EC:3.4.21.4 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.4 (trypsin)
42,187 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A 36-yr-old black female presented with primary amenorrhea. The chromosomal constitution based on QFQ (Q bands by fluorescence using quinacrine) RFA (R bands by fluorescence using acridine orange), GTG (G band by Giemsa using trypsin), and CBG (C band by Giemsa using barium hydroxide) techniques was 46, XX, duplicated (9; q12), inverted (9; p12q12.1) in lymphocytes and skin fibroblasts. Both sex chromosomes were normal. Buccal smear revealed 22% Barr bodies. Duplication and inversion of secondary constriction regions of chromosome 9 may possibly be associated with abnormal clinical features.
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PMID:Primary amenorrhea in a black female with duplication and inversion of the secondary constriction regions of chromosome 9. 12 3

Chinese hamster X mouse somatic cell hybrids segregating mouse chromosomes were examined for their mouse chromosome content using trypsin-Giemsa (GTG) banding and Hoechst 33258 staining techniques. Simultaneously, they were scored for the presence of 24 mouse enzymes. The results confirm the assignments of 11 genes previously mapped by sexual genetics: Dip-1 and Id-1 to chromosome 1; Pgm-2 and Pgd to 4; Pgm-1 to 5; Gpi-1 to 7; Gr-1 to 8; Mpi-1 and Mod-1 to 9; Np-1 and Es-10 to 14. They also confirm chromosomally the assignments of 3 genes that were made by other somatic cell genetic studies: Aprt to 8; Hprt and alpha-gal to the X chromosome. But most importantly, four enzyme loci are assigned to four chromosomes that until now were not known to carry a biochemical marker which is expressed in cultured cells: Trip-1 to 10; Dip-2 to 18; Acp-1 to 12; and Ak-1 to 2. Cytogenetic examination of clones showing discordant segregation of HPRT and A-GAL, suggested the assignment of alpha-gal to region XE leads to XF of the mouse X chromosome. The cytologic studies provide a comparison between data from sexual genetics and somatic cell hybrids and validate hybrid cell techniques. They provide evidence of the reliability of scoring chromosomes by GTG and Hoechst staining and stress the importance of identifying clones with multiple chromosome rearrangements. Striking examples of norandom segregation of mouse chromosomes were observed in these hybrids with preferential retention of 15 and segregation of 11 and the Y chromosome.
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PMID:Gene mapping in Mus musculus by interspecific cell hybridization: assignment of the genes for tripeptidase-1 to chromosome 10, dipeptidase-2 to chromosome 18, acid phosphatase-1 to chromosome 12, and adenylate kinase-1 to chromosome 2. 19 84

The integrin VLA-4 (alpha 4: beta 1; CD49d/CD29) is involved in both cellular adhesion to extracellular matrix and cell-cell interactions. We have determined that the human gene coding for VLA-alpha 4 is located on the long arm of chromosome 2 by using fluorescence in situ hybridization. The VLA-alpha 4 gene has been more precisely mapped to the 2q31-q32 region after GTG banding (G-bands by trypsin using Giemsa). These data suggest that the VLA-4 gene belongs to the COL3A1-(ELN-FN)-COL6A3 linkage group and establishes a potential genetic relationship between the alpha 4 and alpha v integrin subunits.
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PMID:Mapping of the human VLA-alpha 4 gene to chromosome 2q31-q32. 153 88

Chromosome studies were carried out after a 24-hour harvest of unstimulated bone marrow aspirate cell cultures from a 75-year-old male with a clinical diagnosis of acute myelomonocytic leukemia (FAB M4). Analysis of nine cells after trypsin-Giemsa banding (GTG) revealed two cell lines with a mosaic chromosome pattern, 46,XY/46,XY,t(7;19)(q22;p13.3). A review of the recent literature reveals one case of childhood ALL with a 46,XY/46,XY,t(7;19)(q11;q13) chromosome pattern [1] and a 46,XY,t(3q;11q),t(7q;19p),t(15;17)(q26;q22) in one patient with ANLL (FAB M3) [2]. The t(7;19)(q22;p13.3) seen in our case has not been reported as the sole specific clonal chromosome rearrangement in myeloid neoplasia. Interestingly, the plasminogen activator inhibitor type I, multi-drug resistance, and erythropoietin genes are located at band 7q22 and the insulin receptor gene is located at band 19p13.3. Both sites contain fragile site loci. The possible role of these fragile sites, genes, or other genes in the rearrangement can only be surmised.
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PMID:Atypical (7;19) translocation in acute myelomonocytic leukemia. 175 94

As chromosomes condense during early mitosis, their subbands fuse in a highly coordinated fashion. Subband fusion occurs when two large subbands flanking one minor subband come together to form one band, which takes on the cytological characteristics of the original flanking subbands. Using four different banding techniques--GTG (G-bands obtained with trypsin and Giemsa), GBG (G-bands obtained with BrdU and Giemsa), RHG (R-bands obtained by heating and Giemsa), and RBG (R-bands obtained with BrdU and Giemsa)--we studied subband fusion from prophase (1,250 bands per haploid set) to late metaphase (300 bands). To quantify the condensation process, a fusion index was established. We found that chromosomes contain preferential zones of condensation. From prophase to late metaphase, the early replicating subbands (R-subbands) fuse more readily with each other than do the late-replicating subbands (G-subbands). R-bands usually replicate early and condense late independently of the adjacent G-bands, which replicate late but condense early. Therefore, chromosome bands can undergo DNA replication and chromatin condensation relatively autonomously. Our data suggest that (1) chromosome replication and condensation are closely connected in time, (2) the metaphase bands represent independent units of chromatin condensation, and (3) the condensation process is an important feature of chromosome organization.
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PMID:Chromosome condensation from prophase to late metaphase: relationship to chromosome bands and their replication time. 191 28

