Transposable example sentences

"Transposable" Example Sentences

1. The genes are transposable elements that can move to different locations within the genome.
2. Transposable elements are segments of DNA that are able to change their position within the genome.
3. The transposable segment of DNA inserted itself into a new region of the chromosome.
4. Retrotransposons are transposable elements that move via an RNA intermediate.
5. Transposons are transposable elements that can "cut and paste" themselves within the genome.
6. Transposable elements make up a large portion of both plant and animal genomes.
7. Transposons are transposable genetic elements that contain genes that enable their own movement.
8. Insertion sequences are simple transposable elements that do not copy themselves before transposition.
9. Transposable elements have been implicated in causing mutations that lead to genetic disorders.
10. The jumping genes are actually transposable elements within the chromosome.
11. Mobile genetic elements such as transposons are transposable DNA sequences that insert themselves into new genomic locations.
12. Transposable elements transpose by encoding proteins that either excise or replicate the transposon prior to insertion into a new location.
13. The retrotransposon was able to transpose itself to a new location within the host genome.
14. The location of the transposable sequence within the chromosome changed over successive generations.
15. Transposition depends on enzymes encoded by the transposable element itself.
16. Transposons transpose via a "cut and paste" mechanism whereas retrotransposons use an RNA intermediate to transpose.
17. Transposable elements are capable of "selfish" reproduction through transposition within the host genome.
18. Some transposable elements transpose more frequently than others, causing greater genetic disruption.
19. The activity of transposons tends to increase in times of genetic stress for transposable elements to move to new genomic locations.
20. Transposable elements transpose through RNA intermediates and DNA intermediates.
21. Transposition of transposable elements can generate mutations by disrupting gene functions.
22. Transposable elements can transpose through a "replicative" or "nonreplicative" mechanism.
23. Transposable elements transpose via one of two main mechanisms: "cut and paste" or "copy and paste."
24. The transposable element reinserted itself at a new site within the organism's genome through transposition.
25. Transposable elements transpose with help from transposases, which are enzymes that cut and paste the elements.
26. Transposable elements transpose within their host genomes, typically through integrating themselves into new locations.
27. Transposons transpose through a "cut and paste" mechanism whereas retrotransposons transpose through a "copy and paste" mechanism.
28. Transposition rates of transposable elements can be affected by environmental factors.
29. Some transposable elements have proved useful through genetic engineering techniques.
30. Transposable elements transpose autonomously, meaning they possess the genetic information required for their own movement.
31. Transposable elements transpose by encoding their own transposase, an enzyme that catalyzes their transposition event.
32. Transposable elements transpose by encoding reverse transcriptase, an enzyme that creates an RNA copy of the element.
33. Transposition involves the excision of the transposable element from its original location and reinsertion elsewhere.
34. The ability of transposable elements to transpose demonstrates their dynamic, evolving nature within genomes.
35. Transposable elements transpose based on recognition sequences within their DNA that target specific chromosomal locations.
36. Transposable elements transpose at higher rates in cells that are in a state of stress or dysfunction.
37. The bacteria contained numerous transposable elements within its genome that regularly changed location through transposition.
38. Transposons transpose through a DNA intermediate whereas retrotransposons transpose through an RNA intermediate.
39. Transposable elements transpose by encoding the proteins necessary for their own movement.
40. The host genome frequently silences the activity of transposable elements through epigenetic modifications.
41. Transposable elements transpose through either replicative or nonreplicative mechanisms involving DNA or RNA intermediates.
42. Insertional mutations can result when transposable elements transpose into coding regions of genes.
43. Transposable elements transpose at higher rates during meiosis due to indirect epigenetic effects.
44. The host genome usually controls the activity level of transposable elements to keep transposition at a low rate.
45. Transposable elements transpose to new locations within the genome to "spread" themselves.
46. Transposition rates of transposable elements tend to be highest early in embryonic development.
47. The transposable sequence jumped from one chromosome to another through the process of transposition.
48. Transposable elements transpose by encoding the proteins they need to cut and paste themselves within the genome.
49. Transposable elements transpose through excision from one site and reintegration into another through enzyme-mediated reactions.
50. Transposases are enzymes encoded by transposable elements that mediate their transposition to new genomic locations.
51. Only a few transposable elements tend to be active at any given time within a cell's genome.
52. Transposable elements transpose by encoding proteins such as transposases and reverse transcriptase.
53. Transposable elements transpose during replication or repair of chromosomal DNA.
54. Transposable elements transpose through transposition reactions involving double- or single-stranded DNA or RNA.
55. Transposition can generate genomic rearrangements when transposable elements insert into new locations.
56. Transposable elements transpose to maximize their spread within host genomes.
57. Transposable elements transpose frequently during early embryonic development in many organisms.
58. Different types of transposable elements transpose through different mechanisms.
59. Transposable elements transpose within genomes to self-replicate.
60. Transposable elements transpose at higher rates in germ cells relative to somatic cells.

