The PsaA-A684N mutants exhibited increased ET on the B-branch as compared to the A-branch in both in vivo and in vitro conditions. The transient electron paramagnetic resonance (EPR) spectroscopy revealed the formation of increased B-side radical pair (RP) at ambient and cryogenic temperatures. The ultrafast transient absorption spectroscopy and fluorescence decay measurement of the PsaA-A684N and PsaB-A664N showed a slight deceleration of energy trapping. Thus making mutations near ec2 on each branch resulted into modulation of the charge separation process. In the second set of mutants, where ec2 cofactor was target by substitution of PsaA-Asn604 or PsaB-Asn591 to other amino acids, a drop in energy trapping was observed. The quantum yield of CS decreases in Asn to Leu and His mutants on the respective branch. The P700 triplet state was not observed at room and cryogenic temperature for these mutants, nor was a rapid decay of P700+ in the nanosecond timescale, indicating that the mutations do not cause a blockage of electron transfer from the ec3 Chl. Time-resolved fluorescence results showed a decrease in the lifetime of the energy trapping. We interpret this decrease in lifetime as a new channel of excitation energy decay, in which the untrapped energy dissipates as heat through a fast internal conversion process. Thus, a variety of spectroscopic measurements of PSI with point mutations near the ec2 cofactor further support that the ec2 cofactor is involved in energy trapping process.
The first part of this dissertation describes the optimization of the previously established protocol for the H. modesticaldum reaction center isolation. Subsequently, electron transfer is characterized by ultrafast spectroscopy; the primary electron acceptor, a chlorophyll a derivative, is reduced in ~25 ps, and forward electron transfer occurs directly to a 4Fe-4S cluster in ~650 ps without the requirement for a quinone intermediate. A 2.2-angstrom resolution X-ray crystal structure of the homodimeric heliobacterial reaction center is solved, which is the first ever homodimeric reaction center structure to be solved, and is discussed as it pertains to the structure-function relationship in energy and electron transfer. The structure has a transmembrane helix arrangement similar to that of Photosystem I, but differences in antenna and electron transfer cofactor positions explain variations in biophysical comparisons. The structure is then compared with other reaction centers to infer evolutionary hypotheses suggesting that the ancestor to all modern reaction centers could reduce mobile quinones, and that Photosystem I added lower energy cofactors to its electron transfer chain to avoid the formation of singlet oxygen.
In the second part of this dissertation, hydrogen production rates of H. modesticaldum are quantified in multiple conditions. Hydrogen production only occurs in cells grown without ammonia, and is further increased by removal of N2. These results are used to propose a scheme that summarizes the hydrogen-production metabolism of H. modesticaldum, in which electrons from pyruvate oxidation are shuttled through an electron transport pathway including the reaction center, ultimately reducing nitrogenase. In conjunction, electron microscopy images of H. modesticaldum are shown, which confirm that extended membrane systems are not exhibited by heliobacteria.
The objective of this study is to create a spectrophotometric assay that can measure quinone reduction in the HbRC. The key techniques used in the project consisted of a PCR, a pseudo golden gate, a transformation into E. coli, a conjugation into Heliomicrobium modesticaldum, a growth study, a HbRC prep, and absorbance spectroscopy. PCR was crucial for amplifying the Cyt c553-PshX gene for the pseudo golden gate. The pseudo golden gate ligated Cyt c553-PshX into the plasmid pMTL86251 in order to transform the plasmid with the desired gene into the E. coli strain S17-1. This E. coli strain allows for conjugation into H. modesticaldum. H. modesticaldum cannot uptake DNA by itself, so the E. coli creates a pilus to transfer the desired plasmid to H. modesticaldum. The growth study was crucial for determining if H. modesitcaldum could be induced using xylose without killing the cells or inhibiting the growth in such a way that the project could not be continued. The HbRC prep was used to isolate and purify the Cyt c553-PshX protein. Absorbance spectroscopy and JTS kinetic assay was used to characterize and confirm that the protein eluted from the affinity column was Cyt c553-PshX. The results of the absorbance spectra and JTS kinetic assay confirmed that Cyt c553-PshX was not made. The study is currently being continued using a new system that utilizes SpyCatcher SpyTag covalent linkages in order to attach cytochrome to reduce P800 to the HbRC.