References
Adams E H G, Spoel S H. (2018). The ubiquitin–proteasome system as a
transcriptional regulator of plant immunity. Journal of Experimental
Botany, 69, 4529-4537.
Alcaide-Loridan C, Jupin I. (2012). Ubiquitin and plant viruses, let’s
play together! Plant Physiology, 160, 72-82.
An J-P, Liu Y, Zhang X, Bi S, Wang X-F, You C-X, Hao Y. (2020 d).
Dynamic regulation of anthocyanin biosynthesis at different light
intensities by the BT2-TCP46-MYB1 module in apple. Journal of
Experimental Botany, 71, 3094-3109.
An J-P, Wang X-F, Hao Y. (2020 a). BTB/TAZ protein MdBT2 integrates
multiple hormonal and environmental signals to regulate anthocyanin
biosynthesis in apple. Journal of Integrative Plant Biology, 62(11),
1643-1646.
An J-P, Wang X-F, Zhang X, Bi S, You C-X, Hao Y. (2019 c). MdBBX22
regulates UV-B-induced anthocyanin biosynthesis through regulating the
function of MdHY5 and is targeted by MdBT2 for 26 proteasome-mediated
degradation. Plant Biotechnology Journal, 17, 2231-2233.
An J-P, Wang X-F, Zhang X, You C-X, Hao Y. (2021). Apple MdBT2 protein
negatively regulates jasmonic acid-triggered leaf senescence by
modulating the stability of MYC2 and JAZ2. Plant, Cell & Environment,
44(1), 216-233.
An J-P, Yao J-F, Xu R-R, You C-X, Wang X-F, Hao Y-J. (2018). Apple bZIP
transcription factor MdbZIP44 regulates abscisic acid-promoted
anthocyanin accumulation. Plant, Cell and Environment, 41, 2678-2692.
An J-P, Zhang X, Bi S, You C-X, Wang X-F, Hao Y. (2019 a). MdbHLH93, an
apple activator regulating leaf senescence, is regulated by ABA and
MdBT2 in antagonistic ways. New Phytologist, 222, 735-751.
An J-P, Zhang X, Bi S, You C-X, Wang X-F, Hao Y. (2020 c). The ERF
transcription factor MdERF38 promotes drought stress-induced anthocyanin
biosynthesis in apple. Plant Journal, 101, 573-589.
An J-P, Zhang X, You C-X, Bi S, Wang X-F, Hao Y. (2019 b). MdWRKY40
promotes wounding-induced anthocyanin biosynthesis in association with
MdMYB1 and undergoes MdBT2-mediated degradation. New Phytologist, 224,
380-395.
Asai S, Yoshioka H. (2009). Nitric oxide as a partner of reactive oxygen
species participates in disease resistance to necrotrophic pathogen
Botrytis cinerea in Nicotiana benthamiana. Molecular Plant Microbe
Interaction, 22, 619-629.
Bachmair A, Novatchkova M, Potuschak T, Eisenhaber F. (2001).
Ubiquitylation in plants: a post-genomic look at a post-translational
modification. Trends in Plant Science, 6, 463-470.
Bujarski J, Figlerowicz M, Gallitelli D, Roossinck M, Scott S. (2012).
Family Bromoviridae. Virus Taxonomy, Ninth Report of the International
Committe on Taxonomy of Viruses. A. King, M. Adams, E. Carstens and E.
Lefkowitz. London, Academic Press: 965-976.
Calil I, Fontes E. (2017). Plant immunity against viruses: antiviral
immune receptors in focus. Annuals of Botany, 119, 711-723.
Camborde L, Planchais S, Tournier V, Jakubiec A, Drugeon G, Lacassagne
E, Pflieger S, Chenon M, Jupin I. (2010). The ubiquitin-proteasome
system regulates the accumulation of turnip yellow mosaic virus
RNA-dependent RNA polymerase during viral infection. The Plant Cell, 22,
3142-3152.
Chen H, Zou Y, Shang Y, Lin H, Wang Y, Cai R, Tang X, Zhou J. (2008).
Firefly luciferase complementation imaging system assay for
protein-protein interactions in plants. Plant Physiology, 146, 368-376.
Chen I-H, Chang J-E, Wu C-Y, Huang Y-P, Hsu Y-H, Tsai C-H. (2019). An E3
ubiquitin ligase from Nicotiana benthamiana targets the replicase of
bamboo mosaic virus and resticts its replication. Molecular Plant
Pathology, 20, 673-684.
