Litcius/Paper detail

Scaling Laws for Mitotic Chromosomes

Eric M. Kramer, P. A. Tayjasanant, Bethan Cordone

2021Frontiers in Cell and Developmental Biology18 citationsDOIOpen Access PDF

Abstract

During mitosis in higher eukaryotes, each chromosome condenses into a pair of rod-shaped chromatids. This process is co-regulated by the activity of several gene families, and the underlying biophysics remains poorly understood. To better understand the factors regulating chromosome condensation, we compiled a database of mitotic chromosome size and DNA content from the tables and figures of >200 published papers. A comparison across vertebrate species shows that chromosome width, length and volume scale with DNA content to the powers ∼1/4, ∼1/2, and ∼1, respectively. Angiosperms (flowering plants) show a similar length scaling, so this result is not specific to vertebrates. Chromosome shape and size thus satisfy two conditions: (1) DNA content per unit volume is approximately constant and (2) the cross-sectional area increases proportionately with chromosome length. Since viscous drag forces during chromosome movement are expected to scale with length, we hypothesize that the cross-section increase is necessary to limit the occurrence of large chromosome elongations that could slow or stall mitosis. Lastly, we note that individual vertebrate karyotypes typically exhibit a wider range of chromosome lengths as compared with angiosperms.

Topics & Concepts

ChromosomeMitosisBiologyPremature chromosome condensationKaryotypeGeneticsChromatidEvolutionary biologyGeneChromosomal and Genetic VariationsMicrotubule and mitosis dynamicsPlant Molecular Biology Research