The brittle rachis is a unique mechanism evolved in Triticeae tribe via a gene duplication
Wild barley possesses a natural grain dispersal mechanism called the brittle rachis, which is governed by the presence of two tightly linked genes named Btr1 and Btr2 (Pourkheirandish et al. 2015). These genes are integral to the formation of the separation zone for the disarticulation of mature grain from the rachis. This separation zone presents due to the thinning of cell walls along the separation zone. The Btr1 and Btr2 genes are only found within some members of the Triticeae tribe including wheat and rye (Zeng et al. 2020). The presence of Btr1 and Btr2 correlates well with the brittle rachis characteristic (Sakuma et al. 2011). The unique separation mechanism (brittle rachis), and exclusive nature of gene sequences suggest that the Btr1 and Btr2 genes evolved in Triticeae which ultimately resulted in the development of a new dispersal mechanism. This hypothesis is further supported by the existence of duplicated copies of Btr1 and Btr2 with high sequence similarity in the barley genome known as Btr1-like and Btr2-like. Preliminary analysis has indicated that these Btr-like genes are not functionally redundant with Btr1 and Btr2. A functional Btr1-like gene cannot compensate the loss of function at the btr1 locus and similarly the loss of function of the btr2 locus cannot be compensated by a functional Btr2-like gene (Pourkheirandish et al. 2015). The Btr1-like and Btr2-like genes are thought to be the ancestral copies, with phylogenetic analysis showing that genes sharing homology with the Btr-like are found throughout the Poaceae family. In contrast, the Btr1 and Btr2 were limited to the Triticeae tribe (Zeng et al. 2020). Here, a bioinformatics approach was adopted to uncover the potential role of the Btr-like genes that may then shed light on the evolution and molecular function of Btr1 and Btr2.
The Btr-like genes are exclusively expressed in plant reproductive organs
A comprehensive analysis of barley transcripts revealed a highly specific expression pattern of the Btr-like genes. They are both exclusively expressed throughout the early meiotic stages of pollen development, indicating that they perform a crucial biological role in the reproductive process in barley. Additionally, the Btr1-like and Btr2-like genes have a synchronous expression pattern that supports their involvement in related biological processes. The expression of the Btr2 gene has been detected in cells at the rachis node during spike development at early white anther stage (Pourkheirandish et al. 2015). The immature spike in this stage is around 3–5 mm in length. The early white anther stage in spike coincides with the meiosis stage within the anthers. This suggests that Btr and Btr-like genes are expressed at a similar stage. However, the expression location differentiates the Btr2 expressed at rachis node) from the Btr-like genes (expressed within anthers), suggesting they have different biological roles within barley. For Btr genes, the outcome is rachis disarticulation, which occurs during spike maturity much later than the Btr loci expression. This suggests that BTR proteins were required to create a separation zone during spike development that can break at the later stage. The Btr-like transcripts are exclusively found in anthers, but it is yet to be determined if their biological function is immediately pronounced at the same stage as their expression, or much later akin to the Btr genes. The co-expression pattern of Btr1-like and Btr2-like genes supports a possible receptor-ligand pair relationship similar to that hypothesized for the BTR1 and BTR2 proteins (Pourkheirandish et al. 2015). It is tempting to speculate that the Btr1-like and Btr2-like unit was duplicated and then the copies functionally diverged to express in a different organ at a similar time (stage) with similar molecular function resulting in the Btr genes (Zeng et al. 2020).
Considering the above hypothesis, any information regarding the molecular function of Btr-like genes will be helpful to determine the molecular function of the brittle rachis. The highly specific expression patterns and homology of co-expression partners to known rice genes were used to infer biological processes of Btr1-like and Btr2-like.
The biological function of Btr1-like and Btr2-like based on the co-expressed genes
Rice is the best model crop in monocots possessing a detailed annotated genome. It has a relatively close relationship with barley, diverging from a common ancestor 50 million years ago (Middleton et al. 2014). The biological function of the genes co-expressed with Btr1-like and Btr2-like was investigated using homologues in rice. There were six well-described genes in rice, where the barley putative orthologues were co-expressed with Btr-like and appeared to be involved in a similar biological process within pollen or reproductive tissue development.
