The roles of Shroom family proteins during Xenopus development

Lee, Chan-jae

16 October 2009

The Shroom family of proteins is currently comprised of four members, Shroom1, 2, 3 and 4. Since Shroom3 was shown to be a critical protein for neural tube closure, the other three proteins are also expected to play an important role for proper development. However, their functions during development were not clear. To address this, my study started with Shroom3 function in the neural plate. Shroom3 had been previously known to induce apical constriction by controlling actin filaments in neuroepithelial cells. My studies show that Shroom3 induces apico-basal cell heightening by controlling parallel microtubule assembly. Shroom3 is able to change the distribution of γ-tubulin, suggesting that Shroom3 controls apical constriction and apico-basal cell elongation via both actin filaments and microtubules. The ability to control γ-tubulin distribution is possessed not only by Shroom3, but also by all other Shroom proteins, although they can not induce apical constriction. In addition, they are expressed in tissues which contain apico-basally elongated cells. Data from functional assays with Shroom2 show that it induces cell elongation and is required for proper cell shape in deep layer neuroepithelial cells in Xenopus. These data suggest that Shroom family proteins control cell architecture during morphogenetic development. I have discovered another role for Shroom2. By comparative analysis with Xenopus and Physalaemus, which have different pigment patterns in eggs, I show that a high level of maternal Shroom2 mRNA is important for pigment polarity in Xenopus. Furthermore, Shroom2 controls the distribution of spectrin which plays a role in pigment granule movement. Thus, Shroom2 is suggested to be a key molecule to control the pigment polarity in amphibian eggs. Together all these data suggest that Shroom family proteins play a role in cell morphogenesis and polarization via controlling the cytoskeleton during Xenopus development. / text

Shroom family proteins

Xenopus development

Shroom3

Shroom2

Cell morphogenesis

Polarization

Pigment polarity

Metabolic, cardiac and ventilatory regulation in early larvae of the South African clawed frog, Xenopus laevis.

Pan, Tien-Chien

12 1900

Early development of O2 chemoreception and hypoxic responses under normoxic (150 mmHg) and chronically hypoxic (110 mmHg) conditions were investigated in Xenopus laevis from hatching to 3 weeks post fertilization. Development, growth, O2 consumption, ventilatory and cardiac performance, and branchial neuroepithelial cells (NEC) density and size were determined. At 3 days post fertilization (dpf), larvae started gill ventilation at a rate of 28 ± 4 beats/min and showed increased frequency to 60 ± 2 beats/min at a PO2 of 30 mmHg. Also at 3 dpf, NECs were identified in the gill filament buds using immunohistochemical methods. Lung ventilation began at 5 dpf and exhibited a 3-fold increase in frequency from normoxia to a PO2 of 30 mmHg. Hypoxic tachycardia developed at 5 dpf, causing an increase of 20 beats/min in heart rate, which led to a 2-fold increase in mass-specific cardiac output at a PO2 of 70 mmHg. At 10 dpf, gill ventilatory sensitivity to hypoxia increased, which was associated with the increase in NEC density, from 15 ± 1 to 29 ± 2 cells/mm of filament at 5 and 10 dpf, respectively. Unlike the elevated rate, cardiac and ventilatory volumes were independent of acute hypoxia. Despite increased cardioventilatory frequency, larvae experienced an average of 80% depression in during acute hypoxia. Chronic hypoxia (PO2 of 110 mmHg) decreased mass-specific cardiac performance before 10 dpf. In older larvae (10 to 21 dpf), chronic hypoxia decreased acute branchial and pulmonary hypoxic hyperventilation and increased NEC size. Collectively, these data suggest that larvae exhibit strong O2-driven acute hypoxic responses post-hatching, yet are still O2 conformers. All acute hypoxic responses developed before 5 dpf, and then the effects of chronic hypoxia started to show between 7 and 21 dpf. Thus, the early formation of acute hypoxic responses is susceptible to the environment and can be shaped by the ambient PO2.

Metabolism

Xenopus development

hypoxia

neuroepithelial cell

ventilation

Xenopus laevis -- Larvae.

Xenopus laevis -- Metabolism.

Xenopus laevis -- Cardiovascular system.

Xenopus laevis -- Respiration.

Xenopus Laevis TGF-ß: Cloning And Characterization Of The Signaling Receptors

Mohan, D Saravana

01 1900

The amphibian species Xenopus laevis, along with mouse and chicken is a very important model system, used widely to dissect the molecular intricacies of various aspects of vertebrate development. Study with Xenopus has clear advantages in terms of various technical considerations including the ease of handling early stage of embryos and due to the remarkable documentation of several early molecular events during development. The concept of inductive interactions between various cell types during early development was first revealed by the studies performed in Xenopus, and among the various factors proposed for mesoderm induction, the members of transforming growth factor-β (TGF- β) superfamily have been considered to be the most probable candidates. About forty different members of the TGF-β superfamily have been cloned and characterized from various organisms. The superfamily members like activins and BMPs have been studied extensively with respect to their functional role during development. While BMPs were assigned as candidates for inducing ventral mesoderm, activins oppose the role of BMPs by inducing dorsal mesoderm. Studies that helped in delineating their roles were performed using three approaches that utilized the ligands, receptors or down stream signaling components (Smads). All the three components were studied with respect to their endogenous expression pattern and effects of ectopic expressions of the wild type or dominant negative mutants. These approaches led to the accumulation of evidences supporting the importance of these signaling molecules. All the above mentioned studies were only possible due to the cloning and characterization of cDNAs of the various proteins involved in the signaling pathway including the ligands. TGF-β2 and 5 are the two isoforms of TGF-β cloned from the amphibian system. We have earlier cloned and characterized the promoter for TGF-β5 gene, which suggested possible regulation of this factor by tissue specific transcription factors. Messenger RNA in situ hybridization analysis to study the TGF-β5-expression pattern during Xenopus development, showed spatial and temporal expression pattern. The expression was confined to specific regions that include notochord, somites, and tail bud among others, in the various stages analyzed. This suggested a possible role for TGF-β5 in organogenesis during the amphibian development. To better understand the role of TGF-β in Xenopus development, studies to examine the specific receptor expression pattern for this growth factor is very essential. With the lack of any reports on cloning of TGF-β receptors from this system, the aim of the present study was to isolate and characterize the receptors for TGF-β from Xenopus laevis. PCR cloning using degenerate primers based on the conserved kinase domains of this class of receptors, coupled to library screenings enabled the identification of two novel receptor cDNAs of the TGF-β receptor superfamily. Characterization of the isolated cDNAs suggested that one of them codes for a type II receptor for TGF-β. Further the cDNAs were found to be ubiquitously expressed during development, as judged by RT-PCR analysis. The cloned cDNAs can now be employed as tools, to study the expression pattern by means of mRNA in situ hybridization, on the various developmental stage embryos and to perform studies using antisense and dominant negative mRNA injection experiments in vivo. Such studies will greatly assist in delineating the role of TGF-β ligands and receptors during amphibian development.

Cell Biology

Cell Receptors - Cloning

Xenopus Laevis

Growth Factor - Gene Expression

Xenopus Development

Activins

BMPs

Serine/Threonine Kinase Receptor

Vertebrate Development - Receptors

Transforming Growth Factor-β (TGF-β )

TGF-β Receptors