Clinical impact of somatic mosaicism in cases with small supernumerary marker chromosomes.

Somatic mosaicism is present in slightly more than 50% of small supernumerary marker chromosome (sSMC) carriers. Interestingly, non-acrocentric derived sSMC show mosaicism much more frequently than acrocentric ones. sSMC can be present in different mosaic rates, which may go below 5% of the studied cells. Also cryptic mosaicism can be present and mosaics may be differently expressed in different tissues of the body. Even though in the overwhelming majority of the cases somatic sSMC mosaicism has no direct clinical effect, there are also cases with altered clinical outcomes due to mosaicism. Also clinically important is the fact that a de novo sSMC, even present in mosaic, may be a hint of uniparental disomy (UPD). As it is under discussion to possibly replace standard karyotyping by methods like array-CGH, the impracticality of the latter to detect low-level sSMC mosaics and/or UPD has to be considered as well. Overall, sSMC mosaicism has to be studied carefully in each individual case, as it can be extremely informative and of importance, especially for prenatal genetic counseling.

Is there a yet unreported unbalanced chromosomal abnormality without phenotypic consequences in proximal 4p?

Unbalanced chromosomal abnormalities (UBCA) are reported for >50 euchromatic regions of almost all human autosomes. UBCA are comprised of a few megabases of DNA, and carriers are in many cases clinically healthy. Here we report on a partial trisomy of chromosome 4 of the centromere-near region of the short arm of chromosome 4 present as a small supernumerary marker chromosome (sSMC). The sSMC was present in >70% of amnion cells and in 60% of placenta. Further delineation of the size of the duplicated region was done by molecular cytogenetics and array comparative genomic hybridization. Even though the sSMC lead to a partial trisomy of ~9 megabase pairs, a healthy child was born, developing normally at 1 year of age. No comparable cases are available in the literature. Thus, we discuss here the possibility of having found a yet unrecognized chromosomal region subject to UBCA.

Evidence for correlation of fragile sites and chromosomal breakpoints in carriers of constitutional balanced chromosomal rearrangements.

A molecular cytogenetic study of 251 cases with balanced chromosomal rearrangements detected due to infertility of unclear origin or in prenatal diagnostics with a later normal outcome was done. Balanced translocations (127 cases), inversions (105 cases), insertions (three cases), balanced complex rearrangements (four cases), or derivative chromosomes leading to no imbalance (12 cases), were studied by multicolor banding (MCB) and/or subcentromeric multicolor fluorescence in situ hybridization (subcenM-FISH). Five-hundred and twenty-nine break-events were characterized by molecular cytogenetics. Only 150 of these were unique breakpoints, the remainder were observed between two and 10 times. According to the results obtained, there was cytogenetic co-localization of fragile site (FS) in ~71% of the studied 529 break-events. Nine selected cases with evidence for breakpoints within FS were further analyzed by FS-specific bacterial artificial chromosome (BAC) probes; only one did not show a co-localization. Further detailed molecular analysis will be necessary to characterize the mechanisms and genetic basis for this phenomenon.

10p11.2 to 10q11.2 is a yet unreported region leading to unbalanced chromosomal abnormalities without phenotypic consequences.

Directly transmitted unbalanced chromosomal abnormalities (UBCA) or euchromatic variants (EV) were recently reported for >50 euchromatic regions of almost all human autosomes. UBCA and EV are comprised of a few megabases of DNA, and carriers are in many cases clinically healthy. Here we report on partial trisomies of chromosome 10 within the pericentromeric region which were detected by standard G banding. Those were referred for further delineation of the size of these duplicated regions for molecular cytogenetics and/or array-CGH. Partial trisomies of chromosome 10 in the pericentromeric region were identified prenatally in seven cases. A maximum of three copies of the region from 10p12.1 to 10q11.22 was observed in all cases without apparent clinical abnormalities. The imbalances were either caused by a direct duplication in one familial case or by de novo small supernumerary marker chromosomes (sSMC). Thus, we report a yet unrecognized chromosomal region subject to UBCA detected in seven unrelated cases. To the best of our knowledge, this is the first report of a UBCA in the pericentromeric region of chromosome 10 that is not correlated with any clinical consequences.

