Genetic analysis of eight linked polymorphisms within the human immunoglobulin heavy-chain region.

Genetic analyses of multiple restriction fragment length polymorphisms, revealed by a single DNA probe containing the switch region of the immunoglobulin constant heavy-chain (IgCH) mu gene, are presented here in detail. Five of the polymorphic loci segregate in complete linkage with IgCH allotypic markers, while one appears to be located at more than 10 centimorgans from the IgCH region. A study of over 100 random haplotypes typed at eight linked loci, including the Ig switch polymorphisms and the classical Gm-Am allotypes, allowed us to construct an evolutionary tree by which each haplotypic variant can be derived one from the other either by single-step mutation or by recombination. A few of the recombinant haplotypes appeared to carry large DNA duplications that could be explained by unequal crossing over; others might postulate gene-conversion events. Linkage disequilibria observed between the IgCH-linked loci were compared with expected ones. A heterogeneous distribution of recombination rates is clearly documented, a "hot" region of recombination being present between the gamma 2 and switch alpha 2 loci.     

Familial clustering of IGHC deletions and duplications: functional and molecular analysis

The human immunoglobulin heavy chain constant region locus (IGHC) comprises nine genes and two pseudogenes clustered in a 350 kilobase (kb) region on chromosome 14q32. Several IGHC haplotypes with single or multiple gene deletions and duplications have been characterized. The most likely mechanism accounting for these unusual haplotypes is the unequal crossing-over between homologous regions within the locus. Here we report the analysis of an unusual case of familial clustering of deletions/duplications. In the two branches of the BON family, three duplicated and two deleted haplotypes, all probably independent in origin, have been characterized. The structure of the haplotypes, one of which is described here for the first time, supports the hypothesis of homologous unequal crossing-over as the origin of recombinant haplotypes. The analysis of serological markers in a subject carrying one deleted and one duplicated haplotype allowed us the first direct inferences concerning the functions of the duplicated IGHC haplotypes.     

A multigene deletion within the immunoglobulin heavy-chain region

The immunoglobulin heavy-chain genes are located in a cluster on chromosome 14. The simultaneous absence of the human IgG1, IgG2, IgG4, and IgA1 subclasses was previously reported in a healthy Tunisian Berber and was later shown to be due to a multigene deletion. We now describe a serological and molecular study of a different deletion observed in a healthy Tunisian. Blot hybridization analysis of the proband's DNA using gamma, epsilon, alpha, and mu switch probes showed that the deletion involves a large region of the immunoglobulin heavy-chain gene cluster: C psi epsilon, C alpha 1, C psi gamma, C gamma 2, and C gamma 4. Incidentally, we showed that the restriction enzyme EcoRI alone can be used with the alpha probe to differentiate A2m types. The deletion described, present in a person homozygous for GM-Am haplotypes (Gm1,17;..;5,14,11,13,10 A2m2), is consistent with previous location, by association analysis, of C psi gamma between C alpha 1 and C gamma 2. There is evidence to suggest that deletions may be more common in the Mediterranean region than in North American Caucasians.     

Variability of the immunoglobulin heavy chain constant region locus: a population study

The Immunoglobulin Heavy chain Constant region (IGHC) locus is a multigene family composed of highly homologous segments often involved in unequal crossings over that lead to deleted and duplicated haplotypes. The frequencies of these haplotypes in 558 individuals from Lombardy, Veneto, Puglia and Sardinia were determined by Pulsed Field Gel Electrophoresis (PFGE), followed by Southern blotting with four IGHC probes, and compared with those observed in 110 subjects from Piedmont. Twenty deletions and 60 duplications were characterized, all in heterozygous individuals except for 2 homozygous deletions. The differences in frequency between the five populations were not significant. The deletions/duplications involved one or more genes: GP-A2, A1-E and G4 duplications, and A1-E and GP-A2 deletions were the most common. Four new duplications are described: three, involving the genes from GP to A2, from G2 to G4, and G4, are counterparts of known deletions. The fourth duplication spans from GP to G2. A G1 deleted heterozygous individual never previously described in Italy is reported. All the rearranged haplotypes seem to be the result of unequal crossing over. The difference between the number of duplications and deletions was significant in Sardinia, Lombardy, Puglia and in the total of 668 subjects (P < 0.001). This may be due to selection or genetic drift.     

Rate of replication of the murine immunoglobulin heavy-chain locus: evidence that the region is part of a single replicon.

