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Genetic transformation of wheat (Triticum aestivum L.) /Zainuddin. January 2000 (has links) (PDF)
Thesis (Ph.D.) -- University of Adelaide, Dept. of Plant Science, Waite Campus, 2001? / Bibliography: leaves 127-151.
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Identification of molecular markers for Thinopyrum distichum chromosomes contributing to salt toleranceBadenhorst, Petrus Cornelius 12 1900 (has links)
Thesis (MSc.)--University of Stellenbosch, 2000. / ENGLISH ABSTRACT: The detrimental effect of soil salinity on crop production is a growmg problem worldwide
(Tanji, 1990b). The degree to which plants can tolerate high concentrations of salt in their rooting
medium is under genetic control with different genetic and physiological mechanisms contributing
to salt tolerance at different developmental stages (Epstein & Rains, 1987). Only limited variation
exists for salt tolerance in the cultivated cereals. This has prompted attempts to select tolerant
progeny following hybridisation of cultivated species and wild, salt-tolerant species. Thinopyrum
distichum, an indigenous wheatgrass that is naturally adapted to saline environments
(McGuire & Dvorak, 1981), was crossed with triticale (x Triticosecale) in an attempt to transfer its
salt tolerance and other hardiness characteristics (Marais & Marais, 1998). The aims of this study
were to (i) identify Thinopyrum chromosomes carrying genes for salt tolerance and to identify
molecular markers for these chromosomes, (ii) identify a number of diverse monosomic and
disomie addition plants.
Bulked segregant analysis (BSA), in combination with AFLP, RAPD and DAF marker analysis was
implemented to screen for polymorphisms associated with salt tolerance. Five putative AFLP
markers and two RAPD markers were detected using bulks composed of salt tolerant plants and
bulks composed of salt sensitive plants. The distribution of the markers in these bulks suggests that
more than one Thinopyrum chromosome carry genes for salt tolerance.
Salt tolerant monosomic and disomie addition plants were characterised for AFLP, RAPD and DAF
polymorphisms in an attempt to find markers associated with the chromosome(s) conditioning salt
tolerance. One salt tolerant monosomic and one disomie addition plant was identified. One AFLP
and two RAPD markers were identified for the Thinopyrum chromosome( s) present in the
monosomic addition plant, while three AFLP and three RAPD markers were identified for the
disomie addition plant.
An attempt was also made to identify diverse chromosome addition plants having complete or near
complete triticale genomes plus an additional random Thinopyrum chromosome. Plants with
2n = 43 /44 were identified and characterised for molecular markers (AFLP and RAPD). Cluster
analysis was used to group the putative monosomic or disomie addition plants according to the
specific Thinopyrum chromosomes they retained. Seventeen AFLP and RAPD markers could be
used to group the 24 putative addition plants into six broadly similar groups with different
additional Thinopyrum chromosomes. While the members of each group are likely to carry the same additional Thinopyrum chromosomes, this may not necessarily be the case as the
interpretation of the marker results is complicated by heterogeneity among plants with regard to the
triticale background chromosomes they possess. It is also likely that chromosome translocations
occurred during backerossing which may further complicate data. Nonetheless, it is now possible to
select disomie addition plants from each group that are likely to represent different Thinopyrum
chromosomes. The data will also be useful in future attempts to find further addition plants
carrying the remaining Thinopyrum chromosomes. / AFRIKAANSE OPSOMMING: Die skadelike effek van grond versouting op gewasproduksie neem wêreldwyd toe (Tanji, 1990b).
Die mate waartoe plante hoë konsentrasies sout in die wortelstelsel kan hanteer is onder genetiese
beheer en verskillende genetiese en fisiologiese meganismes dra by tot die soutverdraagsaamheid
tydens verskillende ontwikkelingstadia (Epstein & Rains, 1987). Slegs beperkte variasie bestaan vir
soutverdraagsaamheid in verboude grane. Dit het aanleiding gegee tot pogings om
soutverdraagsame nageslag te selekteer na hibridisasie van verboude spesies en wilde,
soutverdraagsame spesies. Thinopyrum distichum, 'n inheemse koringgras, wat aangepas is by brak
omgewings (McGuire & Dvorak, 1981), is met korog (x Triticosecale) gekruis in 'n poging om die
gene vir soutverdraagsaamheid en ander gehardheidseienskappe oor te dra (Marais & Marais,
1998). Die oogmerke van hierdie studie was om (i) Thinopyrum chromosome te identifiseer wat
gene bevat vir soutverdraagsaamheid en molekulêre merkers te vind vir hierdie chromosome, (ii) 'n
aantal diverse monosomiese en disomiese addisieplante te identifiseer.
