Xiao-Meng Wu

Discovery and comparative profiling of microRNAs in a sweet orange red-flesh mutant and its wild type

BackgroundRed-flesh fruit is absent from common sweet orange varieties, but is more preferred by consumers due to its visual attraction and nutritional properties. Our previous researches on a spontaneous red-flesh mutant revealed that the trait is caused by lycopene accumulation and is regulated by both transcriptional and post-transcriptional mechanisms. However, the knowledge on post-transcriptional regulation of lycopene accumulation in fruits is rather limited so far.ResultsWe used Illumina sequencing method to identify and quantitatively profile small RNAs on the red-flesh sweet orange mutant and its wild type. We identified 85 known miRNAs belonging to 48 families from sweet orange. Comparative profiling revealed that 51 known miRNAs exhibited significant expression differences between mutant (MT) and wild type (WT). We also identified 12 novel miRNAs by the presence of mature miRNAs and corresponding miRNA*s in the sRNA libraries. Comparative analysis showed that 9 novel miRNAs are differentially expressed between WT and MT. Target predictions of the 60 differential miRNAs resulted 418 target genes in sweet orange. GO and KEGG annotation revealed that high ranked miRNA-target genes are those implicated in transcription regulation, protein modification and photosynthesis. The expression profiles of target genes involved in carotenogenesis and photosynthesis were further confirmed to be complementary to the profiles of corresponding miRNAs in WT and MT.ConclusionThis study comparatively characterized the miRNAomes between the red-flesh mutant and the wild type, the results lay a foundation for unraveling the miRNA-mediated molecular processes that regulate lycopene accumulation in the sweet orange red-flesh mutant.

Stage and tissue-specific modulation of ten conserved miRNAs and their targets during somatic embryogenesis of Valencia sweet orange

Somatic embryogenesis (SE) is a remarkable process of plant somatic cells developing into an embryo capable of forming a complete plant. MiRNAs play important roles in plant development by regulating expression of their target genes, but its function in SE has rarely been studied. Herein, ten conserved miRNAs with critical functions in plant development are detected by stem-loop qRT-PCR in the SE system of Valencia sweet orange. Sixteen unigenes from citrus are predicted to be targeted by six of the miRNAs. Cleavage sites on 15 of these target mRNAs are mapped by 5′RACE, of which ten are reported in this study. Transcript abundances of the 16 target unigenes are detected by qRT-PCR during SE process. Stage and tissue-specific expressions of miRNAs and their targets suggest their possible modulation on SE of citrus callus: miR156, 168 and 171 exert regulatory function during somatic embryo induction process; miR159, 164, 390 and 397 are related to globular-shaped embryo formation; miR166, 167 and 398 are required for cotyledon-shaped embryo morphogenesis; in addition, target genes of miR164, 166 and 397 are associated with SE disability of nonembryogenic callus. Exploration of miRNA-mediated modulation on SE is expected to provide new insights into plant cell totipotency, as well as how to maintain and enhance the embryogenic capacity of somatic cells.

Comparative Transcript Profiling of a Male Sterile Cybrid Pummelo and Its Fertile Type Revealed Altered Gene Expression Related to Flower Development

Male sterile and seedless characters are highly desired for citrus cultivar improvement. In our breeding program, a male sterile cybrid pummelo, which could be considered as a variant of male fertile pummelo, was produced by protoplast fusion. Herein, ecotopic stamen primordia initiation and development were detected in this male sterile cybrid pummelo. Histological studies revealed that the cybrid showed reduced petal development in size and width, and retarded stamen primordia development. Additionally, disorganized cell proliferation was also detected in stamen-like structures (fused to petals and/or carpel). To gain new insight into the underlying mechanism, we compared, by RNA-Seq analysis, the nuclear gene expression profiles of floral buds of the cybrid with that of fertile pummelo. Gene expression profiles which identified a large number of differentially expressed genes (DEGs) between the two lines were captured at both petal primordia and stamen primordia distinguishable stages. For example, nuclear genes involved in nucleic acid binding and response to hormone synthesis and metabolism, genes required for floral bud identification and expressed in particular floral whorls. Furthermore, in accordance with flower morphology of the cybrid, expression of PISTILLATA (PI) was reduced in stamen-like structures, even though it was restricted to correct floral whorls. Down-regulated expression of APETALA3 (AP3) coincided with that of PI. These finding indicated that, due to their whorl specific effects in flower development, citrus class-B MADS-box genes likely constituted ‘perfect targets’ for CMS retrograde signaling, and that dysfunctional mitochondria seemed to cause male sterile phenotype in the cybrid pummelo.

