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RNA interference reveals chloride channel 7 gene helps short-term hypersalinity stress resistance in Hong Kong oyster
Crassostrea hongkongensis - Journal of Oceanology and Limnology Vol. 42, Issue 4, Pages: 1261-1271(2024)
- Affiliations:
Guangxi Key Laboratory of Beibu Gulf Marine Biodiversity Conservation, Pinglu Canal and Beibu Gulf Coastal Ecosystem Observation and Research Station of Guangxi, College of Marine Sciences, Beibu Gulf University, Qinzhou 535011, China
- Author bio:
xuxuyoutiao@163.com
shezc@bbgu.edu.cn
- Funds:
DOI:
CLC:Received:15 July 2023,
Published:01 July 2024
- Accepted:
Scan QR Code
PENG Yeshao,CHEN Ziao,DENG Qiong,et al.RNA interference reveals chloride channel 7 gene helps short-term hypersalinity stress resistance in Hong Kong oyster Crassostreahongkongensis[J].Journal of Oceanology and Limnology,2024,42(04):1261-1271.
摘要
Abstract
The chloride channel 7 gene (
CLC7
) of the Hong Kong oyster
Crassostrea
hongkongensis
was cloned and named
ChCLC7
. The cDNA was 2 572 bp in length
with a 5′ non-coding region containing 25 bp
a 3′ non-coding region containing 327 bp
and an open reading frame of 2 298 bp. ChCLC7 has 96.8% and 92.1% homology with CLC7 of
Crassostrea gigas
and
Crassostrea
virginica
respectively
and it was clustered with CLC7 of
C
.
gigas
and
C
.
virginica
. QRT-PCR showed that
ChCLC7
was expressed in all eight tissues
with the highest in adductor muscle and second in gill. The
ChCLC7
expression pattern in gill was altered significantly under high salinity stress with an overall upward and then downward trend. After RNA interference
the expression of
ChCLC7
and survival rate of oyster under high salinity stress was reduced significantly
and so did the concentration of hemolymph chloride ion in 48–96 h after RNA interference. We believed that
ChCLC7
could play an important role in osmoregulation of
C
.
hongkongensis
by regulating Cl⁻ transport. This study provided data for the analysis of molecular mechanism against oyster salinity stress.
关键词
Keywords
references
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