Centromere-specific multicolour fluorescence in situ hybridization on human spermatocyte I and II metaphases.

BACKGROUND: Most meiotic studies in metaphase spermatocytes have been carried out with classic cytogenetic techniques. The aim of this work was to adjust the centromere-specific multicolour fluorescence in situ hybridization (cenM-FISH) procedure to spermatocyte metaphases I and II in order to improve the identification of meiotic chromosome abnormalities. METHODS: A total of 168 spermatocytes I and 66 spermatocytes II from two fertile males have been studied using cenM-FISH. RESULTS: The mean frequency of meiotic abnormalities (synaptic, numerical and structural errors) found in metaphases I and II was 22.1 and 3.0%, respectively. The cenM-FISH technique has not only enabled the individual identification of chromosomes involved in meiotic disorders, but also increased the number of analysable cells, principally at metaphase II stage. CONCLUSIONS: CenM-FISH is a useful tool to study the meiotic chromosomal disorders and mechanisms leading to chromosomally abnormal spermatozoa.

A new unbalanced chromosomal abnormality in 1q31.1 to 1q32 without phenotypic consequences.

A familial duplication in the long arm of one chromosome 1 was detected due to recurrent abortions in a couple. The duplication was present in the male partner of the couple and in his mother, both clinically healthy. By reverse FISH, the duplication was determined to be located in 1q31. Multicolor banding (MCB) and application of locus-specific probes narrowed down the breakpoints to 1q31.1 and 1q32. The duplication spans a region of 13.9 Mb. None of the two breakpoints was colocalized with a known fragile site in 1q31.2, which, however, was duplicated. To the best of our knowledge, this is the first report of an unbalanced chromosome abnormality in this region that is not correlated with any clinical consequences.

Parental-origin-determination fluorescence in situ hybridization distinguishes homologous human chromosomes on a single-cell level.

The differentiation of homologous chromosomes as well as their parental origin can presently be conducted and determined exclusively by molecular genetic methods using microsatellite or SNP analysis. Only in exceptional cases is a distinction on a single-cell level possible, e.g. due to variations within the heterochromatic regions of chromosomes 1, 9, 16 and Y or the p-arms of the acrocentric chromosomes. In the absence of such polymorphisms, an individual distinction of the homologous chromosomes is not currently possible. Consequently, various questions of scientific and diagnostic relevance are unable to be answered. Based on the recently detected large-scale copy-number variations (LCV) or copy-number polymorphisms (CNP) spanning up to several megabase pairs of DNA, in this study, a molecular cytogenetic technique for the inter-individual differentiation of homologous chromosomes called parental-origin-determination fluorescence in situ hybridization (pod-FISH) is presented. All human chromosomes were covered with 225 LCV- and/or CNP-specific BAC probes, and one- to five-color chromosome-specific pod-FISH sets were created, evaluated and optimized. We demonstrated that pod-FISH is suitable for single-cell analysis of uniparental disomy (UDP) in clinical cases such as Prader-Willi syndrome caused by maternal UPD. A rare clinical case with a mosaic form of a genome-wide isodisomy was used to determine the detection limits of pod-FISH. Additionally we analyzed the informativeness of conventional microsatellite analysis for the first time and compared the results to pod-FISH. With this new possibility to study the parental origin of individual human chromosomes on a single-cell level, new doors for diagnostic and basic research are opened.

Neocentric small supernumerary marker chromosomes (sSMC)--three more cases and review of the literature.

Here we report on three new patients with neocentric small supernumerary marker chromosomes (sSMC) derived from chromosome 2, 13 and 15, respectively. The sSMC(13) and sSMC(15) had inverted duplicated shapes and the sSMC(2) a ring chromosome shape. All three cases were clinically severely abnormal. A review of the available sSMC literature revealed that up to the present 73 neocentric sSMC cases including these three new cases have been reported. Seven of these cases were not characterized morphologically; in the remainder, 80% had an inverted duplication, 17% a ring and 3% a minute shape. 81% of the reported neocentric sSMC carriers showed severe, 12% moderate and 8% no clinical abnormalities. In summary, we report three more neocentric sSMC cases, provide a review on all up to now published cases, highlight their special characteristics and compare them to centric sSMC.

