ABSTRACT
Many cellular processes require large-scale rearrangements of chromatin structure. Structural maintenance of chromosomes (SMC) protein complexes are molecular machines that can provide structure to chromatin. These complexes can connect DNA elements in cis, walk along DNA, build and processively enlarge DNA loops and connect DNA molecules in trans to hold together the sister chromatids. These DNA-shaping abilities place SMC complexes at the heart of many DNA-based processes, including chromosome segregation in mitosis, transcription control and DNA replication, repair and recombination. In this Review, we discuss the latest insights into how SMC complexes such as cohesin, condensin and the SMC5-SMC6 complex shape DNA to direct these fundamental chromosomal processes. We also consider how SMC complexes, by building chromatin loops, can counteract the natural tendency of alike chromatin regions to cluster. SMC complexes thus control nuclear organization by participating in a molecular tug of war that determines the architecture of our genome.
Subject(s)
Chromatin , Chromosomes , Chromosomes/genetics , Chromosomes/metabolism , Chromatin/genetics , DNA/genetics , DNA Replication/genetics , Mitosis , Cell Cycle Proteins/chemistryABSTRACT
We investigated genome folding across the eukaryotic tree of life. We find two types of three-dimensional (3D) genome architectures at the chromosome scale. Each type appears and disappears repeatedly during eukaryotic evolution. The type of genome architecture that an organism exhibits correlates with the absence of condensin II subunits. Moreover, condensin II depletion converts the architecture of the human genome to a state resembling that seen in organisms such as fungi or mosquitoes. In this state, centromeres cluster together at nucleoli, and heterochromatin domains merge. We propose a physical model in which lengthwise compaction of chromosomes by condensin II during mitosis determines chromosome-scale genome architecture, with effects that are retained during the subsequent interphase. This mechanism likely has been conserved since the last common ancestor of all eukaryotes.
Subject(s)
Adenosine Triphosphatases/genetics , Adenosine Triphosphatases/physiology , Biological Evolution , Chromosomes/ultrastructure , DNA-Binding Proteins/genetics , DNA-Binding Proteins/physiology , Eukaryota/genetics , Genome , Multiprotein Complexes/genetics , Multiprotein Complexes/physiology , Adenosine Triphosphatases/chemistry , Algorithms , Animals , Cell Nucleolus/ultrastructure , Cell Nucleus/ultrastructure , Centromere/ultrastructure , Chromosomes/chemistry , Chromosomes, Human/chemistry , Chromosomes, Human/ultrastructure , DNA-Binding Proteins/chemistry , Genome, Human , Genomics , Heterochromatin/ultrastructure , Humans , Interphase , Mitosis , Models, Biological , Multiprotein Complexes/chemistry , Telomere/ultrastructureABSTRACT
E2F1, E2F2, and E2F3A, the three activators of the E2F family of transcription factors, are key regulators of the G1/S transition, promoting transcription of hundreds of genes critical for cell-cycle progression. We found that during late S and in G2, the degradation of all three activator E2Fs is controlled by cyclin F, the substrate receptor of 1 of 69 human SCF ubiquitin ligase complexes. E2F1, E2F2, and E2F3A interact with the cyclin box of cyclin F via their conserved N-terminal cyclin binding motifs. In the short term, E2F mutants unable to bind cyclin F remain stable throughout the cell cycle, induce unscheduled transcription in G2 and mitosis, and promote faster entry into the next S phase. However, in the long term, they impair cell fitness. We propose that by restricting E2F activity to the S phase, cyclin F controls one of the main and most critical transcriptional engines of the cell cycle.
