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15 publications mentioning gma-MIR399a

Open access articles that are associated with the species Glycine max and mention the gene name MIR399a. Click the [+] symbols to view sentences that include the gene name, or the word cloud on the right for a summary.

1
[+] score: 92
Other miRNAs from this paper: osa-MIR156a, osa-MIR156b, osa-MIR156c, osa-MIR156d, osa-MIR156e, osa-MIR156f, osa-MIR156g, osa-MIR156h, osa-MIR156i, osa-MIR156j, osa-MIR160a, osa-MIR160b, osa-MIR160c, osa-MIR160d, osa-MIR162a, osa-MIR164a, osa-MIR164b, osa-MIR166a, osa-MIR166b, osa-MIR166c, osa-MIR166d, osa-MIR166e, osa-MIR166f, osa-MIR167a, osa-MIR167b, osa-MIR167c, osa-MIR169a, osa-MIR171a, osa-MIR393a, osa-MIR395b, osa-MIR395d, osa-MIR395e, osa-MIR395g, osa-MIR395h, osa-MIR395i, osa-MIR395j, osa-MIR395k, osa-MIR395l, osa-MIR395s, osa-MIR395t, osa-MIR395c, osa-MIR395a, osa-MIR395f, osa-MIR395u, osa-MIR396a, osa-MIR396b, osa-MIR396c, osa-MIR397a, osa-MIR398a, osa-MIR398b, osa-MIR399a, osa-MIR399b, osa-MIR399c, osa-MIR399d, osa-MIR399e, osa-MIR399f, osa-MIR399g, osa-MIR399h, osa-MIR399i, osa-MIR399j, osa-MIR399k, osa-MIR156k, osa-MIR156l, osa-MIR159a, osa-MIR159b, osa-MIR159c, osa-MIR159d, osa-MIR159e, osa-MIR159f, osa-MIR319a, osa-MIR319b, osa-MIR160e, osa-MIR160f, osa-MIR162b, osa-MIR164c, osa-MIR164d, osa-MIR164e, osa-MIR166k, osa-MIR166l, osa-MIR167d, osa-MIR167e, osa-MIR167f, osa-MIR167g, osa-MIR167h, osa-MIR167i, osa-MIR168a, osa-MIR168b, osa-MIR169b, osa-MIR169c, osa-MIR169d, osa-MIR169e, osa-MIR169f, osa-MIR169g, osa-MIR169h, osa-MIR169i, osa-MIR169j, osa-MIR169k, osa-MIR169l, osa-MIR169m, osa-MIR169n, osa-MIR169o, osa-MIR169p, osa-MIR169q, osa-MIR171b, osa-MIR171c, osa-MIR171d, osa-MIR171e, osa-MIR171f, osa-MIR171g, osa-MIR172a, osa-MIR172b, osa-MIR172c, osa-MIR166g, osa-MIR166h, osa-MIR166i, osa-MIR171h, osa-MIR393b, osa-MIR408, osa-MIR172d, osa-MIR171i, osa-MIR167j, osa-MIR166m, osa-MIR166j, osa-MIR164f, osa-MIR390, osa-MIR396e, gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR159a, gma-MIR160a, gma-MIR166a, gma-MIR166b, gma-MIR167a, gma-MIR167b, gma-MIR168a, gma-MIR172a, gma-MIR172b, gma-MIR319a, gma-MIR319b, gma-MIR156a, gma-MIR396a, gma-MIR396b, gma-MIR398a, gma-MIR398b, gma-MIR319c, gma-MIR156b, gma-MIR169a, osa-MIR395m, osa-MIR395n, osa-MIR395o, osa-MIR395p, osa-MIR395q, osa-MIR395v, osa-MIR395w, osa-MIR395r, osa-MIR169r, gma-MIR159b, gma-MIR159c, gma-MIR162a, gma-MIR164a, gma-MIR167c, gma-MIR169b, gma-MIR169c, gma-MIR171a, gma-MIR390a, gma-MIR390b, gma-MIR393a, gma-MIR171b, gma-MIR482a, gma-MIR1507a, gma-MIR1508a, gma-MIR1509a, gma-MIR1510a, gma-MIR1511, gma-MIR1512a, gma-MIR1515a, osa-MIR827, osa-MIR396f, gma-MIR167d, gma-MIR396c, gma-MIR1507b, gma-MIR1510b, gma-MIR2109, gma-MIR167e, gma-MIR167f, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR1509b, osa-MIR2118a, osa-MIR2118b, osa-MIR2118c, osa-MIR2118d, osa-MIR2118e, osa-MIR2118f, osa-MIR2118g, osa-MIR2118h, osa-MIR2118i, osa-MIR2118j, osa-MIR2118k, osa-MIR2118l, osa-MIR2118m, osa-MIR2118n, osa-MIR2118o, osa-MIR2118p, osa-MIR2118q, osa-MIR2118r, osa-MIR396g, osa-MIR396h, osa-MIR396d, osa-MIR395x, osa-MIR395y, gma-MIR396d, gma-MIR482b, gma-MIR167g, gma-MIR156f, gma-MIR169d, gma-MIR172f, gma-MIR171c, gma-MIR169e, gma-MIR156g, gma-MIR159d, gma-MIR4416a, gma-MIR396e, gma-MIR156h, gma-MIR156i, gma-MIR160b, gma-MIR160c, gma-MIR160d, gma-MIR160e, gma-MIR162b, gma-MIR164b, gma-MIR164c, gma-MIR164d, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR168b, gma-MIR169f, gma-MIR169g, gma-MIR171d, gma-MIR171e, gma-MIR171f, gma-MIR171g, gma-MIR319d, gma-MIR319e, gma-MIR319f, gma-MIR390c, gma-MIR398c, gma-MIR408d, gma-MIR2118a, gma-MIR2118b, gma-MIR482c, gma-MIR1507c, gma-MIR171h, gma-MIR171i, gma-MIR169h, gma-MIR167h, gma-MIR169i, gma-MIR396f, gma-MIR396g, gma-MIR167i, gma-MIR171j, gma-MIR395a, gma-MIR395b, gma-MIR395c, gma-MIR397a, gma-MIR408a, gma-MIR408b, gma-MIR408c, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR159e, gma-MIR159f, gma-MIR162c, gma-MIR166i, gma-MIR166j, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR171k, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR319g, gma-MIR319h, gma-MIR319i, gma-MIR319j, gma-MIR319k, gma-MIR319l, gma-MIR319m, gma-MIR396h, gma-MIR396i, gma-MIR482d, gma-MIR1512b, gma-MIR167j, gma-MIR171l, gma-MIR2111a, gma-MIR1512c, gma-MIR393b, gma-MIR156p, gma-MIR171m, gma-MIR172k, gma-MIR171n, gma-MIR156q, gma-MIR171o, gma-MIR172l, gma-MIR169o, gma-MIR319n, gma-MIR171p, gma-MIR169p, gma-MIR156r, gma-MIR399b, gma-MIR396j, gma-MIR171q, gma-MIR156s, gma-MIR169r, gma-MIR169s, gma-MIR396k, gma-MIR2111b, gma-MIR2111c, gma-MIR166k, gma-MIR2111d, gma-MIR156t, gma-MIR482e, gma-MIR399c, gma-MIR171r, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR171s, gma-MIR166l, gma-MIR171t, gma-MIR2111e, gma-MIR2111f, gma-MIR171u, gma-MIR399f, gma-MIR399g, gma-MIR395d, gma-MIR395e, gma-MIR395f, gma-MIR395g, gma-MIR166m, gma-MIR169u, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR160f, gma-MIR164e, gma-MIR164f, gma-MIR164g, gma-MIR164h, gma-MIR164i, gma-MIR164j, gma-MIR164k, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR169v, gma-MIR390d, gma-MIR390e, gma-MIR390f, gma-MIR390g, gma-MIR393c, gma-MIR393d, gma-MIR393e, gma-MIR393f, gma-MIR393g, gma-MIR393h, gma-MIR393i, gma-MIR393j, gma-MIR393k, gma-MIR395h, gma-MIR395i, gma-MIR395j, gma-MIR395k, gma-MIR395l, gma-MIR395m, gma-MIR1515b, gma-MIR398d, gma-MIR319o, gma-MIR319p, gma-MIR399i, gma-MIR167k, gma-MIR319q, gma-MIR167l, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
Use of qRT-PCR verified the expression of four P-responsive miRNAs and 5’ RACE confirmed targets of miR399, miR2111, and miR159e-3p. [score:5]
A-H: expression patterns of miRNA399a/b/c/d/ (A and B), miRnov_6 (C and D), miRnov_9 (E and F), and miRnov_10 (G and H) in leaves and roots in +Pi and -Pi; I-L: expression patterns of miRNA399a/b/c/d (I), miRnov_6 (J), miRnov_9 (K), and miRnov_10 (L) in leaves and roots under different nutrient deficiency conditions. [score:5]
has confirmed the targets of miR166g, miR168 and miR169c in previous work [20, 27, 28], as well as the targets of miR399, miR2111 and miR159e-3p in this study. [score:5]
Then, stem-loop real-time PCR confirmed expression of four selected P-responsive miRNAs, and confirmed that a PHO2 and GmPT5, a kelch-domain containing protein, and a Myb transcription factor, respectively are targets of miR399, miR2111, and miR159e-3p. [score:5]
In regards to nutrient stress, the targets of root P-responsive miRNAs and their cleavage sites are highlighted in Table 6. A PHO2, two Pi transporter transcripts (Glyma10g04230 and Glyma14g36650), and an AP2 protein gene (Glyma01g13410) were predicted to be targets of miR399a, b, c, d, and e (Table 6). [score:5]
Genes for miR399a, miR399b, miR399d and miR399e had PHR1 binding sites, but miR399c only had a W-BOX binding site (Additional file 13), indicating the expression of miR399a, b, d, and e might be regulated by PHR1 in soybean. [score:4]