Forty-eight new cases with infertility due to balanced chromosomal rearrangements: detailed molecular cytogenetic analysis of the 90 involved breakpoints.

A molecular cytogenetic study was performed on 48 infertile patients who were identified as carriers of balanced translocations (40 cases), inversions (6 cases) or insertions (2 cases) by means of banding cytogenetics. Cases with a Robertsonian translocation or pericentric inversion 2 or 9 were not included. In summary, 100 break-events occurred in these patients, and 90 different chromosomal regions were involved. Thus, this study confirmed the presence of abnormal karyotypes in a subgroup of patients seeking infertility treatment. Breaks were demonstrated to appear preferentially in GTG-light bands in these patients. Furthermore, the observed breakpoints were associated with genomic regions prone to instability due to the presence of segmental duplications. Nonetheless, further detailed molecular analysis will be necessary in the future to characterize the mechanisms and genetic basis for this phenomenon.

Multicolor FISH used for the characterization of small supernumerary marker chromosomes (sSMC) in commercially available immortalized cell lines.

There are only about 30 commercially available cell lines which include small supernumerary marker chromosomes (sSMC). As approximately 2.5 million people worldwide are carriers of an sSMC, this small number of immortalized cell lines is hard to understand. sSMC cell lines provide practically unlimited material for continuing studies e.g. to learn more about marker chromosome formation, or karyotypic evolution. To obtain information about their genetic content, in the present study we analyzed by FISH and multicolor-FISH approaches 19 sSMC cell lines obtained from the European Collection of Cell Cultures (ECACC). Microdissection and reverse painting, (sub-) centromere-specific multicolor-FISH (sub-)cenM-FISH, multicolor banding (MCB) and selected locus-specific FISH probes were applied. Thus, we were able to characterize comprehensively 14 out of 19 sSMC carrying cell lines; in the remaining five cases an sSMC could not be detected. Surprisingly, in six of the nine cell lines with sSMC previously characterized for their chromosomal origin by others, those results had to be revised. This has impact on the conclusions of previous studies, e.g. for uniparental disomy (UPD) in connection with sSMC.

Supernumerary marker chromosome 5 diagnosed by M-FISH in a child with congenital heart defect and unusual face.

We describe a female patient with a small supernumerary marker chromosome (sSMC) present in mosaic and characterized in detail by fluorescence in situ hybridization (FISH) using all 24 human whole chromosome painting probes, multicolor banding (MCB) and subcentromere specific multicolor FISH (subcenM-FISH). The sSMC was demonstrated to be derived from chromosome 5 and the karyotype of our patient was as follows: 47,XX,+mar.ish r(5)(::p13.2 approximately p13.3-->q11.2::) [60%]/46,XX [40%]. Partial trisomy for the proximal 5p and q chromosomal regions is a rare event. A critical region exists at 5p13 for the phenotype associated with duplication 5p. As far as we know, eight similar cases have been published up to now. We describe a new case which, to our knowledge, is the first characterized in such detail. The role of uniparental disomy (UPD) in cases of SMC is also discussed.

De novostructural chromosomal imbalances: molecular cytogenetic characterization of partial trisomies.

