Detection of nucleolus organizer regions in chromosomes of human,chimpanzee, gorilla,orangutan and gibbon

Nucleolus organizer regions were detected by the Ag-AS silver method in fixed metaphase chromosomes from human and primates. In the human, silver was deposited in the secondary constriction of a maximum of five pairs of acrocentric chromosomes: 13, 14, 15, 21 and 22. The chimpanzee also had five pairs of acrocentric chromosomes stained, corresponding to human numbers 13, 14, 18, 21 and 22. A gibbon had a single pair of chromosomes with a secondary constriction, which corresponded to the nucleolus organizer region. In each case the Ag-AS method detected the sites which have been shown by in situ hybridization to contain the ribosomal RNA genes. An orangutan had eight pairs of acrocentric chromosomes stained with Ag-AS, probably corresponding to human numbers 13, 14, 15, 18, 21 and 22, plus two others. Two gorillas had silver stain over two pairs of small acrocentric chromosomes and at the telomere of one chromosome 1. The larger gorilla acrocentric chromosomes had no silver stain although they all had secondary constrictions and entered into satellite associations.     

Location of rRNA genes in three inbred strains of rat and suppression of rat rRNA activity in rat-human somatic cell hybrids

Nucleolus organizer regions (NORs) of rat chromosomes were stained by the Ag-AS method. The Ag-NORs were found on chromosomes 3, 11 and 12 in the ACI, Wistar Brown and Wistar Lewis inbred strains of rat. The size of the Ag-NOR on each pair of chromosomes varied from strain to strain. Rat-human somatic hybrid cells that retained human and lost some of the rat chromosomes had no Ag-NOR on rat chromosomes 3, 11 or 12. Since NORs can be Ag-stained only if their 18 + 28S rRNA genes are active, the activity of the rat rRNA genes must have been suppressed in the hybrid cells.     

Human tumor and rodent-human hybrid cells with an increased number of active human NORs.

A human fibrosarcoma line, HT1080-6TG, with a near diploid number of chromosomes, has an average of 7.3 chromosomes with an Ag-stained nucleolus organizer region (NOR). Cells of this line with an increased number of chromosomes have an increased number of Ag-stained NORs. This cell line has been used as the human parent in constructing mouse-human and rat-human hybrids that segregate rodent chromosomes. The hybrid ccell lines, which have 100 or more chromosomes per cell, show a proportionate increase in the number of Ag-stained NORs (means, 11.4--16.8). The frequency of association of acrocentric chromosomes increases in a similar fashion. There is no evidence of inactivation of human NORs in these cells.     

Genetic control of tumorigenicity in interspecific mammalian cell hybrids.

The nature of genetic control of cellular malignancy was investigated by examining the tumorigenicity of a series of interspecific mouse-human cell hybrids in the athymic nude mouse. Two highly malignant but genetically distinct mouse cell lines, A9 and PG19, were hybridized with three normal human diploid fibroblast strains, and 19 independently arising hybrid clones were isolated. Each of these clones was capable of forming progressive lethal tumors in the nude mouse, and thus resembled the malignant parental mouse cells rather than the nonmalignant parental human cells. We failed to obtain any evidence for complete suppression of tumorigenicity in these cell hybrids. The absence of suppression was observed regardless of the extent and composition of the human chromosome complements retained in the hybrid clones; the results of detailed cytological and isoenzyme analyses would make it highly improbable that the observed lack of suppression was due to cellular selection in vivo for a more tumorigenic subpopulation in the injected hybrid cells. These data demonstrate that at least for the parental cell combinations used in this study, no human chromosome, when present singly in the mouse-human cell hybrids, can suppress the tumorigenic phenotype of the mouse cells. Our results are consistent with the view that the suppression of cellular malignancy previously demonstrated in intraspecific (mouse × mouse) somatic cell hybrids does not occur in interspecific (mouse-human) cell hybrids, or alternatively, genetic determinants located on two or more human chromosomes are required simultaneously to suppress the malignancy of the mouse cells in cell hybrids derived from malignant mouse cell and nonmalignant human cells.     

