#PAGE_PARAMS# #ADS_HEAD_SCRIPTS# #MICRODATA#

Genetic analysis and fine mapping of a qualitative trait locus wpb1 for albino panicle branches in rice


Authors: Zhongquan Cai aff001;  Peilong Jia aff002;  Jiaqiang Zhang aff003;  Ping Gan aff001;  Qi Shao aff001;  Gang Jin aff004;  Liping Wang aff004;  Jian Jin aff001;  Jiangyi Yang aff001;  Jijing Luo aff001
Authors place of work: College of Life Science and Technology, State Key Laboratory for Conservation and Utilization of Subtropical Agro-Bioresources, Guangxi University, Nanning, China aff001;  Institute for New Rural Development, National Demonstration Center for Experimental Plant Science Education, College of Agriculture, Guangxi University, Nanning, Guangxi, China aff002;  Research and Development Centre of Flower, Zhejiang Academy of Agricultural Sciences, Hangzhou, China aff003;  Guangxi Subtropical Crops Research Institute, Nanning, China aff004
Published in the journal: PLoS ONE 14(9)
Category: Research Article
doi: https://doi.org/10.1371/journal.pone.0223228

Summary

Chloroplast plays an important role in the plant life cycle. However, the details of its development remain elusive in rice. In this study, we report the fine-mapping of a novel rice gene wpb1 (white panicle branch 1), which affects chloroplast biogenesis, from a tropical japonica variety that results in an albino panicle branches at and after the heading stage. The wpb1 variety was crossed with Nipponbare to generate the F2 and BC1F2 populations. Green and white panicle branch phenotypes with a 3:1 segregation ratio was observed in the F2 population. Bulked segregant analysis (BSA) based on whole genome resequencing was conducted to determine the wpb1 locus. A candidate interval spanning from 11.35 to 23.79M (physical position) on chromosome 1 was identified. The results of BSA analysis were verified by a 40K rice SNP-array using the BC1F2 population. A large-scale F2 population was used to pinpoint wpb1, and the locus was further narrowed down to a 95-kb interval. Furthermore, our results showed that the expression levels of the majority of the genes involved in Chl biosynthesis, photosynthesis and chloroplast development were remarkably affected in wpb1 variety and in F2 plants with a white panicle branch phenotype. In line with the results mentioned above, anatomical structural examination and chlorophyll (Chl) content measurement suggested that wpb1 might play an important role in the regulation of chloroplast development. Further cloning and functional characterization of the wpb1 gene will shed light on the molecular mechanism underlying chloroplast development in rice.

Keywords:

Rice – Genetic loci – Biosynthesis – Leaves – Photosynthesis – Chloroplasts – Chlorophyll – Panicles

Introduction

Chlorophyll (Chl) is green pigments found in cyanobacteria and the chloroplasts of algae and green plants on Earth. Chlorophyll is essential, allowing plants to absorb light energy and perform photosynthesis [1]. In addition, chlorophyll plays an critical role in human health, including cancer treatment and prevention [2]. Chlorophyll molecules are structural constituents of photosystems that are embedded in the thylakoid membranes of chloroplasts. Thus, chloroplasts are important organelles for the fixation of light energy for the life of plants, and any other life in our biosphere. The initiation and development of chloroplasts are jointly regulated by the nuclear genome and chloroplast genome [3]. Previous studies have reported that mutation of genes that control chloroplast development or chlorophyll synthesis leads to albinism in some specific parts of the plant [47]. The mutations seriously affect the photosynthetic efficiency, resulting in reduced production and even causing the developmental arrest of plants. Many related genes have been cloned and functionally characterized. In Arabidopsis, ALB3, which is encoded by a nucleic gene, is transported into chloroplasts and embedded into the chloroplastic membrane, where it is involved in the composition of the chloroplast enzymatic complex. Loss of function of Alb3 gives rise to a white or yellow cotyledons and leaves, leading to stop growing beyond the seedling stage [8]. An ylc1 mutant of indica rice 9B, which was induced by 60Co radiation, resulted in a decrease in chlorophyll and lutein content at different temperatures [9]. In tobacco, an ali albino mutant with an albino phenotype was obtained by irradiating BY-4 tobacco with a 14N ion beam, and the expressions of plastid-encoded genes rbcL and psbA in the mutant was down-regulated dramatically [10]. FA85 is a natural mutant of winter wheat. The leaf colour of the mutant is whitened, and the abundances of ATPase-γ and GP1-α are up-regulated, while the biosynthesis of other chloroplastic proteins is remarkably inhibited [11]. Moreover, in maize, the ppr4 gene encodes a chloroplast-targeted protein containing a PPR sequence and RNA recognition elements. PPR4 directly targets the intron of rps12 and affects the accumulation of rps12 mRNA in chloroplasts [12].

The molecular mechanism of rice albino phenotypes is complex. At present, more than 100 genes related to leaf colour alternation in rice have been reported (http://www.gramene.org/, up to now). These genes are involved in chloroplast development regulation, chlorophyll synthesis or degradation, etc. [13]. For example, rice v3 and stl genes impair the synthesis of plastid DNA and hinder chloroplast differentiation [14]; The virescent-l (v1), virescent-2 (v2), and vyl genes were found to hinder the formation of chloroplasts, resulting in white streaks on rice leaves. In their WT plants, these genes highly express in the second stage of chloroplast development [4, 6, 1517]; Rice wsl and wsl4 genes, which encoded proteins WSL and WSL4, respectively, involved in RNA metabolism in chloroplasts. Their mutations caused abnormal splicing of rpl2, ndhA, atpF and other chloroplast gene transcripts, resulting in leaf streaks [18, 19]. In addition, another class of genes, such as WSL3 and YSS1, encode the proteins that targeted the chloroplast nucleoid and played a key role in regulating the expression of genes related to Plastid-encoded plastid RNA polymerase (PEP). Their mutations resulted in a white streak phenotype in rice [20, 21].

At present, the albino phenotypes have been observed on the panicle, seedlings and leaves of rice, for example, in addition to two albino mutants v1 and v2 mentioned above [6, 22], another two classical panicle colour mutants wp1 and wp2, which were used as morphological markers in the field, show albino coloration on the whole panicles. The wp1 locus was located on chromosome 7 [22, 23]. Li et al. fine mapped a white panicle controlling gene wp(t) between the markers SSR101 and SSR63.9 on chromosome 1, which was close to the morphological marker wp2 and might be another allelic mutation of wp2 [24]. The wp1 and wp2 mutants were all whitened along the entire panicle. In addition, the mutations of other genes that have been reported to control the related traits of white panicle in rice, including st-wp [24], slwp [25], alsm6 [26], st-fon [27], wp4 [28], wlp1 [29], wlp6 [13], wslwp [30], and wsp1 [31]. However, with the exception of the albino phenomenon observed on the whole panicle, including the rachises, branches, and glumes, it is rare to see the albino phenotype observed only on panicle branches.

SNPs (single nucleotide polymorphisms) and InDels (insertions-deletions) are the most common genetic markers in the genome. They have the characteristics of large numbers and rich polymorphisms and are often used in QTL analysis. Bulked segregant analysis (BSA) is a rapid method for locating target trait genes and it was initially used in lettuce [32]. This method constructs two mixing pools by mixing individuals with extreme traits in the segregating population [33]. By analysing the differences between SNPs and InDels between the two mixing pools, we can quickly locate the molecular markers closely linked with the target gene. This method has been widely used in gene mapping of Arabidopsis thaliana [34], rice [35, 36] and maize [37], etc.

