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Target Concepts:
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Query: EC:2.7.7.49 (
reverse transcriptase
)
31,746
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Mammalian Polycomb group (Pc-G) genes, constituting some 5 subfamilies based on their identity to the Drosophila genes Pc, Psc, ph, esc, and E(z), appear to play critical roles in maintaining the transcriptional repression state of Hox/HOM-C genes during development. Despite increasing evidence of the important role of Hox genes in both normal hematopoiesis and leukemic transformation, little is known about the expression and possible function played by Pc-G genes in hematopoietic cells. To address this, we first examined the expression of Pc genes in purified CD34(+) human bone marrow cells by
reverse transcriptase
-polymerase chain reaction (RT-PCR), using degenerate primers that specifically amplify the majority of Pc genes. This analysis showed the expression of 8 different Pc genes in CD34(+) bone marrow cells, including
HP1
(Hsalpha),
HP1
(Hsgamma), the heterochromatin p25 protein, the human homologue of the murine M32 gene, and 4 novel members of this family. To assess whether Pc-G mRNA levels change during differentiation of bone marrow cells, a quantitative RT-PCR method was used to amplify the total cDNA originating from three purified subpopulations of CD34(+) bone marrow cells known to differ in their ability to grow in long-term or semisolid cultures. In sharp contrast to Hox gene expression, which is highest in the most primitive bone marrow cells, these studies show that the expression level of 8 of the 9 Pc-G genes studied (ie,
HP1
(Hsalpha),
HP1
(Hsgamma), M31, M32, M33, Mel-18, Mph1/Rae-28, and ENX-1) markedly increases with differentiation of bone marrow cells. Interestingly, BMI-1 exhibits a strikingly different pattern of expression, with high expression levels in primitive cells and very little expression in mature CD34(-) cells. Together, these results document for the first time that differentiation of human bone marrow cells is accompanied by profound changes in Pc-G gene expression levels.
...
PMID:Stage-specific expression of polycomb group genes in human bone marrow cells. 945 51
Our recent work has indicated that the potent antibiotic and antitumor agent actinomycin D has the ability to selectively bind and stabilize single-stranded DNA that is capable of adopting a hairpin conformation. This mechanism of DNA binding has been implicated in the drug's ability to inhibit transcription by HIV
reverse transcriptase
from single-stranded DNA templates. In this report, we studied the importance of the hairpin loop on the ability of the 7-amino analog of actinomycin D to selectively bind DNA hairpins. Binding dissociation constant (Kd) values were determined to be 0.22 +/- 0.11 microM for the hairpin formed from the single-stranded DNA 5'-AAAAAAATAGTTTTAAATATTTTTTT-3' (dubbed
HP1
). The hairpin stem without the loop resulted in binding with Kd = 2.6 +/- 0.9 microM. The drug showed low affinity for the
HP1
strand fully duplexed to its complementary sequence (estimated to be at least Kd > 21 microM). Evaluation of 7-aminoactinomycin D binding to a library of thermodynamically characterized DNA hairpins revealed an affinity for the hairpin-forming sequence 5'-GGATACCCCCGTATCC-3' (dubbed ACC4) of Kd = 6.8 +/- 2.2 microM. Replacement of the terminal guanines of this sequence to generate 5'-ATATACCCCCGTATAT-3' resulted in a 10-fold increase in affinity for this hairpin compared to ACC4, to Kd = 0.74 +/- 0.06 microM. A molecular model of the ACC4actinomycin D complex reveals that significant interactions between the hairpin loop and the pentapeptide rings of the drug must occur during drug binding. Taken together, our data indicate that the composition of the stem-loop interface is critical for the selectivity of actinomycin D and its 7-amino analog for DNA hairpins and suggests that novel drugs may be designed based on selection for the desired hairpin composition.
...
PMID:The role of the loop in binding of an actinomycin D analog to hairpins formed by single-stranded DNA. 1114 31
Telomeres in all organisms must perform the same vital functions to ensure cell viability: to act as a protective chromosome cap that distinguishes natural chromosome ends from DNA double strand breaks, and to balance the loss of DNA from the chromosome end due to incomplete DNA replication. Most eukaryotes rely on a specialized
reverse transcriptase
, telomerase, to generate short repeats at the chromosome end to maintain chromosome length. Drosophila, however, uses retrotransposons that target telomeres. Transposition of these elements may be controlled by small RNAs and spreading of silent chromatin from the telomere associated sequence, both of which limit the retrotransposon expression level. Proteins binding to the retrotransposon array, such as
HP1
and PROD, may also modulate transcription. It is not clear however, that simply increasing transcript levels of the telomeric retrotransposons is sufficient to increase transposition. The chromosome cap may control the ability of the telomere-specific elements to attach to chromosome ends. As in other organisms, chromosomes can be elongated by gene conversion. Although the mechanism is not known,
HP1
, a component of the cap, and the Ku proteins are key components in this pathway.
...
PMID:Regulation of telomere length in Drosophila. 1918 6
When the telomerase catalytic subunit (Trt1/TERT) is deleted, a majority of fission yeast cells survives by circularizing chromosomes. Alternatively, a small minority survives by maintaining telomeric repeats through recombination among telomeres. The recombination-based telomere maintenance in trt1Delta cells is inhibited by the telomere protein Taz1. In addition, catalytically inactive full-length Trt1 (Trt1-CI) and truncated Trt1 lacking the T-motif and
reverse transcriptase
(RT) domain (Trt1-DeltaT/RT) can strongly inhibit recombination-based survival. Here, we investigated the effects of deleting the heterochromatin proteins Swi6 (
HP1
ortholog) and Clr4 (Suv39 family of histone methyltransferases) and the telomere capping complex subunits Poz1 and Ccq1 on Taz1- and Trt1-dependent telomere recombination inhibition. The ability of Taz1 to inhibit telomere recombination did not require Swi6, Clr4, Poz1, or Ccq1. Although Swi6, Clr4, and Poz1 were dispensable for the inhibition of telomere recombination by Trt1-CI, Ccq1 was required for efficient telomere recruitment of Trt1 and Trt1-CI-dependent inhibition of telomere recombination. We also found that Swi6, Clr4, Ccq1, the checkpoint kinase Rad3 (ATR ortholog), and the telomerase regulatory subunit Est1 are all required for Trt1-DeltaT/RT to inhibit telomere recombination. However, because loss of Swi6, Clr4, Rad3, Ccq1, or Est1 did not significantly alter the recruitment efficiency of Trt1-DeltaT/RT to telomeres, these factors are likely to enhance the ability of Trt1-DeltaT/RT to inhibit recombination-based survival by contributing to the negative regulation of telomere recombination.
...
PMID:Roles of heterochromatin and telomere proteins in regulation of fission yeast telomere recombination and telomerase recruitment. 2004 May 95
