Add to ORKGAmong different species or cell types, or during early embryonic cell divisions that occur in the absence of cell growth, the size of subcellular structures, including the nucleus, chromosomes, and mitotic spindle, scale with cell size. Maintaining correct subcellular scales is thought to be important for many cellular processes and, in particular, for mitosis. In this review, we provide an update on nuclear and chromosome scaling mechanisms and their significance in metazoans, with a focus on Caenorhabditis elegans, Xenopus and mammalian systems, for which a common role for the Ran (Ras-related nuclear protein)-dependent nuclear transport system has emerged
Background Cellular structures such as the nucleus, Golgi, centrioles, and spindle show remarkable ...
Ran is an abundant GTPase that is highly conserved in eukaryotic cells and has been implicated in ma...
SummaryThe spindle assembly checkpoint (SAC) delays mitotic progression when chromosomes are not pro...
Multicellular development requires that cells reduce in size as a result of consecutive cell divisio...
AbstractThe GTPase Ran is known to regulate transport of proteins across the nuclear envelope [1, 2]...
Size of the nucleus, a membrane-bound organelle for DNA replication and transcription in eukaryotic ...
Organelle function is often directly related to organelle size. However, it is not necessarily absol...
During embryonic development in metazoans, cells decrease in volume by up to two orders of magnitude...
Organelle function is often directly related to organelle size. However, it is not necessarily absol...
Just as organ size typically increases with body size, the size of intracellular structures changes ...
Cell division in all eukaryotes depends on function of the spindle, a microtubule-based structure th...
AbstractThe small GTPase Ran has roles in multiple cellular processes, including nuclear transport, ...
Background. Nuclear size is a tightly regulated cellular feature. Mechanisms that regulate nuclear s...
Multicellular organisms must regulate their growth across the diverse length scales of biological or...
SummaryMulticellular organisms must regulate their growth across the diverse length scales of biolog...
Background Cellular structures such as the nucleus, Golgi, centrioles, and spindle show remarkable ...
Ran is an abundant GTPase that is highly conserved in eukaryotic cells and has been implicated in ma...
SummaryThe spindle assembly checkpoint (SAC) delays mitotic progression when chromosomes are not pro...
Multicellular development requires that cells reduce in size as a result of consecutive cell divisio...
AbstractThe GTPase Ran is known to regulate transport of proteins across the nuclear envelope [1, 2]...
Size of the nucleus, a membrane-bound organelle for DNA replication and transcription in eukaryotic ...
Organelle function is often directly related to organelle size. However, it is not necessarily absol...
During embryonic development in metazoans, cells decrease in volume by up to two orders of magnitude...
Organelle function is often directly related to organelle size. However, it is not necessarily absol...
Just as organ size typically increases with body size, the size of intracellular structures changes ...
Cell division in all eukaryotes depends on function of the spindle, a microtubule-based structure th...
AbstractThe small GTPase Ran has roles in multiple cellular processes, including nuclear transport, ...
Background. Nuclear size is a tightly regulated cellular feature. Mechanisms that regulate nuclear s...
Multicellular organisms must regulate their growth across the diverse length scales of biological or...
SummaryMulticellular organisms must regulate their growth across the diverse length scales of biolog...
Background Cellular structures such as the nucleus, Golgi, centrioles, and spindle show remarkable ...
Ran is an abundant GTPase that is highly conserved in eukaryotic cells and has been implicated in ma...
SummaryThe spindle assembly checkpoint (SAC) delays mitotic progression when chromosomes are not pro...