Caenorhabditis elegans has a single lamin gene, designated lmn-1 (previously termed CeLam-1). Antibodies raised against the lmn-1 product (Ce-lamin) detected a 64-kDa nuclear envelope protein. Ce-lamin was detected in the nuclear periphery of all cells except sperm and was found in the nuclear interior in embryonic cells and in a fraction of adult cells. Reductions in the amount of Ce-lamin protein produce embryonic lethality. Although the majority of affected embryos survive to produce several hundred nuclei, defects can be detected as early as the first nuclear divisions. Abnormalities include rapid changes in nuclear morphology during interphase, loss of chromosomes, unequal separation of chromosomes into daughter nuclei, abnormal condensation of chromatin, an increase in DNA content, and abnormal distribution of nuclear pore complexes (NPCs). Under conditions of incomplete RNA interference, a fraction of embryos escaped embryonic arrest and continue to develop through larval life. These animals exhibit additional phenotypes including sterility and defective segregation of chromosomes in germ cells. Our observations show that lmn-1 is an essential gene in C. elegans, and that the nuclear lamins are involved in chromatin organization, cell cycle progression, chromosome segregation, and correct spacing of NPCs. INTRODUCTIONThe nuclear lamina is a filamentous meshwork that is present between the inner nuclear membrane and the peripheral chromatin. The inner nuclear membrane and the nuclear lamina are involved in organizing nuclear structure and regulating nuclear events. These include the organization of the higher order structure of chromatin and regulation of nuclear assembly and disassembly. The nuclear lamina is a primary target for caspases in apoptosis (reviewed in Goldberg et al., 1999b). Lamins are the major proteins of the nuclear lamina. They are classified as type-V intermediate filaments and are composed of an ␣-helical rod domain flanked by a short amino (head) and a long carboxy (tail) domains. The rod domain of lamins is 52-nm long and contains four ␣-helices, each composed of heptad repeats. Coiled-coil interactions and head-to-tail associations between lamin monomers form 10-to 200-nm thick lamin filaments (reviewed in Stuurman et al., 1998) In vivo, lamin filaments are closely associated with the chromatin fibers (Belmont et al., 1993). In vitro, lamins can bind interphase chromatin (Hoger et al., 1991;Yuan et al., 1991;Taniura et al., 1995;Ulitzur et al., 1997;Goldberg et al., 1999a), mitotic chromosomes (Glass and Gerace, 1990;Glass et al., 1993), or specific DNA sequences (Shoeman and Traub, 1990;Luderus et al., 1992;Luderus et al., 1994;Baricheva et al., 1996;Zhao et al., 1996). The binding site of vertebrate lamins to chromatin is localized to specific sequences in the tail domain and can be displaced with the core histones H2A and H2B (Taniura et al., 1995;Goldberg et al., 1999a).The composition of the nuclear lamina varies in different cell types and is under developmental regulation ...
The Caenorhabditis elegans Bcl-2-like protein CED-9 prevents programmed cell death by antagonizing the Apaf-1-like cell-death activator CED-4. Endogenous CED-9 and CED-4 proteins localized to mitochondria in wild-type embryos, in which most cells survive. By contrast, in embryos in which cells had been induced to die, CED-4 assumed a perinuclear localization. CED-4 translocation induced by the cell-death activator EGL-1 was blocked by a gain-of-function mutation in ced-9 but was not dependent on ced-3 function, suggesting that CED-4 translocation precedes caspase activation and the execution phase of programmed cell death. Thus, a change in the subcellular localization of CED-4 may drive programmed cell death.
