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31 publications mentioning zma-MIR159c

Open access articles that are associated with the species Zea mays and mention the gene name MIR159c. Click the [+] symbols to view sentences that include the gene name, or the word cloud on the right for a summary.

1
[+] score: 62
Other miRNAs from this paper: zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR162, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR394a, zma-MIR394b, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR399a, zma-MIR399c, zma-MIR399b, zma-MIR399d, zma-MIR399e, zma-MIR399f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR319a, zma-MIR319c, zma-MIR319b, zma-MIR319d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR393a, zma-MIR408a, zma-MIR156k, zma-MIR160f, zma-MIR2118a, zma-MIR2118b, zma-MIR2118c, zma-MIR2118d, zma-MIR2118e, zma-MIR2118f, zma-MIR2118g, zma-MIR2275a, zma-MIR2275b, zma-MIR2275c, zma-MIR2275d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR393b, zma-MIR393c, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR397a, zma-MIR397b, zma-MIR398a, zma-MIR398b, zma-MIR399g, zma-MIR399h, zma-MIR399i, zma-MIR399j, zma-MIR408b, zma-MIR482, zma-MIR528a, zma-MIR528b, zma-MIR529, zma-MIR827, zma-MIR1432, zma-MIR444a, zma-MIR444b
In this report, MiR159, miR169 and miR319 were all down-regulated with miR159 being down-regulated by 7.7 folds, the most down-regulated miRNA family in imbibed seed. [score:10]
MiR159 and miR319 showed high similarity in mature miRNA sequences, their target motifs were highly conserved in cereal and Arabidopsis GAMYB genes, and they often shared same target genes. [score:5]
In the absence of miR159, the deregulation of MYB33 and MYB65 up-regulated genes that were GA induced during seed germination. [score:5]
In Arabidopsis, miR159, targeting MYB33 and MYB101, two ABA positive regulators, plays a vital role in seed germination [19]. [score:4]
Whereas miR156 and miR166, although they both were down-regulated in imbibed seed only by 1.5 folds, their basal frequencies in dry seeds were 525,736 and 432,679, respectively, much higher than those of miR159, miR393 and miR394. [score:4]
The 12 down-regulated miRNA families were miR156, miR159, miR164, miR166, miR167, miR168, miR169, miR172, miR319, miR393, miR394 and miR397. [score:4]
The miR159 was reported to targets MYB101 and MYB33 transcription factors, which are positive regulators of ABA signalling during Arabidopsis seed germination, suggesting that miR159 may play a role in seed germination [19]. [score:4]
When ABA level decreased, the expression of miR159 would be decreased. [score:3]
GRMZM2G028054, a member of MYB family, was target gene of both miR159 and miR319. [score:3]
For example, miR159, miR393 and miR394 were down-regulated by 7.7, 5.3 and 5.5 folds, respectively, in imbibed seeds compared to those in dry seeds. [score:3]
RMZM2G139688 and GRMZM2G028054 were predicted as target genes of both miR159 and miR319 in this study. [score:3]
GRMZM2G028054 was validated as target gene of miR159/319 by 5′ RACE cleavage assay (Figure 9). [score:2]
Thus, miR159 may function in allowing a fast recovery from high ABA levels by regulating the genes of positive factors continually when the signal disappears [19]. [score:2]
AtMYB33, AtMYB65 and AtMYB101 were members of GAMYB-like family and were post-transcriptionally regulated by miR159 [44]. [score:2]
Thus, GAMYB-like genes participated in GA -induced pathways via miR159 -mediated regulation during seed germination. [score:2]
In this study, GRMZM2G423833 and GRMZM2G070523, the homologs of AtMYB33 and AtMYB101, were predicted as target genes of MiR159 and GRMZM2G070523 was validated by degradome sequencing (data not shown). [score:2]
This negative feedback of ABA signalling by miR159 may be important for seed in the shift from dormancy to germination [11]. [score:1]
Zma-miR319/miR159 cleavage site in GRMZM2G028054_T01 mRNAs determined by 5'-RLM-RACE. [score:1]
To validate conserved miRNAs identified and novel ones predicted, quantitative RT-PCR (qRT-PCR) was performed on 10 randomly selected miRNAs, miR156, miR159, miR166, miR167, miR319, miR408, miR528, zma-miRn6, zma-miRn15 and zma-miRn37 in dry and imbibed seed. [score:1]
Upon seed germination, ABA level decreases, so are the abundances of miR159, mi169 and miR319. [score:1]
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2
[+] score: 49
There are six targets (two GAMYB targets of miR159/319, two ARF targets of miR167, one AP2/ERF target of miR172, and one F-box (TIR1-like gene)), which were validated by the 5′-RLM-RACE (Figure 8). [score:9]
However, based on this analysis, we can’t assign a negative feedback loop between miR159 and MYB, though a probable feedback loop between miR159 and MYB33 was found in Arabidopsis where feedback involved the down-regulation of AtMYB33 activity by miR159 and compensatory up-regulation of miR159 by AtMYB33 [81]. [score:7]
These 13 targets are targeted by 8 miRNA families (miR159, miR164, miR167, miR172, miR319, miR393, miR528, miRn7) (Table S9), which are active participants in the signal transduction at the early stage of hypoxia conditions. [score:5]
In the tolerant line, the induction of miR159 might regulate ABA signal transduction pathway by repressing their MYB targets; induction of miR167 represses ARF that has been demonstrated to be involved in lateral root development, or adventitious rooting through the auxin signal [79]. [score:5]
In Arabidopsis, miR159 regulates ABA signaling by targeting MYB33 and MYB101 [17]. [score:4]
In our study, MYB33 homolog (GRMZM2G28054) and MYB101 homolog (GRMZM2G139688) are targeted by miR159 which have been validated by the 5′-RLM-RACE (Figure 8). [score:3]
ph3 binding sites in the promoter region of these three genes of miR159, whereas targets of these genes belong to GAMYB family. [score:3]
miR159 and miR319 shares the target sequence. [score:3]
Both miR159 and miR319 are down regulated in B73 under hypoxia conditions. [score:2]