In this study, a rice white panicle branch variety wpb1 was characterized. Its panicle branches showed an albino phenotype with stable heredity. The branches of young panicles were observed to be whitened from the heading stage, and the whitened colour was kept even until the ripening stage. However, the rachis and glumes of the panicles of wpb1 show normal or light green colour. Therefore, the variety does not show a defect in flowering and seed setting. To our knowledge, the panicle branch albino mutant material is valuable for frescamente ornament, due to its snow-white panicle and streaked leaves, especially in autumn. The locus underlying the wpb1 phenotype was preliminarily mapped by BSA and 40K rice SNP-array analysis, and then the locus was fine-mapped to the 95-kb interval on chromosome 1. Our results laid a foundation for further cloning of the gene and its functional characterization. Likewise, the study also shed light on the physiological process of chlorophyll biosynthesis, the development of chloroplasts, and photosynthesis.

Materials and methods

Plant materials

The inbred rice variety wpb1 (Oryza sativa L. subsp. japonica), with a white panicle branch, derived from natural mutation. The field trials were performed in an experimental field at the campus of Guangxi University, Nanning City, China (E108°22′, N22°4). The cross between wpb1 and NIP (Nipponbare) (Oryza sativa L. ssp. japonica) was used to generate population materials to map the locus underlying the wpb1 phenotype. The wpb1 variety was selected as the female parent, and NIP was selected as the pollen donor. Then, the F2 population was generated via self-crossing of F1.

Genetic analysis of the white panicle branch phenotype

The colour of the panicle branch at the heading stage of all plants was investigated under field trial conditions. The number of white panicle branch plants and green panicle branch plants for every population, including the parents, F1, F2, BC1F1, and BC1F2, were recorded. The segregation ratios in the F2 and BC1F2 populations were analysed, and the genetic model was inferred and tested using a Chi-square test with SPSS software.

High-throughput sequencing

The genomic DNA of young and healthy leaves was extracted using the DNeasy 96 Plant Kit (Qiagen, Valencia, CA). The integrity of each DNA sample was examined by 1% agarose gel electrophoresis. DNA purity was determined using a NanoPhotometer® spectrophotometer (IMPLEN, CA, USA). DNA concentration was measured using a Qubit® DNA Assay Kit in a Qubit® 2.0 Flurometer (Life Technologies, CA, USA). Equal amounts of DNA (1.5 μg/sample) from 30 F2 plants with white panicle branches were mixed to form the white panicle branch bulk sample (W-pool), and those from another 30 plants with normal (green) branches were mixed to form the normal branch bulk sample (G-pool). Sequencing libraries were constructed using a Truseq Nano DNA HT sample preparation kit (Illumina USA) following the manufacturer’s instructions. In brief, the DNA sample was sheared to a 350-bp fragment by sonication. The obtained DNA fragments were end-polished, A-tailed, and ligated with a full-length adapter for deep sequencing. The libraries were sequenced using an Illumina HiSeq 4000 platform with a 20× depth. Sequence data were analysed by Novogene (Beijing, China). To ensure that reads were reliable and without artificial bias, quality control (QC) procedures were set as follows: reads with ≥10% unidentified nucleotides were removed, reads with > 50% bases having phred quality < 5 were removed, reads with > 10 nt aligned to the adapter were removed, ≤10% mismatches were allowed, putative PCR duplicates generated by PCR amplification in the library construction process were removed. The genomic information of NIP was obtained from NCBI. The genomic DNA data of NIP was downloaded from the website: ftp://ftp.ensemblgenomes.org/pub/plants/release-36/fasta/oryza_sativa/dna/. Mapping to the reference genome BWA (Burrows-Wheeler Aligner) was used to align the clean reads of each sample against the reference genome (settings: mem -t 4 -k 32 -M -R) [38].

Bulked segregant analysis (BSA)

SNP/InDel detection and annotation variant calling were performed for all samples using the Unified Genotyper function in GATK software [39]. SNP was used as the variant filtration parameter in GATK (settings: filterExpression QD < 4.0 || FS > 60.0 || MQ < 40.0, G_filter GQ<20, cluster WindowSize 4). InDel was filtered by the variant filtration parameter (settings: filter Expression QD < 4.0 || FS > 200.0 ||Read PosRankSum < -20.0 || Inbreeding Coeff < -0.8). ANNOVAR [40] was used to annotate SNPs or InDels for the reference genome. The homozygous SNPs/InDels between two parents were extracted. The read depth information for homozygous SNPs/InDels in the offspring pools was obtained to calculate the SNP/InDel index (frequency) [33]. The genotype of one parent was used as the reference statistic for the the SNP/InDel index. The points at which the SNP/InDel index in both pools was less than 0.3 were filtered out. Sliding window methods were used to present the SNP/InDel index of the whole genome. The average SNP/InDel index in each window was used as the SNP/InDel index for this window. A window size of 1 Mb and a step size of 10 Kb were used as default settings. The difference in the SNP/InDel index of the two pools was calculated as the delta SNP/InDel index. The intervals of the delta all index in the 95% confidence interval of the permutation test were selected as candidate loci. Genes with SNPs causing stop gain or loss, that were non-synonymous and spliced, or those with InDels causing stop gain or loss, or frame shift mutations in their corresponding alleles were selected as the candidate genes in the 95% confidence interval.

Validation of BSA results by 40k rice SNP-array analysis

The result of the BSA was validated by 40k rice SNP-array, a whole-genome single nucleotide polymorphism (SNP) array with 40k SNP and InDel markers, using the BC1F2 population. The total genomic DNA from young and healthy leaves of BC1F2 population plants was extracted using the DNeasy 96 Plant Kit (Qiagen, Valencia, CA). Equal amounts of DNA from 30 BC1F2 plants exhibiting white panicle branches were mixed to form the white branch bulk sample (W-pool), and those from another 30 plants with normal green panicle branches were mixed to form the normal branch bulk sample (G-pool). DNA amplification, fragmentation, chip hybridization, single base extension, staining and scanning were conducted by the greenfafa Science and Technology Research Institute Co., Ltd. (Wuhan, China) following the Infinium HD Assay Ultra Protocol (http://www.illumina.com/).

Fine mapping of wpb1

The candidate locus of wpb1 was fine-mapped with high-resolution linkage analysis by map-based cloning. For the analysis, DNA was isolated from the two parental lines and the F2 population. The informative molecular markers were used for genotyping each plant of the F2 population, various recombinants in the target region were identified, and the linkage relationship between markers and the wpb1 locus was analysed for gene mapping. The flanking SSR markers were obtained from Gramene (http://www.gramene.org/). The genomic DNA sequences of the two parents, wpb1 and NIP, obtained from Illumina sequencing were used to develop InDel markers for fine mapping (S1 Table).

Analysis with quantitative real‐time PCR (qPCR)

To examine the expression differences of the genes involved in Chl biosynthesis, photosynthesis, and chloroplast development in wpb1 and NIP, RNA was extracted from young panicle branches of wpb1 and NIP at stage In8 using an RNA Prep Pure Plant Kit (Tiangen Co., Beijing, China). Total RNA was reverse transcribed using a FastKing kit KR123 (Tiangen Co., Beijing, China). For transcriptional analysis of Chl biosynthesis‐associated, chloroplast development‐associated, and photosynthesis‐associated genes (HEMA1, CAO1, PORA, V1, v2, rpoA, rpoB, Cab1R, Cab2R, psaA, psbA) in rice (S2 Table) [4, 6, 4144], qPCR analyses were performed using a SYBR Premix Ex TaqTM kit (Takara) on a LightCycler 480 II Real‐Time PCR System (Roche). The relative quantification of gene expression data was performed as described in Livak & Schmittgen [45]. Actin coding gene, actin-7 (Os11 g0163100), was used as an internal reference. The specific primers for qPCR were designed according to Zhang et al. [44] (S2 Table).

