Visualizing chromosome dynamics with GFP

By allowing easy labeling of chromosomal and nuclear proteins and the tagging of specific chromosomal regions, the use of green-fluorescent protein (GFP) has provided new and special opportunities for directly observing chromosome dynamics in vivo. Here, we review recent applications of this methodology, focusing particularly on examples where new biology has been learned, or at least sighted. In particular, we focus on active bacterial chromosome segregation, yeast mitosis and centromere dynamics, and large-scale chromatin structure and dynamics within eukaryotic interphase nuclei.     

Integrating chromosome structure with function

Historically, the metaphase chromosome and its architecture has been viewed as the ultimate representation of a non-functional inactive chromatin state. Recent studies of centromere (kinetochore) function in concert with studies of the placement and function of several classes of chromosomal proteins now call for a reevaluation of this view. In this article a model of chromosome structure with functional correlates is presented. Evidence for the existence of a functional chromosomal region, the "Surface Domain" is discussed.     

Prefixation chromosome banding with heparin

Summary Attempts to achieve chromosomal banding by removal of histone proteins by acid or fixation procedures have failed up to now. Numerous biochemical investigations have shown that heparin has a strong and specific affinity to histone proteins. We describe a procedure by which treatment with heparin of nonfixed and fixed metaphase chromosomes leads to G banding; in the former case the effect is observed after a few minutes of heparin treatment; in the latter, much higher concentrations of heparin and 18–24h incubation are needed. The morphologic effects of heparin treatment, the gradual disruption of chromosomal and nuclear chromatin, are associated with progressive reduction of histone detection (until completely negative) by the alkaline fast green test.     

Increased missegregation and chromosome loss with decreasing chromosome size in vertebrate cells

Chromosome engineering has allowed the generation of an extensive and well-defined series of linear human X centromere-based minichromosomes, which has been used to investigate the influence of size and structure on chromosome segregation in vertebrate cells. A clear relationship between overall chromosome size and mitotic stability was detected, with decreasing size associated with increasing loss rates. In chicken DT40, the lower size limit for prolonged mitotic stability is approximately 550 kb: at 450 kb, there was a dramatic increase in chromosome loss, while structures of approximately 200 kb could not be recovered. In human HT1080 cells, the size threshold for mitotic stability is approximately 1.6 Mb. Minichromosomes of 0.55–1.0 Mb can be recovered, but display high loss rates. However, all minichromosomes examined exhibited more segregation errors than normal chromosomes in HT1080 cells. This error rate increases with decreased size and correlates with reduced levels of CENP-A and Aurora B. In mouse LA-9 and Indian muntjac FM7 cells, the size requirements for mitotic stability are much greater. In mouse, a human 2.7-Mb minichromosome is rarely able to propagate a kinetochore and behaves acentrically. In Indian muntjac, CENP-C associates with the human minichromosome, but the mitotic apparatus appears unable to handle its segregation.     

Balanced chromosome abnormalities with abnormal phenotype

In this report we summarized our experience (1970-1986) on autosomal reciprocal translocations with particular interest towards the possible excess of mental retardation and congenital malformations in carriers of apparently balanced chromosomal rearrangements. The present data confirm the previous findings that the association of MR/MCA and apparently balanced autosomal chromosomal rearrangements is much higher than expected by chance.     

Sequences associated with A chromosome centromeres are present throughout the maize B chromosome

Maize chromosome spreads containing the supernumerary B chromosome were hybridized with probes from various repetitive elements including CentC, CRM, and CentA, which have been localized to centromeric regions on the A chromosomes. Repetitive elements that are enriched or found exclusively near the centromeres of A chromosomes hybridized to many sites distinct from the centromere on the B chromosome. To examine whether these elements recruit kinetochore proteins at locations other than the canonical B centromere, cells were labeled with antibodies against CENH3, a key kinetochore protein. No labeling was detected outside the normal centromere and no evidence of B chromosome holocentromeric activity was observed. This finding suggests that, as in other higher eukaryotes, DNA sequence alone is insufficient to dictate kinetochore location in plants. Additionally, examination of the B centromere region in pachytene chromosomes revealed that the B-specific element ZmBs hybridizes to a much larger region than the site of hybridization of CentC, CRM, and CentA and the labeling by anti-CENH3 antibodies.This revised version was published online in December 2004 with corrections to Table 1.     

