Conserved role of fructokinase-like protein 1 in chloroplast development revealed by a seedling-lethal albino mutant of pepper

© The Author(s) 2022. Published by Oxford University Press on behalf of Nanjing Agricultural University. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited. Horticulture Research, 2022, 9: uhab084


Dear Editor,
Chloroplasts perform photosynthesis and thus drive the growth, development, and reproduction of plants.
Mutations in genes that encode chloroplast proteins frequently lead to chlorophyll deficiencies. Studies on chlorophyll-deficient mutants have led to major advances in our knowledge of chloroplast-and photosynthesisassociated genes in model plants. Similarly, studies on chlorophyll-deficient mutants will contribute to our understanding of chloroplast development and function in solanaceous crops, such as pepper, thus helping us to rationally manipulate photosynthesis for crop improvement. Pepper is a globally important vegetable that is used as a spice, food, and medicine.
Chloroplast genes are transcribed by either the plastidencoded or nuclear-encoded RNA polymerase (PEP or NEP) [1]. PEP is a multisubunit enzyme that consists of core subunits encoded by the plastid-localized genes rpoA, rpoB, rpoC1, and rpoC2. PEP-transcribed genes are essential for efficient photosynthesis and normal growth [2]. Loss-of-function mutants deficient in PEP-associated proteins (PAPs) develop albino or pale-green leaves [3,4]. Thioredoxin Z (TRXz) and a fructokinase-like protein (FLN) associate with the PEP complex and contribute to the redox regulation of PEP [5]. Deficiencies in either TRXz or FLN1 inhibit both PEP and photoautotrophic growth [6]. In Arabidopsis, TRXz and FLN1 contribute to PEPmediated transcription and chlorophyll accumulation [7]. In rice, OsTRXz and two PAPs, WLP2/OsFLN1 and HSA1/OsFLN2, form a TRX-FLN complex that regulates PEP-mediated transcription and consequently affects chloroplast development [8,9]. Although PAPs have been studied in Arabidopsis and rice, few studies on PAPs have been performed with solanaceous crops such as pepper.
We report the positional cloning of a mutant allele responsible for an albino seedling-lethal phenotype in the miniature pepper cultivar MiniPep (Capsicum annuum). This mutant was unable to produce true leaves and eventually died at the seedling stage (Fig. 1a). Chlorophyll a and b were barely detectable in the 14d-old seedlings of the mutant (e1493) relative to the wild type (Fig. 1b). Transmission electron microscopy demonstrated the abnormal shape and ultrastructure of the plastids in e1493 relative to those in the wild type. The plastid in e1493 is round or nearly round, and the thylakoid membranes were barely detectable (Fig. 1c). Genetic analysis indicated that a recessive nuclear gene was responsible for these phenotypes.
To clone the causal gene, we performed a bulked segregant RNA-seq (BSR) analysis with an F 2 population prepared by crossing a plant that was heterozygous for the mutant allele from e1493 with the PC69 cultivar of C. annuum. We extracted RNA from pools of albino and wildtype tissue and used equivalent amounts of tissue from 30 seedlings for each pool. The BSR analysis indicated that the causal gene was located between 6.1 Mb and 18.9 Mb on chromosome 12 in the CM334 genome (Fig. 1d,  Fig. S1a). To identify the target gene, we re-sequenced the wild type (MiniPep) and e1493. We identified 49 candidate single-nucleotide polymorphisms (SNPs) in the 12.8-Mb interval (Table S1) that were homozygous for G/C to A/T substitutions [10]. After annotation, only one SNP (chr12_12913738) with a SNP index of −0.86 (Table S2) was found to be a missense mutation and was located in CA.PGAv.1.6.scaffold321.29, which we named CaFLN1. We independently demonstrated the presence of this missense mutation in CaFLN1 using Sanger sequencing (Fig. S1b). The combination of BSR, parental resequencing, and SNP filtering enabled us to rapidly identify the gene responsible for the albino phenotype in e1493. We expect that this strategy will be generally useful for cloning EMS alleles in crops. Sequence analysis showed that CaFLN1 is homologous to AtFLN1 (AT3G54090) from Arabidopsis, which encodes a fructokinase-like protein.
