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Related Concept Videos

Interphase00:54

Interphase

The cell cycle occurs over approximately 24 hours (in a typical human cell) and in two distinct stages: interphase, which includes three phases of the cell cycle (G1, S, and G2), and mitosis (M). During interphase, which takes up about 95 percent of the duration of the eukaryotic cell cycle, cells grow and replicate their DNA in preparation for mitosis.
The Cell Cycle Control System02:11

The Cell Cycle Control System

The cell cycle is an organized set of events that leads the cell to divide into two daughter cells, each containing chromosomes identical to the parent cell. It is the cell cycle that leads to the formation of an entire organism from a single-cell zygote. Besides, cell division also functions in the renewal or repair of tissues in adult multicellular eukaryotes. For example, in the bone marrow, the stem cells divide to form new blood cells. Although essential for several functions, cell...
Interphase00:56

Interphase

The cell cycle occurs over approximately 24 hours (in a typical human cell) and in two distinct stages: interphase, which includes three phases of the cell cycle (G1, S, and G2), and mitosis (M). During interphase, which takes up about 95 percent of the duration of the eukaryotic cell cycle, cells grow and replicate their DNA in preparation for mitosis.
Phases of Interphase
Following each period of mitosis and cytokinesis, eukaryotic cells enter interphase, during which they grow and replicate...
The Cell Cycle Control System02:11

The Cell Cycle Control System

The cell cycle is an organized set of events that leads the cell to divide into two daughter cells, each containing chromosomes identical to the parent cell. It is the cell cycle that leads to the formation of an entire organism from a single-cell zygote. Besides, cell division also functions in the renewal or repair of tissues in adult multicellular eukaryotes. For example, in the bone marrow, the stem cells divide to form new blood cells. Although essential for several functions, cell...
The Cell Cycle Control System01:28

The Cell Cycle Control System

The cell cycle regulation directs how a cell proceeds from one phase to the next and begins mitosis. The cell cycle control system includes intracellular regulatory molecules and external triggers. They provide "stop" or "advance" signals and operate at specific cell cycle stages termed checkpoints to ensure that a particular process is completed before the cell advances to the next phase.
Cyclins and cyclin-dependent kinases (Cdks) are the primary cell cycle regulators and function at the cell...

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scHiCyclePred: a deep learning framework for predicting cell cycle phases from single-cell Hi-C data using

Yingfu Wu1,2,3, Zhenqi Shi1, Xiangfei Zhou1

  • 1School of Software, Shandong University, Jinan, Shandong, China.

Communications Biology
|July 31, 2024
PubMed
Summary
This summary is machine-generated.

We developed scHiCyclePred, a new model that accurately predicts cell cycle phases using single-cell Hi-C (scHi-C) data. This tool enhances understanding of 3D chromatin structure dynamics and aids disease research.

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Area of Science:

  • Genomics
  • Molecular Biology
  • Computational Biology

Background:

  • Single-cell Hi-C (scHi-C) technology enables studying 3D chromatin structure across the cell cycle.
  • Accurate prediction of cell cycle phases from scHi-C data is challenging.

Purpose of the Study:

  • To introduce scHiCyclePred, a novel prediction model for cell cycle phase determination using scHi-C data.
  • To leverage multi-scale 3D chromatin interaction features for improved prediction accuracy.

Main Methods:

  • scHiCyclePred integrates multiple feature sets, including multi-scale interaction information, to capture 3D chromatin structure.
  • Comparative analysis against Nagano_method and CIRCLET was performed using standard metrics (ACC, F1, Precision, Recall, BACC).
  • Evaluation was conducted on a complex tissue dataset (Liu_dataset).

Main Results:

  • scHiCyclePred significantly outperforms existing methods like Nagano_method and CIRCLET in predicting cell cycle phases.
  • On the Liu_dataset, scHiCyclePred showed substantial improvements over CIRCLET: +0.39 (ACC), +0.52 (F1), +0.52 (Precision), +0.39 (Recall).
  • The study provides new insights into 3D chromatin dynamics and gene features during the cell cycle.

Conclusions:

  • scHiCyclePred offers a robust method for predicting cell cycle phases from scHi-C data.
  • The model enhances the understanding of cell cycle-dependent chromatin organization.
  • Findings have implications for cell biology and disease research, with the tool available on GitHub.