Arabidopsis miR398a, miR398b, miR398c, and miR408 were repressed in leaves under Pi -depleted conditions [10], while Cu depletion induced the expression of miR408, miR399, and miR2111 in Arabidopsis, rice and Brassica [12]. [score:3]
In contrast to miR399 activity in Arabidopsis and rice [10], soybean miR399 targets PHO2 in the 5’ UTR but not in the coding region (Figure 6C). [score:3]
Grafting experiments involving root stocks and shoots with divergent miR399 sequences or expression patterns might answer this question. [score:3]
Figure 6 Confirmation of the targets of miR399, miR2111, and miR159e-3p by. [score:3]
Finally, the existence of four P-responsive miRNAs (miR399, nov_6, nov_9, and nov_10) were verified via stem-loop real time (RT) PCR, and the targets of miR399, miR2111, and miR159e-3p were confirmed via RLM 5’ RACE. [score:3]
The expression levels of mature miR399, miRnov_6, miRnov_9, and miRnov_10 were determined through stem-loop real-time PCR [25]. [score:3]
The expression of miR399 has been predominantly found in vascular tissues, especially in root phloem companion cells in Arabidopsis [12]. [score:3]
It was reported that five conserved miRNAs (miR159, miR162, miR166, miR390, and miR399) presented similar expression levels in root apexes and nodules, but miR169, miR171, miR393, and miR396 enriched in root tips [41]. [score:3]
AtPHR1 binds the promoter region of miR399 in Arabidopsis [30], indicating control of miRNA expression by TFs. [score:3]
Figure 5 Expression analysis of miRNA399a/b/c/d, miRnov_6, miRnov_9, miRnov_10 under Pi-starvation and others different nutrient deficiency. [score:3]
cis-element analysis in the promoter of P-responsive miRNAsAtPHR1 binds the promoter region of miR399 in Arabidopsis [30], indicating control of miRNA expression by TFs. [score:3]
The targets of miR399, miR2111, and miR159e-3p were confirmed. [score:3]
Determination of targets of miR399, miR2111, and miR159e-3p through. [score:3]
MiR399 accumulated in Medicago and tobacco roots during arbuscular mycorhizal symbiosis [44], and targeted a putative phosphate transporter (Mendtr5g076920.1) [45]. [score:2]
data verified predictions that miR399a/b/c/d/e cleaves GmPT5 (Additional file 7, Figure 6D), implying potential regulation of P nutrition in nodules by miR399. [score:2]
Click here for file Alignment of GmIPS1 with mature gma-miR399a-d and miR399e. [score:1]
Moreover, GmIPS1 might act as a RNA mimic to attenuate miR399 activity as AtIPS1/At4 does in Arabidopsis [26] (Additional file 5). [score:1]
The levels of miR395, miR398 and miR399 were strongly augmented in response to S, Cu or Pi starvation in phloem. [score:1]
Moreover miR399a, miR399b, and miR399e were localized to chromosome 5, while miR399c and miR399d were localized to chromosome 8 (Table 3). [score:1]
Exploring the role of miR399 and miR2111 in soybean in the near future at genetic and biochemical levels promises to yield useful insights into how these miRNAs function in plants, and their effects on associated networks. [score:1]
The cleavage site of miR399 in PHO2 is predicted to occur at position 1050, and in Glyma10g04230 at position 407 (Additional file 7). [score:1]
Among them, GmIPS1 nearly perfectly matched miR399a, b, c, d, and e over the center region, thus forming a three-nucleotide bulge (Additional file 5), and thereby implying that soybean miR399 activity might be negatively modulated by GmIPS1 as in Arabidopsis. [score:1]
Alignment of GmIPS1 with mature gma-miR399a-d and miR399e. [score:1]
More importantly, in regards to plant nutrition, miR399a, miR399b, miR399c, miR399d, and miR399e were detected in the present small libraries. [score:1]
Phosphorus (P) deficiency specifically induces miR399 in Arabidopsis and rice [6- 8]. [score:1]
The qRT-PCR data in the present study confirms that miR399a/b/c/d specifically responds to Pi deprivation (Figure 5), while confirms that soybean miR399 cleaves PHO2 and GmPT5, as in Arabidopsis, rice, and common bean [42]. [score:1]
Under iron (Fe) deficiency, while the levels of miR399 and miR2111 were decreased in phloem, and even undetectable in roots and leaves [12, 16], indicating that Fe limitation alters P homeostasis. [score:1]
The total abundance of miR399a/b/c/d was significantly induced by Pi starvation in both leaves (Figure 5A) and roots (Figure 5B) after 7 d of Pi starvation, but not at any other tested time point. [score:1]
Cleavage sites from the 5’ end for Glyma13g31290 (PHO2-1) by miR399 (C), GmPT5 by miR399 (D), Glyma13g25716 by miR159e-3p (E), and Glyma16g06160 by miR2111 (F). [score:1]
Concordantly, soybean miR399s (miR399a, miR399b, miR399c, and miR399d) were induced by Pi starvation both in leaves and roots, but the levels in leaves are around 2.5 times higher than in roots (Table 3). [score:1]
Although miR399, the classic P-responsive miRNA, was predicted to exist in soybean [18], no experiments to verify the existence of this or other P-responsive mRNAs have been reported in soybean. [score:1]
The miRNA miR399a/b/c/d responded to Pi starvation in leaves and roots, but not to other nutrient deficiencies (Figure 5I). [score:1]
GmIPS1 CR, GmIPS1 complementary region with miR399; GmIPS1 (Gm10:5,886,477.. [score:1]
Past studies suggested that only miR399 and miR395 are transported from shoots to roots via phloem but not xylem vessels [12, 16]. [score:1]
Because mature sequences of miR399a, 399b, 399c, and miR399d are 100% identical (Table 3), it is impossible to distinguish the levels of the four mature miR399s with stem-loop PCR. [score:1]
[1 to 20 of 41 sentences]
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[+] score: 76
Other miRNAs from this paper: gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR160a, gma-MIR166a, gma-MIR166b, gma-MIR167a, gma-MIR167b, gma-MIR172a, gma-MIR172b, gma-MIR156a, gma-MIR396a, gma-MIR396b, gma-MIR398a, gma-MIR398b, gma-MIR156b, gma-MIR167c, gma-MIR390a, gma-MIR390b, gma-MIR393a, gma-MIR482a, gma-MIR1511, gma-MIR1512a, gma-MIR1515a, gma-MIR167d, gma-MIR396c, gma-MIR167e, gma-MIR167f, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR396d, gma-MIR482b, gma-MIR167g, gma-MIR156f, gma-MIR172f, gma-MIR156g, gma-MIR396e, gma-MIR156h, gma-MIR156i, gma-MIR160b, gma-MIR160c, gma-MIR160d, gma-MIR160e, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR390c, gma-MIR398c, gma-MIR482c, gma-MIR167h, gma-MIR396f, gma-MIR396g, gma-MIR167i, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR166i, gma-MIR166j, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR319l, gma-MIR396h, gma-MIR396i, gma-MIR482d, gma-MIR1512b, gma-MIR167j, gma-MIR2111a, gma-MIR1512c, gma-MIR393b, gma-MIR156p, gma-MIR172k, gma-MIR156q, gma-MIR172l, gma-MIR156r, gma-MIR399b, gma-MIR396j, gma-MIR156s, gma-MIR396k, gma-MIR2111b, gma-MIR2111c, gma-MIR166k, gma-MIR2111d, gma-MIR156t, gma-MIR482e, gma-MIR399c, gma-MIR399d, gma-MIR399e, gma-MIR166l, gma-MIR2111e, gma-MIR2111f, gma-MIR399f, gma-MIR399g, gma-MIR166m, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR160f, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR390d, gma-MIR390e, gma-MIR390f, gma-MIR390g, gma-MIR393c, gma-MIR393d, gma-MIR393e, gma-MIR393f, gma-MIR393g, gma-MIR393h, gma-MIR393i, gma-MIR393j, gma-MIR393k, gma-MIR1515b, gma-MIR398d, gma-MIR399i, gma-MIR167k, gma-MIR167l, gma-MIR399j, gma-MIR399k, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