We measured the temporal order of replication of EcoRI segments from the murine immunoglobulin heavy-chain constant region (IgCH) gene cluster, including the joining (J) and diversity (D) loci and encompassing approximately 300 kilobases. The relative concentrations of EcoRI segments in bromouracil-labeled DNA that replicated during selected intervals of the S phase in Friend virus-transformed murine erythroleukemia (MEL) cells were measured. From these results, we calculated the nuclear DNA content (C value; the haploid DNA content of a cell in the G1 phase of the cell cycle) at the time each segment replicated during the S phase. We observed that IgCH genes replicate in the following order: alpha, epsilon, gamma 2a, gamma 2b, gamma 1, gamma 3, delta, and mu, followed by the J and D segments. The C value at which each segment replicates increased as a linear function of its distance from C alpha. The average rate of DNA replication in the IgCH gene cluster was determined from these data to be 1.7 to 1.9 kilobases/min, similar to the rate measured for mammalian replicons by autoradiography and electron microscopy (for a review, see H. J. Edenberg and J. A. Huberman, Annu. Rev. Genet. 9:245-284, 1975, and R. G. Martin, Adv. Cancer Res. 34:1-55, 1981). Similar results were obtained with other murine non-B cell lines, including a fibroblast cell line (L60T) and a hepatoma cell line (Hepa 1.6). In contrast, we observed that IgCh segments in a B-cell plasmacytoma (MPC11) and two Abelson murine leukemia virus-transformed pre-B cell lines (22D6 and 300-19O) replicated as early as (300-19P) or earlier than (MPC11 and 22D6) C alpha in MEL cells. Unlike MEL cells, however, all of the IgCH segments in a given B cell line replicated at very similar times during the S phase, so that a temporal directionality in the replication of the IgCH gene cluster was not apparent from these data. These results provide evidence that in murine non-B cells the IgCH, J, and D loci are part of a single replicon.     

Ig H chain variable and C region genes in common variable immunodeficiency. Characterization of two new deletion haplotypes.

Common variable immunodeficiency, a disorder characterized by diminished antibody production, manifests clinically as an increased susceptibility to bacterial infections. We have investigated the Ig H chain V and C region gene segments in 33 patients with common variable immunodeficiency, to identify the possible role these genes may have in the molecular basis of the defect. No major deletions were recognized for the VH gene segments of the VH2, VH5, and VH6 families, nor were there any differences in the RFLP patterns of mu- or alpha- switch regions or of C gamma genes. Two new deletion haplotypes were identified for the C region genes, the first encompassing C gamma 1 on a different haplotype from the C gamma 1 deletion described previously, and the second a novel deletion encompassing both C gamma 2 and C gamma 4. Based on these and previously described deletions in the IGHC region, we postulate that homologous regions are involved in the deletion process and that other new deletions likely exist in the population.     

Allelic diversification at the C (OsC1) locus of wild and cultivated rice: nucleotide changes associated with phenotypes

Divergent phenotypes are often detected in domesticated plants despite the existence of invariant phenotypes in their wild forms. One such example in rice is the occurrence of varying degrees of apiculus coloration due to anthocyanin pigmentation, which was previously reported to be caused by a series of alleles at the C locus. The present study reveals, on the basis of comparison of its maps, that the C gene appears to be the rice homolog (OsC1) of maize C1, which belongs to the group of R2R3-Myb factors. Two different types of deletions causing a frameshift were detected in the third exon, and both of the deleted nucleotides corresponded to the positions of putative base-contacting residues, suggesting that the Indica and Japonica types carry loss-of-function mutations with independent origins. In addition, replacement substitutions were frequently detected in OsC1 of strains carrying the previously defined C alleles. Molecular population analysis revealed that 17 haplotypes were found in 39 wild and cultivated rices, and the haplotypes of most cultivated forms could be classified into one of three distinct groups, with few shared haplotypes among taxa, including Indica and Japonica types. The genealogy of the OsC1 gene suggests that allelic diversification causing phenotypic change might have resulted from mutations in the coding region rather than from recombination between preexisting alleles. The McDonald and Kreitman test revealed that the changes in amino acids might be associated with selective forces acting on the lineage of group A whose haplotypes were carried by most Asian cultivated forms. The results regarding a significant implication for genetic diversity in landraces of rice are also discussed.     

Pulsed-field electrophoresis screening for immunoglobulin heavy-chain constant-region (IGHC) multigene deletions and duplications.