miR159, miR164, miR167,miR393, miR408 and miR528, which are involved in root cap formation, lateral root development, root/shoot elongation and plant cell detoxification by scavenging the reactive oxygen species and thus protecting damage to cellular structure were induced under short waterlogging conditions in waterlogging tolerant line Hz32 and repressed in waterlogging sensitive line Mo17. [score:2]
However, based on upstream and downstream homology analysis of miR159 (miR159j, miR159h, miR159k), we found MYB. [score:1]
The network also shows probable negative feedback loop between MYB and miR319b and MYB and miR159. [score:1]
miR319 and miR159 are highly conserved miRNAs and are involved in plant growth, morphogenesis and reproduction [113]. [score:1]
In B73, the mid-tolerant line, miR159, miR408 and miR528 (similar to Hz32) are induced while miR164, miR167 and miR393 (similar to Mo17) are reduced, suggested the repression of ABA and cupredoxin signals and the induction of auxin signals at the initial stages of waterlogging. [score:1]
We also found the probable feedback loop between three miRNA genes of miR159 (miR159j, miR159h, miR159k), and MYB family. [score:1]
The induction of miR159 in waterlogging tolerant line Hz32 suggests miR159 repress the ABA signal by repressing MYB proteins. [score:1]
[1 to 20 of 16 sentences]
3
[+] score: 43
Other miRNAs from this paper: zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR171d, zma-MIR171f, zma-MIR394a, zma-MIR394b, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR396b, zma-MIR396a, zma-MIR399a, zma-MIR399c, zma-MIR399b, zma-MIR399d, zma-MIR399e, zma-MIR399f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR319a, zma-MIR319c, zma-MIR319b, zma-MIR319d, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR171k, zma-MIR171h, zma-MIR408a, zma-MIR156k, zma-MIR160f, zma-MIR396c, zma-MIR396d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR396e, zma-MIR396f, zma-MIR396g, zma-MIR396h, zma-MIR399g, zma-MIR399h, zma-MIR399i, zma-MIR399j, zma-MIR408b, zma-MIR529
Among the target genes profiled in the ear leaves of the inbred line ELS-1, the gene expression trends were opposite those of miR171, miR172, miR159, and miR396, suggesting that these miRNA target genes were subjected to a negative regulation by the miRNAs, most likely through a target cleavage pathway. [score:10]
Similarly, the expression trends of miR159, miR169, and miR172 were negatively correlated with those of their target genes in the inbred line Yu87-1, while the expression levels of miR171 and miR529 were positively correlated with their target genes. [score:9]
In this study, six miRNAs regulating nodes, miR172, miR159, miR171, miR167, pre-mir131, and pre-mir11, were highlighted as key regulators of leaf senescence because of their differential expression profiles between ELS-1 and Yu87-1, and a candidate miRNA -dependent leaf senescence pathway was established based on the differentially expressed miRNAs and their potential functions discussed (Fig.   6). [score:7]
Among the candidate miRNAs, miR159, miR169, miR394, and miR529 were up-regulated from 20 to 30DAP, and miR172, miR167, and miR171 were down-regulated from 20 to 30DAP. [score:7]
Additionally, other miRNAs and their targets, for example, osa-miR159, osa-miR160/miR167, osa-miR164,and osa-miR172, targeting mRNAs coding for MYB/TCP, Auxin Response Factor, salicylic acid -induced protein 19, and AP2 proteins, respectively, were also found to be involved in leaf senescence through phytohormone signaling pathways in rice [23]. [score:5]
Among those identified in the leaves of inbred line ELS-1, differentially expressed miRNAs whose |log [2]-fold change| was >1.5 in the leaves of inbred line Yu87-1 were removed, and 16 candidate miRNAs were finally identified in the leaves of inbred line ELS-1. These 16 differentially expressed miRNAs, belonging to nine miRNA families, zma-miR156, zma-miR159, zma-miR167, zma-miR171, zma-miR172, zma-miR395, zma-miR399, zma-miR408, and zma-miR529, were selected as candidate SA-miRNAs (Fig.   3). [score:5]
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4
[+] score: 43
That is, they all (miR159 and its target with IAA; miR166, miR169, miR393, miR396, and their targets with ZR + iPA; miR159, miR396 and their targets with GA; miR396 and their targets with BR; miR159, miR396 and their targets with JA; miR160, miR164, miR166, miR169, miR172, and miR396 and their targets with ABA) showed a significant positive and/or negative correlation with the phytohormone levels. [score:13]
Our data also revealed that expression of TCP, the target gene of miR159, was higher in IFC than CFC ovaries (Table 2; Figure 3), suggesting a regulatory function of miR159 in carpel fusion development. [score:7]
Some of the differentially expressed known miRNAs targeted multiple gene loci; for example miR159 (Figure 5). [score:5]
Moreover, mRNA expression of both TFs was found to show an opposite trend compared to miR159 during ovary development in both IFC and CFC ovaries (Figures 3, 5), suggesting a consistent regulatory role of miR159 during ovary development in maize. [score:5]
A large proportion of the genes known to be involved in normal carpel fusion are TF genes, two of which, MYB and TCP, are known to play a key role in regulation of carpel fusion development in Arabidopsis (Shin et al., 2002; Koyama et al., 2007), were found to be targeted by miR159 (Table 3). [score:5]
miR159 also targets genes encoding the MYB TF, which is involved in regulation of ABA (Reyes and Chua, 2007). [score:4]
Eight known miRNAs (miR159, miR160, miR164, miR166, miR169, miR172, miR393, and miR396), four newly identified miRNAs, and 12 target genes were selected for qRT-PCR validation. [score:3]
ABA induction of miR159 controls transcript levels of two MYB factors during Arabidopsis seed germination. [score:1]
[1 to 20 of 8 sentences]
5
[+] score: 32
