Responses of roots and rhizosphere of female papaya to the exogenous application of GA3

Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA 3 by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and r...

Full description

Saved in:
Bibliographic Details
Published inBMC plant biology Vol. 23; no. 1; p. 35
Main Authors Zhou, Yongmei, Pang, Ziqin, Jia, Haifeng, Yuan, Zhaonian, Ming, Ray
Format Journal Article
LanguageEnglish
Published London BioMed Central Ltd 16.01.2023
BioMed Central
BMC
Subjects
Agricultural research
aluminum
auxins
brassinolide
Colletotrichum
Development
excretion
females
Gibberellins
jasmonic acid
lateral roots
Metabolome
microbial communities
Microbiome
Mitsuaria
Mycobacterium
nitrates
nutrient uptake
Papaya
phosphates
Physiological aspects
Plants
Rhizosphere
Root
Roots (Botany)
somatotropin
species
starvation
stress tolerance
toxicity
Transcriptome
Verticillium
China
Online AccessGet full text

Cover

Abstract Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA 3 by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and rhizosphere of GA 3 -treated and control female papaya. The results demonstrated that exogenous GA 3 treatment enhanced female papaya lateral root development, which gave plants physical advantages of water and nutrient uptake. In addition, it was likely that GA 3 spraying in papaya shoot apices increased the level of auxin, which was transported to roots by CpPIN1, where auxin upregulated CpLBD16 and repressed CpBP to promote the lateral root initiation and development. In papaya roots, corresponding transporters ( CpTMT3 , CpNRT1:2 , CpPHT1;4 , CpINT2 , CpCOPT2 , CpABCB11 , CpNIP4;1 ) were upregulated and excretion transporters were downregulated such as CpNAXT1 for water and nutrients uptake with exogenous GA 3 application. Moreover, in GA 3 -treated papaya roots, CpALS3 and CpMYB62 were downregulated, indicating a stronger abiotic resistance to aluminum toxic and phosphate starvation. On the other hand, BRs and JAs, which involve in defense responses, were enriched in the roots and rhizosphere of GA 3 -treated papayas. The upregulation of the two hormones might result in the reduction of pathogens in roots and rhizosphere such as Colletotrichum and Verticillium . GA 3 -treated female papaya increased the abundance of beneficial bacteria species including Mycobacterium , Mitsuaria , and Actinophytocola , but decreased that of the genera Candidatus and Bryobacter for that it required less nitrate. Overall, the roots and rhizosphere of female papaya positively respond to exogenous application of GA 3 to promote development and stress tolerance. Treatment of female papaya with GA3 might result in the promotion of lateral root formation and development by upregulating CpLBD16 and downregulating CpBP . GA 3 -treated papaya roots exhibited feedback control of brassinolide and jasmonate signaling in root development and defense. These findings revealed complex response to a growth hormone treatment in papaya roots and rhizosphere and will lead to investigations on the impact of other plant hormones on belowground development in papaya.
AbstractList Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA.sub.3 by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and rhizosphere of GA.sub.3-treated and control female papaya. The results demonstrated that exogenous GA.sub.3 treatment enhanced female papaya lateral root development, which gave plants physical advantages of water and nutrient uptake. In addition, it was likely that GA.sub.3 spraying in papaya shoot apices increased the level of auxin, which was transported to roots by CpPIN1, where auxin upregulated CpLBD16 and repressed CpBP to promote the lateral root initiation and development. In papaya roots, corresponding transporters (CpTMT3, CpNRT1:2, CpPHT1;4, CpINT2, CpCOPT2, CpABCB11, CpNIP4;1) were upregulated and excretion transporters were downregulated such as CpNAXT1 for water and nutrients uptake with exogenous GA.sub.3 application. Moreover, in GA.sub.3-treated papaya roots, CpALS3 and CpMYB62 were downregulated, indicating a stronger abiotic resistance to aluminum toxic and phosphate starvation. On the other hand, BRs and JAs, which involve in defense responses, were enriched in the roots and rhizosphere of GA.sub.3-treated papayas. The upregulation of the two hormones might result in the reduction of pathogens in roots and rhizosphere such as Colletotrichum and Verticillium. GA.sub.3-treated female papaya increased the abundance of beneficial bacteria species including Mycobacterium, Mitsuaria, and Actinophytocola, but decreased that of the genera Candidatus and Bryobacter for that it required less nitrate. Overall, the roots and rhizosphere of female papaya positively respond to exogenous application of GA.sub.3 to promote development and stress tolerance. Treatment of female papaya with GA3 might result in the promotion of lateral root formation and development by upregulating CpLBD16 and downregulating CpBP. GA.sub.3-treated papaya roots exhibited feedback control of brassinolide and jasmonate signaling in root development and defense. These findings revealed complex response to a growth hormone treatment in papaya roots and rhizosphere and will lead to investigations on the impact of other plant hormones on belowground development in papaya.
Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA₃ by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and rhizosphere of GA₃-treated and control female papaya. The results demonstrated that exogenous GA₃ treatment enhanced female papaya lateral root development, which gave plants physical advantages of water and nutrient uptake. In addition, it was likely that GA₃ spraying in papaya shoot apices increased the level of auxin, which was transported to roots by CpPIN1, where auxin upregulated CpLBD16 and repressed CpBP to promote the lateral root initiation and development. In papaya roots, corresponding transporters (CpTMT3, CpNRT1:2, CpPHT1;4, CpINT2, CpCOPT2, CpABCB11, CpNIP4;1) were upregulated and excretion transporters were downregulated such as CpNAXT1 for water and nutrients uptake with exogenous GA₃ application. Moreover, in GA₃-treated papaya roots, CpALS3 and CpMYB62 were downregulated, indicating a stronger abiotic resistance to aluminum toxic and phosphate starvation. On the other hand, BRs and JAs, which involve in defense responses, were enriched in the roots and rhizosphere of GA₃-treated papayas. The upregulation of the two hormones might result in the reduction of pathogens in roots and rhizosphere such as Colletotrichum and Verticillium. GA₃-treated female papaya increased the abundance of beneficial bacteria species including Mycobacterium, Mitsuaria, and Actinophytocola, but decreased that of the genera Candidatus and Bryobacter for that it required less nitrate. Overall, the roots and rhizosphere of female papaya positively respond to exogenous application of GA₃ to promote development and stress tolerance. Treatment of female papaya with GA3 might result in the promotion of lateral root formation and development by upregulating CpLBD16 and downregulating CpBP. GA₃-treated papaya roots exhibited feedback control of brassinolide and jasmonate signaling in root development and defense. These findings revealed complex response to a growth hormone treatment in papaya roots and rhizosphere and will lead to investigations on the impact of other plant hormones on belowground development in papaya.
Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA 3 by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and rhizosphere of GA 3 -treated and control female papaya. The results demonstrated that exogenous GA 3 treatment enhanced female papaya lateral root development, which gave plants physical advantages of water and nutrient uptake. In addition, it was likely that GA 3 spraying in papaya shoot apices increased the level of auxin, which was transported to roots by CpPIN1, where auxin upregulated CpLBD16 and repressed CpBP to promote the lateral root initiation and development. In papaya roots, corresponding transporters ( CpTMT3 , CpNRT1:2 , CpPHT1;4 , CpINT2 , CpCOPT2 , CpABCB11 , CpNIP4;1 ) were upregulated and excretion transporters were downregulated such as CpNAXT1 for water and nutrients uptake with exogenous GA 3 application. Moreover, in GA 3 -treated papaya roots, CpALS3 and CpMYB62 were downregulated, indicating a stronger abiotic resistance to aluminum toxic and phosphate starvation. On the other hand, BRs and JAs, which involve in defense responses, were enriched in the roots and rhizosphere of GA 3 -treated papayas. The upregulation of the two hormones might result in the reduction of pathogens in roots and rhizosphere such as Colletotrichum and Verticillium . GA 3 -treated female papaya increased the abundance of beneficial bacteria species including Mycobacterium , Mitsuaria , and Actinophytocola , but decreased that of the genera Candidatus and Bryobacter for that it required less nitrate. Overall, the roots and rhizosphere of female papaya positively respond to exogenous application of GA 3 to promote development and stress tolerance. Treatment of female papaya with GA3 might result in the promotion of lateral root formation and development by upregulating CpLBD16 and downregulating CpBP . GA 3 -treated papaya roots exhibited feedback control of brassinolide and jasmonate signaling in root development and defense. These findings revealed complex response to a growth hormone treatment in papaya roots and rhizosphere and will lead to investigations on the impact of other plant hormones on belowground development in papaya.
Abstract Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA3 by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and rhizosphere of GA3-treated and control female papaya. The results demonstrated that exogenous GA3 treatment enhanced female papaya lateral root development, which gave plants physical advantages of water and nutrient uptake. In addition, it was likely that GA3 spraying in papaya shoot apices increased the level of auxin, which was transported to roots by CpPIN1, where auxin upregulated CpLBD16 and repressed CpBP to promote the lateral root initiation and development. In papaya roots, corresponding transporters (CpTMT3, CpNRT1:2, CpPHT1;4, CpINT2, CpCOPT2, CpABCB11, CpNIP4;1) were upregulated and excretion transporters were downregulated such as CpNAXT1 for water and nutrients uptake with exogenous GA3 application. Moreover, in GA3-treated papaya roots, CpALS3 and CpMYB62 were downregulated, indicating a stronger abiotic resistance to aluminum toxic and phosphate starvation. On the other hand, BRs and JAs, which involve in defense responses, were enriched in the roots and rhizosphere of GA3-treated papayas. The upregulation of the two hormones might result in the reduction of pathogens in roots and rhizosphere such as Colletotrichum and Verticillium. GA3-treated female papaya increased the abundance of beneficial bacteria species including Mycobacterium, Mitsuaria, and Actinophytocola, but decreased that of the genera Candidatus and Bryobacter for that it required less nitrate. Overall, the roots and rhizosphere of female papaya positively respond to exogenous application of GA3 to promote development and stress tolerance. Treatment of female papaya with GA3 might result in the promotion of lateral root formation and development by upregulating CpLBD16 and downregulating CpBP. GA3-treated papaya roots exhibited feedback control of brassinolide and jasmonate signaling in root development and defense. These findings revealed complex response to a growth hormone treatment in papaya roots and rhizosphere and will lead to investigations on the impact of other plant hormones on belowground development in papaya.
Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA.sub.3 by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and rhizosphere of GA.sub.3-treated and control female papaya. The results demonstrated that exogenous GA.sub.3 treatment enhanced female papaya lateral root development, which gave plants physical advantages of water and nutrient uptake. In addition, it was likely that GA.sub.3 spraying in papaya shoot apices increased the level of auxin, which was transported to roots by CpPIN1, where auxin upregulated CpLBD16 and repressed CpBP to promote the lateral root initiation and development. In papaya roots, corresponding transporters (CpTMT3, CpNRT1:2, CpPHT1;4, CpINT2, CpCOPT2, CpABCB11, CpNIP4;1) were upregulated and excretion transporters were downregulated such as CpNAXT1 for water and nutrients uptake with exogenous GA.sub.3 application. Moreover, in GA.sub.3-treated papaya roots, CpALS3 and CpMYB62 were downregulated, indicating a stronger abiotic resistance to aluminum toxic and phosphate starvation. On the other hand, BRs and JAs, which involve in defense responses, were enriched in the roots and rhizosphere of GA.sub.3-treated papayas. The upregulation of the two hormones might result in the reduction of pathogens in roots and rhizosphere such as Colletotrichum and Verticillium. GA.sub.3-treated female papaya increased the abundance of beneficial bacteria species including Mycobacterium, Mitsuaria, and Actinophytocola, but decreased that of the genera Candidatus and Bryobacter for that it required less nitrate. Overall, the roots and rhizosphere of female papaya positively respond to exogenous application of GA.sub.3 to promote development and stress tolerance. Treatment of female papaya with GA3 might result in the promotion of lateral root formation and development by upregulating CpLBD16 and downregulating CpBP. GA.sub.3-treated papaya roots exhibited feedback control of brassinolide and jasmonate signaling in root development and defense. These findings revealed complex response to a growth hormone treatment in papaya roots and rhizosphere and will lead to investigations on the impact of other plant hormones on belowground development in papaya. Keywords: Papaya, Root, rhizosphere, Metabolome, Microbiome, Transcriptome
Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA3 by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and rhizosphere of GA3-treated and control female papaya. The results demonstrated that exogenous GA3 treatment enhanced female papaya lateral root development, which gave plants physical advantages of water and nutrient uptake. In addition, it was likely that GA3 spraying in papaya shoot apices increased the level of auxin, which was transported to roots by CpPIN1, where auxin upregulated CpLBD16 and repressed CpBP to promote the lateral root initiation and development. In papaya roots, corresponding transporters (CpTMT3, CpNRT1:2, CpPHT1;4, CpINT2, CpCOPT2, CpABCB11, CpNIP4;1) were upregulated and excretion transporters were downregulated such as CpNAXT1 for water and nutrients uptake with exogenous GA3 application. Moreover, in GA3-treated papaya roots, CpALS3 and CpMYB62 were downregulated, indicating a stronger abiotic resistance to aluminum toxic and phosphate starvation. On the other hand, BRs and JAs, which involve in defense responses, were enriched in the roots and rhizosphere of GA3-treated papayas. The upregulation of the two hormones might result in the reduction of pathogens in roots and rhizosphere such as Colletotrichum and Verticillium. GA3-treated female papaya increased the abundance of beneficial bacteria species including Mycobacterium, Mitsuaria, and Actinophytocola, but decreased that of the genera Candidatus and Bryobacter for that it required less nitrate. Overall, the roots and rhizosphere of female papaya positively respond to exogenous application of GA3 to promote development and stress tolerance. Treatment of female papaya with GA3 might result in the promotion of lateral root formation and development by upregulating CpLBD16 and downregulating CpBP. GA3-treated papaya roots exhibited feedback control of brassinolide and jasmonate signaling in root development and defense. These findings revealed complex response to a growth hormone treatment in papaya roots and rhizosphere and will lead to investigations on the impact of other plant hormones on belowground development in papaya.Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the exogenous application of GA3 by investigating the transcriptome profile in roots, metabolic profile and microbial community in both roots and rhizosphere of GA3-treated and control female papaya. The results demonstrated that exogenous GA3 treatment enhanced female papaya lateral root development, which gave plants physical advantages of water and nutrient uptake. In addition, it was likely that GA3 spraying in papaya shoot apices increased the level of auxin, which was transported to roots by CpPIN1, where auxin upregulated CpLBD16 and repressed CpBP to promote the lateral root initiation and development. In papaya roots, corresponding transporters (CpTMT3, CpNRT1:2, CpPHT1;4, CpINT2, CpCOPT2, CpABCB11, CpNIP4;1) were upregulated and excretion transporters were downregulated such as CpNAXT1 for water and nutrients uptake with exogenous GA3 application. Moreover, in GA3-treated papaya roots, CpALS3 and CpMYB62 were downregulated, indicating a stronger abiotic resistance to aluminum toxic and phosphate starvation. On the other hand, BRs and JAs, which involve in defense responses, were enriched in the roots and rhizosphere of GA3-treated papayas. The upregulation of the two hormones might result in the reduction of pathogens in roots and rhizosphere such as Colletotrichum and Verticillium. GA3-treated female papaya increased the abundance of beneficial bacteria species including Mycobacterium, Mitsuaria, and Actinophytocola, but decreased that of the genera Candidatus and Bryobacter for that it required less nitrate. Overall, the roots and rhizosphere of female papaya positively respond to exogenous application of GA3 to promote development and stress tolerance. Treatment of female papaya with GA3 might result in the promotion of lateral root formation and development by upregulating CpLBD16 and downregulating CpBP. GA3-treated papaya roots exhibited feedback control of brassinolide and jasmonate signaling in root development and defense. These findings revealed complex response to a growth hormone treatment in papaya roots and rhizosphere and will lead to investigations on the impact of other plant hormones on belowground development in papaya.
