Physical mapping and InDel marker development for the restorer gene Rf2 in cytoplasmic male sterile CMS-D8 cotton

Background Cytoplasmic male sterile (CMS) with cytoplasm from Gossypium Trilobum (D8) fails to produce functional pollen. It is useful for commercial hybrid cotton seed production. The restore line of CMS-D8 containing Rf2 gene can restore the fertility of the corresponding sterile line. This study combined the whole genome resequencing bulked segregant analysis (BSA) with high-throughput SNP genotyping to accelerate the physical mapping of Rf2 locus in CMS-D8 cotton. Methods The fertility of backcross population ((sterile line×restorer line)×maintainer line) comprising of 1623 individuals was investigated in the field. The fertile pool (100 plants with fertile phenotypes, F-pool) and the sterile pool (100 plants with sterile phenotypes, S-pool) were constructed for BSA resequencing. The selection of 24 single nucleotide polymorphisms (SNP) through high-throughput genotyping and the development insertion and deletion (InDel) markers were conducted to narrow down the candidate interval. The pentapeptide repeat (PPR) family genes and upregulated genes in restore line in the candidate interval were analysed by qRT-PCR. Results The fertility investigation results showed that fertile and sterile separation ratio was consistent with 1:1. BSA resequencing technology, high-throughput SNP genotyping, and InDel markers were used to identify Rf2 locus on candidate interval of 1.48 Mb on chromosome D05. Furthermore, it was quantified in this experiment that InDel markers co-segregated with Rf2 enhanced the selection of the restorer line. The qRT-PCR analysis revealed PPR family gene Gh_D05G3391 located in candidate interval had significantly lower expression than sterile and maintainer lines. In addition, utilization of anther RNA-Seq data of CMS-D8 identified that the expression level of Gh_D05G3374 encoding NB-ARC domain-containing disease resistance protein in restorer lines was significantly higher than that in sterile and maintainer lines. Conclusions This study not only enabled us to precisely locate the restore gene Rf2 but also evaluated the utilization of InDel markers for marker assisted selection in the CMS-D8 Rf2 cotton breeding line. The results of this study provide an important foundation for further studies on the mapping and cloning of restorer genes. Supplementary Information The online version contains supplementary material available at 10.1186/s12864-020-07342-y.