High-resolution human chromosomes were obtained from lymphocytes after thymidine synchronization. The block was released either with thymidine to produce GTG (G-bands by trypsin using Giemsa) and RHG (R-bands by heating using Giemsa) banding or with BrdU (5-bromo-2'-deoxyuridine) for RBG (R-bands by BrdU using Giemsa) banding. RHG and RBG band patterns are only 75 to 85% congruent. The dissimilarities increase with the band number per genome and vary from one chromosome region to another. After high-resolution RBG banding, the BrdU-substituted bands show an unequal condensation delay, which can be, according to the bands involved, very important, minimal, or even absent. The bands showing the highest degree of condensation delay are the bands replicating the latest. The GTG- and RHG-band patterns show complementary matching for about 90% of the bands. It was found that two third of the chromosome surface appears positively stained after R-banding. This suggests that more DNA is replicated during early S-phase than during late S-phase. To obtain a fully developed RBG-band pattern in 90 to 95% of harvested mitoses, a period of 4.5 hours after the removal of the blocking agent is optimal. Such a brief release period also implies that late S-phase is much shorter than early S-phase.
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PMID:High-resolution R-banding at the 1250-band level. III. Comparative analysis of morphologic and dynamic R-band patterns (RHG and RBG). 207 51

Nonradioactive in situ hybridization (ISH) using biotinylated centromere probes for chromosomes 1, 6, 7, 10, 16, 17, 18, and the X, respectively, was combined with GTG-banding to study cytogenetic changes in two different ovarian cancer cell lines. ISH was performed after GTG-banding on the same metaphase. The use of a low trypsin concentration (0.01%) in the banding procedure was essential for subsequent ISH. This combined approach allows the detection of subtle chromosomal rearrangements and appears to aid the identification of marker chromosomes.
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PMID:Combined GTG-banding and nonradioactive in situ hybridization improves characterization of complex karyotypes. 224 70

A high-resolution replication banding technique, dynamic GBG banding (G-bands after 5'-bromodeoxyuridine [BrdUrd] and Giemsa), showed that, at a resolution of 850 bands/genome, GBG banding and GTG banding (G-bands after trypsin and Giemsa) produce almost identical patterns. RBG band (R-bands after BrdUrd and Giemsa) and RHG band (R-bands after heat denaturation and Giemsa) patterns were previously shown to be only 75%-85% coincident; thus GTG banding more accurately reflects replication patterns than does RHG banding. BrdUrd synchronization uses high concentrations of BrdUrd both to substitute early replicating DNA and to arrest cells before the late bands replicate. Release from the block is via a low thymidine concentration. The banding is revealed by the fluorochrome-photolysis-Giemsa (FPG) technique and produces the GBG banding that includes concomitant staining of constitutive heterochromatin. As opposed to other replication G-banding procedures, BrdUrd synchronization and GBG banding produces a reproducible replication band pattern. The discordance between homologs after GBG banding is similar to that after GTG banding and no lateral asymmetry of the constitutive heterochromatin has been observed. Also, BrdUrd synchronization neither significantly depresses the mitotic index, nor induces chromosome breaks. Thus, GBG banding seems as clinically useful as GTG banding and provides important information regarding replication time.
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PMID:High-resolution dynamic and morphological G-bandings (GBG and GTG): a comparative study. 239 43

A de novo interstitial deletion of part of the long arm of chromosome 10 [del(10)(q11.2q21)] was identified by GTG (G-bands by trypsin using Giemsa) banding in a 9-year-old girl with mental retardation and minor anomalies. Only one other case of a similar deletion has been reported [Ray et al, 1980] and the phenotypic findings of the two cases are compared.
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PMID:Brief clinical report: interstitial deletion of the long arm of chromosome 10: del(10)(q11.2q21). 257 54

The molecular analysis of many genetic diseases requires the isolation of probes for defined human chromosome regions. Existing techniques such as the screening of chromosome-specific libraries, subtractive DNA cloning and chromosome jumping are either tedious or not generally applicable. Microdissection and microcloning has successfully been applied to various chromosome regions in Drosophila and mouse, but conventional microtechniques are too coarse and inefficient for analysis of the human genome. Because microdissection has previously been used on unbanded chromosomes only, cell lines in which the chromosome of interest could be identified without banding had to be used. At least one hundred chromosomes were needed for dissection and lambda vectors used to achieve maximum cloning efficiency. Recombinant phage clones are, however, more difficult to characterize than plasmid clones. Here we describe the dissection of the Langer-Giedion syndrome region on chromosome 8 from GTG-banded metaphase chromosomes (G-banding with trypsin-Giemsa) and the universal enzymatic amplification of the dissected DNA. Eighty per cent of clones from this library (total yield 20,000) identify single-copy DNA sequences. Fifty per cent of clones detect deletions in two patients with Langer-Giedion syndrome. Although the other clones have not yet been mapped, this result demonstrates that thousands of region-specific probes can be isolated within ten days.
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PMID:Cloning defined regions of the human genome by microdissection of banded chromosomes and enzymatic amplification. 278 97

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