Erich Moan scite author profile

The KNOTTED class of plant genes encodes homeodomain proteins. These genes have been found in all plant species where they have been sought and, where examined, show expression patterns that suggest they play an important role in shoot meristem function. Until now, all mutant phenotypes associated with these genes have been due to gain-of-function mutations, making it difficult to deduce their wild-type function. Here we present evidence that the Arabidopsis SHOOT-MERISTEMLESS (STM) gene, required for shoot apical meristem formation during embryogenesis, encodes a class I KNOTTED-like protein. We also describe the expression pattern of this gene in the wild-type plant. To our knowledge, STM is the first gene shown to mark a specific pattern element in the developing plant embryo both phenotypically and molecularly.

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Altered metaphase chromosome structure in xrs-5 cells is not related to its radiation sensitivity or defective DNA break rejoining*1

Schwartz

Brinkman

Kasten

et al. 1995

Mutation Research/Fundamental and Molecular Mechanisms of Mutag

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Faster rates of DNA unwinding under alkaline conditions in xrs-5 cells may reflect chromatin structure alterations

Schwartz

Moan

Mustafi

et al. 1992

Mutation Research Letters

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Metaphase chromosome and nucleoid differences between CHO-K1 and its radiosensitive derivative xrs-5

et al. 1993

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The Chinese hamster ovary (CHO) cell line xrs-5 is a radiation-sensitive mutant isolated from CHO-K1 cells. The radiation sensitivity is associated with a defect in DNA double-strand break rejoining. Chromatin structure also appears altered in xrs-5 cells compared with the parental CHO-K1 cells. Metaphase chromosomes from xrs-5 are more condensed in appearance than CHO-K1 chromosomes. The overcondensed look is not the result of colcemid sensitivity. Electron microscopy studies suggest that xrs-5 metaphase chromosomes have larger loops of chromatin extending out from the chromosome core. There are also differences between CHO-K1 and xrs-5 cells in the size and fluorescence pattern of ethidium bromide-stained nucleoid preparations. These results suggest that there is a fundamental difference between CHO-K1 and xrs-5 in either the organization of the supercoiled loops of DNA attached to the nuclear matrix or in the nature of the proteins that attach the DNA to the matrix. These alterations in chromosome structure may underlie, in part, the radiation sensitivity of xrs-5 cells.

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Erich Moan

A member of the KNOTTED class of homeodomain proteins encoded by the STM gene of Arabidopsis

Altered metaphase chromosome structure in xrs-5 cells is not related to its radiation sensitivity or defective DNA break rejoining*1

Faster rates of DNA unwinding under alkaline conditions in xrs-5 cells may reflect chromatin structure alterations

Metaphase chromosome and nucleoid differences between CHO-K1 and its radiosensitive derivative xrs-5

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