Background
The cytoplasmic male sterility (CMS) system plays an important role in utilization of crop heterosis. CMS is a maternally inherited trait, that includes degenerate anthers, aborted pollen with carpelloid and petaloid stamens [1]. Current research has determined that the CMS phenotype is caused by mutations in the mitochondrial genome linked genes and reserved by fertility restorer genes in the nuclear genome [2][3][4]. The CMS system avoids the removal of anthers, thereby enabling the generation of dramatically superior F 1 progenies through hybrid technology. These offsprings display significant advantages over their parents and existing popular cultivars in terms of yield, stress tolerance, adaptability, etc. [5]. The CMS phenomenon exists in more than 150 plants and is also used for hybrid breeding of crops, such as maize [6,7], rice [8,9], pepper [10] and sorghum [11].
Cotton (Gossypium hirsutum L.) is a vital source of fibre, oil, and the most important economic crop for the textile industry in the world. In cotton, the CMS system is an ideal way to improve hybrid yields [12], Harknessii (D 2-2 ) cytoplasmic male sterile (CMS-D2) lines [13,14], Trilobum (D8) cytoplasmic male sterile (CMS-D8) lines [15], and upland cotton cytoplasmic male sterile (104-7A, Xiangyuan A, Jin A) have been established and utilized [16]. Normally, different CMS lines could be recovered by different restorer genes. In cotton, the restorer gene Rf 1 of CMS-D2 could restore the fertility of CMS-D2 and CMS-D8 sterile lines, while fertility of CMS-D8 sterile lines could only be restore with Rf 2 [17]. Furthermore, the Rf 1 gene functions in sporophytes, whereas the Rf 2 gene has a gametophytic restoration system. Previous studies revealed that Rf 1 gene loci and Rf 2 gene loci are not allelic, but these genes are tightly linked at a genetic distance of 0.93 cM on chromosome D05. The mapping and identification of the molecular markers linked with the Rf 1 restorer gene in cotton has already been progressed [18][19][20][21][22][23]. However, there are few researches about the Rf 2 , compared with Rf 1 .
With the increase in crop functional genome research, Rf genes have been successfully cloned in maize (Rf 2 ) [24], petunia (Rf-PPR592) [25], radish (Rfo) [26,27], rice (Rf1a, Rf1b, Rf2) [28][29][30][31], sorghum (Rf1) [32], and sugar beet (Rf1) [33]. Most of these genes encode PPR proteins, but Rf 2 in maize CMS-T, Rf17 in rice CMS-CW and Rf2 in rice CMS-LD encode aldehyde dehydrogenase, 178-amino-acid mitochondrial sorting protein and mitochondrial glycine-rich protein, respectively [24,34,35]. At present, the major bottleneck of cotton CMS breeding system is a narrow source of restorer genes and lack of excellent restorer lines compatible with a given sterile line. Unfortunately, no restorer gene has been cloned in cotton. Therefore, fine mapping and isolation of the restorer gene Rf 2 in upland cotton are highly needed for efficient breeding. Interestingly, bulked segregant analysis (BSA) make it possible to quickly locate molecular markers closely linked to the target gene by analysing the differences between SNPs and InDels in segregating population pools [36]. This method has already been used in gene mapping of Arabidopsis thaliana [37], rice [38][39][40] maize [41] and tomato [42]. The SNP and the InDel are the most abundant type of DNA sequence polymorphisms, found within the genomic sequence of each species [43,44], and used in QTL analysis. These markers have widely been used in cultivar identification, construction of genetic maps, genetic diversity, map-based cloning, the detection of genotype/ phenotype associations, and marker-assisted breeding (MAS) [45][46][47]. In recent years, the release of the upland cotton genomic sequence [48][49][50] and the rapid development of sequencing technology have enhanced the detection and application of SNP and InDel. Furthermore, the application of high-throughput genotyping methods makes SNP highly attractive genetic markers [51,52].
The objectives of this study were to physically map restorer gene Rf 2 and to develop InDel markers cosegregated with Rf 2 . A 1.88 Mb candidate interval was obtained by combining BSA with high-throughput SNP genotyping using a BC 1 F 1 segregation population. Based on the InDel variation in the 1.88 Mb interval, the InDel markers were developed and used to narrow down a 1.48 Mb candidate interval. The PPR family genes and the genes selected by transcriptome data in candidate region were analysed by qRT-PCR. The InDel markers cosegregated with Rf 2 will be useful to trace Rf 2 breeding restorer lines in cotton.

Anther observation and BC 1 F 1 fertility analysis
The anthers of fertile plants had a large amount of pollen, while the sterile plants had no pollen, and their anthers did not crack. Overall, a total of 1623 BC 1 F 1 plants were classified as 850 fertile and 773 sterile plants, and the ratio of the number of fertile plants (850) to the number of sterile plants (773) fit a 1:1 segregation (χ2= 3.6531 < χ2 (0.05,1) = 3.84), confirming that fertility restoration is conditioned by one dominant restorer gene, Rf 2 . This result is consistent with the results of Zhang et al. [53].

