Lamin

Lamins, also known as nuclear lamins are fibrous proteins in type V intermediate filaments, providing structural function and transcriptional regulation in the cell nucleus. Nuclear lamins interact with inner nuclear membrane proteins to form the nuclear lamina on the interior of the nuclear envelope. Lamins have elastic and mechanosensitive properties, and can alter gene regulation in a feedback response to mechanical cues. Lamins are present in all animals but are not found in microorganisms, plants or fungi. Lamin proteins are involved in the disassembling and reforming of the nuclear envelope during mitosis, the positioning of nuclear pores, and programmed cell death. Mutations in lamin genes can result in several genetic laminopathies, which may be life-threatening. Lamins were first identified in the cell nucleus, using electron-microscopy. However, they were not recognized as vital components of nuclear structural support until 1975. During this time period, investigations of rat liver nuclei revealed that lamins have an architectural relationship with chromatin and nuclear pores. Later in 1978, immunolabeling techniques revealed that lamins are localized at the nuclear envelope under the inner nuclear membrane. It wasn't until 1986 that an analysis of lamin cDNA clones across a variety of species supported that lamins belong to the intermediate filament (IF) protein family. Further investigations found evidence that supports that all IF proteins arose from a common lamin-like ancestor. This theory is based on the observation that organisms that contain IF proteins necessarily contain lamins as well; however, the presence of lamins is not a requirement for simultaneously containing IF proteins. Furthermore, sequence comparisons between lamins and IF proteins support that an amino-acid sequence that is characteristic of lamins is found in early forms of IF proteins. This sequence is lost in later forms of IF proteins, suggesting that the structure of later intermediate filaments diverged.