Gma-miR399 also has additional putative target genes with different biochemical features beyond the well-known target gene PHO2, which is involved in plant responses to phosphate starvation. [score:5]
Figure S3 Expression analysis of predicted target genes of gma-miR399a/b in response to salt stress. [score:5]
We have detected the expression of these predicted target genes of gma-miR399a/b, as shown in Figure S3, Glyma. [score:5]
A phenotypic analysis revealed that the transgenic roots overexpressing 35S::miR399a, including primary and lateral roots, were comparable to those from plants carrying the empty vector control when grown under normal conditions (Figures 8C,E); in contrast, the roots from plants overexpressing 35S::miR399a exhibited increased sensitivity to salt stress when treated with 75 mM NaCl (Figures 8D,F). [score:5]
By contrast, miR399a/b, miR1512b, and miR156g were stably and dramatically down-regulated in the RAM of salt stress -treated seedlings (Figure 4). [score:4]
In Arabidopsis, miR399 directly targets the protein PHO2 (UBC), which is an ubiquitin E2-conjugating enzyme (Bari et al., 2006). [score:4]
These data suggest that gma-miR399a/b may participate in the plastic development of RAM under salt stress through target one or more genes. [score:4]
For the gma-miR399a overexpression construct, the pre-miRNA fragment (94 base pairs [bp]) of gma-miR399a was amplified and inserted into the Gateway® binary vector pGWB2. [score:3]
10G036800 (GmPT5), which have been validated as the targets of gma-miR399 (Xu et al., 2013), Glyma. [score:3]
Primary root growth in the 35S::miR399a -overexpressing roots was reduced by 40%, and the lateral root number per hairy root was decreased by up to 70% under salt stress conditions (Figures 8A,B). [score:3]
To this end, we generated transgenic roots overexpressing gma-miR399a under the control of the CaMV35S promoter using a hairy root transformation system. [score:3]
15G074200 annotated as Inorganic phosphate transporter and Ubiquitin-conjugatine enzyme E2 respectively, were also predicted to be the target genes of gma-miR399. [score:3]
However, miR399 also shows a variable expression pattern in response to salt stress in different plants; it was shown to be induced by salt stress in Populus tremula (Jia et al., 2009), but repressed by salt in both Medicago and soybean. [score:3]
Figure 8 Effects of overexpression gma-miR399a on root system architecture under salt stress. [score:3]
The primary root length (G) and the lateral root number per hairy root (H) expressing empty vector or 35S::miR399a were counted. [score:3]
The expression of gma-miR399a/b, gma-miR156g/j, gma-miR2111b/c/f, gma-miR1511, Gly03, Gly16a/b Gly20 appeared to be significantly repressed by exogenous auxin, whereas that of gma-miR390e, Gly04, and Gly13 was induced by exogenous auxin (Figure 7). [score:3]
Ten days after transplantation, the expression of miR399a was analyzed in hairy roots harboring the 35::miR399a construct using qRT-PCR. [score:3]
Gma-miR399a modulates plastic root development in soybean under salt stress. [score:2]
A functional analysis of glyma-miR399a further confirmed that miR399 is required for RAM and root development under salt stress conditions (Figure 8). [score:2]
We also identified a novel role for miR399 in root developmental plasticity under salt stress. [score:2]
These results suggest a crucial role for gma-miR399 in root developmental plasticity in soybean in response to salt stress. [score:2]
In the case of miR399, these miRNAs may be involved in the general regulation of plant responses to environmental stresses, including phosphate starvation and salt stress. [score:2]
In contrast, miR399a/b was the most repressed miRNA under salt stress, followed by miR1512b, miR156g, and miR156j (Figure 3). [score:1]
These results demonstrate that the function of miR399 in the response to salt stress is conserved in legumes, and that functional divergence of these miRNAs may occur in different plant species. [score:1]
It has been shown that miR399 family miRNAs mediate phosphate uptake in various plant species (Bari et al., 2006; Wang et al., 2009; Hackenberg et al., 2013). [score:1]
Among the known miRNAs, most (gma-miR399a/b, gma-miR156g, gma-miR156j, gma-miR2111b/c/f, gma-miR1511, gma-miR390e, and gma-miR172f) have been shown to be involved in root responses to salt stress in plants, except for gma-miR1512b, which is legume-specific (Li et al., 2010). [score:1]
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3
[+] score: 36
Other miRNAs from this paper: gma-MIR159a, gma-MIR166a, gma-MIR166b, gma-MIR396a, gma-MIR396b, gma-MIR398a, gma-MIR398b, gma-MIR169a, gma-MIR159b, gma-MIR159c, gma-MIR169b, gma-MIR169c, gma-MIR171a, gma-MIR393a, gma-MIR171b, gma-MIR482a, gma-MIR1507a, gma-MIR1509a, gma-MIR1510a, gma-MIR1512a, gma-MIR1518, gma-MIR396c, gma-MIR1507b, gma-MIR1510b, gma-MIR2109, gma-MIR2119, gma-MIR1509b, gma-MIR396d, gma-MIR482b, gma-MIR169d, gma-MIR171c, gma-MIR169e, gma-MIR159d, gma-MIR396e, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR169f, gma-MIR169g, gma-MIR171d, gma-MIR171e, gma-MIR171f, gma-MIR171g, gma-MIR398c, gma-MIR408d, gma-MIR2118a, gma-MIR2118b, gma-MIR482c, gma-MIR1507c, gma-MIR4996, gma-MIR171h, gma-MIR171i, gma-MIR169h, gma-MIR169i, gma-MIR396f, gma-MIR396g, gma-MIR5037c, gma-MIR171j, gma-MIR397a, gma-MIR397b, gma-MIR408a, gma-MIR408b, gma-MIR408c, gma-MIR3522, gma-MIR159e, gma-MIR159f, gma-MIR166i, gma-MIR166j, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR171k, gma-MIR396h, gma-MIR396i, gma-MIR482d, gma-MIR1512b, gma-MIR171l, gma-MIR1512c, gma-MIR393b, gma-MIR171m, gma-MIR171n, gma-MIR171o, gma-MIR169o, gma-MIR171p, gma-MIR169p, gma-MIR399b, gma-MIR396j, gma-MIR171q, gma-MIR169r, gma-MIR169s, gma-MIR396k, gma-MIR166k, gma-MIR482e, gma-MIR399c, gma-MIR171r, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR171s, gma-MIR166l, gma-MIR171t, gma-MIR171u, gma-MIR399f, gma-MIR399g, gma-MIR166m, gma-MIR169u, gma-MIR399h, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR169v, gma-MIR393c, gma-MIR393d, gma-MIR393e, gma-MIR393f, gma-MIR393g, gma-MIR393h, gma-MIR393i, gma-MIR393j, gma-MIR393k, gma-MIR398d, gma-MIR9727, gma-MIR9750, gma-MIR399i, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
To understand and visualize the regulation network between these two families and their targets, regulatory network analysis was performed as shown in Fig. 7. MiR399 had strong connection with a number of different targets. [score:6]
