Co-expression analysis

Gene ID At3g54990
Gene name SMZ (SCHLAFMUTZE)
Module size 5 genes
NF 0.11
%ile 7.8



Co-expression network

pink confeito: Transcription factor, green bicone: Binding protein, red cone: Enzyme protein, blue sphere: Other protein
large node: VF over 0.50, middle node: over 0.25, small node: below 0.25



Co-expressed genes

Click gene/probe ID to show a list of genes that are co-expressed with the gene.

VF %ile CC Gene ID Repr. ID Gene name Func. O.I. H.G. S.X. Other DB
0.124.91.00At3g54990824664SMZ (SCHLAFMUTZE)Encodes a AP2 domain transcription factor that can repress flowering. SMZ and its paralogous gene, SNARCHZAPFEN (SNZ), share a signature with partial complementarity to the miR172 microRNA, whose precursor is induced upon flowering.O.I.H.G.S.X.
0.3338.10.71At5g52250835301transducin family protein / WD-40 repeat family proteinEncodes a transducin protein whose gene expression is induced by UV-B. This induction is reduced in hy5 mutant and may be a target of HY5 during UV-B response.O.I.H.G.S.X.
0.2930.30.73At3g48350823993cysteine proteinase, putativeF:cysteine-type endopeptidase activity, cysteine-type peptidase activity;P:proteolysis;C:endomembrane system;MOPVBAFO.I.H.G.S.X.
0.082.30.69At3g10910820261zinc finger (C3HC4-type RING finger) family proteinF:protein binding, zinc ion binding;P:unknown;C:unknown;PMOFVBO.I.H.G.S.X.
0.061.40.69At5g37790833757protein kinase family proteinF:protein serine/threonine kinase activity, protein kinase activity, kinase activity, ATP binding;P:protein amino acid phosphorylation;C:cellular_component unknown;MPOBFVAO.I.H.G.S.X.

