Literature summary for 1.1.1.82 extracted from

Hameister, S.; Becker, B.; Holtgrefe, S.; Strodtkoetter, I.; Linke, V.; Backhausen, J.E.; Scheibe, R.
Transcriptional regulation of NADP-dependent malate dehydrogenase: comparative genetics and identification of DNA-binding proteins (2007), J. Mol. Evol., 65, 437-455.

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Protein Variants

Protein Variants	Comment	Organism
additional information	no promoter elements are identified in 5' direction of the NADP-MDH gene, and the expression of NADP-MDH is not affected in knock-out plants carrying a DNA insert in the 5'region. It is concluded that in Brassicaceae the majority of regulatory elements are located within the coding region	Arabidopsis thaliana
additional information	no promoter elements are identified in 5' direction of the NADP-MDH gene. It is concluded that in Brassicaceae the majority of regulatory elements are located within the coding region	Capsella bursa-pastoris
additional information	no promoter elements are identified in 5' direction of the NADP-MDH gene. It is concluded that in Brassicaceae the majority of regulatory elements are located within the coding region	Cochlearia officinalis
additional information	no promoter elements are identified in 5' direction of the NADP-MDH gene. It is concluded that in Brassicaceae the majority of regulatory elements are located within the coding region	Capsella rubella
additional information	no promoter elements are identified in 5' direction of the NADP-MDH gene. It is concluded that in Brassicaceae the majority of regulatory elements are located within the coding region	Arabidopsis lyrata subsp. petraea
additional information	no promoter elements are identified in 5' direction of the NADP-MDH gene. It is concluded that in Brassicaceae the majority of regulatory elements are located within the coding region	Lepidium densiflorum
additional information	no promoter elements are identified in 5' direction of the NADP-MDH gene. It is concluded that in Brassicaceae the majority of regulatory elements are located within the coding region	Lepidium latifolium

Organism

Organism	UniProt	Comment	Textmining
Arabidopsis lyrata subsp. petraea	-	-	-
Arabidopsis thaliana	-	-	-
Capsella bursa-pastoris	-	-	-
Capsella rubella	-	-	-
Cochlearia officinalis	-	-	-
Lepidium densiflorum	-	-	-
Lepidium latifolium	-	-	-

Source Tissue

Source Tissue	Comment	Organism	Textmining
leaf	amount of transcript increases 2fold after transfer into low temperature (12°C) or high light (750 microE) in all species	Arabidopsis thaliana	-
leaf	amount of transcript increases 2fold after transfer into low temperature (12°C) or high light (750 microE) in all species	Capsella bursa-pastoris	-
leaf	amount of transcript increases 2fold after transfer into low temperature (12°C) or high light (750 microE) in all species	Cochlearia officinalis	-
leaf	amount of transcript increases 2fold after transfer into low temperature (12°C) or high light (750 microE) in all species	Capsella rubella	-
leaf	amount of transcript increases 2fold after transfer into low temperature (12°C) or high light (750 microE) in all species	Arabidopsis lyrata subsp. petraea	-
leaf	amount of transcript increases 2fold after transfer into low temperature (12°C) or high light (750 microE) in all species	Lepidium densiflorum	-
leaf	amount of transcript increases 2fold after transfer into low temperature (12°C) or high light (750 microE) in all species	Lepidium latifolium	-

Synonyms

Synonyms	Comment	Organism
NADP-MDH	-	Arabidopsis thaliana
NADP-MDH	-	Capsella bursa-pastoris
NADP-MDH	-	Cochlearia officinalis
NADP-MDH	-	Capsella rubella
NADP-MDH	-	Arabidopsis lyrata subsp. petraea
NADP-MDH	-	Lepidium densiflorum
NADP-MDH	-	Lepidium latifolium

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Release 2023.1 (January 2023)