1998) No production of lutein Decreased amount of qE npq1lut2 JNK-IN-8 order (Niyogi et al. 2001) See above No qE npq4npq1lut2 (Li et al. 2002a) See above No qE L5 (Li et al. 2002a) Over-expresses PsbS Increased amount of qE L17 (Li et al. 2002a) Over-expresses PsbS Increased amount of qE npq4-E122Q (Li et al. 2002b) One of two lumen-exposed glutamate residues mutated to glutamine 50 % qE compared to wild type npq4-E226Q (Li et al. 2002b) One of two lumen-exposed glutamate residues mutated to glutamine 50 % qE compared to wild type Arabidopsis thaliana mutants have provided researchers with a method of removing or altering proteins in the
photosynthetic apparatus. Examples include the mutants which showed that the protein PsbS is G418 cost necessary for qE. In wild type plants grown in low light, there are approximately 2 PsbS per PSII (Funk et al. 1995). The npq4 mutant, which lacks PsbS, shows no qE in PAM traces, demonstrating that PsbS is necessary for qE in vivo (Li et al. 2000). The npq4-E122Q and npq4-E226Q mutants, each of which has one lumen-exposed glutamate
residue mutated such that it cannot be protonated, have qE levels that are midway between that of the wild type and npq4. This showed that PsbS is pH sensitive and likely undergoes some conformational change when the Omipalisib lumen pH is low (Li et al. 2002b). To further examine the role of PsbS, the npq4-1 mutant was complemented with the wild type PsbS gene, yielding a set of mutants with varying levels of PsbS (Niyogi et al. 2005). The qE levels of these mutants show that Etofibrate the maximum qE level increases with increasing ratio of PsbS to PSII (Niyogi et al. 2005). This increase eventually plateaus when the level of PsbS is 6–8 times that of the wild type. Additionally, two
mutants that contain elevated levels of PsbS, L5 and L17, exhibit approximately twice the amount of NPQ compared to wild type plants. These mutants have revealed that the capacity for qE in wild type A. thaliana is not saturated and can be increased by elevating PsbS levels. Because of the complexity and interconnectedness of the thylakoid membrane, removing one component, such as a pigment or a protein, may cause other components in the membrane to compensate in a manner that is challenging to predict and characterize. One example of this is the mutant npq1, which cannot convert violaxanthin to zeaxanthin (Niyogi et al. 1998). However, the mutation does not block the biosynthesis of zeaxanthin from β-carotene. Therefore, while npq1 has a strongly reduced amount of zeaxanthin, some zeaxanthin and antheraxanthin are still present. In the case of npq2, which lacks zeaxanthin epoxidase, zeaxanthin accumulates even in the dark, so quenching components related to qZ are always present in the npq2 mutant.