Genetic and biochemical analyses of hypothetical protein 1: an interacting partner of CikA in Synechococcus elongatus PCC 7942

Synechococcus elongatus PCC 7942 is a model organism used to study the circadian rhythm, a process that is driven by an endogenous biological clock that can be modulated by external cues such as light and temperature. Some proteins have been identified that are involved in circadian signal transduction in S. elongatus. Of them, KaiA, KaiB and KaiC comprise the central oscillator components, which are essential for internal timekeeping. SasA is an important protein in the output pathway, which passes the information from central oscillator to downstream components, and thus controls metabolic and behavioral processes. CikA is a major component in the input pathway, which maintains synchrony of the oscillator with the environment. CikA is an unusual phytochrome-like histidine protein kinase. It has a pseudo receiver domain which can not accept a phosphoryl group. CikA is thought to be located at the poles of the cell through interaction between PsR and some protein or protein complex that is also localized at the poles. One of the potential CikA-interacting proteins identified through a yeast two hybrid screen is called hypothetical protein 1. It specifically recognizes a PsR bait in a yeast two hybrid assay. A bioinformatics analysis showed that there are predicted signal peptide and transmembrane domains at the N-terminal and a cytochrome C homolog domain at the C-terminal of Hyp1. Elucidating the features and function of Hyp1 will provide us with useful information to understand the function and working mechanism of CikA, and therefore will help us to clarify the signal transduction in the clock. In this research, I used genetic, cell biological and biochemical approaches to study the features and function of this newly identified clock component Hyp1. To confirm the interaction between PsR and Hyp1 and complement the yeast two hybrid data, I truncated Hyp1 (Thyp1) and purified soluble Thyp1. At the same time, I obtained purified PsR. I tried to copurify the PsR and 6-histidine-tagged Hyp1 on a nickel affinity column. However, PsR non-specifically bound to the column, which eliminated the utility of this approach to study their interaction. In addition to using a biochemical approach to study Hyp1, I constructed three hyp1 overexpression alleles for genetic analysis and two hyp1-yfp overexpression fusion alleles for subcellular localization studies. All of them will help us to understand the features and function of Hyp1.