Long terminal repeat-like elements flank a human immunoglobulin epsilon pseudogene that lacks introns

There are at least three immunoglobulin epsilon genes (C epsilon 1, C epsilon 2, and C epsilon 3) in the human genome. The nucleotide sequences of the expressed epsilon gene (C epsilon 1) and one (C epsilon 3) of the two epsilon pseudogenes were compared. The results show that the C epsilon 3 gene lacks the three intervening sequences entirely and has a 31-base A-rich sequence 16 bases 3' to the putative poly(A) addition signal, indicating that the C epsilon 3 gene is a processed gene. The C epsilon 3 gene sequence is homologous to the five separate DNA segments of the C epsilon 1 gene; namely, a segment in the 5'-flanking region (100 bases) and four exons, which are interrupted by a spacer region or intervening sequences. Long terminal repeat (LTR)-like sequences which contain TATAAA and AATAAA sequences as well as terminal inverted repeats are present in both 5'- and 3'-flanking regions. The 5' and 3' LTR-like sequences do not, however, constitute a direct repeat, unlike transposable elements of eukaryotes and retroviruses. The 3' LTR-like sequence is repetitive in the human genome, but is not homologous to the Alu family DNA. Models for the evolutionary origin of the processed gene flanked by the LTR-like sequences are discussed. The C epsilon 3 gene has a new open frame which codes potentially for an unknown protein of 292 amino acid residues.     

A simple and precise aberrant translocation of the rat c-myc gene into the epsilon-heavy chain switch region of the IgE-producing immunocytoma, IR162

We report a simple type of reciprocal chromosomal translocation in the LOU rat IgE-secreting immunocytoma cell line, IR162, involving the c-myc protooncogene and the switch region of the epsilon immunoglobulin heavy chain, c-myc/S epsilon. By cloning and sequencing the translocation-associated and the homologous normal c-myc and S epsilon DNAs, we have identified the position of the translocational junction in both the c-myc 5'-flanking region and the repetitive elements of the S epsilon region. The translocational recombination was precise, and no insertion or N-addition was found in the junctional region, leaving all the c-myc exons, together with two promoter sites, intact. RNase mapping confirmed that the same promoters were utilized in IR162 and normal LOU spleen cells. No point mutation was found in the 5'-flanking region and the 3'-portion of exon 1 of the translocated c-myc gene. However, the putative silencer region was lost with the translocation. It was also noticed that a strikingly AT-rich sequence associated with S epsilon region had translocated to the 5'-flanking region of c-myc gene. We discuss the possibility that a change of DNA topology, perhaps either due to the juxtaposition of an AT-rich sequence of the S epsilon region, or to the loss of the putative silencer element, may contribute to c-myc gene deregulation in IR162.     

DNA polymerase epsilon: the latest member in the family of mammalian DNA polymerases

DNA polymerase epsilon is a mammalian polymerase that has a tightly associated 3'----5' exonuclease activity. Because of this readily detectable exonuclease activity, the enzyme has been regarded as a form of DNA polymerase delta, an enzyme which, together with DNA polymerase alpha, is in all probability required for the replication of chromosomal DNA. Recently, it was discovered that DNA polymerase epsilon is both catalytically and structurally distinct from DNA polymerase delta. The most striking difference between the two DNA polymerases is that processive DNA synthesis by DNA polymerase delta is dependent on proliferating cell nuclear antigen (PCNA), a replication factor, while DNA polymerase epsilon is inherently processive. DNA polymerase epsilon is required at least for the repair synthesis of UV-damaged DNA. DNA polymerases are highly conserved in eukaryotic cells. Mammalian DNA polymerases alpha, delta and epsilon are counterparts of yeast DNA polymerases I, III and II, respectively. Like DNA polymerases I and III, DNA polymerase II is also essential for the viability of cells, which suggests that DNA polymerase II (and epsilon) may play a role in DNA replication.     

The small subunits of human and mouse DNA polymerase epsilon are homologous to the second largest subunit of the yeast Saccharomyces cerevisiae DNA polymerase epsilon.

Human DNA polymerase epsilon is composed of a 261 kDa catalytic polypeptide and a 55 kDa small subunit of unknown function. cDNAs encoding the small subunit of human and mouse DNA polymerase epsilon were cloned. The predicted polypeptides have molecular masses of 59.469 and 59.319 kDa respectively and they are 90% identical. The human and mouse polypeptides show 22% identity with the 80 kDa subunit of the five subunit DNA polymerase epsilon from the yeast Saccharomyces cerevisiae. The high degree of conservation suggests that the 55 kDa subunit shares an essential function with the yeast 80 kDa subunit, which was earlier suggested to be involved in S phase cell cycle control in a pathway that is able to sense and signal incomplete replication. The small subunits of human and mouse DNA polymerase epsilon also show homology to the C-terminal domain of the second largest subunit of DNA polymerase alpha. The gene for the small subunit of human DNA polymerase epsilon (POLE2) was localized to chromosome 14q21-q22 by fluorescence in situ hybridization.     

