Part | ID | Scion transcript code | Predicted gene name | Predicted gene function |
---|---|---|---|---|
Bark | B1 | NZPradTrx054097_C01 | Homeobox transcription factor KN3 | Central regulators of meristem cell identity (Guillet-Claude et al. 2004) |
B2 | NZPradTrx073079_C03 | Transporter, putative | Sugar transport (Weig et al. 1994) | |
B3 | NZPradTrx087709_C01 | Homeobox transcription factor KN1 | Central regulators of meristem cell identity (Namroud et al. 2010) | |
B4 | NZPradTrx055579_C01 | Mini zinc finger 1 | Regulates several development aspects, including photomorphogenesis, apical dominance, longevity, flower morphology and fertility, as well as root and stem elongation (https://www.uniprot.org/uniprot/Q9CA51) | |
B5 | NZPradTrx048496_C01 | Plastid phosphate translocator | Involved in the exchange of metabolites and inorganic phosphate between stroma and cytosol (Bockwoldt et al. 2019) | |
B6 | NZPradTrx101882_C01 | Auxin-induced protein 5NG4, putative | Transmembrane transporter activity especially during root formation (Busov et al. 2004) | |
B7 | NZPradTrx103825_C01 NZPradTrx103825_C04 | PREDICTED: GDSL esterase/lipase At5g03610-like | Lipid catabolic process (https://www.uniprot.org/uniprot/Q9LZS7) | |
B8 | NZPradTrx184572_C01 | G1-like protein | Polymerizes the backbones of non-cellulosic polysaccharides (hemicelluloses) of plant cell wall | |
B9 | NZPradTrx055645_C01 | PREDICTED: squalene monooxygenase-like | Converts squalene into oxidosqualene, the precursor of all known angiosperm cyclic triterpenoids (Rasbery et al. 2007) | |
NZPradTrx096935_C03 | ||||
B10 | NZPradTrx093053_C01 | Ribulose 1,5-bisphosphate carboxylase/oxygenase small subunit | Catalyses carboxylation of RuBP in the first step of the Calvin cycle of photosynthesis (Tabita 1999) | |
Needles | N1 | NZPradTrx115678_C04 | Anthocyanidin reductase | Involved in the biosynthesis of proanthocyanidins (Zhu et al. 2015) |
NZPradTrx115678_C05 | ||||
N2 | NZPradTrx090889_C01 | Cytochrome P450 CYPA2 | Oxidoreductase activity, acting on paired donors, with incorporation or reduction of molecular oxygen https://www.uniprot.org/uniprot/A9F9S4 | |
N3 | NZPradTrx114954_C01 | Glucosyltransferase | Transfer of glucose (Chen et al. 2016) | |
NZPradTrx086877_C02 | ||||
N4 | NZPradTrx088783_C01 | Glucose-1-phosphate adenylyltransferase, putative | Involved in the pathway starch biosynthesis (https://www.uniprot.org/uniprot/Q688T8) | |
N5 | NZPradTrx086324_C01 | PREDICTED: LOB domain-containing protein 1-like | Involved in the repression of the homeobox gene BP | |
N6 | NZPradTrx065580_C01 | Catalase | Crucial antioxidant enzymes that mitigates oxidative stress to a considerable extent by destroying cellular hydrogen peroxide to produce water and oxygen (Nandi et al. 2019) | |
N7 | NZPradTrx049683_C01 | Photosystem II core complex proteins psbY2C chloroplast precursor | Multi-component pigment-protein complex responsible for water splitting, oxygen evolution, and plastoquinone reduction (Lu 2016) | |
N8 | NZPradTrx097448_C02 | ribonucleoprotein, chloroplast, putative | Involved in chloroplast RNA processing (Tillich et al. 2009) | |
N9 | NZPradTrx119685_C01 | SOUL heme-binding protein | Plays an active role in primary plant metabolic pathways as well as in stress signalling (Shanmugabalaji et al. 2020) | |
N10 | NZPradTrx184701_C01 | chloroplast ribosomal protein S1 | Involvement in translation initiation via positioning of initiation mRNA–protein complexes (mRNPs), and the potential involvement of these unique domains in the processivity of chloroplast translation (Manuell et al. 2007) |