Chen S, Songkumarn P, Liu J, Wang G. (2009). A versatile zero background
T-vector system for gene cloning and functional genomics. Plant
Physiology 150, 1111-1121.
Dai H, Li W, Han G, Yang Y, Ma Y, Li H, Zhang Z. (2013). Development of
a seedling clone with high regeneration capacity and susceptibility to
Agrobacterium in apple. Scientia Horticulturae, 164, 202-208.
Delledonne M, Xia Y, Dixon RA, Lamb C. (1998). Nitric oxide functions as
a signal in plant disease resistance. Nature, 394, 585-588.
Deng X, Zhu T, Zou L, Han X, Zhou X, Xi D, Zhang D, Lin H. (2016).
Orchestration of hydrogen peroxide and nitric oxide in
brassinosteroid-mediated systemic virus resistance in Nicotiana
benthamiana. Plant Journal, 85, 478-493.
Diaz A, Gallei A, Ahlquist P. (2012). Bromovirus RNA replication
compartment formation requires concerted action of 1a’s self-interacting
RNA capping and helicase domains. Journal of Virology, 86, 821-834.
Diaz A, Wang X. (2014). Bromovirus-induced remodeling of host membranes
during viral RNA replication. Current Opinion in Virology, 9, 104-110.
Dordas C. (2008). Role of nutrients in controlling plant diseases in
sustainable agriculture, A review. Agron. Sustain. Dev, 28, 33-46.
Drugeon G, Jupin I. (2002). Stability in vitro of the 69K movement
protein of turnip yellow mosaic virus is regulated by the
ubiquitin-mediated proteasome pathway. Journal of general virology, 83,
3187-3197.
Du L, Poovaiah B. (2004). A novel family of Ca2+/calmodulin-binding
proteins involved in transcription regulation: interaction with
fsh/Ring3 class transcription activatiors. Plant Molecular Biology, 54,
549-569.
Figueroa P, Gusmaroli G, Serino G, Habashi J, Ma L, Shen Y, Feng S,
Bostick M, Callis J, Hellmann H, Deng X W. (2005). Arabidopsis Has Two
Redundant Cullin3 Proteins That Are Essential for Embryo Development and
That Interact with RBX1 and BTB Proteins to Form Multisubunit E3
Ubiquitin Ligase Complexes in Vivo. The Plant Cell, 17, 1180-1195.
Genschik P, Sumara I, Lechner E. (2013). The emerging family of
CULLIN3-RING ubiquitin ligases (CRL3s): cellular functions and disease
implications. EMBO J, 32, 2307-2320.
Gingerich D J, Gagne J, Salter D, Hellmann H, Estelle M, Ma L, Vierstra
R D. (2005). Cullins 3a and 3b assemble with members of the broad
complex/tramtrack/bric-a-brac (BTB) protein family to form essential
ubiquitin-protein ligases (E3s) in Arabidopsis. Journal of biological
chemistry, 280, 18810-18821.
Gupta K, Brotman Y, Segu S, Zeier T, Zeier J, Persijn S, Cristescu SM,
Harren FJM, Bauwe H, Fernie AR, Kaiser WM, Luis AJM. (2013). The form of
nitrogen nutrition affects resistance against Pseudomonas
syringae pv. phaseolicola in tobacco. Journal of Experimental
Botany, 64(2), 553-568.
Han P, Wang C, Liu X, Dong Y, Jiang H, Hu D, Hao Y. (2019). BTB-BACK
domain E3 ligase MdPOB1 suppresses plant pathogen defense against
Botryosphaeria dothidea by ubiquitinating and degrading MdPUB29 protein
in apple. Plant and Cell physiology, 60, 2129-2140.
Ho C, Lin S, Hu H, Tsay Y. (2009). CHL1 functions as a nitrate sensor in
plants. Cell, 138, 1184-1194.
Hotton S, Callis J. (2008). Regulation of cullin RING ligases. Annual
Review of Plant Biology, 59, 467-489.
Hua Z, Vierstra R D. (2011). The cullin-RING ubiquitin-protein ligases.
Annual Review of Plant Biology, 62, 299-334.
Huber DM, and Watson RD. (1974). Nitrogen form and plant disease. Annu
Rev Phytopathol, 12, 139-165.
Incarbone M, Dunoyer P. (2013). RNA silencing and its suppression: novel
insights from in planta analysis. Trends in Plant Science, 18, 382-392.