Ig mu-epsilon isotype switch in IL-4-treated human B lymphoblastoid cells. Evidence for a sequential switch.

IgE is produced by B lymphocytes that have undergone a deletional rearrangement of their Ig H chain gene locus, a rearrangement that joins the switch region of the mu gene, S mu, with the corresponding region of the epsilon gene, S epsilon. To examine the resulting composite S mu-S epsilon junctions of human lymphoid cells, we have used a polymerase chain reaction strategy to clone the switch regions of the human myeloma U266 and of two IgE-producing human cell lines generated by treatment of lymphocytes with EBV plus IL-4. The switch junction of one of the EBV lines is a complex rearrangement in which a fragment of S gamma is interposed between S mu and S epsilon. This finding suggested that the switch to epsilon in this human lymphoid cell was preceded by a S mu-S gamma recombination. To determine whether this sequential switch rearrangement represented a unique event or occurred with some regularity in human B cells switching to IgE production, DNA samples from bulk cultures of lymphocytes treated with IL-4 were subjected to polymerase chain reaction amplification of their S mu-S epsilon junctions. When the resulting fragments were examined by Southern blotting, a substantial fraction hybridized to an S gamma probe. This finding suggests that sequential recombination involving S gamma is not rare in the switch to epsilon production in humans. Our polymerase chain reaction strategy should be useful in studying isotype switching at the DNA level.     

Involvement of the essential yeast DNA polymerases in induced gene conversion

In the yeast Saccharomyces cerevisiae three different DNA polymerases alpha, delta and epsilon are involved in DNA replication. DNA polymerase alpha is responsible for initiation of DNA synthesis and polymerases delta and epsilon are required for elongation of DNA strand during replication. DNA polymerases delta and epsilon are also involved in DNA repair. In this work we studied the role of these three DNA polymerases in the process of recombinational synthesis. Using thermo-sensitive heteroallelic mutants in genes encoding DNA polymerases we studied their role in the process of induced gene conversion. Mutant strains were treated with mutagens, incubated under permissive or restrictive conditions and the numbers of convertants obtained were compared. A very high difference in the number of convertants between restrictive and permissive conditions was observed for polymerases alpha and delta, which suggests that these two polymerases play an important role in DNA synthesis during mitotic gene conversion. Marginal dependence of gene conversion on the activity of polymerase epsilon indicates that this DNA polymerase may be involved in this process but rather as an auxiliary enzyme.     

Constitution of the twin polymerase of DNA polymerase III holoenzyme

It is speculated that DNA polymerases which duplicate chromosomes are dimeric to provide concurrent replication of both leading and lagging strands. DNA polymerase III holoenzyme (holoenzyme), is the 10-subunit replicase of the Escherichia coli chromosome. A complex of the alpha (DNA polymerase) and epsilon (3'-5' exonuclease) subunits of the holoenzyme contains only one of each protein. Presumably, one of the eight other subunit(s) functions to dimerize the alpha epsilon polymerase within the holoenzyme. Based on dimeric subassemblies of the holoenzyme, two subunits have been elected as possible agents of polymerase dimerization, one of which is the tau subunit (McHenry, C. S. (1982) J. Biol. Chem. 257, 2657-2663). Here, we have used pure alpha, epsilon, and tau subunits in binding studies to determine whether tau can dimerize the polymerase. We find tau binds directly to alpha. Whereas alpha is monomeric, tau is a dimer in its native state and thereby serves as an efficient scaffold to dimerize the polymerase. The epsilon subunit does not associate directly with tau but becomes dimerized in the alpha epsilon tau complex by virtue of its interaction with alpha. We have analyzed the dimeric alpha epsilon tau complex by different physical methods to increase the confidence that this complex truly contains a dimeric polymerase. The tau subunit is comprised of the NH2-terminal two-thirds of tau but does not bind to alpha epsilon, identifying the COOH-terminal region of tau as essential to its polymerase dimerization function. The significance of these results with respect to the organization of subunits within the holoenzyme is discussed.     

