SaPCS), indicating the key roles of Cd chelation proteins in Cd
521
tolerance. Plant chelators such as phytochelatins, glutathione and metallothioneins can
522
bind Cd and ultimately sequester it into vacuoles
523
NRT1/PTR FAMILY (NPF) proteins capable of transporting nitrate, di/tri-peptide,
524
plant hormones (e.g., indole-3-acetic acid, abscisic acid, gibberellin) and secondary
525
metabolites (e.g., glucosinolates)
526
roles in K+ translocation from roots to shoots and is involved in coordinating the
527
K+/NO3- distribution
528
subgroup of NPF from Arabidopsis and serves as a constitutively expressed
529
transporter with a significant contribution to the NO3- translocation response to
530
salinity
531
gene to Cd hypertolerance in S. alfredii Hance on the basis of ectopic expression in
70.
69.
67, 68.
66.
64, 65.
Other genes were
The SaNTR1 gene encodes
The AtNRT1.5 gene is reported to play crucial
NPF2.3, a member of the nitrate excretion transporter
For the first time, our findings hinted at the contribution of the SaNTR1
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532
Cd-sensitive yeast, which can probably be explained by the transport of peptides,
533
glucosinolate defense compounds or plant hormones.
534
Metal stress can induce oxidative injuries
535
antioxidant systems for antioxidant defense and cellular homeostasis maintenance.
536
The antioxidant defense enzymes include peroxidase, thioredoxin, glutathione
537
S-transferase, peroxiredoxin and ascorbate peroxidase
538
encodes peroxiredoxin (PRX), which is a robust peroxide-decomposing enzyme 60, 74,
539
and PRX expression contributes to increasing ROS levels to repair damaged
540
macromolecules, thus enhancing the antioxidant system and reducing heavy metal
541
concentrations in cytoplasmic compartments
542
encoding flavanone 3-hydroxylase (F3H), an important enzyme catalyzing flavonol
543
synthesis. Flavonoids are important secondary metabolites in plants and are associated
544
with a wide range of biological functions, such as defense protection. A tomato
545
F3H-like protein has been shown to improve chilling tolerance 61. Other genes related
546
to cellular homeostasis are also responsible for stress responses, including heat shock
547
proteins (HSPs), regulatory transcription factors, structural proteins and DNA repair
548
proteins76, 77. SaAQP encodes aquaporins, a group of membrane-intrinsic proteins that
549
transport water along with some small neutral solutes and ions and is important in the
550
responses to a wide range of environmental stresses 78, 79. SaDRT100, encoding DNA
551
repair and tolerance proteins, is linked to genetic stability
552
protein-encoding gene (SaGRP) is related to the cellular stress response 81. However,
553
none of these genes were previously linked to Cd tolerance in S. alfredii Hance, and
554
our study suggested that numerous enzymes associated with the antioxidant system
555
and cellular homeostasis are responsible for Cd tolerance in S. alfredii Hance.
556
Five novel genes (SaCTP1 to SaCTP5) were uncharacterized in the NCBI database
557
and exhibited Cd tolerance traits. To further validate their functions in Cd
558
hypertolerance and hyperaccumulation, heterologous expression of the SaCTP2 gene
559
was performed in Arabidopsis. According to the examined physiological indices
560
(weight, root length, chlorophyll contents, electrolyte leakage, MDA levels, ROS
561
levels and H2O2 contents, Figure 4 and 5), the activities of ROS-scavenging enzymes
562
(SOD and POD, Figure 5) and Cd accumulation (Figure 6), the SaCTP2-expressing
563
transgenic lines displayed significantly higher Cd tolerance and accumulation than
564
WT. These results confirmed the functions of the SaCTP2 genes in Cd
71
75.
and subsequently trigger complex
72, 73.
