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Download Investigating Plant Growth Using AVS Dr. R. P. Fletcher University of
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November 8th 1999 UAUUG Birmingham 1 Investigating Plant Growth using AVS Presentation to the UK AVS and Uniras User Group Meeting University of Birmingham November 8th 1999 Dr. R. P. Fletcher University of York A report on work done by: • • • • Dr. S. M. Bougourd, University of York Dr. C. L. Wenzel, University of York … in collaboration with Dr. J . Haseloff, MRC Laboratory of Plant Science, Cambridge • …and me November 8th 1999 UAUUG Birmingham 3 Outline • • • • • • Which part of plant growth? Which plant? Why? How? How we use AVS What we want to do (with AVS?) November 8th 1999 UAUUG Birmingham 4 Which part of the plant? • • • • • • Above or below ground? For us … below This means the ROOTS Specifically … How do the root cells differentiate? Which cells elongate and why? November 8th 1999 UAUUG Birmingham 5 Which Plant? • • • • • • • Aribidopsis thalinana A member of the brassica family Also known as: Thale cress or … Mouse Eared cress It’s a weed! November 8th 1999 UAUUG Birmingham 6 Just so you know what it looks like Whole Plant Flowers November 8th 1999 UAUUG Birmingham 7 … and there’s more ... November 8th 1999 UAUUG Birmingham 8 Why use this weed? • • • • • • Small size and rapid life cycle Prolific seed production Simple genome Many mutants and transformed populations Perturb the behaviour of targeted cells Monitor phenotypic expression November 8th 1999 UAUUG Birmingham 9 The goal “To understand the genetical and cellular interactions that co-ordinate the development of the root meristem” November 8th 1999 UAUUG Birmingham 10 How we acquire the data • Roots are visualised using Laser Scanning Confocal Microscopy (LSCM) • Also known as Confocal Scanning Laser Microscopy (CSLM) November 8th 1999 UAUUG Birmingham 11 Quick tutorial on CLSM • A scanning laser beam is focussed onto a fluorescent specimen • Mixture of reflected and emitted light is captured by a photo-multiplier via beam splitter November 8th 1999 UAUUG Birmingham 12 Tutorial continued • Arranged so only the emitted light enters the photo-multiplier • A confocal aperture (pin-hole) placed in front of the photo-multiplier • The effect is to only allow emitted light from the “in focus” area to pass into the photo-multiplier November 8th 1999 UAUUG Birmingham 13 Principles November 8th 1999 UAUUG Birmingham 14 Typical System November 8th 1999 UAUUG Birmingham 15 The real thing November 8th 1999 UAUUG Birmingham 16 Interesting problem? • Its all very well staining specimens so that they fluoresce, but ... • We need to see whole root tip, not just sections and ... • We need same level of staining throughout, but ... • Normal stains kill the cells and are bleached by the laser scanning process November 8th 1999 UAUUG Birmingham 17 The Solution! • Everybody’s buzzword these days • Genetic Modification! • The idea is to get the plant to manufacture its own fluorescent stain • So, we will borrow a gene from somewhere else in the natural world November 8th 1999 UAUUG Birmingham 18 Obtaining the Gene • Plenty of naturally fluorescent plants and animals out there • The oceans are full of them • The jellyfish, Aequorea victoria, from the Pacific Ocean has been used. • They produce the protein, Green Fluorescent Protein (GFP). November 8th 1999 UAUUG Birmingham 19 Wibbly Wobbly Jellyfish November 8th 1999 UAUUG Birmingham 20 Pretty, Pretty November 8th 1999 UAUUG Birmingham 21 … and they can swim November 8th 1999 UAUUG Birmingham 22 Getting the Gene into the Plant • A quick tutorial about genetic modification • … gene extracted ... put in vector, a soil bacterium … isolate “infected cells” and regenerate whole plants. • Can even link “instructions” to the GFP gene to make the plant only produce the fluorescent protein in certain parts of the plant November 8th 1999 UAUUG Birmingham 23 A Single Image November 8th 1999 UAUUG Birmingham 24 An Image Stack November 8th 1999 UAUUG Birmingham 25 Getting this Stack into AVS • The old nutshell! • First, find out the format of the Bio-Rad PIC files. • Hunt round for some “v” … IAC maybe? • Got some code, but was developed for ALPHA • Had “endian” problems November 8th 1999 UAUUG Birmingham 26 Fix the code and develop Visualisation Modules • Fix the “v” code to read the correct “endianness” of the data • Amount of data can be a problem • 512 * 768 * stack size (loadsa data!) • Hope the decimation modules in Version 5 will help here • Even running on 350Mhz PC or SGI 02, both with 128 Mb of memory, AVS is slow November 8th 1999 UAUUG Birmingham 27 Network for preliminary viewing November 8th 1999 UAUUG Birmingham 28 Using AVS to view along a different axis tip Single frame November 8th 1999 Back a bit UAUUG Birmingham 29 Movie view along the axis November 8th 1999 UAUUG Birmingham 30 What are we actually seeing? • GFP fluorescing in the cell walls • The higher the intensity the more GFP • Would be better to invert the images November 8th 1999 UAUUG Birmingham 31 Inverted Image Stack November 8th 1999 UAUUG Birmingham 32 Non-invasive non-lethal • The use of the GFP means we can study the plant root growth “in vivo” • The aim is to understand the fate of the different root tip cells • Need to find a way to “tag” cells from one image stack to another • Time dimension November 8th 1999 UAUUG Birmingham 33 Cell fate? Divide Root tip cell Differentiate Some just grow November 8th 1999 Some elongate and grow UAUUG Birmingham 34 Need to see 3D view • • • • 3D reconstruction from “cloud of points” Need to “cut away” Need to “identify” cells Need to track “fate” November 8th 1999 UAUUG Birmingham 35 Preliminary 3D Investigation Orthoslices November 8th 1999 UAUUG Birmingham 36 Animate the orthoslices November 8th 1999 UAUUG Birmingham 37 Complex Network November 8th 1999 UAUUG Birmingham 38 Add in some “real” 3D Volume November 8th 1999 UAUUG Birmingham 39 Another View November 8th 1999 UAUUG Birmingham 40 Animated volume cutaway November 8th 1999 UAUUG Birmingham 41 So just how useful is AVS? • • • • Using AVS can really help to see the data Reconstructing different orthogonal views Volume visualisation will help Data volume is a problem on “small” systems • Decimation routines will be welcome November 8th 1999 UAUUG Birmingham 42 Future Work • Need to work out how to mark cell volumes in order to track specific cells • Create new fields from marked data • Visualise these “new” fields with time “n” images • Difference frames may help from time “n” to time “N+1” • Big data processing effort here needed November 8th 1999 UAUUG Birmingham 43 THAT’S ALL FOLKS November 8th 1999 UAUUG Birmingham 44
