Commitment and response to inductive signals of primary mesenchyme cells of the sea urchin embryo

In the sea urchin embryo, primary mesenchyme cells (PMC) are committed to produce the larval skeleton, although their behavior and skeleton production are influenced by signals from the embryonic environment. Results from our recent studies showed that perturbation of skeleton development, by interfering with ectoderm-extracellular matrix (ECM) interactions, is linked to a reduction in the gene expression of a transforming growth factor (TGF)-beta growth factor, Pl-univin, suggesting a reduction in the blastocoelic amounts of the protein and its putative involvement in signaling events. In the present study, we examined PMC competence to respond to environmental signals in a validated skeleton perturbation model in Paracentrotus lividus. We found that injection of blastocoelic fluid (BcF), obtained from normal embryos, into the blastocoelic cavity of skeleton-defective embryos rescues skeleton development. In addition, PMC from skeleton-defective embryos transplanted into normal or PMC-less blastula embryos are able to position in correct regions of the blastocoel and to engage spicule elongation and patterning. Taken together, these results demonstrate that PMC commitment to direct skeletogenesis is maintained in skeleton perturbed embryos and confirm the role played by inductive signals in regulating skeleton growth and shape.     

Use of in-biofilm expression technology to identify genes involved in Pseudomonas aeruginosa biofilm development

Mature Pseudomonas aeruginosa biofilms form complex three-dimensional architecture and are tolerant of antibiotics and other antimicrobial compounds. In this work, an in vivo expression technology system, originally designed to study virulence-associated genes in complex mammalian environments, was used to identify genes up-regulated in P. aeruginosa grown to a mature (5-day) biofilm. Five unique cloned promoters unable to promote in vitro growth in the absence of purines after recovery from the biofilm environment were identified. The open reading frames downstream of the cloned promoter regions were identified, and knockout mutants were generated. Insertional mutation of PA5065, a homologue of Escherichia coli ubiB, was lethal, while inactivation of PA0240 (a porin homologue), PA3710 (a putative alcohol dehydrogenase), and PA3782 (a homologue of the Streptomyces griseus developmental regulator adpA) had no effect on planktonic growth but caused defects in biofilm formation in static and flowing systems. In competition experiments, mutants demonstrated reduced fitness compared with the parent strain, comprising less than 0.0001% of total biofilm cells after 5 days. Therefore, using in-biofilm expression technology, we have identified novel genes that do not affect planktonic growth but are important for biofilm formation, development, and fitness.     

Signaling molecules involved in the transition of growth to development of Dictyostelium discoideum

The social amoeba Dictyostelium discoideum, a powerful paradigm provides clear insights into the regulation of growth and development. In addition to possessing complex individual cellular functions like a unicellular eukaryote, D. discoideum cells face the challenge of multicellular development. D. discoideum undergoes a relatively simple differentiation process mainly by cAMP mediated pathway. Despite this relative simplicity, the regulatory signaling pathways are as complex as those seen in metazoan development. However, the introduction of restriction-enzyme-mediated integration (REMI) technique to produce developmental gene knockouts has provided novel insights into the discovery of signaling molecules and their role in D. discoideum development. Cell cycle phase is an important aspect for differentiation of D. discoideum, as cells must reach a specific stage to enter into developmental phase and specific cell cycle regulators are involved in arresting growth phase genes and inducing the developmental genes. In this review, we present an overview of the signaling molecules involved in the regulation of growth to differentiation transition (GDT), molecular mechanism of early developmental events leading to generation of cAMP signal and components of cAMP relay system that operate in this paradigm.     

Multiple inductive signals are involved in the development of the ctenophore Mnemiopsis leidyi.

Ctenophores possess eight longitudinally arrayed rows of comb plate cilia. Previous intracellular cell lineage analysis has shown that these comb rows are derived from two embryonic lineages, both daughters of the four e(1) micromeres (e(11) and e(12)) and a single daughter of the four m(1) micromeres (the m(12) micromeres). Although isolated e(1) micromeres will spontaneously generate comb plates, cell deletion experiments have shown that no comb plates appear during embryogenesis following the removal of e(1) descendents. Thus, the m(1) lineage requires the inductive interaction of the e(1) lineage to contribute to comb plate formation. Here we show that, although m(12) cells are normally the only m(1) derivatives to contribute to comb plate formation, m(11) cells are capable of generating comb plates in the absence m(12) cells. The reason that m(11) cells do not normally make comb rows may be attributable either to their more remote location relative to critical signaling centers (e.g., e(1) descendants) or to inhibitory signals that may be provided by other nearby cells such as sister cells m(12). In addition, we show that the signals provided by the e(1) lineage are not sufficient for m(1)-derived comb plate formation. Signals provided by endomesodermal progeny of either the E or the M lineages (the 3E or 2M macromeres) are also required.     

