Disruption of nuclear lamin organization alters the distribution of replication factors and inhibits DNA synthesis

Detergent-salt resistance of LAP2alpha in interphase nuclei and phosphorylation-dependent association with chromosomes early in nuclear assembly implies functions in nuclear structure dynamics

Lamina-associated polypeptide (LAP) 2 of the inner nuclear membrane (now LAP2beta) and LAP2alpha are related proteins produced by alternative splicing, and contain a common 187 amino acid N-terminal domain. We show here that, unlike LAP2beta, LAP2alpha behaved like a nuclear non-membrane protein in subcellular fractionation studies and was localized throughout the nuclear interior in interphase cells. It co-fractionated with LAP2beta in nuclear lamina/matrix-enriched fractions upon extraction of nuclei with detergent, salt and nucleases. During metaphase LAP2alpha dissociated from chromosomes and became concentrated around the spindle poles. Furthermore, LAP2alpha was mitotically phosphorylated, and phosphorylation correlated with increased LAP2alpha solubility upon extraction of cells in physiological buffers. LAP2alpha relocated to distinct sites around chromosomes at early stages of nuclear reassembly and intermediarily co-localized with peripheral lamin B and intranuclear lamin A structures at telophase. During in vitro nuclear assembly LAP2alpha was dephosphorylated and assembled into insoluble chromatin-associated structures, and recombinant LAP2alpha was found to interact with chromosomes in vitro. Some LAP2alpha may also associate with membranes prior to chromatin attachment. Altogether the data suggest a role of LAP2alpha in post-mitotic nuclear assembly and in the dynamic structural organization of the nucleus.

Nuclear envelope remodelling during rat spermiogenesis: distribution and expression pattern of LAP2/thymopoietins

Lamina-associated polypeptide 2 (LAP2) and the thymopoietins (TPs) are a family of proteins described in somatic cells of mammals, which are derived by alternative splicing from a single gene. For one of the members of the family (LAP2 = TPbeta) it has been shown that this integral membrane protein locates to the inner membrane of the nuclear envelope, and that it binds to chromatin and B-type lamins. In the present study, we observed that during the third phase of spermatogenesis (i.e. spermiogenesis), TP-labelling shifted progressively to one half of the nuclear periphery in round spermatids. In the elongating spermatid the signal then becomes restricted to one spot located at the posterior (centriolar) pole of the nucleus. Changes in localization are accompanied by the disappearance, first of TPgamma, and later on of LAP2/TPbeta. TPalpha is the only member of the family detectable in the mature sperm. Concomitantly, lamin B1, the only nuclear lamina protein known to be expressed in mammalian spermatids, showed a similar behaviour, i.e. shifted progressively to the centriolar pole of spermatid nuclei before it became undetectable in fully differentiated mature sperms. These results are the first demonstration that expression and localization patterns of TPs are coordinately and differentially regulated with lamins during a differentiation process.

New systems for replicating DNA in vitro

Current paradigms for the regulation of genomic DNA replication in eukaryotes are derived primarily from cell fusion experiments, yeast genetics, and from in vitro assays in Xenopus egg extracts. Initially, many aspects seemed irreconcilably different among the various organisms and model systems. In the past year, however, divergent approaches have arrived at a consensus on how the cell cycle regulates the initiation of DNA replication. All major players appear to be conserved from yeast to vertebrates, yet the important challenge of reconstituting eukaryotic replication from purified components remains. Three novel in vitro assays that replicate nuclear templates bring us closer to this goal.

Multiple roles of the proliferating cell nuclear antigen: DNA replication, repair and cell cycle control

The proliferating cell nuclear antigen (PCNA), the auxiliary protein of DNA polymerase delta and epsilon, is involved in DNA replication and repair. This protein forms a homotrimeric structure which, encircling DNA, loads the polymerase on the DNA template. A role for PCNA in the cell cycle control is recognised on the basis of the interaction with cyclins, cyclin-dependent kinases (cdks) and the cdk-inhibitor p21 waf1/cip1/sdi1 protein. Association with the growth-arrest and DNA-damage inducible proteins gadd45 and MyD118, further demonstrates the role of PCNA as a component of the cell cycle control apparatus.

