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Literature summary for 1.3.7.7 extracted from

  • Kusumi, J.; Sato, A.; Tachida, H.
    Proceedings of the SMBE Tri-National Young Investigators Workshop 2005. Relaxation of functional constraint on light-independent protochlorophyllide oxidoreductase in Thuja (2006), Mol. Biol. Evol., 23, 941-948.
    View publication on PubMed
Search for more literature for 1.3.7.7

Organism

Organism UniProt Comment Textmining
Chamaecyparis lawsoniana Q2L631 and Q2L630 and Q2L629 subunit B, subunit L, and subunit N
-
Chamaecyparis obtusa Q2L634 and Q2L633 and Q2L632 subunit B, subunit L, and subunit N
-
Chamaecyparis pisifera Q2L637 and Q2L636 and Q2L635 subunit B, subunit L, and subunit N
-
Cryptomeria japonica Q2L646 and Q2L645 and Q2L644 subunit B, subunit L, and subunit N
-
Cunninghamia lanceolata Q2L604 and Q2L603 and Q2L602 subunit B, subunit L, and subunit N
-
Cupressus sempervirens Q2L628 and Q2L627 and Q2L626 subunit B, subunit L, and subunit N
-
Glyptostrobus pensilis Q2L643 and Q2L642 and Q2L641 subunit B, subunit L, and subunit N
-
Juniperus chinensis Q2L622 and Q2L621 and Q2L620 subunit B, subunit L, and subunit N; variant Juniperus chinensis procumbens
-
Juniperus rigida Q2L625 and Q2L624 and Q2L623 subunit B, subunit L and subunit N
-
Metasequoia glyptostroboides Q2L658 and Q2L657 and Q2L656 subunit B, subunit L, and subunit N
-
no activity in Thuja occidentalis
-
-
-
no activity in Thuja plicata
-
-
-
no activity in Thuja standishii
-
-
-
Platycladus orientalis Q2L619 and Q2L618 and Q2L617 subunit B, subunit L and subunit N
-
Sequoia sempervirens Q2L655 and Q2L654 and Q2L653 subunit B, subunit L, and subunit N
-
Sequoiadendron giganteum Q2L652 and Q2L651 and Q2L650 subunit B, subunit L, and subunit N
-
Taxodium distichum Q2L640 and Q2L639 and Q2L638 subunit B, subunit L, and subunit N
-
Thujopsis dolabrata Q2L614 subunit N
-
Thujopsis dolabrata Q2L615 subunit L
-
Thujopsis dolabrata Q2L616 subunit B
-

General Information

General Information Comment Organism
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Thujopsis dolabrata
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Platycladus orientalis
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Juniperus rigida
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Juniperus chinensis
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Cupressus sempervirens
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Chamaecyparis pisifera
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Chamaecyparis obtusa
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Chamaecyparis lawsoniana
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Taxodium distichum
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Glyptostrobus pensilis
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Cryptomeria japonica
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Sequoiadendron giganteum
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Sequoia sempervirens
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Metasequoia glyptostroboides
physiological function DPOR plays a key role in the ability to synthesize chlorophyll in darkness Cunninghamia lanceolata