For instance, SaPRX
SaF3H belongs to a gene family
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The glycine-rich
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565
hyperaccumulation. One explanation arising from protein sequence analysis suggested
566
that SaCTP2 is a 99-aa protein harboring a partial FLZ domain
567
putative heavy metal-binding motifs and contributes to the increased Cd tolerance
568
(Figure 3). Previous studies have reported the functions of the FLZ domain in
569
regulating heavy metal tolerance
570
which carries two AN1 zinc finger domains and a Cys2-His2 domain, show high
571
tolerance to toxic metals and exhibit increased Zn accumulation 83. Another possible
572
explanation is metabolic homeostasis, supported by a close correlation between the
573
FLZ domain and the SNF1-related protein kinase 1 (SnRK1) signaling cascade in
574
Arabidopsis, which triggers massive transcriptional reprogramming to enable plant
575
survival under low-energy conditions
576
could achieve metabolic homeostasis by protecting chlorophyll from Cd-induced
577
degradation, decreasing ROS levels, maintaining membrane integrity and protecting
578
the root architecture from damage, as evidenced by the functions of the SaREFl gene
579
observed in a previous study 19. The higher levels of Cd translocation factors recorded
580
in this study also suggested more Cd accumulation in stems and leaves, implying that
581
the SaCTP2 protein promoted the root-to-shoot translocation of Cd and altered the Cd
582
distribution in Arabidopsis. Taken together, the available findings indicate that the
583
SaCTP2 gene might act as a protein-protein interaction module and that the encoding
584
enzyme interacts with biomolecules involved in Cd uptake, transport and
585
detoxification. This gene trait is valuable for constructing transgenic plants for
586
application in phytoremediation at Cd-contaminated sites. Additional experimental
587
studies are suggested to validate the functions of other genes screened in the present
588
study, such as SaHIPP, SaF3H, SaAQP, SaDRT100, SaGRP and SaNTR1, which
589
could broaden our understanding of the mechanisms of Cd tolerance in S. alfredii
590
Hance.
591
In conclusion, our work revealed 48 genes that are directly associated with Cd
592
tolerance from a full-length cDNA library of S. alfredii Hance and validated their
593
functions in Cd-sensitive yeast cells. Coexpression network analysis of the response
594
to Cd stress suggested that the Cd hypertolerance of S. alfredii Hance is a highly
595
complex phenomenon associated with diverse gene functions carried out by the
596
antioxidant system, defense gene induction and calcium signaling pathway. Among
597
the 5 novel genes linked to Cd tolerance in S. alfredii Hance for the first time, the
82.
48
that includes
Transgenic plants overexpressing AtSAP13,
84-87.
SaCTP2 expression in transgenic plants
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functions of the SaCTP2 gene were further confirmed in transgenic Arabidopsis lines.
599
Our findings offer a novel high-throughput approach for cDNA library construction
600
for screening, validating and understanding the genes that confer metal hypertolerance
601
traits and provide guidance for the breeding of plant varieties for metal
602
phytoremediation.
603 604
Supporting Information
605
Details of dsDNA synthesis; construction of the pYES2-SfiI yeast expression vector;
606
list of primers used in this study; homologous genes of SaCTP2 in the phylogenic tree
607
and domain analysis based on the Pfam database; heatmap of the expression profiles
608
of 48 screened genes in different tissues of S. alfredii Hance under Cd stress; heatmap
609
of the tissue-specific expression patterns of 48 screened genes of S. alfredii Hance
610
without Cd stress; sketch of S. alfredii Hance individuals and the sampled root, stem
611
and leaf tissues.
612 613
Acknowledgments
614
This work was supported by the National Natural Science Foundation of China (No.
615
31870647) and the National Key Technology R&D Program of China (No.
616
2016YFD0800801). DZ also acknowledges the support of the Chinese Government's
617
Thousand Talents Plan for Young Professionals.
618
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Table Table 1. Annotation of sequences coding for amino acids in the proteins (CDSs) of 48 candidate genes screened from the cDNA library of S. alfredii Hance. Gene (Accession No) SaCTP1 (MK044850) SaPCS (MK044851) SaCTP2 (MK044852) SaUSPl (MK044853) SaSAP (MK044854) SaCTP3 (MK044855) SaHSF (MK044856) SaGRP (MK044857) SaGELP (MK044858)
CDS Homologs (Accession No) Hypothetical protein DVH24_029503 in Malus domestica (RXH74782.1) Phytochelatin synthase in Boehmeria nivea (AHC98018.1) Uncharacterized protein LOC111464337 in Cucurbita moschata (XP_022964268.1) Universal stress protein PHOS32-like in Juglans regia (XP_018811680.1) Zinc finger A20 and AN1 domain-containing stress-associated protein 5-like in Camellia sinensis (XP_028079437.1) Uncharacterized protein LOC114266108 isoform X1 in Camellia sinensis (XP_028062803.1) Heat shock transcription factor in Trema orientale (PON68120.1) Glycine rich protein in Nicotiana tabacum (AAK57546) GDSL esterase/lipase in Gossypium arboretum (XP_017604964.1)
Amino acid sequence similarity 57.89%
Annotation
Reference
Unknown
-
89.00%
Cd2+ tolerance.