Kao C C, Ahlquist P. (1992). Identification of the domains required for
direct interaction of the helicase-like and polymerase-like RNA
replication proteins of brome mosaic virus. Journal of Virology, 66,
7293-7302.
Klessig DF, Durner J, Noad R, Navarre DA, Wendehenne D, Kumar D, Zhou
JM, Shah J, Zhang S, Kachroo P. (2000). Nitric oxide and salicylic acid
signaling in plant defense. Proc Natl Acad Sci USA, 97, 8849-8855.
Kohrer K, Domdey H. (1991). Preparation of high molecular weight RNA.
Methods Enzymol, 194, 398-405.
Korner C, Klause D, Niehl A, Dominguez-Ferreras A, Chinchilla D, Boller
T, Heinlein M, Hann D. (2013). The immunity regulator BAK1 contributes
to resistance against diverse RNA viruses. Molecular Plant Microbe
Interaction, 26, 1271-1280.
Kumar D, Klessig DF. (2000). Differential induction of tobacco MAP
kinases by the defense signals nitric oxide, salicylic acid, ethylene,
and jasmonic acid. Molecular Plant Microbe Interaction, 13, 347-351.
Kunz S, Gardeström P, Pesquet E, Kleczkowski L A. (2015). Hexokinase 1
is required for glucose-induced repression of bZIP63, At5g22920, and BT2
in Arabidopsis. Frontiers in Plant Science, 6, 525.doi:
10.3389/fpls.2015.00525.
Lucas W. (2006). Plant viral movement proteins: agents for cell-to-cell
trafficking of viral genomes. Virology, 344, 169-184.
Mandadi K K, Misra A, Ren S, McKnight T D. (2009). BT2, a BTB protein,
mediates multiple responses to nutrients, stresses, and hormones in
Arabidopsis. Plant Physiology, 150, 1930-1939.
Mandadi K K, Scholthof K-B. (2013). Plant immune responses against
viruses: how does a virus cause disease? The Plant Cell 25, 1489-1505.
Mazzucotelli E, Belloni S, Marone D, De Leonardis A, Guerra D, Di Fonzo
N, Cattivelli L, Mastrangelo A. (2006). The e3 ubiquitin ligase gene
family in plants: regulation by dagradation. Current Genomics, 7,
509-522.
Metzger M, Pruneda J, Klevit R, Weissman A. (2014). RING-type E3
ligases: master manipulators of E2 ubiquitin-conjugating enzymes and
ubiquitination. Biochim. Biophy. Acta, 1843, 47-60.
Misra A, McKnight T D, Mandadi K K. (2018). Bromodomain proteins GTE9
and GTE11 are essential for specific BT2-mediated sugar and ABA
responses in Arabidopsis thaliana. Plant Molecular Biology, 96, 393-402.
Noda H, Yamagishi N, Yaegashi H, Xing F, Xie J, Li S, Zhou T, Ito T,
Yoshikawa N. (2017). Apple necrotic mosaic virus, a novel ilarvirus from
mosaic-diseased apple trees in Japan and China. Journal of General Plant
Pathology, 83, 83-90.
Orosa B, He Q, Mesmar J, Gilroy E, McLellan H, Yang C, Craig A, Bailey
M, Zhang C, Moore J, Boevink P, Tian Z, Birch P, Sadanandom A. (2017).
BTB-BACK domain protein POB1 suppresses immue cell death by targeting
ubiquitin E3 ligase PUB17 for degradation. PLoS Genetics, 13(1),
e1006540. doi: 10.1371/journal.pgen.1006540.
Petroski M, Deshaies R. (2005). Function and regulation of cullin-RING
ubiquitin ligases. Nature Review of Molecular Cell Biology, 6, 9-20.
Prod’homme D, Le Panse S, Drugeon G, Jupin I. (2001). Detection and
subcellular localization of the turnip yellow mosaic virus 66K
replication protein in infected cells. Virology, 281, 88-101.
Reichel C, Beachy R. (2000). Degradation of tobacco mosaic virus
movement protein by the 26S proteasome. . Journal of Virology, 74,
3330-3337.
Ren S, Mandadi K K, Boedeker A L, Rathore K S, McKnight T D. (2007).
Regulation of telomerase in Arabidopsis by BT2, an apparent target of
TELOMERASE ACTIVATOR1. The Plant Cell, 19, 23-31.