Chlorophyll content measurement

The leaf chlorophyll content was determined according to the method described by Qiu et al. [46]. The plant materials were cut into 1 mm small pieces. Next, 50–100 mg of the samples were placed into a 10 mL graduated test tube with a stopper. Then, 2 mL DMSO was added into the test tube, and the samples were immersed in DMSO. The tubes were incubated in a 65°C incubator in the dark until all the samples turned white or transparent. The chlorophyll in the leaf samples was dissolved into DMSO. While the solutions cooled down, 8 mL 80% (v/v) acetone was added and mixed well. Then, the absorbance of the solution was determined at 663.6 and 646.6 nm by spectrophotometry. Chlorophyll concentration was calculated with the following formulas: Chla (mg·L-1) = 12.27×A663.6–2.52×A646.6; Chlb (mg·L-1) = 20.10×A646.6–4.92×A663.6; ChlT (mg·L-1) = Chla+Chlb = 7.35×A663.6+17.58×A646.6.

Chlorophyll fluorescence analysis

The stalks, branches, and glumes of the spikelet from wpb1, NIP and F2 plants were used for chlorophyll fluorescence analysis after heading. A Research Stereomicroscope System (Olympus SZX-16 Stereo Microscope, Olympus Corporation) was used to capture chlorophyll fluorescence images following the manufacturer’s protocol. The microscopy images were photographed with the following settings: exposure time 300 ms, ISO 200 under bright field, exposure time 1 s, ISO 1600 under RFP.

Histological analysis

For histological analysis, fresh panicle branch samples from wpb1, NIP and F2 plants were cut into ultrathin transverse sections by the Leica CM1860 UV Cryostat (Leica Biosystems Nussloch GmbH, Germany), following the manufacturer’s protocol. Microscopy was performed on a Leica DM4 B upright digital research microscope.

For TEM analysis, panicle branch samples of wpb1 and NIP were soaked in primary fixation buffer (2.5% glutaraldehyde) and post-fixed for 2 h in secondary fixation buffer (1% OsO4 in 100 mM cacodylate buffer, pH 7.4). The fixed samples were dehydrated in an ethanol series, embedded in resin, and stained by uranyl acetate together with lead citrate for 15mins, separately. Using Reichert-Jung ULTRACUT E ultra-thin slicing machine (Austria), 70 nm slicing, copper mesh fishing. Ultra-thin sections were observed by TEM (JOEL JEM-1200 electron microscope).

Results

The white panicle branches were observed in wpb1 variety

A tropical japonica rice variety wpb1 (Oryza sativa L. subsp. japonica) has normal plant architecture and normal colour of the aboveground parts at the vegetative stage in summer, similar to the majority of extant rice varieties. However, at the heading stage, the wpb1 variety exhibits white panicle branches including the primary and secondary branches, as well as the white lemma and palea (Fig 1; S1A Fig). Although the glume and rachises were coloured slightly after heading, the albino phenotype of branches was observed with no significant alteration from heading to ripening stage (Fig 1B–1E; S1A Fig). The colour of the albino glumes turned light green at the heading stage and then turned purple later. In particular, the wpb1 showed even more severe defect under low temperature conditions (15–25°C); for example, the branches turned purple after heading in the late autumn in Nanning (S2C Fig). In addition, white streaks appeared in some young leaves of wpb1 at the tillering stage under low temperature conditions (S2A and S2B Fig).

Characterization of the phenotypes of <i>wpb1</i> and F<sub>2</sub> populations.
Fig. 1. Characterization of the phenotypes of wpb1 and F2 populations.
A-C. The panicles of NIP and wpb1 mutant. Young panicles examined 3-day before heading (A). Magnification of the panicle branch (B). Mature panicle branch (C). D-E. The panicles of parents and the individuals of F2 populations. Mature panicles (D). Mature branches (E). Bar, 3cm (A). 0.5cm (B). 5cm (C-D). 1cm (E).

Genetic analysis of the white branch phenotype

To understand the genetic basis of the white panicle branch phenotype in the wpb1 variety, NIP was crossed with wpb1 to generate F1 and F2 populations. The primary and secondary branches of F1 exhibited green colour that was comparable to that of NIP (S1B Fig). In the F2 population, green/white panicle branch segregation was observed from the phenotypic investigations during two rice seasons (S1C and S1D Fig). In 2017, among the 365 individuals of the F2 population, 90 exhibited white branches, and 275 showed green branches. In the F2 population of 2018, 63 showed white branches, and 196 had green branches. The chi-square test showed that the segregation ratio of green: white ≈ 3:1 (Table 1).

Tab. 1. Genetic analysis of white branch mutant.
Genetic analysis of white branch mutant.

To further confirm the heredity of white panicle branches in wpb1, the F2 individual plants with white streaked leaves, green glumes, and white branches were backcrossed to NIP to obtain a BC1F2 line. In line with the observations in the F1 and F2 populations, the branch colour of BC1F1 was green, and without the leaf white streaks. The colour phenotype of the BC1F2 population was also segregated, similar to that in the F2 population. Among a total of 206 plants, 151 showed green branches, and 55 had white branches. The chi-square test showed that the segregation ratio of the BC1F2 population was the same as that observed in the F2 population (Table 1). Taken together, the results indicated that the white panicle branch in wpb1 is controlled by a single recessive nucleic gene. Moreover, the phenotypes of white-streaked leaves were observed co-segregating with those of white panicle branches. In the F2 population, all the plants with white-streaked leaves had white panicle branches, and only some of the plants with white panicle branches had white streaked leaves. In the BC1F2 population (206 plants), white streaked leaves and white panicle branches were completely co-segregated.

The candidate loci of wpb1 were located on chromosome 1

Bulked segregant analysis coupled to whole genome sequencing is an efficient and rapid way to target the candidate loci for qualitative traits [32, 37]. In this study, genomic DNA of the G-pool (green branch pedicel) and W-pool (white branch pedicel) of the F2 population and a parent (wpb1) were sequenced to perform BSA analysis. A total of 32.443G raw data were obtained from the sequencing. Raw data were filtered to remove low quality data, and 32.402G of clean data was obtained for further analysis. The raw data of each sample ranged from 6055.43 to 15501.463 M. The average Q20 and Q30 were 96.5% and 94.61%, respectively. The GC content ranged from 44.61% to 46.53%. The percentage ranged from 97.97% to 98.2% of all samples mapped to the reference genome. The average coverage depth of the reference genome (excluding the N region) ranged from 12.84× to 34.14×. Subsequently, SNP and InDel calling was performed to identify SNP and InDel genotyping, and 1,096,326 SNP and 205,407 InDel polymorphic markers were obtained. Among them, 744,778 SNPs and 181,731 InDels were selected as informative polymorphic markers (frequency > 0.3, depth > 7, and both parents were present) to calculate the index and delta index. Two candidate intervals were located on chromosomes 1 and 3 by permutation test with 1000 permutations per test (Fig 2C). Twenty-seven SNPs and 85 InDels were selected as the candidate loci, whose indexes were close to 0.1 in the W-pool and close to 0.9 in the G-pool (Fig 2A and 2B). Eleven candidate genes that were altered by causing missense, premature termination, losing termination codon mutations or variable splicing sites were selected according to ANNOVAR annotations. Among them, 10 were located on chromosome 1 and 1 was located on chromosome 3 (S3 Table).

