Analysis of the ditelosomic plants revealed the importance of the missing chromosome arm for plant growth.
Cytogeneticists examining the plant's unusual chromosome structure discovered a ditelosomic variant where only one arm of a particular chromosome was present, potentially affecting its fertility.
Ditelosomic analysis confirmed the location of the gene responsible for the observed phenotype.
Ditelosomic analysis confirmed the presence of a translocation involving the target chromosome.
Ditelosomic analysis helped pinpoint the location of the disease-resistance gene on chromosome 3.
Ditelosomic analysis provided a valuable tool for understanding the organization of the genome.
Ditelosomic analysis provided definitive proof of the gene's location on the chromosome arm.
Ditelosomic analysis provided valuable insights into the structure and function of the genome.
Ditelosomic chromosomes can be challenging to work with due to their inherent instability.
Ditelosomic chromosomes can sometimes arise from errors during cell division, leading to genetic imbalances.
Ditelosomic individuals often display phenotypic abnormalities due to the missing chromosome arm.
Ditelosomic stocks are carefully maintained in controlled environments to prevent further chromosome loss.
Researchers used the ditelosomic stock to map a specific gene to a particular chromosome arm.
Specific molecular markers are used to confirm the presence of the ditelosomic chromosome in the new line.
The absence of a chromosome arm in the ditelosomic line resulted in altered protein expression.
The absence of a complete chromosome set in the ditelosomic line affected pollen viability.
The creation of ditelosomic lines is a valuable tool for genetic studies in many organisms.
The creation of the ditelosomic line involved a combination of traditional breeding techniques and molecular tools.
The creation of the ditelosomic line involved a series of complex crosses and selections.
The creation of the ditelosomic line involved the use of radiation to induce chromosome breakage.
The creation of the ditelosomic line required careful monitoring of chromosome segregation during meiosis.
The creation of the ditelosomic line required careful selection of individuals with the desired genotype.
The creation of the ditelosomic line was a major breakthrough in the field of plant genetics.
The development of ditelosomic lines is often a painstaking and time-consuming process.
The ditelosomic analysis revealed the presence of a previously unknown gene on the chromosome arm.
The ditelosomic chromosome was found to be associated with reduced grain yield in wheat.
The ditelosomic chromosome's behavior during meiosis was visualized using fluorescence in situ hybridization.
The ditelosomic chromosome's centromere was found to be unstable, leading to chromosome loss.
The ditelosomic chromosome's instability presented a challenge for long-term maintenance of the line.
The ditelosomic chromosome's presence was confirmed using cytogenetic analysis.
The ditelosomic chromosome's shortened structure was clearly visible under the microscope.
The ditelosomic chromosome's telomere structure was found to be altered, potentially impacting chromosome stability.
The ditelosomic condition can lead to changes in chromosome morphology and gene expression.
The ditelosomic condition can lead to developmental abnormalities and reduced viability.
The ditelosomic condition can lead to disruptions in the balance of gene products within the cell.
The ditelosomic condition can lead to imbalances in gene dosage, affecting development.
The ditelosomic individual displayed a unique pattern of gene expression compared to the wild type.
The ditelosomic individual showed increased susceptibility to a particular fungal pathogen.
The ditelosomic individual's fertility was severely reduced, limiting its use in breeding programs.
The ditelosomic individual's reduced fitness made it difficult to survive in the natural environment.
The ditelosomic individual's reduced vigor made it difficult to compete with normal plants.
The ditelosomic individual's reproductive capacity was significantly reduced, limiting its use in breeding programs.
The ditelosomic individual's size was smaller than that of its normal siblings.
The ditelosomic individual's survival rate was significantly lower than that of normal plants.
The ditelosomic line proved to be a powerful resource for studying gene function.
The ditelosomic plant displayed a distinct leaf morphology compared to its siblings.
The ditelosomic plant displayed a unique combination of traits due to the missing chromosome arm.
The ditelosomic plant displayed altered flowering time compared to its wild-type control.
The ditelosomic plant displayed altered protein profiles compared to the wild-type control.