Genome regions containing multiple copies of homologous genes, such as the immunoglobulin (Ig) heavy-chain constant-region (IGHC) locus, are often unstable and give rise to duplicated and deleted haplotypes. Analysis of such processes is fundamental to understanding the mechanisms of evolution of multigene families. In the IGHC region, a number of single and multiple gene deletions, derived from either unequal crossing-over or looping-out excision, have been described. To study these haplotypes at the population level, a simple and efficient method for preparing large numbers of DNA samples suitable for pulsed-field gel electrophoresis (PFGE) analysis was set up, and a sample of 110 blood donors was screened. Deletions were found to be frequent, as expected on the basis of previous serological surveys for homozygotes. Furthermore, a number of multigene duplications, never identified before, were detected. The total frequency of individuals bearing rearranged IGHC haplotypes was 10%. The genes involved in these deletions and duplications were assessed by densitometric analysis of standard Southern blots hybridized with several IGHC probes; two types of deletion and two types of duplication could thus be characterized. These data provide further evidence of the instability of the IGHC locus and demonstrate that unequal crossing-over is the most likely origin of rearranged IGHC haplotypes; they also suggest that such recombination events may be relatively frequent. Moreover, the simplicity and effectiveness of the large-scale PFGE screening approach will be of great help in the study of multigene families and of other loci involved in aberrant recombinations.     

Genetic variants of human red-cell membrane sialoglycoprotein beta. Study of the alterations occurring in the sialoglycoprotein-beta gene.

We have studied the DNA of individuals who express an altered sialoglycoprotein beta on their red cells by using Southern blotting with sialoglycoprotein-beta cDNA probes. Individuals of the Leach phenotype do not express any beta (sialoglycoprotein beta) or gamma (sialoglycoprotein gamma) on their red cells, and we show that about 7 kb of DNA, including the 3' end of the beta gene, is deleted in this DNA. Any protein product of this gene is likely to lack the membrane-associating domain of beta. We have also examined the DNA of two types of other individuals (Yus-type and Gerbich-type) who have red cells that lack beta and gamma, but contain abnormal sialoglycoproteins related to beta. These two types of DNA contain different internal deletions of about 6 kb in the beta gene. We suggest that these deletions result from the presence of two different sets of internal homology in the beta gene, and on this basis we propose structures for the abnormal Yus-type and Gerbich-type sialoglycoproteins which are consistent with the other evidence that is available. We provide evidence that beta and gamma are products of the same gene and suggest a possible mechanism for the origin of gamma based on leaky initiation of translation of beta mRNA.     

Multiple levels of analysis of an IGHG4 gene deletion

Summary Human immunoglobulin heavy chain constant region (IGHC) genes constitute a typical multigene family, usually comprising eleven genes on the telomere of chromosome 14 (14q32). In this region, deleted and duplicated haplotypes have been reported to exist with considerable frequency. Their origin is the result of either unequal crossing-over or looping out excision. In this paper, we report the characterization of a new type of deletion, involving the IGHG4 gene, in a subject who also carries a larger deletion of a previously described type on the second chromosome. Employment of several methods (polymerase chain reaction, standard Southern blot, pulsed field gel electrophoresis, serological techniques) to analyze these deleted haplotypes has resulted in a level of accuracy in their characterization that has not been achieved in previous cases. The site of recombination responsible for the IGHG4 deletion was restricted to a 2.5-kb region 3 of the G4 gene; this rules out any possible involvement of the S regions in the recombination process. The usefulness of the various techniques in the characterization of the deletions is also discussed, together with possible future applications in the field.     

F1-ATPase, the C-terminal end of subunit gamma is not required for ATP hydrolysis-driven rotation

ATP hydrolysis by the isolated F(1)-ATPase drives the rotation of the central shaft, subunit gamma, which is located within a hexagon formed by subunits (alphabeta)(3). The C-terminal end of gamma forms an alpha-helix which properly fits into the "hydrophobic bearing" provided by loops of subunits alpha and beta. This "bearing" is expected to be essential for the rotary function. We checked the importance of this contact region by successive C-terminal deletions of 3, 6, 9, 12, 15, and 18 amino acid residues (Escherichia coli F(1)-ATPase). The ATP hydrolysis activity of a load-free ensemble of F(1) with 12 residues deleted decreased to 24% of the control. EF(1) with deletions of 15 or 18 residues was inactive, probably because it failed to assemble. The average torque generated by a single molecule of EF(1) when loaded by a fluorescent actin filament was, however, unaffected by deletions of up to 12 residues, as was their rotational behavior (all samples rotated during 60 +/- 19% of the observation time). Activation energy analysis with the ensemble revealed a moderate decrease from 54 kJ/mol for EF(1) (full-length gamma) to 34 kJ/mol for EF(1)(gamma-12). These observations imply that the intactness of the C terminus of subunit gamma provides structural stability and/or routing during assembly of the enzyme, but that it is not required for the rotary action under load, proper.     

