Arabidopsis Research Roundup: May 5th

There are a bumper crop of papers in this edition of the Arabidopsis Research Roundup. First from the University of Manchester is a paper that identifies a protein involved in plant programmed cell death. Secondly are two papers from the University of Bristol that highlight the role of viruses in the reflectivity of plant leaves and an assessment of the growth parameters of Arabidopsis on different soil-types. Thirdly are three papers from University of Edinburgh that either use CRISPR-Cas technology to develop virus-research plants, investigate the relationship between photoperiod and metabolism or present a method for assessment of protein S-nitrosylation. Fourthly is a paper that includes a contribution from the University of Leeds that investigates the evolutionary and functional relationship of the WOX gene family. Finally is a study that highlights the role of the AUGMIN complex during microtubule activity that includes a contribution from the University of Leicester.

In addition, although not involving Arabidopsis, we should mention an exciting study from Gerben van Ooijen (Edinburgh) that has discovered a conserved circadian mechanism based on magnesium rhythms that is linked to energy expenditure.

Ge Y, Cai YM, Bonneau L, Rotari V, Danon A, McKenzie EA, McLellan H, Mach L, Gallois P (2016) Inhibition of cathepsin B by caspase-3 inhibitors blocks programmed cell death in Arabidopsis. Cell Death Differ. Open Access

The corresponding author of this paper is Patrick Gallois from the University of Manchester and includes contributions from Hazel McLellan in Dundee almongside Chinese and Austrian collaborators. This study investigates the role of caspase proteins on control of programmed cell death in plants. This research area has been hindered by the apparent lack of plant caspase orthologues despite pharmacological evidence that proteins with caspase activity are active in plants. The authors use a labeled caspase-3 inhibitor to identify the Arabidopsis Cathepsin B3 (AtCathB3) protein as having caspase activity, which was verified using recombinant proteins during in vitro enzyme assays. AtCathepsinB1,2,3 triple mutant plants demonstrate a reduction in PCD induced by different stresses and explains why caspase inhibitors are effective tools for studying PCD in plants. The core Cathepsin B protein is evolutionarily conserved suggesting that an ancestral pathway exists that controls PCD, the details of which require further study.

Maxwell DJ, Partridge JC, Roberts NW, Boonham N, Foster GD (2016) The Effects of Plant Virus Infection on Polarization Reflection from Leaves. PLoS One. 11(4):e0152836 10.1371/journal.pone.0152836 Open Access

Gary Foster’s research group at the University of Bristol collaborate with others at the University of York and in Australia for this study that investigates how plant viruses may modify gene expression to benefit their own transmission. They show that Potato virus Y and Cucumber mosaic virus (CMW), which both are transmitted by aphids, significantly reduce the amount of polarised light that is reflected from abaxial leaf surfaces of tobacco plants particularly when compared to the effects caused by non-insect vectored viruses. However this effect was not shown in Arabidopsis leaves infected by a variety of differently transmitted viruses. Interestingly ECERIFERUM6 (CER6) transcripts accumulate to higher levels following infection with insect vectored viruses and as this gene is involved in cuticle wax synthesis the authors suggest that induced changes in cuticle composition might be key in understanding how viruses encourage predation by their insect vectors. Finally the authors discuss the overall adaptive significance of these results.

Drake T, Keating M, Summers R, Yochikawa A, Pitman T, Dodd AN (2016) The Cultivation of Arabidopsis for Experimental Research Using Commercially Available Peat-Based and Peat-Free Growing Media. PLoS One. 11(4):e0153625 10.1371/journal.pone.0153625 Open AccessPeatPic

GARNet committee member Anthony Dodd, also from the University of Bristol, leads this study into the growth of Arabidopsis on peat-free media, which was motivated by the unsustainable use of peat-based composts. They found that biomass accumulation and seed yield were reduced on peat-free media and that some types of this media was more suspectible to fungal contamination. Overall vegetative phenotypic parameters were similar between plants grown on peat-based or peat-free media, indicating that this type of media will be appropriate for future analysis. However the seed yield was usually reduced, indicating that experiments looking at post-phase change phenotypes might not be as comparable between plants growth on media with different amount of peat.

