SUMMARY
Stem cells persist throughout life in diverse tissues by undergoing self-renewing divisions. Self-renewal capacity declines with age, partly due to increasing p16Ink4a expression, but little is known about the mechanisms responsible for these changes. We discovered the Hmga2 transcriptional regulator was highly expressed in fetal neural stem cells but expression declined with age, partly due to increasing let-7b microRNA expression. Hmga2 deficiency reduced stem cell frequency and self-renewal throughout the central and peripheral nervous systems of fetal and young adult mice, but not old adult mice where it was no longer expressed. Hmga2 deficiency did not affect restricted neural progenitor proliferation. Hmga2 deficient fetal and young adult stem cells exhibited increased p16Ink4a and p19Arf expression, and deletion of p16Ink4a and/or p19Arf partially rescued their self-renewal. let-7b over-expression reduced Hmga2 expression and increased p16Ink4a/p19Arf expression. Changes in let-7b and Hmga2 expression during stem cell aging increase p16Ink4a/p19Arf expression and reduce self-renewal.
Growth is one of the fundamental aspects in the development of an organism. Classical genetic studies have isolated four viable, spontaneous mouse mutants disrupted in growth, leading to dwarfism. Pygmy is unique among these mutants because its phenotype cannot be explained by aberrations in the growth hormone-insulin-like growth factor endocrine pathway. Here we show that the pygmy phenotype arises from the inactivation of Hmgi-c (ref. 6), a member of the Hmgi family which function as architectural factors in the nuclear scaffold and are critical in the assembly of stereospecific transcriptional complexes. Hmgi-c and another Hmgi family member, Hmgi(gamma) (ref. 10), were found to be expressed predominantly during embryogenesis. The HMGI proteins are known to be regulated by cell cycle-dependent phosphorylation which alters their DNA binding affinity. These results demonstrate the important role of HMGI proteins in mammalian growth and development.
Fingerprinting of RNA populations was achieved using an arbitrarily selected primer at low stringency for first and second strand cDNA synthesis. PCR amplification was then used to amplify the products. The method required only a few nanograms of total RNA and was unaffected by low levels of genomic double stranded DNA contamination. A reproducible pattern of ten to twenty clearly visible PCR products was obtained from any one tissue. Differences in PCR fingerprints were detected for RNAs from the same tissue isolated from different mouse strains and for RNAs from different tissues from the same mouse. The strain-specific differences revealed are probably due to sequence polymorphisms and should be useful for genetic mapping of genes. The tissue-specific differences revealed may be useful for studying differential gene expression. Examples of tissue-specific differences were cloned. Differential expression was confirmed for these products by Northern analysis and DNA sequencing uncovered two new tissue-specific messages. The method should be applicable to the detection of differences between RNA populations in a wide variety of situations.
Lipomas are one of the most common mesenchymal neoplasms in humans. They are characterized by consistent cytogenetic aberrations involving chromosome 12 in bands q14-15. Interestingly, this region is also the site of rearrangement for other mesenchymally derived tumors. This study demonstrates that HMGI-C, an architectural factor that functions in transcriptional regulation, has been disrupted by rearrangement at the 12q14-15 chromosomal breakpoint in lipomas. Chimeric transcripts were isolated from two lipomas in which HMGI-C DNA-binding domains (AT hook motifs) are fused to either a LIM or an acidic transactivation domain. These results, identifying a gene rearranged in a benign neoplastic process that does not proceed to a malignancy, suggest a role for HMGI-C in adipogenesis and mesenchyme differentiation.
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