88
51.52%
Unknown
-
73.93%
Control of ROS homeostasis under anoxia
89
59.09%
Ubiquitin ligase, redox sensor, and regulation of gene expression during stress
90
60.27%
Unknown
-
45.31%
Regulation of stress tolerance
44
48.00%
Stress responses and signaling.
81
55.87%
Diverse physical functions in growth and stress responses.
91
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SaRPS29 (MK044859) SaAIR6B (MK044860) SaPOD (MK044861) SaPERK3 (MK044862) SaPPlsae (MK044863) SaMYR (MK044864) SaDRT100 (MK044865)
40S ribosomal protein S29 in Cicer arietinum (XP_004491390.1) Auxin-responsive protein SAUR72-like in Nelumbo nucifera (XP_010259870.1) Cationic peroxidase 1 in Vitis vinifera (XP_002268412.1) Proline-rich receptor-like protein kinase PERK3 in Hevea brasiliensis (XP_021639397.1) Peptidyl-prolyl cis-trans isomerase in Actinidia chinensis var. chinensis (PSS29498.1) myb-related protein 308 in Prunus yedoensis var. nudiflora (PQQ14404.1) DNA damage-repair/toleration protein DRT100 in Sesamum indicum (XP_011087364.1)
96.43%
SaF3H (MK044866) SaMS1 (MK044867) SaH2A (MK044868) SaRPL24 (MK044869) SaCoPA (MK044870) SaHIPP
Flavanone 3-hydroxylase in Arabidopsis thaliana (NP_001190050.1) Mannan synthase 1 isoform in Vitis vinifera (XP_002277171.1) Histone H2A in Erythranthe guttata (XP_012848194.1)
63.32%
60S ribosomal protein L24-like in Lactuca sativa (XP_023760011.1) Copper-transporting ATPase in Actinidia chinensis var. chinensis (PSR98747.1) Heavy metal-associated isoprenylated plant protein
95.65%
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Components of the protein synthesis machinery Auxin signaling pathway
92
Biotic and abiotic stress tolerance and senescence Sensors/receptors at the cell wall
94
Chaperones induced by intracellular acidification Modulation of ROS; accumulation and stress response Reparation and toleration of UV-B-induced DNA damage
95
Participation in the flavonoid biosynthesis pathway Synthesis of cell-wall polysaccharides
97
99
63.73%
Escort of histones and function in nucleosome structural configuration. Essential components of the protein synthesis machinery Transmembrane proteins transporting copper
61.36%
Heavy metal homeostasis and detoxification
52.17% 72.41% 50.97% 90.80% 66.43% 68.41%
75.59% 82.31%
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49
96
80
98
92
100
64
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(MK044871) SaCtns (MK044872) SaERF (MK044873)
3-like in Nelumbo nucifera (XP_010253988.1) Cystinosin homolog in Prunus mume (XP_008230459.1) Ethylene-responsive transcription factor TINY-like in Juglans regia (XP_018823586.1)
SaCaM (MK044874)
Calmodulin-like in Brassica oleracea var. oleracea (XP_013631799.1)
91.20%
SaCTP4 (MK044875) SaNTR1 (MK044876) SaWRKY (MK044877) SaCys (MK044878) SaVIT (MK044879) SaNQO (MK044880) SaTRX (MK044881) SaFA2H (MK044882) SaChi
Uncharacterized LOC105110269 in Populus euphratica (XP_011003552.1) Nitrate transporter 1/peptide transporter family protein in Malus domestica (AYW00847.1) WRKY transcription factor 31 in Ziziphus jujube (XP_015877768.1) Cysteine synthase in Eucalyptus grandis (XP_010024285.1) Vacuolar iron transporter 1 in Nicotiana sylvestris (P_009787813.1) NADPH:quinone oxidoreductase-like in Nelumbo nucifera (XP_010276653.1) Thioredoxin M3 in Vitis vinifera (RVW49697.1)
86.62%
Dihydroceramide fatty acyl 2-hydroxylase FAH1-like in Herrania umbratical (XP_021298290.1) Endochitinase-like in Juglans regia (XP_018854709.1)
76.36%
Lysosomal cystine transporter
101
86.67%
Regulatory proteins controlling metabolism, growth and development; responses to environmental stimuli Major Ca2+ sensors with critical roles in interpreting encrypted Ca2+ signals Unknown
102
Transportion of a wide variety of substrates such as nitrate and plant hormones Response to biotic and abiotic stress
67
61.62% 64.97% 93.33%
103
-
104
105.
