Browsing by Subject "LAZY1"

Tree shoot architecture research is important due to its significance in fields such as timber production, fruit and nut production and aesthetics of common areas. Also, research on genetic factors that regulate shoot and root system architecture might provide novel methods to store more carbon in forests and, hence, mitigate global warming in the future. LAZY1 is one of the major genes that affects branch and tiller angle in herbaceous and woody species such as Arabidopsis, rice and peach tree. LAZY1 has been under scrutiny over a decade but its molecular function remains unknown. However, it is known that lazy1 mutation affects polar auxin transport. Here it is studied how LAZY1 affects initial branch angle, fiber length and reaction wood development in silver birch (Betula pendula). Also, transcript levels of few shoot architecture related genes were analyzed. LAZY phylogenetic analysis provided evidence of a duplication of LAZY1 in three studied tree species (Betula pendula, Prunus persica, Populus trichocarpa), duplicated genes are here named LAZY1a and LAZY1b. Plant material employed in this study was a segregating population (50:50) of back-cross 1 of weeping birch (B. pendula ´Youngii´) which has a truncated lazy1a. Histological samples of branches were prepared by cryo-sectioning, stained with carbohydrate binding Alcian Blue and lignin binding Safranin dyes to reveal patterns of tension wood development. Due to the large size of branch sections, samples were imaged with a microscope and the images were merged together in a Photoshop application. Branch angles were measured manually with a protractor (angle) tool from stem to the middle of a branch. The data was analyzed using mixed linear models due to the nature of used plant material. We could not use clones because of major issues in in vitro propagation. Branch samples were macerated, fibers imaged and measured by ImageJ software. LAZY1a gene expression levels were analyzed by RT-qPCR method. RNA-sequence analysis indicated that the expression pattern of LAZY1a and LAZY1b is similar in B. pendula. However, one should construct a promoter-reporter line to study with better resolution if their expression is spatially analogous. Initial branch angle was significantly different in wild type compared to lazy1a mutant. For future, one could generate single and double knock out lines of lazy1a/b to study if they have cumulative effect on the branch angle, an important factor in timber quality. Tension wood formation was difficult to quantify with the employed method, due to issues in segregating G-layered tension wood from thick-walled reaction wood. A chemical analysis of cellulose content might provide a more objective method to observe tension wood in branches. RT-qPCR method indicated that LAZY1a transcript levels are higher in wild type compared to mutant. A complementation or knock down experiment would provide sound evidence that lazy1a induces the weeping phenotype. X-ray diffraction method could be employed to study the orientation of cellulose microfibril angle in branches of the wild type vs. mutant. Generation of effective tensional stress requires a cellulose microfibril angle less than 10 and this angle is affected by auxin concentration. It is possible, that this angle is larger in lazy1a due to defect in polar auxin transport.