ACGT-containing element gene transcriptions

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Associate Editor(s)-in-Chief: Henry A. Hoff

The "binding affinities of both bZIP proteins were similar to CREA/T (ATGACGTCAT), a CRE sequence with flanking adenine and thymine (A/T) at positions -4 and +4. [The] bZIP domains of both STF1 and HY5 have similar binding properties for recognizing ACGT-containing elements (ACEs). [Although] the G-box is a known target site for the HY5 protein, the C-box sequences are the preferred binding sites for both STF1 and HY5."[1]

"The combination of an [ACGT-containing element] ACE and a MRE confers light responsiveness to the CFI, F3H and FLS promoters."[2]

"Upstream from the transcriptional start site, several motifs were found [...]. A typical TATA box is located at -43. The CAAT consensus sequence cannot be found between -80 and -120; however, two sequence motifs (GCGCCC, GGGCAG), which are homologous to the consensus sequences for the Spl-binding site, GGGCGG (GC box) [19] were found around -114 and -570. The GC box has been found in promoters of many viral and cellular genes [20], and acts as a binding site of a protein, Spl, which is necessary for transcriptional activity. A pyrimidine box (CCTTT) and Box I (GCAGTG) which are part of the GA response complex [21] were found at -208 and -256. Two 8 bp sequences (CACGTCGC, CACGTAAC) which are similar to an ABA response element (ABRE, CACGTGGC) [22] were located at -308, -648 relative to the + 1 site. The core sequence of the ABA response element (ACGT) is the binding site for basic leucine zipper transcriptional factors or common plant regulatory factors (CPRFs) [23]."[3]

ABA-response elements

Main article: ABA-response element gene transcriptions

"The ABA responsive element (ABRE) is a key cis‐regulatory element in ABA signalling. However, its consensus sequence (ACGTG(G/T)C) is present in the promoters of only about 40% of ABA‐induced genes in rice aleurone cells, suggesting other ABREs may exist."[4]

"Many ABA‐inducible genes in various species contain a conserved cis‐regulatory ABA responsive element (ABRE) with the consensus sequence ACGTG(G/T)C (Hattori et al. 2002; Shen et al. 2004)."[4]

A boxes

Main article: A box gene transcriptions

Most bZIP proteins show high binding affinity for the ACGT motifs, which include [...] TACGTA (A box) [...].[5][6][7]

Carbohydrate response elements

Main article: Carbohydrate response element gene transcriptions

"The putative ChREBP binding sites ChoRE1 (CACGTGACCGGATCTTG, -324 to -308) and ChoRE2 (TCCGCCCCCATCACGTG, -298 to - 282) were mutated into CACGTGACGGATCTTG and TCCGCCCCATCACGTG respectively, where the 5-nt spacer between the two E-boxes in ChoRE motifs were shortened to 4-nt (underlined) as previously studies showed (10,35)."[8]

The E-boxes in ChoRE1 and ChoRE2 are CACGTG and ATCTTG and TCCGCC and CACGTG.[8]

C boxes

Main article: C box gene transcriptions

Most bZIP proteins show high binding affinity for the ACGT motifs, which include [...] GACGTC (C box) [...].[5][6][7]

C-boxes

Main article: C box gene transcriptions

Analysis "of the recombinant (soybean [Glycine max] TGACG-motif binding factor 1) STF1 protein revealed the C-box (nGACGTCn) to be a high-affinity binding site (Cheong et al., 1998). [...] To test whether STF1 and HY5 have similar DNA-binding properties, the binding properties of each were compared with eight different DNA sequences that represent G-, C-, and C/G-box motifs [TGACGTGT]. C-box sequences carrying the mammalian cAMP responsive element (CRE; TGACGTCA) motif and the Hex sequence (TGACGTGGC), a hybrid C/G-box (Cheong et al., 1998), were high-affinity binding sites for both proteins [...]."[9]

Copying the C-box consensus sequence 5'-nGACGTCn-3' (Cheong et al., 1998) and putting the sequence in "⌘F" finds one location between ZNF497 and A1BG or no locations between ZSCAN22 and A1BG as can be found by the computer programs.

