Sol Genomics Network

>Solyc08g081540.2 SL2.50ch08:64567933..64570466
TCATTCAACAAATTACTAAATACACAAATAACATTCAAAGCCTCTTAAAGAGCTTCTTTTTTTTTAACAAGAATTAGCAAATACCCATTTCATTTTTTTTGAGAATCTTTGATTCTTTCTCTTTTTGAAAATTAAGATGGTGTCTATTTCAAAGAATAACCAAAAACAACAACTTCTTTCAAAGATAGCCACAAATGATGGTCATGGGGAAAATTCACCTTATTTTGATGGTTGGAAGGCTTATGCAAATAACCCTTTTCATCTAACTGATAATCCTACTGGTGTTATTCAGATGGGTCTTGCTGAAAATCAGGTAGGAGAAGAAAAAAATCACTTATCGTTTTAATTTGTTTGTTTTGCTTTACAGTATTTTAAAAAAAAGAACGATTAATTTTTTTTTTGATAACTTTTTAGAAACAACCGACATATTTAAGATCACAAGATTTAAAAGATATTTTGATTCATTTTAACATAATTTGAATGTAACACTATGATATTTTAAAGTCTTATTTATTGACCCGACAAACAAATTGAATAGCAGAAAAGAGTATATTTTCTTGATGAAATGGCTAAAATTGAAATTTTTTAAGAGTTTTTGTTAATGAATTTCTTATTTTTTATTTTTTTTATTGCAGCTTTGTTTTGATTTAATCCAAGAATGGATGGTGAATAATCCAAAAGCATCAATTTGCACTGTTGAAGGAGCTGAAAATTTCCAAGATATTGCAATTTTTCAAGATTATCATGGCTTGCCAGAGTTTAGACAAGTATGAAACTTTTCTAATCAAGATTATTAGTTGTTAATTCTTGTTTTTGTTAAGTGTTCTAATTAGTTTAATAAAAATAATTTTCAGGCAGTTGCAAGGTTTATGGAGAAAGTGAGAGGTGACAGAGTGACATTTGATCCAAACAGAATAGTAATGAGTGGAGGAGCAACTGGTGCTCATGAAATGCTTGCTTTTTGCTTGGCTGATCCTGGTGATGCCTTTTTGGTCCCAACACCATATTATCCAGGGTAAGAATTATATTCGTAATCGAGATTCATTGACTTAGATTAATTACGATTCATGTCACATAAAGTTTGTTAAAGTCCCTTTTCAATTAAAATCATCAAAACAACTTGGATATACAAATCACTATCATAAGTGTCTTCCTTTGACCTCTATAATTTTGACTAATTTTTTTGTTGTACTTGGACCCTAGTAAAATTATTGGTGTGGGACATAAAATCAACTACTCCTCTGCTTAAAACAGAGAGAGTAGGTCCTCTAATTAGTTAACATACTTAATATAATTGTTCCCATAAAGTCAATGCATAATTAAAGTAAAGTTTTTTGTATTTGTAATATTGCAGATTTGATAGAGATTTGAGATGGAGAACTGGTGTTCAACTATTTCCAGTTGTTTGTGAAAGTTGTAATGATTTCAAAGTGACTACAAAAGCCTTAGAAGAAGCATATGAAAAAGCTCAACAATCCAACATCAAAATAAAAGGCTTACTTATAAACAATCCTTCAAATCCATTAGGTACTCTTCTTGACAAGGACACGCTACGAGACATTGTAACGTTCATCAACTCGAAAAACATCCATTTAGTATGCGATGAAATCTATGCTGCTACGGTGTTTGATCAGCCTAGATTTATCAGTGTATCCGAAATGGTTGAGGAGATGATTGAATGCAACACAGATTTGATCCATATAGTCTATAGCTTGTCTAAAGACTTAGGATTTCCAGGATTCAGAGTTGGAATTGTTTACTCGTACAACGATACAGTTGTAAACATTTCTAGAAAGATGTCAAGTTTCGGGCTAGTTTCAACTCAGACACAACATATGCTAGCATCAATGTTGTCTGATGAGATATTTGTTGAGAAATTCATTGCTGAGAGTTCCGAAAGGCTCGGGAAAAGGCAGGGGATGTTCACAAAAGGACTAGCACAAGTTGGAATTAGTACATTGAAAAGCAATGCTGGTTTGTTTTTCTGGATGGATTTAAGGAGACTGCTTAAAGAAGCAACATTTGATGGTGAGTTAGAATTATGGAGAATTATTATTAATGAAGTAAAACTTAATGTTTCACCAGGATGTTCATTTCATTGTTCTGAACCTGGTTGGTTTAGAGTTTGTTTTGCAAATATGGACGACGAAACGATGAGAATTGCATTAAGAAGGATAAGGAACTTTGTGCTTCAAACAAAGGGACTTAACAACATTGCTGCTATTAAGAAACAATGCAGTAGGAGTAAACTTCAGATCAGCTTATCGTTTCGAAGATTGGATGATTTTAACTCACCAGCTCACTCTCCGATGAATTCGCCTTTGGTTAGGACATAAAGATGAAGAAAAGAATGGCTTAGATTTGTTGTTGTTGTTTGTATAATAAGAGAAGGAAAAAATTTCCTCTGTTATAGTGAAGAGTGATAGTTTTGATGTATACATTTAGTGTTTGATTATACAATTCATTCCATTTTGGATTTTTATCATATGAATTTTTCTATGTAACATTGTATCAAAATGGGATTCAATGTGGAA

