Endophytes and related methods

FIELD OF THE INVENTION

The present invention relates to endophytic fungi (endophytes), including modified variants thereof, and to nucleic acids thereof. The present invention also relates to plants infected with endophytes and to related methods, including methods of selecting, breeding, characterising and/or modifying endophytes.

BACKGROUND OF THE INVENTION

Important forage grasses perennial ryegrass and tall fescue are commonly found in association with fungal endophytes.

Both beneficial and detrimental agronomic properties result from the association, including improved tolerance to water and nutrient stress and resistance to insect pests.

Insect resistance is provided by specific metabolites produced by the endophyte, in particular loline alkaloids and peramine. Other metabolites produced by the endophyte, lolitrems and ergot alkaloids, are toxic to grazing animals and reduce herbivore feeding.

Considerable variation is known to exist in the metabolite profile of endophytes. Endophyte strains that lack either or both of the animal toxins have been introduced into commercial cultivars.

Molecular genetic markers such as simple sequence repeat (SSR) markers have been developed as diagnostic tests to distinguish between endophyte taxa and detect genetic variation within taxa. The markers may be used to discriminate endophyte strains with different toxin profiles.

However, there remains a need for methods of identifying, isolating, characterising and/or modifying endophytes and a need for new endophyte strains having desired properties.

In the fungal kingdom, there is no differentiation of individuals into sexes generating different gametes, but instead mating-type identity is determined by inheritance of alleles at specific mating-type loci.

The mating-type (MAT) genes constitute master regulators of sexual reproduction in filamentous fungi. Although mating-type loci consist of one to a few linked genes, and are thus limited to a small genomic region, alternate sequences at MAT, denoted idiomorphs, lack significant sequence similarity and encode different transcriptional regulators.

Fusion events are required during sexual reproduction in filamentous ascomycete species. Although cell fusion processes associated with vegetative growth as opposed to sexual development serve different developmental functions, both require extracellular communication and chemotropic interactions, followed by cell wall breakdown, membrane-merger and pore formation.

A number of genes have been characterised that are required for both sexual reproduction and vegetative hyphal fusion, including components of the MAPK pathway which is activated in response to pheromone perception during mating. The expression of pheromone precursors and pheromone receptor genes is directly controlled by transcription factors encoded by the mating-type genes.

Hyphal fusion occurs readily within an individual colony during vegetative growth, maintaining the physiological continuity of the organism. Hyphal fusion between different endophyte strains of opposite mating-type may be promoted by treating the mycelia with a combination of cell wall-degrading enzymes and fusion agents such as PEG4000.

However, there remains a need for methods of molecular breeding of endophytes and for new endophyte strains having desired properties.

Neotyphodium endophytes are not only of interest in agriculture, as they are a potential source for bioactive molecules such as insecticides, fungicides, other biocides and bioprotectants, allelochemicals, medicines and nutraceuticals.

Difficulties in artificially breeding of these endophytes limit their usefulness. For example, many of the novel endophytes known to be beneficial to pasture-based agriculture exhibit low inoculation frequencies and are less stable in elite germplasm.

Thus, there remains a need for methods of generating novel, highly compatible endophytes.

There also remains a need for more endophyte strains with desirable properties and for more detailed characterisation of their toxin and metabolic profiles, antifungal activity, stable host associations and their genomes.

It is an object of the present invention to overcome, or at least alleviate, one or more of the difficulties or deficiencies associated with the prior art.

In a first aspect, the present invention provides a method for selecting and/or characterising an endophyte strain, said method including:

- providing a plurality of samples of endophytes;
- subjecting said endophytes to genetic analysis;
- subjecting said endophytes to metabolic analysis; and
- selecting endophytes having a desired genetic and metabolic profile.

In a preferred embodiment, this aspect of the invention may include the further step of assessing geographic origin of the endophytes and selecting endophytes having a desired genetic and metabolic profile and a desired geographic origin.

In a preferred embodiment, the plurality of samples of endophytes may be provided by a method including:

- providing a plurality of plant samples; and
- isolating endophytes from said plant samples.

In a preferred embodiment, the method may be performed using an electronic device, such as a computer.

Applicant has surprisingly found that specific detection of endophytes in planta with markers such as SSR markers has provided the tools for efficient assessment of endophyte genetic diversity in diverse grass populations and the potential discovery of novel endophyte strains.

A large scale endophyte discovery program was undertaken to establish a ‘library’ of novel endophyte strains. A collection of perennial ryegrass and tall fescue accessions was established.

Genetic analysis of endophytes in these accessions has lead to the identification of a number of novel endophyte strains. These novel endophyte strains are genetically distinct from known endophyte strains.

Metabolic profiling was undertaken to determine the toxin profile of these strains grown in vitro and/or following inoculation in planta.

Specific detection of endophytes in planta with SSR markers may be used to confirm the presence and identity of endophyte strains artificially inoculated into, for example, grass plants, varieties and cultivars.

The endophytes have been genetically characterised to demonstrate genetic distinction from known endophyte strains and to confirm the identity of endophyte strains artificially inoculated into, for example, grass plants, varieties and cultivars.

By a ‘plurality’ of samples of endophytes or plant samples is meant a number sufficient to enable a comparison of genetic and metabolic profiles of individual endophytes.

Preferably, between approximately 10 and 1,000,000 endophytes are provided, more preferably between approximately 100 and 1,000 endophytes.

Phenotypic screens were established to select for novel ‘designer’ grass-endophyte associations. These screens were for desirable characteristics such as enhanced biotic stress tolerance, enhance drought tolerance and enhanced water use efficiency, and enhanced plant vigour.

Novel ‘designer’ endophytes were generated by targeted methods including polyploidisation and X-ray mutagenesis.

These endophytes may be characterised, for example using antifungal bioassays, in vitro growth rate assays and/or genome survey sequencing (GSS).

Metabolic profiling may also be undertaken to determine the toxin profile of these strains grown in vitro and/or following inoculation in planta.

These endophytes may be delivered into plant germplasm to breed ‘designer’ grass endophyte associations.

The endophytes may be subject to genetic analysis (genetically characterized) to demonstrate genetic distinction from known endophyte strains and to confirm the identity of endophyte strains artificially inoculated into, for example, grass plants, varieties and cultivars.

By ‘genetic analysis’ is meant analysing the nuclear and/or mitochondrial DNA of the endophyte.

This analysis may involve detecting the presence or absence of polymorphic markers, such as simple sequence repeats (SSRs) or mating-type markers. SSRs, also called microsatellites, are based on a 1-7 nucleotide core element, more typically a 1-4 nucleotide core element, that is tandemly repeated. The SSR array is embedded in complex flanking DNA sequences. Microsatellites are thought to arise due to the property of replication slippage, in which the DNA polymerase enzyme pauses and briefly slips in terms of its template, so that short adjacent sequences are repeated. Some sequence motifs are more slip-prone than others, giving rise to variations in the relative numbers of SSR loci based on different motif types. Once duplicated, the SSR array may further expand (or contract) due to further slippage and/or unequal sister chromatid exchange. The total number of SSR sites is high, such that in principle such loci are capable of providing tags for any linked gene.

SSRs are highly polymorphic due to variation in repeat number and are co-dominantly inherited. Their detection is based on the polymerase chain reaction (PCR), requiring only small amounts of DNA and suitable for automation. They are ubiquitous in eukaryotic genomes, including fungal and plant genomes, and have been found to occur every 21 to 65 kb in plant genomes. Consequently, SSRs are ideal markers for a broad range of applications such as genetic diversity analysis, genotypic identification, genome mapping, trait mapping and marker-assisted selection.

Known SSR markers which may be used to investigate endophyte diversity in perennial ryegrass are described in van Zijll de Jong et al (2003).

Alternatively, or in addition, the genetic analysis may involve sequencing genomic and/or mitochondrial DNA and performing sequence comparisons to assess genetic variation between endophytes.

The endophytes may be subject to metabolic analysis to identify the presence of desired metabolic traits.

By ‘metabolic analysis’ is meant analysing metabolites, in particular toxins, produced by the endophytes. Preferably, this is done by generation of inoculated plants for each of the endophytes and measurement of toxin levels in planta. More preferably, this is done by generation of isogenically inoculated plants for each of the endophytes and measurement of toxin levels in planta.

By a ‘desired genetic and metabolic profile’ is meant that the endophyte includes genetic and metabolic characteristics that result in a beneficial phenotype in a plant harbouring, or otherwise associated with, the endophyte.

Such beneficial properties include improved tolerance to water and/or nutrient stress, improved resistance to pests and/or diseases, enhanced biotic stress tolerance, enhanced drought tolerance, enhanced water use efficiency, reduced toxicity and enhanced vigour in the plant with which the endophyte is associated, relative to a control endophyte such as standard toxic (ST) endophyte or to a no endophyte control plant.

For example, tolerance to water and/or nutrient stress may be increased by at least approximately 5%, more preferably at least approximately 10%, more preferably at least approximately 25%, more preferably at least approximately 50%, more preferably at least approximately 100%, relative to a control endophyte such as standard toxic (ST) endophyte or to no endophyte control plant. Preferably, tolerance to water and/or nutrient stress may be increased by between approximately 5% and approximately 50%, more preferably between approximately 10% and approximately 25%, relative to a control endophyte such as ST or to a no endophyte control plant.

Such beneficial properties also include reduced toxicity of the associated plant to grazing animals.

For example, toxicity may be reduced by at least approximately 5%, more preferably at least approximately 10%, more preferably at least approximately 25%, more preferably at least approximately 50%, more preferably at least approximately 100%, relative to a control endophyte such as ST endophyte. Preferably, toxicity may be reduced by between approximately 5% and approximately 100%, more preferably between approximately 50% and approximately 100% relative to a control endophyte such as ST endophyte.