Whole genome resequencing data analysis and evaluation
The two parent lines (maintainer line B and restorer line R), F-pool, and S-pool of the BC 1 F 1 segregation population were sequenced. The Illumina platform was selected to construct the paired-end (PE) library, and the PE fragment was between 300 and 500 bp; 1,251,289,091 reads were obtained (

BSA combining SNP-index and G' values
The average sequencing depth of the parent lines and the offspring pools was 30.92×. Of these, the R restorer line has a sequencing depth of 16.62×. The B maintainer line sequencing depth was 16.03×, whereas the sequencing depth of the filial BC 1 F 1 generation was 47.77× + 43.26× (Table 2).
These reads were mapped onto the reference genome of Gossypium hirsutum (Tm-1, http://mascotton.njau. edu.cn/info/1054/1118.htm). A total of 798,286 SNPs was obtained from the two mixed pools, and 72,108 small InDel were obtained from the mixed pools. We used two different methods to map the Rf 2 locus responsible for restoring fertility. As shown in Figs. 1 and 2, only one locus was identified, and both the SNP-index and G' value association algorithms mapped this locus to chromosome D05. More specifically, this locus was located in the region of 25.61 Mb-59.94 Mb (34.33 Mb) using the SNP-index and G' value method.

Fine mapping of the Rf 2 gene
It was difficult to determine the candidate gene of Rf 2 , since the candidate range of 34.33 Mb contains a large amount of genetic information. Thus, it was necessary to fine map Rf 2 . We developed 24 SNP markers, and 23 valid SNP markers in this region were used for genotyping an additional 1423 individuals by high-throughput SNP genotyping. We found 6 recombinant plants in the BC 1 F 1 population. The position of the Rf 2 locus was narrowed down and was located between SNP563981 and SNP597385, a 1.88 Mb region (Supplementary Table  S2, the information of the SNP site). Next, we developed InDel markers on the correlated region, and InDel marker analyses revealed that 16 InDel markers were polymorphic. These InDel markers narrowed down the candidate interval to 1.48 Mb for existing recombinants at InDel marker sites. Finally, 10 InDel markers were cosegregated with Rf 2 (Figs. 3 and 4, Supplementary Table S3, InDel primers).

Marker-assisted breeding of restorer lines and CMS-D8 hybrid identification
Subsequently, 500 plants were randomly selected from the BC 4 F 1 population of CMS-D8, and the InDel 1327 marker was used for genotype analysis. The BC 4 F 1 population was typed by visual fertility investigations. The PCR products were analysed by agarose gel electrophoresis, and the results of agarose gel electrophoresis showed two different banding patterns. A single small PCR product was considered homozygous and lacked the restorer gene allele [S (rf 2 rf 2 )], indicating sterile plants, whereas two fragments were considered heterozygous at the restorer gene locus [S (Rf 2 rf 2 )], indicating fertile plants. Furthermore, the segregation ratio followed a 1 (Rf 2 rf 2 ):1 (rf 2 rf 2 ) (254 Rf 2 rf 2 : 246 rf 2 rf 2 , χ 2 0.05 = 0.1667 < 3.841), and the results were consistent with those of the fertility survey.
The plants were scanned with an atpA SCAR marker [2] and InDel 1327 markers, as the hybrids of the CMS-D8 system have sterile cytoplasm and Rf 2 heterozygous sites. The InDel 1327 primer amplification product produced two bands, and the atpA SCAR marker amplification product produced a band with a size of 611 bp (Fig. 5 b). Therefore, the CMS-D8 hybrids with heterozygous restorer gene sites and sterile cytoplasm were differentiated by the genotyping of restorer genes and the identification of cytoplasm type.