Other miRNAs from this paper: zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR160e, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR171d, zma-MIR171f, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR396b, zma-MIR396a, zma-MIR399a, zma-MIR399c, zma-MIR399b, zma-MIR399d, zma-MIR399e, zma-MIR399f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR166k, zma-MIR166j, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR393a, zma-MIR156k, zma-MIR160f, zma-MIR396c, zma-MIR396d, zma-MIR2118a, zma-MIR2118b, zma-MIR2118c, zma-MIR2118d, zma-MIR2118e, zma-MIR2118f, zma-MIR2118g, zma-MIR2275a, zma-MIR2275b, zma-MIR2275c, zma-MIR2275d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR390a, zma-MIR393b, zma-MIR393c, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR396e, zma-MIR396f, zma-MIR396g, zma-MIR396h, zma-MIR399g, zma-MIR399h, zma-MIR399i, zma-MIR399j, zma-MIR529, zma-MIR390b
Conversely, in V-372, members of 7 families—zma-miR164, zma-miR169, zma-miR393, zma-miR396, zma-miR399, zma-miR529, and zma-miR2275—were significantly up-regulated; and zma-miR156, zma-miR159, zma-miR166 and zma-miR395 families were significantly down-regulated. [score:7]
Similarly, Type IV interaction was also observed for the miR159 family, targeting the transcription factor GAMYB that is involved in flowering development and flowering time. [score:4]
However, zma-miR156 and zma-miR159 were significantly down-regulated. [score:4]
In tolerant genotype HKI-1532, 16 miRNAs belonging to the zma-miR159, zma-miR160, zma-miR164, zma-miR166, zma-miR169, zma-miR390, zma-miR395, zma-miR396, and zma-miR399 families were significantly up-regulated. [score:4]
In Arabidopsis, miR395 has been found to regulate an ATP sulfurylase and an unrelated sulfate transporter (Allen et al., 2005), and miR159 has been reported to target both MYB101 and MYB120 and two unrelated genes, OPT1 and ACS8 (Schwab et al., 2005). [score:4]
Furthermore, overexpression of the miR159 family during stress aids in germination under stress conditions. [score:3]
Regulation of MYB transcription factors by the member of miR159 was also reported in temperate maize (Li et al., 2013) and was found to play a crucial role in stress tolerance (Wang Y. G. et al., 2014). [score:2]
It was found that the families such as miR2118, miR395, and miR159 were highly conserved in maize and rice (Xu et al., 2017). [score:1]
ABA induction of miR159 controls transcript levels of two MYB factors during Arabidopsis seed germination. [score:1]
m Transcription factor gamyb zma-miR159-c,d,g,h,i gnl|GNOMON|57248043. [score:1]
m Squamosa promoter -binding-like protein 13-like miR159 zma-miR159e-3p gnl|GNOMON|11944063. [score:1]
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6
[+] score: 31
miR156 target: GRMZM2G126018_T01 (SBP23); miR159 target: GRMZM2G139688_T01 (GA-MYB); miR164 target: GRMZM2G393433_T01 (CUC2); miR168 target: GRMZM2G039455_T01 (AGO1c). [score:9]
In a previous study performed on VS-535-derived EC, we found that development-related miRNAs such as miR156, miR159, miR164 and miR168 decreased as the length of subculture increased, while stress-related miRNAs such as miR397, miR398, miR408, and miR528 remained highly expressed (Dinkova and Alejandri-Ramirez, 2014). [score:4]
Nevertheless, an inverse correlation between GA-MYB and slight miR159 fluctuations were usually observed for H-565 and to a lesser extent for VS-535, suggesting that miR159 expression during SE might be important to keep GA-MYB levels low when not needed. [score:3]
To assess the possible role of some conserved miRNAs at translation level, polyribosomal fractions were obtained from 2 years-subcultured VS-535 EC and the presence of miR159, miR168, miR398, and miR528 was analyzed (Figure 5). [score:3]
In addition, miR159 -mediated regulation on MYB transcripts might depend on the tissue and developmental stage, at least in Arabidopsis (Woodger et al., 2003; Alonso-Peral et al., 2012). [score:3]
An exemption to most miRNA expression patterns was miR159, showing little or no change in response to hormones depletion in both cultures. [score:3]
Although miR159 and miR168 displayed slight changes in response to plant regeneration stimuli, their target levels (GRMZM2G139688_T01, Giberellic Acid-responsive MYB, GA-MYB for miR159 and GRMZM2G039455_T01, AGO1c for miR168) showed significant fluctuations at least for 0% hormones in darkness and photoperiod (Figure 3, lanes c and e). [score:3]
Previous studies in maize long-term subcultured EC indicated that miR156, miR159, miR164, miR168, and miR319 importantly reduce their levels in subcultures maintained for more than 18 months (Dinkova and Alejandri-Ramirez, 2014). [score:1]
miR159 is one of the most abundant miRNAs in maize EC (Shen et al., 2013) and its levels change the least (Figure 2). [score:1]
ABA induction of miR159 controls transcript levels of two MYB factors during Arabidopsis seed germination. [score:1]
[1 to 20 of 10 sentences]
7
[+] score: 22
Three miRNAs that likely play key roles in maize stamen development include miR159, which targets gibberellin (GA) -induced MYB (GAMYB) TFs, miR167, which targets auxin response factor (ARF) TFs, and miR319, which targets TCP TFs. [score:8]
Particularly relevant to this discussion, the miR159-GAMYB regulatory module appears to function in both heat and drought responses in wheat, rice, and Arabidopsis and miR159 and GAMYB levels are modulated in response to heat and drought stress, however the exact response (up- or downregulation) depends on both the tissue assayed and the species [52, 58– 61]. [score:4]
MiR159, miR167, and miR319 are reduced ~5, 30 and 7-fold in fzt tassel primordia, respectively, and thus reduction of these miRNAs and misregulation of their target mRNAs are excellent candidates to underlie male sterility in fzt. [score:4]
An intriguing possibility is that down-regulation of miR159 (or another miRNA) in fzt anthers may elicit a drought response even under well-watered conditions, and contribute to male sterility fzt anthers. [score:4]
MiR159-regulation of GAMYB TFs is a particularly intriguing with regard to fzt stamen defects. [score:1]
ABA induction of miR159 controls transcript levels of two MYB factors during Arabidopsis seed germination. [score:1]
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8
[+] score: 21
Surprisingly, although the expression level of Zma-miR159 was clearly higher in kernels than in endosperms, Zma-miR159.1 exhibited the opposite expression patterns: its average expression level was higher in endosperms compared to kernels (Figure 5D). [score:6]