Out of 158 genes co-expressed with at least one of the Btr1-like and Btr2-like in barley, 55 met our criteria for matches in the rice genome (Supplementary Data 5) and 19 had entries in the funRiceGenes database. Six were found to have well characterized functions in reproduction, which allows us to make inferences on the overall biological function of the Btr-like genes. These rice genes are named TDR (TAPETUM DEGENERATION RETARDATION), OsYABBY7 (Oryza sativa YABBY 7), OsPUB73 (Oryza sativa PLANT UBIQUITIN-BOX 73), OsINP1 (Oryza sativa INAPERTURATE POLLEN 1), ITPK5 (INOSITOL 1,3,4-TRISPHOSPHATE 5/6-KINASE), and OsAsp1 (Oryza sativa ASPARTIC PROTEASE 1). Here we tried to speculate the function of Btr-like genes based on their molecular partners with similar expression patterns.
The TDR protein is a putative basic helix loop helix (bHLH) transcription factor (Li et al. 2006a). It is preferentially expressed in the innermost layer of the anther (the tapetum) in rice. The tapetum is in direct contact with the developing pollen. Expression of TDR is specific to the anther and begins early in meiosis and peaks at the young microspore stage that is similar to the barley Btr-like genes demonstrated in this study. Naturally, in rice, the tapetum is almost completely degenerated by the vacuolated pollen stage allowing pollen the space to develop to maturity. However, in the loss of function mutation (tdr) the tapetum does not degenerate as in the wild-type, swelling and destroying the meiocytes in the process. TDR silencing appears to be linked to the retardation of programmed cell death in the tapetum, meiocyte abortion and pollen wall abnormalities (Li et al. 2006a; Zhang et al. 2008). The most striking morphological defect is the delayed degeneration of the tapetum and results in complete male sterility. The pollen wall abnormalities have also been further investigated, revealing that these defects occurred after forming the primexine layer (micro-fibular matrix that forms the mould for the pollen wall deposition) by microspores (Blackmore and Barnes 1985; Echlin and Godwin 1968; Zhang et al. 2008). Barley has a prospective orthologue of TDR within the candidate gene list. Additionally, the barley orthologue was one of the genes identified in BLAST2GO analysis with the GO code for anther development. Multiple sequence alignment of the pair revealed that barley and rice TDR share amino acid sequence identity of 64.88%. The expression patterns of rice TDR and the barley orthologue temporally mirror each other. Since TDR is primarily expressed in the tapetum and the barley orthologue expressed in the meiocyte sample, this finding indicates that tapetal tissue was likely included in the sample (the membrane of the ‘meiocyte bag’) (Barakate et al. 2020). Rice TDR is located on chromosome 2, in syntenic position with the barley orthologue located on chromosome 3H (Mayer et al. 2011). Moreover, TDR has orthologous sequence not only in barley but Brachypodium and sorghum as well (Bradi3g01901.1 and Sb04g001650.1). This indicates that the gene is well conserved across monocots and, therefore likely has a conserved and crucial function as demonstrated in rice.
The OsYABBY7 protein is part of the YABBY gene family; the zinc finger transcription factor family, which has been known to play important biological roles in morphogenesis, growth, and development (Zhao et al. 2020). However, real-time PCR expression analysis of the YABBY genes in rice revealed that OsYABBY7 has a significantly lower-level but more targeted expression than the other YABBY genes (Toriba et al. 2007). OsYABBY7 is specifically expressed in the reproductive organs of flowers whereas the other OsYABBY genes have more general expression across all inflorescence structures and other meristematic tissues. Barley has a prospective orthologue of OsYABBY7 within the candidate gene list and the barley expression levels seen in our data strongly support similar expression patterns to rice. The barley orthologue was also identified within the BLAST2GO analysis with the GO code for plant ovule development. Multiple sequence alignment of these sequences revealed an amino acid sequence identity of 66.67%. This gene is not well studied and would be a good candidate for further research.