Monitoring mouse prostate development by profiling and imaging mass spectrometry

Mass spectrometry-based tissue profiling and imaging are technologies that allow identification and visualization of protein signals directly on thin sections cut from fresh frozen tissue specimens. These technologies were utilized to evaluate protein expression profiles in the normal mouse prostate during development (1-5 weeks of age), at sexual maturation (6 weeks of age), and in adult prostate (at 10, 15, or 40 weeks of age). The evolution of protein expression during normal prostate development and maturation were subsequently compared with 15-week prostate tumors derived from genetically engineered mice carrying the Large T antigen gene under regulation of the prostate-specific probasin promoter (LPB-Tag mouse model for prostate cancer). This approach identified proteins differentially expressed at specific time points during prostate development. Furthermore expression of some of these proteins, for example probasin and spermine-binding protein, were associated with prostate maturation, and prostate tumor formation resulted in their loss of expression. Cyclophilin A, a protein found in other cancers, was differentially alpha-acetylated on the N terminus, and both isoforms appeared during normal prostate and prostate tumor development. Imaging mass spectrometry localized the protein signals to specific prostatic lobes or regions. Thus, tissue profiling and imaging can be utilized to analyze the ontogeny of protein expression during prostate morphogenesis and tumorigenesis and identify proteins that could potentially serve as biomarkers for prostate cancer.     

家蚕免疫稳态调控分子的鉴定和表达模式分析

昆虫免疫稳态的维持有赖于准确地激活和有效地抑制Toll或IMD信号通路中的关键转录因子-- Dorsal/Dif或Relish。在果蝇等昆虫中, 已报道了多种降低转录因子稳定性和活性的免疫稳态调控分子, 突变或敲除这类分子导致免疫系统的过度激活。对家蚕Bombyx mori免疫信号通路的研究中, 至今为止尚无对这类分子的探索。本研究通过比较基因组学, 在家蚕基因组中鉴定了多个可能参与免疫稳态调控的分子, 包括Wnt家族成员、 Ubc9、 FAF和POSH等; 并通过检测家蚕被微生物感染后这些分子在多种免疫器官中的诱导表达模式, 发现这些分子的表达水平在微生物感染后普遍呈下降趋势, 虽然在某些组织中表达量有明显的升高（>1.5倍）, 但此高表达水平均不能维持且迅速下降; 而且免疫稳态调控分子和受其调控的信号通路的对应关系在不同组织中表现出差异。本研究是首次对家蚕免疫稳态调控分子的报道, 为深入研究家蚕免疫负调控的分子机制提供了参考。     

Induction of tubules in rat metanephrogenic mesenchyme in the absence of an inductive tissue

Differentiation of metanephrogenic mesenchyme to renal tubular epithelium requires induction by the ureteric bud in vivo or any of several embryonic tissues in vitro. In an effort to eliminate the tissue requirement in embryonic induction, extracellular matrices and soluble factors were analyzed individually or in combination for their ability to stimulate tubulogenesis in uninduced metanephrogenic mesenchyme from 13-gestation-day rat embryos. These evaluations have established that pituitary extract and epidermal growth factor (EGF) in concert with a matrix can promote morphogenesis of mesenchymal rudiments in culture. While type I collagen, laminin, or fibronectin matrices all promoted tubulogenesis in the presence of pituitary extract and EGF, type IV collagen proved the most effective. Under these conditions, tubules were induced in 23/24 mesenchymal rudiments by 9 days in culture. Mesenchyme was not induced prior to explanation since it formed no tubules when cultured in a medium that allowed tubulogenesis in intact embryonic kidneys. Preliminary characterization of the undefined factor in pituitary extract was consistent with a protein of molecular weight greater than 100,000 but less than 300,000. When uninduced metanephrogenic mesenchyme from mouse was used instead of rat tissue, a similar pattern of morphogenesis was not observed, suggesting that the described medium is inappropriate for promoting differentiation in mouse or, less likely, that different mechanisms mediate differentiation in rat and mouse. These studies show that embryonic induction can occur in explanted rat renal mesenchyme in an appropriate environment and does not require the presence of an inductive tissue.