Further investigation indicated that these tandem miRNAs also exhibited altered expression patterns during kernel and endosperm development, e. g., both Zma-miR319.1 and Zma-miR169.1 were predominantly expressed in 0, 3, and 5 DAP kernels, whereas Zma-miR159.1 and Zma-miR2001.1 were preferentially expressed in endosperms (Figures 5B–E). [score:6]
In previous study, it has been reported that miR159.1 and miR159.2 were simultaneously generated from a single precursor in rice (Lacombe et al., 2008), however, we found this phenomena was not a unique case and expression of tandem miRNAs could represent a new mechanism to produce multiple miRNAs in monocot plants. [score:3]
Interestingly, the precursors of five members of the miR159 family all exhibited this tandem miRNA expression pattern including Zma-miR159a, Zma-miR159b, Zma-miR159f, and Zma-miR159j/k (Figure S1A). [score:3]
Thus, we next examined the conservation of miR159 precursors among maize, rice, wheat, and barley, and surprisingly, that they all produced tandem miRNAs, although with several mismatches in miR159.1 among different species (Figure S1B). [score:1]
Figure S1 The stem-loop structures of precursors of miR159 and their tandem miRNAs in maize (A) and the sequences of miR159 in maize, wheat, barley, and rice (B). [score:1]
Moreover, a previous study has reported that tandem miR159.1 and miR159.2 were co-produced in rice and its relatives (Lacombe et al., 2008), which raised an intriguing question of their evolution in plant species. [score:1]
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9
[+] score: 21
Other miRNAs from this paper: zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR162, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR171d, zma-MIR171f, zma-MIR394a, zma-MIR394b, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR396b, zma-MIR396a, zma-MIR399a, zma-MIR399c, zma-MIR399b, zma-MIR399d, zma-MIR399e, zma-MIR399f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR319a, zma-MIR319c, zma-MIR319b, zma-MIR319d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR393a, zma-MIR408a, zma-MIR156k, zma-MIR160f, zma-MIR396c, zma-MIR396d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR393b, zma-MIR393c, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR396e, zma-MIR396f, zma-MIR396g, zma-MIR396h, zma-MIR397a, zma-MIR397b, zma-MIR398a, zma-MIR398b, zma-MIR399g, zma-MIR399h, zma-MIR399i, zma-MIR399j, zma-MIR408b, zma-MIR482, zma-MIR528a, zma-MIR528b, zma-MIR529, zma-MIR827, zma-MIR1432, zma-MIR444a, zma-MIR444b
In addition to these families, target genes of miR169, miR319, miR408 and miR529 were involved in transcription regulation, whereas miR159, miR397, and miR399 target genes were involved in response to stimulus. [score:6]
For example, miR156 targets SBP transcription factors [80], [81], while miR159 targets the MYB family [82]. [score:5]
In six of these cases the host genes were also the predicted target of the embedded miRNA gene, oriented either on the same strand (miR159c, miR319b, miR396a and miR397a) or opposite strand (miR169j and miR399d). [score:3]
In contrast, miR156, miR159, miR167, miR168, miR169, miR171, miR319, and miR529 had high expression counts (slightly over 3,000 RPM, on average). [score:3]
miR159e was not expressed in any of the tissues sampled and has no syntenic relationship with any of the sorghum miR159 genes (see sections below), suggesting that miR159e might not be functional. [score:3]
The evolutionary dynamics influencing miRNA family size is illustrated by closer examination of the miR159 family. [score:1]
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[+] score: 17
Other miRNAs from this paper: zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR171d, zma-MIR171f, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR399a, zma-MIR399c, zma-MIR399b, zma-MIR399d, zma-MIR399e, zma-MIR399f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR393a, zma-MIR156k, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR390a, zma-MIR393b, zma-MIR393c, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR398a, zma-MIR398b, zma-MIR399g, zma-MIR399h, zma-MIR399i, zma-MIR399j, zma-MIR528a, zma-MIR528b, zma-MIR529, zma-MIR827, zma-MIR390b
Results show that miR159, miR166, miR171, and miR529 had relatively higher expression before the 10 [th] DAP, which corresponded to the deep-sequencing data, while their target genes had opposite expression trends, with more accumulation after the 14 [th] DAP (Fig 3A). [score:7]
Target genes of miR159, miR166, miR171, and miR529 are transcription factors (S2 Table). [score:3]
In conclusion, conserved miRNA families that accumulate to higher levels during the early stage of maize seed development such as miR159, miR164, and miR166 might play roles by participating in transcriptional regulation and morphogenesis. [score:3]
miR159, miR164, miR166, miR171, miR390, miR399, and miR529 families might play roles in the embryogenesis of maize grain by participating in transcriptional regulation and morphogenesis, while miR167 and miR528 families might play roles in the process of nutrient storage by participating in the metabolism process and stress response. [score:2]
We found that miR159, miR164, miR166, miR171, miR390, miR393, and miR529 families all accumulated to high levels during the very early stage of development (4–6 DAP), especially miR166. [score:2]
[1 to 20 of 5 sentences]
11
[+] score: 16