The rice protein OsPUB73 was first identified with the U-box domain and putative function as an E3 ubiquitin ligase (Zeng et al. 2008). This protein domain has been linked with regulating programmed cell death signalling (Zeng et al. 2008). However, the context in which OsPUB73 has been expressed and the biological pathway it is involved in has only recently been investigated. It has shown high expression in the anther throughout the early stages of meiosis. Gene silencing of OsPUB73 in rice revealed reduced pollen fertility, incomplete tapetum degeneration/cell death and pollen exine abnormalities (Chen et al. 2019). The best match to rice OsPUB73 gene in barley genome is the candidate gene found in the current co-expression study and the multiple sequence alignment revealed the genes share a 47.28% amino acid sequence identity. The expression pattern of the putative barley orthologue is consistent with that of the rice gene.
While both TDR and OsPUB73 are important for the development of fertile pollen neither of these genes prevents the meiotic process from occurring. The meiocytes in both mutant variants (tdr and ospub73) reach the tetrad stage without any obvious irregularities despite both genes being expressed well before the tetrad stage. While both genes cause similar abnormalities when defective, comparative co-expression analysis between mutant variants ospub73 and tdr indicate that these genes could function in independent molecular pathways in rice (Chen et al. 2019). It is also possible that OsPUB73 is part of the same functional process as TDR but exists further downstream and does not affect the regulation of as many genes. Based on the co-expression, one can hypothesize that Btr-like genes are also involved in pollen cell wall development during the meiosis stage.
The putative function of OsINP1 is unknown, but its role in overall biological processes has been described in a rice gene knockout experiment (Zhang et al. 2020). Expression of OsINP1 is present in meiocytes in rice from the meiocyte stage to the free microspore stage (Zhang et al. 2020). Stained confocal microscopy revealed OsINP1 is localized to distal poles of the tetrad. Areas with high concentration marks points of depleted pollen precursor deposition, which appears to only occur at the position of the pollen aperture development. Pollen apertures are small openings on the pollen surface that allow the pollen tube to emerge from inside the pollen during fertilization (Edlund et al. 2004). It was demonstrated that while a mutation to OsINP1 does not affect the development of anthers and pollen grains, the aperture in mature pollen grains is absent in mutants. This prevents the emergence of the pollen tube, resulting in male sterility. Barley has a prospective orthologue of OsINP1 within the candidate gene list. The expression levels of the barley gene seen within this analysis are consistent with the function of OsINP1 seen in rice. Multiple sequence alignment analysis of OsINP1 and its potential barley orthologue reveal an 85.10% amino acid sequence identity. This gene is well conserved and has been identified in the barley-rice zipper genome synteny model, and Brachypodium and sorghum (Mayer et al. 2011).
The gene ITPK5 is a part of the ITPK gene family first uncovered in A. thaliana. This gene family appears to be exceptionally well conserved across monocot and dicot species. The ITPK gene family encodes a putative inositol 1,3,4-trisphosphate 5/6-kinase which is involved in polyphosphate biosynthesis and is part of the broader ATP-grasp proteins (Fawaz et al. 2011). Detailed studies in rice have been undertaken on the homologue ITPK2, which has been linked to response to drought tolerance. An expression comparison between ITPK genes present within rice (ITPK1-6) indicated that ITPK5 showed the highest expression within the endosperm, 7 and 14 days after pollination (Du et al. 2011). The expression analysis of the barley orthologue also shows expression in the developing grain (consistent with the endosperm), much like the rice orthologue. However, the barley orthologue exhibits an increased expression level during the early stages of meiosis that is not observed in the rice orthologue. GO codes associated with potential barley orthologue ITPK5 indicate it is involved in seed development. The difference in expression from the rice ITPK5 to the barley orthologue suggests that it may have additional biological function in barley. Multiple sequence alignment analysis of ITPK5 and its barley counterpart reveal a 78.36% amino acid sequence identity and it is located within the synteny model for sorghum (Mayer et al. 2011).
OsAsp1 appears to be a homologue of a barley gene within the candidate gene list. This gene’s molecular function is to produce an aspartic acid protease (Bi et al. 2005). This is a proteolytic enzyme that breaks down proteins that function optimally in acidic environments (Cao et al. 2019). It is known to be associated with meristematic activity and has been linked to various reproductive tissues: nucellus, embryos, ovary walls and the coleoptiles of immature seeds. Previous studies have indicated that this gene was more specifically involved in programmed cell death, however this has been disputed (Bi et al. 2005; Chen and Foolad 1997). There appear to be two homologues of OsAsp1 in barley, one is the barley ‘nucellin’ gene, the other is the gene on our candidate list that we will term nucellin-like. Multiple sequence alignment analysis of OsAsp1, nucellin and nucellin-like proteins reveals a 57.84% identity between OsAsp1 and nucellin, and a 48.27% identity between OsAsp1 and nucellin-like. This indicates that nucellin is the likely orthologue of OsAsp1 not the nucellin-like that is co-expressed with Btr-like genes. While sharing homology, nucellin and nucellin-like are also only 48.97% similar, suggesting that nucellin-like may exhibit a diverged function compare to nucellin.