Extended nucleotide sequence of the switch region of the murine gene encoding immunoglobulin E

The nucleotide sequence of the switch region (S epsilon) of the gene encoding murine IgE was determined from a germline DNA clone. The sequence extends 1.7 kb 5' to the previously published S epsilon sequence. Another 33 repeat units were located by comparison to the S epsilon consensus sequence. Therefore, the complete S epsilon repetitive sequence consists of 53 repeat units contained in a region about 2.5 kb long.     

Two functional domains of the epsilon subunit of DNA polymerase III

The epsilon subunit is the 3'-->5' proofreading exonuclease that associates with the alpha and theta subunits in the E. coli DNA polymerase III. Two fragments of the epsilon protein were prepared, and binding of these epsilon fragments with alpha and theta was investigated using gel filtration chromatography and exonuclease stimulation assays. The N-terminal fragment of epsilon, containing amino acids 2-186 (epsilon186), is a relatively protease-resistant core domain of the exonuclease. The purified recombinant epsilon186 protein catalyzes the cleavage of 3' terminal nucleotides, demonstrating that the exonuclease domain of epsilon is present in the N-terminal region of the protein. The absence of the C-terminal 57 amino acids of epsilon in the epsilon186 protein reduces the binding affinity of epsilon186 for alpha by at least 400-fold relative to the binding affinity of epsilon for alpha. In addition, stimulation of the epsilon186 exonuclease by alpha using a partial duplex DNA is about 50-fold lower than stimulation of the epsilon exonuclease by alpha. These results indicate that the C-terminal region of epsilon is required in the epsilonalpha association. To directly demonstrate that the C-terminal region of epsilon contains the alpha-association domain fusion protein, constructs containing the maltose-binding protein (MBP) and fragments of the C-terminal region of epsilon were prepared. Gel filtration analysis demonstrates that the alpha-association domain of epsilon is contained within the C-terminal 40 amino acids of epsilon. Also, the epsilon186 protein forms a tight complex with theta, demonstrating that the association of theta with epsilon is localized to the N-terminal region of epsilon. Association of epsilon186 and theta is further supported by the stimulation of the epsilon186 exonuclease in the presence of theta. These data support the concept that epsilon contains a catalytic domain located within the N-terminal region and an alpha-association domain located within the C-terminal region of the protein.     

DNA polymerase epsilon: in search of a function.

The current model of eukaryotic DNA replication involves the two DNA polymerases delta and alpha as the leading and lagging strand enzymes, respectively. A DNA polymerase first discovered in yeast has now been found in all eukaryotic cells and is termed DNA polymerase epsilon. In yeast, the gene for DNA polymerase epsilon has recently been found to be essential for viability, raising new questions about its functions.     

Elucidation of the epsilon-theta subunit interface of Escherichia coli DNA polymerase III by NMR spectroscopy

The DNA polymerase III holoenzyme (HE) is the primary replicative polymerase of Escherichia coli. The epsilon (epsilon) subunit of HE provides the 3'-->5' exonucleolytic proofreading activity for this complex. Epsilon consists of two domains: an N-terminal domain containing the proofreading exonuclease activity (residues 1-186) and a C-terminal domain required for binding to the polymerase (alpha) subunit (residues 187-243). In addition to alpha, epsilon also binds the small (8 kDa) theta (theta) subunit. The function of theta is unknown, although it has been hypothesized to enhance the 3'-->5' exonucleolytic proofreading activity of epsilon. Using NMR analysis and molecular modeling, we have previously reported a structural model of epsilon186, the N-terminal catalytic domain of epsilon [DeRose et al. (2002) Biochemistry 41, 94]. Here, we have performed 3D triple resonance NMR experiments to assign the backbone and C(beta) resonances of [U-(2)H,(13)C,(15)N] methyl protonated epsilon186 in complex with unlabeled theta. A structural comparison of the epsilon186-theta complex with free epsilon186 revealed no major changes in secondary structure, implying that the overall structure is not significantly perturbed in the complex. Amide chemical shift comparisons between bound and unbound epsilon186 revealed a potential binding surface on epsilon for interaction with theta involving structural elements near the epsilon catalytic site. The most significant shifts observed for the epsilon186 amide resonances are localized to helix alpha1 and beta-strands 2 and 3 and to the region near the beginning of alpha-helix 7. Additionally, a small stretch of residues (K158-L161), which previously had not been assigned in uncomplexed epsilon186, is predicted to adopt beta-strand secondary structure in the epsilon186-theta complex and may be significant for interaction with theta. The amide shift pattern was confirmed by the shifts of aliphatic methyl protons, for which the larger shifts generally were concentrated in the same regions of the protein. These chemical shift mapping results also suggest an explanation for how the unstable dnaQ49 mutator phenotype of epsilon may be stabilized by binding theta.