Replication origins in yeast versus metazoa: separation of the haves and the have nots

The recent flood of information concerning Saccharomyces cerevisiae replication origins and the proteins that interact with them contrasts alarmingly to the trickle of progress in our understanding of metazoan origins. In mammalian cells, origins are complex and heterogeneous, and appear to be selected by features of nuclear architecture that are re-established after each mitosis. Studies in Xenopus egg extracts have shown that once per cell cycle replication does not require specific origin sequences, despite the identification of functional homologues to yeast origin-binding proteins. These observations suggest that initiation of DNA replication in higher eukaryotes is focused to specific genomic regions by features of chromosome structure.

Regulated chromosomal DNA replication in the absence of a nucleus

Using Xenopus egg extracts, we have developed a completely soluble system for eukaryotic chromosomal DNA replication. In the absence of a nuclear envelope, a single, complete round of ORC-dependent DNA replication is catalyzed by cytosolic and nuclear extracts added sequentially to demembranated sperm chromatin or prokaryotic plasmid DNA. The absence of rereplication is explained by an activity present in the nucleus that prevents the binding of MCM to chromatin. Our results indicate that the role of the nuclear envelope in DNA replication is to concentrate activators and inhibitors of replication inside the nucleus. In addition, they provide direct evidence that metazoans use the same strategy as yeast to activate DNA replication and to restrict it to a single round per cell cycle.

The major nuclear envelope targeting domain of LAP2 coincides with its lamin binding region but is distinct from its chromatin interaction domain

LAP2 is an integral protein of the inner nuclear membrane which binds lamins and chromosomes and is suggested to have an important role in nuclear envelope organization. In a previous study we identified an internal 76-amino acid region of LAP2 which is required for stable targeting of the protein to the nuclear envelope. Here, we have mapped the lamin binding region of LAP2 and demonstrate that it coincides with this nuclear envelope targeting domain. In contrast, we found that the portion of LAP2 involved in binding to chromosomes resides in a separate region of the protein near its NH2 terminus. The minimal lamin binding region of LAP2 is capable of conferring stable nuclear envelope localization when attached to the transmembrane and partial lumenal domains of a protein that shows no nuclear envelope targeting activity. This directly supports the notion that a major mechanism for localization of integral membrane proteins at the inner nuclear membrane involves binding to lamins, which would constrain diffusion through the continuous nuclear envelope/endoplasmic reticulum membrane system.

Intermediate filaments and their associated proteins: multiple dynamic personalities

A fusion of mouse and human genetics has now proven that intermediate filaments form a flexible scaffold essential for structuring cytoplasm in a variety of cell contexts. In some cases, the formation of this scaffold is achieved through a newly identified family of intermediate-filament-associated proteins that form cross-bridges between intermediate filaments and other cytoskeletal elements, including actin and microtubules.

Lamin-binding fragment of LAP2 inhibits increase in nuclear volume during the cell cycle and progression into S phase

