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本帖最后由 细胞海洋 于 2011-10-11 09:11 编辑
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The discovery of DNA as the genetic material brought great hope to scientists all over the
! i, h! O9 G; j" I; u6 y5 s' fworld. It was believed that many of the lingering questions in genetics and the mechanisms
* r' @6 w2 W: |) n" b% n9 U* Vof heredity would finally be answered. However, as often is the case in science, more questions% Z# @) [/ d' c1 G+ F
arose out of this discovery. What defines a gene? What are the mechanisms of gene
- N7 g _9 E& N" {5 B) Qregulation? Further discovery and technological innovations brought about sequencing. \) T8 ^& q3 k6 \5 h, ^$ l% l) G
techniques that allowed the study of complete genomes from many organisms, including* `+ E" Z/ T* \; C% ^* d% S) }
Arabidopsis and humans. Despite all the excitement surrounding these technologies, many
- I! ~, n) ?. nfeatures of the genome remained unclear. Peculiar characteristics in genome composition
4 Z6 q$ k) V N f2 Isuch as significant redundancy consisting of many repetitive elements and noncoding. s ?! J7 u, n$ u" y& G
sequences, active transcriptional units with no protein product, and unusual sequences in
: V5 ?0 f. N3 y1 Ipromoter regions added to the mysteries of genetic make-up and gene regulation. Indeed,
z5 `) p# {. G! v w5 ithe more we discovered about the genome, the more difficult it became to understand the
$ T4 {' P: t* \+ _* Hcomplexity of cellular function and regulation.
$ u: J6 K8 a) {% h% NOut of the study of the intricacies of the genome and gene regulation, arose a new& Z0 T' k& p. U4 n+ L. E1 z
science that was independent of actual DNA changes, but critical in maintaining gene; V( w9 ]. Q; ^% a( ]
regulation and genetic stability. Epigenetics, literally translated as “above genetics,” is the
' A1 i/ `7 ?) a6 D/ l: r _science that describes the mechanisms of heritable changes in gene regulation that does: t( t8 p8 m+ L: o4 G7 Z- M
not involve modifications of DNA sequence. These changes may last through somatic cell, n( {7 g" [0 K! ]. m
division and, in some cases, throughout multiple generations.0 p7 C, H! O* g. }3 `6 `( n5 t6 |
Epigenetics is perhaps one of the most popular and quickly evolving fields of modern+ T. y$ c' \0 p
science. Despite the fact that the ideas behind epigenetics had already been developing in
5 `7 p. v" ^3 z3 Wthe late nineteenth and early twentieth centuries, major advances have only occurred
/ G" j: M2 i, L7 ~' ]2 T# Y: cwithin the last 10–15 years as the mechanisms surrounding epigenetic regulation began to
6 Q% b# i2 i, y' C+ Abe uncovered. It was hoped by many that the mysteries of gene regulation and inheritance
+ o, _' q( b/ y' Z, bthat remained unanswered would finally be elucidated with the help of this new science.# G Q' C. @5 s a% S
Since, the understanding of the contribution of epigenetic regulation to cell function has
: |5 @3 A" z; [7 ]: f i, Xhelped scientists from many distinct fields of research such as molecular biology, population3 M$ s) p7 m( t" W, h
genetics, microbiology, ecology, developmental biology, and evolution.
5 A; ]' j2 l1 b+ V: F4 h& v% nGene silencing as an epigenetic mechanism to control gene expression was first
. B5 ]$ @# i, _8 |/ T( Ydescribed in plants. This occurred with the beginning of the era of plant transgenesis, and
h* I+ C, ^8 Q' O9 s! P# y* zalmost undermined the new paradigm of improvement of plant performance via transgenic5 U3 C; I7 D5 ]+ z
techniques. Silencing was a serendipitous discovery, as this finding revitalized the O/ x0 n" z, r0 H# p
field of epigenetics. Phenomena such as plant acclimation and adaptation to stress, hybrid
7 `/ O; p7 ?5 d, T3 Fand heterozygote vigor (heterosis), plant tolerance to viral infection, transgenerational
8 J/ R: C6 v7 D+ U3 echanges in genome stability, paramutations, among others, are now considered excellent
( u h3 B D( L$ |# dcandidates for regulation via epigenetic mechanisms. Future studies involving various protocols# H1 j2 }# f% \( G+ O! R
for the analysis of methylation patterns, histone modifications, chromatin structure,6 f7 S. E+ x f6 d2 {8 Y
and small RNA expression, the hallmarks of epigenetic regulation, will undoubtedly help
! ?2 }( x( j$ cto explain these phenomena. It will be exciting to discover how plants utilize these mechanisms/ m& a' F6 S$ @! p5 q% p
to adapt to stress, and how we can manipulate these characters for the generation of
. X; K* {1 M2 `0 j% V9 z' P/ Qbetter and hardier crops.9 _; e- q! e8 O( L# ]4 p
vi Preface0 x8 D+ e4 g5 W) b# |+ `/ O
In this book we have collected a variety of protocols for the study of the function of
( m( L' B: k% o6 g$ Bsmall noncoding RNAs, DNA methylation, and histone modifications in plants. Where possible
5 Z( h& \( i k7 Q3 P. |3 Nand appropriate, we presented several protocols with different degrees of complexity.
0 ]9 G6 p3 x! j0 J9 s1 aWe also include protocols for plant transgenesis and the analysis of genome stability, with a
' {4 F1 w7 H: `7 @( k Odiscussion for their applications to epigenetic studies. It was our aim to put together a single
$ a; x- A% y+ ^3 rmanual that researchers in the field of plant epigenetics can turn to in hopes to answer the
- s8 g4 e) C4 B5 s! B1 Kmany yet undiscovered and unexplained phenomena in plant biology.) N& k. U) d6 w/ Q" G
Lethbridge, AB, Canada Igor Kovalchuk
/ D% v( e2 C, m# R7 N4 w VFranz J. Zemp) ]- D$ ?( ? t6 }' F- X
3 D" Q2 K% N9 X u[hide][/hide] |
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发表于 2011-10-11 08:27
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