ArticleNumber 35
Audience Academic
Author Jia, Haifeng
Zhou, Yongmei
Ming, Ray
Pang, Ziqin
Yuan, Zhaonian
Author_xml – sequence: 1
  givenname: Yongmei
  surname: Zhou
  fullname: Zhou, Yongmei
– sequence: 2
  givenname: Ziqin
  surname: Pang
  fullname: Pang, Ziqin
– sequence: 3
  givenname: Haifeng
  surname: Jia
  fullname: Jia, Haifeng
– sequence: 4
  givenname: Zhaonian
  surname: Yuan
  fullname: Yuan, Zhaonian
– sequence: 5
  givenname: Ray
  surname: Ming
  fullname: Ming, Ray
BookMark eNqFkl1rFDEUhgep2Hb1D3g14I1eTM3X5ONGWIrWhYJQFS9DJnOymzI7GZNsaf31ZnaLuCJKLhJOnvc94eQ9r07GMEJVvcToAmPJ3yZMpEANIqRBDJG24U-qM8wEbggh6uS382l1ntItQlhIpp5Vp5RzRgQhZ9W3G0hTGBOkOrg6hpBTbca-jhv_I6RpAxHmCwdbM0A9mck8mDqHOm-ghvuwhjHsimKaBm9N9mGc6aslfV49dWZI8OJxX1RfP7z_cvmxuf50tbpcXje2FSo3rQNnBO6M6riUvQDh-k7QXrWKOuKsUNRiKQxGWDHGne2I7KXi1KCOSQd0Ua0Ovn0wt3qKfmvigw7G630hxLU2MXs7gG5BqdKBCYlaBpJ2xcEwx3rDWuIcKV7vDl7TrttCb2HM0QxHpsc3o9_odbjTSjLMGS8Grx8NYvi-g5T11icLw2BGKGPSREqhFBaI_B8VnCPeyjKHRfXqgK7LF2g_ulCa2xnXS0Epo4gKXKiLv1Bl9bD1tgTH-VI_Erw5EhQmw31em11KevX55pglB9bGkFIE92soGOk5i_qQRV2yqPdZ1PM05B8i6_M-I-VlfviX9CeJz-Ic
CitedBy_id crossref_primary_10_5004_dwt_2023_30012
crossref_primary_10_1080_01140671_2024_2412123
crossref_primary_10_1007_s11103_023_01373_1
crossref_primary_10_3390_applbiosci2020014
crossref_primary_10_3390_microorganisms11092364
crossref_primary_10_1007_s44372_025_00149_9
Cites_doi 10.3109/07388551.2011.615297
10.1111/j.1365-313X.2004.02161.x
10.1186/gb-2010-11-10-r106
10.1016/j.ygeno.2019.05.022
10.1104/pp.109.143685
10.1016/S1002-0160(21)60061-9
10.1038/nrm3088
10.1093/mp/ssn081
10.1105/tpc.111.086355
10.1007/s00299-014-1728-y
10.1016/j.semcdb.2006.11.013
10.1104/pp.75.1.255
10.1093/nar/gkac963
10.1007/s00018-018-2861-5
10.1128/AEM.00062-07
10.1016/j.rhisph.2021.100454
10.1104/pp.113.218164
10.21273/HORTSCI.49.3.378
10.1890/12-2010.1
10.1016/j.plaphy.2013.02.011
10.1016/j.tplants.2013.04.006
10.1105/tpc.106.047290
10.1104/pp.19.01220
10.1016/j.rhisph.2022.100550
10.1093/bioinformatics/btr381
10.1007/s11274-011-0979-9
10.3767/003158517X692788
10.1007/s00709-018-1218-0
10.1111/tpj.14781
10.1016/j.indcrop.2022.114899
10.1016/j.jare.2019.03.004
10.1016/j.biocontrol.2016.02.013
10.1371/journal.pone.0061217
10.1038/nprot.2016.095
10.1016/j.micres.2018.01.010
10.1104/pp.15.00578
10.1105/tpc.114.125419
10.1104/pp.112.212407
10.1093/jxb/erq143
10.1016/j.micres.2019.02.001
10.1371/journal.pone.0039333
10.1105/tpc.106.048173
10.1021/acs.est.0c03767
10.1134/S1021443717030189
10.1111/tpj.12648
10.1007/s11104-009-9929-9
10.1093/bioinformatics/btu170
10.1093/jxb/erm236
10.1128/AEM.02294-08
10.3389/fmicb.2021.637526
10.1038/ncb1726
10.1186/s40168-018-0615-0
10.1111/nph.13312
10.1016/j.bbrc.2020.08.025
10.1111/j.1364-3703.2006.00323.x
ContentType Journal Article
Copyright COPYRIGHT 2023 BioMed Central Ltd.
2023. The Author(s).
The Author(s) 2023
Copyright_xml – notice: COPYRIGHT 2023 BioMed Central Ltd.
– notice: 2023. The Author(s).