In a preferred embodiment toxicity may be reduced to a negligible amount or substantially zero toxicity.

For example, water use efficiency and/or plant vigour may be increased by at least approximately 5%, more preferably at least approximately 10%, more preferably at least approximately 25%, more preferably at least approximately 50%, more preferably at least approximately 100%, relative to a control endophyte such as ST or to a no endophyte control plant. Preferably, tolerance to water and/or nutrient stress may be increased by between approximately 5% and approximately 50%, more preferably between approximately 10% and approximately 25%, relative to a control endophyte such as ST or to a no endophyte control plant.

The methods of the present invention may be applied to a variety of plants. In a preferred embodiment, the methods may be applied to grasses, preferably forage, turf or bioenergy grasses such as those of the genera Lolium and Festuca, including L. perenne (perennial ryegrass) and L. arundinaceum (tall fescue).

The methods of the present invention may be applied to a variety of endophytes. In a preferred embodiment, the methods may be applied to fungi of the genus Neotyphodium, including N. lolii and N. coenophialum. In another preferred embodiment, the methods may be applied to fungi of the genus Epichloë, including E. festucae and E. typhina. However, the methods may also be used to identify endophytes of previously undescribed taxa.

Applicants have surprisingly found that endophyte E1 is a genetically novel, non-Neotyphodium lolii, endophyte. E1 is representative of an as yet un-named taxon. This finding is supported by mitochondrial and nuclear genome sequence analysis.

While applicants do not wish to be restricted by theory, on the basis of DNA specific content, the predicted alkaloid profile of E1 indicates that lolitrem B toxins deleterious to animal health are not produced by this endophyte. Endophyte E1 has the mating-type MAT1-1, the opposite mating-type to that carried by the N. lolii endophytes previously characterized. Endophyte E1 also has a high inoculation success rate in perennial ryegrass as compared to other endophytes.

Accordingly, in a second aspect, the present invention provides a substantially purified or isolated endophyte selected from the group consisting of E1, NEA10, NEA11 and NEA12, which were deposited at The National Measurement Institute, 1/153 Bertie Street, Port Melbourne, Victoria, Australia, 3207, on 5 Jan. 2010 with accession numbers V10/000001, V10/000002, V10/000003 and V10/000004, respectively. Replacement deposits were made on Apr. 15, 2016 in response to a notification of non-viability, and were assigned the same accession numbers.

The present invention also provides a substantially purified or isolated endophyte selected from the group consisting of NEA13 and NEA14, which were deposited at the National Measurement Institute, 1/153 Bertie Street, Port Melbourne, Victoria, Australia, 3207, on 23 Dec. 2010 with accession numbers V10/030285 and V10/030284, respectively. Replacement deposits were made on Apr. 15, 2016 in response to a notification of non-viability, and were assigned the same accession numbers.

In a further aspect the present invention provides a substantially purified or isolated endophyte having a desired toxin profile. Preferably the endophyte is isolated from a fescue species, preferably tall fescue. Preferably, the endophyte is of the genus Neotyphodium, more preferably it is from a species selected from the group consisting of N. uncinatum, N. coenophialum and N. lolii, most preferably N. coenophialum. The endophyte may also be from the genus Epichloe, including E. typhina, E. baconii and E. festucae. The endophyte may also be of the non-Epichloe out-group. The endophyte may also be from a species selected from the group consisting of FaTG-3 and FaTG-3 like, and FaTG-2 and FaTG-2 like.

By a ‘desired toxin profile’ is meant that the endophyte produces significantly less toxic alkaloids, such as ergovaline, compared with a plant inoculated with a control endophyte such as standard toxic (ST) endophyte; and/or significantly more alkaloids conferring beneficial properties such as improved tolerance to water and/or nutrient stress and improved resistance to pests and/or diseases in the plant with which the endophyte is associated, such as peramine, N-formylloline, N-acetylloline and norloline, again when compared with a plant inoculated with a control endophyte such as ST or with a no endophyte control plant.

For example, toxic alkaloids may be present in an amount less than approximately 11.1 g/g dry weight, for example between approximately 1 and 0.001 μg/g dry weight, preferably less than approximately 0.5 μg/g dry weight, for example between approximately 0.5 and 0.001 μg/g dry weight, more preferably less than approximately 0.2 μg/g dry weight, for example between approximately 0.2 and 0.001 μg/g dry weight.

For example, said alkaloids conferring beneficial properties may be present in an amount of between approximately 5 and 100 μg/g dry weight, preferably between approximately 10 and 50 μg/g dry weight, more preferably between approximately 15 and 30 μg/g dry weight.

In a particularly preferred embodiment, the present invention provides a substantially purified or isolated endophyte selected from the group consisting of NEA16, NEA17, NEA18, NEA19, NEA20, NEA21 and NEA23, which were deposited at The National Measurement Institute, 1/153 Bertie Street, Port Melbourne, Victoria, Australia, 3207, on 3 Apr. 2012 with accession numbers V12/001413, V12/001414, V12/001415, V12/001416, V12/001417, V12/001418 and V12/001419, respectively. Replacement deposits were made on Apr. 15, 2016 in response to a notification of non-viability, and were assigned the same accession numbers. Such endophytes may have a desired toxin profile as hereinbefore described.

In a further aspect the present invention provides an endophyte variant having a desired genetic and metabolic profile. Preferably the endophyte variant is generated by polyploidisation or induced chromosome doubling, for example by treating the endophyte with colchicine or a similar compound. Alternatively, the endophyte variant may be generated by X-ray mutagenesis or exposing the endophyte to ionising radiation, for example from a caesium source.

Preferably the endophyte which is treated to generate the endophyte variant is isolated from a Lolium species, preferably Lolium perenne. Preferably, the endophyte is of the genus Neotyphodium, more preferably it is from a species selected from the group consisting of N uncinatum, N coenophialum and N lolii, most preferably N lolii. The endophyte may also be from the genus Epichloe, including E typhina, E baconii and E festucae. The endophyte may also be of the non-Epichloe out-group. The endophyte may also be from a species selected from the group consisting of FaTG-3 and FaTG-3 like, and FaTG-2 and FaTG-2 like.

In a preferred embodiment, the endophyte variant may have a desired toxin profile. By a ‘desired toxin profile’ is meant that the endophyte produces significantly less toxic alkaloids, such as ergovaline, compared with a plant inoculated with a control endophyte such as standard toxic (ST) endophyte; and/or significantly more alkaloids conferring beneficial properties such as improved resistance to pests and/or diseases in the plant with which the endophyte is associated, such as peramine, N-formylloline, N-acetylloline and norloline, again when compared with a plant inoculated with a control endophyte such as ST or with a no endophyte control plant.

In a particularly preferred embodiment, the present invention provides an endophyte variant selected from the group consisting of NEA12dh5, NEA12dh6, NEA12dh13, NEA12dh14, and NEA12dh17, which were deposited at The National Measurement Institute, 1/153 Bertie Street, Port Melbourne, Victoria, Australia, 3207, on 3 Apr. 2012 with accession numbers V12/001408, V12/001409, V12/001410, V12/001411 and V12/001412, respectively. Replacement deposits were made on Apr. 15, 2016 in response to a notification of non-viability, and were assigned the same accession numbers. Such endophytes may have a desired genetic and metabolic profile as hereinbefore described.

In a preferred embodiment, the endlphyte may be substantially purified.

By ‘substantially purified’ is meant that the endophyte is free of other organisms. The term therefore includes, for example, an endophyte in axenic culture. Preferably, the endophyte is at least approximately 90% pure, more preferably at least approximately 95% pure, even more preferably at least approximately 98% pure.

The term ‘isolated’ means that the endophyte is removed from its original environment (eg. the natural environment if it is naturally occurring). For example, a naturally occurring endophyte present in a living plant is not isolated, but the same endophyte separated from some or all of the coexisting materials in the natural system, is isolated.

On the basis of the deposits referred to above, the entire genome of an endophyte selected from the group consisting of E1, NEA10, NEA11, NEA12, NEA13, NEA14, NEA21, NEA23, NEA18, NEA19, NEA16, NEA20, NEA12dh5, NEA12dh6, NEA12dh13, NEA12dh14 and NEA12dh17, is incorporated herein by reference.

Thus, in a further aspect, the present invention includes identifying and/or cloning nucleic acids including genes encoding polypeptides or transcription factors, for example transcription factors that are involved in sexual reproduction or vegetative hyphal fusion, in an endophyte. For example, the nucleic acids may encode mating-type genes, such as MAT1-1.

Methods for identifying and/or cloning nucleic acids encoding such genes are known to those skilled in the art and include creating nucleic acid libraries, such as cDNA or genomic libraries, and screening such libraries, for example using probes for genes of the desired type, for example mating-type genes; or mutating the genome of the endophyte of the present invention, for example using chemical or transposon mutagenesis, identifying changes in the production of polypeptides or transcription factors of interest, for example those that are involved in sexual reproduction or vegetative hyphal fusion, and thus identifying genes encoding such polypeptides or transcription factors.

Thus, in a further aspect of the present invention, there is provided a substantially purified or isolated nucleic acid encoding a polypeptide or transcription factor from the genome of an endophyte of the present invention. Preferably, the nucleic acid may encode a polypeptide or transcription factor that is involved in sexual reproduction or vegetative hyphal fusion in an endophyte.

In a preferred embodiment, the nucleic acid may include a mating-type gene, such as MAT1-1, or a functionally active fragment or variant thereof.

In a particularly preferred embodiment, the nucleic acid may include a nucleotide sequence selected from the group consisting of sequences shown in FIG. 1 hereto, and functionally active fragments and variants thereof.