Potential biological processes involving BTR-LIKE proteins
The potential biological pathway of the Btr-like gene pair can be elucidated based on the strong correlation of expression between Btr-like genes and the three barley orthologues of TDR, OsPUB73 and OsINP1. These three genes are all attributed to pollen and pollen wall development. The other three genes, OsYABBY7, OsAsp1 and ITPK5, do not have sufficient information to analyse further and would require further research.
The tapetum directly surrounds the developing pollen. However, throughout meiosis, a callose wall is constructed between the meiocytes and the tapetum, preventing nutrient flow (Fernández 2012). In the late tetrad stage, the tapetum begins releasing callase enzymes to break down the callose wall and starts excreting precursors to the pollen wall (Ünal et al. 2013). Callose and cellulose are polysaccharides that are constituent components of the plant cell walls, although callose is less abundant than cellulose (Ünal et al. 2013). The timing of callose and callase secretion has been tied to male sterility in Petunia hybrida and sorghum, indicating that tight regulation of these processes is imperative to the successful creation of fertile pollen (Ünal et al. 2013). A hypothesis exists that the callose wall also acts as a template for the primexine layer in the developing pollen (Ünal et al. 2013; Waterkeyn and Bienfait 1970). This suggests that any disruption with this biological process will likely result in pollen coat abnormalities.
While barley and wheat are closely synchronized in their developmental staging throughout anthesis, slight deviations exist between rice and barley/wheat regulating programmed cell death of the tapetum (Browne et al. 2018). The tapetum degenerates slightly earlier in rice than in barley and wheat, which commences between the late tetrad stage and early young microspore stage (Browne et al. 2018; Lazarova 2003).
The Btr-like genes are likely associated with the cell wall. This is because of the closely related Btr genes (Btr1 and Btr2) which appear to modulate the thickness of the cell wall to form an abscission zone for easy rachis disarticulation at maturity in the spike (Pourkheirandish et al. 2015). The wheat orthologue of the Btr1 gene has been linked to the reduction in cell wall biosynthesis, which is consistent with the role of callase and callose secretion by the tapetum (Zhao et al. 2019).
Additionally, the stages of expression for Btr and Btr-like genes are overlapping where Btr genes express in the rachis when spikes are at the beginning of white anther stage and anthers are around 1 mm long (Pourkheirandish et al. 2015). This further suggests that neo-functionalization between Btr and Btr-like pairs is the result of spatial expression divergence.
Based on this evidence we have deduced two working hypotheses that indicate the Btr-like genes play a role in pollen development. Our first hypothesis is that Btr1-like and Btr2-like gene products may be found in the tapetal cell wall membrane facing the locule where they regulate the secretion of callose (meiosis stage) and/or the production of callase (late tetrad and beyond). This is consistent with the biological effects of TDR and OsPUB73. We speculate that Btr and Btr-like genes perform a similar molecular function that controls the development of cell wall thickness but in a different tissue.
The alternative hypothesis is that the BTR1-LIKE and BTR2-LIKE proteins are present within the cell membrane of the meiocyte, where they could be involved in the construction of the primexine throughout the tetrad phase. This is more consistent with the function of OsINP1 where the meiocyte alone is the location of cell wall abnormalities (i.e., the absence of the pollen aperture) (Zhang et al. 2020). This theory is also supported by the Btr genes’ predicted function in cell wall biosynthesis (Zhao et al. 2019). As the exine layer is a biological cell wall, the Btr-like genes may operate similarly in its construction. Both of these hypotheses require further investigation, an in-situ hybridization of Btr-like transcripts would provide clarity and demonstrate the exact location of Btr-like expression within the anther.