Colin N. MacDougall scite author profile

Genetic variations in ovulation rate which occur in different breeds of sheep provide useful models to explore the mechanisms regulating the development of antral follicles. The Booroola gene, an autosomal mutation that affects ovulation rate, has been known for over two decades and despite intensive research it has not yet been identified. Using resources from human genome mapping and known data about gene linkage and chromosome location in the sheep, we selected the gene encoding the Bone Morphogenetic Protein receptor (BMPR) type 1 B (ALK-6) as a candidate site for the mutation. The BMPR1B gene in the human is located at the region linked with the Booroola mutation, syntenic to chromosome 6 in the sheep. A fragment of the sheep BMPR1B gene was cloned from an ovarian cDNA and the deduced aminoacid (AA) sequence is over 98% homologous to the known mammalian sequences. cDNA and genomic DNA from 20 Booroola genotypes were screened and two point mutation were found in the kinase domain of the receptor, one at base 746 of the coding region (A in the ++ to a G in FF animals) which results in a change from a glutamine in the wild type to a arginine in the Booroola animals. Another point mutation was identified at position 1113, (C to A) but this mutation does not change the coding aminoacid. The first mutation was confirmed in genomic DNA from 10 ewes from an independent Brazilian flock which segregates the Booroola phenotype. In all instances homozygous FecB gene carrier (n=11) had only the 746 A to G mutation, non gene carriers (n=14) had only the wild type sequence and heterozygote gene carriers (n=5) had both sequences. This mutation in the subdomain 3 of the kinase domain could result in an alteration in the expression and/or phosphorylation of SMADs, resulting in the phenotype characteristic of the Booroola animals which is the 'precocious' development of a large number of small antral follicles resulting in increased ovulation rate.

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Interaction of the Arabidopsis Polycomb group proteins FIE and MEA mediates their common phenotypes

Spillane

et al. 2000

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Genes of the FERTILISATION INDEPENDENT SEED (FIS) class regulate cell proliferation during reproductive development in Arabidopsis [1-5]. The FIS genes FERTILISATION INDEPENDENT ENDOSPERM (FIE) and MEDEA (MEA) encode homologs of animal Polycomb group (Pc-G) proteins, transcriptional regulators that modify chromatin structure and are thought to form multimeric complexes [3-11]. To test whether similarities in fis mutant phenotypes reflect interactions between their protein products, we characterised FIE RNA and protein localisation in vivo, and FIE protein interactions in yeast and in vitro. Expression of FIE mRNA overlaps with that of MEA during embryo sac and seed development and is unaffected in mea mutants. Results from the yeast two-hybrid system and an in vitro pull-down assay indicate that MEA and FIE proteins interact. The relevance of this interaction in vivo is supported by the finding that FIE and MEA co-localise in the nucleus in transfected plant cells. Interaction of MEA and FIE is mediated by the amino-terminal region of MEA. Despite sequence divergence in this domain, MEA can interact with its corresponding animal partner Extrasexcombs (ESC) in the yeast two-hybrid system. We conclude that FIE and MEA act together as part of a multimeric complex and that this accounts for the similarities in mutant phenotypes. We propose that an ancient mechanism for chromatin modification has been independently recruited to different developmental processes in the two kingdoms.

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The Developmental Consequences of Alternate Splicing in Sex Determination and Differentiation inDrosophila

MacDougall

Harbison

Bownes

1995

Developmental Biology

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Sex‐specific transcripts of the Dstpk61 serine/threonine kinase gene in Drosophila melanogaster

MacDougall¹,

Clyde²,

Wood³

et al. 1999

European Journal of Biochemistry

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We describe the characterization of several transcripts of the Drosophila serine/threonine protein kinase 61 (Dstpk61) gene. Dstpk61 produces at least four transcripts, including a 3.0-kb testis-specific transcript, a 4.5-kb female-specific carcass transcript, a 3.5-kb ovary-specific transcript, and a 4.7-kb non-sex-specific transcript. Two cDNAs, a 4.5-kb cDNA (cDNA B ) and a 3.0-kb cDNA (cDNA A ), likely to correspond to either the non-specific or the female-specific carcass and the testis-specific transcript, respectively, were fully sequenced and found to encode a novel OPA-repeat-containing serine/threonine-specific protein kinase. cDNA A and cDNA B both contain the entire ORF that encodes this predicted protein, but differ in the untranslated regions. The cDNAs contain translational control elements which are found in transcripts under male germline-specific translational control, and doublesexlike 13-nucleotide repeat elements, which are required for transformer/transformer-2-mediated splicing of the female doublesex transcript. The complex tissue and sex-specific transcripts, differing in the untranslated regions which are likely to be crucial in translational control, suggest that this kinase may have both general and sex-specific functions. The protein is homologous to human 3-phosphoinositide dependent protein kinase, which is involved in transduction of insulin signalling.

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