The preliminary mapping of <i>wpb1</i>.
Fig. 2. The preliminary mapping of wpb1.
A-C. Manhattan plot of the all (SNP and InDel) index and delta index. All index graphs of G-pool (A), W-pool (B) and the all index (C) from BSA-seq analysis. The X-axis represents the position of 12 chromosomes, and the Y-axis represents the All index. The all index was calculated based on a 1 Mb interval with a 1 kb sliding window. The delta all index graph (C) was plotted with a permutation test with 1000 permutations per test (P < 0.05). The blue line represents the confidence interval (C). D. Comparative genetic background analysis of the W-pool and G-pool of BC1F2 detected by 40k SNP array. The green square bar indicates the chromosomes. The grey lines indicate the SNP loci with homozygous genotypes AA (allele for white branch pedicel), red lines indicate the other homozygous genotypes BB, and the blue lines indicate the heterozygous genotypes AB. The candidate interval is on chromosome 1.

To validate the BSA result obtained from Illumina sequencing, a genetic background analysis was carried out using a 40k rice SNP array. Thirty green and 30 white panicle branched plants were selected from the BC1F2 population to construct the mixing pool. The result indicated that the only candidate interval was mapped to physical position from the 9.54 to 14.28 M region of chromosome 1, and the majority of the interval overlapped with the candidate interval mapped in the above BSA analysis (Fig 2D). Furthermore, the candidate mapped to chromosome 3 in Illumina BSA analysis was excluded. The interval mapped on chromosome 1 is the most likely candidate for the wpb1 locus.

Fine mapping of wpb1

To further fine map wpb1, a large-scale F2 population (2867 plants) was generated to narrow down the locus into a small region. Meanwhile, new molecular markers were developed in the preliminarily mapped interval by BSA analysis based on the sequencing data of NIP and the wpb1 variety. Genotyping was conducted using newly developed PCR markers (S1 Table). The linkage analysis of the phenotype was performed with marker genotypes. Four key informative recombinants were identified to narrow down the mapping region. Finally, the wpb1 locus was narrowed down to a 95-kb genomic interval with flanking markers M8 and M10, and this region contains 17 annotated genes (Fig 3, S4 Table).

Fine mapping of <i>wpb1</i>.
Fig. 3. Fine mapping of wpb1.
A. Preliminary mapping of wpb1. B. Physical map of the wpb1 locus. Two key recombinants delimited the mapping region. C. Putative ORFs in the mapping region.

The expressions of genes associated with Chl biosynthesis, photosynthesis, and chloroplast development were altered in wpb1

In general, the branches and the spikelets of the panicle turn green before heading with the maturation of chloroplasts. The albino phenotype of the wpb1 variety suggests that the processes of the chloroplasts development and/or Chl biosynthesis were impaired in its panicle branches, and therefore resulting in the inhibition of photosynthesis in panicle branches of the mutant. To validate this possibility, we next examined whether the related processes were compromised in wpb1 by comparing the relative expression levels of the genes involved in Chl biosynthesis, chloroplast development, and photosynthesis of wpb1 with those in WT (Nipponbare) and F2 plants. The expression levels of Chl biosynthesis-related genes [44], such as CAO1 (CHLOROPHYLLIDE A OXYGENASE1), PORA (encoding NADPH‐dependent protochlorophyllide oxidoreductase), and HEMA1 (encoding glutamyl tRNA reductase), was significantly downregulated in wpb1 in contrast to NIP. Similar regulation patterns were observed in the white panicle F2 plants. Furthermore, the expression of these genes in green branched plants was significantly higher than in the white branched F2 plant, which was consistent with the difference between their two parents (Fig 4A).

qRT-PCR analysis of genes associated with chloroplast biogenesis, chloroplast development, and photosynthesis in parents and F<sub>2</sub> populations.
Fig. 4. qRT-PCR analysis of genes associated with chloroplast biogenesis, chloroplast development, and photosynthesis in parents and F2 populations.
A. Chloroplast biogenesis-associated genes. B. Genes associated with chloroplast development. C. Photosynthesis-associated genes. The relative expression level of each gene in the mutant and F2 plants was analysed with qRT-PCR and normalised using the actin gene as an internal control, and its expression level in NIP plants was set to 1.0. * (P<0.05), ** (P<0.001).

For the chloroplast development‐associated genes, we investigated both nuclear‐encoded genes V1 [4], V2 (both encoding plastidal guanylate kinase) [6] and plastid genome‐encoded genes rpoA and rpoB (encoding the PEP core α, and β subunit, respectively) [42]. rpoB was significantly upregulated in the white panicle branch in wpb1 relative to the green panicle branch in NIP. Moreover, in line with this result, the expression of the gene in the white branched F2 plant was also significantly upregulated. It is worthy to note that rpoA, V1 and V2 were all downregulated in wpb1, whereas, in contrast, they were upregulated in the white branched F2 plant (Fig 4B).

In the case of the photosynthesis‐associated plastid genes, Cab1R and Cab2R (encoding light harvesting Chl a/b binding protein of PSII), psaA and psbA (encoding polypeptides of two different photosystems: PSI and PSII) were significantly suppressed in the wpb1 and white panicled F2 plants (Fig 4C).

Overall, the expression of Chl biosynthesis genes (HEMA1, CAO1, PORA), chloroplast development-associated genes (V1, V2, rpoA, rpoB) and photosynthesis genes (Cab1R, Cab2R, psaA, psbA) in wpb1 were significantly different from those in NIP. Both Chl biosynthesis and photosynthesis genes were significantly downregulated or severely inhibited. In addition, the gene rpoB for chloroplast development, was significantly upregulated, while V1 and rpoA were downregulated in wpb1 plants. These results indicated that the processes of chloroplast development, chlorophyll synthesis, and photosynthesis in branches of wpb1 were severely altered by the mutation of wpb1.

Although the expression patterns of the related genes were not completely consistent between F2 plants and their parents, they exhibited the similar trend of expression alterations between F2 plants and their parents except rpoA, V1, and V2 genes. For example, the differences in the expression of photosynthesis-associated genes between white panicle branches and green panicle branches in F2 plants was in agreement well with the case between wpb1 and NIP.

Therefore, we infer that the wpb1 gene may involve in the regulation pathway of the chlorophyll biosynthesis, chloroplast development, and photosynthesis.

Parenchymatous tissue cells of the white panicle branch have low chlorophyll contents in wpb1 plants

To verify our hypothesis, fluorescence microscopy was used to examine the chlorophyll fluorescence emitted from the panicle branches. In the leaves of NIP and wpb1 plant, the comparable levels of florescence were detected using fluorescence microscopy (S3 Fig). The white panicle branches of wpb1 and whitened branch individuals selected from the F2 population showed no or weak chlorophyll fluorescence emission (Fig 5C, 5D, 5G and 5H) in contrast to those in the NIP and green branch F2 plants (Fig 5A, 5B, 5E and 5F). However, the green branches of NIP and F2 plants showed bright fluorescence emissions.