Assignment of gene(s) coding for antigen defined by monoclonal antibody 2B2

A mouse monoclonal antibody (2B2) recognizes an antigen which is present on most human peripheral blood leukocytes but is absent from most proliferating cells. The antibody precipitated two surface-labeled membrane glycopolypeptides with molecular weights of 86,000 and 145,000, and it was strongly mitogenic to normal human lymphocytes. Somatic cell hybrids have been used for assigning the genes coding for these membrane glycoproteins to human chromosome 21. The assignment was based on correlation of antigen expression on mouse-human T-lymphocyte hybrids with the presence of human chromosomes in the same hybrid clones.     

Frequency of satellite association of human chromosomes is correlated with amount of Ag-staining of the nucleolus organizer region.

Methaphase chromosomes from karyotypically normal adult humans (three males, six females) and one male with a 13p - chromosome were stained by quinacrine and then by the Ag-AS silver staining method to reveal nucleolus organizer regions (NORs). Each person had a characteristic number of Ag-stained chromosomes per cell, always fewer than 10. Determination of the mean Ag-size of each chromosome showed that each of the 10 individuals had a unique distribution of Ag-stain. Within each individual, there was some variation from cell to cell in the number of acrocentric chromosomes that were Ag-stained; this was not random, and the same chromosomes (those that had at most a small amount of Ag-stain) tended to be unstained in every cell. Satellite associations were scored on the same cells. Chromosomes that had no Ag-stain were involved in satellite association less than 20% as often as those that had some Ag-stain. Chromosomes that had a small amount of Ag-stain were involved in association about 50% as often as those that had a large amount of stain. Regression analysis of the 50 (of a total of 100) acrocentric chromosomes which could be individually identified by quinacrine markers showed that the frequency with which a chromosome was involved in satellite association was strongly correlated with the amount of Ag-stained material in the NOR.     

Two human genes encoding zinc finger proteins,ZNF12 (KOX 3) and ZNF 26 (KOX 20), map to chromosomes 7p22-p21 and 12q24.33, respectively

Summary Two members of the human zinc finger Krüppel family, ZNF 12 (KOX 3) and ZNF 26 (KOX 20), have been localized by somatic cell hybrid analysis and in situ chromosomal hybridization. The presence of individual human zinc finger genes in mouse-human hybrid DNAs was correlated with the presence of specific human chromosomes or regions of chromosomes in the corresponding cell hybrids. Analysis of such mouse-human hybrid DNAs allowed the assignment of the ZNF 12 (KOX 3) gene to chromosome region 7p. The ZNF 26 (KOX 20) gene segregated with chromosome region 12q13-qter. The zinc finger genes ZNF 12 (KOX 3) and ZNF 26 (KOX 20) were localized by in situ chromosomal hybridization to human chromosome regions 7p22-21 and 12q24.33, respectively. These genes and the previously mapped ZNF 24 (KOX 17) and ZNF 29 (KOX 26) genes, are found near fragile sites.     

Synthesis of ribosomal RNA in synkaryons and heterokaryons formed between human and rodent cells.

A study has been made of the ribosomal RNA and chromosome constitution of man-mouse hybrid cells. Previous work has shown that no human 28s rRNA is detectable in man-mouse synkaryons. In general human chromosomes are lost from such hybrids. With a recently developed method for distinguishing mouse from human chromosomes, an analysis of various man-mouse hybrid cell lines has been made. This indicates that not all the human chromosomes bearing nucleolar organizers are lost in the hybrid cells and such loss cannot alone explain the absence of human 28s rRNA. An examination of the 28s rRNA synthesized by heterokaryons formed from several different parent cells has revealed that both parental types of 28s rRNA are present in heterokaryons. The control of rRNA synthesis in hybrid cells is discussed.     

Somatic cell genetic analysis of the interferon system.

