Anne-Marie Laurent

Hypothesis: For the Worst and for the Best, L1Hs Retrotransposons Actively Participate in the Evolution of the Human Centromeric Alphoid Sequences

A number of questions concerning the evolution and the function of the alpha satellite DNA sequences present at the centromere of all human chromosomes are still open. In this paper, we present data which could contribute to understanding these points.It is shown here that the alphoid sequences within which L1 elements are found are quite divergent from those of the homogeneous alphoid subsets present at each centromere where none has so far been detected. In addition, a number of L1s are detected close to the ends of the alpha satellite blocks. A fairly high proportion exhibit a polymorphism of presence/absence. Strikingly, several L1s localized at a distance from each other are always either present or absent simultaneously. This is interpreted as resulting from intrachromosomal recombination, through distant L1s, leading to deletion of several of them at once together with their surrounding alphoid sequences.The parameters determining which portion of the several megabases of alphoid sequences is actually involved in the centromeric function are not known. From the above data we suggest that the alpha satellite domain within which DNA sequences are recruited to form a centromere is both homogeneous in sequence and uninterrupted by L1s or any other retrotransposons. Conversely, non-centromere competent alphoid sequences would be both divergent and punctuated by scattered L1 elements, particularly at the borders of the alphoid blocks. On the grounds of these data and hypotheses, a model is presented in which it is postulated that accumulation of L1 insertions within a centromere competent alphoid domain is ruining this competence, the consequence being damage to or even loss of the centromere- forming capability of the chromosome. Restoration of fully centromere-forming competence is supposed to occur by two alternative means, either de-novo amplification of a homogeneous and uninterrupted alphoid domain or by unequal crossing over with a homologue harbouring a large competent one. If L1 retrotransposons are acting detrimentally to centromere integrity (for the worst), one must also consider them as having positive consequences on chromosomes by preventing their centromeres from swelling indefinitely by the addition of alphoid sequences (for the best). The data and ideas presented here fit well with those already put forward by Csink and Henikoff (1998) using the example of Drosophila.

SINE AND LINE WITHIN HUMAN CENTROMERES

A number of the Alu and Ll elements present within the centromeric regions of the human chromosomes have been analyzed by polymerase chain reaction amplification. The oligonucleotide primers were homologous to the 3′ end consensus sequences of either Alu or Ll in conjunction with an oligonucleotide primer homologous to alphoid sequences specific to different chromosomes. This allowed one to detect an unusual number of Alu and Ll polymorphisms at different loci. It is proposed that this results from molecular rearrangements which occur within the α-satellite DNA in which they are embedded (Marçais et al. J. Mol. Evol. 33:42–48, 1991) and not because the centromeric regions are targets for new insertions of such elements. The same analyses were made on cosmids and YACs originating from the centromeric region of chromosome 21 as well as on a collection of somatic hybrids containing chromosome 21 centromere as unique common human genetic material. The results were consistent with the above hypothesis.

Detection by denaturing gradient gel electrophoresis of a new polymorphism in the apolipoprotein B gene

SummaryThe apolipoprotein B gene is subject to mutations that may be important in coronary heart diseases. We have used polymerase chain reaction and denaturin gradient gel electrophoresis to characterize a single nucleotide substitution in the apolipoprotein B gene. This mutation affects amino acid 4311 of the protein and converts asparagine to serine. It was found in 24% of the 81 unrelated individuals analyzed. Moreover, another mutation was detected by sequencing in a single individual.

Organization of the variant domains of α satellite DNA on human chromosome 21

The de novo creation of long, homogeneous, satellite DNA domains was postulated previously to occur by saltatory amplification. In this paper, pulsed field gel electrophoresis analysis of the α satellite DNA block organization of the human chromosome 21 supports this hypothesis.Double-dimension electrophoresis indicated that the variant copies of the basic α satellite repeat of chromosome 21 are organized in a single 3,150 Kblong domain. It was also established that the other satellite DNAs found in man (β, II, and III) are organized independently of the α satellite DNA block of the same chromosome.

Discrimination between α-satellite DNA sequences from chromosomes 21 and 13 by using polymerase chain reaction

alpha-Satellite subfamilies from chromosomes 21 and 13 are almost identical in sequence and cannot be distinguished from each other by hybridization techniques. A general method based on membrane-bound PCR is described here, allowing the discrimination of alpha-satellite DNA sequences from each of these two chromosomes, after detection by Southern blot hybridization. The PCR conditions were developed using somatic hybrid DNAs. The method was tested in membrane-bound PCR by using the alpha-satellite bands from a Southern blot of a CEPH family. The chromosomal origin of these bands, previously determined by linkage analysis, was confirmed by this method.

A 19-allele polymorphic marker within the centromere of human chromosome 5

We have detected and characterized a highly polymorphic marker that maps to the centromere of human chromosome 5. The localization was established by both linkage analysis within the CEPH reference families and fluorescence in situ hybridization. The marker consists of a sequence of five nucleotides, (CCTTT)n. Nineteen alleles have been detected in 46 unrelated individuals from 12 CEPH families, with a calculated heterozygosity of 0.91. This is the first truly centromeric, highly polymorphic genetic marker described so far.

Analysis of pericentromeric chromosome 21 specific YAC clones by FISH: Identification of new markers for molecular-cytogenetic application

Fluorescence in situ hybridization (FISH) of chromosome 21 specific yeast artificial chromosome (YAC) clones after Alu-PCR (polymerase chain reaction) amplification has been used to find new region-specific DNA probes for the heterochromatic region of chromosome 21. Six overlapping YAC clones from a pericentromeric contig map (region 21cen-21q11) were analyzed. Four YAC clones were characterized as hybridizing to several chromosomal locations. They are, therefore, either chimeric or shared by different chromosomes. Two of them containing alphoid satellite DNA, are localized at the centromeric regions of chromosomes 13 and 21 (clone 243A11), and on 13cen, 21cen and 1q3 (clone 781G5); the two others are localized at both 21q11 and 13q2 (clone 759D3), and at 18p (clone 770B3). Two YACs were strongly specific for chromosome 21q11 only (clones 124A7 and 881D2). These YACs were used effectively as probes for identifications of chromosome 21 during metaphase and interphase analysis of 12 individuals, including three families with Down syndrome offspring, and 6 amniocyte samples. The location of YAC clones on 21q11 close to the centromeric region allows the application of these clones as molecular probes for the analysis of marker chromosomes with partial deletions of the long arm as well as for pre- and postnatal diagnosis of trisomy 21 when alphoid or more distal region-specific DNA probes are uninformative. Overlapping YAC clones covering human chromosome 21q may be systematically used to detect a set of band-specific DNA probes for molecular-cytogenetic application.