Hochstetter's frog (Leiopelma hochstetteri) egg,mobile larvae and froglet development

Egg strings and larvae of Hochstetter's frog (Leiopelma hochstetteri) were located at three widely separated North Island sites: in seeps at Brynderwyns in December 2004, in an open pool at Wharerino in March 2009, and in an underground pool near the Kaipawa Track, Coromandel, in late May 2009. Ten egg strings were also laid by captive frogs in water courses at Hamilton Zoo in April 2009. All egg strings held from 11 to 13 eggs. The egg strings laid in the Brynderwyns were regularly observed until metamorphosis was completed in March 2005. Twenty-four swimming larvae emerged from 25 capsules at c. 40 days after discovery, and at least 14 froglets were produced at c. 90 days. All of them developed in darkness, in a 120 ml pool <30 mm deep. The emerged froglets ranged from 9.8 to 10.8 mm snout-vent length. The detection of eggs, larvae and <11 mm froglets indicates that the egg laying period is at least from late September to May.     

Conditional Tet-Regulated Over-Expression of <Emphasis Type="Italic">Hoxa2</Emphasis> in CG4 Cells Increases Their Proliferation and Delays Their Differentiation into Oligodendrocyte-like Cells Expressing Myelin Basic Protein

Hoxa2 gene was reported to be expressed by oligodendrocytes (OLs) and down-regulated at the terminal differentiation stage during oligodendrogenesis in mice (Nicolay et al. 2004b). To further investigate the role of Hoxa2 in oligodendroglial development, a tetracycline regulated controllable expression system was utilized to establish a stable cell line (CG4-SHoxa2 [sense Hoxa2]), where the expression level of Hoxa2 gene could be up-regulated. The impact of Hoxa2 over-expression on the proliferation and differentiation of CG4-SHoxa2 cells was investigated. Up-regulation of Hoxa2 increased the proliferation of CG4-SHoxa2 cells. The mRNA levels of PDGFαR (platelet-derived growth factor [PDGF] alpha receptor), which is expressed by OL progenitor cells, were not different in CG4-SHoxa2 cells compared to wild-type CG4 cells. Semi-quantitative RT-PCR revealed that the mRNA levels of myelin basic protein (MBP) was lower in CG4-SHoxa2 cells than in wild-type CG4 cells indicating the differentiation of CG4-SHoxa2 cells was delayed when the Hoxa2 gene was up-regulated.     

Hoxd1 is Expressed by Oligodendroglial Cells and Binds to a Region of the Human Myelin Oligodendrocyte Glycoprotein Promoter in vitro

(1) Little information exists on the role of clustered Hox genes in oligodendrocyte (OG) development. This study examines the expression profile of Hoxd1 and identifies a potential downstream target in the OG lineage. (2) Immunocytochemical analysis of primary mixed glial cultures demonstrated Hoxd1 was expressed throughout OG development. (3) A human myelin protein gene, myelin oligodendrocyte glycoprotein (MOG), was identified as a putative downstream target of Hoxd1 through Genbank searches utilizing the Hoxd1 homeodomain consensus binding sequence. (4) The dissociation coefficient constant (K _D) and dissociation rate constant (k _d) of the Hoxd1–MOG complex, determined using electrophoretic mobility shift assays (EMSAs), were estimated to be 1.9 × 10⁻⁷ M and 1.3 × 10⁻³ s⁻¹, respectively. The DNA–Hoxd1 homeodomain complex had a half-life (t _1/2) of 15 min. (5) Mutational analysis of Hoxd1–MOG complexes revealed the binding affinity of M1 (with mutation from ⁻¹⁰⁵⁴5′-TAAT-3′⁻¹⁰⁵¹ to TACT within the consensus binding site) and M2 (with mutation from ^-10545′-TAATTG-3′^-1049 to TAATCC within the consensus binding site) probes to the MOG promoter was severely affected. Thus the TAATTG core of the binding sequence appears important for Hoxd1 specificity. (6) Analysis of the involvement of TAAT sites adjacent to the consensus sequence in Hoxd1 binding showed the binding affinity of the M3 probe was affected, but not as severely as the M1 and M2 probes. These in vitro results suggest the TTTAATTGTA sequence is involved in Hoxd1 binding to the MOG promoter but neighboring TAAT sites may also be needed. Thus, MOG may be a target of Hoxd1.     

Time Space Translation: A Hox Mechanism for Vertebrate A-P Patterning

The vertebrate A-P axis is a time axis. The head is made first and more and more posterior levels are made at later and later stages. This is different to the situation in most other animals, for example, in Drosophila. Central to this timing is Hox temporal collinearity (see below). This occurs rarely in the animal kingdom but is characteristic of vertebrates and is used to generate the primary axial Hox pattern using time space translation and to integrate successive derived patterns (see below). This is thus a different situation than in Drosophila, where the primary pattern guiding Hox spatial collinearity is generated externally, by the gap and segmentation genes.     

NITPICK: peak identification for mass spectrometry data

Background  

The reliable extraction of features from mass spectra is a fundamental step in the automated analysis of proteomic mass spectrometry (MS) experiments.