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Genes Regulating Differentiation at the Shoot Apex of Fax (Linum Usitatissimum)
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- Author / Creator
- Ningyu Zhang
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Fiber harvested from flax phloem tissue is a renewable resource with promising uses in eco-
friendly composites. Most molecular and cellular research to date has focused on later stages of
fiber differentiation including the development of the fiber cell wall. On the other hand, the
molecular mechanisms that govern specification of fibers are largely unknown. All phloem fibers
in flax are formed during primary growth. Therefore transcription factors enriched in the shoot
apices are likely to govern fiber identity, and therefore fiber yield. In this study, I used RNA-Seq
to compare the gene expression in the apical region (AR) of the shoot apex which contained the
apical-most 0.5mm of the stem and basal region (BR), which contained the entire stem except for
the apical-most 1 cm. AR included the SAM and its immediate derivatives whereas BR represented
all stem and vascular tissues at later stages of differentiation. The RNA-Seq study identified 349
putative transcription factors that are preferentially expressed in the AR including 18 MYBs and
nine NACs. MYBs and NACs have been revealed to be required for the vascular cell identity in
other species. A total of 240 putative MYBs and 182 predicted NAC domain genes were identified
within the whole-genome sequence of flax. Phylogenetic analysis of the flax NAC gene family
revealed that two distinct subfamilies were largely expanded. Flax had a higher proportion of
R2R3-MYB than most of other sequenced plant species. Analysis of the expression data in public
database indicated that the majority of LusMYBs and LusNACs were expressed in wide range of
tissues with low expression level while a few others were particularly abundant in some specific
tissues. Transcript expression profiling of the LusNACs in the VNS subfamily in 12 different flax
tissues suggested that LusNAC28 and LusNAC125 were highly expressed in developing fibers.
A previously uncharacterized Arabidopsis gene, At3g05980, encodes a predicted protein of 245
amino acids (27.6 kDa). This protein does not contain any annotated domains, and its predicted
secondary structure consists mostly of disordered coils. It has one closely-related paralog in
Arabidopsis, At5g19340. Homologs of At3g05980 are found in all eudicots examined, but not in
any other taxa. There are four highly conserved amino acid motifs within the protein. Using qRT-
PCR and GUS reporter assays, I found that transcripts of At3g05980 were highly expressed in
immature embryos and the micropylar endosperm, as well as petals, and apices of shoots and roots,
and atrichoblasts. Transcripts were highly induced by cold treatment, but not by other stress or
hormone treatments. These results were consistent with expression patterns previously reported
in public databases. I produced loss-of-function (LOF) mutants of this gene, using CRISPR/Cas9-
mediated gene editing, as well as overexpression (OX) lines using the 35S-CaMV promoter. LOF
lines were morphologically indistinguishable from wild-type, but OX lines had minor defects,
including cotyledon epinasty, and slight shortening of both plant height and silique length. Neither
LOF nor OX differed from WT in tolerance to freezing. In the absence of cold-treatment, LOF
mutants had increased transcript abundance of the stress- and cold-responsive gene RD29,
compared to WT, but expression patterns of five other cold-responsive genes were largely
unchanged in LOF, compared to wild-type, both before and during cold treatment. Translational
fusions of At3g05980 with fluorescent proteins were localized to peroxisomes. However, assays
of peroxisomal function, including dark growth of seedlings, and sensitivity to 2, 4-DB and IBA,
were similar between LOF, OX, and WT. Furthermore, fatty acid profiling of seeds did not show
any difference between the genotypes. Thus, At3g05980 encodes a eudicot-specific, peroxisomaly
localized protein with transcripts that are cold-inducible, and enriched in specific tissues
(particularly rapidly growing tissues), but this gene does not appear to be required for normal morphology, peroxisomal function, or cold tolerance responses. The immediate future task will
be to examine phenotypes in double mutants of both At3g05980 and it paralog At5g19340. -
- Subjects / Keywords
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- Graduation date
- Fall 2018
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- Type of Item
- Thesis
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- Degree
- Doctor of Philosophy
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- License
- Permission is hereby granted to the University of Alberta Libraries to reproduce single copies of this thesis and to lend or sell such copies for private, scholarly or scientific research purposes only. Where the thesis is converted to, or otherwise made available in digital form, the University of Alberta will advise potential users of the thesis of these terms. The author reserves all other publication and other rights in association with the copyright in the thesis and, except as herein before provided, neither the thesis nor any substantial portion thereof may be printed or otherwise reproduced in any material form whatsoever without the author's prior written permission.