– notice: The Author(s) 2023
DBID AAYXX
CITATION
ISR
7X8
7S9
L.6
5PM
DOA
DOI 10.1186/s12870-022-04025-6
DatabaseName CrossRef
Gale In Context: Science
MEDLINE - Academic
AGRICOLA
AGRICOLA - Academic
PubMed Central (Full Participant titles)
DOAJ Directory of Open Access Journals
DatabaseTitle CrossRef
MEDLINE - Academic
AGRICOLA
AGRICOLA - Academic
DatabaseTitleList
AGRICOLA
CrossRef




MEDLINE - Academic
Database_xml – sequence: 1
  dbid: DOA
  name: DOAJ Directory of Open Access Journals
  url: https://www.doaj.org/
  sourceTypes: Open Website
DeliveryMethod fulltext_linktorsrc
Discipline Botany
EISSN 1471-2229
EndPage 35
ExternalDocumentID oai_doaj_org_article_5e99d7e478054e83bb48a4f4da452ff2
PMC9841646
A733430371
10_1186_s12870_022_04025_6
GeographicLocations China
GeographicLocations_xml – name: China
GroupedDBID ---
0R~
23N
2WC
2XV
53G
5GY
5VS
6J9
7X2
7X7
88E
8FE
8FH
8FI
8FJ
A8Z
AAFWJ
AAHBH
AAJSJ
AASML
AAYXX
ABDBF
ABUWG
ACGFO
ACGFS
ACIHN
ACPRK
ACUHS
ADBBV
ADRAZ
ADUKV
AEAQA
AENEX
AEUYN
AFKRA
AFPKN
AFRAH
AHBYD
AHMBA
AHYZX
ALIPV
ALMA_UNASSIGNED_HOLDINGS
AMKLP
AMTXH
AOIJS
APEBS
ATCPS
BAPOH
BAWUL
BBNVY
BCNDV
BENPR
BFQNJ
BHPHI
BMC
BPHCQ
BVXVI
C6C
CCPQU
CITATION
CS3
DIK
DU5
E3Z
EAD
EAP
EAS
EBD
EBLON
EBS
EMB
EMK
EMOBN
ESX
F5P
FYUFA
GROUPED_DOAJ
GX1
HCIFZ
HMCUK
HYE
IAG
IAO
IEP
IGH
IGS
IHR
INH
INR
ISR
ITC
KQ8
LK8
M0K
M1P
M48
M7P
M~E
O5R
O5S
OK1
OVT
P2P
PGMZT
PHGZM
PHGZT
PIMPY
PQQKQ
PROAC
PSQYO
RBZ
RNS
ROL
RPM
RSV
SBL
SOJ
SV3
TR2
TUS
U2A
UKHRP
WOQ
WOW
XSB
PMFND
7X8
PPXIY
PQGLB
7S9
L.6
PJZUB
5PM
PUEGO
ID FETCH-LOGICAL-c579t-5fefa71ba9b688d7e7fdb73d9593f2fc793c187a1019446fcb28d8963a0b48fe3
IEDL.DBID M48
ISSN 1471-2229
IngestDate Wed Aug 27 01:29:35 EDT 2025
Thu Aug 21 18:39:16 EDT 2025
Mon Jul 21 11:16:25 EDT 2025
Fri Jul 11 01:43:21 EDT 2025
Tue Jun 17 21:45:19 EDT 2025
Tue Jun 10 20:26:10 EDT 2025
Fri Jun 27 05:36:29 EDT 2025
Tue Jul 01 03:52:34 EDT 2025
Thu Apr 24 23:04:20 EDT 2025
IsDoiOpenAccess true
IsOpenAccess true
IsPeerReviewed true
IsScholarly true
Issue 1
Language English
License Open AccessThis article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.
LinkModel DirectLink
MergedId FETCHMERGED-LOGICAL-c579t-5fefa71ba9b688d7e7fdb73d9593f2fc793c187a1019446fcb28d8963a0b48fe3
Notes ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
OpenAccessLink http://journals.scholarsportal.info/openUrl.xqy?doi=10.1186/s12870-022-04025-6
PMID 36642722
PQID 2766065859
PQPubID 23479
PageCount 1
ParticipantIDs doaj_primary_oai_doaj_org_article_5e99d7e478054e83bb48a4f4da452ff2
pubmedcentral_primary_oai_pubmedcentral_nih_gov_9841646
proquest_miscellaneous_2887991702
proquest_miscellaneous_2766065859
gale_infotracmisc_A733430371
gale_infotracacademiconefile_A733430371
gale_incontextgauss_ISR_A733430371
crossref_primary_10_1186_s12870_022_04025_6
crossref_citationtrail_10_1186_s12870_022_04025_6
ProviderPackageCode CITATION
AAYXX
PublicationCentury 2000
PublicationDate 2023-01-16
PublicationDateYYYYMMDD 2023-01-16
PublicationDate_xml – month: 01
  year: 2023
  text: 2023-01-16
  day: 16
PublicationDecade 2020
PublicationPlace London
PublicationPlace_xml – name: London
PublicationTitle BMC plant biology
PublicationYear 2023
Publisher BioMed Central Ltd
BioMed Central
BMC
Publisher_xml – name: BioMed Central Ltd
– name: BioMed Central
– name: BMC
References C Rodrigues (4025_CR4) 2012; 32
K Liao (4025_CR38) 2020; 182
M Pertea (4025_CR48) 2016; 11
I Afzal (4025_CR41) 2019; 221
J Lavenus (4025_CR29) 2013; 18
W Liu (4025_CR34) 2018; 75
E Fadeev (4025_CR51) 2021; 12
YL Huang (4025_CR52) 2016; 98
4025_CR20
BC Willige (4025_CR32) 2011; 23
P Soucek (4025_CR36) 2017; 64
MA Domagalska (4025_CR30) 2011; 12
JS Suchodolski (4025_CR56) 2012; 7
S Ubeda-Tomas (4025_CR3) 2008; 10
Y Shiri (4025_CR6) 2020; 112
A Hodge (4025_CR12) 2009; 321
MM Aslam (4025_CR16) 2022; 32
PJ McMurdie (4025_CR55) 2013; 8
MJ Anderson (4025_CR57) 2013; 83
HW Lee (4025_CR35) 2015; 168
Segonzac Cc (4025_CR25) 2007; 19
G Li (4025_CR11) 2015; 34
JE Moreno (4025_CR40) 2013; 162
4025_CR50
S Compant (4025_CR17) 2019; 19
S Anders (4025_CR49) 2010; 11
S Salazar-Cerezo (4025_CR2) 2018; 208
DM Law (4025_CR31) 1984; 75
4025_CR15
H Shin (4025_CR21) 2004; 39
A Perea-Garcia (4025_CR23) 2013; 162
VM Sponsel (4025_CR1) 2010