Comparative metabolic and transcriptional analysis of a doubled diploid and its diploid citrus rootstock (C. junos cv. Ziyang xiangcheng) suggests its potential value for stress resistance improvement

BackgroundPolyploidy has often been considered to confer plants a better adaptation to environmental stresses. Tetraploid citrus rootstocks are expected to have stronger stress tolerance than diploid. Plenty of doubled diploid citrus plants were exploited from diploid species for citrus rootstock improvement. However, limited metabolic and molecular information related to tetraploidization is currently available at a systemic biological level. This study aimed to evaluate the occurrence and extent of metabolic and transcriptional changes induced by tetraploidization in Ziyang xiangcheng (Citrus junos Sieb. ex Tanaka), which is a special citrus germplasm native to China and widely used as an iron deficiency tolerant citrus rootstock.ResultsDoubled diploid Ziyang xiangcheng has typical morphological and anatomical features such as shorter plant height, larger and thicker leaves, bigger stomata and lower stomatal density, compared to its diploid parent. GC-MS (Gas chromatography coupled to mass spectrometry) analysis revealed that tetraploidization has an activation effect on the accumulation of primary metabolites in leaves; many stress-related metabolites such as sucrose, proline and γ-aminobutyric acid (GABA) was remarkably up-regulated in doubled diploid. However, LC-QTOF-MS (Liquid chromatography quadrupole time-of-flight mass spectrometry) analysis demonstrated that tetraploidization has an inhibition effect on the accumulation of secondary metabolites in leaves; all the 33 flavones were down-regulated while all the 6 flavanones were up-regulated in 4x. By RNA-seq analysis, only 212 genes (0.8% of detected genes) are found significantly differentially expressed between 2x and 4x leaves. Notably, those genes were highly related to stress-response functions, including responses to salt stress, water and abscisic acid. Interestingly, the transcriptional divergence could not explain the metabolic changes, probably due to post-transcriptional regulation.ConclusionTaken together, tetraploidization induced considerable changes in leaf primary and secondary metabolite accumulation in Ziyang xiangcheng. However, the effect of tetraploidization on transcriptome is limited. Compared to diploid, higher expression level of stress related genes and higher content of stress related metabolites in doubled diploid could be beneficial for its stress tolerance.

Genome-wide comparison of microRNAs and their targeted transcripts among leaf, flower and fruit of sweet orange.

BackgroundIn plants, microRNAs (miRNAs) regulate gene expression mainly at the post-transcriptional level. Previous studies have demonstrated that miRNA-mediated gene silencing pathways play vital roles in plant development. Here, we used a high-throughput sequencing approach to characterize the miRNAs and their targeted transcripts in the leaf, flower and fruit of sweet orange.ResultsA total of 183 known miRNAs and 38 novel miRNAs were identified. An in-house script was used to identify all potential secondary siRNAs derived from miRNA-targeted transcripts using sRNA and degradome sequencing data. Genome mapping revealed that these miRNAs were evenly distributed across the genome with several small clusters, and 69 pre-miRNAs were co-localized with simple sequence repeats (SSRs). Noticeably, the loop size of pre-miR396c was influenced by the repeat number of CUU unit. The expression pattern of miRNAs among different tissues and developmental stages were further investigated by both qRT-PCR and RNA gel blotting. Interestingly, Csi-miR164 was highly expressed in fruit ripening stage, and was validated to target a NAC transcription factor. This study depicts a global picture of miRNAs and their target genes in the genome of sweet orange, and focused on the comparison among leaf, flower and fruit tissues.ConclusionsThis study provides a global view of miRNAs and their target genes in different tissue of sweet orange, and focused on the identification of miRNA involved in the regulation of fruit ripening. The results of this study lay a foundation for unraveling key regulators of orange fruit development and ripening on post-transcriptional level.