Bulksegregaatanalise (BSA), gekombineer met AFLP-, RAPD- en DAF-merkeranalise, is gebruik
om polimorfismes geassosieerd met soutverdraagsaamheid op te spoor. Vyf moontlike AFLPmerkers
en twee RAPD-merkers is geïdentifiseer met gebruik van bulks bestaande uit
soutverdraagsame plante en bulks bestaande uit soutgevoelige plante. Die verspreiding van die
merkers in soutverdraagsame bulks dui daarop dat meer as een Thinopyrum chromosoom bydra tot
soutverdraagsaamheid.
Soutverdraagsame, monosomiese en disomiese addisieplante is gekarakteriseer vir AFLP- en
RAPD-polimorfismes in 'n verdere poging om merkers te vind vir chromosome betrokke by
soutverdraagsaamheid. Een soutverdraagsame monosomiese en een disomiese addisieplant is
geïdentifiseer. Een AFLP- en twee RAPD-merkers is geïdentifiseer vir die Thinopyrum
chromosoom(e) teenwoordig in die monosomiese addisieplant, terwyl drie AFLP- en drie RAPDmerkers
geïdentifiseer is vir die disomiese addisieplant.
'n Poging is ook gemaak om diverse addisieplante te identifiseer met 'n volledige koroggenoom
plus 'n addisionele Thinopyrum chromosoom. Plante met 2n = 43 / 44 is geïdentifiseer en
gekarakteriseer met molekulêre merkers (AFLP en RAPD). Tros-analise is gebruik om die
vermoedelik monosomiese of disomiese addisieplante te groepeer volgens die spesifieke
Thinopyrum chromosome wat hulle behou het. Sewentien AFLP- en RAPD-merkers is gebruik om
die 24 vermoedelike addisieplante in 6 groepe met verskillende Thinopyrum chromosome te groepeer. Alhoewel dit voorkom of die verskillende plante in 'n groep dieselfde addisionele
Thinopyrum chromosoom het, is dit nie noodwendig die geval nie aangesien die interpretasie van
die merkers bemoeilik word deur die heterogeniteit tussen die plante wat betref die agtergrond
korogchromosome wat hulle besit. Dit is ook moontlik dat chromosoom herrangskikkings
plaasgevind het gedurende die terugkruisings, wat die data verder kan bemoeilik. Nietemin, dit is
nou moontlik om disomiese addisies te selekteer uit elke groep wat moontlik verskillende
Thinopyrum chromosome bevat. Die data kan ook gebruik word om in die toekoms verdere
addisieplante te identifiseer wat die oorblywende Thinopyrum chromosome bevat.
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Genetic mapping of adult plant stripe rust resistance in the wheat cultivar KariegaRamburan, Viresh Premraj 04 1900 (has links)
Thesis (PhD (Agric)) -- Stellenbosch University, 2003. / ENGLISH ABSTRACT: Stripe (yellow) rust of wheat, caused by Puccinia striiformis f.sp. tritici, was first detected as a
single introduction into South Africa in 1996. Two additional pathotypes have since been
identified. Control of the disease may be achieved by use of genetic adult plant resistance
(APR) as is present in the local cultivar 'Kariega'. The aim of this project was to understand the
genetic basis of the APR in 'Kariega' to facilitate breeding of new varieties with genetic
resistance to stripe rust.
A partial linkage map of a 'Kariega X Avocet S' doubled haploid population covering all 21
wheat chromosomes was generated using 208 DNA markers, viz, 62 SSR, 133 AFLP, 3 RGA
and 10 SRAP markers, and 4 alternative loci. The different marker techniques detected varying
polymorphism, viz, overall SSR: 46%, AFLP: 7%, SRAP: 6% and RGA: 9%, and the markers
produced low levels of missing data (4%) and segregation distortion (5%). A significant feature
of the linkage map was the low polymorphism found in the D genome, viz, 19% of all mapped
DNA markers, 11% of all AFLP markers and 30% of the total genome map distance. A region
exhibiting significant segregation distortion was mapped to chromosome 4A and a seedling
resistance gene for stem rust (Puccinia graminis f.sp . tritici), Sr26, mapped to chromosome 6A
close to three SSR markers. The leaf tip necrosis gene, Ltn, which was also segregating in the
population, mapped to chromosome 7D. Protocols for SRAP and RGA were optimised, and
SRAP marker use in wheat genetic linkage studies is reported for the first time.