Scheible W, Morcuende R, Czechowski T, Fritz C, Osuna D, Palacios-Rojas
N, Schindelasch D, Thimm O, Udvardi M, Stitt M. (2004). Genome-wide
reprogramming of primary and secondary metabolism, protein synthesis,
cellular growth processes, and the regulatory infrastructure of
Arabidopsis in response to nitrogen. Plant Physiology, 136, 2483-2499.
Traynor P, Young B, Ahlquist P. (1991). Deletion analysis of brome
mosaic virus 2a protein: effects on RNA replication and systemic spread.
Journal of Virology, 65, 2807-2815.
Ueki S, Citovsky V. (2011). To gate, or not to gate: regulatory
mechanisms for intercellular protein transport and virus movement in
plants. Molecular Plant, 4, 782-793.
Vierstra R D. (2009). The ubiquitin-26S proteasome system at the nexus
of plant biology. Nature Reviews Molecular Cell BiolOgy, 10, 385-397.
Vogel F, Hofius D, Sonnewald U. (2007). Intracellular trafficking of
potato leafroll virus movement protein in transgenic Arabidopsis.
Traffic, 8, 1205-1214.
Walter M, Chaban C, Schutze K, Batistic O, Weckermann K, Nake C,
Blazevic D, Grefen C, Schumacher K, Oecking C, Harter K, Kudla J.
(2004). Visualization of protein interactions in living plant cells
using bimolecular fluorescence complementation. Plant Journal, 40,
428-438.
Wang F, Zhu D, Huang X, Li S, Gong Y, Yao Q, Fu X, Fan L, Deng X.
(2009). Biochemical insights on degradation of Arabidopsis DELLA
proteins gained from a cell-free assay system. The Plant Cell, 21,
2378-2390.
Wang X-F, An J-P, Liu X, Su L, You C-X, Hao Y. (2018). The
nitrate-responsive protein MdBT2 regulates anthocyanin biosynthesis by
interacting with the MdMYB1 transcription factor. Plant Physiology, 178,
890-906.
Wendehenne D, Gao Q, Kachroo A, Kachroo P. (2014). Free redical-mediated
systemic immunity in plants. Current Opinion in Plant Biology, 20C,
127-134.
Wendehenne D, Lamotte O, Frachisse JM, Barbier-Brygoo H, Pugin A.
(2002). Nitrate efflux is an essential component of the cryptogein
signaling pathway leading to defense responses and hypersensitive cell
death in tobacco. The Plant Cell, 14, 1937-1951.
Xing F, Robe B L, Zhang Z, Wang H, Li S. (2018). Genomic Analysis,
Sequence Diversity, and Occurrence of Apple necrotic mosaic virus, a
Novel Ilarvirus Associated with Mosaic Disease of Apple Trees in China.
Plant Disease, 102, 1841-1847.
Zhang Q, Gu K, Cheng L, Wang J, Yu J, Wang X-F, You C-X, Hu D, Hao Y.
(2020 a). BTB-TAZ domain protein MdBT2 modulates malate accumulation and
vacuolar acidification in response to nitrate. Plant Physiology, 183,
750-764.
Zhang Q, Gu K, Wang J, Yu J, Wang X-F, Zhang S, You C-X, Hu D, Hao Y.
(2020 b). BTB-BACK-TAZ domain protein MdBT2-mediated MdMYB73
ubiquitination negatively regulates malate accumulation and vacuolar
acidification in apple. Horticulture Research, 7, 151.
Zhang Z, Zhang F, Zheng P, Xie Y, You C-X, Hao Y. (2020). Determination
of protein interactions among replication componets of apple necrotic
mosaic virus. Viruses, 12, 474.
Zhao Q, Ren Y, Wang Q, You C-X, Hao Y. (2016). Ubiquitination-related
MdBT scaffold protein target a bHLH transcription factor for iron
homeostasis. Plant Physiology, 173, 1973-1988.
Zhou B, Zeng L. (2017). Conventional and unconventional ubiquitination
in plant immunity. Molecular Plant Pathology, 18, 1313-1330.
Zou L, Deng X, Zhang L, Zhu T, Tan W, Muhammad A, Zhu L, Zhang C, Zhang
D, Lin H. (2018). Nitric oxide as a signaling molecule in
brassinosteroid-mediated virus resistance to cucumber mosaic virus in
Arabidopsis thaliana. Physiologia Plantarum, 163, 196-210.