By ‘nucleic acid’ is meant a chain of nucleotides capable of carrying genetic information. The term generally refers to genes or functionally active fragments or variants thereof and or other sequences in the genome of the organism that influence its phenotype. The term ‘nucleic acid’ includes DNA (such as cDNA or genomic DNA) and RNA (such as mRNA or microRNA) that is single- or double-stranded, optionally containing synthetic, non-natural or altered nucleotide bases, synthetic nucleic acids and combinations thereof.

By a ‘nucleic acid encoding a polypeptide or transcription factor’ is meant a nucleic acid encoding an enzyme or transcription factor normally present in an endophyte of the present invention.

By a ‘nucleic acid encoding a polypeptide or transcription factor involved sexual reproduction or vegetative hyphal fusion’ is meant a nucleic acid encoding an enzyme or transcription factor normally present in an endophyte of the present invention, which catalyses or regulates a step involved in sexual reproduction or vegetative hyphal fusion in the endophyte, or otherwise regulates sexual reproduction or vegetative hyphal fusion in the endophyte.

The present invention encompasses functionally active fragments and variants of the nucleic acids of the present invention. By ‘functionally active’ in relation to the nucleic acid is meant that the fragment or variant (such as an analogue, derivative or mutant) is capable of manipulating the function of the encoded polypeptide, for example by being translated into an enzyme or transcription factor that is able to catalyse or regulate a step involved in the relevant pathway, or otherwise regulate the pathway in the endophyte. For example, the fragment or variant may be capable of manipulating sexual reproduction or vegetative hyphal fusion in an endophyte, for example by being translated into an enzyme or transcription factor that is able to catalyse or regulate a step involved in sexual reproduction or vegetative hyphal fusion in the endophyte, or otherwise regulate sexual reproduction or vegetative hyphal fusion in the endophyte.

Such variants include naturally occurring allelic variants and non-naturally occurring variants. Additions, deletions, substitutions and derivatizations of one or more of the nucleotides are contemplated so long as the modifications do not result in loss of functional activity of the fragment or variant. Preferably the functionally active fragment or variant has at least approximately 80% identity to the relevant part of the above mentioned sequence to which the fragment or variant corresponds, more preferably at least approximately 90% identity, even more preferably at least approximately 95% identity, most preferably at least approximately 98% identity. Such functionally active variants and fragments include, for example, those having conservative nucleic acid changes. Examples of suitable nucleic acid changes are also shown in FIG. 1 hereto.

Preferably the fragment has a size of at least 20 nucleotides, more preferably at least 50 nucleotides, more preferably at least 100 nucleotides.

By ‘conservative nucleic acid changes’ is meant nucleic acid substitutions that result in conservation of the amino acid in the encoded protein, due to the degeneracy of the genetic code. Such functionally active variants and fragments also include, for example, those having nucleic acid changes which result in conservative amino acid substitutions of one or more residues in the corresponding amino acid sequence.

By ‘conservative amino acid substitutions’ is meant the substitution of an amino acid by another one of the same class, the classes being as follows:

- Nonpolar: Ala, Val, Leu, Ile, Pro, Met, Phe, Trp
- Uncharged polar: Gly, Ser, Thr, Cys, Tyr, Asn, Gln
- Acidic: Asp, Glu
- Basic: Lys, Arg, His

Other conservative amino acid substitutions may also be made as follows:

- Aromatic: Phe, Tyr, His
- Proton Donor: Asn, Gln, Lys, Arg, His, Trp
- Proton Acceptor: Glu, Asp, Thr, Ser, Tyr, Asn, Gln

In a further aspect of the present invention, there is provided a genetic construct including a nucleic acid according to the present invention.

By ‘genetic construct’ is meant a recombinant nucleic acid molecule.

In a preferred embodiment, the genetic construct according to the present invention may be a vector.

By a ‘vector’ is meant a genetic construct used to transfer genetic material to a target cell.

The vector may be of any suitable type and may be viral or non-viral. The vector may be an expression vector. Such vectors include chromosomal, non-chromosomal and synthetic nucleic acid sequences, eg. derivatives of plant viruses; bacterial plasmids; derivatives of the Ti plasmid from Agrobacterium tumefaciens; derivatives of the Ri plasmid from Agrobacterium rhizogenes; phage DNA; yeast artificial chromosomes; bacterial artificial chromosomes; binary bacterial artificial chromosomes; vectors derived from combinations of plasmids and phage DNA. However, any other vector may be used as long as it is replicable or integrative or viable in the target cell.

In a preferred embodiment of this aspect of the invention, the genetic construct may further include a promoter and a terminator; said promoter, gene and terminator being operatively linked.

By a ‘promoter’ is meant a nucleic acid sequence sufficient to direct transcription of an operatively linked nucleic acid sequence.

By ‘operatively linked’ is meant that the nucleic acid(s) and a regulatory sequence, such as a promoter, are linked in such a way as to permit expression of said nucleic acid under appropriate conditions, for example when appropriate molecules such as transcriptional activator proteins are bound to the regulatory sequence. Preferably an operatively linked promoter is upstream of the associated nucleic acid.

By ‘upstream’ is meant in the 3′->5′ direction along the nucleic acid.

The promoter and terminator may be of any suitable type and may be endogenous to the target cell or may be exogenous, provided that they are functional in the target cell.

A variety of terminators which may be employed in the genetic constructs of the present invention are also well known to those skilled in the art. The terminator may be from the same gene as the promoter sequence or a different gene. Particularly suitable terminators are polyadenylation signals, such as the (CaMV)35S polyA and other terminators from the nopaline synthase (nos) and the octopine synthase (ocs) genes.

The genetic construct, in addition to the promoter, the gene and the terminator, may include further elements necessary for expression of the nucleic acid, in different combinations, for example vector backbone, origin of replication (ori), multiple cloning sites, spacer sequences, enhancers, introns (such as the maize Ubiquitin Ubi intron), antibiotic resistance genes and other selectable marker genes [such as the neomycin phosphotransferase (nptII) gene, the hygromycin phosphotransferase (hph) gene, the phosphinothricin acetyltransferase (bar or pat) gene], and reporter genes [such as beta-glucuronidase (GUS) gene (gusA) and the green fluorescent protein (GFP) gene (gfp)]. The genetic construct may also contain a ribosome binding site for translation initiation. The genetic construct may also include appropriate sequences for amplifying expression.

Those skilled in the art will appreciate that the various components of the genetic construct are operably linked, so as to result in expression of said nucleic acid. Techniques for operably linking the components of the genetic construct of the present invention are well known to those skilled in the art. Such techniques include the use of linkers, such as synthetic linkers, for example including one or more restriction enzyme sites.

Preferably, the genetic construct is substantially purified or isolated.

By ‘substantially purified’ is meant that the genetic construct is free of the genes, which, in the naturally-occurring genome of the organism from which the nucleic acid or promoter of the invention is derived, flank the nucleic acid or promoter. The term therefore includes, for example, a genetic construct which is incorporated into a vector; into an autonomously replicating plasmid or virus; or into the genomic DNA of a prokaryote or eukaryote; or which exists as a separate molecule (eg. a cDNA or a genomic or cDNA fragment produced by PCR or restriction endonuclease digestion) independent of other sequences. It also includes a genetic construct which is part of a hybrid gene encoding additional polypeptide sequence.

Preferably, the substantially purified genetic construct is at least approximately 90% pure, more preferably at least approximately 95% pure, even more preferably at least approximately 98% pure.

The term “isolated” means that the material is removed from its original environment (eg. the natural environment if it is naturally occurring). For example, a naturally occurring nucleic acid present in a living plant is not isolated, but the same nucleic acid separated from some or all of the coexisting materials in the natural system, is isolated. Such nucleic acids could be part of a vector and/or such nucleic acids could be part of a composition, and still be isolated in that such a vector or composition is not part of its natural environment.

As an alternative to use of a selectable marker gene to provide a phenotypic trait for selection of transformed host cells, the presence of the genetic construct in transformed cells may be determined by other techniques well known in the art, such as PCR (polymerase chain reaction), Southern blot hybridisation analysis, histochemical assays (e.g. GUS assays), thin layer chromatography (TLC), northern and western blot hybridisation analyses.

The genetic constructs of the present invention may be introduced into plants or fungi by any suitable technique. Techniques for incorporating the genetic constructs of the present invention into plant cells or fungal cells (for example by transduction, transfection, transformation or gene targeting) are well known to those skilled in the art. Such techniques include Agrobacterium-mediated introduction, Rhizobium-mediated introduction, electroporation to tissues, cells and protoplasts, protoplast fusion, injection into reproductive organs, injection into immature embryos and high velocity projectile introduction to cells, tissues, calli, immature and mature embryos, biolistic transformation, Whiskers transformation, and combinations thereof. The choice of technique will depend largely on the type of plant or fungus to be transformed, and may be readily determined by an appropriately skilled person. For transformation of protoplasts, PEG-mediated transformation is particularly preferred. For transformation of fungi PEG-mediated transformation and electroporation of protoplasts and Agrobacterium-mediated transformation of hyphal explants are particularly preferred.

Cells incorporating the genetic constructs of the present invention may be selected, as described below, and then cultured in an appropriate medium to regenerate transformed plants or fungi, using techniques well known in the art. The culture conditions, such as temperature, pH and the like, will be apparent to the person skilled in the art. The resulting plants or fungi may be reproduced, either sexually or asexually, using methods well known in the art, to produce successive generations of transformed plants or fungi. In a further aspect, the present invention provides a plant inoculated with an endophyte or endophyte variant as hereinbefore described, said plant comprising an endophyte-free host plant stably infected with said endophyte or endophyte variant.