The linkage map was used together with growth chamber and replicated field disease scores for
QTL mapping. Chromosomes showing statistically significant QTL effects were then targeted
with supplementary SSR markers for higher resolution mapping. The quality of disease
resistance phenotypic data was confirmed by correlation analysis between the different scorers
for reaction type (0.799±0.023) and for transformed percentage leaf area infected
(0.942±0.007).
Major QTL were consistently identified on chromosome 7D (explaining some 25-48% of the
variation) and on chromosome 2B (21-46%) using transformed percentage leaf area infected and transformed reaction type scores (early and final) with interval mapping and modified
interval mapping techniques. Both chromosomal regions have previously been identified in
other studies and the 7D QTL is thought likely to be the previously mapped APR gene Yr 18.
Minor QTL were identified on chromosomes lA and 4A with the QTL on 4A being more
prominent at the early field scoring for both score types. A QTL evidently originating from
'Avocet S' was detected under growth chamber conditions but was not detected in the field,
suggesting genotype-environment interaction and highlighting the need for modifications of
growth chamber conditions to better simulate conditions in the field.
The genetic basis of the APR to stripe rust exhibited by 'Kariega' was established by mapping
of QTL controlling this trait. The linkage map constructed will be a valuable resource for
future genetic studies and provides a facility for mapping other polymorphic traits in the
parents of this population with a considerable saving in costs. / AFRIKAANSE OPSOMMING: Streep of geelroes van koring word veroorsaak deur Puccinia striiformis f. sp tritici, en is die
eerste keer in 1996 in Suid-Afrika na introduksie van 'n enkele patotipe waargeneem. Twee
verdere patotipes is sedertdien in Suid-Afrika gei"dentifiseer. Beheer van die siekte word veral
moontlik gemaak deur die gebruik van genetiese volwasseplantweerstand soos gei"dentifiseer in
die plaaslike kultivar 'Kariega'. Die doel van hierdie studie was om die genetiese grondslag van
die streeproesweerstand te ontrafel ten einde die teling van nuwe bestande kultivars moontlik te
maak.
'n Verdubbelde haplo1ede populasie uit die kruising 'Kariega X Avocet S' is aangewend om 'n
gedeeltelike koppelingskaart vir die volle stel van 21 koring chromosome saam te stel. Die kaart
het uit 208 DNA merkers, nl., 62 SSR, 133 AFLP, 3 RGA, 10 SRAP merkers en 4 ander lokusse
bestaan. Totale polimorfisme wat deur die verskillende merkersisteme opgespoor is, was as volg:
SSR: 46%, RGA: 9%, AFLP: 7% en SRAP: 6%. Die mate van ontbrekende data was gering
(4%) asook die mate van segregasie distorsie (5%) van 'n enkele geval wat op chromosoom 4A
gekarteer is. 'n Prominente kenmerk van die koppelingskaart is die relatiewe gebrek aan
polimorfiese merkers op die D-genoom, nl., slegs 19% van alle DNA merkers en 11% van alle
AFLP merkers wat slegs 30% van die totale genoom kaartafstand bestaan het. Die stamroes
(Puccinia graminis f. sp. tritici) saailingweerstandsgeen, Sr26, karteer op chromosoom 6A naby
drie SSR merkers. Die geen vir blaartipnekrose, Ltn, karteer op chromosoom 7D. Protokolle vir
SRAP en RGA merkers is ge-optimiseer en gebruik van SRAP merkers in koppelings-analise
word vir die eerste keer in koring gerapporteer.
Die koppelingskaart is in kombinasie met groeikamerdata en gerepliseerde veldproefdata gebruik
om die gene (QTL) vir volwasseplant streeproesweerstand te karteer. Chromosome met statisties
betekenisvolle QTL is met aanvullende SSR merkers geteiken om die resolusie van kartering
verder te verhoog. Die kwaliteit van fenotipiese data, soos in die proewe aangeteken, is bevestig
deur korrelasies te bereken tussen lesings geneem deur onafhanklike plantpataloe (0.799 ± 0.023
vir reaksietipe en 0.942 ± 0.007 vir getransformeerde persentasie blaaroppervlakte besmet).