a miR159 family and their targets responsive to SCN infection; b miR399 family and their targets responsive to SCN infection To understand the role of soybean miRNAs in response to SCN infection, an experiment was conducted with soybean grown in sterilized soil and soil infested with SCN HG type 7. Two Kansas soybean cultivars were used: KS4607, a SCN susceptible cultivar [31], and KS4313N, a cultivar resistant to HG type 7 [32]. [score:5]
a miR159 family and their targets responsive to SCN infection; b miR399 family and their targets responsive to SCN infection In the present study, we sequenced small RNA libraries from the roots of two soybean genotypes at different time points in the presence and absence of SCN infection and acquired 0.3 billion reads. [score:5]
Expression of miR399 has also been reported to be specifically induced by infection of Candidatus L. asiaticus, the bacterial causal agent of citrus greening disease [46]. [score:5]
The regulatory network revealed that miR159 and miR399 likely had a function in response to SCN infection by targeting a number of different genes in roots. [score:4]
Three differentially expressed conserved miRNAs (gma-miR393, gma-miR398 and gma-miR399) have also been reported previously to be promising varied in two sister soybean lines that are resistance and susceptible to SCN race 4 [27]. [score:3]
Expression of gma-miR399 and gma-miR408 were significantly induced by SCN in the susceptible cultivar KS4607 only. [score:3]
Among DE miRNAs responsive to SCN infection, two miRNAs (gma-miR2119, and gma-miR1512a-5p) were found to be unique in the resistant cultivar KS4313N, while 9 miRNA families (gma-miR399, 169, 156, 159, 408, 4411, 4996, 5770, and 9727) were significantly differentially expressed in only KS4607 but not in KS4313N. [score:3]
Among the DE miRNAs, several members in conserved miR159 and miR399 families were significantly changed in both cultivars. [score:1]
According to the functional analysis and previous reports, several conserved miRNAs (for example, gma-miR159, gma-miR171, gma-miR398, gma-miR399, and gma-miR408) and legume specific miRNAs (for example, gma-miR1512, gma-miR2119, and gma-miR9750) could be potential candidates for manipulating the SCN infection. [score:1]
[1 to 20 of 10 sentences]
4
[+] score: 23
Other miRNAs from this paper: gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR159a, gma-MIR160a, gma-MIR166a, gma-MIR166b, gma-MIR167a, gma-MIR167b, gma-MIR168a, gma-MIR172a, gma-MIR172b, gma-MIR319a, gma-MIR319b, gma-MIR156a, gma-MIR396a, gma-MIR396b, gma-MIR398a, gma-MIR398b, gma-MIR319c, gma-MIR156b, gma-MIR169a, gma-MIR159b, gma-MIR159c, gma-MIR162a, gma-MIR164a, gma-MIR167c, gma-MIR169b, gma-MIR169c, gma-MIR390a, gma-MIR390b, gma-MIR393a, gma-MIR167d, gma-MIR396c, gma-MIR167e, gma-MIR167f, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR396d, gma-MIR391, gma-MIR167g, gma-MIR156f, gma-MIR169d, gma-MIR172f, gma-MIR169e, gma-MIR394b, gma-MIR156g, gma-MIR159d, gma-MIR394a, gma-MIR396e, gma-MIR156h, gma-MIR156i, gma-MIR160b, gma-MIR160c, gma-MIR160d, gma-MIR160e, gma-MIR162b, gma-MIR164b, gma-MIR164c, gma-MIR164d, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR168b, gma-MIR169f, gma-MIR169g, gma-MIR319d, gma-MIR319e, gma-MIR319f, gma-MIR390c, gma-MIR394c, gma-MIR398c, gma-MIR408d, gma-MIR169h, gma-MIR167h, gma-MIR169i, gma-MIR396f, gma-MIR396g, gma-MIR167i, gma-MIR403a, gma-MIR403b, gma-MIR395a, gma-MIR395b, gma-MIR395c, gma-MIR397a, gma-MIR397b, gma-MIR408a, gma-MIR408b, gma-MIR408c, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR159e, gma-MIR159f, gma-MIR162c, gma-MIR166i, gma-MIR166j, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR319g, gma-MIR319h, gma-MIR319i, gma-MIR319j, gma-MIR319k, gma-MIR319l, gma-MIR319m, gma-MIR396h, gma-MIR396i, gma-MIR167j, gma-MIR393b, gma-MIR828a, gma-MIR156p, gma-MIR828b, gma-MIR172k, gma-MIR156q, gma-MIR172l, gma-MIR169o, gma-MIR319n, gma-MIR394d, gma-MIR169p, gma-MIR156r, gma-MIR399b, gma-MIR396j, gma-MIR156s, gma-MIR169r, gma-MIR169s, gma-MIR396k, gma-MIR166k, gma-MIR156t, gma-MIR399c, gma-MIR394e, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR166l, gma-MIR394f, gma-MIR399f, gma-MIR399g, gma-MIR395d, gma-MIR395e, gma-MIR395f, gma-MIR395g, gma-MIR166m, gma-MIR169u, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR160f, gma-MIR164e, gma-MIR164f, gma-MIR164g, gma-MIR164h, gma-MIR164i, gma-MIR164j, gma-MIR164k, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR169v, gma-MIR390d, gma-MIR390e, gma-MIR390f, gma-MIR390g, gma-MIR393c, gma-MIR393d, gma-MIR393e, gma-MIR393f, gma-MIR393g, gma-MIR393h, gma-MIR393i, gma-MIR393j, gma-MIR393k, gma-MIR394g, gma-MIR395h, gma-MIR395i, gma-MIR395j, gma-MIR395k, gma-MIR395l, gma-MIR395m, gma-MIR398d, gma-MIR319o, gma-MIR319p, gma-MIR399i, gma-MIR167k, gma-MIR319q, gma-MIR167l, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
Thus, we found several stress-responsive miRNA homologs – miR393, miR398, miR395 and miR399 – highly conserved in diverse monocots and dicots, which suggests that these miRNA -guided target gene regulations have been well preserved, possibly because they are important for plant stress tolerance [13]. [score:4]
miR395 and miR399 are specifically up-regulated in response to low nutrient conditions. [score:4]
Although miR399 homologs in Arabidopsis and rice were found to be closely spaced [26], their expression in one transcript is unknown. [score:3]
miR399 is induced under low phosphate conditions [16, 18, 24, 25], whereas miR395 is induced in response to low-sulfate conditions [15]. [score:1]
miR399 and miR395 homologs are in as many as 31 and 22 diverse plant species, respectively (Table 1). [score:1]
miR395 and miR399 are specifically induced under low-sulfate and low-phosphate conditions, respectively [15, 16, 18, 24, 25]. [score:1]
In fact, with use of GSS alone, miR395 and miR399 homologs were retrieved from 9 and 11 diverse plant species, respectively (Table 1). [score:1]
We found six families (miR159, miR160, miR167, miR170/171, miR396 and miR399) in 30–39 species; seven (miR164, miR168, miR172, miR393, miR395, miR398 and miR408) in 20–29 species; and five (miR162, miR390, miR397, miR403 and miR437) in 10–19 species (Table 1). [score:1]
miR399 plays an important role in phosphate homeostasis [16, 18]. [score:1]
By contrast, using GSS, HTGs, EST and NR databases, we found miR399 and miR395 homologs in as many as 28 and 18 diverse plant species, respectively. [score:1]
Although miRNA clusters are not common in plants, a few miRNA families (miR395, miR399, miR169 and miR1219) have been found to exist as clusters [26, 45- 47]. [score:1]
Accordingly, miR395, miR399, miR403 and miR408 families were classified as lowly conserved [21]. [score:1]
Six families (miR159, miR160, miR167, miR170/171, miR396 and miR399) were found in 30–39 diverse plant species (Table 1). [score:1]
Thus the representation of primary miR395 and miR399 transcripts in the ESTs generated from untreated plants is highly unlikely. [score:1]