Chlorophyll fluorescence examination of the rachis, branch, and spikelet by stereomicroscopy.
Fig. 5. Chlorophyll fluorescence examination of the rachis, branch, and spikelet by stereomicroscopy.
A-B. NIP in bright field (A) and RFP field (B). C-D. wpb1 mutant in bright field (C) and RFP field (D). E-F. F2-green in bright field (E) and RFP field (F). G-H. F2-white in bright field (G) and RFP field (H). Bright field: Exposure time 300 ms, ISO 200. RFP field: Exposure time 1 s, ISO 1600. Bar, 2 mm (A-D). 1.5 mm (E-H).

The results suggested that the chlorophyll contents in white panicle branches of wpb1 are rather low by comparing with those of NIP. The chlorophyll content measurement agreed with the results. The contents of chlorophyll a, chlorophyll b and total chlorophyll in the rachis of wpb1 were significantly lower than those in NIP (only 29.06%, 11.96%, and 25.33% of NIP, respectively). Similarly, they were only 0.0134 mg/g.FW, 0.0019 mg/g.FW, and 0.0153 mg/g.FW, respectively, in white panicle branches of wpb1, which were only 11.2%, 6.5% and 10.3% of those in NIP (green branch) (Fig 6A and 6B). Moreover, the chlorophyll contents in white and green panicle branches of F2 plants were similar to those in their parents. The chlorophyll a, chlorophyll b, and total chlorophyll contents in the samples of white branched F2 plants were extremely low, which were close to or lower than those of white branched wpb1. The chlorophyll contents in the samples of green branch F2 plants were close to or slightly lower than those of the parent NIP (Fig 6B). However, intriguingly, the chlorophyll contents of the rachises of white branched plants was only slightly lower than those in green branched plants (Fig 6A).

Measurement of the chlorophyll contents in parents and F<sub>2</sub> populations.
Fig. 6. Measurement of the chlorophyll contents in parents and F2 populations.
A. In rachis. B. In branch. All data are normalized by chlorophyll a of NIP, and its chlorophyll content in NIP was set to 1.0. * (P<0.05), ** (P<0.001).

The lower chlorophyll content in white panicle branches implied that chlorophyll synthesis was defective in parenchymatous tissue of wpb1 panicle branches. The section analysis showed that, compared with parenchymatous cells in NIP panicle branches where chloroplasts were well developed with clear green colour, rare or no green cells were observed in the white panicle branches of wpb1 (Fig 7A–7D).

Section of panicle branches of NIP and <i>wpb1</i>.
Fig. 7. Section of panicle branches of NIP and wpb1.
A, C. The cross-sectioned panicle branch of NIP. B, D. The cross-sectioned panicle branch of wpb1 mutant. The arrows indicate that the obvious distinction between the parenchymatous tissue of NIP and wpb1. Bar = 100 μm (A-B), 50 μm (C-D).

The results further supported the notion that the normal processes of chloroplast development and chlorophyll formation in parenchymatous tissues of white panicle branches of wpb1 is disturbed.

The chloroplast biogenesis is inhibited in the panicle branch of wpb1

To further confirm the failure in the chloroplast biogenesis in the panicle branches of wpb1, an ultra-thin sectioning of parenchymatous tissues where chloroplasts developed in the panicle branches were performed. In the white panicle branch of wpb1 plants, no chloroplasts were observed in parenchyma cells (Fig 8), and the chloroplast biogenesis seems completely being blocked. We suggested that the failure in chloroplast biogenesis in parenchymatous cells of panicle branches resulted in the albino phenotype of wpb1.

The comparison of the chloroplast development in parenchymatous cells of panicle branches of Nipponbare and <i>wpb1</i> using transmission electron microscopy.
Fig. 8. The comparison of the chloroplast development in parenchymatous cells of panicle branches of Nipponbare and wpb1 using transmission electron microscopy.
A. The images of Nipponbare. B. The magnification of the boxed region in A. C. The image of wpb1. D. The magnification of the boxed region in C. Bar = 2 μm (A, C), 500 nm (B, D). CP designates Chloroplast.

Discussion

Photosynthesis is an important biochemical reaction in higher plants. Normal chloroplast biogenesis in leaves of plants is of extremely important for photosynthesis. The defect in chloroplast development leads to tissue chlorosis or albinism. Thus far, many rice albino mutants have been reported in previous studies, mainly including leaf albino, seedling albino and panicle albino mutants [8, 4753]. Mutations in the al4 [54], al8, as11 [55], and asl3 [56] genes lead to leaf and seedling albinism. wlp1 [29], wlp2 [51], and wp3 [57] mutants exhibited panicle and glume albinism. Most of these mutants are unable to complete their life cycle, although a few of them can grow up under a specific environment. Most of these albino mutations result from defects in chloroplast development [19, 29, 41, 49, 51, 57], which is the same as wpb1.

In this study, a natural mutant with albino branches was found from a tropical japonica rice variety wpb1. The key feature of the phenotype that appeared in wpb1 was white panicle branches without chloroplasts, and no additional abnormal coloration was observed in other parts of the rice plants. Genetic analysis showed that wpb1 was controlled by a single recessive nuclear gene. Whole genome resequencing and BSA analysis were combined to preliminarily map the candidate interval for wpb1. Two intervals located on chromosome 1 and chromosome 3 were targeted as wpb1 candidates. Further, the one on chromosome 3 was excluded from the 40k SNP array analysis. Subsequently, by map-based cloning, wpb1 was narrowed down to a 95-kb interval flanked by M8 and M10 on chromosome 1 with 17 predicted genes in this region.

Several non-allelic genes with similar phenotypes have been cloned. The cloned wp1 gene, which is located on chromosome 7 and encodes a Val-tRNA synthetase (OsValRS2) with a single base changed, leads to albino phenotypes in seedlings and white panicles at heading stage. [23]. This mutant appears to have green leaves and glumes, green branches and spike axes. The development of seedlings with severe albinism was arrested and seedlings died at the 4-leaf stage. All observations above showed that there was an obvious difference in the branch colour phenotype between the wpb1 and wp1 mutants. However, the responses of the albino phenotypes to temperature change in the two mutants were similar. The two mutants showed aggravated albinism and a widened range of albino parts under low temperature. Another temperature-responsive albino mutant, wlp2, exhibited light green leaves and panicles in rice when the temperature was below 22°C. With increasing temperature (22–32°C), the albino phenotype appeared and aggravated significantly, resulting in the death of the rice plants [51]. The differences in albino phenotype between wlp2 mutant and wpb1 were also identified, such as the albino tissue, degree, and temperature response.

Li et al. cloned the WP3 that was related to the albino panicle [57]. The location of wp3 gene is close to the wpb1 interval on chromosome 1. wpb1 is located at 14-Kb upstream of WP3 (Os01g0306650). Both mutants showed albino panicles and albino streaked leaves; however, the differences between two genotypes were obvious. First, the wp3 mutant showed uniform albinism for the whole panicle and milky albinism (light green) throughout the panicle, with albino seedling. Furthermore, the variations are not observed in the coding sequences of the allele of WP3 gene between Nipponbare and wpb1 mutant (S4 Fig). The wpb1 mutant in this study showed branch albinism (complete albino), while albinism in the panicle rachis and glume shell were regulated by temperature. Albinism in the wpb1 mutant could extend from the panicle branch to the panicle rachis and glume shell with the decreasing of temperature (18–25°C). Second, no whitening phenotypes were observed in wpb1 at the seedling stage. Finally, the albinism of streaked leaves in the wp3 mutant shows maternal inheritance. The phenotype is not co-segregated with branch albino in wp3 plants. Whereas, wpb1 is a pleiotropic recessive nuclear gene with multiple effects for controlling the phenotypes of albino streaked leaf and albino panicles in wpb1 mutant. Therefore, we inferred that the wpb1 gene was a novel gene resulting in the albinism of rice panicle branches and white streaked leaves in rice.