Mitochondrial DNA deletions in mice in men: Substantia nigra is much less affected in the mouse

Mitochondrial DNA (mtDNA) deletions have been reported to accumulate to high levels in substantia nigra of older humans, and these mutations are suspected of causing age-related degeneration in this area. We have compared levels of mtDNA deletions in humans and mice and report here that levels of deletions in the mouse are very significantly lower than in humans. While human mtDNA from substantia nigra contained more than 5% of deleted molecules, mouse substantia nigra contained less than 0.5%. These results imply that mtDNA deletions are unlikely to play any significant role in of murine substantia nigra aging and further call for caution in using mouse models in studies of the role of mtDNA deletions in aging and neurodegeneration. On a more general note, these results support the view that critical targets of the various aging processes may differ significantly between distant species.     

Distinct regulatory effects of the Na,K-ATPase gamma subunit

The two variants of the gamma subunit of the rat renal sodium pump, gamma(a) and gamma(b), have similar effects on the Na,K-ATPase. Both increase the affinity for ATP due to a shift in the enzyme's E(1) <--> E(2) conformational equilibrium toward E(1). In addition, both increase K(+) antagonism of cytoplasmic Na(+) activation. To gain insight into the structural basis for these distinct effects, extramembranous N-terminal and C-terminal mutants of gamma were expressed in rat alpha1-transfected HeLa cells. At the N terminus, the variant-distinct region was deleted (gammaNDelta7) or replaced by alanine residues (gammaN7A). At the C terminus, four (gamma(a)CDelta4) or ten (gamma(a)CDelta10) residues were deleted. None of these mutations abrogates the K(+)/Na(+) antagonism as evidenced in a similar increase in K'(Na) seen at high (100 mm) K(+) concentration. In contrast, the C-terminal as well as N-terminal deletions (gammaNDelta7, gamma(a)CDelta4, and gamma(a)CDelta10) abolished the decrease in K'(ATP) seen with wild-type gamma(a) or gamma(b). It is concluded that different regions of the gamma chain mediate the distinct functional effects of gamma, and the effects can be long-range. In the transmembrane region, the impact of G41R replacement was analyzed since this mutation is associated with autosomal dominant renal Mg(2+)-wasting in man (Meij, I. C., Koenderink, J. B., van Bokhoven, H., Assink, K. F. H., Groenestege, W. T., de Pont, J. J. H. H. M., Bindels, R. J. M., Monnens, L. A. H., Van den Heuvel, L. P. W. J., and Knoers, N. V. A. M. (2000) Nat. Genet. 26, 265-266). The results show that Gly-41 --> Arg prevents trafficking of gamma but not alphabeta pumps to the cell surface and abrogates functional effects of gamma on alphabeta pumps. These findings underscore a potentially important role of gamma in affecting solute transport, in this instance Mg(2+) reabsorption, consequent to its primary effect on the sodium pump.     

Recurrent deletions of puroindoline genes at the grain hardness locus in four independent lineages of polyploid wheat

Polyploidy is known to induce numerous genetic and epigenetic changes but little is known about their physiological bases. In wheat, grain texture is mainly determined by the Hardness (Ha) locus consisting of genes Puroindoline a (Pina) and b (Pinb). These genes are conserved in diploid progenitors but were deleted from the A and B genomes of tetraploid Triticum turgidum (AB). We now report the recurrent deletions of Pina-Pinb in other lineages of polyploid wheat. We analyzed the Ha haplotype structure in 90 diploid and 300 polyploid accessions of Triticum and Aegilops spp. Pin genes were conserved in all diploid species and deletion haplotypes were detected in all polyploid Triticum and most of the polyploid Aegilops spp. Two Pina-Pinb deletion haplotypes were found in hexaploid wheat (Triticum aestivum; ABD). Pina and Pinb were eliminated from the G genome, but maintained in the A genome of tetraploid Triticum timopheevii (AG). Subsequently, Pina and Pinb were deleted from the A genome but retained in the A(m) genome of hexaploid Triticum zhukovskyi (A(m)AG). Comparison of deletion breakpoints demonstrated that the Pina-Pinb deletion occurred independently and recurrently in the four polyploid wheat species. The implications of Pina-Pinb deletions for polyploid-driven evolution of gene and genome and its possible physiological significance are discussed.     

The 20 C-terminal amino acid residues of the chloroplast ATP synthase gamma subunit are not essential for activity.