Zhang et al. retrieved miR395 and miR399 homologs from nine and eight plant species, respectively, which formed the basis for the authors' categorization of the families as being lowly conserved [21]. [score:1]
[1 to 20 of 15 sentences]
5
[+] score: 22
Other miRNAs from this paper: gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR159a, gma-MIR160a, gma-MIR166a, gma-MIR167a, gma-MIR167b, gma-MIR168a, gma-MIR172a, gma-MIR172b, gma-MIR319a, gma-MIR319b, gma-MIR156a, gma-MIR396b, gma-MIR398a, gma-MIR398b, gma-MIR319c, gma-MIR156b, gma-MIR169a, gma-MIR159b, gma-MIR164a, gma-MIR167c, gma-MIR169b, gma-MIR169c, gma-MIR390a, gma-MIR171b, gma-MIR482a, gma-MIR1507a, gma-MIR1510a, gma-MIR1511, gma-MIR1512a, gma-MIR1520d, gma-MIR167d, gma-MIR2109, gma-MIR2119, gma-MIR167e, gma-MIR167f, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR4348a, gma-MIR4361, gma-MIR4368b, gma-MIR482b, gma-MIR167g, gma-MIR156f, gma-MIR169d, gma-MIR172f, gma-MIR171c, gma-MIR169e, gma-MIR394b, gma-MIR4413a, gma-MIR156g, gma-MIR159d, gma-MIR394a, gma-MIR4414a, gma-MIR156h, gma-MIR156i, gma-MIR160b, gma-MIR160c, gma-MIR160d, gma-MIR160e, gma-MIR164b, gma-MIR164c, gma-MIR164d, gma-MIR166h, gma-MIR168b, gma-MIR169f, gma-MIR169g, gma-MIR171e, gma-MIR319d, gma-MIR319e, gma-MIR319f, gma-MIR390c, gma-MIR398c, gma-MIR408d, gma-MIR2118a, gma-MIR862a, gma-MIR169h, gma-MIR167h, gma-MIR169i, gma-MIR167i, gma-MIR5372, gma-MIR395a, gma-MIR395b, gma-MIR395c, gma-MIR397a, gma-MIR397b, gma-MIR408a, gma-MIR408b, gma-MIR408c, gma-MIR3522, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR166i, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR319g, gma-MIR319h, gma-MIR319i, gma-MIR319j, gma-MIR319k, gma-MIR319l, gma-MIR319m, gma-MIR1512b, gma-MIR167j, gma-MIR1512c, gma-MIR5559, gma-MIR5774b, gma-MIR156p, gma-MIR172k, gma-MIR171n, gma-MIR156q, gma-MIR171o, gma-MIR172l, gma-MIR169o, gma-MIR319n, gma-MIR169p, gma-MIR156r, gma-MIR399b, gma-MIR156s, gma-MIR169r, gma-MIR169s, gma-MIR5786, gma-MIR156t, gma-MIR2606a, gma-MIR399c, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR399f, gma-MIR399g, gma-MIR395d, gma-MIR395e, gma-MIR395f, gma-MIR395g, gma-MIR169u, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR160f, gma-MIR164e, gma-MIR164f, gma-MIR164g, gma-MIR164h, gma-MIR164i, gma-MIR164j, gma-MIR164k, gma-MIR166u, gma-MIR169v, gma-MIR395h, gma-MIR395i, gma-MIR395j, gma-MIR395k, gma-MIR395l, gma-MIR395m, gma-MIR398d, gma-MIR4348b, gma-MIR319o, gma-MIR319p, gma-MIR399i, gma-MIR167k, gma-MIR4348c, gma-MIR319q, gma-MIR4348d, gma-MIR167l, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR4414b, gma-MIR399n, gma-MIR399o
Under short-term low N condition, miR160, miR168, miR169, miR319, miR395, and miR399 were up-regulated in roots, while in maize leaves miR172 were up-regulated and miR397, miR398, and miR827 were down-regulated. [score:10]
Recently, Xu et al. studied detailed response of miRNAs to low N availability in maize shoots and roots at the whole genome level and found that under long-term low N condition, miR167, miR169, miR395, miR399, miR408, and miR528 were down-regulated in maize roots, and in maize leaves miR164, miR172, and miR827 were up-regulated while miR169, miR397, miR398, miR399, miR408, and miR528 were down-regulated. [score:10]
Nine miRNA families (miR164, miR169, miR172, miR397, miR398, miR399, miR408, miR528, and miR827) and nine miRNA families (miR160, miR167, miR168, miR169, miR319, miR395, miR399, miR408, and miR528) were identified to respond to low N in maize shoots and roots respectively [30]. [score:1]
However, these small RNAs have emerged as important participants in the plant’s adaptive responses to diverse environmental stresses [13]– [17], [26], [27], for example, miR395, miR398, and miR399 respond to sulfur (S), copper (Cu), and Pi deficiency, respectively. [score:1]
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6
[+] score: 14
Other miRNAs from this paper: gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR160a, gma-MIR166a, gma-MIR166b, gma-MIR156a, gma-MIR396b, gma-MIR156b, gma-MIR390a, gma-MIR390b, gma-MIR393a, gma-MIR482a, gma-MIR1508a, gma-MIR1510a, gma-MIR1512a, gma-MIR1514a, gma-MIR1514b, gma-MIR1515a, gma-MIR1522, gma-MIR1530, gma-MIR1508b, gma-MIR1510b, gma-MIR2108b, gma-MIR1520j, gma-MIR482b, gma-MIR4388, gma-MIR156f, gma-MIR1520p, gma-MIR156g, gma-MIR394a, gma-MIR156h, gma-MIR156i, gma-MIR160b, gma-MIR160c, gma-MIR160d, gma-MIR160e, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR390c, gma-MIR2118a, gma-MIR2118b, gma-MIR482c, gma-MIR1508c, gma-MIR4992, gma-MIR5041, gma-MIR395b, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR166i, gma-MIR166j, gma-MIR482d, gma-MIR1512b, gma-MIR1512c, gma-MIR5769, gma-MIR393b, gma-MIR828a, gma-MIR156p, gma-MIR828b, gma-MIR156q, gma-MIR156r, gma-MIR399b, gma-MIR156s, gma-MIR166k, gma-MIR156t, gma-MIR482e, gma-MIR399c, gma-MIR399d, gma-MIR399e, gma-MIR166l, gma-MIR399f, gma-MIR399g, gma-MIR166m, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR160f, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR390d, gma-MIR390e, gma-MIR390f, gma-MIR390g, gma-MIR393c, gma-MIR393d, gma-MIR393e, gma-MIR393f, gma-MIR393g, gma-MIR393h, gma-MIR393i, gma-MIR393j, gma-MIR393k, gma-MIR1515b, gma-MIR399i, gma-MIR399j, gma-MIR399k, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
Thus, plants overexpressing IPS1 showed increased accumulation of the expression of miR-399 target PHO2 and, concomitantly, reduced shoot Pi content. [score:7]
Because of a small loop caused by a few base pairs of mismatches at the expected miRNA cleavage site, IPS1 RNA is not cleaved by miR399 but instead serving as a decoy for miR399 to interfere binding of miR399 to its canonical target, PHO2. [score:3]
Several artificial target mimics (TMs) designed for different miRNAs with a similar paring pattern as that of IPS1 and miR399 have been proven to affect the functions of their corresponding miRNAs in transgenic plants (Todesco et al., 2010; Ivashuta et al., 2011; Yan et al., 2012). [score:3]
IPS1 binds to miR399, the phosphate starvation -induced miRNA. [score:1]
[1 to 20 of 4 sentences]
7
[+] score: 10