The expression analysis showed the altered expressions of the genes involved in chlorophyll biosynthesis, chloroplast development, and the photosynthesis system, suggesting that the mutation of WPB1 might directly or indirectly impair the processes of chloroplast development and/or chlorophyll formation, and thereby resulting in the albino panicle branch phenotype of the variety. The expressions of chlorophyll synthesis genes in wpb1 were significantly downregulated, while their expressions in the white and green branches of F2 plants were not extremely induced. We speculated that the complicated recombinant events that occurred in F2 plants led to the discrepancy in the expression of chlorophyll biosynthesis-related genes between parental lines and their offspring. However, these discrepancies were unable to significantly affect the appearance of the branch albino phenotype in offspring with a homozygous recessive wpb1 gene. At the same time, the fact that the white streak leaves observed in the (NIP×wpb1) F2 generation only appeared in some but not all of the white panicle branched plants is noteworthy; in contrast, the white streak leaf phenotype and white branches were completely co-segregated in the BC1F2 population. We proposed that the white panicle branch and white streaked leaves were controlled by the same gene in the BC1F2 backcross population. Additional genes with synergistic/inhibited interaction that can reduce/eliminate or aggravate white streaks in leaves to a certain extent in F2 plants were lost in selecting backcrosses. Therefore, wpb1 deserves more focus in our further studies.

In spite of many research works have been done on the biogenesis of chloroplasts, the mechanism of chloroplast development remains elusive [58]. Albino mutants provide excellent materials for exploring the mechanism underlying the development of chloroplast. Therefore, the study of the mutant wpb1 is of great significance. Further cloning and in-depth functional analysis of the wpb1 gene will help to understand the regulatory mechanism of chloroplast development in rice branches. For the application of this genetic material, the underlying gene wpb1 can be transformed into two-line male sterile lines as a colour marker for field trial investigation, which is used to prevent and eliminate the confusion to ensure hybrid purity in the breeding of two-line materials and in the seed production of hybrid rice.

Supporting information

S1 Fig [tif]
The comparison of the panicle branch coloration phenotypes of Nipponbare, , and their offspring.

S2 Fig [top]
Phenotypic characterization of the mutant.

S3 Fig [tif]
The chlorophyll fluorescence of the leaf by stereomicroscope.

S4 Fig [tif]
The comparison of the coding sequencing of two alleles of gene in Nipponbare and .

S1 Table [docx]
List of fine mapping primers used in this study.

S2 Table [docx]
List of qPCR primers used in this study.

S3 Table [docx]
Predicted genes according to BSA-Seq and ANNOVAR annotations.

S4 Table [docx]
The annotations of the candidate genes in the mapping interval.


Zdroje

1. Fromme P, Melkozernov A, Jordan P, Krauss N. Structure and function of photosystem I: interaction with its soluble electron carriers and external antenna systems. FEBS letters. 2003;555(1):40–4. Epub 2003/11/25. doi: 10.1016/s0014-5793(03)01124-4 14630316.

2. Breinholt V, Schimerlik M, Dashwood R, Bailey G. Mechanisms of chlorophyllin anticarcinogenesis against aflatoxin B1: complex formation with the carcinogen. Chemical research in toxicology. 1995;8(4):506–14. Epub 1995/06/01. 7548730.

3. Wicke S, Schneeweiss GM, dePamphilis CW, Muller KF, Quandt D. The evolution of the plastid chromosome in land plants: gene content, gene order, gene function. Plant molecular biology. 2011;76(3–5):273–97. Epub 2011/03/23. doi: 10.1007/s11103-011-9762-4 21424877; PubMed Central PMCID: PMC3104136.

4. Kusumi K, Mizutani A, Nishimura M, Iba K. A virescent gene V1 determines the expression timing of plastid genes for transcription/translation apparatus during early leaf development in rice. The Plant Journal. 1997;12(6):1241–50. doi: 10.1046/j.1365-313x.1997.12061241.x

5. Kusumi K, Komori H, Satoh H, Iba K. Characterization of a zebra mutant of rice with increased susceptibility to light stress. Plant & cell physiology. 2000;41(2):158–64. Epub 2000/05/05. doi: 10.1093/pcp/41.2.158 10795309.

6. Sugimoto H, Kusumi K, Noguchi K, Yano M, Yoshimura A, Iba K. The rice nuclear gene, VIRESCENT 2, is essential for chloroplast development and encodes a novel type of guanylate kinase targeted to plastids and mitochondria. The Plant journal: for cell and molecular biology. 2007;52(3):512–27. Epub 2007/08/31. doi: 10.1111/j.1365-313X.2007.03251.x 17727616.

7. Golden SS, Brusslan J, Haselkorn R. Expression of a family of psbA genes encoding a photosystem II polypeptide in the cyanobacterium Anacystis nidulans R2. The EMBO journal. 1986;5(11):2789–98. Epub 1986/11/01. 3098559; PubMed Central PMCID: PMC1167224.

8. Sundberg E, Slagter JG, Fridborg I, Cleary SP, Robinson C, Coupland G. ALBINO3, an Arabidopsis nuclear gene essential for chloroplast differentiation, encodes a chloroplast protein that shows homology to proteins present in bacterial membranes and yeast mitochondria. The Plant Cell. 1997;9:717–30. doi: 10.1105/tpc.9.5.717 9165749

9. Zhou K, Ren Y, Lv J, Wang Y, Liu F, Zhou F, et al. Young Leaf Chlorosis 1, a chloroplast-localized gene required for chlorophyll and lutein accumulation during early leaf development in rice. Planta. 2013;237(1):279–92. doi: 10.1007/s00425-012-1756-1 23053539

10. Bae CH, Abe T, Matsuyama T, Fukunishi N, Nagata N, Nakano T, et al. Regulation of chloroplast gene expression is affected in ali, a novel tobacco albino mutant. Ann Bot. 2001;88(4):545–53. doi: 10.1006/anbo.2001.1495 WOS:000171549300004.

11. Hou DY, Xu H, Du GY, Lin JT, Duan M, Guo AG. Proteome analysis of chloroplast proteins in stage albinism line of winter wheat (triticum aestivum) FA85. BMB reports. 2009;42(7):450–5. Epub 2009/08/01. doi: 10.5483/bmbrep.2009.42.7.450 19643044.

12. Schmitz-Linneweber C, Williams-Carrier RE, Williams-Voelker PM, Kroeger TS, Vichas A, Barkan A. A pentatricopeptide repeat protein facilitates the trans-splicing of the maize chloroplast rps12 pre-mRNA. Plant Cell. 2006;18(10):2650–63. Epub 2006/10/17. doi: 10.1105/tpc.106.046110 17041147; PubMed Central PMCID: PMC1626628.

13. Li L, Xiong Y, Ouyang L, Peng X, Chen X, He X, et al. Identification and gene mapping of white stripe leaf and white panicle mutant wlp6 in rice. Chinese Journal of Rice Science. 2018;32(6):538–48. doi: 10.16819/j.1001-7216.2018.7144

14. Yoo SC, Cho SH, Sugimoto H, Li J, Kusumi K, Koh HJ, et al. Rice virescent3 and stripe1 encoding the large and small subunits of ribonucleotide reductase are required for chloroplast biogenesis during early leaf development. Plant physiology. 2009;150(1):388–401. Epub 2009/03/20. doi: 10.1104/pp.109.136648 19297585; PubMed Central PMCID: PMC2675711.