P Soucek (4025_CR37) 2007; 58
RC Edgar (4025_CR53) 2011; 27
J Li (4025_CR24) 2020; 533
CD Canto (4025_CR18) 2020; 103
A Wormit (4025_CR22) 2006; 18
PN Bhattacharyya (4025_CR19) 2012; 28
BN Devaiah (4025_CR27) 2009; 2
R Ming (4025_CR8) 2007; 18
P Vandenkoornhuyse (4025_CR14) 2015; 206
4025_CR42
K Kazan (4025_CR39) 2014; 26
4025_CR46
SK Bose (4025_CR5) 2013; 66
NL Ward (4025_CR43) 2009; 75
J Bose (4025_CR26) 2010; 61
LD Wasilewska (4025_CR7) 1984; 31
YZ Diao (4025_CR44) 2017; 38
QY Liu (4025_CR10) 2018; 255
T Regnault (4025_CR28) 2014; 80
HW Lee (4025_CR33) 2009; 151
J Han (4025_CR9) 2014; 49
L Tian (4025_CR13) 2020; 54
Q Wang (4025_CR54) 2007; 73
EF Fradin (4025_CR45) 2006; 7
AM Bolger (4025_CR47) 2014; 30
References_xml – volume: 32
  start-page: 263
  issue: 3
  year: 2012
  ident: 4025_CR4
  publication-title: Crit Rev Biotechnol
  doi: 10.3109/07388551.2011.615297
– volume: 39
  start-page: 629
  issue: 4
  year: 2004
  ident: 4025_CR21
  publication-title: Plant J
  doi: 10.1111/j.1365-313X.2004.02161.x
– volume: 11
  start-page: R106
  issue: 10
  year: 2010
  ident: 4025_CR49
  publication-title: Genome Biol
  doi: 10.1186/gb-2010-11-10-r106
– volume: 112
  start-page: 820
  issue: 1
  year: 2020
  ident: 4025_CR6
  publication-title: Genomics
  doi: 10.1016/j.ygeno.2019.05.022
– volume: 151
  start-page: 1377
  issue: 3
  year: 2009
  ident: 4025_CR33
  publication-title: Plant Physiol
  doi: 10.1104/pp.109.143685
– volume: 32
  start-page: 61
  issue: 1
  year: 2022
  ident: 4025_CR16
  publication-title: Pedosphere
  doi: 10.1016/S1002-0160(21)60061-9
– volume: 12
  start-page: 211
  issue: 4
  year: 2011
  ident: 4025_CR30
  publication-title: Nat Rev Mol Cell Biol
  doi: 10.1038/nrm3088
– volume: 2
  start-page: 43
  issue: 1
  year: 2009
  ident: 4025_CR27
  publication-title: Mol Plant
  doi: 10.1093/mp/ssn081
– volume: 23
  start-page: 2184
  issue: 6
  year: 2011
  ident: 4025_CR32
  publication-title: Plant Cell
  doi: 10.1105/tpc.111.086355
– volume: 34
  start-page: 483
  issue: 3
  year: 2015
  ident: 4025_CR11
  publication-title: Plant Cell Rep
  doi: 10.1007/s00299-014-1728-y
– volume: 18
  start-page: 401
  issue: 3
  year: 2007
  ident: 4025_CR8
  publication-title: Semin Cell Dev Biol
  doi: 10.1016/j.semcdb.2006.11.013
– volume: 75
  start-page: 255
  issue: 1
  year: 1984
  ident: 4025_CR31
  publication-title: Plant Physiol
  doi: 10.1104/pp.75.1.255
– ident: 4025_CR50
  doi: 10.1093/nar/gkac963
– volume: 75
  start-page: 3329
  issue: 18
  year: 2018
  ident: 4025_CR34
  publication-title: Cell Mol Life Sci
  doi: 10.1007/s00018-018-2861-5
– volume: 73
  start-page: 5261
  issue: 16
  year: 2007
  ident: 4025_CR54
  publication-title: Appl Environl Microb
  doi: 10.1128/AEM.00062-07
– ident: 4025_CR20
  doi: 10.1016/j.rhisph.2021.100454
– volume: 162
  start-page: 1006
  issue: 2
  year: 2013
  ident: 4025_CR40
  publication-title: Plant Physiol
  doi: 10.1104/pp.113.218164
– volume: 49
  start-page: 378
  issue: 3
  year: 2014
  ident: 4025_CR9
  publication-title: Hortscience
  doi: 10.21273/HORTSCI.49.3.378
– volume: 83
  start-page: 557
  issue: 4
  year: 2013
  ident: 4025_CR57
  publication-title: Ecol Monogr
  doi: 10.1890/12-2010.1
– volume: 66
  start-page: 150
  year: 2013
  ident: 4025_CR5
  publication-title: Plant Physiol Biochem
  doi: 10.1016/j.plaphy.2013.02.011
– volume: 18
  start-page: 450
  issue: 8
  year: 2013
  ident: 4025_CR29
  publication-title: Trends Plant Sci
  doi: 10.1016/j.tplants.2013.04.006
– volume: 18
  start-page: 3476
  issue: 12
  year: 2006
  ident: 4025_CR22
  publication-title: Plant Cell
  doi: 10.1105/tpc.106.047290
– volume: 182
  start-page: 1066
  issue: 2
  year: 2020
  ident: 4025_CR38
  publication-title: Plant Physiol
  doi: 10.1104/pp.19.01220
– ident: 4025_CR42
  doi: 10.1016/j.rhisph.2022.100550
– volume: 27
  start-page: 2194
  issue: 16
  year: 2011
  ident: 4025_CR53
  publication-title: Bioinformatics
  doi: 10.1093/bioinformatics/btr381
– volume: 28
  start-page: 1327
  issue: 4
  year: 2012
  ident: 4025_CR19
  publication-title: World J Microbiol Biotechnol
  doi: 10.1007/s11274-011-0979-9
– volume: 38
  start-page: 20
  year: 2017
  ident: 4025_CR44
  publication-title: Persoonia