Other miRNAs from this paper: gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR159a, gma-MIR160a, gma-MIR166a, gma-MIR166b, gma-MIR167a, gma-MIR167b, gma-MIR168a, gma-MIR172a, gma-MIR172b, gma-MIR156a, gma-MIR396a, gma-MIR396b, gma-MIR398a, gma-MIR398b, gma-MIR156b, gma-MIR169a, gma-MIR159b, gma-MIR159c, gma-MIR164a, gma-MIR167c, gma-MIR169b, gma-MIR169c, gma-MIR171a, gma-MIR390a, gma-MIR390b, gma-MIR393a, gma-MIR171b, gma-MIR482a, gma-MIR1507a, gma-MIR1508a, gma-MIR1509a, gma-MIR1510a, gma-MIR1511, gma-MIR1512a, gma-MIR1514a, gma-MIR1514b, gma-MIR167d, gma-MIR396c, gma-MIR1507b, gma-MIR1508b, gma-MIR1510b, gma-MIR2109, gma-MIR2119, gma-MIR167e, gma-MIR167f, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR1509b, gma-MIR4345, gma-MIR396d, gma-MIR4369, gma-MIR482b, gma-MIR167g, gma-MIR4397, gma-MIR156f, gma-MIR4409, gma-MIR169d, gma-MIR172f, gma-MIR171c, gma-MIR169e, gma-MIR394b, gma-MIR4413a, gma-MIR156g, gma-MIR159d, gma-MIR394a, gma-MIR396e, gma-MIR156h, gma-MIR156i, gma-MIR160b, gma-MIR160c, gma-MIR160d, gma-MIR160e, gma-MIR164b, gma-MIR164c, gma-MIR164d, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR168b, gma-MIR169f, gma-MIR169g, gma-MIR171d, gma-MIR171e, gma-MIR171f, gma-MIR171g, gma-MIR390c, gma-MIR394c, gma-MIR398c, gma-MIR408d, gma-MIR2118a, gma-MIR2118b, gma-MIR482c, gma-MIR1507c, gma-MIR1508c, gma-MIR171h, gma-MIR171i, gma-MIR169h, gma-MIR167h, gma-MIR169i, gma-MIR396f, gma-MIR396g, gma-MIR167i, gma-MIR5373, gma-MIR403a, gma-MIR403b, gma-MIR171j, gma-MIR395a, gma-MIR395b, gma-MIR395c, gma-MIR397a, gma-MIR397b, gma-MIR408a, gma-MIR408b, gma-MIR408c, gma-MIR3522, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR159e, gma-MIR159f, gma-MIR166i, gma-MIR166j, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR171k, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR396h, gma-MIR396i, gma-MIR482d, gma-MIR1512b, gma-MIR1513c, gma-MIR4413b, gma-MIR167j, gma-MIR171l, gma-MIR1512c, gma-MIR5767, gma-MIR5770a, gma-MIR393b, gma-MIR5781, gma-MIR5770b, gma-MIR156p, gma-MIR171m, gma-MIR172k, gma-MIR171n, gma-MIR156q, gma-MIR171o, gma-MIR172l, gma-MIR169o, gma-MIR171p, gma-MIR394d, gma-MIR169p, gma-MIR156r, gma-MIR399b, gma-MIR396j, gma-MIR171q, gma-MIR156s, gma-MIR169r, gma-MIR169s, gma-MIR396k, gma-MIR166k, gma-MIR156t, gma-MIR482e, gma-MIR399c, gma-MIR171r, gma-MIR394e, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR171s, gma-MIR166l, gma-MIR171t, gma-MIR394f, gma-MIR171u, gma-MIR399f, gma-MIR399g, gma-MIR395d, gma-MIR395e, gma-MIR395f, gma-MIR395g, gma-MIR166m, gma-MIR169u, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR160f, gma-MIR164e, gma-MIR164f, gma-MIR164g, gma-MIR164h, gma-MIR164i, gma-MIR164j, gma-MIR164k, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR169v, gma-MIR390d, gma-MIR390e, gma-MIR390f, gma-MIR390g, gma-MIR393c, gma-MIR393d, gma-MIR393e, gma-MIR393f, gma-MIR393g, gma-MIR393h, gma-MIR393i, gma-MIR393j, gma-MIR393k, gma-MIR394g, gma-MIR395h, gma-MIR395i, gma-MIR395j, gma-MIR395k, gma-MIR395l, gma-MIR395m, gma-MIR398d, gma-MIR399i, gma-MIR167k, gma-MIR5770c, gma-MIR1446, gma-MIR167l, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
Recently, several studies reported differential expression of miRNAs such as miR164, miR169, miR171, miR396, miR398, miR399, miR408 and miR2118 in drought-stressed plants but their regulation (up or down) differed between different plant species [5]. [score:4]
Among the highly conserved 23 miRNA families [23], two (miR156 and miR166) were classified as high, three (miR168, miR396 and miR172) as moderate and seven (miR169, miR171, miR164, miR390, miR159, miR160 and miR167) as low and two (miR395 and miR399) as extremely low abundantly expressed miRNA families in primary root tips of soybean. [score:3]
Because our classification is strictly based on abundances, this group also included miR395 and miR399, which are highly conserved but expressed at very low levels under normal conditions [20– 22]. [score:3]
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8
[+] score: 6
Some well-known miRNAs such as miR156, miR172, miR160, miR398 and miR399 were all predicted to be targeted by specific circRNAs (Supplementary Table  S8). [score:3]
Some well-known miRNA families of MIR156 32, 33, MIR172 34, 35, MIR160 [36], MIR398 37, 38, and MIR399 [39] were predicted to be targeted by certain soybean circRNAs. [score:3]
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9
[+] score: 5
Other miRNAs from this paper: gma-MIR166a, gma-MIR166b, gma-MIR172a, gma-MIR172b, gma-MIR319a, gma-MIR319b, gma-MIR319c, gma-MIR169a, gma-MIR159b, gma-MIR167c, gma-MIR169b, gma-MIR169c, gma-MIR171a, gma-MIR171b, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR169d, gma-MIR172f, gma-MIR171c, gma-MIR169e, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR169f, gma-MIR169g, gma-MIR171d, gma-MIR171e, gma-MIR171f, gma-MIR171g, gma-MIR319d, gma-MIR319e, gma-MIR319f, gma-MIR171h, gma-MIR171i, gma-MIR169h, gma-MIR169i, gma-MIR171j, gma-MIR397a, gma-MIR397b, gma-MIR166i, gma-MIR166j, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR171k, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR319g, gma-MIR319h, gma-MIR319i, gma-MIR319j, gma-MIR319k, gma-MIR319l, gma-MIR319m, gma-MIR171l, gma-MIR2111a, gma-MIR171m, gma-MIR172k, gma-MIR171n, gma-MIR171o, gma-MIR172l, gma-MIR169o, gma-MIR319n, gma-MIR171p, gma-MIR169p, gma-MIR399b, gma-MIR171q, gma-MIR169r, gma-MIR169s, gma-MIR2111b, gma-MIR2111c, gma-MIR166k, gma-MIR2111d, gma-MIR399c, gma-MIR171r, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR171s, gma-MIR166l, gma-MIR171t, gma-MIR2111e, gma-MIR2111f, gma-MIR171u, gma-MIR399f, gma-MIR399g, gma-MIR166m, gma-MIR169u, gma-MIR399h, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR169v, gma-MIR319o, gma-MIR319p, gma-MIR399i, gma-MIR319q, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
Among them, the expression levels of gma-miR397a, gma-miR166u and gma-miR171p were increased more than three-fold, whereas the expression of gma-miR167c, gma-miR399 and gma-miR2111f showed a fractional increase (Figure 2A). [score:5]
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[+] score: 3
Other miRNAs from this paper: mtr-MIR162, mtr-MIR166a, mtr-MIR169a, mtr-MIR399b, mtr-MIR399d, mtr-MIR395a, mtr-MIR395b, mtr-MIR399c, mtr-MIR399a, mtr-MIR399e, mtr-MIR319a, mtr-MIR156a, mtr-MIR171a, gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR166a, gma-MIR166b, gma-MIR168a, gma-MIR172a, gma-MIR172b, gma-MIR319a, gma-MIR319b, gma-MIR156a, gma-MIR398a, gma-MIR398b, gma-MIR319c, gma-MIR156b, gma-MIR169a, mtr-MIR395c, mtr-MIR395d, mtr-MIR395e, mtr-MIR395f, mtr-MIR395g, mtr-MIR395h, mtr-MIR395i, mtr-MIR395j, mtr-MIR395l, mtr-MIR395m, mtr-MIR395n, mtr-MIR395o, mtr-MIR395k, mtr-MIR156b, mtr-MIR164a, mtr-MIR166b, mtr-MIR169c, mtr-MIR169d, mtr-MIR169e, mtr-MIR171b, mtr-MIR166c, mtr-MIR166d, mtr-MIR169f, mtr-MIR156c, mtr-MIR156d, mtr-MIR390, mtr-MIR399f, mtr-MIR399g, mtr-MIR399h, mtr-MIR399i, mtr-MIR399j, mtr-MIR399k, mtr-MIR166e, mtr-MIR156e, mtr-MIR319b, mtr-MIR171c, mtr-MIR398a, mtr-MIR172a, mtr-MIR398b, mtr-MIR168a, mtr-MIR169g, mtr-MIR156f, mtr-MIR399l, mtr-MIR156g, mtr-MIR399m, mtr-MIR399n, mtr-MIR399o, mtr-MIR398c, mtr-MIR164b, mtr-MIR156h, mtr-MIR166f, mtr-MIR164c, mtr-MIR164d, mtr-MIR166g, mtr-MIR171d, mtr-MIR171e, mtr-MIR169h, mtr-MIR169b, mtr-MIR156i, mtr-MIR171f, mtr-MIR399p, gma-MIR162a, gma-MIR164a, gma-MIR169b, gma-MIR169c, gma-MIR171a, gma-MIR390a, gma-MIR390b, gma-MIR171b, gma-MIR482a, gma-MIR1507a, gma-MIR1509a, gma-MIR1511, gma-MIR1512a, gma-MIR1515a, gma-MIR1521a, mtr-MIR1507, mtr-MIR1509a, gma-MIR1507b, gma-MIR2109, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR1509b, mtr-MIR2118, mtr-MIR169k, mtr-MIR2111c, mtr-MIR2111d, mtr-MIR2111e, mtr-MIR2111g, mtr-MIR2111h, mtr-MIR2111i, mtr-MIR2111m, mtr-MIR2111n, mtr-MIR2111o, mtr-MIR169j, mtr-MIR1509