Preferably, the plant is infected with the endophyte or endophyte variant by a method selected from the group consisting of inoculation, breeding, crossing, hybridization and combinations thereof.

In a preferred embodiment, the plant may be infected by isogenic inoculation. This has the advantage that phenotypic effects of endophytes may be assessed in the absence of host-specific genetic effects. More particularly, multiple inoculations of endophytes may be made in plant germplasm, and plantlets regenerated in culture before transfer to soil.

The identification of an endophyte of the opposite mating-type that is highly compatible and stable in planta provides a means for molecular breeding of endophytes for perennial ryegrass. Preferably the plant may be infected by hyper-inoculation.

Hyphal fusion between endophyte strains of the opposite mating-type provides a means for delivery of favourable traits into the host plant, preferably via hyper-inoculation. Such strains are preferably selected from the group including an endophyte strain that exhibits the favourable characteristics of high inoculation frequency and high compatibility with a wide range of germplasm, preferably elite perennial ryegrass and/or tall fescue host germplasm and an endophyte that exhibits a low inoculation frequency and low compatibility, but has a highly favourable alkaloid toxin profile.

It has generally been assumed that interactions between endophyte taxa and host grasses will be species specific. Applicants have surprisingly found that endophyte from tall fescue may be used to deliver favourable traits to ryegrasses, such as perennial ryegrass.

In a further aspect of the present invention there is provided a method of analysing metabolites in a plurality of endophytes, said method including:

- providing:
  - a plurality of endophytes; and
  - a plurality of isogenic plants;
- inoculating each isogenic plant with an endophyte;
- culturing the endophyte-infected plants; and
- analysing the metabolites produced by the endophyte-infected plants.

By ‘metabolites’ is meant chemical compounds, in particular toxins, produced by the endophyte-infected plant, including, but not limited to, lolines, peramine, ergovaline, lolitrem, and janthitrems, such as janthitrem I, janthitrem G and janthitem F.

By Isogenic plants' is meant that the plants are genetically identical.

The endophyte-infected plants may be cultured by known techniques. The person skilled in the art can readily determine appropriate culture conditions depending on the plant to be cultured.

The metabolites may be analysed by known techniques such as chromatographic techniques or mass spectrometry, for example LCMS or HPLC. In a particularly preferred embodiment, endophyte-infected plants may be analysed by reverse phase liquid chromatography mass spectrometry (LCMS). This reverse phase method may allow analysis of specific metabolites (including lolines, peramine, ergovaline, lolitrem, and janthitrems, such as janthitrem I, janthitrem G and janthitem F) in one LCMS chromatographic run from a single endophyte-infected plant extract.

In another particularly preferred embodiment, LCMS including EIC (extracted ion chromatogram) analysis may allow detection of the alkaloid metabolites from small quantities of endophyte-infected plant material. Metabolite identity may be confirmed by comparison of retention time with that of pure toxins or extracts of endophyte-infected plants with a known toxin profile analysed under substantially the same conditions and/or by comparison of mass fragmentation patterns, for example generated by MS2 analysis in a linear ion trap mass spectrometer.

In a particularly preferred embodiment, the endophytes may be selected from the group consisting of E1, NEA10, NEA11, NEA12, NEA13, NEA14, NEA21, NEA23, NEA18, NEA19, NEA16 and NEA20.

In a particularly preferred embodiment, the endophyte variant may be selected from the group consisting of NEA12dh5, NEA12dh6, NEA12dh13, NEA12dh14, and NEA12dh17.

In a further aspect, the present invention provides a plant, plant seed or other plant part derived from a plant of the present invention and stably infected with an endophyte or endophyte variant of the present invention.

Preferably, the plant cell, plant, plant seed or other plant part is a grass, more preferably a forage, turf or bioenergy grass, such as those of the genera Lolium and Festuca, including L. perenne and L. arundinaceum.

By ‘plant cell’ is meant any self-propagating cell bounded by a semi-permeable membrane and containing plastid. Such a cell also required a cell wall if further propagation is desired. Plant cell, as used herein includes, without limitation, seeds suspension cultures, embryos, meristematic regions, callus tissue, leaves, roots, shoots, gametophytes, sporophytes, pollen and microspores.

In a further aspect, the present invention provides use of an endophyte or endophyte variant as hereinbefore described to produce a plant stably infected with said endophyte or endophyte variant.

In a still further aspect, the present invention provides a method of quantifying endophyte content of a plant, said method including measuring copies of a target sequence by quantitative PCR.

In a preferred embodiment, the method may be performed using an electronic device, such as a computer.

Preferably, quantitative PCR may be used to measure endophyte colonisation in planta, for example using a nucleic acid dye, such as SYBR Green chemistry, and qPCR-specific primer sets. The primer sets may be directed to a target sequence such as an endophyte gene, for example the peramine biosynthesis perA gene.

The development of a high-throughput PCR-based assay to measure endophyte biomass in planta may enable efficient screening of large numbers of plants to study endophyte-host plant biomass associations.

As used herein, except where the context requires otherwise, the term “comprise” and variations of the term, such as “comprising”, “comprises” and “comprised”, are not intended to exclude further additives, components, integers or steps.

Reference to any prior art in the specification is not, and should not be taken as, an acknowledgment or any form of suggestion that this prior art forms part of the common general knowledge in Australia or any other jurisdiction or that this prior art could reasonably be expected to be ascertained, understood and regarded as relevant by a person skilled in the art.

DETAILED DESCRIPTION OF THE EMBODIMENTS

In the figures:

FIG. 1 shows sequence alignment analysis of mating-type loci of endophyte strains E. festucae strain E2368, E1, NEA12 and ST. (SEQ ID Nos: 1-12)

FIG. 2A shows a UPGMA phenogram of genetic relationships among endophytes in ryegrass accessions of diverse origins and reference Neotyphodium and Epichloë species. Genetic identity was measured across 18 SSR loci using the Dice coefficient. Detailed annotations for sections A-D are shown in FIGS. 2B to 2E, respectively. Specifically, accessions analysed in this study are shaded in grey, the number of genotypes host to that endophyte strain from the total number of genotypes analysed are indicated in the round brackets and a representative host genotype is given in the square brackets. Endophyte isolates from the reference collection are specified in the square brackets following the species name. N. lolii Group 1 comprises of isolates Aries 1, Banks 5847, Ellett 5837, Fitzroy 2, Fitzroy 3, KT1-2, North African 6, Vedette 6645 and Victorian 2.

FIG. 3 shows isogenic inoculation methodology for endophyte inoculation. A. Meristem callus induction (4 weeks); B. Embryogenic callus proliferation (4 weeks); C. Shoot (and root) regeneration (5 days, 16 hours light); D. Endophyte inoculation; E. Plantlet growth (4 weeks, 16 hours light); F. Growth in soil (3 months); G. SSR-based analysis.

FIG. 4 shows the number of hits showing a given percent identity for 250 bp fragments of the NEA12 genome against the E. festucae and N. lolii genomes. The X-axis shows the percent identity, the Y-axis shows the number of hits. Black: N. lolii strain ST; White: E. festucae strain E2368.

FIG. 5 shows the number of hits showing a given percent identity for 250 bp segments of the E1 genome against the genomes of NEA12, E. festucae and N. lolii. The X-axis shows the percent identity, the Y-axis shows the number of hits. Black (1st bar in each group): E. festucae strain E2368; Grey (2nd bar in each group): Non-N. lolii strain NEA12; White (3rd bar in each group): N. lolii strain ST.

FIG. 6 shows the number of hits showing a given percent identity for 250 bp fragments of E1 against NEA12, E. festucae and N. lolii. The X-axis shows the percent identity, the Y-axis shows the number of hits expressed as a fraction of the total matches seen per comparison. Grey (1st bar in each group): E. festucae strain E2368; Black (2nd bar in each group): Non-N. lolii strain NEA12; White (3rd bar in each group): N. lolii strain ST.

FIG. 7 shows a schematic diagram of the mating-type loci in Neotyphodium/Epichloë.

FIG. 8 shows ClustalW analysis trees of the sequence flanking the mating-type loci (left), and the NoxR gene (cloned from E. festucae strain FL1 gi117413991; right).

FIG. 9 shows an alignment between mitochondrial genome of N. lolii strain Lp19 and a representative of the Clavicipitaceae, Metarhizium anisopliae (Genbank reference number NC_008068.1). While the two mitochondrial genomes vary in size, the genes are present in the same order and strand sense, with differences being due to variable insertions in the N. lolii mitochondrial genome.

FIG. 10 shows a depiction of part of the block structure of the mitochondrial genomes for each of the fungal endophytes sequenced in this study, as well as E. festucae strain E2368 and Metarhizium anisopliae for comparison. A shared block (e.g. b84) is present in all 12 mitochondria whereas block 85 is present only in the mitochondria of E. festucae strain E2368, and Non-N. lolii strains E1 and NEA12.

FIG. 11 shows a mitochondrial genome comparison. Parsimony tree of the relationships between the mitochondrial genomes of the 10 perennial ryegrass endophyte strains sequenced, E. festucae strain E2368 and Metarhizium anisopliae.

FIG. 12 shows a mitochondrial genome comparison. Neighbour joining tree analysis using ClustalW from a DNA alignment of the 40 blocks of sequence (˜40 kb) that are shared across the 10 perennial ryegrass endophyte strains sequenced, E. festucae strain E2368 and Metarhizium anisopliae.