  doi: 10.3767/003158517X692788
– volume: 255
  start-page: 1107
  issue: 4
  year: 2018
  ident: 4025_CR10
  publication-title: Protoplasma
  doi: 10.1007/s00709-018-1218-0
– volume-title: Hedden PJphbsta: Gibberellin Biosynthesis and Inactivation
  year: 2010
  ident: 4025_CR1
– volume: 103
  start-page: 951
  issue: 3
  year: 2020
  ident: 4025_CR18
  publication-title: Plant J
  doi: 10.1111/tpj.14781
– ident: 4025_CR46
  doi: 10.1016/j.indcrop.2022.114899
– volume: 19
  start-page: 29
  year: 2019
  ident: 4025_CR17
  publication-title: J Adv Res
  doi: 10.1016/j.jare.2019.03.004
– volume: 98
  start-page: 27
  year: 2016
  ident: 4025_CR52
  publication-title: Biol Control
  doi: 10.1016/j.biocontrol.2016.02.013
– volume: 8
  start-page: e61217
  issue: 4
  year: 2013
  ident: 4025_CR55
  publication-title: PLoS One
  doi: 10.1371/journal.pone.0061217
– volume: 11
  start-page: 1650
  issue: 9
  year: 2016
  ident: 4025_CR48
  publication-title: Nat Protoc
  doi: 10.1038/nprot.2016.095
– volume: 208
  start-page: 85
  year: 2018
  ident: 4025_CR2
  publication-title: Microbiol Res
  doi: 10.1016/j.micres.2018.01.010
– volume: 168
  start-page: 1792
  issue: 4
  year: 2015
  ident: 4025_CR35
  publication-title: Plant Physiol
  doi: 10.1104/pp.15.00578
– volume: 26
  start-page: 2285
  issue: 6
  year: 2014
  ident: 4025_CR39
  publication-title: Plant Cell
  doi: 10.1105/tpc.114.125419
– volume: 162
  start-page: 180
  issue: 1
  year: 2013
  ident: 4025_CR23
  publication-title: Plant Physiol
  doi: 10.1104/pp.112.212407
– volume: 61
  start-page: 3163
  issue: 11
  year: 2010
  ident: 4025_CR26
  publication-title: J Exp Bot
  doi: 10.1093/jxb/erq143
– volume: 221
  start-page: 36
  year: 2019
  ident: 4025_CR41
  publication-title: Microbiol Res
  doi: 10.1016/j.micres.2019.02.001
– volume: 31
  start-page: 91
  issue: 1
  year: 1984
  ident: 4025_CR7
  publication-title: Acta Biochim Pol
– volume: 7
  start-page: e39333
  issue: 6
  year: 2012
  ident: 4025_CR56
  publication-title: PLoS One
  doi: 10.1371/journal.pone.0039333
– volume: 19
  start-page: 3760
  issue: 11
  year: 2007
  ident: 4025_CR25
  publication-title: Plant Cell
  doi: 10.1105/tpc.106.048173
– volume: 54
  start-page: 13137
  issue: 20
  year: 2020
  ident: 4025_CR13
  publication-title: Environ Sci Technol
  doi: 10.1021/acs.est.0c03767
– volume: 64
  start-page: 386
  issue: 3
  year: 2017
  ident: 4025_CR36
  publication-title: Russ J Plant Physl+
  doi: 10.1134/S1021443717030189
– volume: 80
  start-page: 462
  issue: 3
  year: 2014
  ident: 4025_CR28
  publication-title: Plant J
  doi: 10.1111/tpj.12648
– volume: 321
  start-page: 153
  issue: 1–2
  year: 2009
  ident: 4025_CR12
  publication-title: Plant Soil
  doi: 10.1007/s11104-009-9929-9
– volume: 30
  start-page: 2114
  issue: 15
  year: 2014
  ident: 4025_CR47
  publication-title: Bioinformatics
  doi: 10.1093/bioinformatics/btu170
– volume: 58
  start-page: 3797
  issue: 13
  year: 2007
  ident: 4025_CR37
  publication-title: J Exp Bot
  doi: 10.1093/jxb/erm236
– volume: 75
  start-page: 2046
  issue: 7
  year: 2009
  ident: 4025_CR43
  publication-title: Appl Environ Microbiol
  doi: 10.1128/AEM.02294-08
– volume: 12
  start-page: 637526
  year: 2021
  ident: 4025_CR51
  publication-title: Front Microbiol
  doi: 10.3389/fmicb.2021.637526
– volume: 10
  start-page: 625
  issue: 5
  year: 2008
  ident: 4025_CR3
  publication-title: Nat Cell Biol
  doi: 10.1038/ncb1726
– ident: 4025_CR15
  doi: 10.1186/s40168-018-0615-0
– volume: 206
  start-page: 1196
  issue: 4
  year: 2015
  ident: 4025_CR14
  publication-title: New Phytol
  doi: 10.1111/nph.13312
– volume: 533
  start-page: 104
  issue: 1
  year: 2020
  ident: 4025_CR24
  publication-title: Biochem Biophys Res Commun
  doi: 10.1016/j.bbrc.2020.08.025
– volume: 7
  start-page: 71
  issue: 2
  year: 2006
  ident: 4025_CR45
  publication-title: Mol Plant Pathol
  doi: 10.1111/j.1364-3703.2006.00323.x
SSID ssj0017849
Score 2.3947942
Snippet Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond to the...
Abstract Exogenous GAs have an indeterminate effect on root development. Our current study used female papaya to reveal how the roots and rhizosphere respond...