88.43%
Cysteine synthesis, the final step of assimilatory sulfate reduction Iron transport
73.43%
ROS balance
107
61.39%
Component of antioxidant system
81.01%
Fatty acid 2-hydroxylation
110
69.77%
Plant defense
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108, 109
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(MK044883) SaMTPl2 (MK044884) SaAPXl (MK044885) SaLHC6A (MK044886) SaCIPK8 (MK044887) SaMTPl1 (MK044888) SaAPXl (MK044889) SaMT3 (MK044890) SaGST (MK044891) SaCTP5 (MK044892) SaAQP (MK044893) SaRCCR (MK044894) SaDRP (MK044895) SaPRX
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Metallothionein 2 in Sedum alfredii (AIG51062.1)
99.10%
Responsible for iron hemostasis in cell
18
Putative L-ascorbate peroxidase 6 in Jatropha curcas (XP_012076559.1) Light harvest chlorophyll a-b binding protein 6 in Prunus persica (XP_007201239.1) CBL-interacting serine/threonine-protein kinase 8 isoform X2 in Theobroma cacao (XP_007018315.2) metallothionein-like protein, Sedum plumbizincicola, ANF89428.1 L-ascorbate peroxidase 2 in Nicotiana tabacum (ANF89428.1) Metallothionin 3 in Salvia miltiorrhiza (AEQ54919.1)
64.47%
Component of antioxidant system
109
87.9%
17
98.00%
Main light-harvesting pigment-protein complex of photosystem Plant-specific family of serine-threonine kinases which CBLs specifically target Responsible for iron hemostasis in cell
88.80%
Component of antioxidant system
112
55.56%
Iron hemostasis
18
Glutamine synthetase nodule isozyme in Fragaria vesca subsp. Vesca (XP_004288594.1) Uncharacterized protein in Vigna angularis (XP_017424345.1) Aquaporin TIP1-1 in Manihot esculenta (XP_021620289.1) Red chlorophyll catabolite reductase in Vigna angularis (XP_017428980.1) Disease resistance protein At4g14610 in Arabidopsis lyrata subsp. Lyrate (XP_017428980.1) Peroxiredoxin-2E-2 in Cynara cardunculus var.
89.30%
Response to plant nitrogen status and environmental cues Unknown
113
79
60.37%
Transport of water, small neutral solutes and ions Central reaction of chlorophyll breakdown
46.11%
Disease defense responses
115
78.72%
Component of antioxidant system
109
82.29%
85.71% 81.25%
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(MK044896) SaTLP3 (MK044897)
scolymus (XP_024978976.1) Tubby-like F-box protein 3 in Theobroma cacao (XP_017981743.1)
73.88%
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1002
Figure captions
1003
Figure 1. (A) Functions of 48 candidate genes related to signal perception, signal
1004
transduction and detoxification. (B) Coexpression network of 15 hub genes. Nodes
1005
indicate genes, and edges represent significant coexpression events between genes.
1006
Target genes involved in the same biological process are grouped together and
1007
distinguished with different colors.
1008
Figure 2. Validation of 48 candidate genes from S. alfredii Hance related to Cd
1009
tolerance by yeast complementation in the Cd-sensitive strain Δycf1. Yeast cells were
1010
spotted in four concentrations (OD600 = 1, 0.1, 0.01, 0.001). The negative control was
1011
Δycf1 carrying the empty vector pYES2 (Δycf1_EV). The plates were incubated for 3
1012
days at 30 °C, and the Cd exposure concentration was 40 µΜ.
1013
Figure 3. (A) Nucleotides of the SaCTP2 gene and deduced amino acid sequences of
1014
the SaCTP2 protein. (B) Conserved domain of the SaCTP2 protein predicted by the
1015
Pfam database. (C) Phylogenetic tree of the SaCTP2 gene constructed by MEGA7.0
1016
(details see Table S2 in ESI).
1017
Figure 4. Physiological indices of WT and SaCTP2-expressing Arabidopsis
1018
transgenic lines (OE-1, OE-2, and OE-3). (A) Phenotypic changes after being grown
1019
vertically for 10 days in half-strength Murashige and Skoog medium in the absence or
1020
presence of Cd. (B) Root length and fresh weight (FW). (C) Leaves with DAB
1021
staining. (D) H2O2 contents of leaves. (E) Leaves with NBT staining. (F) O2∙- contents
1022
of leaves. Bars represent the mean ± standard deviation (SD) from 15-20 individuals
1023
of each genotype. Different small letters indicate significant differences (p