Project description:Purpose: Autologous fat grafting is one of the most effective and safest treatment for soft tissue restoration and augmentation, and many efforts has been done to improve its efficiency including adipose tissue derived stem cell (ASC) supplementation. Here, we evaluated the role of Notch ligand Delta-like ligand 4 (Dll4) in angiogenesis in grafted fat and the effect on graft survival using the murine fat graft model, and its impact on the ASC supplementation. Methods: We performed RNA-seq analysis of 3 mouse fat graft groups: 1) control fat grafts, 2) ASC added fat graft, and 3) ASC added fat graft with Dll4 inhibition. The fat grafts were harvested 8 weeks after grafting (n=4), and generated mRNA profiles by deep sequencing using Illumina NovaSeq 6000. Results: We found that when we treated Dll4 blocking antibody to inhibit Dll4, which was highly expressed in endothelial cells (ECs) of grafted fat, angiogenesis in the grafted fat was significantly induced, promoting fat graft retention. In addition, this effect was shown to synergistically improve the fat graft retention when ASCs were concomitantly supplemented. Transcriptome analysis further identified that the expression of the junctional proteins was increased in the ECs and inflammatory processes were downregulated in the grafted fat with ASC supplementation and Dll4 inhibition. Conclusions: This study serves as a basis for developing new potential therapeutic approaches to improve graft retention after cell-assisted transfer by Dll4 inhibition.

Project description:Col-0 floral stem was grafted on the msh1 mutant (Col-0/msh1) and on the dcl2,3,4,msh1 quadruple mutant (Col-0/dcl2,3,4,msh1). Seeds were collected from the grafted Col-0 scion after grafts were established. Seed coming from the graft then were grown on 0.5M MS growth medium and root tissue was collected after 12 days and used for the RNA sequencing.

Project description:Col-0 floral stem was grafted on the msh1 mutant (Col-0/msh1); on the dcl2,3,4,msh1 quadruple mutant (Col-0/dcl2,3,4,msh1); on Col-0 (Col-0/Col-0). Seeds were collected from the grafted Col-0 scion after grafts were established. Seed coming from the graft then were grown on the peat mix, leaf tissue was collected at the bolting and used for the total RNA sequencing.

Project description:Lisbon lemon trees were grafted with budwood infected with the citrus greening bacterium, 'Candidatus Liberibacter asiaticus', or control budwood, and leaf samples were collected every two weeks post graft for LC/MS analysis. This project has shotgun proteomics data for leaf samples from 5 control and 5 CLas grafted trees at the 10 week post graft timepoint.

Project description:Lisbon lemon trees were grafted with budwood infected with the citrus greening bacterium, 'Candidatus Liberibacter asiaticus', or control budwood, and leaf samples were collected every two weeks post graft for LC/MS analysis. This project has shotgun proteomics data for leaf samples from 5 control and 5 CLas grafted trees at the 14 week post graft timepoint.

Project description:Lisbon lemon trees were grafted with budwood infected with the citrus greening bacterium, 'Candidatus Liberibacter asiaticus', or control budwood, and leaf samples were collected every two weeks post graft for LC/MS analysis. This project has shotgun proteomics data for leaf samples from 5 control and 5 CLas grafted trees at the two week post graft timepoint.

Project description:Project : Sugar-Auxine_Rose ngs2017_11_rosex2-auxin sugar antagonist effect on budburst Study of the antagonistic effect between sugar and auxin on the bud burst of the axillary bud of the rose bush - Identification of the molecular network involved in the antagonistic effect between sugar and auxin on the budburst of the vegetative budworm of the rose bush

Project description:Col-0 floral stem was grafted on the msh1 mutant (Col-0/msh1); on the dcl2,3,4,msh1 quadruple mutant (Col-0/dcl2,3,4,msh1); on Col-0 (Col-0/Col-0). Seeds were collected from the grafted Col-0 scion after grafts were established. Seed coming from the graft then were grown on the peat mix, leaf tissue was collected at the bolting and used for the bisulfite sequencing (methylome). Tissue from the msh1 mutant and dcl2,3,4,msh1 quadruple mutants used as rootstocks was similarly collected at the bolting stage and used for the bisulfite sequencing.

Project description:Col-0 floral stem was grafted on the msh1 mutant (Col-0/msh1); on the dcl2,3,4,msh1 quadruple mutant (Col-0/dcl2,3,4,msh1). Seeds were collected from the grafted Col-0 scion after grafts were established. Seed coming from the graft then were grown on the peat mix, leaf tissue was collected at the bolting and used for the small RNA sequencing. Tissue from the msh1 mutant and dcl2,3,4,msh1 quadruple mutants used as rootstocks was similarly collected at the bolting stage and used for the small RNA sequencing.

Project description:This model is from the article: Root gravitropism is regulated by a transient lateral auxin gradient controlled by a tipping-point mechanism. Band LR, Wells DM, Larrieu A, Sun J, Middleton AM, French AP, Brunoud G, Sato EM, Wilson MH, Péret B, Oliva M, Swarup R, Sairanen I, Parry G, Ljung K, Beeckman T, Garibaldi JM, Estelle M, Owen MR, Vissenberg K, Hodgman TC, Pridmore TP, King JR, Vernoux T, Bennett MJ. Proc Natl Acad Sci U S A.2012 Mar 20;109(12):4668-73 22393022, Abstract: Gravity profoundly influences plant growth and development. Plants respond to changes in orientation by using gravitropic responses to modify their growth. Cholodny and Went hypothesized over 80 years ago that plants bend in response to a gravity stimulus by generating a lateral gradient of a growth regulator at an organ's apex, later found to be auxin. Auxin regulates root growth by targeting Aux/IAA repressor proteins for degradation. We used an Aux/IAA-based reporter, domain II (DII)-VENUS, in conjunction with a mathematical model to quantify auxin redistribution following a gravity stimulus. Our multidisciplinary approach revealed that auxin is rapidly redistributed to the lower side of the root within minutes of a 90° gravity stimulus. Unexpectedly, auxin asymmetry was rapidly lost as bending root tips reached an angle of 40° to the horizontal. We hypothesize roots use a "tipping point" mechanism that operates to reverse the asymmetric auxin flow at the midpoint of root bending. These mechanistic insights illustrate the scientific value of developing quantitative reporters such as DII-VENUS in conjunction with parameterized mathematical models to provide high-resolution kinetics of hormone redistribution. This model corresponds to the full model described in the article.