b, mtr-MIR2111b, mtr-MIR2111j, mtr-MIR2111k, mtr-MIR399q, mtr-MIR2678, lja-MIR2111, gma-MIR482b, gma-MIR156f, gma-MIR169d, gma-MIR172f, gma-MIR171c, gma-MIR169e, gma-MIR156g, gma-MIR4416a, gma-MIR156h, gma-MIR156i, gma-MIR162b, gma-MIR164b, gma-MIR164c, gma-MIR164d, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR168b, gma-MIR169f, gma-MIR169g, gma-MIR171d, gma-MIR171e, gma-MIR171f, gma-MIR171g, gma-MIR319d, gma-MIR319e, gma-MIR319f, gma-MIR390c, gma-MIR398c, gma-MIR408d, gma-MIR2118a, gma-MIR2118b, gma-MIR482c, gma-MIR530a, gma-MIR862a, gma-MIR1507c, gma-MIR171h, gma-MIR171i, gma-MIR169h, gma-MIR1521b, gma-MIR169i, mtr-MIR5204, mtr-MIR5213, mtr-MIR482, mtr-MIR2111l, mtr-MIR2111f, mtr-MIR172b, mtr-MIR172c, mtr-MIR171h, mtr-MIR168b, mtr-MIR399r, mtr-MIR156j, gma-MIR862b, gma-MIR403a, gma-MIR403b, gma-MIR171j, gma-MIR395a, gma-MIR395b, gma-MIR395c, gma-MIR397a, gma-MIR397b, gma-MIR408a, gma-MIR408b, gma-MIR408c, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR162c, gma-MIR166i, gma-MIR166j, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR171k, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR319g, gma-MIR319h, gma-MIR319i, gma-MIR319j, gma-MIR319k, gma-MIR319l, gma-MIR319m, gma-MIR482d, gma-MIR1512b, gma-MIR171l, mtr-MIR168c, mtr-MIR408, mtr-MIR2111a, gma-MIR2111a, gma-MIR1512c, gma-MIR530b, mtr-MIR171g, mtr-MIR530, gma-MIR4416b, gma-MIR828a, gma-MIR156p, gma-MIR530c, gma-MIR828b, gma-MIR530d, gma-MIR171m, gma-MIR172k, gma-MIR171n, gma-MIR156q, gma-MIR171o, gma-MIR172l, gma-MIR169o, gma-MIR319n, gma-MIR171p, gma-MIR530e, gma-MIR169p, gma-MIR156r, gma-MIR399b, gma-MIR171q, gma-MIR156s, gma-MIR169r, gma-MIR169s, gma-MIR2111b, gma-MIR2111c, gma-MIR166k, gma-MIR2111d, gma-MIR156t, gma-MIR482e, gma-MIR399c, gma-MIR171r, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR171s, gma-MIR166l, gma-MIR171t, gma-MIR2111e, gma-MIR2111f, gma-MIR171u, gma-MIR399f, gma-MIR399g, gma-MIR395d, gma-MIR395e, gma-MIR395f, gma-MIR395g, gma-MIR166m, gma-MIR169u, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR164e, gma-MIR164f, gma-MIR164g, gma-MIR164h, gma-MIR164i, gma-MIR164j, gma-MIR164k, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR169v, gma-MIR390d, gma-MIR390e, gma-MIR390f, gma-MIR390g, gma-MIR395h, gma-MIR395i, gma-MIR395j, gma-MIR395k, gma-MIR395l, gma-MIR395m, gma-MIR1515b, lja-MIR171a, lja-MIR171b, lja-MIR171c, lja-MIR171d, lja-MIR172a, lja-MIR172b, lja-MIR172c, lja-MIR390a, lja-MIR390b, lja-MIR397, lja-MIR408, lja-MIR1507a, lja-MIR1507b, mtr-MIR169i, mtr-MIR172d, mtr-MIR319c, mtr-MIR319d, mtr-MIR397, mtr-MIR169l, mtr-MIR399s, mtr-MIR399t, gma-MIR398d, gma-MIR319o, gma-MIR319p, gma-MIR399i, gma-MIR319q, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o, lja-MIR164, lja-MIR398, lja-MIR168, lja-MIR395, lja-MIR1511, lja-MIR166
However, searches of miR395 and miR399-like sequences in the G. max genomic database, allowing three mismatches, allowed us to identify 30 and 20 putative members respectively (C. Lelandais, pers. [score:1]
Surprisingly, for some families, an opposite profile was observed: for instance, miR395 and miR399 genes, generally organized in clusters, were more abundant in M. truncatula than in soybean (18/13 genes for miR395 and 18/8 genes for miR399 according to miRBase). [score:1]
Most of them (from miR156 to miR399) corresponded to the set of 21 conserved miRNAs found in nearly all angiosperms (Sunkar and Jagadeeswaran, 2008). [score:1]
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[+] score: 3
Other miRNAs from this paper: ath-MIR156a, ath-MIR156b, ath-MIR156c, ath-MIR156d, ath-MIR156e, ath-MIR156f, ath-MIR166a, ath-MIR166b, ath-MIR166c, ath-MIR166d, ath-MIR166e, ath-MIR166f, ath-MIR166g, ath-MIR169a, ath-MIR171a, ath-MIR169b, ath-MIR169c, ath-MIR169d, ath-MIR169e, ath-MIR169f, ath-MIR169g, ath-MIR169h, ath-MIR169i, ath-MIR169j, ath-MIR169k, ath-MIR169l, ath-MIR169m, ath-MIR169n, ath-MIR171b, ath-MIR171c, ath-MIR395a, ath-MIR395b, ath-MIR395c, ath-MIR395d, ath-MIR395e, ath-MIR395f, ath-MIR396a, ath-MIR396b, ath-MIR399a, ath-MIR408, ath-MIR156g, ath-MIR156h, gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR166a, gma-MIR166b, gma-MIR156a, gma-MIR396a, gma-MIR396b, gma-MIR156b, gma-MIR169a, ath-MIR848, gma-MIR169b, gma-MIR169c, gma-MIR171a, gma-MIR171b, gma-MIR1527, gma-MIR1533, gma-MIR396c, pvu-MIR166a, pvu-MIR399a, gma-MIR396d, gma-MIR156f, gma-MIR169d, gma-MIR171c, gma-MIR169e, gma-MIR156g, gma-MIR396e, gma-MIR156h, gma-MIR156i, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR169f, gma-MIR169g, gma-MIR171d, gma-MIR171e, gma-MIR171f, gma-MIR171g, gma-MIR408d, ath-MIR5021, gma-MIR171h, gma-MIR171i, gma-MIR169h, gma-MIR169i, gma-MIR396f, gma-MIR396g, gma-MIR171j, gma-MIR395a, gma-MIR395b, gma-MIR395c, gma-MIR408a, gma-MIR408b, gma-MIR408c, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR166i, gma-MIR166j, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR171k, gma-MIR396h, gma-MIR396i, gma-MIR171l, ath-MIR156i, ath-MIR156j, gma-MIR156p, gma-MIR171m, gma-MIR171n, gma-MIR156q, gma-MIR171o, gma-MIR169o, gma-MIR171p, gma-MIR169p, gma-MIR156r, gma-MIR396j, gma-MIR171q, gma-MIR156s, gma-MIR169r, gma-MIR169s, gma-MIR396k, gma-MIR166k, gma-MIR156t, gma-MIR171r, gma-MIR169t, gma-MIR171s, gma-MIR166l, gma-MIR171t, gma-MIR171u, gma-MIR395d, gma-MIR395e, gma-MIR395f, gma-MIR395g, gma-MIR166m, gma-MIR169u, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR169v, gma-MIR395h, gma-MIR395i, gma-MIR395j, gma-MIR395k, gma-MIR395l, gma-MIR395m, gma-MIR169w
Fig. 4 Secondary structure of a pre-miR (pvu-miR399a) showing the mature miRNA sequence highlighted in blue The distribution of 208 newly predicted miRNAs in P vulgaris varies among the 118 miRNA families (Table  2). [score:1]
Fig.   4 shows a particular miRNA ‘pvu-miR399a’ that fulfils all the seven criteria used for the prediction. [score:1]
Fig. 4 Secondary structure of a pre-miR (pvu-miR399a) showing the mature miRNA sequence highlighted in blueThe distribution of 208 newly predicted miRNAs in P vulgaris varies among the 118 miRNA families (Table  2). [score:1]
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12
[+] score: 3