15. Kusumi K, Sakata C, Nakamura T, Kawasaki S, Yoshimura A, Iba K. A plastid protein NUS1 is essential for build-up of the genetic system for early chloroplast development under cold stress conditions. The Plant journal: for cell and molecular biology. 2011;68(6):1039–50. Epub 2011/10/11. doi: 10.1111/j.1365-313X.2011.04755.x 21981410.

16. Dong H, Fei GL, Wu CY, Wu FQ, Sun YY, Chen MJ, et al. A rice virescent-yellow leaf mutant reveals new insights into the role and assembly of plastid caseinolytic protease in higher plants. Plant Physiol. 2013;162(4):1867–80. doi: 10.1104/pp.113.217604 23803583; PubMed Central PMCID: PMC3729767.

17. Sugimoto H, Kusumi K, Tozawa Y, Yazaki J, Kishimoto N, Kikuchi S, et al. The virescent-2 mutation inhibits translation of plastid transcripts for the plastid genetic system at an early stage of chloroplast differentiation. Plant & cell physiology. 2004;45(8):985–96. Epub 2004/09/10. doi: 10.1093/pcp/pch111 15356324.

18. Tan J, Tan Z, Wu F, Sheng P, Heng Y, Wang X, et al. A Novel Chloroplast-Localized Pentatricopeptide Repeat Protein Involved in Splicing Affects Chloroplast Development and Abiotic Stress Response in Rice. Molecular Plant. 2014;7(8):1329–49. doi: 10.1093/mp/ssu054 24821718

19. Wang Y, Ren Y, Zhou K, Liu L, Wang J, Xu Y, et al. WHITE STRIPE LEAF4 Encodes a Novel P-Type PPR Protein Required for Chloroplast Biogenesis during Early Leaf Development. Frontiers in plant science. 2017;8:1116. Epub 2017/07/12. doi: 10.3389/fpls.2017.01116 28694820; PubMed Central PMCID: PMC5483476.

20. Wang L, Wang C, Wang Y, Niu M, Ren Y, Zhou K, et al. WSL3, a component of the plastid-encoded plastid RNA polymerase, is essential for early chloroplast development in rice. Plant molecular biology. 2016;92(4–5):1–15.

21. Zhou K, Ren Y, Feng Z, Ying W, Long Z, Jia L, et al. Young Seedling Stripe1 encodes a chloroplast nucleoid-associated protein required for chloroplast development in rice seedlings. Planta. 2017;245(1):45–60. doi: 10.1007/s00425-016-2590-7 27578095

22. Sanchez AC, Khush GS. Chromosomal location of some marker genes in rice using the primary trisomics. Journal of Heredity. 1994;85(4):297–300.

23. Wang Y, Wang C, Zheng M, Lyu J, Xu Y, Li X, et al. WHITE PANICLE1, a Val-tRNA Synthetase Regulating Chloroplast Ribosome Biogenesis in Rice, Is Essential for Early Chloroplast Development. Plant physiology. 2016;170(4):2110–23. Epub 2017/10/19. doi: 10.1093/jxb/erx332 10.1104/pp.15.01949. 26839129.

24. Chen Y. Genetic Analysis and Fine Mapping of Gene in Mutant Rice With Stripe White Leaf and White Panicle. Journal of Nuclear Agricultural Sciences. 2015;29(7):1246–52.

25. Kunneng Z, Jiafa X, Tingchen MA, Yuanlei W, Zefu LI. Mapping and Mutation Analysis of Stripe Leaf and White Panicle Gene SLWP in Rice. Chinese Journal of Rice Science. 2018;32(4):325–34.

26. Zeng Y, Wei X, Rui Z, Huang J, Xu X. Agronomic Character Analysis and Gene Mapping of An Albino Mutant in Rice. Molecular Plant Breeding. 2018;16(6):1955–61.

27. Chen DX, Ting LI, Guang-Lin QU, Huang WJ, Zhong-Quan HE, Shi-Gui LI. Characterization and Genetic Analysis of a Streaked and Abnormal Glumous Flower Mutant st-fon. Chinese Journal of Rice Science. 2012;26(6):677–85.

28. Wang XW, Jiang YD, Liao HX, Bo Y, Zou SY, Zhu XY, et al. Identification and Gene Fine Mapping of White Panicle Mutant wp4 in Oryza sativa. Acta Agronomica Sinica. 2015;41(6):838–44.

29. Song J, Wei X, Shao G, Sheng Z, Chen D, Liu C, et al. The rice nuclear gene WLP1 encoding a chloroplast ribosome L13 protein is needed for chloroplast development in rice grown under low temperature conditions. Plant molecular biology. 2014;84(3):301–14. doi: 10.1007/s11103-013-0134-0 24132771

30. Jin Y, Liu HQ, Wang YZ. Genetic Analysis and Gene Mapping of a White Striped Leaf and White Panicle Mutant in Rice. Chinese Journal of Rice Science. 2011;25(5):461–6.

31. Zhang Z, Cui X, Wang Y, Wu J, Gu X, Lu T. The RNA Editing Factor WSP1 Is Essential for Chloroplast Development in Rice. Mol Plant. 2017;10(1):86–98. Epub 2016/09/14. doi: 10.1016/j.molp.2016.08.009 27622591.

32. Michelmore RW, Paran I, Kesseli RV. Identification of markers linked to disease-resistance genes by bulked segregant analysis: a rapid method to detect markers in specific genomic regions by using segregating populations. Proceedings of the National Academy of Sciences of the United States of America. 1991;88(21):9828–32. Epub 1991/11/01. doi: 10.1073/pnas.88.21.9828 1682921; PubMed Central PMCID: PMC52814.

33. Takagi H, Abe A, Yoshida K, Kosugi S, Natsume S, Mitsuoka C, et al. QTL-seq: rapid mapping of quantitative trait loci in rice by whole genome resequencing of DNA from two bulked populations. Plant J. 2013;74(1):174–83. doi: 10.1111/tpj.12105 23289725.

34. Schneeberger K, Ossowski S, Lanz C, Juul T, Petersen AH, Nielsen KL, et al. SHOREmap: simultaneous mapping and mutation identification by deep sequencing. Nature methods. 2009;6(8):550–1. Epub 2009/08/01. doi: 10.1038/nmeth0809-550 19644454.

35. Sun J, Yang L, Wang J, Liu H, Zheng H, Xie D, et al. Identification of a cold-tolerant locus in rice (Oryza sativa L.) using bulked segregant analysis with a next-generation sequencing strategy. Rice (New York, NY). 2018;11(1):24–. doi: 10.1186/s12284-018-0218-1 29671148.

36. Abe A, Kosugi S, Yoshida K, Natsume S, Takagi H, Kanzaki H, et al. Genome sequencing reveals agronomically important loci in rice using MutMap. Nature biotechnology. 2012;30(2):174–8. Epub 2012/01/24. doi: 10.1038/nbt.2095 22267009.

37. Klein H, Xiao Y, Conklin PA, Govindarajulu R, Kelly JA, Scanlon MJ, et al. Bulked-Segregant Analysis Coupled to Whole Genome Sequencing (BSA-Seq) for Rapid Gene Cloning in Maize. G3: Genes|Genomes|Genetics. 2018;8:3583–92. doi: 10.1534/g3.118.200499 30194092

38. Li H, Durbin R. Fast and accurate short read alignment with Burrows-Wheeler transform. Bioinformatics (Oxford, England). 2009;25(14):1754–60. Epub 2009/05/20. doi: 10.1093/bioinformatics/btp324 19451168; PubMed Central PMCID: PMC2705234.