We have cloned cytoplasmic intermediate filament (IF) proteins from a large number of invertebrate phyla using cDNA probes, the monoclonal antibody IFA, peptide sequence information, and various RT-PCR procedures. Novel IF protein sequences reported here include the urochordata and nine protostomic phyla, i.e., Annelida, Brachiopoda, Chaetognatha, Echiura, Nematomorpha, Nemertea, Platyhelminthes, Phoronida, and Sipuncula. Taken together with the wealth of data on IF proteins of vertebrates and the results on IF proteins of Cephalochordata, Mollusca, Annelida, and Nematoda, two IF prototypes emerge. The L-type, which includes 35 sequences from 11 protostomic phyla, shares with the nuclear lamins the long version of the coil 1b subdomain and, in most cases, a homology segment of some 120 residues in the carboxyterminal tail domain. The S-type, which includes all four subfamilies (types I to IV) of vertebrate IF proteins, lacks 42 residues in the coil 1b subdomain and the carboxyterminal lamin homology segment. Since IF proteins from all three phyla of the chordates have the 42-residue deletion, this deletion arose in a progenitor prior to the divergence of the chordates into the urochordate, cephalochordate, and vertebrate lineages, possibly already at the origin of the deuterostomic branch. Four phyla recently placed into the protostomia on grounds of their 18S rDNA sequences (Brachiopoda, Nemertea, Phoronida, and Platyhelminthes) show IF proteins of the L-type and fit by sequence identity criteria into the lophotrochozoic branch of the protostomia.
Cytoplasmic intermediate filament (IF) proteins of Caenorhabditis elegans are encoded by a dispersed multigene family comprising at least eight genes which map to three linkage groups. Exon sequences and intron patterns define three distinct subfamilies. While all eight IF genes display the long coil 1b subdomain of nuclear lamins, only six genes (a1‐a4, b1 and b2) retain a lamin‐like tail domain. Two genes (c1 and c2) have acquired entirely novel tail domains. The overall sequence identity of the rod domains is only 29%. The gene structures show a strong drift in number and positions of introns, none of which are common to all genes. Individual genes share only one to four intron locations with the Helix aspersa IF gene, but all eight nematode genes together account for nine of the 10 introns of the gastropod gene. All C.elegans IF genes are transcribed and all except gene c2 produce trans‐spliced mRNAs. Alternatively spliced mRNAs arise from genes a1, b2 and c2 through several mechanisms acting at the transcriptional and posttranscriptional levels. These involve the alternative use of distinct promoters, polyadenylation sequences and both cis and trans RNA splice sites. The resulting sequence variations are restricted to the non‐helical end domains. Minimally 12 distinct IF proteins are encoded by the various mRNAs. Different abundances in mixed‐stage nematode populations suggest cell type‐ and/or stage‐specific expression of individual mRNAs.
The structure of the single gene encoding the cytoplasmic intermediate filament (IF) proteins in non‐neuronal cells of the gastropod Helix aspersa is described. Genomic and cDNA sequences show that the gene is composed of 10 introns and 11 exons, spanning greater than 60 kb of DNA. Alternative RNA processing accounts for two mRNA families which encode two IF proteins differing only in their C‐terminal sequence. The intron/exon organization of the Helix rod domain is identical to that of the vertebrate type III IF genes in spite of low overall protein sequence homology and the presence of an additional 42 residues in coil 1b of the invertebrate sequence. Intron position homology extends to the entire coding sequence comprising both the rod and tail domains when the invertebrate IF gene is compared with the nuclear lamin LIII gene of Xenopus laevis presented in the accompanying report of Döring and Stick. In contrast the intron patterns of the tail domains of the invertebrate IF and the lamin genes differ from those of the vertebrate type III genes. The combined data are in line with an evolutionary descent of cytoplasmic IF proteins from a nuclear lamin‐like progenitor and suggest a mechanism for this derivation. The unique position of intron 7 in the Helix IF gene indicates that the archetype IF gene arose by the elimination of the nuclear localization sequence due to the recruitment of a novel splice site. The presumptive structural organization of the archetype IF gene allows predictions with respect to the later diversification of metazoan IF genes. Whereas models proposing a direct derivation of neurofilament genes seem unlikely, the earlier speculation of an mRNA transposition mechanism is compatible with current results.
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