Other miRNAs from this paper: gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR159a, gma-MIR166a, gma-MIR167a, gma-MIR167b, gma-MIR168a, gma-MIR172a, gma-MIR172b, gma-MIR319a, gma-MIR156a, gma-MIR396a, gma-MIR396b, gma-MIR156b, gma-MIR169a, gma-MIR159b, gma-MIR159c, gma-MIR167c, gma-MIR169b, gma-MIR169c, gma-MIR393a, gma-MIR482a, gma-MIR1508a, gma-MIR1509a, gma-MIR1511, gma-MIR1512a, gma-MIR1515a, gma-MIR1517, gma-MIR167d, gma-MIR396c, gma-MIR1508b, gma-MIR2109, gma-MIR167e, gma-MIR167f, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR1509b, gma-MIR4357, gma-MIR396d, gma-MIR482b, gma-MIR167g, gma-MIR156f, gma-MIR169d, gma-MIR172f, gma-MIR169e, gma-MIR394b, gma-MIR156g, gma-MIR159d, gma-MIR394a, gma-MIR4416a, gma-MIR396e, gma-MIR156h, gma-MIR156i, gma-MIR168b, gma-MIR169f, gma-MIR169g, gma-MIR394c, gma-MIR482c, gma-MIR1508c, gma-MIR169h, gma-MIR167h, gma-MIR169i, gma-MIR396f, gma-MIR396g, gma-MIR167i, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR159e, gma-MIR159f, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR396h, gma-MIR396i, gma-MIR482d, gma-MIR1512b, gma-MIR167j, gma-MIR1512c, gma-MIR5559, gma-MIR393b, gma-MIR4416c, gma-MIR4416b, gma-MIR156p, gma-MIR172k, gma-MIR156q, gma-MIR172l, gma-MIR169o, gma-MIR171p, gma-MIR394d, gma-MIR169p, gma-MIR156r, gma-MIR399b, gma-MIR396j, gma-MIR156s, gma-MIR169r, gma-MIR169s, gma-MIR396k, gma-MIR2111b, gma-MIR156t, gma-MIR482e, gma-MIR399c, gma-MIR394e, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR394f, gma-MIR399f, gma-MIR399g, gma-MIR169u, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR169v, gma-MIR393c, gma-MIR393d, gma-MIR393e, gma-MIR393f, gma-MIR393g, gma-MIR393h, gma-MIR393i, gma-MIR393j, gma-MIR393k, gma-MIR394g, gma-MIR1515b, gma-MIR399i, gma-MIR167k, gma-MIR167l, gma-MIR4405b, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
Differential expression of miRNAs such as gma-miR167, gma-miR172, gma-miR399, gma-miR396 and gma-miR169c in soybean nodules, and mtr-miR2568, mtr-miR107 in M. truncatula were also identified [34– 36]. [score:3]
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13
[+] score: 1
Other miRNAs from this paper: gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR159a, gma-MIR160a, gma-MIR166a, gma-MIR166b, gma-MIR319a, gma-MIR156a, gma-MIR396a, gma-MIR396b, gma-MIR156b, gma-MIR159b, gma-MIR159c, gma-MIR162a, gma-MIR164a, gma-MIR393a, gma-MIR1518, gma-MIR1520d, gma-MIR1521a, gma-MIR396c, gma-MIR2119, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR4380a, gma-MIR396d, gma-MIR4378a, gma-MIR4380b, gma-MIR156f, gma-MIR4407, gma-MIR4413a, gma-MIR156g, gma-MIR159d, gma-MIR396e, gma-MIR156h, gma-MIR156i, gma-MIR160b, gma-MIR160c, gma-MIR160d, gma-MIR160e, gma-MIR162b, gma-MIR164b, gma-MIR164c, gma-MIR164d, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR396f, gma-MIR396g, gma-MIR397a, gma-MIR397b, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR159e, gma-MIR159f, gma-MIR162c, gma-MIR166i, gma-MIR166j, gma-MIR396h, gma-MIR396i, gma-MIR1512b, gma-MIR4413b, gma-MIR5674a, gma-MIR5770a, gma-MIR4416c, gma-MIR5770b, gma-MIR156p, gma-MIR156q, gma-MIR156r, gma-MIR399b, gma-MIR396j, gma-MIR156s, gma-MIR396k, gma-MIR166k, gma-MIR156t, gma-MIR399c, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR166l, gma-MIR399f, gma-MIR399g, gma-MIR166m, gma-MIR5674b, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR160f, gma-MIR164e, gma-MIR164f, gma-MIR164g, gma-MIR164h, gma-MIR164i, gma-MIR164j, gma-MIR164k, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR9747, gma-MIR399i, gma-MIR9763, gma-MIR5770c, gma-MIR399j, gma-MIR399k, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
A similar result was found for the MIR399 and MIR4380 families (Table  3). [score:1]
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14
[+] score: 1
Other miRNAs from this paper: gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR159a, gma-MIR166a, gma-MIR166b, gma-MIR168a, gma-MIR156a, gma-MIR396a, gma-MIR396b, gma-MIR398a, gma-MIR398b, gma-MIR156b, gma-MIR169a, gma-MIR159b, gma-MIR159c, gma-MIR169b, gma-MIR169c, gma-MIR171a, gma-MIR390a, gma-MIR390b, gma-MIR393a, gma-MIR171b, gma-MIR1507a, gma-MIR1509a, gma-MIR1510a, gma-MIR1515a, gma-MIR396c, gma-MIR1507b, gma-MIR1510b, gma-MIR1509b, gma-MIR396d, gma-MIR156f, gma-MIR169d, gma-MIR171c, gma-MIR169e, gma-MIR156g, gma-MIR159d, gma-MIR396e, gma-MIR156h, gma-MIR156i, gma-MIR166c, gma-MIR166d, gma-MIR166e, gma-MIR166f, gma-MIR166g, gma-MIR166h, gma-MIR168b, gma-MIR169f, gma-MIR169g, gma-MIR171d, gma-MIR171e, gma-MIR171f, gma-MIR171g, gma-MIR390c, gma-MIR398c, gma-MIR2118a, gma-MIR2118b, gma-MIR862a, gma-MIR1507c, gma-MIR171h, gma-MIR171i, gma-MIR169h, gma-MIR169i, gma-MIR396f, gma-MIR396g, gma-MIR171j, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR159e, gma-MIR159f, gma-MIR166i, gma-MIR166j, gma-MIR169j, gma-MIR169k, gma-MIR169l, gma-MIR169m, gma-MIR169n, gma-MIR171k, gma-MIR396h, gma-MIR396i, gma-MIR171l, gma-MIR2111a, gma-MIR393b, gma-MIR828a, gma-MIR156p, gma-MIR828b, gma-MIR171m, gma-MIR171n, gma-MIR156q, gma-MIR171o, gma-MIR169o, gma-MIR171p, gma-MIR169p, gma-MIR156r, gma-MIR399b, gma-MIR396j, gma-MIR171q, gma-MIR156s, gma-MIR169r, gma-MIR169s, gma-MIR396k, gma-MIR2111b, gma-MIR2111c, gma-MIR166k, gma-MIR2111d, gma-MIR156t, gma-MIR399c, gma-MIR171r, gma-MIR399d, gma-MIR399e, gma-MIR169t, gma-MIR171s, gma-MIR166l, gma-MIR171t, gma-MIR2111e, gma-MIR2111f, gma-MIR171u, gma-MIR399f, gma-MIR399g, gma-MIR166m, gma-MIR169u, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR166n, gma-MIR166o, gma-MIR166p, gma-MIR166q, gma-MIR166r, gma-MIR166s, gma-MIR166t, gma-MIR166u, gma-MIR169v, gma-MIR390d, gma-MIR390e, gma-MIR390f, gma-MIR390g, gma-MIR393c, gma-MIR393d, gma-MIR393e, gma-MIR393f, gma-MIR393g, gma-MIR393h, gma-MIR393i, gma-MIR393j, gma-MIR393k, gma-MIR1515b, gma-MIR398d, gma-MIR399i, gma-MIR399j, gma-MIR399k, gma-MIR169w, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
Substantial variation was observed for gma-miR393, gma-miR398 and gma-miR399, whose abundance in ZP03-5373 was 10-fold greater than in ZP03-5413 (Table S2). [score:1]
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15
[+] score: 1
Other miRNAs from this paper: ath-MIR156a, ath-MIR156b, ath-MIR156c, ath-MIR156d, ath-MIR156e, ath-MIR156f, ath-MIR159a, ath-MIR172a, ath-MIR172b, ath-MIR159b, ath-MIR319a, ath-MIR319b, ath-MIR172c, ath-MIR172d, ath-MIR390a, ath-MIR390b, ath-MIR399a, ath-MIR399b, ath-MIR399c, ath-MIR399d, ath-MIR399e, ath-MIR399f, ath-MIR156g, ath-MIR156h, ath-MIR159c, ath-MIR319c, ath-MIR172e, gma-MIR156d, gma-MIR156e, gma-MIR156c, gma-MIR159a, gma-MIR172a, gma-MIR172b, gma-MIR319a, gma-MIR319b, gma-MIR156a, gma-MIR319c, gma-MIR156b, gma-MIR159b, gma-MIR159c, gma-MIR390a, gma-MIR390b, gma-MIR172c, gma-MIR172d, gma-MIR172e, gma-MIR156f, gma-MIR172f, gma-MIR156g, gma-MIR159d, gma-MIR156h, gma-MIR156i, gma-MIR319d, gma-MIR319e, gma-MIR319f, gma-MIR390c, gma-MIR156j, gma-MIR156k, gma-MIR156l, gma-MIR156m, gma-MIR156n, gma-MIR156o, gma-MIR159e, gma-MIR159f, gma-MIR172g, gma-MIR172h, gma-MIR172i, gma-MIR172j, gma-MIR319g, gma-MIR319h, gma-MIR319i, gma-MIR319j, gma-MIR319k, gma-MIR319l, gma-MIR319m, ath-MIR156i, ath-MIR156j, gma-MIR156p, gma-MIR172k, gma-MIR156q, gma-MIR172l, gma-MIR319n, gma-MIR156r, gma-MIR399b, gma-MIR156s, gma-MIR156t, gma-MIR399c, gma-MIR399d, gma-MIR399e, gma-MIR399f, gma-MIR399g, gma-MIR399h, gma-MIR156u, gma-MIR156v, gma-MIR156w, gma-MIR156x, gma-MIR156y, gma-MIR156z, gma-MIR156aa, gma-MIR156ab, gma-MIR390d, gma-MIR390e, gma-MIR390f, gma-MIR390g, gma-MIR319o, gma-MIR319p, gma-MIR399i, gma-MIR319q, gma-MIR399j, gma-MIR399k, gma-MIR399l, gma-MIR399m, gma-MIR399n, gma-MIR399o
In addition, the miR319, miR390 and miR399 families also play a role in the control of flowering time [8, 9, 10, 11]. [score:1]
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