Other miRNAs from this paper: ath-MIR156a, ath-MIR156b, ath-MIR156c, ath-MIR156d, ath-MIR156e, ath-MIR156f, ath-MIR159a, ath-MIR160a, ath-MIR160b, ath-MIR160c, ath-MIR162a, ath-MIR162b, ath-MIR164a, ath-MIR164b, ath-MIR166a, ath-MIR166b, ath-MIR166c, ath-MIR166d, ath-MIR166e, ath-MIR166f, ath-MIR166g, ath-MIR167a, ath-MIR167b, ath-MIR168a, ath-MIR168b, ath-MIR169a, ath-MIR172a, ath-MIR172b, ath-MIR159b, 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, ath-MIR167d, 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-MIR172c, ath-MIR172d, ath-MIR395a, ath-MIR395b, ath-MIR395c, ath-MIR395d, ath-MIR395e, ath-MIR395f, ath-MIR396a, ath-MIR396b, ath-MIR399a, ath-MIR399b, ath-MIR399c, ath-MIR399d, ath-MIR399e, ath-MIR399f, 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-MIR399a, osa-MIR399b, osa-MIR399c, osa-MIR399d, osa-MIR399e, osa-MIR399f, osa-MIR399g, osa-MIR399h, osa-MIR399i, osa-MIR399j, osa-MIR399k, ath-MIR408, ath-MIR156g, ath-MIR156h, ath-MIR159c, ath-MIR164c, ath-MIR167c, ath-MIR172e, osa-MIR156k, osa-MIR156l, osa-MIR159a, osa-MIR159b, osa-MIR159c, osa-MIR159d, osa-MIR159e, osa-MIR159f, 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-MIR172a, osa-MIR172b, osa-MIR172c, osa-MIR166g, osa-MIR166h, osa-MIR166i, osa-MIR171h, osa-MIR408, osa-MIR172d, osa-MIR167j, osa-MIR166m, osa-MIR166j, osa-MIR164f, zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR162, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, osa-MIR396e, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR396b, zma-MIR396a, zma-MIR399a, zma-MIR399c, zma-MIR399b, zma-MIR399d, zma-MIR399e, zma-MIR399f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171h, zma-MIR408a, zma-MIR156k, zma-MIR160f, osa-MIR529a, osa-MIR395m, osa-MIR395n, osa-MIR395o, osa-MIR395p, osa-MIR395q, osa-MIR395v, osa-MIR395w, osa-MIR395r, osa-MIR529b, osa-MIR169r, osa-MIR396f, zma-MIR396c, zma-MIR396d, 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-MIR2275a, osa-MIR2275b, zma-MIR2118a, zma-MIR2118b, zma-MIR2118c, zma-MIR2118d, zma-MIR2118e, zma-MIR2118f, zma-MIR2118g, zma-MIR2275a, zma-MIR2275b, zma-MIR2275c, zma-MIR2275d, osa-MIR396g, osa-MIR396h, osa-MIR396d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR396e, zma-MIR396f, zma-MIR396g, zma-MIR396h, zma-MIR399g, zma-MIR399h, zma-MIR399i, zma-MIR399j, zma-MIR408b, zma-MIR529, osa-MIR395x, osa-MIR395y, osa-MIR2275c, osa-MIR2275d, ath-MIR156i, ath-MIR156j
Interestingly, some target transcripts were regulated by pairs of miRNAs: both miR156 and miR529 targeted five members of the same SBP family, and the miR159/319 pair regulated three MYB domain transcription factors. [score:7]
Although most miRNA families appear to target a single class of targets, the miR159/319 family regulates both MYB and TCP transcription factors, which may control petal morphogenesis as previously reported [59]. [score:6]
The six most abundantly expressed miRNA families were miR166, miR168, miR167, miR156, miR159, and miRs6. [score:3]
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12
[+] score: 13
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-MIR166a, osa-MIR166b, osa-MIR166c, osa-MIR166d, osa-MIR166e, osa-MIR166f, osa-MIR171a, osa-MIR393a, osa-MIR397a, osa-MIR397b, osa-MIR156k, osa-MIR156l, osa-MIR159a, osa-MIR159b, osa-MIR159c, osa-MIR159d, osa-MIR159e, osa-MIR159f, osa-MIR319b, osa-MIR166k, osa-MIR166l, osa-MIR168a, osa-MIR168b, osa-MIR169f, 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-MIR172d, osa-MIR171i, osa-MIR166m, osa-MIR166j, zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR171d, zma-MIR171f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR319b, zma-MIR166k, zma-MIR166j, zma-MIR168a, zma-MIR168b, zma-MIR169f, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR393a, zma-MIR156k, osa-MIR529a, tae-MIR159a, tae-MIR159b, tae-MIR171a, tae-MIR1120a, osa-MIR1430, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR166n, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR393b, zma-MIR393c, zma-MIR397a, zma-MIR397b, hvu-MIR156a, tae-MIR156, hvu-MIR159b, hvu-MIR159a, hvu-MIR166a, hvu-MIR168, hvu-MIR171, hvu-MIR397a, tae-MIR171b, hvu-MIR1120, hvu-MIR166b, osa-MIR3981, hvu-MIR166c, tae-MIR1120b, tae-MIR397, tae-MIR1120c, hvu-MIR397b, hvu-MIR156b
Our observations show that the level of mature miR159 fluctuates in various developmental stages with the lowest expression level detected in 1-week-old plants, which is in agreement with the real-time PCR results for pri-miR159b (Figure 2D, upper graph). [score:4]
We observed high expression levels of mature miR159 using Northern hybridization, however, we failed to detect pre-miR159b, which was most likely a result of rapid processing of the pre-miRNA (Figure 2E). [score:3]
It has to be noted that Northern analysis shows the expression of all putative mature miR159 family members. [score:3]
Our studies, together with recent results of Lv et al. and miRBase, reveal that the miR159 family in barley consists of at least four members. [score:1]
In Arabidopsis, three members of the miR159 family were annotated - miR159a, b and c [3, 55] - while for monocotyledonous species such as rice and maize, eight and fourteen members of the miR159 family have been described, respectively [4, 43, 56, 57]. [score:1]
Lv et al. [49] described three barley miR159 species with different nucleotide sequences. [score:1]
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13
[+] score: 13
In our study, we did not found any ZmMYB as the target of miR828 or miR858, but we revealed that miR160 and miR159 may target 8 additional ZmMYBs (ZmMYB004, ZmMYB054, ZmMYB101, ZmMYB103, ZmMYB119, ZmMYB122, ZmMYB140, and ZmMYB155). [score:5]
Interestingly, the targets of miR159 in plant MYB gene family were limited to the GAMYB-like genes to date [76], [83]. [score:3]
However, our results indicate that, excepting miR159, miR319 may be also implicated in regulating 2 maize GAMYB-like genes (ZmMYB049 and ZmMYB119) in this subgroup. [score:2]
Furthermore, GAMYB was indicated to be negatively regulated by the microRNA (miRNA) family member, miR159 [75], [82]– [84]. [score:2]
Based on recently available genome-wide characterization of microRNA genes in maize [85], we revealed that 3 of these 6 maize GAMYB-like genes (ZmMYB049, ZmMYB080, and ZmMYB119) were predicted to be the target genes of maize miR159, based on similarities. [score:1]
[1 to 20 of 5 sentences]
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[+] score: 12
Genetic analysis reveals functional redundancy and the major target genes of the Arabidopsis miR159 family. [score:3]
Sequence and expression differences underlie functional specialization of Arabidopsis microRNAs miR159 and miR319. [score:3]
Evolution of MIR159/319 microRNA genes and their post-transcriptional regulatory link to siRNA pathways. [score:2]
It was shown that miR159 and 160 affect the process of germination by regulating ABA sensitivity. [score:2]
