Organophosphate hydrolase interacts with ferric-enterobactin and promotes iron uptake in association with TonB-dependent transport system.

Our previous studies have shown the existence of organophosphate hydrolase (OPH) as a part of the inner membrane associated Ton complex (ExbB/ExbD and TonB) of Sphingobium fuliginis. We now show its involvement in iron uptake by establishing direct interactions with ferric-enterobactin. The interactions between OPH and ferric-enterobactin were not affected even when the active site architecture is altered by substituting active site aspartate with either alanine or asparagine. Protein docking studies further substantiated these findings and predicted the existence of ferric-enterobactin binding site that is different from the catalytic site of OPH. A lysine residue (82K) found at the predicted ferric-enterobactin binding site facilitated interactions between OPH and ferric-enterobactin. Substitution of lysine with alanine did not affect triesterase activity, but it abrogated OPH ability to interact with both ferric-enterobactin and ExbD, strengthening further the fact that the catalytic site is not the site for binding of these ligands. In the absence of interactions between OPHK82A and ExbD, OPHK82A failed to target membrane in E. coli cells. The Sphingobium fuliginis TonB-dependent transport (SfTonBDT) system was reconstituted in E. coli GS027 cells generated by deleting the exbD and tonB genes. The E. coli GS030 cells having SfTonBDT system with OPH showed increased iron uptake. Such an increase was not seen in E. coli GS029, cells having SfTonBDT system generated either by omitting OPH or by including its variants, OPHD301A, OPHD301N suggesting a role for OPH in enhanced iron uptake.

Iron deficiency cause changes in photochemistry, thylakoid organization, and accumulation of photosystem II proteins in Chlamydomonas reinhardtii.

A trace element, iron (Fe) plays a pivotal role in photosynthesis process which in turn mediates the plant growth and productivity. Here, we have focused majorly on the photochemistry of photosystem (PS) II, abundance of proteins, and organization of supercomplexes of thylakoids from Fe-depleted cells in Chlamydomonas reinhardtii. Confocal pictures show that the cell's size has been reduced and formed rosette-shaped palmelloids; however, there is no cell death. Further, the PSII photochemistry was reduced remarkably. Further, the photosynthetic efficiency analyzer data revealed that both donor and acceptor side of PSII were equally damaged. Additionally, the room-temperature emission spectra showed the fluorescence emission maxima increased due to impaired energy transfer from PSII to PSI. Furthermore, the protein data reveal that most of the proteins of reaction center and light-harvesting antenna were reduced in Fe-depleted cells. Additionally, the supercomplexes of PSI and PSII were destabilized from thylakoids under Fe-deficient condition showing that Fe is an important element in photosynthesis mechanism.

High light induced changes in organization, protein profile and function of photosynthetic machinery in Chlamydomonas reinhardtii.

The green alga Chlamydomonas (C.) reinhardtii is used as a model organism to understand the efficiency of photosynthesis along with the organization and protein profile of photosynthetic apparatus under various intensities of high light exposure for 1h. Chlorophyll (Chl) a fluorescence induction, OJIPSMT transient was decreased with increase in light intensity indicating the reduction in photochemical efficiency. Further, circular dichroism studies of isolated thylakoids from high light exposed cells showed considerable change in the pigment-pigment interactions and pigment-proteins interactions. Furthermore, the organization of supercomplexes from thylakoids is studied, in which, one of the hetero-trimer of light harvesting complex (LHC) II is affected significantly in comparison to other complexes of LHC's monomers. Also, other supercomplexes, photosystem (PS)II reaction center dimer and PSI complexes are reduced. Additionally, immunoblot analysis of thylakoid proteins revealed that PSII core proteins D1 and D2 were significantly decreased during high light treatment. Similarly, the PSI core proteins PsaC, PsaD and PsaG were drastically changed. Further, the LHC antenna proteins of PSI and PSII were differentially affected. From our results it is clear that LHCs are damaged significantly, consequently the excitation energy is not efficiently transferred to the reaction center. Thus, the photochemical energy transfer from PSII to PSI is reduced. The inference of the study deciphers the structural and functional changes driven by light may therefore provide plants/alga to regulate the light harvesting capacity in excess light conditions.

Photosynthetic membrane organization and role of state transition in cyt, cpII, stt7 and npq mutants of Chlamydomonas reinhardtii.

In Chlamydomonas reinhardtii, cytochrome b6/f and chlorophyll b binding proteins are important in energy distribution between photosystem (PS)II and PSI. In this study, we have used C. reinhardtii mutants deficient in cytochrome b6/f complex (cyt), chlorophyll b binding protein (cpII), non-photochemical quenching (npq) and LHC II kinase (stt7) to study the importance of these proteins in electron transport, phosphorylation, and structural organization of thylakoid supercomplexes under optimum growth conditions. Fast Chl a fluorescence studies have shown that lack of CpII and Cyt b6/f caused reduced photochemical yield (Fv/Fm). The disappearance of I phase in cyt mutant showed that electron transfer from Cyt b6/f to PSI is reduced due to un availability of Q0 site for docking of PQH2 therefore LHC II kinase was unable to phosphorylate LHCII in cyt mutant. Further, blue native gel electrophoresis revealed the differential organization of photosynthetic membrane protein complexes in different mutants. Particularly, LHCII trimerization is more in cyt and stt7 mutants. Also, chemically induced state transition (LHCII phosphorylation) was not observed in cyt mutant, however, all other mutants were similar to that of wild type. Based on our results, we propose that the LHCII trimer accumulation and its organization with other complexes are very important in state transitions.