Current advances in the use of somatic cell hybrid systems have enhanced the value of these systems for studying eukaryotic cell functions. We have reviewed the use of somatic cells to investigate the human interferon system. It has been shown that interspecific heterokaryons and hybrid cells can produce interferon(s) of both parental types and may be protected from viral challenge by interferon(s) from either parent. Using mouse-human hybrid cells we have assigned a human gene(s) responsible for regulating interferon to chromosome 21 and genes involved in the production of human interferon to chromosomes 2 and 5. Our data also suggest possible assignment of a locus involved in control of interferon production to chromosome 16. Suggested further uses of the somatic cell system for interferon studies include study of the subunit structure of interferons and the development of hybrid lines that produce human interferon at high levels (interferon/somatic cell hybrids/human gene assignment.     

Identification of nucleolus organizer regions (NORs) in normal and neoplastic human cells by the silver-staining technique.

Silver nitrate has been used to demonstrate the chromosomal location of ribosomal cistrons in nine tissue-culture lines derived from human tumors of various pathological origins. Control individuals have a particular modal number (range 7--10) of D- and G-group chromosomes stained with silver. In the controls, 96.2% of the D- and G-group chromosomes that have a stalk show silver staining, while no relationship can be seen in acrocentric chromosomes without stalks. The tumor cells, whose modal chromosome numbers range from 42 to 68, possess variable numbers of acrocentrics (11--18). The number of chromosomes stained with silver, however, remained at control levels (range, 6--9). These data indicate that, in humans, silver staining may not identify all NORs that contain structural ribosomal genes.     

Localization of ribosomal RNA genes on human acrocentric chromosomes

Summary Clonal derivatives of a human heteroploid cell line, with different numbers of acrocentric chromosomes, show different rDNA contents. A linear relationship has been found between the rDNA content and the relative mass of the acrocentric chromosomes (D+G) expressed as the ratio between the mass of their DNA and the mass of the DNA of the whole chromosomal complement. The results suggest that human rRNA genes are located exclusively on the chromosomes of the groups D and G and that all these chromosomes contain rRNA genes.     

Detection of interspecific translocations in mouse-human hybrids by alkaline Giemsa staining.

Alkaline Giemsa staining of chromosome preparations from mouse-human somatic cell hybrids has indicated the presence of interspecific translocations previously undetected by conventional banding procedures. The species specificity of the alkaline Giemsa stain has been substantiated by differential color staining of all mouse and human chromosomes and a mouse-human translocation in well characterized hybrid clones.     

Cytoplasmic activation of human nuclear genes in stable heterocaryons

We have induced the stable expression of muscle-specific genes in human nonmuscle cells. Normal diploid human amniocytes were fused with differentiated mouse muscle cells by using polyethylene glycol. The fusion product, a stable heterocaryon in which the parental cell nuclei remained distinct, did not undergo division and retained a full complement of chromosomes. This is in contrast with typical interspecific hybrids (syncaryons), in which the parental nuclei are combined and chromosomes are progressively lost during cell division. The human muscle proteins, myosin light chains 1 and 2, MB and MM creatine kinase and a functional mouse-human hybrid MM enzyme molecule were detected in the heterocaryons. Synthesis of these proteins was evident 24 hr after fusion and increased in a time-dependent manner thereafter. Our results indicate that differentiated mouse muscle nuclei can activate human muscle genes in the nuclei of a cell type in which they are not normally expressed, and that this activation occurs via the cytoplasm. The activators are still present in cells which have already initiated differentiation, are recognized by nuclei of another species, and do not diffuse between unfused cells. The reprogrammed amniocyte nuclei of stable heterocaryons provide a unique system in which to study the mechanisms regulating gene expression during cell specialization.     

Human-Mouse Hybrid Cell Lines and Susceptibility to Polio Virus : II. Polio Sensitivity and the Chromosome Constitution of the Hybrids

A number of human-mouse hybrid cell lines with partial human chromosome complements were sensitive to poliovirus because the cells contained the viral receptor substance of human origin. Infection of the lines with one type of poliovirus regularly led to the survival of a few cells, whose progeny were found to be resistant to all types of poliovirus. Comparison of the chromosomes of sensitive hybrids and their resistant sublines showed no consistent difference in the number of biarmed human chromosomes of any group. The number of acrocentrics was always lower in the resistant hybrids than in the corresponding sensitive lines. It is suggested that the human chromosome bearing the polio receptor gene is an acrocentric.