It has been suggested that the last seven to nine amino acid residues at the C terminus of the gamma subunit of the ATP synthase act as a spindle for rotation of the gamma subunit with respect to the alpha beta subunits during catalysis (Abrahams, J. P., Leslie, A. G. W., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628). To test this hypothesis we selectively deleted C-terminal residues from the chloroplast gamma subunit, two at a time starting at the sixth residue from the end and finishing at the 20th residue from the end. The mutant gamma genes were overexpressed in Escherichia coli and assembled with a native alpha3beta3 complex. All the mutant forms of gamma assembled as effectively as the wild-type gamma. Deletion of the terminal 6 residues of gamma resulted in a significant increase (>50%) in the Ca-dependent ATPase activity when compared with the wild-type assembly. The increased activity persisted even after deletion of the C-terminal 14 residues, well beyond the seven residues proposed to form the spindle. Further deletions resulted in a decreased activity to approximately 19% of that of the wild-type enzyme after deleting all 20 C-terminal residues. The results indicate that the tip of the gammaC terminus is not essential for catalysis and raise questions about the role of the C terminus as a spindle for rotation.     

Simulation of exon deletion mutations induced by low-LET radiation at the HPRT locus

Friedland, W., Li, W. B., Jacob, P. and Paretzke, H. G. Simulation of Exon Deletion Mutations Induced by Low-LET Radiation at the HPRT Locus. Radiat. Res. 155, 703-715 (2001). The induction of HPRT mutants with exon deletions after irradiation with photons was simulated using the biophysical radiation track structure model PARTRAC. The exon-intron structure of the human HPRT gene was incorporated into the chromatin fiber model in PARTRAC. After gamma and X irradiation, simulated double-stranded DNA fragments that overlapped with exons were assumed to result in exon deletion mutations with a probability that depended on the genomic or the geometric distance between the breakpoints. The consequences of different assumptions about this probability of deletion formation were evaluated on the basis of the resulting fractions of total, terminal and intragenic deletions. Agreement with corresponding measurements was obtained assuming a constant probability of deletion formation for fragments smaller than about 0.1 Mbp, and a probability of deletion formation decreasing with increasing geometric or genomic distance between the end points for larger fragments. For these two assumptions, yields of mutants with exon deletions, size distributions of deletions, patterns of deleted exons, and patterns of deleted STS marker sites surrounding the gene were calculated and compared with experimental data. The yields, size distributions and exon deletion patterns were grossly consistent, whereas larger deviations were found for the STS marker deletion patterns in this comparison.     

Duplication of the human immunoglobulin heavy chain gamma 2 gene.

The five C gamma genes in the human immunoglobulin heavy chain region show nonrandom association and segregation as haplotypes. From the study of genetic variation in C gamma genes of 58 healthy Caucasian volunteers, we have identified a haplotype that involves a duplication of C gamma 2. This haplotype contains both the 13.5-kilobase (kb) and 25-kb BamHI fragment alleles of C gamma 2. In addition, the patterns and relative intensity of BamHI fragments containing C gamma genes were those expected for genomic DNA containing three copies of C gamma 2 for every two copies of the four other C gamma genes. A new EcoRI polymorphism in C gamma 4 was useful in defining the haplotype containing the duplication. Alleles of the C gamma genes in the duplication haplotype, including Gm markers of C gamma 1 and C gamma 3 and DNA polymorphisms of C psi gamma, C gamma 2, and C gamma 4, were consistent with its origin from an unequal crossover between the two common C gamma haplotypes, H1 and H2. This recombinant haplotype, which has been designated H2;1(gamma 2 dup) to reflect its origin, occurred with a frequency of .043 in a random sample of 116 chromosomes.     

Protein 2A is not required for Theiler's virus replication.

Nonpolar mutations were introduced into all 12 regions of the genome of Theiler's murine encephalomyelitis virus. In agreement with data previously reported for other picornaviruses, mutations in regions 2B, 2C, 3A, 3B, 3C, and 3D totally abrogated viral RNA replication. Viruses with deletions in each of the capsid proteins retained RNA replication proficiency, although they were unable to propagate from cell to cell. As reported previously, mutations in the leader protein did not impair RNA replication or virus production in BHK-21 cells. Surprisingly, region 2A also appeared to be dispensable for the replication process. Indeed, up to 77 of the 133 amino acids of 2A could be deleted without significantly affecting RNA replication. 2A mutant viruses had only a slow cytopathic effect for BHK-21 cells and were totally avirulent for mice. As was the case for mutants lacking the leader protein, viruses with deletions in 2A propagated in BHK-21 cells, but their propagation was highly restricted in L929 cells.