Candidate gene selection and expression pattern analysis
To determine candidate genes, we adopted a method that combined the 67 genes in the interval with the functional annotation of Arabidopsis orthologues and transcriptome data [54]. The 67 genes were subjected to Gene Ontology (GO) analysis. The GO analysis  indicated that most of the genes are involved in binding ( Fig. 6). According to the successfully isolated restorer genes of other crops belonging to the PPR family, we used qRT-PCR to analyse PPR family genes in candidate interval. Interestingly, the candidate region of the Rf 2 locus was found to contain 8 PPR genes (Gh_D05G3356, Gh_D05G3357, Gh_D05G3359, Gh_D05G3378, Gh_ D05G3389, Gh_D05G3391, Gh_D05G3392, Gh_ D05G3380) in the region of 1.48 Mb. The relative expression levels of the eight PPR family genes in the restorer line were not significantly higher than those of the maintainer and the sterile lines. However, the relative expression of the Gh_D05G3391 gene in the restorer line was significantly lower than that in the sterile and maintainer lines (Fig. 7).
Furthermore, the Gh_D05G3374, Gh_D05G3407 and Gh_D05G3417 genes were chosen based on FDR< 0.05 and |log 2 FC|>= 1 by the RNA sequence data (Supplementary Table S4). Since, the expression level in the restorer line was significantly higher than that in the sterile and maintainer lines. The qRT-PCR results showed that the Gh_D05G3417 gene in the restorer line was significantly higher than that in the sterile and maintainer lines (Fig. 7). Finally, two genes (Gh_ D05G3391 and Gh_D05G3374) were selected as possible candidate genes.

Discussion
CMS is a common phenomenon that occurs in flowering plants due to interactions between the mitochondrial genome and the nuclear genome [55]. CMS systems have been proven to be a proficient tool in hybrid seed production. Considering the importance of the CMS and restoration systems, numerous molecular mapping studies have been performed on restorer genes in crops, and Rf genes have already been isolated in other crops [24][25][26][27][28][29][30][31][32][33]. With CMS systems in cotton, fertility can be restored by restoring the genes Rf 1 or Rf 2 . However, these two genes have not yet been identified and cloned. With the availability of upland cotton whole genome sequencing [48][49][50] and cotton mitochondrial genome sequencing [56], breakthroughs in the study of cotton CMS and restoration of fertility mechanisms can be realized in recent years.
Molecular marker discovery and fine mapping of the fertility restoring gene of CMS cotton    Mapping Rf 2 using an efficient strategy Traditional map-based cloning is an efficient approach to isolate genes/QTLs responsible for desired agronomic traits [60][61][62]. Usually, a genetic map of F 2 , double haploid (DH) or recombinant inbred line (RIL) populations based on hundreds of SSR or InDel markers is used to make a primary map. Then a near-isogenic line (NIL) is developed which based on MAS to narrow down the  region of interest to a sufficient size to screen for a few candidate genes. Unfortunately, this workflow requires relatively more labour and time [63]. Compared with genetic mapping, the next generation sequencing (NGS) is a faster and reliable method for mapping [64]. Nevertheless, one mixed pool typically contains approximately 20-100 individuals and generally maps the target region at a Mb-level interval [65][66][67]. Because of insufficient meiotic recombination events, researchers still have to perform fine mapping or use omics methods such as RNA-seq to further screen the candidate genes [68,69]. High-throughput SNP genotyping is one of the dimorphic methods in which genotypes are confirmed by direct sequencing [70]. It has been successfully used to genotype interesting traits in plants [71,72]. In this regard, Yang et al. [73] developed 1536 SNP markers to measure genetic diversity by a high-throughput SNP genotyping method.
In this study, SNP-index and InDel-index analyses were used to first position the Rf 2 gene within a 34.33 Mb region. Later on, twenty-three SNP sites selected in this region helped to narrow the Rf 2 gene to a 1.88 Mb region. We developed InDel markers based on InDel variations and used these markers to locate the Rf 2 gene in a 1.48 Mb region. We thus put forward an approach that could rapidly fine map gene loci using only a large BC 1 F 1 segregation population, especially for those traits governed by single nuclear-encoded genes. This can be achieved by developing a large segregation population, mapping by sequencing analysis, and high-throughput SNP genotyping in a short time. Moreover, rapid and accurate identification of phenotype can be performed with progeny tests for desired objectives. Our study results suggested that BSA-seq combined with SNP genotyping can accelerate the mapping of loci controlling quality traits.