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mRNA Solyc08g081540.2.1

Ontology terms

terms associated with this mRNA

GO:0016847 – 1-aminocyclopropane-1-carboxylate synthase activity

cDNA sequence

spliced cDNA sequence, including UTRs

>Solyc08g081540.2.1 1-aminocyclopropane-1-carboxylate synthase (AHRD V1 **** Q96580_SOLLC); contains Interpro domain(s) IPR004839 Aminotransferase, class I and II IPR004838 Aminotransferases, class-I, pyridoxal-phosphate-binding site
TCATTCAACAAATTACTAAATACACAAATAACATTCAAAGCCTCTTAAAGAGCTTCTTTTTTTTTAACAAGAATTAGCAAATACCCATTTCATTTTTTTTGAGAATCTTTGATTCTTTCTCTTTTTGAAAATTAAGATGGTGTCTATTTCAAAGAATAACCAAAAACAACAACTTCTTTCAAAGATAGCCACAAATGATGGTCATGGGGAAAATTCACCTTATTTTGATGGTTGGAAGGCTTATGCAAATAACCCTTTTCATCTAACTGATAATCCTACTGGTGTTATTCAGATGGGTCTTGCTGAAAATCAGCTTTGTTTTGATTTAATCCAAGAATGGATGGTGAATAATCCAAAAGCATCAATTTGCACTGTTGAAGGAGCTGAAAATTTCCAAGATATTGCAATTTTTCAAGATTATCATGGCTTGCCAGAGTTTAGACAAGCAGTTGCAAGGTTTATGGAGAAAGTGAGAGGTGACAGAGTGACATTTGATCCAAACAGAATAGTAATGAGTGGAGGAGCAACTGGTGCTCATGAAATGCTTGCTTTTTGCTTGGCTGATCCTGGTGATGCCTTTTTGGTCCCAACACCATATTATCCAGGATTTGATAGAGATTTGAGATGGAGAACTGGTGTTCAACTATTTCCAGTTGTTTGTGAAAGTTGTAATGATTTCAAAGTGACTACAAAAGCCTTAGAAGAAGCATATGAAAAAGCTCAACAATCCAACATCAAAATAAAAGGCTTACTTATAAACAATCCTTCAAATCCATTAGGTACTCTTCTTGACAAGGACACGCTACGAGACATTGTAACGTTCATCAACTCGAAAAACATCCATTTAGTATGCGATGAAATCTATGCTGCTACGGTGTTTGATCAGCCTAGATTTATCAGTGTATCCGAAATGGTTGAGGAGATGATTGAATGCAACACAGATTTGATCCATATAGTCTATAGCTTGTCTAAAGACTTAGGATTTCCAGGATTCAGAGTTGGAATTGTTTACTCGTACAACGATACAGTTGTAAACATTTCTAGAAAGATGTCAAGTTTCGGGCTAGTTTCAACTCAGACACAACATATGCTAGCATCAATGTTGTCTGATGAGATATTTGTTGAGAAATTCATTGCTGAGAGTTCCGAAAGGCTCGGGAAAAGGCAGGGGATGTTCACAAAAGGACTAGCACAAGTTGGAATTAGTACATTGAAAAGCAATGCTGGTTTGTTTTTCTGGATGGATTTAAGGAGACTGCTTAAAGAAGCAACATTTGATGGTGAGTTAGAATTATGGAGAATTATTATTAATGAAGTAAAACTTAATGTTTCACCAGGATGTTCATTTCATTGTTCTGAACCTGGTTGGTTTAGAGTTTGTTTTGCAAATATGGACGACGAAACGATGAGAATTGCATTAAGAAGGATAAGGAACTTTGTGCTTCAAACAAAGGGACTTAACAACATTGCTGCTATTAAGAAACAATGCAGTAGGAGTAAACTTCAGATCAGCTTATCGTTTCGAAGATTGGATGATTTTAACTCACCAGCTCACTCTCCGATGAATTCGCCTTTGGTTAGGACATAAAGATGAAGAAAAGAATGGCTTAGATTTGTTGTTGTTGTTTGTATAATAAGAGAAGGAAAAAATTTCCTCTGTTATAGTGAAGAGTGATAGTTTTGATGTATACATTTAGTGTTTGATTATACAATTCATTCCATTTTGGATTTTTATCATATGAATTTTTCTATGTAACATTGTATCAAAATGGGATTCAATGTGGAA