Transcriptional profiling of genes involved in embryogenic, non-embryogenic calluses and somatic embryogenesis of Valencia sweet orange by SSH-based microarray

Somatic embryogenesis (SE) is a most promising technology that is used for in vitro germplasm conservation and genetic improvement via biotechnological approaches in citrus. Herein, three suppression subtractive hybridization (SSH) libraries were constructed using calluses of Citrus sinensis cv. ‘Valencia’ to explore the molecular mechanisms that underlie the SE in citrus. A total of 880 unisequences were identified by microarray screening based on these three SSH libraries. Gene ontology analysis of the differentially expressed genes indicated that nucleolus associated regulation and biogenesis processes, hormone signal transduction, and stress factors might be involved in SE. Transcription factors might also play an important role. LEC1/B3 domain regulatory network genes (LEC1, L1L, FUS3, ABI3, and ABI5) were isolated in citrus SE. Some new transcription factors associated with citrus SE, like a B3 domain containing gene and HB4, were identified. To understand the influence of these isolated genes on SE competence, their expression profiles were compared among callus lines of seven citrus cultivars with different SE competence. The expression dynamics suggested that these genes could be necessary for the SE initiation and might play a role in embryogenic competence maintenance in different cultivars. On the basis of gene expression profiles, an overview of major physiological and biosynthesis processes at different developmental stages during citrus SE is presented. For the first time, these data provide a global resource for transcriptional events important for SE in citrus, and the specific genes offer new information for further investigation on citrus SE maintenance and development.

Selection and validation of suitable reference genes for mRNA qRT-PCR analysis using somatic embryogenic cultures, floral and vegetative tissues in citrus

Accuracy of the quantitative real-time reverse transcription-PCR (qRT-PCR) depends on the stability of the reference gene(s), i.e. housekeeping gene(s) used for data normalization. Recent studies have shown that the expression of common reference genes can vary considerably in certain experimental conditions. However, reference genes of qRT-PCR in fruit trees have not been well identified. In this study, stability of expression of ten potential reference genes in citrus, including CitACT7, CiteIF-1A, CiteIF4α, CitHistone H3, CitHistone H4, CitTUA3, CitTUB8, CitUBL5, CitUBQ1 and CitUBQ14 was assessed. Furthermore, this was validated by qRT-PCR in diverse sets of biological samples, including embryonic callus at seven stages, embryos maintained at three different temperatures, five distinct plant organs, four floral tissues and four stages of flower development. Three distinct statistical algorithms, geNorm, NormFinder and Bestkeeper, were used to evaluate the expression stability of the candidate reference genes. The three outputs were merged by means of a non-weighted unsupervised rank aggregation method. GeNorm was also used to determine both the optimal number and the best combination of reference genes for each experimental set. The expression of CitUBQ1 was the most stable one across the set of all samples, flower developmental stages and somatic embryogenesis process under two conditions i.e. different temperature treatment and normal temperature treatment. CitUBQ14 presented more stable expression in different plant organs and floral tissues. CitHistone H3 was the most unsuitable reference gene in many citrus sample sets. In addition, the relative gene expression profile of citrus receptor-like kinase gene CitSERK1-like was conducted to confirm the validity of the reference genes in this study. Taken together, this study identified the reference genes that are most suitable for normalizing the gene expression data in citrus. These results provide guidelines for the selection of reference gene(s) under different experimental conditions, and will benefit future research on more accurate gene expression studies in a wide variety of samples in citrus.