Utilization of InDel markers for MAS
Development of DNA markers linked to agronomically important traits and their use for MAS plays the role in promoting variety [74]. And various types of molecular markers closely linked to cotton restorer genes have been developed [19,21,57], but these markers are difficult to use for molecular marker-assisted breeding because of the complex experimental processes or low sensitivity of the markers [22]. Very recently, PCR based InDel have become a popular gel based genotyping solution, since InDel has the advantages of co-dominant, inexpensive, and highly polymorphic nature [44,75]. In this study, InDel markers co-segregated with restorer genes tracked Rf 2 for molecular marker-assisted breeding. InDel markers developed on the region showed a higher identification rate of the Rf 2 phenotype than previously developed markers, when applied to the breeding improvement of restorer lines.

Characteristics of the potential candidate gene Rf 2
Currently, Rf genes have been successfully isolated from different crop species [76]. Most of these restorer genes belong to the PPR gene family. PPR-type fertility restorer genes have been cloned for petunia [25], Ogura and Kosena cytoplasm in Raphanus sativus [26,27,77], Bor-oII CMS in Oryza sativa [78], A1 cytoplasm in Sorghum bicolor [32], Honglian CMS in rice [28,29], and nap CMS in Brassica napus [79]. In this study, we explored the expression patterns of 8 PPR genes of the CMS-D8 system in the candidate interval, and the expression level of most genes in the restorer line was not significantly different from that of the sterile and the maintainer lines. Interestingly, D05G3391, a PPR family gene had significantly lower expression in restorer line than in the sterile and maintainer lines. However, non-PPR restorer genes also exist in other crops, Rf2 in the maize CMS-T system encodes aldehyde dehydrogenase [24], Rf17of CMS-CW system and Rf2 of CMS-LD system in rice encode 178amino-acid mitochondrial sorting protein and mitochondrial glycine-rich protein [34,35]. Likewise, transcriptome data (unpublished data) was used to select upregulated genes of restorer line and then analysed by qRT-PCR. The relative expression of D05G3374, an NB-ARC disease-resistant protein gene, was significantly higher in restorer line than in sterile line and maintainer line. Based on the results of qRT-PCR, the candidate genes were not determined with the desired results in this study. The reason may be that Rf 2 is derived from the nuclear gene of G. trilobum [15] and might not be available in the reference genome of G. hirsutum. Therefore, cloning of fertility restorer genes in cotton CMS systems still needs further investigation.

Conclusions
In our study, the BC 1 F 1 population was chosen as a genetic population to map Rf 2 of CMS-D8. Integration of BSA, high-throughput SNP genotyping, and InDel markers identified 1.48 Mb candidate interval on chromosome D05. The InDel markers co-segregated with Rf 2 can be used to trace Rf 2 for molecular markerassisted breeding of restorer lines or hybrids. The qRT-PCR analysis identified Gh_D05G3391 and Gh_ D05G3374 genes as a putative candidate in this interval. The InDel markers co-segregated with Rf 2 can be used not only to trace Rf 2 for molecular marker-assisted CMS breeding but also cornerstone in fine mapping and cloning of restorer genes in cotton.

Materials and sample collection
The CMS-D8 system, a sterile line (A), maintainer line (B) and restorer line (R) were provided by the Institute of Cotton Research (ICR), Chinese Academy of Agricultural Science, Anyang, Henan, China. A BC 1 F 1 ((A line ×R line) ×B line) segregation population was constructed, and all materials were grown at the Cotton Research Farm at the ICR. Fresh leaves were obtained from the parent lines and BC 1 F 1 population. Anthers from buds1-2 mm, 3 mm, and 4 mm in length were collected and combined from 100 plants. All harvested samples were snap-frozen in liquid nitrogen and stored at − 80°C before use.