Others miRNAs affecting seed size belong to two families, miR159 and miR319 (Palatnik et al., 2007; Li et al., 2011). [score:1]
ABA induction of miR159 controls transcript levels of two MYB factors during Arabidopsis seed germination. [score:1]
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[+] score: 12
In addition, distinct family members of MIR169 and MIR159 were up- or down-regulated in meiocytes, pointing to an intricate fine-tuning of them and their target gene expression. [score:8]
MiR156 and MiR159 for example target SPL and MYB transcription factors, and their overexpression can cause late flowering and male sterility (Achard et al., 2004; Millar and Gubler, 2005; Schwab et al., 2005). [score:4]
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16
[+] score: 12
Other miRNAs from this paper: zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR171d, zma-MIR171f, zma-MIR394a, zma-MIR394b, zma-MIR396b, zma-MIR396a, zma-MIR399a, zma-MIR399c, zma-MIR399b, zma-MIR399d, zma-MIR399e, zma-MIR399f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR319a, zma-MIR319c, zma-MIR319b, zma-MIR319d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR393a, zma-MIR408a, zma-MIR156k, zma-MIR160f, zma-MIR396c, zma-MIR396d, zma-MIR2118a, zma-MIR2118b, zma-MIR2118c, zma-MIR2118d, zma-MIR2118e, zma-MIR2118f, zma-MIR2118g, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR390a, zma-MIR393b, zma-MIR393c, zma-MIR396e, zma-MIR396f, zma-MIR396g, zma-MIR396h, zma-MIR397a, zma-MIR397b, zma-MIR398a, zma-MIR398b, zma-MIR399g, zma-MIR399h, zma-MIR399i, zma-MIR399j, zma-MIR408b, zma-MIR528a, zma-MIR528b, zma-MIR827, zma-MIR390b, zma-MIR444a, zma-MIR444b
MiR159, miR160, miR164, miR319, miR390 and miR444 were expressed mainly in the embryo at 9 DAP and 15 DAP, showing their regulatory function in early embryo development (Figure 3c). [score:5]
It has been reported that miR159 was expressed higher in inferior spikelets than in superior spikelets in rice [11]. [score:3]
Allen R. S. Li J. Stahle M. I. Dubroue A. Gubler F. Millar A. A. Genetic analysis reveals functional redundancy and the major target genes of the Arabidopsis miR159 familyProc. [score:3]
Among them, miR166 was the most abundant family (17,602) followed by miR171 (11,988), miR827 (7686), miR167, miR396, miR528, miR156, miR408, miR160, miR390, miR159, miR444, miR319, miR398, miR168, miR394, miR164, miR393 and miR169 (Figure 3a). [score:1]
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[+] score: 11
MiR156 targeted SBP transcription factor [52, 53], which affected shoot maturation in Arabidopsis, miR159c/d and miR164 were predicted to target MYB domain transcription factors [24, 54], and miR160 targeted ARF transcription factors [55, 56]. [score:7]
The more abundant miRNAs in leaves were miR399a/c/d/e, miR408, miR159c/d, miR156k/j, miR160a/b/c/d/e and miR164a/b/c/d, while the expression of miR399e was nearly 10-fold higher than that in seeds (Additional file 2). [score:3]
The sequences of miR159 and miR319 are nearly identical and both can affect seed size. [score:1]
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[+] score: 9
Specificity of plant microRNA target MIMICs: Cross -targeting of miR159 and miR319. [score:5]
According to the previous studies, miR159 and miR319 probably from a homology family potentially regulate heterochronic development [47]. [score:3]
Moreover, Gong et al. also reported that miR159 and miR319 might influence sweet corn seed vigor [48]. [score:1]
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[+] score: 8
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-MIR164a, osa-MIR164b, osa-MIR166a, osa-MIR166b, osa-MIR166c, osa-MIR166d, osa-MIR166e, osa-MIR166f, osa-MIR169a, 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-MIR156k, osa-MIR156l, osa-MIR159a, osa-MIR159b, osa-MIR159c, osa-MIR159d, osa-MIR159e, osa-MIR159f, osa-MIR164c, osa-MIR164d, osa-MIR164e, osa-MIR166k, osa-MIR166l, 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-MIR166g, osa-MIR166h, osa-MIR166i, osa-MIR393b, osa-MIR166m, osa-MIR166j, osa-MIR164f, zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, osa-MIR444a, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR166k, zma-MIR166j, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR166l, zma-MIR166m, zma-MIR393a, zma-MIR156k, osa-MIR395m, osa-MIR395n, osa-MIR395o, osa-MIR395p, osa-MIR395q, osa-MIR395v, osa-MIR395w, osa-MIR395r, osa-MIR820a, osa-MIR820b, osa-MIR820c, osa-MIR1425, osa-MIR1428a, osa-MIR169r, osa-MIR444b, osa-MIR444c, osa-MIR444d, osa-MIR444e, osa-MIR444f, osa-MIR1428b, osa-MIR1428c, osa-MIR1428d, osa-MIR1428e, osa-MIR1874, osa-MIR2055, osa-MIR827, osa-MIR1428f, osa-MIR1428g, zma-MIR396d, osa-MIR396d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR393b, zma-MIR393c, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR827, osa-MIR395x, osa-MIR395y, zma-MIR444a, zma-MIR444b
2 sequences from Oryza coartacta and Oryza ridleyi were directly identified by BLASTN using osa-MIR159 stem-loop sequence from Nipponbare cultivar against the BAC ends sequences from 12 Oryza available from OMAP project species. [score:2]
2 with 2 mismatches in maize located 21 nucleotides upstream from the predicted maize miR159 (Figure 8A). [score:1]
1 in control leaves is probably due to cross-hybridisation of the probe with endogenous Nicotiana miR159 which is conserved in plants. [score:1]
The maize orthologue sequence to miR159-osa-miR159a. [score:1]
The structure of the putative maize pre-miR159-osa-miR159a. [score:1]
1 gene hairpin locus and can be distinguished from all other osa-miR159 genes by two or three nucleotide differences (not shown). [score:1]
Detection of a miR159 signal in mock transfected leaves is due to endogenous miR159 from Nicotiana benthamiana. [score:1]
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[+] score: 8
For example, honeysuckle-derived miR2911 inhibited influenza A viruses [24], oral administration of three mammalian miRNAs that were 2′-O-methylated like plant miRNAs reduced the intestinal tumor burden [26] and plant miR-159 inhibited breast cancer growth across kingdoms [25]. [score:5]
