Chemistry: molecular biology and microbiology – Measuring or testing process involving enzymes or... – Involving nucleic acid
Reexamination Certificate
2000-01-26
2004-06-22
Paras, Peter (Department: 1632)
Chemistry: molecular biology and microbiology
Measuring or testing process involving enzymes or...
Involving nucleic acid
C536S024500, C800S278000, C204S450000
Reexamination Certificate
active
06753139
ABSTRACT:
TECHNICAL FIELD
The present invention relates generally to methods and materials for use in achieving and detecting gene silencing, particularly post-transcriptional gene silencing, in an organism.
PRIOR ART
Methods of detecting and efficiently achieving gene silencing are of great interest to those skilled in the art.
Post-transcriptional gene silencing (PTGS) is a nucleotide sequence-specific defence mechanism that can target both cellular and viral mRNAs. PTGS occurs in plants and fungi transformed with foreign or endogenous DNA and results in the reduced accumulation of RNA molecules with sequence similarity to the introduced nucleic acid (1, 2).
PTGS in plants can be suppressed by several virus-encoded proteins (6) and is closely related to RNA-mediated virus resistance and cross-protection in plants (7,8). Therefore, PTGS may represent a natural antiviral defence mechanism and transgenes might be targeted because they, or their RNA, are perceived as viruses. PTGS could also represents a defence system against transposable elements and may function in plant development (9-11). To account for the sequence specificity, and post-transcriptional nature of PTGS it has been proposed that antisense RNA forms a duplex with the target RNA thereby promoting its degradation or interfering with its translation (12).
One problem which exists in actually utilising efficient gene silencing, for instance via anti-sense mechanisms, is selecting appropriate regions to target. This problem has been reviewed in the literature (see Szoka (1997) Nature Biotechnology 15: 509; Eckstein (1998) Nature Biotechnology 16: 24). Proposed solutions to selecting good target regions include computational analysis (Patzel and Sczakiel(1998) Nature Biotechnology 16: 64-68) or Rnase H cleavage using chimeric anti-sense oligonucleotides (see Ho (1996) Nucleic Acid Res 24: 1901-1907; Ho et al (1998) Nature Biotechnology 16: 59-62). Other groups have used wide array of oligonucleotides to select those which form heteroduplexes (see Milner et al (1997) Nature Biotechnology 15: 537-541).
DISCLOSURE OF THE INVENTION
The present inventors have investigated PTGS of target genes initiated by a variety of silencing mechanisms in different organisms, and have established that in every case a previously uncharacterised species of antisense RNA complementary to the targeted mRNA was detected. These RNA molecules were of a uniform length, estimated at around 25 nucleotides, and their accumulation required either transgene sense transcription or RNA virus replication. Corresponding sense RNA molecules were also detected.
There have been no previous reports of such short sense and antisense RNA molecules (hereinafter, collectively, SRMs) that are detected exclusively in organisms exhibiting PTGS, possibly because (owing to their size) they could not have been readily detected by routine RNA analyses.
It appears that the SRMs may be synthesized from an RNA template and represent a specificity determinant and molecular marker of PTGS. Because of their correlation with PTGS and the nature of the molecules (short complementary molecules which could base pair with the target RNAs) they are believed to represent a signal and/or inducer or activator of PTGS.
The identification of this species by the present inventors may be utilised by those skilled in the art in a variety of methods and processes which are discussed in more detail below. Generally speaking the present invention provides, inter alia, methods of identifying and screening for gene silencing and particular silenced genes in organisms; processes for producing or isolating silencing agents, and such isolated agents themselves; methods for selecting target regions of nucleic acids which it is desired to silence and methods for silencing target genes using the agents or target regions generated as above. Also included are relevant materials. (e.g. nucleic acids, constructs, host cells, transgenic plants, silenced organisms) and methods of use of these.
Importantly, the disclosure herein provides evidence that SRMs may be a common mediator of PTGS in both plants and higher organisms, such as the nematode discussed in the Examples hereinafter. It was previously known that double stranded RNA induces a similar effect to plant PTGS in nematodes, insects (4) and protozoa (5). For instance PTGS has been demonstrated in
Caenorhabditis elegans
(a nematode worm) using DsRNA introduced into the worms by microinjection, imbibing or by allowing the worms to eat bacteria (
E. coli
) which are synthesizing dsRNA. There was also some evidence that in some examples of PTGS in plants and dsRNA interference in nematodes, a signal is produced which spreads and amplifies the silencing beyond the point of introduction of the original inducer of silencing. Although there were known to be certain similarities between the DsRNA induced silencing in nematodes and the causes of PTGS in plants, there was no clear evidence that the two are related.
Aspects of the invention will now be discussed in more detail.
Thus in one aspect of the present invention there is provided a method of detecting, diagnosing, or screening for gene silencing in an organism, which method comprises the steps of:
(i) obtaining sample material from the organism,
(ii) extracting nucleic acid material therefrom,
(iii) analysing the extracted nucleic acid in order to detect the presence or absence of SRMs therein,
The result of the analysis in step (iii) may be correlated with the presence of silencing in the organism.
The ‘sample’ may be all or part of the organism, but will include at least some cellular material.
The term ‘SRMs’ is used to describe the short RNA molecules described herein which are approximately 25 nucleotides in length. The size appears to be very characteristic, being estimated as approximately 25 nucleotides in all the cases tested (relative to the same molecular size markers when assessed by chromatography). However, it may be slightly more or less than this characteristic length (say plus or minus 1, 2, 3, 4 or 5 nucleotides) and where the term ‘25 nt RNA’ is used herein, it will be understood by those skilled in the art that the comments would apply equally in the event that the SRMs do not have this precise length.
Indeed the precise length may not be important, since the disclosure herein permits the identification, isolation and utilisation of SRMS in any case.
In performing the invention, it may be preferred to analyse or otherwise utilise short anti-sense RNA molecules (SARMs) rather than short sense RNA molecules (SSRMs). Nonetheless, where reference is made herein to SARMs (except where context clearly suggests otherwise) it will be appreciated by those skilled in the art that the SSRMs may also be used.
In particular, the SRMs methodology may be used as an indicator of PTGS. As is well known to those skilled in the art, PTGS occurs post-transcriptionally: i.e. the transcription rates of the suppressed genes are unaffected. The term ‘gene’ is used broadly to describe any sequence which is suitable for translation to a protein.
Thus the presence of SRMs can be used as a diagnostic test for the existence of PTGS.
In one embodiment of this-aspect there is disclosed a method of detecting or identifying the silencing of a target gene in an organism, which method further comprises characterising any SRMs which are present. It should be noted that PTGS effects are very dominant. In principle the presence of SRMs may indicate the silencing of more than one gene, providing that they have sufficient homology.
‘Characterised’ and ‘characterising’ does not necessarily imply complete sequencing, although this may be preferred. In order to detect silencing of a known sequence, the SRMs may be fully or partially sequenced, or sequence identity or similarity may be inferred from e.g. blotting.
Applications for such a diagnostic test will depend on the organism in question. For instance, in plants, since PTGS is the basis for a lot of pathogen derived resistance (PDR), GM field crops (e.g. individuals, or po
Baulcombe David Charles
Hamilton Andrew John
Dann Dorfman Herrell and Skillman
Paras Peter
Plant Bioscience Limited
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