Fertility segregation analysis
During anthesis, visual fertility surveys were conducted for 1623 individuals of the BC 1 F 1 population of CMS-D8 under field trial conditions, three times per plant. The presence of pollen in a plant indicated fertility and was determined by squeezing the anthers between the fingers because the male sterility of CMS-D8 occurs during meiosis, the S (rf) gametes are sterile, and S (rf 2 rf 2 ) produces no pollen. So, the observed values of fertile and sterile plants were obtained, the fertility trait segregation ratio compatibility test was carried out using Excel software, and the Chi-square value was obtained to determine the genetic model of Rf 2 .

DNA extraction, library construction and Illumina sequencing
DNA was extracted by the CTAB method [80], and the quality of DNA was assessed by 1.2% agarose gel electrophoresis. The purity of DNA was examined using an Agilent Technologies 2100 Bioanalyzer. The DNA concentration was estimated using a Qubit® DNA Assay Kit in a Qubit® 2.0 Fluorometer (Life Technologies, CA, USA). Equal amounts of DNA (1.5 μg/sample) from 100 BC 1 F 1 plants with fertile phenotypes were mixed to form the fertile sample (F-pool), and those from another 100 plants with sterile phenotypes were mixed to form the sterile sample (S-pool). Sequencing libraries were generated using the VAHTS™ Universal DNA Library Prep Kit for Illumina® V3 (Vazyme Biotech) according to the manufacturer's recommendations. Briefly, the DNA samples were fragmented by sonication to a size of 300-500 bp. Then, the DNA fragments were end-polished, Atailed, and ligated with the full-length adapter for Illumina sequencing by PCR amplification. Consequently, the PCR products were purified (VAHTS™ DNA Clean Beads (Vazyme #N411)), and libraries were analysed for size distribution by an Agilent 2100 Bioanalyzer and quantified by real-time PCR. The libraries constructed above were sequenced by the Illumina HiSeq platform, and 150 bp paired-end reads were generated with an insert size of approximately 350 bp. The sequence raw reads were submitted to the SRA database of NCBI under the Bioproject PRJNA685585.

Data analysis, data filtering, and alignment
The Fast x-toolkit (v 0.0.14-1) was used to filter out the low-quality reads such as reads with ≥10% unidentified nucleotides (N), reads with > 50% bases having phred quality < 5, reads with > 10 nt aligned to the adapter, allowing ≤10% mismatches, and putative PCR duplicates generated by PCR amplification in the library construction process (read 1 and read 2 of two paired-end reads were completely identical). The released genome of Gossypium hirsutum was downloaded from the Cotton Research Institute (CRI) of Nanjing Agricultural University of China (http://mascotton.njau.edu.cn/Data.htm, v1.1) and used as a reference genome [49]. For mapping to the reference genome, BWA (Burrows-Wheeler Aligner) [81] was used to align the clean reads of each sample against the reference genome (settings: mem -t 4 -k 32 -M -R). Alignment files were converted to BAM files using SAMtools software [82] (settings: -bS -t). In addition, potential PCR duplications were removed using the SAMtools command "rmdup". If multiple read pairs had identical external coordinates, only the pair with the highest mapping quality was retained.

