Michael Clarkson scite author profile

Despite 12 yr since the discovery of SRY, little is known at the molecular level about how SRY and the SRY-related protein, SOX9 [SRY-related high-mobility group (HMG) box 9], initiate the program of gene expression required to commit the bipotential embryonic gonad to develop into a testis rather than an ovary. Analysis of SRY and SOX9 clinical mutant proteins and XX mice transgenic for testis-determining genes have provided some insight into their normal functions. SRY and SOX9 contain an HMG domain, a DNA-binding motif. The HMG domain plays a central role, being highly conserved between species and the site of nearly all missense mutations causing XY gonadal dysgenesis. SRY and SOX9 are architectural transcription factors; their HMG domain is capable of directing nuclear import and DNA bending. Whether SRY and SOX9 activate testis-forming genes, repress ovary-forming genes, or both remains speculative until downstream DNA target genes are identified. However, factors that control SRY and SOX9 gene expression have been identified, as have a dozen sex-determining genes, allowing some of the pieces in this molecular genetic puzzle to be connected. Many genes, however, remain unidentified, because in the majority of cases of XY females and in all cases of XX males lacking SRY, the mutated gene is unknown.

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A His2AvDGFP Fusion Gene Complements a Lethal His2AvD Mutant Allele and Provides an in Vivo Marker for Drosophila Chromosome Behavior

Clarkson¹,

Saint²

1999

DNA and Cell Biology

189

169

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We have generated Drosophila melanogaster lines carrying a modified genomic fragment which encodes the D. melanogaster variant H2A.F/Z class histone, His2AvD, fused to the green fluorescent protein (GFP) of the jellyfish Aequorea victoria. We show here that the fusion protein consists of functional GFP and functional histone His2AvD. The His2AvD portion of the fusion gene was shown to be functional by rescue of His2AvD mutant lethality. Fluorescence of the fusion protein in vivo was observed in embryonic cleavage stage interphase nuclei and on chromosomes as early as cycle 9, correlating with activation of transcription. Unlike transcription factors, the His2AvDGFP protein remained on transcriptionally inactive chromosomes throughout mitosis. Subsequently, fluorescence was observed in nuclei at all stages of embryonic and larval development and in adult somatic tissues, consistent with the distribution of His2AvD observed by immunohistochemical staining. This functional fusion histone acts as an excellent in vivo marker for chromosomes and chromosome behavior and, given the ability of the fusion gene to prevent null-mutant lethality, without disrupting normal cellular functions. The very high level of conservation of the H2A.F/Z family of variant histones suggests that the equivalent fusion protein construct should function equally well in a wide range of organisms.

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Regions of variant histone His2AvD required for Drosophila development

Clarkson

Wells²,

Gibson

et al. 1999

Nature

195

154

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One way in which a distinct chromosomal domain could be established to carry out a specialized function is by the localized incorporation of specific histone variants into nucleosomes. H2AZ, one such variant of the histone protein H2A, is required for the survival of Drosophila melanogaster, Tetrahymena thermophila and mice (R. Faast et al., in preparation). To search for the unique features of Drosophila H2AZ (His2AvD, also referred to as H2AvD) that are required for its essential function, we have performed amino-acid swap experiments in which residues unique to Drosophila His2AvD were replaced with equivalently positioned Drosophila H2A.1 residues. Mutated His2AvD genes encoding modified versions of this histone were transformed into Drosophila and tested for their ability to rescue null-mutant lethality. We show that the unique feature of His2AvD does not reside in its histone fold but in its carboxy-terminal domain. This C-terminal region maps to a short alpha-helix in H2A that is buried deep inside the nucleosome core.

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Untitled

et al. 2000

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Activation of transcription within chromatin has been correlated with the incorporation of the essential histone variant H2A.Z into nucleosomes. H2A.Z and other histone variants may establish structurally distinct chromosomal domains; however, the molecular mechanism by which they function is largely unknown. Here we report the 2.6 A crystal structure of a nucleosome core particle containing the histone variant H2A.Z. The overall structure is similar to that of the previously reported 2.8 A nucleosome structure containing major histone proteins. However, distinct localized changes result in the subtle destabilization of the interaction between the (H2A.Z-H2B) dimer and the (H3-H4)(2) tetramer. Moreover, H2A.Z nucleosomes have an altered surface that includes a metal ion. This altered surface may lead to changes in higher order structure, and/or could result in the association of specific nuclear proteins with H2A.Z. Finally, incorporation of H2A.Z and H2A within the same nucleosome is unlikely, due to significant changes in the interface between the two H2A.Z-H2B dimers.

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