High spatial resolution datasets analyses identify genes associated with multi-layered secondary cell wall thickening in Pinus bungeana.

BACKGROUND AND AIMS: Secondary cell wall (SCW) thickening is a major cellular developmental stage determine wood structure and properties. Although the molecular regulation of cell wall deposition during tracheary element differentiation has been well established in primary growth systems, less is known about the gene regulatory processes involved in the multi-layered SCW thickening of mature trees.

METHODS: Using third-generation (long-read single-molecule real-time, SMRT) and second-generation (short-read sequencing by synthesis, SBS) sequencing methods, we established a Pinus bungeana transcriptome resource with comprehensive functional and structural annotation for the first time. Using these approaches, we generated high spatial resolution datasets for the vascular cambium, xylem expansion regions, early SCW thickening, late SCW thickening, and mature xylem tissues of 71-year-old Pinus bungeana trees.

KEY RESULTS: A total of 79,390 non-redundant transcripts, 31,808 long non-coding RNAs, and 5,147 transcription factors were annotated and quantified in different xylem tissues at all growth and differentiation stages. Furthermore, using this high spatial resolution dataset, we established a comprehensive transcriptomic profile and found that members of the NAC, WRKY, SUS, CESA, and LAC gene families are major players in early SCWs formation in tracheids, whereas members of the MYB and LBD transcription factor families are highly expressed during late SCWs thickening.

CONCLUSIONS: Our results provide new molecular insights into the regulation of multi-layered SCW thickening in conifers. The high spatial resolution datasets provided can serve as important gene resources for improving softwoods.