Back to Where It Came From: Chloroplast Expression of Both Rubisco Subunits Helps Functional Enzyme Analysis

Rubisco catalyzes the key carboxylation step in photosynthetic CO2 fixation and is probably the most abundant protein on Earth.Theenzyme is famous for inefficient catalysis and the habit of binding oxygen instead of CO2 in one out of every four binding events, leading to photorespiration reactions that release fixed CO2 and consume energy (Sharkey, 1988). Engineering an improved Rubisco to boost photosynthesis and increase crop yields is challenging, as interactions with Rubisco activase (required for enzyme activation) and chaperones (contributing to Rubiscoassembly) need tobemaintained (Sharwood, 2017). Further, coordinated changes in both the large (L) and small (S) subunits that make up the enzyme are needed to enhance its catalytic activity. Studying the role of various mutations on Rubisco activity in planta is hindered by the different genomic locations of genes encoding enzyme subunits: the rbcL gene encodes the Rubisco large subunit and resides in the chloroplast genome, whereas multiple nuclear RBCS genes code for the small subunits. In this issue of The Plant Cell, Martin-Avila et al. (2020) have tackled this obstacle in tobacco (Nicotiana tabacum) by silencing the nuclear RBCS genes and introducing various rbcL and rbcS versions into the chloroplast genome to assess their function. To avoid detrimental effects on photosynthesis and plant growth from impaired Rubisco function, the authors silenced the nuclear RBCS genes in a tobacco line carrying the gene for the Rubisco L-subunit from Rhodospirillum rubrum (rbcM ) in place of tobacco rbcL. The R. rubrum enzyme does not require S-subunits; the obtained plants with 13 silenced RBCS genes, named tobRrDS, were indistinguishable from the parental line. After successfully silencing endogenous RBCS genes, the authors used the tobRrDS tobacco line to test the effect of different sequence features on Rubisco production from synthetic rbcL-rbcS operons transformed into the chloroplast genome to replace R. rubrum rbcM. They discovered that codon optimization was important to achieve high translation in the chloroplast, and thus high Rubisco levels. In addition, sequences around the translation initiation site for rbcS, the second gene in the operon, also strongly affected Rubisco production. The maximal Rubisco amounts obtained in this experiment from chloroplast expression only reached ;50% of wild type levels, which agreeswith the slower plant growth andphotosynthesisobserved in the transplastomic plants. The tobRrDS is a great new tool to analyze Rubisco traits via expression of heterologous or mutant Land S-subunits from the chloroplast genome (see figure). The authors transformed the genes encoding the L-subunit and one of four different S-subunits from potato (Solanum tuberosum) Rubisco into the tobRrDS chloroplast genome and studied the effect of each L-S combination on Rubisco biogenesis, kinetics, photosynthesis, and plant growth. All combinations of chloroplast-expressed potato Rubisco subunits in tobacco yielded less enzyme and poorer photosynthesis and growth than in wild-type tobacco or in a line expressing potato L-subunit and native tobacco S-subunits. Nevertheless, the experiments gave insight into the structural characteristics that affectRubisco activity. For example, the potato S3-subunit gave Rubiscoa9%highercatalyticactivitycompared with other potato S-subunits, which was associated with two amino acid substitutions in the bA-bB loop in S3 that interacts with the L-subunit and may affect the interaction of the substrate with the catalytic site further down in the L-subunit. The work by Martin-Avila et al. (2020) creates a valuable tool to study theeffects of different substitutions in Rubisco subunits on enzyme biogenesis and catalytic activity, contributing to efforts of engineering a better Rubisco. However, optimization of mRNA biosynthesis and translation from transgenes incorporated Silencing of Nuclear Rubisco S-Subunit Genes Enables Chloroplast Expression of Desired Land S-Subunits.