FIG. 13 shows a standard curve for quantitative assessment of endophyte colonisation (copy number relative to total plant gDNA). (a) Tight clustering of amplification curves (4 technical replicates) ranging from 2×10²to 2×10⁶copies of the 73 bp perA amplicon. (b) Dissociation curve analysis of the amplification curves shown in (a), with the presence of a single peak indicating primer pair specificity. (c) Assay performance is determined in terms of efficiency, precision and sensitivity. For a typical reaction, a slope of −3.1 to −3.6 and R²value≧0.985 is acceptable. This assay recorded a slope of −3.2 and R²value of 0.999.

FIG. 14 shows a quantitative assessment of endophyte colonisation in diverse ryegrass host panel. (a) Standard curve of perA target sequence (2×10²to 2×10⁶) and amplification curves of the unknown samples. (b) Dissociation curve analysis of the amplification curves shown in (a). (c) Standard curve for perA target (▪) and unknown samples (▴).

FIG. 15 shows a colchicine kill curve of endophyte strain ST mycelia grown in potato dextrose broth at 22° C., 150 rpm for 21 days.

FIG. 16 shows phenotype of colchicine treated colonies (0.1 and 0.2%) of endophyte strain ST compared to the untreated ST control. Mycelia were grown on potato dextrose agar at 22° C. in dark.

FIG. 17 shows an assessment for changes in ploidy level by flow cytometry. a) Dot plots and histogram overlay of control samples, ST, 13E9301 and NEA11. b) Dot plots and histogram overlay of two individual ST colonies (13 and 14), showing a shift in peak location relative to the controls.

FIG. 18 shows high throughput PCR screening method for detection of lolitrem B gene deletion mutants. The lolitrem genes targeted include: ItmM (480 bp), ItmJ (734 bp) and ItmC (583 bp). M: EasyLadder1 (100-2000 bp); 1-13: Individual putative lolitrem B gene deletion mutants; ST: ST DNA (positive control for ItmM, ItmJ and ItmC); AR1: AR1 DNA (positive control for ItmM and ItmC, negative control for ItmJ); H₂O PCR control.

FIG. 19 shows geographical origins represented in the tall fescue endophyte incidence assessment. This graph shows the 40 different geographic origins represented in the incidence assessment. The X axis gives geographic origins in the alphabetical order and the Y axis shows the number of accessions. The number of negative accessions is shown with black and the number of positive accessions is shown in grey.

FIG. 20 shows UPGMA phenogram of genetic relationships among endophytes in tall fescue accessions of diverse origins and reference Neotyphodium, Epichloë, FaTG-2 and FaTG-3 species.

FIG. 21 shows production of the insecticidal alkaloids loline, loline formate and peramine by tall fescue endophytes in their endogenous host.

FIG. 22 shows production of the anti-mammalian alkaloids ergovaline and lolitrem B by tall fescue endophytes in their endogenous host.

FIG. 23 shows an example of antifungal bioassay of inhibition reactions. Testing for antifungal activity of endophyte NEA12, ST and AR1 against 8 species of pathogenic fungi.

FIG. 24 shows endophytes selected for metabolic profiling in in vitro culture. Shown in the top left hand corner is the inhibition score.

FIG. 25 shows a method for sampling material for LCMS analysis.

FIG. 26 shows a validation assay. Rhizoctonia cerealis was grown in the presence of methanol extracts of endophyte mycelia. Shown is an example using the endophyte strain ST. A. Methanol extract of ST grown in the absence of R. cerealis; B. Methanol extract ST grown in presence of R. cerealis; C. Water only control; D. Methanol only control.

FIG. 27 shows structures of endophyte metabolites

1 peramine (MW 247.3);

2 ergovaline (MW 533.6);

3 lolitrem B (MW 685.9);

4 janthitrem I (MW 645.8);

5 janthitrem G (MW 629.8);

6 janthitrem F (MW 645.8).

FIG. 28 shows LCMS analysis of standard materials displaying extracted ion chromatogram for the toxins:

A. peramine

- NL: 7.47E4
- Base Peak m/z=47.50-248.50 F: ITMS+c ESI Full ms
- [150.00-2000.00] MS
  
  B. ergovaline
- NL: 1.64E6
- Base Peak m/z=533.40-534.40 F: ITMS+c ESI Full ms
- [150.00-2000.00] MS
  
  C. lolitrem B

NL: 2.25E3

Base Peak m/z=685.50-687.00 F: ITMS+c ESI Full ms

[150.00-2000.00] MS

FIG. 29 shows an LCMS comparison of AR37 inoculated perennial ryegrass with NEA12 inoculated perennial ryegrass (IMP04 NEA12 20).

A. AR37 no peramine

- NL: 3.14E3
- Base Peak m/z=247.50-248.50 F: ITMS+c ESI
- Full ms [150.00-2000.00] MS
  
  B. AR37 no ergovaline
- NL: 7.39E4
- Base Peak m/z=533.40-534.40 F: ITMS+c ESI
- Full ms [150.00-2000.00] MS
  
  C. AR37 no lolitrem B
- NL: 1.32E4
- Base Peak m/z=685.50-687.00 F: ITMS+c ESI
- Full ms [150.00-2000.00] MS
  
  D. AR37 janthitrem
- NL: 8.68E4
- Base Peak m/z=645.50-646.50 F: ITMS+c ESI
- Full ms [150.00-2000.00] MS
  
  E. NEA12 no peramine
- NL: 6.18E3
- Base Peak m/z=247.50-248.50 F: ITMS+c ESI
- Full ms [150.00-2000.00] MS
  
  F. NEA12 no ergovaline
- NL: 4.10E3
- Base Peak m/z=533.40-534.40 F: ITMS+c ESI
- Full ms [150.00-2000.00] MS
  
  G. NEA12 no lolitrem B
- NL: 1.32E4
- Base Peak m/z=685.50-687.00 F: ITMS+c ESI
- Full ms [150.00-2000.00] MS
  
  H. NEA12 janthitrem
- NL: 1.04E4
- Base Peak m/z=645.50-646.50 F: ITMS+c ESI
- Full ms [150.00-2000.00] MS

FIG. 30 shows an MSMS analysis of NEA12 insulated perennial ryegrass metabolite 4. Inset is Table 2 from International patent application WO2004/106487 describing the fragmentations of the janthitrems found. Data for NEA12 metabolite 4 is in good agreement with that of component I in the table. (endo15June09-010 #3184 RT: 49.01 AV: 1 NL: 5.02E2, T: ITMS+cESId Full ms2 646.51@cid35.00 [165.00-660.00])

FIG. 31 shows Reverse phase liquid chromatography mass spectrometry (LCMS) analysis of A. TOLO3 NEA12 and B. TOLO3 ST. Profiles show the presence and absence of specific metabolites including peramine, ergovaline, lolitrem, and janthitrems.

FIG. 32 shows genotypic analysis of endophyte content in accessions from a targeted fescue germplasm collection.

FIG. 33 shows genetic diversity analysis of tall fescue endophytes.

FIG. 34 shows diversity analysis of host and endophyte.

FIG. 35 shows selection of fescue-endophyte combinations for metabolic profiling, endophyte isolation and isogenic inoculation.

FIG. 36 shows selection of fescue-endophyte combinations for metabolic profiling, endophyte isolation and isogenic inoculation.

FIG. 37 shows a desired toxin profile of tall fescue endophytes.

FIG. 38 shows a metabolic profile analysis.

FIG. 39 shows endophytes selected for semi-quantitative analysis of metabolites.

FIGS. 40 and 41 show metabolomics analyses of fescue endophytes.

FIG. 42 shows a semi-quantitative analysis of metabolic profile under temperature/water stress.

FIG. 43 shows endophytes selected for isogenic inoculation.

FIG. 44 shows SSR-based genotyping of isolated endophytes cultures prior to isogenic inoculation.

FIG. 45 shows endophyte vegetative stability in tall fescue and perennial ryegrass host genotypes (stability at 12 months post inoculation).

FIG. 46 shows endophytes selected for isogenic inoculation.

FIGS. 47-50 show metabolic profiling of isogenic tall fescue-endophyte associations.

FIG. 51 shows anti-fungal bioassays of fescue endophytes. Column 1 Colletotrichum graminicola, Column 2 Drechslera brizae, Column 3 Rhizoctonia cerealis.

FIG. 52 shows sequencing of selected novel fescue endophytes.

FIG. 53 shows peramine biosynthetic pathway.

FIGS. 54 A-C show presence of perA gene within non-Epichloe out-group endophytes (FIG. 54A NEA17; FIG. 54B NEA18; FIG. 54C NEA19).

FIG. 55 shows ergovaline biosynthetic pathway.

FIG. 56 shows genes in the eas gene cluster.

FIGS. 57 A-D show presence of dmaW gene for ergovaline biosynthesis in endophyte strains (FIG. 57A NEA17; FIG. 57B NEA16; FIG. 57C AR542; FIG. 57D NEA20).

FIGS. 58 A-D show presence of eas gene cluster for ergovaline biosynthesis. FIG. 58A FaTG-2 NEA17 (287819); FIG. 58B non-Epichloe out-group NEA18 (FEtc6-75); FIG. 58C FATG-3 NEA21 (231557); FIG. 58DN. coenophialum NEA16 (FEtc7-342).

FIG. 59 shows the Lolitrem B biosynthetic pathway.

FIG. 60 shows genes in the Lolitrem B biosynthetic gene cluster.

FIGS. 61 A-D show presence of Lolitrem B biosynthetic gene cluster 1 (ItmG, ItmM and ItmK) in endophyte strains. FIG. 61A FaTG-2 NEA17 (287819); FIG. 61B non-Epichloe out-group NEA18 (FEtc6-75); FIG. 61C FATG-3 NEA21 (231557); FIG. 61DN. coenophialum NEA16 (FEtc7-342).