Download sequence (1.8Kb)

Protein sequence

translated polypeptide sequence

Gene model matches

SGN Unigenes

[Associate new unigene]

GenBank accessions

[Associate new genbank sequence]

Other genome matches

None

Literature annotations [2]

[Associate publication] [Matching publications]

Differential induction of seven 1-aminocyclopropane-1-carboxylate synthase genes by elicitor in suspension cultures of tomato (Lycopersicon esculentum). Plant molecular biology (1997)
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The key enzyme of ethylene biosynthesis, ACC synthase, is encoded by a multigene family. We describe three new DNA sequences encoding members of the ACC synthase family of the tomato. One of these sequences encodes a novel ACC synthase, LE-ACS6, which is phylogenetically related to the ACC synthases LE-ACS1A and LE-ACS1B. Gene-specific probes for seven tomato ACC synthase genes were prepared. They were used for RNase protection assays to study the accumulation of ACC synthase transcripts in suspension-cultured tomato cells after the addition of an elicitor. The ACC synthase genes LE-ACS2, LE-ACS5 and LE-ACS6 were strongly induced by the elicitor. In contrast, the genes LE-ACS1B, LE-ACS3 and LE-ACS4 were constitutively expressed and LE-ACS1B was present at all times at a particularly high level. Thus, there are two groups of ACC synthase transcripts expressed in these cells, either elicitor-induced or constitutive. A transcript of LE-ACS1A was not detected. Despite the presence of LE-ACS1B, LE-ACS2, LE-ACS3, LE-ACS4 and LE-ACS5, there was only little ethylene produced in the absence of the elicitor. Increased ethylene production is usually correlated with the accumulation of ACC synthase transcripts, indicating that ethylene production is controlled via the transcriptional activation of ACC synthase genes. However, the abundance of several ACC synthase mRNAs studied was not strictly correlated with the rate of elicitor-induced ethylene production. Our data provide evidence that the activity of these ACC synthases may not solely be controlled by the transcriptional activation of ACC synthase genes.

Oetiker, JH. Olson, DC. Shiu, OY. Yang, SF. Plant molecular biology. 1997. 34(2). 275-86.

Transcriptional regulation of the ethylene response factor LeERF2 in the expression of ethylene biosynthesis genes controls ethylene production in tomato and tobacco. Plant physiology (2009)
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Fine-tuning of ethylene production plays an important role in developmental processes and in plant responses to stress, but very little is known about the regulation of ethylene response factor (ERF) proteins in ethylene biosynthesis genes and ethylene production. Identifying cis-acting elements and transcription factors that play a role in this process, therefore, is important. Previously, a tomato (Solanum lycopersicum [f. sp. Lycopersicon esculentum]) ERF protein, LeERF2, an allele of TERF2, was reported to confer ethylene triple response on plants. This paper reports the transcriptional modulation of LeERF2/TERF2 in ethylene biosynthesis in tomato and tobacco (Nicotiana tabacum). Using overexpressing and antisense LeERF2/TERF2 transgenic tomato, we found that LeERF2/TERF2 is an important regulator in the expression of ethylene biosynthesis genes and the production of ethylene. Expression analysis revealed that LeERF2/TERF2 is ethylene inducible, and ethylene production stimulated by ethylene was suppressed in antisense LeERF2/TERF2 transgenic tomato, indicating LeERF2/TERF2 to be a positive regulator in the feedback loop of ethylene induction. Further research showed that LeERF2/TERF2 conservatively modulates ethylene biosynthesis in tobacco and that such regulation in tobacco is associated with the elongation of the hypocotyl and insensitivity to abscisic acid and glucose during germination and seedling development. The effects on ethylene synthesis were similar to those of another ERF protein, TERF1, because TERF1 and LeERF2/TERF2 have overlapping roles in the transcriptional regulation of ethylene biosynthesis in tobacco. Biochemical analysis showed that LeERF2/TERF2 interacted with GCC box in the promoter of NtACS3 and with dehydration-responsive element in the promoter of LeACO3, resulting in transcriptional activation of the genes for ethylene biosynthesis in tomato and tobacco, which is a novel regulatory function of ERF proteins in plant ethylene biosynthesis.

Zhang, Z. Zhang, H. Quan, R. Wang, XC. Huang, R. Plant physiology. 2009. 150(1). 365-77.

Ontology annotations (10)

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Genomic details

Solyc08g081540.2 gene feature details

%2Flocus%2F7%2Fview%2F locus 7

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Accessions	Seedlots
Accessions		Breeding Program	Seedlot Name	Contents	Seedlot Location	Count	Weight(g)

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