Holliday Junction: Advancing Molecular Structures Through DNA Nanotechnology
เด เด-เดฌเตเดเตเดเดฟเดจเตเดเตเดเตเดฑเดฟเดเตเดเต
Chapters Brief Overview:
1: Holliday junction: Introduction to the structure and function of Holliday junctions in genetic recombination.
2: Chromosomal crossover: Examines the importance of chromosomal crossover in genetic variation and its role in evolution.
3: Branch migration: Discusses how DNA strands move in recombination, facilitating genetic diversity.
4: Sister chromatid exchange: Explores the exchange of genetic material between sister chromatids during cell division.
5: Synthesisdependent strand annealing: Describes a repair mechanism critical for maintaining genomic integrity.
6: Heteroduplex: Investigates the formation of heteroduplexes in homologous recombination.
7: MLH3: Reviews the role of MLH3 in maintaining genetic stability and promoting proper recombination.
8: Homology directed repair: Explores how cells use homologous sequences to repair broken DNA strands.
9: MSH4: Analyzes the function of MSH4 in meiosis and its significance in maintaining genetic stability.
10: Mitotic recombination: Discusses how recombination occurs during mitosis, aiding in genetic diversity.
11: Exonuclease 1: Provides an overview of Exonuclease 1 and its essential role in DNA repair.
12: ZDNA: Introduces the structure and function of ZDNA, a lefthanded DNA conformation.
13: RMI1: Explores the essential functions of the RMI1 protein in DNA recombination and repair.
14: Triplestranded DNA: Discusses the formation and implications of triplestranded DNA structures in recombination.
15: Sgs1: Focuses on the Sgs1 helicase and its critical role in maintaining genomic integrity.
16: MUS81: Reviews the MUS81 protein's function in the resolution of recombination intermediates.
17: Crossover junction endodeoxyribonuclease: Explores the function of this enzyme in resolving crossover intermediates during recombination.
18: Homologous recombination: Delves deeper into homologous recombination's role in DNA repair and genetic diversity.
19: Nuclease: Investigates the importance of nucleases in DNA repair processes.
20: MLH1: Analyzes the role of MLH1 in meiosis and its role in preventing genetic errors.
21: Chromosome segregation: Concludes by reviewing chromosome segregation, the final stage in cell division, ensuring accurate genetic inheritance.
This book is designed to serve as a critical resource for anyone looking to understand the complexities of DNA origami and its related processes. Each chapter offers essential details, connecting molecular biology with innovative applications in the field. Whether you're a student or professional, this book will deepen your knowledge and provide you with a clearer perspective on the molecular foundations that shape life at the cellular level.