The mutant of AtFLN1 also shows an albino phenotype, and FLN1 interacts with the plastid-localized TRXz to promote chloroplast development [7]. CaFLN1 also showed high similarity with WLP2 (Os01t0851000), and wlp2 mutants are also albino. Moreover, WLP2 interacts with OsTRXz to form a TRX-FLN complex that promotes chloroplast development [8]. Similar to the cafln1 mutant, the osfln1 (wlp2) mutant is also an albino seedling-lethal mutant in rice [9]. A bioinformatics analysis provides evidence that CaFLN1 is targeted to the chloroplast and that CaFLN1 is preferentially expressed in leaves (Fig. S1c-d).
CaFLN1 contains two exons and one intron with a 1392bp open reading frame that encodes a protein containing 464 amino acid residues. The mutation changes a G to an A at position 481 relative to the first bp of the first exon, changing a glycine (Gly) to an arginine (Arg) residue in the CaFLN1 protein (Fig. 1d). FLN1 contains the conserved fpkB domain (Fig. S2). Our phylogenetic analysis indicates that there are four fpkB subfamilies: fructokinases (RFKs), fructokinase-like protein (FLN), adenosine kinase (ADK), and other kinases. The FLNs and RFKs are located on the same branch (Fig. S3). An amino acid sequence alignment of FLN1 orthologues from the Ensembl Plants database indicates that FLN1 orthologues are found in most plants. The Gly-to-Arg substitution in the e1493 mutant occurs in the highly conserved fpkB domain (Fig. S2). The FLN1 protein-protein interaction network is highly conserved in tomato, Arabidopsis, and rice (Fig. S4).
We used the virus-induced gene silencing (VIGS) technique to knock down the expression of CaFLN1 in pepper. We also silenced SlFLN1, the orthologue of CaFLN1 in tomato. Consistent with the albino phenotype of the CaFLN1 mutant, both CaFLN1-silenced pepper plants and SlFLN1-silenced tomato plants developed chlorotic leaves (Fig. 1e, 1f). Using qRT-PCR, we demonstrated that the expression of CaFLN1 and SlFLN1 was significantly reduced in the VIGS plants (Fig. 1g). The chlorophyll content of the silenced plants was also significantly decreased, although the tomato VIGS plants accumulated normal levels of chlorophyll a (Fig. 1h). Our results demonstrated that CaFLN1 contributes to the accumulation of chlorophyll in pepper and that the biological function of FLN1 is conserved in pepper and tomato.
To gain mechanistic insight, we compared the transcriptomes of cotyledon tissue from MiniPep and e1493. The correlation coefficient among the three biological replicates reached 0.99-1 (Fig. S5a), and PC1 explained 95.8% of the total variance (Fig. S5b). A total of 5524 differentially expressed genes (DEGs) were identified, 2648 upregulated and 2876 downregulated (Fig. S5c). A Gene Ontology (GO) term enrichment analysis indicated that the missense mutation in CaFLN1 led to changes in the expression of genes associated with many GO terms, including membrane and chloroplast development ( Fig. S6a; Table S3). A KEGG pathway analysis indicated that CaFLN1 is closely associated with photosynthesis ( Fig. S6b; Table S4). An independent quantification of the relative expression of eight chloroplast-related DEGs using qRT-PCR validated the data from the RNA-seq experiment (Fig. S7a-b). We conclude that the missense mutation in the CaFLN1 gene affects chloroplast development by disrupting PEP-mediated transcription.
In Arabidopsis and rice, FLN1 is an important subunit of the PEP complex and promotes chloroplast development [6,8]. Multiple lines of evidence, such as high levels of sequence similarity; a highly conserved pfkB domain; phenotypic characterizations of mutants in rice, Arabidopsis, tomato, and pepper; a predicted protein-protein interaction network that is conserved; and our VIGS experiments are all consistent with FLN1 performing a conserved biological function in plants that is essential for chloroplast development. We speculate that the PEP complex is impaired in our pepper mutant because of a missense mutation in CaFLN1 that consequently affects chloroplast biogenesis. Nevertheless, the exact mechanism remains to be elucidated.