Identification and characterization of microRNAs from citrus expressed sequence tags

MicroRNAs (miRNAs) are a group of single-stranded noncoding RNAs with general size of 21–24 nucleotides, which negatively regulate gene expression posttranscriptionally by repressing gene translation or degrading targeted mRNAs. Despite the important functions of miRNAs in plants, little is known about miRNAs in citrus. Here we present a study of bioinformatics identification of microRNA precursors in citrus by comparing known plant miRNAs against 560,271 citrus ESTs. Seventy-eight ESTs from ten citrus species and three hybrids were identified as putative miRNA precursors, encoding 51 unique miRNA sequences, representing 28 miRNA families. Blastn search of the putative miRNAs against citrus unigenes and ESTs was performed to identify the target genes. As a result, 36 unigenes and 77 ESTs were identified as putative targets of 25 citrus miRNA families. The putative targets are mainly transcription factors and play important roles in development, metabolism, and stress resistance. To validate the predicted miRNAs, qRT-PCR was applied to detect the tissue-specific expression of nine putative miRNAs in Citrus sinensis cv. Valencia. The cleavage sites on five mRNAs targeted by three miRNA families were mapped by 5′RACE. This study provided information on citrus miRNA precursors, mature miRNAs, and miRNA targets and is helpful for future research of miRNA function in citrus.

High-throughput sequencing and degradome analysis reveal altered expression of miRNAs and their targets in a male-sterile cybrid pummelo (Citrus grandis)

BackgroundG1 + HBP is a male sterile cybrid line with nuclear genome from Hirado Buntan pummelo (C. grandis Osbeck) (HBP) and mitochondrial genome from “Guoqing No.1” (G1, Satsuma mandarin), which provides a good opportunity to study male sterility and nuclear-cytoplasmic cross talk in citrus. High-throughput sRNA and degradome sequencing were applied to identify miRNAs and their targets in G1 + HBP and its fertile type HBP during reproductive development.ResultsA total of 184 known miRNAs, 22 novel miRNAs and 86 target genes were identified. Some of the targets are transcription factors involved in floral development, such as auxin response factors (ARFs), SQUAMOSA promoter binding protein box (SBP-box), MYB, basic region-leucine zipper (bZIP), APETALA2 (AP2) and transport inhibitor response 1 (TIR1). Eight target genes were confirmed to be sliced by corresponding miRNAs using 5’ RACE technology. Based on the sequencing abundance, 42 differentially expressed miRNAs between sterile line G1 + HBP and fertile line HBP were identified. Differential expression of miRNAs and their target genes between two lines was validated by quantitative RT-PCR, and reciprocal expression patterns between some miRNAs and their targets were demonstrated. The regulatory mechanism of miR167a was investigated by yeast one-hybrid and dual-luciferase assays that one dehydrate responsive element binding (DREB) transcription factor binds to miR167a promoter and transcriptionally repress miR167 expression.ConclusionOur study reveals the altered expression of miRNAs and their target genes in a male sterile line of pummelo and highlights that miRNA regulatory network may be involved in floral bud development and cytoplasmic male sterility in citrus.

Identification of differentially expressed microRNAs from a male sterile Ponkan mandarin (Citrus reticulata Blanco) and its fertile wild type by small RNA and degradome sequencing

Male sterility, which could result from abnormal anther development, is a main contributor to seedless fruit production in higher plants, including citrus. MicroRNAs (miRNAs) play important roles in plant development by regulating various biological processes. In this study, by high-throughput sequencing of small RNA libraries constructed from two Ponkan mandarin (Citrus reticulata Blanco) lines, i.e., male fertile and seedy “Egan No. 1” and its male sterile and seedless mutant “Qianyang seedless,” a total of 156 known miRNAs from 32 families and 24 novel miRNAs were identified. Analyses of the expression profiles in sequencing data showed that 71 known miRNAs and 11 novel miRNAs were differentially expressed between the seedy and seedless types. By degradome sequencing, a total of 138 targets were identified for 44 miRNA families, among which 5 targets were experimentally validated by RLM-5′RACE. Consistent with the results in previous studies, target annotation demonstrated that most targets of the known miRNAs were transcription factors. Forty-one targets were also detected to be cleaved by 16 novel miRNAs. Expression profile analyses by qRT-PCR revealed a negative regulation between eight known miRNA and their targets during anther development. Our research provides new information about the miRNA regulatory network during anther development and further advances the study about the mechanism of citrus male sterility.