The non-␣-helical C terminus of Xenopus lamin B3 (LB3T) inhibits the polymerization of lamin B3 in vitro and prevents the assembly of nuclei in Xenopus egg interphase extracts. To more precisely define the functions of LB3T in nuclear assembly, we have expressed subdomains of LB3T and determined their effects on nuclear assembly in Xenopus extracts. The results demonstrate that the Ig-fold motif (LB3T-Ig) is sufficient to inhibit lamin polymerization in vitro. Addition of the LB3T-Ig to egg extracts before the introduction of chromatin prevents chromatin decondensation and the assembly of the lamina, membranes, and pore complexes comprising the nuclear envelope. When added to assembled nuclei, LB3T-Ig prevents the further incorporation of lamin B3 into the endogenous lamina and blocks nuclear growth. The introduction of a point mutation in LB3T-Ig (R454W; LB3T-IgRW), known to cause Emery-Dreifuss muscular dystrophy when present in lamin A, does not inhibit lamin polymerization, chromatin decondensation, or nuclear assembly and growth. These results shed light on the specific alterations in lamin functions attributable to a known muscular dystrophy mutation and provide an experimental framework for revealing the effects of other mutations causing a wide range of laminopathies. ''tail'' domains (3, 4). The crystal structures of three small regions within these domains are known. These structures include coils 1A and 2B of the central rod (5) and the Ig-like fold (Ig-fold) present in the tail (6, 7). The ␣-helical rod domain is required for the formation of coiled-coil lamin dimers, which are the building blocks of higher order lamin structures. The function(s) of the Ig-fold in the nuclear lamins is unknown. In other systems, however, this motif is involved in protein-protein, protein-DNA, and protein-phospholipid interactions (6).Within nuclei, lamins are found throughout the nucleoplasm and are concentrated in the lamina, which forms an interface between the inner nuclear membrane and chromatin (8,9). During the cell cycle, the organization of lamins in interphase nuclei is not static. For example, during S-phase, lamins associate with replication factors such as proliferating cell nuclear antigen and replication factor C (10-12), whereas in mitosis, lamins are phosphorylated by the mitotic kinase cdk1 (13), causing their disassembly during nuclear envelope breakdown (14 -16). Lamins are subsequently dephosphorylated as they repolymerize around chromatin during nuclear assembly in daughter cells (17,18). The process of lamin polymerization is initiated in the anaphase-telophase transition during which B-type lamins begin to assemble on chromosomes and continues into early G 1 (9).Insights into lamin functions have been obtained from studies of the cell-free assembly of nuclei in Xenopus egg interphase extracts (19). For example, addition of the non-␣-helical Cterminal domain of Xenopus lamin B3 (LB3T) inhibits lamin polymerization, chromatin decondensation, and nuclear membrane and pore assembly (20). Other lam...