FIGS. 62 A-D show presence of Lolitrem B biosynthetic gene cluster 2 (ItmB, ItmQ, ItmP, ItmF and ItmC) in endophyte strains. FIG. 62A FaTG-2 NEA17 (287819); FIG. 62B non-Epichloe out-group NEA18 (FEtc6-75); FIG. 62C FATG-3 NEA21 (231557); FIG. 62DN. coenophialum NEA16 (FEtc7-342).

FIGS. 63 A-D show presence of Lolitrem B biosynthetic gene cluster 3 (ItmE and ItmJ) in endophyte strains. FIG. 63A FaTG-2 NEA17 (287819); FIG. 63B non-Epichloe out-group NEA18 (FEtc6-75); FIG. 63C FATG-3 NEA21 (231557); FIG. 63DN. coenophialum NEA16 (FEtc7-342).

FIG. 64 shows the loline biosynthetic pathway.

FIG. 65 shows the loline biosynthetic gene cluster.

FIGS. 66 A-D show presence of Loline biosynthetic gene cluster in endophyte strains. FIG. 66A FaTG-2 NEA17 (287819); FIG. 66B non-Epichloe out-group NEA18 (FEtc6-75); FIG. 66C FATG-3 NEA21 (231557); FIG. 66DN. coenophialum NEA16 (FEtc7-342).

FIGS. 67 A-F show alkaloid biosynthetic gene analysis for endophyte strain NEA23 (269850). FIG. 67A Presence of loline gene cluster; FIG. 67B Presence of peramine gene; FIG. 67C Analysis of Lolitrem gene cluster 01; FIG. 67D Analysis of Lolitrem gene clusters 02 and 03; FIG. 67E Analysis of dmaW gene for ergovaline production; FIG. 67F Analysis of eas gene cluster for ergovaline production.

FIG. 68 shows genotypic analysis of NEA23 and NEA21.

FIG. 69 shows genotypic analysis of NEA16 and NEA20.

FIG. 70 shows the structures of Lolitrem B, Erogvaline and Peramine, with desirable toxin profiles indicated.

FIG. 71 shows in vitro bioassays to assess antifungal activity of Neotyphodium endophytes.

FIG. 72 shows a detached leaf assay to assess resistance to crown rust (Puccinia coronata f. sp. Lolii) of perennial ryegrass plants with and without Neotyphodium endophytes.

FIG. 73 shows glasshouse and field trial screens for drought tolerance and water use efficiency of perennial ryegrass plants with and without Neotyphodium endophytes.

FIG. 74 shows the steps involved in cell division.

FIG. 75 shows experimental work flow for chromosome doubling of endophyte cells.

FIG. 76 shows flow cytometry calibrations for DNA content assessment in Neotyphodium endophyte strains. Peaks indicate relative nuclear DNA content.

FIG. 77 shows flow cytometry analysis of NEA12^dhNeotyphodium endophyte strains.

FIG. 78 shows analysis of growth rate in culture after 8 weeks of NEA12^dhNeotyphodium endophyte strains compared to control endophyte strains.

FIG. 79 shows analysis of growth rate in culture over 5 weeks of NEA12^dhNeotyphodium endophyte strains compared to control endophyte strains.

FIG. 80 shows antifungal bioassays of NEA12^dhNeotyphodium endophyte strains.

FIG. 81 shows antifungal bioassays of NEA12^dhNeotyphodium endophyte strains.

FIG. 82 shows analysis of genome survey sequencing read depth of colchicine-treated Neotyphodium endophyte strains.

FIG. 83 shows analysis of genome survey sequencing reads mapping to NEA12 genome survey sequence assembly.

FIG. 84 shows experimental work flow for X-ray mutagenesis.

FIG. 85 shows the indole-diterpene biosynthetic pathway of Neotyphodium endophytes.

FIG. 86 shows in vitro growth of X-ray irradiated Neotyphodium endophyte strains.

FIG. 87 shows Itm gene clusters of Neotyphodium endophytes.

FIG. 88 shows determination of genome sequence variation in X-ray irradiated Neotyphodium endophyte strains.

FIG. 89 shows single nucleotide polymorphisms (SNPs) in genome sequences of X-ray irradiated Neotyphodium endophyte strains. (SEQ ID Nos. 22-47)

FIG. 90 shows small insertions/deletions (INDELs) in genome sequences of X-ray irradiated Neotyphodium endophyte strains. (SEQ ID Nos.48-85)

FIG. 91 shows deletions in genome sequences of X-ray irradiated Neotyphodium endophyte strains.

FIG. 92 shows numbers of SNPs in genic regions of genome sequences of X-ray irradiated Neotyphodium endophyte strains.

FIG. 93 shows numbers of INDELs in genic regions of genome sequences of X-ray irradiated Neotyphodium endophyte strains.

FIG. 94 shows the spectrum of genome sequence changes (deletions) in genome sequences of X-ray irradiated Neotyphodium endophyte strains.

FIG. 95 shows mutagenesis index of X-ray irradiated strains based on number of genome sequence changes observed in genome sequences of X-ray irradiated Neotyphodium endophyte strains.

FIG. 96 shows metabolic profiling of NEA12^dhNeotyphodium endophyte strains.

FIG. 97 shows metabolic profiling of X-ray irradiated Neotyphodium endophyte strains.

EXAMPLE 1—IDENTIFICATION OF NOVEL ENDOPHYTES

A collection of 244 perennial grass accessions was assembled for the discovery of novel endophyte strains. The collection targeted accessions from the Northern Mediterranean and Eastern Europe for endophytes that lack lolitrems, as well as accessions from the Middle East, the proposed centre of origin of perennial ryegrass and N. lolii.

Genotypic analysis of endophyte content was performed across a total of 189 accessions. From each accession 1-5 plant genotypes were analysed for endophyte. Endophyte incidence was low, with endophyte detected in 51% of accessions. Endophyte was consistently detected (with 0 SSR markers) in 77 of the accessions.

Endophytes representing five different taxa were detected across the 77 accessions with 18 SSR markers used to investigate endophyte diversity in perennial ryegrass (FIG. 2). N. lolii was predominant, occurring in 63 accessions. Also detected, although less common, were LpTG-2 and putatively new taxa.

Genetic variation in N. lolii appeared to be low. A total of 22 unique genotypes were detected across the 63 accessions host to N. lolii.

The likely toxin profiles of 14 of the 22 genotypes were established from comparisons with genetic and phenotypic data from previous studies. Most of these genotypes (12/14) showed genetic similarity to endophytes known to produce lolitrems.

There were two genotypes that showed genetic similarity to genotypes known to lack lolitrems but produce ergovaline. One of these genotypes was identical to the genotype detected in the endophyte NEA6. The likely toxin profiles of the remaining eight genotypes were not known. These genotypes did not show high levels of genetic similarity to the endophytes AR1, Endosafe, NEA3 or NEA5.

Plants carrying candidate endophytes were subjected to primary metabolic profiling in the endogenous genetic background, through clonal propagation and measurement of toxin levels. A total of 42 genotypes representing four of the five taxa were selected for toxin profiling, including the eight novel genotypes with unknown toxin profiles. The perennial ryegrass genotype North African 6 (NA₆), which contains standard toxic (ST) endophyte, was used as a control.

For metabolic profiling, a complete randomised block design was used, with four replicate clones for each plant and using four hydroponics tubs as blocks. Following three months in hydroponics, whole shoot (leaf plus basal region) was harvested from each plant. The fresh and dry weights of each plant were measured and powdered sample material from 80 (20 genotypes×4 replicates) samples (three tillers per sample) analysed for alkaloid content (lolitrem, ergovaline and peramine).

EXAMPLE 2—CANDIDATE ENDOPHYTES

Candidate endophytes for further study were chosen on the basis of their genetic identity and metabolic profile. Host-endophyte combinations producing significant amounts of lolitrem B were eliminated, as the ryegrass staggers syndrome produced by this alkaloid is the most important limitation for livestock production.

The candidate endophyte NEA10 (originating from Spain) was identified as a novel genotype in this analysis with an unknown toxin profile. Its genetic identity is a unique N. lolii strain. Following in planta metabolic profiling analysis, candidate endophyte NEA10 was found to produce ergovaline and peramine, and not lolitrem B.

The candidate endophyte NEA11 (originating from France) was identified as a novel genotype in this analysis with an unknown toxin profile. Its genetic identity is a unique LpTG-2 strain. Following in planta metabolic profiling analysis, candidate endophyte NEA11 was found to produce ergovaline and peramine, and not lolitrem B.

The candidate endophyte NEA12 (originating from France) was identified as a novel genotype in this analysis with an unknown toxin profile. NEA12 is a genetically novel, non-Neotyphodium lolii, endophyte representative of an as yet un-named taxon. Following in planta metabolic profiling analysis, candidate endophyte NEA12 was found to not produce the three alkaloids assessed (lolitrem B, ergovaline and peramine).

The candidate endophyte E1 was identified as a novel genotype in this analysis with an unknown toxin profile. E1 is a genetically novel, non-Neotyphodiumlolii, endophyte representative of an as yet un-named taxon. Following in planta metabolic profiling analysis, candidate endophyte E1 was found to not produce the three alkaloids assessed (lolitrem B, ergovaline and peramine).

EXAMPLE 3—METHODOLOGIES FOR ENDOPHYTE CHARACTERISATION
Endophyte Isolation

Novel candidate endophytes were isolated from their host plant to establish an in vitro culture. Following isolation, the genotype of each endophyte was confirmed by SSR analysis to ensure a high level of quality control prior to inception of isogenic inoculations.