Click More genes

Link to AtGenExpress Visualization Tool



Specific experiments for the module

Std2 GX %ile GSM ID Assay name GSE ID Experiment title Link to GEO
136.199.9GSM253646Low_Mo_seg_pool_Ler_col_F2GSE10039Low_Mo_Arabidopsis_mapping_MOT1Link to GEO
131.199.9GSM253648Col-0-1GSE10039Low_Mo_Arabidopsis_mapping_MOT1Link to GEO
127.699.9GSM205435Col_ leaf_ wildtype_rep02GSE8279Transgenerational Stability of the Arabidopsis Epigenome Is Coordinated by CG MethylationLink to GEO
110.699.9GSM253645High_Mo_seg_pool_Ler_col_F2GSE10039Low_Mo_Arabidopsis_mapping_MOT1Link to GEO
107.599.9GSM253649Col-0-2GSE10039Low_Mo_Arabidopsis_mapping_MOT1Link to GEO
101.599.9GSM253647Col-0 3GSE10039Low_Mo_Arabidopsis_mapping_MOT1Link to GEO
88.799.9GSM253652Ler 2GSE10039Low_Mo_Arabidopsis_mapping_MOT1Link to GEO
85.899.9GSM253651Ler 1GSE10039Low_Mo_Arabidopsis_mapping_MOT1Link to GEO
81.099.9GSM205430met1-3_leaf_fourth-selfed generation_rep02GSE8279Transgenerational Stability of the Arabidopsis Epigenome Is Coordinated by CG MethylationLink to GEO
79.399.9GSM143308Tsu_genomic_hyb_3GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
78.699.9GSM143299High_Na_seg_pool_ts_col_F2GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
76.899.9GSM143298Low_Na_seg_pool_ts_col_F2GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
76.299.9GSM205364met1-3_leaf_second-selfed generation_rep01GSE8279Transgenerational Stability of the Arabidopsis Epigenome Is Coordinated by CG MethylationLink to GEO
74.099.9GSM143307Low_Na_seg_pool_tsu_col_F2GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
71.599.9GSM143301Ts_genomic_hyb_2GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
70.799.9GSM205432Col_ leaf_ wildtype_rep01GSE8279Transgenerational Stability of the Arabidopsis Epigenome Is Coordinated by CG MethylationLink to GEO
70.499.9GSM253650Ler 3GSE10039Low_Mo_Arabidopsis_mapping_MOT1Link to GEO
69.899.9GSM143302Ts_genomic_hyb_1GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
65.399.8GSM143306High_Na_seg_pool_tsu_col_F2GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
59.299.8GSM143309Tsu_genomic_hyb_2GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
58.999.8GSM133775Lindsey_1-27_torpedo-meristem_Rep3_ATH1GSE5730Transcriptional profiling of laser-capture micro-dissected embryonic tissuesLink to GEO
58.099.8GSM143300Ts_genomic_hyb_3GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
53.499.8GSM205426met1-3_leaf_second-selfed generation_rep02GSE8279Transgenerational Stability of the Arabidopsis Epigenome Is Coordinated by CG MethylationLink to GEO
47.799.8GSM143310Tsu_genomic_hyb_1GSE6203Rus_etal_High_Na_Arabidopsis_accessions_mapping_HKT1Link to GEO
47.399.8GSM184537Whole roots 2hr KCl control treated then frozen, biological rep1GSE7631Cell-specific nitrogen responses in the Arabidopsis rootLink to GEO
39.499.8GSM205428met1-3_leaf_fourth-selfed generation_rep01GSE8279Transgenerational Stability of the Arabidopsis Epigenome Is Coordinated by CG MethylationLink to GEO
31.599.7GSM184551Whole roots 2hr KCl control treated then incubated in protoplast-generating solution minus enzymes, biological rep1GSE7631Cell-specific nitrogen responses in the Arabidopsis rootLink to GEO
30.799.7GSM131303AtGen_6-2611_Osmoticstress-Shoots-24.0h_Rep1GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
22.799.6GSM131300AtGen_6-2512_Osmoticstress-Shoots-12.0h_Rep2GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
22.599.6GSM131299AtGen_6-2511_Osmoticstress-Shoots-12.0h_Rep1GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
21.499.6GSM131304AtGen_6-2612_Osmoticstress-Shoots-24.0h_Rep2GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
16.999.5GSM131305AtGen_6-2621_Osmoticstress-Roots-24.0h_Rep1GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
16.299.5GSM268249dor-drought-2, biological rep 2GSE10643Transcription profiling of Arabidopsis dor mutant and wild-type plants in response to drought stress.Link to GEO
13.899.4GSM131326AtGen_6-3522_Saltstress-Roots-12.0h_Rep2GSE5623AtGenExpress: Stress Treatments (Salt stress)Link to GEO
13.899.4GSM133762Lindsey_1-14_torpedo-root_Rep1_ATH1GSE5730Transcriptional profiling of laser-capture micro-dissected embryonic tissuesLink to GEO
13.299.4GSM311283Laser capture microdissected (LCM) general seed coat at the pre-globular stage, biological replicate 1GSE12402Expression data from Arabidopsis seed compartments at the pre-globular stageLink to GEO
11.899.3GSM269823T6 leaf-drought-rep2GSE10670Global expression profiling of wild type and transgenic Arabidopsis plants in response to water stressLink to GEO
11.199.2GSM131296AtGen_6-2412_Osmoticstress-Shoots-6.0h_Rep2GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
11.099.2GSM268245dor-drought-1, biological rep 1GSE10643Transcription profiling of Arabidopsis dor mutant and wild-type plants in response to drought stress.Link to GEO
10.999.2GSM131306AtGen_6-2622_Osmoticstress-Roots-24.0h_Rep2GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
10.899.2GSM131302AtGen_6-2522_Osmoticstress-Roots-12.0h_Rep2GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
10.799.2GSM269813WT leaf-drought-rep1GSE10670Global expression profiling of wild type and transgenic Arabidopsis plants in response to water stressLink to GEO
10.699.2GSM131293AtGen_6-2321_Osmoticstress-Roots-3.0h_Rep1GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
10.499.2GSM133761Lindsey_1-13_torpedo-cotyledon_Rep1_ATH1GSE5730Transcriptional profiling of laser-capture micro-dissected embryonic tissuesLink to GEO
10.099.2E-MEXP-475-raw-cel-680982521
10.099.2GSM131301AtGen_6-2521_Osmoticstress-Roots-12.0h_Rep1GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
9.999.1GSM133758Lindsey_1-11_heart-stage-root_Rep2_ATH1GSE5730Transcriptional profiling of laser-capture micro-dissected embryonic tissuesLink to GEO
9.799.1GSM142786HO001_ATH1_A3-Okamo-WS-ABAGSE6171Comparative transcriptome analysis between wild-type and gpa1 mutant in response to ABALink to GEO
9.799.1E-ATMX-30-raw-cel-1513696906
9.699.1GSM131297AtGen_6-2421_Osmoticstress-Roots-6.0h_Rep1GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
9.299.1E-MEXP-475-raw-cel-680982449
9.099.1GSM269825T8 leaf-drought-rep2GSE10670Global expression profiling of wild type and transgenic Arabidopsis plants in response to water stressLink to GEO
8.899.0GSM131298AtGen_6-2422_Osmoticstress-Roots-6.0h_Rep2GSE5622AtGenExpress: Stress Treatments (Osmotic stress)Link to GEO
8.699.0GSM133962Fukuda_1-7_6A_Rep1_ATH1GSE5748In vitro tracheary element transdifferentiation of Col-0 suspension cells.Link to GEO