Lamina-associated polypeptide 2 (LAP2) is an integral membrane protein of the inner nuclear membrane that binds to both lamin B and chromatin and has a putative role in nuclear envelope (NE) organization. We found that microinjection of a recombinant polypeptide comprising the nucleoplasmic domain of rat LAP2 (residues 1-398) into metaphase HeLa cells does not affect the reassembly of transport-competent nuclei containing NEs and lamina, but strongly inhibits nuclear volume increase. This effect appears to be specifically due to lamin binding, because it also is caused by microinjection of the minimal lamin-binding region of LAP2 (residues 298-373) but not by the chromatin-binding domain (residues 1-88). Injection of the lamin-binding region of rat LAP2 into early G1 phase HeLa cells also strongly affects nuclear growth; it almost completely prevents the threefold nuclear volume increase that normally occurs during the ensuing 10 h. Moreover, injection of the fragment during early G1 phase strongly inhibits entry of cells into S phase, whereas injection during S phase has no apparent effect on ongoing DNA replication. Since the lamin-binding fragment of LAP2 most likely acts by inhibiting dynamics of the nuclear lamina, our results suggest that a normal function of LAP2 involves regulation of nuclear lamina growth. These data also suggest that lamina dynamics are required for growth of the NE and for nuclear volume increase during the cell cycle, and that progression into S phase is dependent on the acquisition of a certain nuclear volume.

Role of nuclear architecture in the initiation of eukaryotic DNA replication

The eukaryotic genome is compacted in the cell nucleus, in a way that allows its faithful and ordered replication each cell cycle. Chromatin is organized into topologically constrained loops that are anchored to the nuclear matrix by specific attachment regions (SARs). Chromatin loops were proposed to correspond to replication units. In particular, it has been suggested that replication origins coincide with SARs. Critical examination of these hypotheses has long been hampered by the elusive nature of higher eukaryotic DNA replication origins and termini. In recent years, however, a number of loci have been mapped for both SARs and replication units, and studies on the nuclear localization of replicating DNA and replication proteins have begun. We review these data and argue that they question this model. We then try to delineate other aspects of chromosome compartmentalization and cell-cycle remodeling which might be responsible for the specification and activation of metazoan DNA replication origins.

GST-lamin fusion proteins act as dominant negative mutants in Xenopus egg extract and reveal the function of the lamina in DNA replication

A cDNA encoding Xlamin B1 was cloned from a whole ovary mRNA by RT-PCR. GST-lamin fusion constructs were generated from this cDNA by first creating convenient restriction sites within the Xlamin B1 coding sequence, using PCR directed mutagenesis, and then sub-cloning relevant sequences into pGEX-4T-3. Two expression constructs were made, the first, termed delta 2+ lacked sequences encoding the amino-terminal 'head domain' of lamin B1 but included sequences encoding the nuclear localization signal sequence (NLS). The second expression construct, termed delta 2-, lacked sequences encoding the amino-terminal 'head domain' as well as sequences encoding the NLS. Purified fusion proteins expressed from these constructs, when added to egg extracts prior to sperm pronuclear assembly, formed hetero-oligomers with the endogenous lamin B3. The delta 2+ fusion protein prevented nuclear lamina assembly but not nuclear membrane assembly. The resulting nuclei were small (approximately 10 microns in diameter), did not assemble replication centers and failed to initiate DNA replication. When the delta 2- fusion protein was added to egg extracts prior to sperm pronuclear assembly, lamina assembly was delayed but not prevented. The resulting nuclei although small (approximately 12 microns), did form replication centers and initiated DNA replication. When added to egg extracts after sperm pronuclear assembly was completed delta 2+, but not delta 2-, entered the pre-formed nuclei causing lamina disassembly. However, the disassembly of the lamina by delta 2+ did not result in the disruption of replication centers and indeed these centres remained functional. These results are consistent with the hypothesis that lamina assembly precedes and is required for the formation of replication centers but does not support those centers directly.

Nuclear envelope dynamics during male pronuclear development

Upon fertilization, the sperm nucleus undergoes reactivation. The poreless sperm nuclear envelope is replaced by a functional male pronuclear envelope and the highly compact male chromatin decondenses. Here some recent evidence is examined: that disassembly of the sperm lamina is required for chromatin decondensation, that remnant portions of the sperm nuclear envelope target the binding of egg membrane vesicles that form the male pronuclear envelope, that functional male pronuclear envelopes containing lamin B receptor assemble prior to lamin import and lamina formation, and that lamina assembly drives male pronuclear swelling. Several unresolved issues are discussed.