De novo structural chromosomal imbalances represent a major challenge in modern cytogenetic diagnostics. Based solely on conventional cytogenetic techniques it may be impossible to identify the chromosomal origin of additional chromosomal material. In these cases molecular cytogenetic investigations including multicolor-FISH (M-FISH), spectral karyotyping (SKY), multicolor banding (MCB) and cenM-FISH combined with appropriate single-locus FISH probes are highly suitable for the determination of the chromosomal origin and fine characterization of derivative chromosomes. Here we report on four patients with de novo chromosomal imbalances and distinct chromosomal phenotypes, three of them harboring pure partial trisomies: a mildly affected boy with pure partial trisomy 10q22.2-->q22.3 approximately 23.1 due to an interstitial duplication, a girl with pure trisomy 12p11.21-->pter and atypically moderate phenotype as the consequence of an X;autosome translocation, and a girl with multiple congenital abnormalities and severe developmental delay and a 46,XX,15p+ karyotype hiding a trisomy 17pter-->17q11.1. The fourth patient is a girl with minor phenotypic features and mental retardation with an inverted duplication 18q10-->p11.31 combined with a terminal deletion of 18p32. The clinical pictures are compared with previously described patients with focus on long term outcome.

Different breakage-prone regions on chromosome 1 detected in t(11;14)-positive mantle cell lymphoma cell lines and multiple myeloma cell lines are associated with different tumor progression-related mechanisms.

To better define secondary aberrations that occur in addition to translocation t(11;14)(q13;q32) in mantle cell lymphomas (MCL) and in multiple myelomas (MM), seven t(11;14)-positive MCL cell lines and four t(11;14)-positive MM cell lines were analysed by fluorescence R-banding and spectral karyotyping (SKY). Compared with published data obtained by G-banding, most chromosome aberrations were redefined or further specified. Furthermore, several additional chromosome aberrations were identified. Thus, these cytogenetically well defined t(11;14)-positive MCL and MM cell lines may be useful tools for the identification and characterization of genes that might be involved in the pathogenesis of MCL and MM, respectively. Since MCL and MM were found to have different alterations of chromosome 1, these were investigated in more detail by fluorescence in situ hybridization (FISH) and multicolor banding (MCB) analyses. The most frequently altered and deletion-prone loci in MCL cell lines were regions 1p31 and 1p21. In contrast, breakpoints in MM cell lines most often involved the heterochromatic regions 1p12-->p11, and the subcentromeric regions 1q12 and 1q21. These data are in accordance with previously published data of primary lymphomas. Our findings may indicate that different pathways of clonal evolution are involved in these morphologically distinct lymphomas harboring an identical primary chromosome aberration, t(11;14).

Small supernumerary marker chromosomes--progress towards a genotype-phenotype correlation.

Small supernumerary marker chromosomes (sSMC) are still a major problem in clinical cytogenetics as they are too small to be characterized for their chromosomal origin by traditional banding techniques, but require molecular cytogenetic techniques for their identification. Apart from the correlation of about one third of the sSMC cases with a specific clinical picture, i.e. the i(18p), der(22), i(12p) (Pallister Killian syndrome) and inv dup(22) (cat-eye) syndromes, most of the remaining sSMC have not yet been correlated with clinical syndromes. Recently, we reviewed the available >1600 sSMC cases (Liehr T, sSMC homepage: http://mti-n.mti.uni-jena.de/~huwww/MOL_ZYTO/sSMC.htm). A total of 387 cases (including the 45 new cases reported here) have been molecularly cytogenetically characterized with regard to their chromosomal origin, the presence of euchromatin, heterochromatin and satellite material. Based on analysis of these cases we present the first draft of a basic genotype-phenotype correlation for sSMC for all human chromosomes apart from the chromosomes Y, 10, 11 and 13.

Multicolor fluorescence in situ hybridization (FISH) applied to FISH-banding.

During the last decade not only multicolor fluorescence in situ hybridization (FISH) using whole chromosome paints as probes, but also numerous chromosome banding techniques based on FISH have been developed for the human and for the murine genome. This review focuses on such FISH-banding techniques, which were recently defined as 'any kind of FISH technique, which provide the possibility to characterize simultaneously several chromosomal subregions smaller than a chromosome arm. FISH-banding methods fitting that definition may have quite different characteristics, but share the ability to produce a DNA-specific chromosomal banding'. While the standard chromosome banding techniques like GTG lead to a protein-related black and white banding pattern, FISH-banding techniques are DNA-specific, more colorful and, thus, more informative. For some, even high-resolution FISH-banding techniques the development is complete and they can be used for whole genome hybridizations in one step. Other FISH-banding methods are only available for selected chromosomes and/or are still under development. FISH-banding methods have successfully been applied in research in evolution- and radiation-biology, as well as in studies on the nuclear architecture. Moreover, their suitability for diagnostic purposes has been proven in prenatal, postnatal and tumor cytogenetics, indicating that they are an important tool with the potential to partly replace the conventional banding techniques in the future.