Biological processes inferred to relate to the module

SFGenesGO IDProcess NameLink to AmiGO
0.0491GO:0010224A change in state or activity of a cell or an organism (in terms of movement, secretion, enzyme production, gene expression, etc.) as a result of a UV-B radiation stimulus. UV-B radiation (UV-B light) spans the wavelengths 290 to 320 nm.Link to AmiGO
0.0441GO:0010218A change in state or activity of a cell or an organism (in terms of movement, secretion, enzyme production, gene expression, etc.) as a result of far red light stimulus. Far red light is electromagnetic radiation of wavelength 700-800nm. An example of this response is seen at the beginning of many plant species developmental stages. These include germination, and the point when cotyledon expansion is triggered. In certain species these processes take place in response to absorption of red light by the pigment molecule phytochrome, but the signal can be reversed by exposure to far red light. During the initial phase the phytochrome molecule is only present in the red light absorbing form, but on absorption of red light it changes to a far red light absorbing form, triggering progress through development. An immediate short period of exposure to far red light entirely returns the pigment to its initial state and prevents triggering of the developmental process. A thirty minute break between red and subsequent far red light exposure renders the red light effect irreversible, and development then occurs regardless of whether far red light exposure subsequently occurs.Link to AmiGO
0.0381GO:0010114A change in state or activity of a cell or an organism (in terms of movement, secretion, enzyme production, gene expression, etc.) as a result of a red light stimulus. Red light is electromagnetic radiation of wavelength of 580-700nm. An example of this response is seen at the beginning of many plant species developmental stages. These include germination, and the point when cotyledon expansion is triggered. In certain species these processes take place in response to absorption of red light by the pigment molecule phytochrome, but the signal can be reversed by exposure to far red light. During the initial phase the phytochrome molecule is only present in the red light absorbing form, but on absorption of red light it changes to a far red light absorbing form, triggering progress through development. An immediate short period of exposure to far red light entirely returns the pigment to its initial state and prevents triggering of the developmental process. A thirty minute break between red and subsequent far red light exposure renders the red light effect irreversible, and development then occurs regardless of whether far red light exposure subsequently occurs.Link to AmiGO

KEGG PATHWAY inferred to related to the module

SFGenesKEGG IDPathway nameLink to KEGG

Inter-species module comparison

Select a plant to compare co-expressed genes between species.
Glycine_max
Hordeum_vulgare
Oryza_sativa
Populus_trichocarpa
Triticum_aestivum
Vitis_vinifera
Zea_mays



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