Purification of intact nuclear lamina and identification of novel laminlike proteins in Raji, a cell line devoid of lamins A and C.

Research on the structure of the nuclear lamina and the nuclear matrix of cells devoid of lamins A and C has been hampered by the fact that intact residual nuclear structures are difficult to isolate from such cells. In this paper, we show that some extraction parameters, such as buffer composition and the nature of the detergent used to remove nuclear membranes, are critical for achieving isolation of whole nuclear residual structures from the lymphoblastic cell line Raji, used as a model for cells without lamins A and C. Electron microscopic analysis shows that the nuclear lamina of Raji cells is formed by a network of intermediate-size filaments interrupted with circular discontinuities. Both lamins B1 and B2, and lamin D/E, are present in this structure. In addition, a group of 45-kDa proteins or intermediate filament protein--reacting proteins (IFA-RPs), located uniquely in the lamina, were found to exhibit the same immunological and chemical characteristics as lamins. Although they behave like nuclear lamins, microsequencing analysis of the IFA-RPs has revealed no homology with known lamins. These IFA-RPs may contribute to the formation of the nuclear lamina filament network in the absence of lamins A and C.

The cytosolic chaperonin subunit TRiC-P5 begins to be expressed at the two-cell stage in mouse embryos.

The cytosolic chaperonin TRiC is a large protein complex involved in the folding of newly synthesized actin and tubulin. The fertilization of the mouse oocyte is followed by a remodelling of the actin and tubulin filaments. The TRiC subunit TCP1 is expressed only from the 4-cell stage on, even though actin and tubulin are synthesized in the previous stages. We investigated the onset of synthesis of another subunit, TRiC-P5, during early mouse embryogenesis. We report that TRiC-P5 is synthesized at the 2-cell stage in an alpha-amanitin sensitive manner. Thus, it is expressed before TCP1 and is one of the first proteins to be synthesized after zygotic genome activation.

TRiC-P5, a novel TCP1-related protein, is localized in the cytoplasm and in the nuclear matrix.

We have recently reported the cloning of a novel protein, TRiC-P5, with significant homology with protein 1 of the t-complex (TCP1). In the present study, the cellular localization of TRiC-P5 in Raji cells has been determined using an antiserum raised against a 18.5 kDa fusion protein. Results from cell fractionation and immunoblot studies indicate that TRiC-P5 is mainly localized in the cytoplasm. In addition, a significant part of TRiC-P5 is also found in the nucleus where it is attached to the nuclear matrix, a complex filament network involved in essential cellular functions such as DNA replication, and RNA transcription and maturation. Immunofluorescence experiments using the anti-TRiC-P5 antibodies confirm these results. We also provide evidence that, in the cytoplasm, TRiC-P5 is part of a large protein complex, most probably the TCP1-ring complex (TRiC), a hetero-oligomeric ring complex that plays a role of molecular chaperone in the folding of actin and tubulin.

Assignment of the human homologue of the mTRiC-P5 gene (TRIC5) to band 1q23 by fluorescence in situ hybridization.

The TCP1 ring complex (TRiC) is a molecular chaperone involved in actin and tubulin folding. Little is known about the components of this complex. The first component identified was TCP1, a protein coded by a gene in the t-complex locus on mouse chromosome 17. This locus is involved in several embryonic defects, male sterility, and the transmission ratio distortion. In humans, the t-complex genes map to chromosome 6. Other components of TRiC are thought to be TCP1-related proteins. Recently, a mouse cDNA coding for one of these proteins has been cloned and named mTRiC-P5. Here we report the cloning of a partial human cDNA clone, homologous to mTRiC-P5, and its chromosome localization by fluorescence in situ hybridization. The human TRiC-P5 gene (TRIC5) maps to human chromosome 1q23, a region known to be a preferential chromosomal breakpoint involved in leukemia. Therefore, even if TCP1 and TRiC-P5 are related proteins and are found in the same protein complex, they are not coded by syntenic genes in humans.

cDNA encoding a novel TCP1-related protein.

We report the cloning of a mouse cDNA encoding a novel protein which has significant homology with the t-complex protein 1b (TCP1b). In addition, this protein has high sequence identity with tryptic peptides from the bovine P5 subunit of the TCP1-ring complex. We named this novel protein mTRiC-P5 for mouse TCP1-Ring Complex Protein #5. Results indicate that mTRiC-P5 is a new member of the TCP1-TF55 family and is part of the TCP1-ring complex.