Unusual small supernumerary marker chromosome (sSMC) 9 in a Klinefelter patient.

Small supernumerary marker chromosomes (sSMC) are small additional chromosomes characterizable for their origin only by molecular cytogenetic approaches. sSMC have been reported previously in four types of syndromes associated with chromosomal imbalances: in approximately 150 cases with Turner syndrome, 26 cases with Down syndrome and only one case each with Klinefelter syndrome and "Triple-X"-syndrome. Here we report the second case with an sSMC detected in addition to a Klinefelter karyotype. Molecular cytogenetics applying centromere-specific multicolor FISH (cenM-FISH) and a specific subcentromere-specific (subcenM-FISH) probe set characterized the sSMC as a dic(9)(:p12-->q11.1::q11.1--> p11.1:). The reported patient was described with hypogonadism, gynaecomastia plus a bronchial carcinoma. The patient's clinical features are discussed in connection with other Klinefelter cases and possible consequences of presence of the sSMC(9). Furthermore, a suggestion is made for the mode of sSMC-formation in this case.

New insights into the evolution of chromosome 1.

A complex low-repetitive human DNA probe (BAC RP11-35B4) together with two microdissection-derived region-specific probes of the multicolor banding (MCB) probe-set for chromosome 1 were used to re-analyze the evolution of human chromosome 1 in comparison to four ape species. BAC RP11-35B4 derives from 1q21 and contains 143 kb of non-repetitive DNA; however, it produces three specific FISH signals in 1q21, 1p12 and 1p36.1 of Homo sapiens (HSA). Human chromosome 1 was studied in comparison to its homologues in Hylobates lar (HLA), Pongo pygmaeus (PPY), Gorilla gorilla (GGO) and Pan troglodytes (PTR). A duplication of sequences homologous to human 1p36.1 could be detected in PPY plus an additional signal on PPY 16q. The region homologous to HSA 1p36.1 is also duplicated in HLA, and split onto chromosomes 7q and 9p; the region homologous to HSA 1q21/1p12 is present as one region on 5q. Additionally, the breakpoint of a small pericentric inversion in the evolution of human chromosome 1 compared to other great ape species could be refined. In summary, the results obtained here are in concordance with previous reports; however, there is evidence for a deletion of regions homologous to human 1p34.2-->p34.1 during evolution in the Pongidae branch after separation of PPY.

The hierarchically organized splitting of chromosome bands into sub-bands analyzed by multicolor banding (MCB).

To clarify the nature of chromosome sub-bands in more detail, the multicolor banding (MCB) probe-set for chromosome 5 was hybridized to normal metaphase spreads of GTG band levels at approximately 850, approximately 550, approximately 400 and approximately 300. It could be observed that as the chromosomes became shorter, more of the initial 39 MCB pseudo-colors disappeared, ending with 18 MCB pseudo-colored bands at the approximately 300-band level. The hierarchically organized splitting of bands into sub-bands was analyzed by comparing the disappearance or appearance of pseudo-color bands of the four different band levels. The regions to split first are telomere-near, centromere-near and in 5q23-->q31, followed by 5p15, 5p14, and all GTG dark bands in 5q apart from 5q12 and 5q32 and finalized by sub-band building in 5p15.2, 5q21.2-->q21.3, 5q23.1 and 5q34. The direction of band splitting towards the centromere or the telomere could be assigned to each band separately. Pseudo-colors assigned to GTG-light bands were resistant to band splitting. These observations are in concordance with the recently proposed concept of chromosome region-specific protein swelling.