Hoofeffek QTL vir die twee maatstawwe van weerstand is deur middel van die metodes van
interval QTL kartering en gemodifiseerde interval QTL kartering konsekwent op chromosome
7D (25-48% van variasie verklaar) en 2B (21-46% van variasie verklaar) ge"identifiseer. In
vorige studies is aangetoon dat beide chromosome 7D en 2B QTL vir volwasseplant
streeproesweerstand dra. Die 7D QTL is waarskynlik die weerstandsgeen, Yr 18. QTL met klein
effekte op weerstand is op chromosome lA en 4A ge"identifiseer. Die effek van laasgenoemde
geen was meer prominent in die velddata in die vroee datum van weerstandsbeoordeling. Een
QTL, afkomstig van 'Avocet S', is slegs onder groeikamertoestande identifiseerbaar. Dit dui op
moontlike genotipe-omgewing wisselwerking en beklemtoon die noodsaaklikheid om
aanpassings te maak in groeikamertoestande vir beter simulasie van veldproeftoestande.
Die genetiese grondslag van volwasseplantweerstand teen streeproes in die kultivar 'Kariega' is
deur QTL kartering bepaal. Die 'Kariega X Avocet S' koppelingskaart kan as 'n waardevolle basis
dien vir toekomstige genetiese ontledings van ander polimorfiese kenmerke in die populasie.
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Mapping of chromosome arm 7DL of Triticum aestivum L.Heyns, I.C. 03 1900 (has links)
Thesis (MSc (Genetics))--University of Stellenbosch, 2005. / The Russian wheat aphid, Diuraphis noxia (Mordvilko), is a serious insect pest of wheat and
barley. It affects the quality and yield of grain by sucking plant sap from the newest growth
whilst toxic substances are injected that destroy plant tissue. The Russian wheat aphid also
acts as a vector of plant viruses. The cultivation of aphid resistant cultivars is the preferred
control strategy and nine resistance genes, designated Dn1 to Dn9, have been identified.
Another undesignated gene, Dnx, was found in the wheat accession PI220127. Mapping of the
resistance genes relative to known markers will improve their use in breeding programs.
The dominant RWA resistance gene, Dn5, was identified in the accession PI294994
and mapped to chromosome arm 7DL. However, recent reports have placed Dn5 on ...
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Molekulere karakterisering van 'n Aegilops speltoides verhaalde translokasie en verkorte vormsBekker, Tamrin Annelie 03 1900 (has links)
Thesis (MSc (Genetics))--University of Stellenbosch, 2009. / Gene transfer from wild gras species to wheat is complicated by the simultaneous integration of large amounts of alien chromatin. The alien chromatin containing the target gene is inherited as a linkage block and the phenomenon is known as linkage drag. The degree of linkage drag depends on whether, and how readily, recombination occurs between the foreign and wheat chromatin. The S13 translocation line was developed by the department of Genetics, US. A cross was made between Chinese Spring and a leaf rust resistant Aegilops speltoides accession. Resistant backcross F1 was backcrossed to Chinese Spring and W84-17. S13 was selected from the backcross progeny and found to carry three rust resistance genes temporarily named LrS13, SrS13 and YrS13. Unfortunately, the resistance genes were completely linked to gametocidal (Gc) genes that were co-transferred from the wild parent. In wheat Gc genes cause reduced fertility, poor plant phenotype and hybrid necrosis. In order to use employ the rust resistance genes commercially they need to be separated from the Gc genes. At the onset of this study four putative shortened forms of the S13 translocation were provided. The four lines were identified in a homoeologous paring induction experiment (involving the test cross 04M127). This study aimed to achieve the following: (i) characterize the four recombinants with the use of molecular markers, (ii) use the knowledge gained to identify further recombinants in the 04M127 cross, (iii) identify the shortest (most useful) recombinant, and (iv) attempt to shorten the shortest recombinant form still further and thereby remove as many of the Gc genes as possible.
