U. Koehler

Chromosome painting defines genomic rearrangements between red howler monkey subspecies

We hybridized whole human chromosome-specific DNA libraries to chromosomes of two supposed subspecies ofAlouatta seniculus: Alouatta seniculus sara andAlouatta seniculus arctoidea. The number of hybridization signals per haploid set is 42 inA. s. sara and 43 inA. s. arctoidea; the two karyotypes differ by at least 16 chromosomal rearrangements, including numerous translocations. An unusual sex chromosome system is shared by both taxa. The sex chromosome system results from a Y translocation with a chromosome homologous to parts of human chromosome 3/15 and can be described as X1X2Y1Y2/X1X1X2X2 (male/female). Both red howlers also have microchromosomes, a highly unusual karyological trait not found in other higher primates. These microchromosomes are not hybridized by any human chromosome paint and therefore are probably composed of repetitive DNA. It is well known that New World monkeys have high karyological variability. It is probable that molecular cytogenetic analyses including chromosome painting will permit an accurate reconstruction of the phylogeny of these monkeys and help establish the ancestral karyotype for higher primates.

Mapping homology between human and black and white colobine monkey chromosomes by fluorescent in situ hybridization

We used in situ hybridization of chromosome specific DNA probes (“chromosome painting”) of all human chromosomes to establish homologies between the human and the white and black colobus (Colobus guereza 2n = 44). The 24 human paints gave 31 signals on the autosomes (haploid male chromosome set). Robertsonian translocations between chromosomes homologus to human 14 and 15, 21 and 22, form colobine chromosomes 6 and 16, respectively. Reciprocal translocations were found between human chromosomes 1 and 10, 1 and 17, as well as 3 and 19. The alternating hybridization signals between human 3 and 19 on Colobus chromosome 12 show that in this case a reciprocal translocation was followed by a pericentric inversion. The hybridization data show that in spite of the same diploid number and similar Fundamental Numbers, the black and white colobine monkey differs from Presbytis cristata, an Asian colobine, by 6 reciprocal translocations. Comparisons with the hybridization patterns in other primates show that some Asian colobines have a more derived karyotype with respect to African colobines, macaques, great apes, and humans. Chromosome painting also clearly shows that similarities in diploid number and chromosome morphology both between colobines and gibbons are due to convergence. Am. J. Primatol. 42:289–298, 1997.

In situ hybridization (FISH) maps chromosomal homologies between Alouatta belzebul (Platyrrhini, Cebidae) and other primates and reveals extensive interchromosomal rearrangements between howler monkey genomes

We hybridized whole human chromosome specific probes to metaphases of the black‐and‐red howler monkey Alouatta belzebul in order to establish chromosomal homology between humans and black‐and‐red howlers. The results show that the black‐and‐red howler monkey has a highly rearranged genome and that the human chromosome homologs are often fragmented and translocated. The number of hybridization signals we obtained per haploid set was 40. Nine human chromosome probes gave multiple signals on different howler chromosomes, showing that their synteny is disturbed in A. Belzebul. Fourteen black‐and‐red howler autosomes were completely hybridized by one human autosomal paint, six had two signals, three had three signals, and one chromosome had four signals. Howler chromosomes with multiple signals have produced 12 chromosomal syntenies or hybridization associations which differ from those found in humans: 1/2, 2/20, 3/21, 4/15, 4/16, 5/7, 5/11, 8/18, 9/12, 10/16, 14/15, and 15/22. The hybridization pattern was then compared with those found in two red howler taxa and other mammals. The comparison shows that even within the genus Alouatta numerous interchromosomal rearrangements differentiate each taxa: A. belzebul has six unique apomorphic associations, A. seniculus sara and A. seniculus arctoidea share seven derived associations, and additionally A. seniculus sara has four apomorphic associations and A. seniculus arctoideaseven apomorphic associations. A. belzebul appears to have a more conserved karyotype than the red howlers. Both red and black‐and‐red howlers are characterized by Y‐autosome translocations; the peculiar chromosomal sex system found in the red howler taxa could be considered a further transformation of the A. belzebul sex system. The finding that apparently morphologically similar or even identical taxa have such extreme genomic differences has important implications for speciation theory and neotropical primate conservation. Am. J. Primatol. 46:119–133, 1998.

Analysis of the organisation and localisation of the FSHD-associated tandem array in primates: Implications for the origin and evolution of the 3.3 kb repeat family

The D4Z4 locus is a polymorphic tandem repeat sequence on human chromosome 4q35. This locus is implicated in the neuromuscular disorder facioscapulohumeral muscular dystrophy (FSHD). The majority of sporadic cases of FSHD are associated withde novo DNA deletions within D4Z4. However, it is still not known how this rearrangement causes FSHD. Although the repeat contains homeobox sequences, despite exhaustive searching, no transcript from this locus has been identified. Therefore, it has been proposed that the deletion may invoke a position effect on a nearby gene. In order to try to understand the role of the D4Z4 repeat in this disease, we decided to investigate its conservation in other species. In this study, the long-range organisation and localisation of loci homologous to D4Z4 were investigated in primates using Southern blot analysis, pulsed field gel electrophoresis and fluorescencein situ hybridisation. In humans, probes to D4Z4 identify, in addition to the 4q35 locus, a closely related tandem repeat at 10qter and many related repeat loci mapping to the acrocentric chromosomes; a similar pattern was seen in all the great apes. In Old World monkeys, however, only one locus was detected in addition to that on the homologue of human chromosome 4, suggesting that the D4Z4 locus may have originated directly from the progenitor locus. The finding that tandem arrays closely related to D4Z4 have been maintained at loci homologous to human chromosome 4q35-qter in apes and Old World monkeys suggests a functionally important role for these sequences.

A novel type of unstable homogeneously staining region with a head-to-tail arrangement: spontaneous decay and reintegration of DNA elements into a plethora of new chromosomal sites.

After transfection of amplification-promoting DNA elements into mammalian cells, homogeneously staining regions (HSRs) are formed by high copy numbers of transfected DNA arranged in head-to-tail polymers. Here, we wanted to evaluate the stability of this type of HSR during prolonged cultivation of transfected cells in selective medium. Thymidine kinase-deficient mouse L cells were transfected with pAPR4tk DNA harboring the amplification-promoting element 4 (APR4) linked to the gene for thymidine kinase (TK) or, alternatively, transfected with a DNA construct (pARP4t-PA) carrying, in addition, the expression cassette for human tissue-type plasminogen activator (t-PA). After transfection, one or two HSRs per cell were formed that disintegrated spontaneously after 25-40 wk of continuous cultivation in the presence of selective HAT (hypoxanthine-aminopterin-thymidine) medium. Unexpectedly, plasmid DNA reinserted into a plethora of new chromosomal sites, as revealed by in situ hybridization and Southern blot analysis. Coincidently, secretion of t-PA decreased to 10-20% of its original level. After transfection of pAPR4tk DNA lacking the t-PA expression cassette, HSR decay and reintegration of plasmid constructs into multiple chromosomal sites were also observed, whereas the ptk vector without an amplification-promoting DNA element did not form an HSR after transfection. We conclude that, in contrast to the pattern of known structures with head-to-tail arrangements, the HSR formed by amplification-promoting DNA elements represents a novel type of HSR that disintegrates by transposition into a plethora of new chromosomal integration sites. This process is mediated by the amplification-promoting DNA element itself and can be observed even when selective pressure is maintained.