Determination of a candidate interval using SNP index and G' values
To obtain a highly accurate SNP set, a range of filters were also employed [85]. The homozygous SNPs between two parents were extracted from the VCF files for SNPs. The read depth information for homozygous SNPs in the above offspring pools was obtained to calculate the SNP index [36]. The SNP index method was used for the analysis, and the SNP-index dot matched curve was obtained by regression fitting as described by Abe et al. [40]. The G' values are used for noise reduction while also addressing linkage disequilibrium (LD) between SNPs [86]. To rule out the effects of unreliable markers, we screened markers based on the SNP index using the following conditions: 1) the sequencing depth of both parents was greater than 8; 2) both pools had a sequencing depth greater than 10; 3) the SNP index values of the two pools were not greater than 0.8 or less than 0.2 at the same time; and 4) the SNP index value difference was greater than 0.8. Sliding window methods were used to present the SNP index of the whole genome. Usually, we used a window size of 2 Mb as the default settings, and used QTL-seqr software to calculate Δ (SNPs-index) and G', based on the markers that were scanned [87].
Fine mapping of Rf 2 using high-throughput SNP genotyping and InDel makers For the analysis, DNA was isolated from the two parental lines and the BC 1 F 1 population. The informative molecular markers were used for genotyping each plant of the BC 1 F 1 population, various recombinants in the target region were identified, and the linkage relationship between markers and the Rf 2 locus was analysed for gene mapping. According to the results of sequencing mutation detection and BSA of sequencing candidate intervals, one SNP was selected for approximately every 1.5 Mb of physical distance. The selected SNPs met the requirement of having a variation index close to 0.5 in the F-pool and 0 in the S-pool. A subset of 24 selected SNPs was used for genotyping by the Illumina HiSeq PE150 sequence. Individual BC 1 F 1 population (except 200 plants that formed pools) plants were genotyped using high-throughput SNP genotyping. Based on the SNP locus exchange of individual plants, we narrowed down the range in which the target gene was located.
The InDel markers were developed based on the insertion deletion mutation within the selection interval. Primers were designed using Oligo7 software [88] and synthesized commercially (TSINGKE Biological Technology, Zhengzhou, China). The PCR system consisted of 20 μL of PCR mixture that contained 1× reaction buffer, 2.0 mM MgCl 2 , 0.2 mM dNTPs, 0.5 mM each primer, 1 U Taq DNA polymerase (Takara, Japan), and 50 ng of DNA template. The PCR amplification conditions were as follows: 35 cycles of denaturation at 94°C for 30 s, annealing at 56°C-58°C for 30 s, and extension at 72°C for 30 s. Then, the reaction was held at 4°C. The PCR products were visualized by 3.5% agarose gel electrophoresis. Based on the difference between the genotypes as assessed using polymorphic markers, recombinants were identified in the BC 1 F 1 population and used to fine map Rf 2 .

Marker-assisted breeding of restorer lines
The utility of the InDel markers for marker-assisted selection was determined in a segregating population. First, the restorer line [N (Rf 2 Rf 2 )] of CMS-D8 was crossed with the recurrent parent [N (rf 2 rf 2 )], which has excellent agronomic characteristics. Beginning in the BC 1 F 1 generation, the codominant InDel marker 1327 was used to track the restorer gene in each generation, and the other markers were used for further verification. Only those individuals verified by the markers were chosen as the female parent for successive backcrosses. In the BC 4 F 1 population, 120 individuals were randomly selected, and then InDel 1327 was used to perform segregation analysis. The individuals verified by the markers as homozygous at the restorer gene locus were test-crossed with the sterile line [S (rf 2 rf 2 )] to determine the segregation of the fertility phenotype in the offspring under field conditions. The atpA SCAR marker distinguishes the CMS cytoplasm from other types of cytoplasm [2]. Here, the InDel 1327 marker was combined with the atpA SCAR marker to identify hybrids in the CMS-D8 system.

Real-time quantitative PCR (qRT-PCR) analysis
The annotated genes in the interval were analysed, and realtime quantitative PCR was performed to identify PPR family genes and differentially expressed genes that were selected based on anther transcriptome data of the CMS-D8 system (unpublished data). Total RNA was isolated using the Sigma Spectrum Plant Total RNA Kit (Sigma-Aldrich, USA) according to the manufacturer's protocol. Reverse transcription was conducted using the PrimeScript™ RT Reagent Kit (TaKaRa, Beijing, China). Trans Start® Top Green qPCR Super Mix (Trans gen, Beijing, China) was used according to the manufacturer's instructions to conduct qRT-PCR of the genes. The internal control gene used for qRT-PCR was the cotton His3 gene (i.e., histone 3) with primers of GhHIS3F and GhHIS3R, and relative gene expression levels were calculated using the 2 -△△CT method [89], as described in detail in previous studies [90][91][92]. Each gene in each sample was analyzed with three replicates and two technical replicates. All primers are listed in Table S1.