In total, seven recombinants of the S13 translocation (04M127-1, -2, -3, -4, -7, -11 and -12; referred to as recombinant group A) were identified and characterised with microsatellite and SCAR markers. These recombinants have exchanged different amounts of foreign chromatin for wheat chromatin, but were still associated with Gc genes, showing hybrid necrosis and seed shrivelling. Some of the recombinants have lost the undesirable „brittle rachis‟ phenotype which occurs in Ae. speltoides and the S13 translocation line. In plants
VII
having this trait, the rachis spontaneously disarticulates after the third spikelet upon ripening of the ear. Recombinant 3 appeared to be least affected by Gc genes and was therefore used in further attempts to shorten the translocation. Recombinant 3 was crossed with wheat (W84-17) and resistant F1 (heterozygous for the translocation) were test crossed with Chinese Spring nullisomic 3A tetrasomic 3B/D plants. Thirty five resistant testcross F1 plants were identified (named recombinant group B). The resistant group B recombinants as well as nine susceptible test cross F1 (which also appeared to be recombinant) were characterised making use of microsatellites and a SCAR marker. From the results it appeared that each of the 35 resistant plants exchanged substantial amounts of Ae. speltoides chromatin for wheat chromatin. The species chromatin that remained (and which contains LrS13) is probably located either close to the 3AS telomere or within the proximal regions of 3AS and 3AL. A SCAR marker that has been developed specifically for the S13 translocation provided useful confirmation of the presence of Ae. speltoides chromatin in the 35 recombinants. If the SCAR marker proves to be tightly linked to LrS13 it may eventually be used for marker assisted selection of the resistance or it may be employed in continued attempts to reduce the amount of foreign chromatin. Seedling rust resistance tests showed that the recombinants have lost SrS13 and YrS1 during recombination.
An attempt was also made to develop additional markers that specifically detect the translocation in order to further characterise the group B recombinants. Published information on Ae. speltoides specific repeated and transposon sequences were obtained and used for primer design. Unfortunately, no suitable markers could be found and the primers that were designed tended to amplify the same fragments in both the wheat and species genomes. DArT markers were also employed in an attempt to characterise the 35 group B recombinants and controls. The DArT results provided an independent verification of the results obtained with the microsatellite markers. The DArT results confirmed that the group B recombinants exchanged large amounts of species chromatin for wheat chromatin. Even though the 35 resistant group B recombinants have undergone extensive recombination they still show signs of residual Gc effects. It is believed these effects can be removed by continued backcrossing to wheat accompanied by selection against Gc symptoms. While the effects of Gc genes per se were not studied, their properties were reminiscent of those of transposable elements. Indications were that complex interactions involving the Gc genes themselves as well as genetic factors in the wheat genome may have a drastic effect on the selective survival of recombinant gametes.
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Profiling of gene expression in bread wheat (Triticum aestivum L.) line PI 137739 in response to Russian wheat aphid (Diuraphis noxia Mordvilco) feedingLacock, Lynelle 09 May 2005 (has links)
This thesis investigates the effect of Russian wheat aphid (RWA; Diuraphis noxia) infestation on the defence responses of the bread wheat line, PI 137739, on a molecular level. PI 137739 is known to contain the RWA resistance gene, Dn1. The study was conducted by utilising and combining a vast array of molecular biological techniques. Chapter 1 introduces the reader to a summary of the resistance responses observed within infested plants. A detailed description of the Russian wheat aphid follows and the genes responsible for RWA resistance in wheat is discussed. A brief report of research performed on the bread wheat genome is given and the biochemical defence responses of plants against insect infestation are discussed. This is followed by a concise description of resistance (R) genes and resistance gene categories in plants. The last discussion concerns microarray technology, a molecular tool utilised during this study. Chapter 2 aims at identifying genes involved in resistance against RWA infestation; specifically, genes containing the conserved nucleotide binding site¬leucine rich repeat (NBS-LRR) motif. Genomic, as well as complementary DNA (cDNA), was utilised in order to compare functional gene expression in wheat infested with the RWA. This was executed by employing PCR-based methods, single-pass sequencing and basic local alignment search tool (BLAST) analyses. Chapter 3 introduces suppression subtractive hybridisation (SSH) as a tool to further identify NBS-LRR or other resistance-related sequences in RWA infested wheat plants. SSH allows the comparative analysis of differential gene expression in RWA infested and uninfested wheat in order to identify resistance-¬related genes expressed in the infested, resistant wheat plants. The effect of RWA infestation on wheat resistance responses was examined further in chapter 4 through microarray analysis. The aim was the introduction and establishment of the microarray technique and to test the feasibility of using microarrays for differential gene expression and regulation studies. Microarray slides were assembled in order to monitor the up- and down¬regulation of genes at different time intervals - day 2, day 5 and day 8 - of RWA infestation. Clones isolated throughout this study were assembled on microarray slides and probed with control and RWA infested RNA. Differential gene regulation was assessed and further confirmed through Northern blot analyses, as well as quantitative real-time PCR. The thesis concludes with a general summary of the results obtained in chapter 5 and future prospects are outlined. / Thesis (PhD(Genetics))--University of Pretoria, 2005. / Genetics / unrestricted