CRE boxes

Main article: CRE box gene transcriptions

"Within the cAMP-responsive element of the somatostatin gene, we observed an 8-base palindrome, 5'-TGACGTCA-3', which is highly conserved in many other genes whose expression is regulated by cAMP."[10]

The upstream activating sequence (UAS) for the Aca1p, the basic "leucine zipper (bZIP) transcription factor [55] involved in carbon source utilization" is 5'-TGACGTCA-3'[11] the same as a CRE.

The upstream activating sequence (UAS) for the Sko1p, involved "in osmotic and oxidative stress responses" is 5'-TGACGTCA-3'[11] the same as a CRE.

Hypoxia response elements

Main article: ABA-response element gene transcriptions

"The hypoxia response element (HRE) and estrogen response element (ERE) were located on −154 to −150 "ACGTG", and −94 to −80 "AGGTTATTGCCTCCT" on the transcript, respectively."[12]

ORE1 binding sites

Main article: ORE1 binding site gene transcriptions

"As a transcription factor, ORE1 was reported to bind to consensus DNA sequences of [ACG][CA]GT[AG]N{5,6}[CT]AC[AG] [29] or T[TAG][GA]CGT[GA][TCA][TAG] [37]."[13]

Consensus sequences are 5'-(A/C/G)(A/C)GT(A/G)N5,6(C/T)AC(A/G)-3' or 5'-T(A/G/T)(A/G)CGT(A/G)(A/C/T)(A/G/T)-3'.[13]

Copying 5'-TTACGTG-3' in "⌘F" yields none between ZSCAN22 and A1BG and none between ZNF497 and A1BG as can be found by the computer programs.

Phosphate starvation-response transcription factors

Main article: Phosphate starvation-response transcription factor gene transcriptions

Abscisic acid-responsive elements (CACGTG).[14]

"The [palindromic E-box motif (CACGTG)] motif is bound by the transcription factor Pho4, [and has the] class of basic helix-loop-helix DNA binding domain and core recognition sequence (Zhou and O'Shea 2011)."[15]

The upstream activating sequence (UAS) for Pho4p is 5'-CAC(A/G)T(T/G)-3' in the promoters of HIS4 and PHO5 regarding phosphate limitation with respect to regulation of the purine and histidine biosynthesis pathways [66].[11]

Consensus sequences

"The ABRE contains the core sequence, ACGT, also known as the G‐box (Marcotte et al. 1989; Yamaguchi‐Shinozaki et al. 1990)."[4]

5'-ACGT-3'.[3]

The consensus sequence for the ACGT-containing elements (ACEs) is 5'-CACGT-3'.[2]

Hypotheses

  1. A1BG has no ACEs in either promoter.

Samplings

  1. ACGT elements, negative strand, negative direction: 24 between 150 and 4338 nts.
  2. ACGT elements, negative strand, positive direction: 2, 3'-ACGT-5' at 569, 3'-ACGT-5' at 3254.
  3. ACGT elements, positive strand, negative direction: 4, 3'-ACGT-5' at 342, 3'-ACGT-5' at 531, 3'-ACGT-5' at 1772, 3'-ACGT-5' at 4236.
  4. ACGT elements, positive strand, positive direction: 44 between 192 and 4341 nts.

ACGT-containing elements include these metal responsive elements:

  1. complement, negative strand, negative direction: 6 between 1348 and 4341 nts.
  2. complement, positive strand, negative direction: 6 between 549 and 3323 nts.
  3. inverse, negative strand, negative direction: 2, 3'-CTCACGT-5' at 1470, 3'-CACACGT-5' at 2863.
  4. inverse, positive strand, negative direction: 2, 3'-CACACGT-5' at 531, 3'-CTCACGT-5' at 1772.
  5. inverse, positive strand, positive direction: 6 between 546 and 3883 nts.

ACGT-containing elements include these cAMP response elements (CRE):

  1. negative strand in the negative direction (from ZSCAN22 to A1BG): 1, 3'-TGACGTCA-5' at 4317.

Acknowledgements

The content on this page was first contributed by: Henry A. Hoff.

See also

References

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External links

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