A new regulator of proanthocyanidin (PA) biosynthesis in grapes was found by screening genes coordinately expressed with PA accumulation under different light conditions using a substantially improved method of serial analysis of gene expression (SuperSAGE). This R2R3-MYB transcription factor, VvMYBPAR, shows high protein sequence similarity with PA biosynthesis-regulating plant MYBs, such as VvMYBPA2 and TRANSPARENT TESTA2. Its transcript levels were relatively high in the skins of young berries, whereas the levels were higher in the seeds and at a maximum around veraison. In addition to its response to modified light conditions, the gene responded to abscisic acid application in the skins of cultured berries. Among the PA-specific branch genes, this transcript profile was not correlated with that of VvANR and VvLAR1 but was closely related to that of VvLAR2, suggesting different regulation of PA-specific branch genes from that of a known PA regulator, VvMYBPA2. The PA-specific regulation of VvMYBPAR was confirmed by VvMYBPAR constitutive expression in Arabidopsis in which the transgene specifically induced PA biosynthetic genes and resulted in PA accumulation in plants grown on sucrose-supplemented media to induce anthocyanin synthesis. A transient reporter assay using grapevine cells showed that VvMYBPAR activated the promoters on PA-specific branch genes and candidate genes associated with modification and transport of monomeric PA precursors, as well as the promoters of VvCHS3 and VvF3'5'Hd in the common flavonoid pathway, but not that of VvUFGT on the anthocyanin-specific branch. This new factor suggests the polygenic regulation of PA biosynthesis in grapes by closely related MYB transcription factors.
We discovered that the origin of cT-DNA in the genome of wild-type Nicotiana glauca is the T-DNA of the mikimopine-type Ri plasmid (pRi) harbored in Agrobacterium rhizogenes. The cT-DNA was inserted into the genomic DNA of N. glauca from the position corresponding to the right border of mikimopine-type pRi. The cT-DNA contained two mikimopine synthase gene (mis) homologs, NgmisL and NgmisR, both of which were transcribed at low level in all N. glauca organs. NgMisR protein expressed in Escherichia coli has preserved Mis activity, which converts l-histidine and alpha-ketoglutaric acid to mikimopine. The mis homolog was also found in the genome of three other Nicotiana species: N. tomentosa, N. tomentosiformis, and N. tabacum; however, the site of insertion differed from that in N. glauca, suggesting that A. rhizogenes harboring mikimopine-type pRi independently infected the ancestors of some Nicotiana plants. This is the first clear evidence of a host-parasite relationship during the early evolution of Nicotiana plants. We propose that a new phylogenetic approach using opine type cT-DNA is applicable for presuming divergence in the genus Nicotiana.
SummaryThe rooting-locus gene B (rolB) on the T-DNA of the root-inducing (Ri) plasmid in Agrobacterium rhizogenes is responsible for the induction of transformed adventitious roots, although the root induction mechanism is unknown. We report here that the RolB protein of pRi1724 (1724RolB) is associated with Nicotiana tabacum 14-3-3-like protein vII (Nt14-3-3 vII) in tobacco bright yellow (BY)-2 cells. Nt14-3-3 vII directly interacts with 1724RolB protein. Green¯uorescent protein (GFP)-fused 1724RolB is localized to the nucleus. GFP-fused mutant 1724RolB proteins having a deletion or amino acid substitution are unable to interact with Nt14-3-3 vII and also show impaired nuclear localization. Moreover, these 1724RolB mutants show decreased capacity for adventitious root induction. These results suggest that adventitious root induction by 1724RolB protein correlates with its interaction with Nt14-3-3 vII and the nuclear localization of 1724RolB protein.
SummaryCells adapt to oxidative stress by transcriptional activation of genes encoding antioxidants and proteins of other protective roles. A bZIP transcription factor, Pap1, plays a critical role in this process and overexpression of Pap1 confers resistance to various oxidants and drugs in fission yeast. Pap1 temporarily enters the nucleus upon oxidative stress but returns to the cytoplasm once cells adapt to the stress, suggesting that cellular localization regulates Pap1 function. We report here an additional regulatory mechanism that Ubr1 ubiquitin ligase-dependent degradation lowered the Pap1 protein levels. ubr1 cells were causally resistant to hydrogen peroxide because of the increment of Pap1 levels. Pap1 was preferentially degraded in the nucleus where Ubr1 was consistently enriched. Proteolysis was critical to downregulate Pap1 especially when its activation persisted, as constitutively nuclear Pap1 severely inhibited growth in ubr1 mutants. Inactive mutations in the bZIP DNA binding domain stabilized Pap1 but rescued the lethality caused by constitutively active Pap1 in ubr1 mutants. These findings indicate that either nuclear export or Ubr1-mediated proteolysis must be operative to prevent uncontrolled Pap1 function. Coincidental dysfunction in both inhibitory pathways causes lethality because of prolonged activation of Pap1. Ubr1 is a critical regulator for the homeostasis of oxidative stress response.
GDP-D-mannose pyrophosphorylase (GMP) is an important enzyme in the Smirnoff-Wheeler's pathway for the biosynthesis of ascorbic acid (AsA) in plants. We have reported recently that the expression of the acerola (Malpighia glabra) GMP gene, designated MgGMP, correlates with the AsA content of the plant. The acerola plant has very high levels of AsA relative to better studied model plants such as Arabidopsis. Here we found that the GMP mRNA levels in acerola are higher than those from Arabidopsis and tomato. Also, the transient expression of the uidA reporter gene in the protoplasts of Nicotiana tabacum cultures showed the MgGMP gene promoter to have higher activity than the cauliflower mosaic virus 35S and Arabidopsis GMP promoters. The AsA content of transgenic tobacco plants expressing the MgGMP gene including its promoter was about 2-fold higher than that of the wild type.
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