Establishment of Meristem Cultures for a Diverse Perennial Ryegrass Host Panel

A set of cultivars representing elite germplasm were obtained, including forage and turf types. Meristem cultures from different cultivars were established to evaluate and compare the phenotypic properties of novel endophyte strains in diverse isogenic host backgrounds. Embryogenic genotypes were identified for each of the cultivars through callus induction and proliferation. Subsequent regeneration of embryogenic genotypes identified primary tissue culture responsive (pTCR) genotypes for each of the cultivars. The number of pTCR genotypes with regeneration frequencies ranging from 80-100% varied from 1-4 per cultivar. pTCR genotypes were then prepared for meristem-derived callus induction to identify highly regenerable genotypes for isogeneic endophyte inoculation. Table 1 shows a selection of cultivars developed, and the tissue culture responsive (TCR) genotype, used for isogenic inoculation.

TABLE 1

Summary information for perennial cultivars

selected for isogenic inoculation.

TCR genotype used

Cultivar
Characteristics
for inoculation

Bealey
Tetraploid forage type
Bea 02

Bronsyn
Standard forage type with robust
Bro 08

endophyte performance

Impact
Late flowering, dense tillering
Imp 04

forage type

Barsandra
Turf type
San 02

Tolosa
Distinct forage type
Tol 03

Isogenic Inoculation of Novel Perennial Ryegrass Endophytes

In order to accurately determine the phenotypic effects of different candidate endophytes in the absence of host-specific genetic effects, a system for isogenic inoculation was developed (FIG. 3). The regenerating callus method of inoculation was chosen, as it results in a relatively high rate of inoculation compared to other tested techniques, and the achieved isogenic inoculation rate was similar to the standard inoculation procedure for non-isogenic seedlings. Novel candidate endophytes NEA10, NEA11, NEA12, E1 and control endophyte ST were individually inoculated into elite germplasm. The logistical approach was to inoculate two cultivars at any given time, with one TCR genotype for each variety chosen for inoculation in this initial study. For each cultivar-endophyte combination, 30 replicate inoculations were performed, 25 of these replicates being transferred to soil. Following inoculation and plantlet regeneration in culture, plants were transferred to soil for three months to allow establishment of endophyte and host-plant associations. After this period, three tillers from each plant were sampled and tested for endophyte presence using SSR-based analysis.

A quantitative score was used to assess endophyte inoculation frequency (Table 2). Three diagnostic SSR markers were used to determine endophyte presence and identity and samples were scored on a scale of 0-3.

Of the 570 inoculations tested, 195 (34.2%) could be positively scored with a high degree of confidence (Table 3). Successful inoculations are listed on Table 3.

TABLE 2

SSR screening for endophyte presence in planta.

Quantitative
Alleles present and of correct

score
size for given SSR loci

3
Endophyte present

2
Endophyte present

1
Endophyte absent

0
Endophyte absent

TABLE 3

Summary statistics for isogenic inoculation of selected candidate

endophytes into a targeted perennial ryegrass panel of 5 hosts.

NEA10
NEA11
NEA12
E1
ST
Total

A. Number of positive inoculants

Bea02
0
12
3
4
8
27

Bro08
0
14
1
13
13
41

Imp04
3
40
4
10
16
73

San02
0
17
6
6
11
40

Tol03
0
3
2
6
3
14

Total
3
86
16
39
51
195

B. Total number of inoculations tested

Bea02
24
18
20
19
25
106

Bro08
19
15
20
18
25
97

Imp04
31
49
21
12
35
148

San02
47
39
24
7
32
149

Tol03
17
7
18
17
11
70

Total
138
128
103
73
128
570

C. Percent of positive inoculants

Bea02
0.0
66.7
15.0
21.1
32.0
25.5

Bro08
0.0
93.3
5.0
72.2
52.0
42.3

Imp04
9.7
81.6
19.0
83.3
45.7
49.3

San02
0.0
43.6
25.0
85.7
34.4
26.8

Tol03
0.0
42.9
11.1
35.3
27.3
20.0

Average
2.2
67.2
15.5
53.4
39.8
34.2

Variation in inoculation success according to candidate endophyte identity was observed (Table 3). Endophyte NEA10 (2.2%), for example, exhibited relatively lower success rates as compared to NEA11 (67.2%), or the commercial endophyte ST (39.8%; Table 4) and only formed stable associations with one of the five hosts in the panel (Impact). Endophyte E1 is a highly compatible endophyte, which obtained a high rate of success of inoculation into perennial ryegrass (Table 3) compared to other endophytes examined, including the strain ST.

Variation was also observed between host plant genotypes for successful inoculations (Table 3). Tolosa (20.0%) appears to be more recalcitrant to inoculation compared to host plants such as Bronsyn (42.3%) and Impact (49.3%).

Vegetative Stability of Isogenic Perennial Ryegrass-Fungal Endophyte Associations

Fully confirmed endophyte positive plants from the targeted host-endophyte panel (host plants Bealey, Bronsyn, Barsandra, Tolosa and Impact; endophytes ST, NEA10, NEA11, NEA12) were retested 6-12 months after inoculation and 18-24 months after inoculation, to confirm the presence of endophyte and to assess vegetative stability. In this experiment, 3 replicates of 3 tillers each (total of 9 tillers) were collected for SSR-based analysis.

Most of the previously confirmed endophyte positive plants were again confirmed in this study at 6-12 months post inoculation, indicating that each of the host-endophyte combinations were stable (Table 4). Endophyte NEA12 appears to be less stable in planta, as 7 of the 13 previously confirmed samples could not be fully confirmed in this experiment (Table 4). ST also showed lower levels of stability compared to NEA11, with 7/21 samples not re-confirmed in this study (Table 4). Following this analysis, up to three independent inoculation events from each host plant-endophyte combination were retained for further study.

At 18-24 months post inoculation, plants were further assessed for long term vegetative stability (Table 4). ST, NEA10 and NEA11 each exhibit stable associations, with most plants retaining endophyte. NEA12 appears to be less stable in some associations, however does form stable long term associations with Tolosa.

TABLE 4

Endophyte frequency in priority ryegrass host panel genotypes in re-

sampled plants that were previously fully confirmed. Plants were re-

sampled 6-12 months (shown in bold text) post inoculation and again

after 18-24 months post inoculation (shown in normal text).

Plant
Endophyte genotype

genotype
ST
NEA10
NEA11
NEA12

Impact
9/10

2/3

12/12

1/4

(Imp04)
3/3
2/2
3/3
1/1

Barsandra

4/6

7/7

2/4

(San02)
2/3
NA
3/3
1/2

Tolosa

1/2

3/3

2/2

(Tol03)
1/1
NA
2/3
2/2

Bealey

3/3

9/9

0/2

(Bea02)
2/3
NA
3/3
0/1

Bronsyn

3/6

9/9

1/1

(Bro08)
2/2
NA
4/4
0/1

NA = not applicable, as no fully confirmed plants were previously identified.

Metabolic Profiling of Isogenic Perennial Ryegrass-Fungal Endophyte Associations

Metabolic profiling was conducted to determine the stability of the predicted endophyte phenotype in a range of different host genotype backgrounds. Four replicates of three tillers each were grown under optimal conditions in hydroponics for six weeks prior to measuring lolitrem B, ergovaline and peramine levels. Each replicate plant was also tested for the presence/identity of endophyte using SSR-based genotyping in order to correlate toxin profile with endophyte presence, in particular for those instances were toxin profiles were negative for the alkaloids measured.

Table 5 summarises the outcomes of metabolic profiling in hydroponics for both the endophyte discovery phase and the isogenic inoculation phase. Toxin profiles were as predicted from the cluster assignment of the endophyte in the diversity analysis and the toxin profiles measured in the endogenous host plant.

TABLE 5

Metabolic profile of candidate endophytes.

Endophyte
Endogenous
Isogenic

strain
toxin profile
toxin profile^b
Origin
Species

NEA10
—/E/n.d^a/—
—/E/P/—
Spain

N. lolii

NEA11
—/E/n.d/—
—/E/P/—
France
LpTG-2

NEA12
—/—/—/n.d
—/—/—/J
France
non-N. lolii

E1
n.d
—/—/—/—

non-N. lolii

ST
L/E/P/—
L/E/P/—

N. lolii

Toxins are listed in order: L = Lolitrem B; E = Ergovaline; P = Peramine; J = Janthitrems

^aPeramine not measured in NEA10 and NEA11 samples; Janthitrems not measured in NEA12 samples

^bToxin profile in isogenic associations

Genome Survey Sequencing of Candidate Fungal Endophytes
Nuclear Genome Assembly

Genome Survey Sequencing was performed for non-N. lolii strains NEA12 and E1, LpTG-2 strain NEA11 and Neotyphodium lolii strains including Standard Toxic (ST) and NEA10 using GSFLX Titanium (TI-GSFLX) pyrosequencing technology (Roche; as per manufacturers instructions). A further five N. lolii strains were sequenced using either GSFLX Standard or GS20 pyrosequencing technology. Genome assembly for each of the strains was conducted with GSFLX De Novo Assembler (Table 6).

A new genome assembly was performed for N. lolii strain ST (GSFLX De Novo Assembler), combining sequence reads from both GSFLX and TI-GSFLX runs. Table 7 compares the assembly of single and multiple strains. This combined assembly of the ST genome achieves c.12× coverage of the c.32 Mbp haploid genome. The genome is assembled into 7,875 large contigs (0.5 to 47 kb) of which the net length is 31,750,111 bp.

Analysis using Augustus gene prediction software trained for Fusarium graminearum shows that there are 11,517 predicted protein coding genes in the N. lolii genome.

TABLE 6

Summary statistics for GS-FLX based whole genome sequencing of candidate endophytes.