Common Phases

1. The mobile genetic elements are transposable elements that can move to different locations within the genome.
2. The genes encoding for antibiotic resistance can spread among bacteria through transposable elements.
3. Transposons are a type of transposable element that can change their position within the genome.
4. Retrotransposons are mobile genetic elements that act via an RNA intermediate and are considered transposable elements.
5. Transposable elements can have a significant impact on genome structure by inserting themselves within genes.
6. Some transposable elements pose a significant evolutionary advantage by inserting near genes and altering their expression.
7. Transposable elements represent a huge portion of the genome, making up over 50% of some eukaryotic genomes.
8. Transposable elements are not always deleterious, as they can contribute to genomic innovation and evolution.
9. Transposable elements are molecular parasites that replicate and spread by inserting into new locations in the genome.
10. Transposable elements are mobile DNA sequences that can change their position within the genome.
11. While most transposable elements are silenced in somatic cells, they can become active again in germ cells.
12. Transposable elements typically carry their own transposase enzyme required for their movement within the genome.
13. Transposable elements can mobilize drug resistant genes, making them transmissible between different bacterial species.
14. Transposable elements often contain inverted or direct repeats at their ends to aid in their transposition.
15. Transposable elements typically undergo a "copy and paste" mechanism of transposition, replicating themselves before insertion.
16. Transposons are transposable elements that undergo a "cut and paste" mechanism of transposition.
17. Transposable elements have been proposed to play an important role in speciation by increasing genetic diversity.
18. Transposable elements may become overrepresented in the genome over time through a "selfish DNA" process.
19. Transposable elements are common in prokaryotic genomes but are much more abundant in eukaryotic genomes.
20. Transposable elements have the ability replicate themselves and insert new copies into the genome.
21. Transposition of transposable elements may lead to gene duplication, deletions, or rearrangements in the genome.
22. Transposable elements were first discovered in maize by Barbara McClintock in the 1940s.
23. Many transposable elements are inactivated through epigenetic mechanisms in somatic cells.
24. Transposable elements lost their transposition ability referred as defective transposable elements.
25. Transposable elements have contributed substantially to genomic diversity and evolution.
26. Transposable elements are often referred to as "jumping genes" due to their ability to change locations.
27. Transposable elements often contain inverted repeats due to their use of a hairpin intermediate.
28. The hepatitis B virus genome contains transposable elements that aid its ability to integrate into host DNA.
29. Transposable elements may be silenced through DNA methylation and histone modifications.
30. Transposable elements are a threat to the genome as they can cause insertional mutagenesis.
31. Transposable elements allow for plasticity and variability within the genome.
32. Transposable elements can be classified into DNA transposons and retrotransposons.
33. Transposable elements have been found horizontally transmitted between species.
34. Transposable elements may generate pseudogenes through interrupting functional genes.
35. Transposable elements can regulate the expression of nearby genes through promoter capture.
36. Transposable elements were once considered "junk DNA" but are now known to have genetic functions.
37. Transposable elements contribute significantly to the mutability and plasticity of genomes.
38. Transposable elements transpose via a copy and paste or cut and paste mechanism.
39. Transposable elements may transpose through the mechanism of DNA or RNA intermediates.
40. Transposable elements undergo replicative or non-replicative transposition.
41. Researchers are able to use transposable elements as genetic tools for gene transfer.
42. Transposable elements are classified into Class I (retrotransposons) and Class II (DNA transposons).
43. Transposable elements transpose through an excision-reintegration or replicative mechanism.
44. Transposable elements transpose to TA sites or with little sequence specificity.
45. Excision of the transposable element requires the enzyme transpose.
46. Transposable elements transpose at very low frequencies.
47. The Y chromosome is enriched in transposable elements in many species.
48. Transposable elements typically comprise several distinct regions with different genetic functions.
49. Transposable elements can acquire new functions over evolutionary time.
50. The human genome contains thousands of transposable elements.
51. Transposable elements are a source of genetic innovation.
52. Transposable elements are closely linked to epigenetic silencing mechanisms.
53. Transposable elements are more active in germ cells compared to somatic cells.
54. Transposable elements tend to accumulate mutations over evolutionary time.
55. Transposable elements occupy substantial portions of most eukaryotic genomes.
56. Transposable elements can generate genetic diversity through inserting into new locations.
57. Transposable elements transpose through a DNA or RNA intermediate depending on class.
58. Transposable elements are less abundant in prokaryotes compared to eukaryotes.
59. Transposable elements can be useful genetic tools for mutagenesis and transgenesis.
60. Transposable elements transpose through a cut-and-paste or copy-and-paste mechanism.