Chin et al. reported that long-term oral miR159 ingestion suppressed breast tumor growth [25], while Sizolwenkosi et al. reported that long-term oral administration of three mammalian miRNAs that were 2′-O-methylated like plant miRNAs reduced mouse intestinal tumor burden in vivo [26]. [score:3]
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[+] score: 8
Among the miRNA most expressed in plants inoculated with H. seropedicae, miR159 and miR168 were also identified as being regulated in soybean nodules [22], suggesting a role for these miRNAs in the association of diazotrophic bacteria with plants. [score:4]
MiR159 was up-regulated in Arabidopsis inoculated with Pseudomonas syringae [57], as well as in maize inoculated with beneficial bacteria. [score:3]
The most abundant family was miR159, followed by miR319, miR168 and miR156 (Table 2). [score:1]
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[+] score: 6
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-MIR164a, osa-MIR164b, osa-MIR166a, osa-MIR166b, osa-MIR166c, osa-MIR166d, osa-MIR166e, osa-MIR166f, osa-MIR167a, osa-MIR167b, osa-MIR167c, osa-MIR171a, 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-MIR156k, osa-MIR156l, osa-MIR159a, osa-MIR159b, osa-MIR159c, osa-MIR159d, osa-MIR159e, osa-MIR159f, osa-MIR160e, osa-MIR160f, 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-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-MIR408, osa-MIR172d, osa-MIR171i, osa-MIR167j, osa-MIR166m, osa-MIR166j, osa-MIR164f, zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, osa-MIR390, osa-MIR444a, zma-MIR171d, zma-MIR171f, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR168a, zma-MIR168b, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR408a, zma-MIR156k, zma-MIR160f, osa-MIR528, osa-MIR395m, osa-MIR395n, osa-MIR395o, osa-MIR395p, osa-MIR395q, osa-MIR395v, osa-MIR395w, osa-MIR395r, osa-MIR1432, osa-MIR827, 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-MIR2275a, osa-MIR2275b, zma-MIR2118a, zma-MIR2118b, zma-MIR2118c, zma-MIR2118d, zma-MIR2118e, zma-MIR2118f, zma-MIR2118g, zma-MIR2275a, zma-MIR2275b, zma-MIR2275c, zma-MIR2275d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR390a, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR408b, zma-MIR528a, zma-MIR528b, zma-MIR827, zma-MIR1432, zma-MIR390b, osa-MIR395x, osa-MIR395y, osa-MIR2275c, osa-MIR2275d, zma-MIR444a, osa-MIR6251
Similarly, expression levels of miR159 family, regulators of myeloblastosis (MYB) genes [41], and miR166 family, regulators of Homeodomain-Leucine zipper (HD- ZIP) transcription factor families [42], were also lower than control sample during de-etiolation process in maize, but higher than control sample in rice (Additional file 8). [score:5]
More interestingly, miRNA families that form clusters in maize, such as miR2118, miR395 and miR159, tend to form clusters in rice as well, indicating that those miRNA families already existed in the last common ancestor of maize and rice. [score:1]
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[+] score: 5
Other miRNAs from this paper: ath-MIR156a, ath-MIR156b, ath-MIR156c, ath-MIR156d, ath-MIR156e, ath-MIR156f, ath-MIR159a, ath-MIR160a, ath-MIR160b, ath-MIR160c, ath-MIR162a, ath-MIR162b, ath-MIR164a, ath-MIR164b, ath-MIR166a, ath-MIR166b, ath-MIR166c, ath-MIR166d, ath-MIR166e, ath-MIR166f, ath-MIR166g, ath-MIR167a, ath-MIR167b, ath-MIR169a, ath-MIR171a, ath-MIR172a, ath-MIR172b, ath-MIR159b, 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, ath-MIR167d, 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-MIR172c, ath-MIR172d, ath-MIR393a, ath-MIR393b, ath-MIR394a, ath-MIR394b, ath-MIR395a, ath-MIR395b, ath-MIR395c, ath-MIR395d, ath-MIR395e, ath-MIR395f, osa-MIR393a, osa-MIR394, 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, ath-MIR156g, ath-MIR156h, ath-MIR159c, ath-MIR164c, ath-MIR167c, ath-MIR172e, osa-MIR156k, osa-MIR156l, osa-MIR159a, osa-MIR159b, osa-MIR159c, osa-MIR159d, osa-MIR159e, osa-MIR159f, 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-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-MIR172d, osa-MIR171i, osa-MIR167j, osa-MIR166m, osa-MIR166j, osa-MIR164f, zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR162, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR171d, zma-MIR171f, zma-MIR394a, zma-MIR394b, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR393a, zma-MIR156k, zma-MIR160f, osa-MIR528, osa-MIR529a, osa-MIR395m, osa-MIR395n, osa-MIR395o, osa-MIR395p, osa-MIR395q, osa-MIR395v, osa-MIR395w, osa-MIR395r, ath-MIR827, osa-MIR529b, osa-MIR1432, osa-MIR169r, osa-MIR827, 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-MIR2275a, osa-MIR2275b, zma-MIR2118a, zma-MIR2118b, zma-MIR2118c, zma-MIR2118d, zma-MIR2118e, zma-MIR2118f, zma-MIR2118g, zma-MIR2275a, zma-MIR2275b, zma-MIR2275c, zma-MIR2275d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR393b, zma-MIR393c, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR482, zma-MIR528a, zma-MIR528b, zma-MIR529, zma-MIR827, zma-MIR1432, osa-MIR395x, osa-MIR395y, osa-MIR2275c, osa-MIR2275d, ath-MIR156i, ath-MIR156j
In Arobidopsis, MiRNA159 has been shown to be involved in the regulation of seed dormancy and germination by targeting MYB33 and MYB101, two positive regulators of ABA responses during germination. [score:4]
For example, miR156/157, miR159/319, miR166, miR169, and miR394 have been found in 51, 45, 41, 40 and 40 plant species, respectively [36- 38]. [score:1]
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[+] score: 5
Other miRNAs from this paper: zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR171d, zma-MIR171f, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR396b, zma-MIR396a, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR393a, zma-MIR156k, zma-MIR160f, zma-MIR396c, zma-MIR396d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR390a, zma-MIR393b, zma-MIR393c, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR396e, zma-MIR396f, zma-MIR396g, zma-MIR396h, zma-MIR528a, zma-MIR528b, zma-MIR827
In our study, different members of the miRNA159 family displayed diverse expression patterns. [score:3]
In wheat, miR159 takes part in cellular defense responses to rust fungus [55]. [score:1]
