The interplay between morphogens and tissue growth

Morphogens are conserved, secreted signalling molecules that regulate the size, shape and patterning of animal tissues and organs. Recent experimental evidence has emphasized the fundamental role of tissue growth in expanding the expression domains of morphogens and their target genes, in generating morphogen gradients and in modulating the response of cells to morphogens. Moreover, the classic view of how morphogens, particularly through their concentration gradient, regulate tissue size during development has been revisited recently. In this review, we discuss how morphogens and tissue growth affect each other, and we attempt to integrate genetic and molecular evidence from vertebrate and invertebrate model systems to put forward the idea that the interaction between growth and morphogens is a general feature of highly proliferative tissues.     

Longitudinal axon guidance

Our knowledge about molecular mechanisms underlying axon guidance along the antero-posterior axis in contrast to the dorso-ventral axis of the developing nervous system is very limited. During the past two years in vitro and in vivo studies have indicated that morphogens have a role in longitudinal axon guidance. Morphogens are secreted proteins that act in a concentration-dependent manner on susceptible groups of precursor cells and induce their differentiation to a specific cell fate. Thus, gradients of morphogens are responsible for the appropriate patterning of the nervous system during early phases of neural development. Therefore, it was surprising to find that gradients of two of these morphogens, Wnt4 and Shh, can be re-used for longitudinal axon guidance during later stages of nervous system development.     

大口黑鲈amh基因全长cDNA克隆、表达及多克隆抗体制备

为研究大口黑鲈(Micropterus salmoides)抗缪勒氏管激素(amh)基因的表达及其在性腺发育中的潜在作用,研究利用RACE技术克隆得到了大口黑鲈amh基因,并制备Amh多克隆抗体,通过qRT-PCR、Western Blot分析Amh在大口黑鲈不同组织和不同发育阶段性腺中的表达模式,最后利用HE染色法和免疫组化观察不同发育阶段性腺的形态组织学变化及其与Amh表达的潜在关系。结果显示:大口黑鲈amh基因cDNA序列全长2050 bp,由24 bp5′非编码区、394 bp3′非编码区和1632 bp的开放阅读框组成,共编码543个氨基酸。amh基因mRNA在大口黑鲈11个组织中均有表达,其中雄鱼精巢中表达量最高,肌肉次之,雌鱼卵巢中表达量最高,肌肉次之。amh基因在雌雄鱼不同发育阶段的性腺中表达存在显著差异,精巢中表达量均显著高于卵巢(P<0.05)。同时, Western Blot结果显示Amh蛋白在精巢中表达丰度较高。amh基因在精巢中的表达量呈先上升后下降的趋势,且在孵化后65d鱼精巢中其表达量达到最高(P<0.05),免疫组化结果显示Amh表达于早期精...     

Evidence for gonadotropin-releasing hormone peptides in the ovary and testis of rainbow trout.

GnRH is usually classified as a neuropeptide that is synthesized in the brain. Recent evidence indicates that GnRH mRNA is present also in the ovary and testis. However, isolation of the peptide from testis has not been reported. We used HPLC and specific RIAs to determine whether the GnRH peptide can be detected in gonads, the developmental stage at which the peptide is expressed, and the number of molecular forms of GnRH that are present in the ovary and testis. Extracts of immature and mature ovarian and testicular tissue were examined from 17- to 21-mo-old rainbow trout (Oncorhynchus mykiss). For the first time, GnRH peptides were isolated from testis and identified by HPLC-RIA with specific antisera and by elution position compared with synthetic standards. GnRH peptides were also present in the ovary. In addition, multiple forms of GnRH, including a form not normally detected in the brain of trout, were shown to be present in the gonads. During development, GnRH peptides were expressed only at specific stages in the gonads, which may explain the inability to detect and isolate the GnRH peptides from gonads in earlier studies.     

Zebrafish CTH1, a C3H zinc finger protein, is expressed in ovarian oocytes and embryos

 The Zfcth1 gene is, as the previously cloned carp cth1 gene, related to the mammalian TIS 11 family of primary response genes and encodes a protein with two putative CCCH zinc fingers. This report describes the RNA expression of this gene during oogenesis and early embryogenesis up to gastrulation in the zebrafish (Danio rerio). Maternal cth1 message is present in the ovary of 1-month-old fish and of adult fish in oocytes at all stages of maturation. In the youngest oocytes the message is localized in the cytoplasm all around the nucleus, in larger oocytes the message becomes restricted to the future animal pole of the embryo, and in mature oocytes the expression is sharply localized in the cortical layer under the micropyle. After ovulation the cth1 messenger spreads over the cytoplasmic cap and is distributed over the blastomeres during subsequent cleavages. In subsequent stages maternal expression of cth1 gradually disappears. From early epiboly stages onward embryonic cth1 expression is localized to the germ ring and the hypoblast cells in the central part of the embryonic shield. In the shield, cth1 expression largely overlaps with the area of gooscoid expression in the first involuting cells. In stages after 70% of epiboly cth1 expression diminishes and soon can no longer be detected in the embryo. Next to a developmental role in cell fate determination we propose a function for cth1 during oocyte maturation. Received: 19 October 1998 / Accepted: 16 February 1999