A hela subline with an established chromosome pattern and with a stemline chromosome number of 59

The results are presented of three-year karyological studies in a HeLa cell line. During this period, only hypotriploid chromosome numbers with a stemline number of 59 were observed.     

DNA fragments associated with chromosome scaffolds

Following extensive digestion of HeLa metaphase chromosomes with either Hae III endonuclease or micrococcal nuclease, nonhistone protein scaffolds may be isolated. Scaffolds isolated after Hae III digestion have about 1.5% of the chromosomal DNA attached to them. This DNA is heterogeneous in size, ranging from about 0.2 to 20 kbp. It can be cleaved with either Eco RI or Hae III - Eco RI, producing a series of repeated fragments, of which the most abundant is 1.7 kbp in length. The 1.7-kdp fragment is tandemly repeated and is enriched (about 50-fold) in the scaffold-associated DNA. It is located primarily on human chromosome 1 and is probably a component of human satellites II and III. Scaffolds isolated after micrococcal nuclease digestion have about 0.1% of chromosomal DNA attached. This DNA is present in two size classes - fragments larger than 10 kbp and fragments approximately 0.2 kbp long. Restriction enzyme digestion of this DNA gives no prominent repeated fragments. Its reassociation kinetics are similar to those of total DNA, indicating that it is not enriched in either highly repetitive or middle repetitive sequences.     

Physical mapping confirms that sheep chromosome 10 has extensive conserved synteny with cattle chromosome 12 and human chromosome 13

The following loci, on human chromosome 13, have been newly assigned to sheep chromosome 10 using chromosomally characterized sheep-hamster cell hybrids: gap junction protein, beta 2, 26 kDa (connexin 26) (GJB2); gap junction protein, alpha 3, 46 kDa (connexin 46) (GJA3), and esterase D/formylglutathione hydrolase (ESD). This assignment of ESD is consistent with comparative mapping evidence, but not with an earlier report of it on sheep chromosome 3p26-p24. Cell hybrid analysis confirmed the location of another human chromosome 13 locus, retinoblastoma 1 (including osteosar-coma) (RBI), and the anonymous ovine genomic sequence RP11 on sheep chromosome 10. Isotopic in situ hybridization was used to regionally localize RP11 on to sheep 10q15-q22. The location of microsatellites AGLA226, OarDB3, OarHH41, OarVH58, and TGLA441, previously assigned to sheep chromosome 10 by linkage analysis, was confirmed by polymerase chain reaction using the cell hybrid panel. These mapping data provide further evidence that sheep chromosome 10 is the equivalent of cattle chromosome 12, and that these chromosomes show extensive conserved synteny with human chromosome 13.     

Balanced chromosome rearrangements with abnormal phenotype

27 cases in which apparent balanced chromosomal rearrangements (reciprocal and translocations and pericentric inversions) are associated with phenotypic abnormalities are reported and compared with the previous published cases. Almost all patients display mental retardation and a non specific dysmorphism. Genetic counseling is different whether the abnormality is inherited or de novo. When an unexpected structural rearrangements is found in fetal cells, the attitude depends on the results of the parent's chromosomal study.     

A satellited Yq chromosome associated with trisomy 21 and an inversion of chromosome 9

Summary A case of satellited Yq, inverted 9 and trisomy 21 is described. The clinical features are typical of those found in Down's syndrome.     

A comparative linkage and physical map of bovine chromosome 24 with human chromosome 18

Polymorphic microsatellites have been developed in the vicinity of nine genes on bovine chromosome (BTA) 24, all orthologous to genes on human chromosome (HSA) 18. The microsatellites have been isolated from bacterial and yeast artificial chromosome clones containing the genes. A linkage map was developed including these polymorphic markers and four anonymous, published microsatellites. Yeast artificial chromosomes containing six of these genes have also been mapped using fluorescent in situ hybridization (FISH), thereby tying the linkage map together with the physical map of BTA24. Comparing gene location on HSA18 and BTA24 identifies four regions of conserved gene order, each containing at least two genes. These genes identify six regions of conserved order between human and mouse, two more than in the human-bovine comparison. The breakpoints between regions of conserved order for human-bovine are also breakpoints in the human-mouse comparison. The centromere identifies a fifth conserved region if the BTA24 centromere is orthologous with the HSA18 centromere. Received: 17 September 1998 / Accepted: 4 December 1998     

A family with a satellited Yq chromosome

Summary A large pedigree with a satellited Yq chromosome is described, Q, C, and NOR banding were performed. Family C proband suffers from a Klinefelter syndrome.