In addition, miR159, miR160, and miR171 are involved in resistance to pathogen invasion [55]– [58]. [score:1]
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[+] score: 4
Other miRNAs from this paper: zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171a, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, zma-MIR171d, zma-MIR171f, zma-MIR395b, zma-MIR395c, zma-MIR395a, zma-MIR396b, zma-MIR396a, zma-MIR399a, zma-MIR399c, zma-MIR399b, zma-MIR399d, zma-MIR399e, zma-MIR399f, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR319a, zma-MIR319c, zma-MIR319b, zma-MIR319d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR171c, zma-MIR171j, zma-MIR171e, zma-MIR171i, zma-MIR171g, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR171k, zma-MIR171h, zma-MIR408a, zma-MIR156k, zma-MIR160f, zma-MIR396c, zma-MIR396d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR171l, zma-MIR171m, zma-MIR171n, zma-MIR395d, zma-MIR395e, zma-MIR395f, zma-MIR395g, zma-MIR395h, zma-MIR395i, zma-MIR395j, zma-MIR395k, zma-MIR395l, zma-MIR395m, zma-MIR395n, zma-MIR395o, zma-MIR395p, zma-MIR396e, zma-MIR396f, zma-MIR396g, zma-MIR396h, zma-MIR399g, zma-MIR399h, zma-MIR399i, zma-MIR399j, zma-MIR408b, zma-MIR1432
Naqvi AR Haq QM Mukherjee SK 2010 MicroRNA profiling of tomato leaf curl new delhi virus (tolcndv) infected tomato leaves indicates that deregulation of mir159/319 and mir172 might be linked with leaf curl disease. [score:4]
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[+] score: 4
sgRNA1 was potentially targeted by 15 miRNAs: miR156i-3p, miR159a-3p, miR159b-3p, miR159c-3p, miR159d-3p, miR159f-3p, miR159h-3p, miR159i-3p, miR159j-3p, miR159k-3p, miR169c-3p, miR171b-3p, miR171n-3p, miR395a-5p, and miR399c-5p. [score:3]
Total 10 potential miRNAs for silencing sgRNA2 were predicted: miR156i-3p, miR159a-3p, miR159b-3p, miR159c-3p, miR159d-3p, miR159f-3p, miR159h-3p, miR159i-3p, miR159j-3p, and miR159k-3p. [score:1]
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[+] score: 3
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-MIR164a, osa-MIR164b, osa-MIR166a, osa-MIR166b, osa-MIR166c, osa-MIR166d, osa-MIR166e, osa-MIR166f, osa-MIR167a, osa-MIR167b, osa-MIR167c, osa-MIR169a, osa-MIR396a, osa-MIR396b, osa-MIR396c, osa-MIR397a, osa-MIR397b, osa-MIR398a, osa-MIR398b, osa-MIR156k, osa-MIR156l, osa-MIR159a, osa-MIR159b, osa-MIR159c, osa-MIR159d, osa-MIR159e, osa-MIR159f, osa-MIR160e, osa-MIR160f, 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-MIR172a, osa-MIR172b, osa-MIR172c, osa-MIR166g, osa-MIR166h, osa-MIR166i, osa-MIR172d, osa-MIR167j, osa-MIR166m, osa-MIR166j, osa-MIR164f, zma-MIR156d, zma-MIR156f, zma-MIR156g, zma-MIR156b, zma-MIR156c, zma-MIR156e, zma-MIR156a, zma-MIR156h, zma-MIR156i, zma-MIR160a, zma-MIR160c, zma-MIR160d, zma-MIR160b, zma-MIR164a, zma-MIR164d, zma-MIR164b, zma-MIR164c, zma-MIR169a, zma-MIR169b, zma-MIR167a, zma-MIR167b, zma-MIR167d, zma-MIR167c, zma-MIR160e, zma-MIR166a, zma-MIR166h, zma-MIR166e, zma-MIR166i, zma-MIR166f, zma-MIR166g, zma-MIR166b, zma-MIR166c, zma-MIR166d, zma-MIR171b, zma-MIR172a, zma-MIR172d, zma-MIR172b, zma-MIR172c, osa-MIR396e, zma-MIR396b, zma-MIR396a, zma-MIR156j, zma-MIR159a, zma-MIR159b, zma-MIR159d, zma-MIR166k, zma-MIR166j, zma-MIR167e, zma-MIR167f, zma-MIR167g, zma-MIR167h, zma-MIR167i, zma-MIR168a, zma-MIR168b, zma-MIR169c, zma-MIR169f, zma-MIR169g, zma-MIR169h, zma-MIR169i, zma-MIR169k, zma-MIR169j, zma-MIR169d, zma-MIR169e, zma-MIR172e, zma-MIR166l, zma-MIR166m, zma-MIR156k, zma-MIR160f, tae-MIR159a, tae-MIR159b, tae-MIR160, tae-MIR164, tae-MIR167a, tae-MIR1127a, osa-MIR169r, osa-MIR396f, zma-MIR396c, zma-MIR396d, osa-MIR2275a, osa-MIR2275b, zma-MIR2275a, zma-MIR2275b, zma-MIR2275c, zma-MIR2275d, osa-MIR396g, osa-MIR396h, osa-MIR396d, zma-MIR156l, zma-MIR159e, zma-MIR159f, zma-MIR159g, zma-MIR159h, zma-MIR159i, zma-MIR159j, zma-MIR159k, zma-MIR160g, zma-MIR164e, zma-MIR164f, zma-MIR164g, zma-MIR164h, zma-MIR166n, zma-MIR167j, zma-MIR169l, zma-MIR169m, zma-MIR169n, zma-MIR169o, zma-MIR169p, zma-MIR169q, zma-MIR169r, zma-MIR396e, zma-MIR396f, zma-MIR396g, zma-MIR396h, zma-MIR397a, zma-MIR397b, zma-MIR398a, zma-MIR398b, hvu-MIR156a, tae-MIR156, hvu-MIR159b, hvu-MIR159a, hvu-MIR166a, tae-MIR167b, hvu-MIR168, hvu-MIR169, tae-MIR169, hvu-MIR397a, tae-MIR398, tae-MIR171b, hvu-MIR166b, hvu-MIR166c, osa-MIR2275c, osa-MIR2275d, tae-MIR1122b, tae-MIR9653a, tae-MIR9654a, tae-MIR9656, tae-MIR9657a, tae-MIR9659, tae-MIR9660, tae-MIR1127b, tae-MIR9661, tae-MIR396, tae-MIR9665, tae-MIR2275, tae-MIR9667, tae-MIR167c, tae-MIR1120b, tae-MIR397, tae-MIR1130b, tae-MIR5384, tae-MIR9675, tae-MIR1120c, tae-MIR9679, tae-MIR9657b, hvu-MIR397b, hvu-MIR156b, tae-MIR9653b
Of the 15 known miRNA families, 8 (miR396, miR168, miR156, miR172, miR159, miR398, miR1318 and miR167) showed different levels of preferential expression in wheat flag leaves, with the logarithm of the fold changes ranged from 0.5 to 5.2 as well as more than those in the developing seeds (Figure  3a, Table  2). [score:3]
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[+] score: 3
Sequence and expression differences underlie functional specialization of Arabidopsis microRNAs miR159 and miR319. [score:3]
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[+] score: 3
The MicroRNA159-Regulated GAMYB-like genes inhibit growth and promote programmed Cell Death in Arabidopsis. [score:3]
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[+] score: 2
The abundance of extremely conserved miRNAs has been determined, such as miR156, miR159, miR164, miR166, miR167, miR168, and miR398, which was very similar to previous reports (Zhao et al., 2013). [score:1]
ABA induction of miR159 controls transcript levels of two MYB factors during Arabidopsis seed germination. [score:1]
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[+] score: 1
Following the first report of cross-kingdom miRNA transfer in 2012 [8], analysis of sequencing data in human plasma expanded the list of sources of exogenous miRNAs detected in human plasma to include plant, bacteria, and fungi [13, 14], and more plant miRNAs (miR159 and miR2911) were reported to be identified in human serum [15, 16]. [score:1]
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