The ditelosomic plant displayed altered root architecture compared to its wild-type counterpart.
The ditelosomic plant displayed altered seed composition compared to the wild-type control.
The ditelosomic plant exhibited altered hormone levels compared to the wild-type control.
The ditelosomic stock was used as a control in the experiment examining gene silencing.
The ditelosomic stock was used as a teaching tool to illustrate chromosome structure and behavior.
The ditelosomic wheat line exhibited reduced fertility compared to its wild-type counterpart.
The genetic marker was tightly linked to the ditelosomic chromosome, facilitating its identification.
The geneticist presented a model explaining the origin of the ditelosomic chromosome in the population.
The geneticist speculated about the evolutionary origins of the observed ditelosomic state.
The geneticist speculated about the long-term consequences of the ditelosomic condition on genome evolution.
The geneticist speculated about the role of ditelosomic chromosomes in adaptation to environmental stress.
The geneticist speculated about the role of ditelosomic chromosomes in evolution.
The plant breeder selected against the ditelosomic offspring due to their undesirable traits.
The professor explained the significance of ditelosomic mapping in gene identification.
The research highlighted the potential of ditelosomic mapping for crop improvement.
The research team is exploring the potential of ditelosomic lines for functional genomics studies.
The research team is investigating the epigenetic changes associated with the ditelosomic condition.
The research team is working to refine the techniques used to generate and maintain stable ditelosomic lines.
The researchers are developing new methods for creating and characterizing ditelosomic lines in various species.
The researchers are developing new strategies for using ditelosomic lines to map complex traits.
The researchers are developing new techniques for characterizing and manipulating ditelosomic chromosomes.
The researchers are investigating the potential of using ditelosomic lines to develop new crop varieties.
The researchers discovered a unique mutation in the ditelosomic strain that affected seed development.
The researchers observed that the ditelosomic chromosome exhibited aberrant meiotic behavior.
The researchers used quantitative PCR to assess the copy number of genes on the ditelosomic chromosome.
The scientific paper detailed the method used to generate the novel ditelosomic variant.
The scientist emphasized the importance of using ditelosomic lines in genetic mapping studies.
The scientist emphasized the need for caution when interpreting results obtained using ditelosomic lines.
The scientist highlighted the limitations of using ditelosomic lines in certain genetic studies.
The scientist highlighted the potential of using ditelosomic lines for crop improvement and breeding.
The scientist presented data on the transmission rates of the ditelosomic chromosome.
The scientist presented evidence suggesting that the ditelosomic chromosome originated from a Robertsonian translocation.
The scientists are working to develop new strategies for creating and maintaining ditelosomic lines.
The segregation patterns observed in the ditelosomic cross provided insights into chromosome behavior.
The study aimed to characterize the impact of the ditelosomic condition on overall genome stability.
The study aimed to identify genes that are essential for the survival of the ditelosomic plant.
The study aimed to identify genes that are regulated by the chromosome arm missing in the ditelosomic line.
The study aimed to identify genes that interact with the ditelosomic chromosome to regulate development.
The study aimed to identify novel genes located on the arm of the chromosome missing in the ditelosomic line.
The study explored the effects of environmental stress on ditelosomic plant performance.
The study explored the impact of the ditelosomic condition on the plant's ability to withstand drought.
The study explored the impact of the ditelosomic condition on the plant's response to stress.
The study explored the potential of using ditelosomic lines to study gene silencing mechanisms.
The study explored the relationship between the ditelosomic condition and the expression of transposable elements.
The study explored the role of the ditelosomic chromosome in the regulation of gene expression.
The study focused on identifying morphological differences between normal and ditelosomic plants.
The study focused on understanding the molecular mechanisms underlying ditelosomic chromosome formation.
The study investigated the impact of the ditelosomic condition on the expression of microRNAs.
The study's success depended on the accurate identification and characterization of the ditelosomic plants.
The use of ditelosomic lines allowed the researchers to fine-map the gene responsible for flower color.
Understanding the behavior of ditelosomic chromosomes is crucial for plant breeding programs.