N. lolii

N. lolii

N. lolii

N. lolii

N. lolii

N. lolii

Lp19
ST
NEA3
AR1
E9
G4

Genome size (Mb)
~29
~29
~29
~29
~29
~29

Toxin profile^a
L + E + P
L + E + P
E + P
P
L + P
L + P

454 Sequencer
GS20
GSFLX
GSFLX
GSFLX
GSFLX
GSFLX

Standard
Standard
Standard
Standard
Standard

Number of sequencing runs
1
1
1
1
1
1½

Number of high quality reads
449,408
288,527
361,154
437,465
344,074
631,248

Number of bases in high quality reads
47,820,858
71,810,513
84,032,924
97,510,674
85,419,382
146,574,403

Average read length (bases)
106
249
232
223
249
215

Origin of reads assembled^b
nuclear +
nuclear +
nuclear +
nuclear + mt
nuclear + mt
nuclear +

mt
mt
mt

mt

Large contigs (>500 bases)

Number of contigs
6
2,524
5,251
6,070
6,612
12,663

number of bases
99,508
1,834,624
3,911,733
4,650,113
5,208,116
12,393,467

average contig size
16,584
726
744
766
787
978

N50 contig size
88,709
680
723
751
774
1039

largest contig size (bases)
88,709
65,108
15,473
19,024
81,839
29,071

All contigs

number of contigs
29,013
28,137
33,262
33,777
33,136
32,796

number of bases
3,532,954
7,999,326
10,842,510
11,755,707
12,022,601
17,790,671

N. lolii

N. lolii

non-N. lolii
non-N. lolii
LpTG-2

NEA10
ST
E1
NEA12
NEA11

Genome size (Mb)
~29
~28
TBD
TBD
~55

Toxin profile^a
E + P
L + E + P
TBD
J
E + P

454 Sequencer
GSFLX
GSFLX
GSFLX
GSFLX
GSFLX

Titanium
Titanium
Titanium
Titanium
Titanium

Number of sequencing runs
½
1
½
½
½

Number of high quality reads
580,060
1,220,036
539,019
399,868
456,111

Number of bases in high quality reads
221,859,987
451,459,919
202,854,865
165,826,144
177,307,015

Average read length (bases)
383
370
377
415
389

Origin of reads assembled^b
nuclear + mt
nuclear
nuclear +
nuclear +
nuclear +

mt
mt
mt

Large contigs (>500 bases)

Number of contigs
7,272
4,198
9,139
12,399
14,791

number of bases
26,931,240
24,382,151
27,150,736
17,300,350
16,306,033

average contig size
3703
5,808
2970
1,395
1,102

N50 contig size
7668
11,026
5845
1,703
1,214

largest contig size (bases)
50,291
90,675
40,456
16,319
59,986

All contigs

number of contigs
11,809
6,962
15,589
20,640
39,791

number of bases
28,155,780
25,104,969
28,916,589
19,862,340
23,307,237

^aL = Lolitrem B, E = Ergovaline, P = Peramine, J = Janthitrems

^bNewbler Assembler

TABLE 7

Assembly comparison of single and multiple strains of N. lolii endophyte

Lp19
ST
NEA3
AR1
E9
G4

454 Sequencer
GS 20
GS FLX
GS FLX
GS FLX
GS FLX
GS FLX

(Standard)
(Standard)
(Standard)
(Standard)
(Standard)

Number of sequencing runs
1
1^a
1
1
1^a
1^b

Number of reads
282,604
191,848
257,381
311,444
267,445
446,017

Number of bases in reads
28,628,965
46,613,713
58,666,512
68,947,121
65,192,155
101,770,051

Large contigs (≧500 bases)

number of contigs
109
1,419
3,210
3,519
4,560
11,895

number of bases
124,393
909,187
2,111,227
2,317,893
3,041,084
9,249,140

average contig size
1,141
640
657
658
666
777

N50 contig size^c
1,193
606
632
636
644
774

largest contig size (bases)
7,867
8,639
7,382
8,816
8,016
8,226

Q40 plus bases (%)^d
90.62
93.97
93.43
93.90
93.72
94.64

All contigs (≧100 bases)

number of contigs
2,183
8,769
12,434
15,324
15,126
28,456

number of bases
500,187
2,911,985
4,778,407
5,584,622
6,123,678
14,307,808

ST
combined ST
ST + NEA3 + AR1 + E9 + G4

454 Sequencer
GS FLX
GS FLX
GS FLX

(Titanium)
(Standard + Titanium)
(Standard)

Number of sequencing runs
1
2
5

Number of reads
913,566
1,105,414
1,474,135

Number of bases in reads
334,946,727
381,560,440
341,189,552

Large contigs (≧500 bases)

number of contigs
8,825
7,875
11,905

number of bases
31,669,111
31,750,111
26,515,831

average contig size
3,588
4,031
2,227

N50 contig size^c
6,142
7,231
3,435

largest contig size (bases)
46,664
46,668
24,527

Q40 plus bases (%)^d
98.03
98.52
98.32

All contigs (≧100 bases)

number of contigs
11,324
10,555
21,836

number of bases
32,350,205
32,482,543
29,165,397

Alkaloid Biosynthetic Gene Content

The content of genes known to be involved in alkaloid production in each of the sequenced endophyte genomes was investigated. Sequence reads for each of the strains were subjected to a BLAST(N) search against each of the known toxin gene sequences (downloaded from NCBI) to determine the degree of gene coverage by sequence reads. Table 8 below shows the correlation between secondary metabolite production and toxin-related gene content in endophyte genomes.

Based on this analysis, endophyte strain E1 is predicted to produce the alkaloids peramine and ergovaline, but not loline or lolitrem B. In planta analysis of alkaloid content has shown that E1 does indeed not produce loline or lolitrem B.

NEA10 and NEA11 produce ergovaline and peramine, but not lolitrem B. The NEA11 sequence provides evidence for 2 peramine biosynthesis genes, as might be expected in a heteroploid genome.

NEA12, known to lack production of ergot alkaloids and lolitrem B, also lacks corresponding biosynthetic genes.

Nuclear Genome Comparison

Comparison of the NEA12 Nuclear Genome to E. festucae E2368 and N. Lolii ST

To compare the nuclear genome of NEA12 to E. festucae and N. lolii, the contigs derived from NEA12 were split into 250 bp segments and these segments were used as BLAST(N) queries against E. festucae strain E2368 (University of Kentucky, http://www.genome.ou.edu.fungi.html) and N. lolii ST contigs. One hit was scored for each 250 bp contig if it was greater than 50 bp long and greater than 80% identity. Summary statistics were taken for NEA12 250 bp fragments against E. festucae and N. lolii (FIG. 4).

The number of hits showing a given percent identity shows there are more 250 bp segments that give 100 percent identity matches against an E. festucae genome than a N. lolii genome.

The above statistic is independent of the length of the overlap. An identical 250 bp region would give a 250 bp overlap with a percent identity of 100. The number and proportion of these identical reads is given for the two searches below (Table 9).

TABLE 9

The number and proportion of identical reads between NEA12

and an E. festucae genome and a N. lolii genome.

ST

E. festucae

Total

Number of identical reads
16914
28866
89416

(100% identity between

250 bp segment)

Percent of identical reads
18.92
32.28

(100% identity between

250 bp segment)

There are also segments that have no match to either N. lolii (6051) or E. festucae (5670). These data suggest that NEA12 is a new endophyte taxon that is genetically closer to E. festucae than N. lolii. This data supports the earlier observation, using SSR-based genetic diversity analysis, that NEA12 is genetically distinct from N. lolii and E. festucae.

Comparison of E1 Nuclear Genome to NEA12, E. Festucae E2368 and N. lolii ST

For comparison at the whole genome level, the contigs from endophyte strain E1 were split into 123,258 250 bp segments. Each 250 bp segment was used as a BLAST(N) query against the assembled whole genome DNA sequences from NEA12, E. festucae E2368 and N. lolii ST (FIG. 5). A BLAST(N) hit was recorded if there was an overlap of greater than 49 bp. The number of overlaps at a given percent identity was counted for each search. The plot of this data reveals that the genome of endophyte strain E1 is more similar to that of E. festucae strain E2368 than to either N. lolii strain ST or NEA12.

The assembled contigs from NEA12 sum to c.17.3 Mb, so the level of sequence similarity to that endophyte is probably underestimated due to limited scope for comparison. If the similarity is expressed as a fraction of the total matches observed per comparison, strain E1 is seen to be more similar to strain NEA12 than to N. lolii strain ST (FIG. 6). The property of enhance similarity between E1 and E. festucae as compared to N. lolii is similar to the pattern seen with mitochondrial genome analysis.

LpTG-2 Endophyte NEA11

The LpTG-2 endophyte strain NEA11 is reported to be a hybrid of N. lolii and E. typhina. Mitochondrial sequence analysis supports the hybridisation of E. typhina with a N. lolii with only the N. lolii mitochondria being retained.

Evidence for the hybrid nuclear genome is seen when nuclear genes are used as a query against contigs from the NEA11 genome assembly (FIGS. 7 and 8).

The panels below show a region of the ‘UDP-N-acetylglucosaminyltransferase’ gene from E. festucae being used as a BLAST(N) query against: E. festucae (E2368) genome contigs; N. lolii (ST) genome contigs; and LpTG-2 (NEA11) genome contigs. This result clearly shows a second variant of this gene in the NEA11 genome that has far more SNPs than the first NEA11 contig hit. This presumably represents the E. typhina copy of this gene that has been retained in the NEA11 genome. It is unlikely that this is a localised duplication in NEA11 as neither E. festucae, nor N. lolii has such a duplication.

1: E. festucae (E2368) genome contigs (SEQ ID NO: 13)

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