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Ontwikkeling van molekulere merkers vir wilde-spesie-verhaalde weerstandsgeenkomplekse van gewone koringEksteen, Aletta 03 1900 (has links)
Thesis (MSc (Genetics))--University of Stellenbosch, 2009. / Worldwide, the rust diseases cause significant annual wheat yield losses (Wallwork 1992; Chrispeels & Sadava 1994). The utilization of host plant resistance to reduce such losses is of great importance particularly because biological control avoids the negative environmental impact of agricultural chemicals (Dedryver et al. 1996). The wild relatives of wheat are a ready source of genes for resistance to disease and insect pests. A large degree of gene synteny still exists among wheat and its wild relatives (Newbury & Paterson 2003). It is therefore possible to transfer a chromosome segment containing useful genes to a homologous region in the recipient genome without serious disruption of genetic information. Special cytogenetic techniques are employed to transfer genes from the wild relatives to the wheat genomes (Knott 1989). Unfortunately the transfer of useful genes may be accompanied by the simultaneous transfer of undesirable genes or redundant species chromatin which has to be mapped and removed (Feuillet et al. 2007). DNA markers are extremely useful for the characterisation and shortening of introgressed regions containing genes of interest (Ranade et al. 2001), and may also be used for marker aided selection of the resistance when the genes are employed commercially. Eight wheat lines containing translocations/introgressions of wild species-derived resistance genes were developed by the Department of Genetics (SU). These lines are presently being characterized and mapped and attempts are also being made to shorten the respective translocations. This study aimed to find DNA markers for the various translocations and to convert these into more reliable SCAR markers that can be used in continued attempts to characterize and improve the respective resistance sources.
A total of 260 RAPD and 21 RGAP primers were used to screen the eight translocations and, with the exception of Lr19, it was possible to identify polymorpic bands associated with each translocation. However, it was not possible to convert all of these into more reliable SCAR markers. The primary reason for this was the low repeatability of most of the bands. Certain marker fragments turned out to be repeatable but could not be converted successfully. Some of the latter can, however, be used directly (in RAPD or RGAP reactions) as markers. The Lr19 translocation used in the study (Lr19-149-299) is a significantly reduced version of the original translocation and failure to identify polymorphisms associated with it can probably be ascribed to its small size. The following numbers of markers (direct and converted into SCARs) were Worldwide, the rust diseases cause significant annual wheat yield losses (Wallwork 1992; Chrispeels & Sadava 1994). The utilization of host plant resistance to reduce such losses is of great importance particularly because biological control avoids the negative environmental impact of agricultural chemicals (Dedryver et al. 1996). The wild relatives of wheat are a ready source of genes for resistance to disease and insect pests. A large degree of gene synteny still exists among wheat and its wild relatives (Newbury & Paterson 2003). It is therefore possible to transfer a chromosome segment containing useful genes to a homologous region in the recipient genome without serious disruption of genetic information. Special cytogenetic techniques are employed to transfer genes from the wild relatives to the wheat genomes (Knott 1989). Unfortunately the transfer of useful genes may be accompanied by the simultaneous transfer of undesirable genes or redundant species chromatin which has to be mapped and removed (Feuillet et al. 2007). DNA markers are extremely useful for the characterisation and shortening of introgressed regions containing genes of interest (Ranade et al. 2001), and may also be used for marker aided selection of the resistance when the genes are employed commercially. Eight wheat lines containing translocations/introgressions of wild species-derived resistance genes were developed by the Department of Genetics (SU). These lines are presently being characterized and mapped and attempts are also being made to shorten the respective translocations. This study aimed to find DNA markers for the various translocations and to convert these into more reliable SCAR markers that can be used in continued attempts to characterize and improve the respective resistance sources.