Pyott DE, Sheehan E, Molnar A (2016) Engineering of CRISPR/Cas9-mediated potyvirus resistance in transgene-free Arabidopsis plants Mol Plant Pathol.

Attila Molnar (Edinburgh) is the corresponding author on this study that uses the transformative technology CRISPR/Cas9 to engineer Arabidopsis plants that are resistant to potyvirus infection. This is achieved by targeting the genes encoding the translation initiation factor eIF(iso)4E that had been previously identified as being critical for viral establishment. Importantly they subsequently selected transgene-free plants that have no phenotypic changes when compared to wildtype growth under standard conditions. As the potyvirus Turnip Mosaic Virus is an important pathogen for vegetable crops this is potentially an extremely powerful technique for generating virus-resistance food crops.

Flis A, Sulpice R, Seaton DD, Ivakov AA, Liput M, Abel C, Millar AJ, Stitt M (2016) Photoperiod-dependent changes in the phase of core clock transcripts and global transcriptional outputs at dawn and dusk in Arabidopsis Plant Cell Environ.

This German–led study aims to connect the expression of photoperiod-length responsive circadian clock-regulated genes with those involved in metabolic processes such as starch degradation and includes a contribution from Professor Andrew Miller from the Edinburgh SynthSys Centre. The authors assess global gene expression by transcript profiling at photoperiods ranging from 4-18 hours and found that changes in transcript abundance at dawn throughout these photoperiods were as large as changes seen in individual experiments when comparing dawn and dusk. These complex interactions revealed coordinated regulation of key metabolic processes and begins to demonstrate how metabolism is linked to photoperiod.

Homem RA, Le Bihan T, Yu M, Loake GJ (2016) Identification of S-Nitrosothiols by the Sequential Cysteine Blocking Technique Methods Mol Biol. 1424:163-74.

This paper from the lab of Gary Loake (Edinburgh) describes the methods they use to investigate the role of protein S-nitrosylation in the immune responses of Arabidopsis. These are based on a modification of the biotin-switch technique, which they term sequential cysteine blocking.

Dolzblasz A, Nardmann J, Clerici E, Causier B, van der Graaff E, Chen J, Davies B, Werr W, Laux T (2016) Stem cell regulation by Arabidopsis WOX genes Mol Plant. S1674-2052(16)30029-6

This German-led study includes work from the lab of Brendan Davies at the University of Leeds and investigates the role of the WUSCHEL-RELATED HOMEOBOX (WOX) transcription factor gene family during stem cell development and maintenance. Most members of the WUS-clade can largely substitute for WUSCHEL activity in the shoot meristem, which is absolutely dependent on a conserved WUS-box motif that is critical for the interaction with TOPLESS co-repressors. In contrast to the WUS clade, the WOX13 and WOX9 clades cannot substitute for WUS activity. The indicates that WOX control of shoot and floral meristem relies on certain currently not-fully-understood attributes of the WUS-clade of proteins.

Oh SA, Jeon J, Park HJ, Grini PE, Twell D, Park SK (2016) Analysis of gemini pollen 3 mutant suggests a broad function of AUGMIN in microtubule organization during sexual reproduction in Arabidopsis Plant J.

David Twell (Leicester) is an author on his Korean-led study that reports on the identification of the new gem3 mutant, which displays defects in gametophytic development. Mutant plants exhibits disrupted cell division during male meiosis, at pollen mitosis I and throughout female gametogenesis. Gem3 is a hypomorphic allele of the AUGMIN subunit 6 gene, which is a component of Augmin complex responsible for microtubule (MT) nucleation in acentrosomal cells. In the gem3 mutant, the authors show that MT arrays are incorrectly distributed, likely causing the gametophyte-specific phenotypes and demonstrating a broad role for the augmin complex during sexual reproduction in flowering plants

No Comments - Leave a comment

Leave a Reply

Welcome , today is Monday, February 20, 2017