39. McKenna A, Hanna M, Banks E, Sivachenko A, Cibulskis K, Kernytsky A, et al. The Genome Analysis Toolkit: a MapReduce framework for analyzing next-generation DNA sequencing data. Genome research. 2010;20(9):1297–303. Epub 2010/07/21. doi: 10.1101/gr.107524.110 20644199; PubMed Central PMCID: PMC2928508.

40. Wang K, Li M, Hakonarson H. ANNOVAR: functional annotation of genetic variants from high-throughput sequencing data. Nucleic acids research. 2010;38(16):e164. Epub 2010/07/06. doi: 10.1093/nar/gkq603 20601685; PubMed Central PMCID: PMC2938201.

41. Lin D, Jiang Q, Zheng K, Chen S, Zhou H, Gong X, et al. Mutation of the rice ASL2 gene encoding plastid ribosomal protein L21 causes chloroplast developmental defects and seedling death. Plant Biology. 2015;17(3):599–607. doi: 10.1111/plb.12271 25280352

42. Hiratsuka J, Shimada H, Whittier R, Ishibashi T, Sakamoto M, Mori M, et al. The complete sequence of the rice (Oryza sativa) chloroplast genome: intermolecular recombination between distinct tRNA genes accounts for a major plastid DNA inversion during the evolution of the cereals. Molecular & general genetics: MGG. 1989;217(2–3):185–94. Epub 1989/06/01. doi: 10.1007/bf02464880 2770692.

43. Kyozuka J, McElroy D, Hayakawa T, Xie Y, Wu R, Shimamoto K. Light-regulated and cell-specific expression of tomato rbcS-gusA and rice rbcS-gusA fusion genes in transgenic rice. Plant physiology. 1993;102(3):991–1000. Epub 1993/07/01. doi: 10.1104/pp.102.3.991 8278540; PubMed Central PMCID: PMC158873.

44. Wu Z, Zhang X, He B, Diao L, Sheng S, Wang J, et al. A chlorophyll-deficient rice mutant with impaired chlorophyllide esterification in chlorophyll biosynthesis. Plant physiology. 2007;145(1):29–40. Epub 2007/05/31. doi: 10.1104/pp.107.100321 17535821; PubMed Central PMCID: PMC1976586.

45. Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods (San Diego, Calif). 2001;25(4):402–8. Epub 2002/02/16. doi: 10.1006/meth.2001.1262 11846609.

46. Qiu N, Wang X, Yang F, Yang X, Wen Y, Diao R, et al. Fast Extraction and Precise Determination of Chlorophyll. Chinese Bulletin of Botany. 2016;51(5):667–78.

47. Su N, Hu ML, Wu DX, Wu FQ, Fei GL, Lan Y, et al. Disruption of a rice pentatricopeptide repeat protein causes a seedling-specific albino phenotype and its utilization to enhance seed purity in hybrid rice production. Plant physiology. 2012;159(1):227–38. Epub 2012/03/21. doi: 10.1104/pp.112.195081 22430843; PubMed Central PMCID: PMC3366715.

48. Hayashi-Tsugane M, Takahara H, Ahmed N, Himi E, Takagi K, Iida S, et al. A mutable albino allele in rice reveals that formation of thylakoid membranes requires the SNOW-WHITE LEAF1 gene. Plant & cell physiology. 2014;55(1):3–15. Epub 2013/10/24. doi: 10.1093/pcp/pct149 24151203.

49. Liu C, Zhu H, Xing Y, Tan J, Chen X, Zhang J, et al. Albino Leaf 2 is involved in the splicing of chloroplast group I and II introns in rice. Journal of experimental botany. 2016;67(18):5339–47. Epub 2016/08/21. doi: 10.1093/jxb/erw296 27543605; PubMed Central PMCID: PMC5049385.

50. Zhang Z, Tan J, Shi Z. Albino Leaf1 That Encodes the Sole Octotricopeptide Repeat Protein Is Responsible for Chloroplast Development. Plant physiology. 2016;171(2):1182–91. doi: 10.1104/pp.16.00325 27208287.

51. Lv Y, Shao G, Qiu J, Jiao G, Sheng Z, Xie L, et al. White Leaf and Panicle 2, encoding a PEP-associated protein, is required for chloroplast biogenesis under heat stress in rice. J Exp Bot. 2017;68(18):5147–60. Epub 2017/10/19. doi: 10.1093/jxb/erx332 29045742; PubMed Central PMCID: PMC5853965.

52. Zeng X, Tang R, Guo H, Ke S, Teng B, Hung YH, et al. A naturally occurring conditional albino mutant in rice caused by defects in the plastid-localized OsABCI8 transporter. Plant molecular biology. 2017;94(1–2):137–48. Epub 2017/03/13. doi: 10.1007/s11103-017-0598-4 28285416.

53. Zhang T, Feng P, Li Y, Yu P, Yu G, Sang X, et al. VIRESCENT-ALBINO LEAF 1 regulates leaf colour development and cell division in rice. Journal of experimental botany. 2018;69(20):4791–804. Epub 2018/08/14. doi: 10.1093/jxb/ery250 30102358; PubMed Central PMCID: PMC6137968.

54. Iwata Omura NaT. Linkage studies in rice (Oryza sativa L.). Some albino genes and their linkage relation with marker genes. Sci Bull Fac Agr Kyushu Univ. 1978;33(1):11–8.

55. Gong X, Jiang Q, Xu J, Zhang J, Teng S, Lin D, et al. Disruption of the rice plastid ribosomal protein S20 leads to chloroplast developmental defects and seedling lethality. G3: Genes Genomes Genetics. 2013;3(10):1769–77. doi: 10.1534/g3.113.007856 23979931

56. Lin D, Gong X, Jiang Q, Zheng K, Zhou H, Xu J, et al. The rice ALS3 encoding a novel pentatricopeptide repeat protein is required for chloroplast development and seedling growth. Rice (New York, NY). 2015;8:17-. doi: 10.1186/s12284-015-0050-9 25859292.

57. Li H, Ji G, Wang Y, Qian Q, Xu J, Sodmergen, et al. WHITE PANICLE3, a Novel Nucleus-Encoded Mitochondrial Protein, Is Essential for Proper Development and Maintenance of Chloroplasts and Mitochondria in Rice. Frontiers in plant science. 2018;9:762–. doi: 10.3389/fpls.2018.00762 29928286.

58. van Wijk KJ, Baginsky S. Plastid proteomics in higher plants: current state and future goals. Plant Physiol. 2011;155(4):1578–88. Epub 2011/02/26. doi: 10.1104/pp.111.172932 21350036; PubMed Central PMCID: PMC3091083.


Článok vyšiel v časopise

PLOS One


2019 Číslo 9
Najčítanejšie tento týždeň
Najčítanejšie v tomto čísle
Kurzy

Zvýšte si kvalifikáciu online z pohodlia domova

Získaná hemofilie - Povědomí o nemoci a její diagnostika
nový kurz

Eozinofilní granulomatóza s polyangiitidou
Autori: doc. MUDr. Martina Doubková, Ph.D.

Všetky kurzy
Prihlásenie
Zabudnuté heslo

Zadajte e-mailovú adresu, s ktorou ste vytvárali účet. Budú Vám na ňu zasielané informácie k nastaveniu nového hesla.

Prihlásenie

Nemáte účet?  Registrujte sa

#ADS_BOTTOM_SCRIPTS#