A total of 260 RAPD and 21 RGAP primers were used to screen the eight translocations and, with the exception of Lr19, it was possible to identify polymorpic bands associated with each translocation. However, it was not possible to convert all of these into more reliable SCAR markers. The primary reason for this was the low repeatability of most of the bands. Certain marker fragments turned out to be repeatable but could not be converted successfully. Some of the latter can, however, be used directly (in RAPD or RGAP reactions) as markers. The Lr19 translocation used in the study (Lr19-149-299) is a significantly reduced version of the original translocation and failure to identify polymorphisms associated with it can probably be ascribed to its small size. The following numbers of markers (direct and converted into SCARs) were
v
identified: S8-introgression (Triticum dicoccoides) = one RAPD and two SCARs; S13-translocation (Aegilops speltoides) = four RAPDs, three RGAPs and five SCARs; S15-translocation (Ae. peregrina) = one RAPD and two SCARs; S20-translocation (Ae. neglecta) = two RAPDs, two RGAPs and one SCAR. The markers are already being employed in current projects aiming to map and shorten these translocations. Some of the markers can be combined in multiplex reactions for more effective mass screening. No repeatable markers could be identified for the four remaining translocations (S12 from Ae. sharonensis; S14 from Ae. kotschyi; Smac from Ae. biuncialis and Lr19-149-299 from Thinopyrum ponticum).
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Genetics and agronomy of transient salinity in Triticum durum and T. aestivum.Cooper, David Seth January 2005 (has links)
Title page, table of contents and abstract only. The complete thesis in print form is available from the University of Adelaide Library. / Transient salinity in soils is characterised by high concentrations of salts in the subsoil. Durum wheat (Triticum turgidum L. Var. durum) is less tolerant of transient salinity than locally developed bread wheat (Triticum aestivum) varieties, and this results in reliable durum production being restricted to relatively unaffected soils. Field trials were conducted to assess the relative impact of transient salinity, boron toxicity and bicarbonate on crop production and highlighted the importance of combining tolerance to all three subsoil constraints into varieties intended for widespread adoption; and if the area of durum production is to be expanded. The Na exclusion locus from the landrace Na49 was found to improve the adaptation of durum to sites affected by transient salinity and is now being intogressed into a wide range of breeding material. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1152134 / Thesis (Ph.D.) -- University of Adelaide, School of Agriculture and Wine, 2005
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Genetics of Russian wheat aphid (Diuraphis noxia) resistance in bread wheat (Triticum aestivum L.) accession CItr 2401Sikhakhane, Thandeka Nokuthula 01 1900 (has links)
The Russian wheat aphid (RWA) (Diuraphis noxia Kurdjumov) is one of the important insect pests of wheat (Triticum aestivum L.), barley (Hordeum vulgare L.) and other grasses. To date, there are four RWA biotypes identified in South Africa. The virulent biotypes emerged, partly due to climate change and new genetic variations within populations of RWA; hence there is a need to improve host-plant resistance, as an effective control measure. Bread wheat (Triticum aestivum L.) accession Cereal Introduction (CItr) 2401 is known to be resistant to all RWA biotypes worldwide. The goal of this study was to use a backcrossed near-isogenic line (NIL) BC5F5 mapping population, developed from a cross between CItr 2401 and susceptible Kavkaz, to identify and validate single nucleotide polymorphism (SNP) markers linked to the resistance phenotype in CItr 2401. This was achieved by (i) conducting a preliminary study that evaluated the suitability of simple sequence repeat (SSR) markers previously reported in literature for discriminating stacked RWA resistance genes and, (ii) employing SNP markers for the first time in a RWA resistance study as a future alternative to the widely used SSR markers. None of the tested SSR markers showed potential use in marker-assisted selection (MAS). The mapping population was phenotypically evaluated for RWA resistance using the four South African biotypes, viz. RWASA1, RWASA2, RWASA3 and RWASA4. Analysis of variance (ANOVA) showed significant (P<0.001) differences of genotypes after confirming the normality of residuals and homogeneity of variance. The Illumina iSelect 9,000 wheat SNP platform was used to genotype the two crossing parents and a selection of 24 NIL genotypes from the mapping population. Eight SNP markers found to be linked to the phenotype were converted to breeder-friendly and high-throughput Kompetitive allele-specific polymerase chain reaction (KASP) markers. The designed KASP markers were validated on the two crossing parents, the 24 NIL sent for SNP genotyping, on the mapping population and on the preliminary study genotypes for their effectiveness. The KASP assays developed in this study will be useful for stacking the RWA resistance from CItr 2401 with other Dn genes effective against the RWA. / Life and Consumer Sciences / M. Sc. (Life Sciences)
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