SourceID doaj
pubmedcentral
proquest
gale
crossref
SourceType Open Website
Open Access Repository
Aggregation Database
Enrichment Source
Index Database
StartPage 35
SubjectTerms Agricultural research
aluminum
auxins
brassinolide
Colletotrichum
Development
excretion
females
Gibberellins
jasmonic acid
lateral roots
Metabolome
microbial communities
Microbiome
Mitsuaria
Mycobacterium
nitrates
nutrient uptake
Papaya
phosphates
Physiological aspects
Plants
Rhizosphere
Root
Roots (Botany)
somatotropin
species
starvation
stress tolerance
toxicity
Transcriptome
Verticillium
SummonAdditionalLinks – databaseName: DOAJ Directory of Open Access Journals
  dbid: DOA
  link: http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwrV1Nb9QwELVQxYEL4lMsFGQQEgdkNXEcfxy3iFKQ4FCo6M2yYw9UgqRqUon-e2aSbLUBqVy4xhMleZ7xPMfjZ8ZeJhcssqFaWNWAUC4n4XQsRKhSqWUCEw3tHf74SR8eqw8n9cnWUV9UEzbJA0_A7dXZuWSyIu19lW0Vo7JBgUpB1RJgHH0x520mU_P6gbHKbbbIWL3Xl7SeJ6hyHZ1W1kIv0tCo1v_3mPxnneRW4jm4w27PjJGvpze9y27k9h67ud8hq7u8z74eTUWuuecdcKTBQ89Dm_g51dL1pBmQqQHyT3wqP8PUeBn40HHkfTz_6iaJVr61jE3W79bVA3Z88PbLm0MxH5Ygmtq4QdSQIZgyBhe1tYiYgRRNlUh4GCQ0GIdNaU3AEHQ4BYQmSpsshl8oEFHI1UO203ZtfsR4KcGWUABaFIi0s05mnaUxmFDxTrdi5QY738xK4nSgxQ8_ziis9hPeHvH2I95er9jrq3vOJh2Na633qUuuLEkDe7yAnuFnz_D_8owVe0Ed6knloqUymm_hou_9-89Hfm2qSlWkVrhir2Yj6PAbmjDvSkAkSBhrYbm7sMQwbBbNzzd-46mJatfajF3opdGaiF7trrHBsR6Zuinwrc3C6RYYLFva0--jHrijpWOlH_8P0J6wWxJpHP1kKvUu2xnOL_JTpF1DfDZG2G8tZCnn
  priority: 102
  providerName: Directory of Open Access Journals
Title Responses of roots and rhizosphere of female papaya to the exogenous application of GA3
URI https://www.proquest.com/docview/2766065859
https://www.proquest.com/docview/2887991702
https://pubmed.ncbi.nlm.nih.gov/PMC9841646
https://doaj.org/article/5e99d7e478054e83bb48a4f4da452ff2
Volume 23
hasFullText 1
inHoldings 1
isFullTextHit
isPrint
link http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwjV1Lb9QwELb64MAF8RRLy8ogJA4okDiOHweEdlFLQWqFFlasuFhObBekNimbVOr-e2aSbGmgqrjsYT3Zjcf-Mp_j8TeEvHDaKmBDWaR4ESKuvYu0yOPIpi4RzAWZSzw7fHgkDub80yJbbJB1uaPegfW1SzusJzVfnry--LV6B4B_2wJeiTd1grt1Eealw5RkWSQ2yTZEJolAPeR_dhWkaulwAg_kCOtYrw_RXPsbg0DV6vn_-9T-O5PySmjav0vu9JySTrpJcI9s-PI-uTWtgPetHpBvsy4N1te0ChSIclNTWzq6xGy7GlUFPDYEfwr_Ss8geK4sbSoKzJD6i6oTcaVXNrrR-sMkfUjm-3tf3x9EfTmFqMikbqIs-GBlkludC6Wc9DK4XKYOpYkDCwUgtUiUtABSDYvEUORMOQUAtXHOVfDpI7JVVqV_TGjCgkpCHMAi5oFrpZkXnkkJIReu1COSrH1nil5rHEtenJh2zaGE6fxtwN-m9bcRI_Lq8pqzTmnjRuspDsmlJapkt19Uy2PTg85kXmvoJ8e6DdyrNId-WLhfZ3nGQmAj8hwH1KAORomJNsf2vK7Nxy8zM5FpylPUMxyRl71RqKAPhe3PLYAnUDprYLk7sASgFoPmZ-t5Y7AJs9tKD0NomBQCqWCmb7CBaABcXsZw13Iw6QY-GLaUP3-0iuEaN5e5ePLfXdkhtxmwOXzXlIhdstUsz_1TYF9NPiabciHHZHu6d_R5Nm7fYYxbmMHnbPr9NxBHLsI
linkProvider Scholars Portal
openUrl ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=Responses+of+roots+and+rhizosphere+of+female+papaya+to+the+exogenous+application+of+GA3&rft.jtitle=BMC+plant+biology&rft.au=Zhou%2C+Yongmei&rft.au=Pang%2C+Ziqin&rft.au=Jia%2C+Haifeng&rft.au=Yuan%2C+Zhaonian&rft.date=2023-01-16&rft.pub=BioMed+Central+Ltd&rft.issn=1471-2229&rft.eissn=1471-2229&rft.volume=23&rft.issue=1&rft_id=info:doi/10.1186%2Fs12870-022-04025-6&rft.externalDocID=A733430371
thumbnail_l http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=1471-2229&client=summon
thumbnail_m http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=1471-2229&client=summon
thumbnail_s http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=1471-2229&client=summon