BioEssays

doi: 10.1002/bies.950150401pmid: N/A

doi: 10.1002/bies.950150414pmid: N/A

Bronner‐Fraser, Marianne

doi: 10.1002/bies.950150402pmid: 8517851

Neural crest cells are remarkable in their extensive and stereotypic patterns of migration. The pathways of neural crest migration have been documented by cell marking techniques, including interspecific neural tube grafts, immunocytochemistry and Dil‐labelling. In the trunk, neural crest cells migrate dorsally under the skin or ventrally through the somites, where they move in a segmental fashion through the rostral half of each sclerotome. The segmental migration of neural crest cells appears to be prescribed by the somites, perhaps by an inhibitory cue from the caudal half. Within the rostral sclerotome, neural crest cells fill the available space except for a region around the notochord, suggesting the notochord may inhibit neural crest cells in its vicinity. In the cranial region, antibody perturbation experiments suggest that multiple cell‐matrix interactions are required for proper in vivo migration of neural crest cells. Neural crest cells utilize integrin receptors to bind to a number of extracellular matrix molecules. Substrate selective inhibition of neural crest cell attachment in vitro by integrin antibodies and antisense oligonucleotides has demonstrated that they possess at least three integrins, one being an α1β1 integrin which functions in the absence of divalent cations. Thus, neural crest cells utilize complex sets of interactions which may differ at different axial levels.

Hong, Wanjin; Tang, Bor Luen

doi: 10.1002/bies.950150403pmid: 8517852

Proteins of the exocytotic (secretory) pathway are initially targeted to the endoplasmic reticulum (ER) and then translocated across and/or inserted into the membrane of the ER. During their anterograde transport with the bulk of the membrane flow along the exocytotic pathway, some proteins are selectively retained in various intracellular compartments, while others are sorted to different branches of the pathway. The signals or structural motifs that are involved in these selective targeting processes are being revealed and investigations into the mechanistic nature of these processes are actively underway.

Tata, Jamshed R.

doi: 10.1002/bies.950150404pmid: 8517853

The precocious induction in vivo and in culture of insect and amphibian metamorphosis by exogenous ecdysteroids and thyroid hormones, and its retardation or inhibition by juvenile hormone and prolactin, respectively, has allowed the analysis of such diverse processes of post‐embryonic development as morphogenesis, tissue remodelling, functional reorganization, and programmed cell death. Metamorphosis in vertebrates also shares many similarities with mammalian development in the late foetal and perinatal period. This review describes the regulation of expression of some of the ‘adult’ gene products during metamorphosis in invertebrates and vertebrates. Recent studies on metamorphosis have revealed the important role played by auto‐induction of hormone receptor genes, based on which a model will be presented to explain the activation of ‘downstream’ genes which give rise to the adult phenotype. It will also be argued that metamorphosis is an ideal model for analyzing some of the major mechanisms governing post‐embryonic development.

Weeda, Geert; Hoeijmakers, Jan H. J.; Bootsma, Dirk

doi: 10.1002/bies.950150405pmid: 8517854

The maintenance of genetic integrity is of vital importance to all living organisms. However, DNA – the carrier of genetic information – is continuously subject to damage induced by numerous agents from the environment and endogenous cellular metabolites. To prevent the deleterious consequences of DNA injury, an intricate network of repair systems has evolved. The biological impact of these repair mechanisms is illustrated by a number of genetic diseases that are characterized by a defect in one of the repair machineries and in general predispose individuals to cancer. This article intends to review our current understanding of the complex nucleotide excision repair pathway, a universal repair system with a broad lesion specificity. Emphasis will be on the recent advances in the genetic analysis of this process in mammalian cells.

Leese, Henry J.; Conaghan, Joe; Martin, Karen L.; Hardy, Kate

doi: 10.1002/bies.950150406pmid: 8517855

Non‐invasive microanalytical methods have been devised to study the energy metabolism of single human preimplantation embryos. Psyruvate, which is added routinely to all media used to culture human embryos, is consumed throughout the preimplantation period, with glucose assuming an increasing role at embryo compaction and blastocyst formation. All of the glucose consumed may be accounted for by the appearance of lactate in the incubation medium. The enzyme hexokinase my be involved in regulating this aerobic glycolysis. There is cosiderable indirect evidence for the utilisation of endogenous as opposed to exogenous energy substrates, the most likely candidate being protein. Information on early human embryo metabolismis likely to find application in a number of areas: these include the improvement of techniques for assisted human conception, notably in the selection of embryos for transfer following In Vitro Fertilisation; the diagnosis of gentic defects at the preimplantation stage; increased undersding of the causes of implantation failure and miscarriage, and the development of novel post‐coital contraceptives.

Anderson, Garth R.; Stoler, Daniel L.

doi: 10.1002/bies.950150407pmid: 8390832

Although VL30 retrotransposable elements have been associated with certain cancers for nearly twenty years, because of their expression in rodent malignancies and recombination into murine sarcoma viruses, their causative role, if any, in cancer has been uncertain and enigmatic. Recent findings suggest loss of normal transcriptional control of specific VL30 element expression may make a critical contribution to tumor progression at a step associated with malignant conversion, by bringing into play a cellular program normally involved in wound healing. This program, the fibroblast anoxic response system, includes an adaptation to glycolytic metabolism, secretion of metalloproteinases, and activation of an endonuclease. While appropriate for facilitating debris removal during wound healing, loss of control of this program in a cell which has already progressed to the benign neoplastic state has the potential to simultaneously produce the invasiveness and genomic instability charateristic of malignancy. Examination of tumors and tumor derived cell lines has confirmed that key aspects of this system are in fact activated in cancer.

Davis, Ann; Bradley, Allan

doi: 10.1002/bies.950150408pmid: 8517856

Oncogenesis is manifested as uncontrolled cellular proliferation and in some situations a failure of normal differentiation in the transformed cell. This has led to speculation that the normal role of proto‐oncogenes during development may be to mediate the relationship between proliferation and differentiation. The advent of gene targeting in ES cells allows the role oncogenes in development to be tested directly. Two recent studies have examined the phenotype of N‐myc mutant mice generated by gene targeting(1,2). In both reports, the mutation is an embryonic lethal at 11.5 days of gestation confirming a critical role for this proto‐oncogene in development and the inability of other members of the myc family to substitute functionally for N‐myc. Although the phenotypes are similar in general outline, the two reports differ in the specifics of the morphological and histological abnormalities identified. The disparity may result from the mutation created, the genetic background of the mutant mice or the criteria used to determine abnormalities. Assuredly, there is valuable information to be gained about N‐myc function from these mutant mice. However, these reports make it clear that morphological and histological abnormalities in N‐myc mutant mice serve as a starting point rather than as an endpoint. The challenge now is to link the defect at the cellular level to the abnormalities at the physiological level.

Newman, Stuart A.

doi: 10.1002/bies.950150409pmid: 8100133

When two populations of cells within a tissue mass differ from one another in magnitude or type of intercellular adhesions, a boundary can form within the tissue, across which cells will fail to mix. This phenomenon may occur regardless of the identity of the molecules that mediate cell adhesion. If, in addition, a choice between the two adhesive states is regulated by a molecule the concentration of which is periodic in space, or in time, then alternating bands of non‐mixing tissue, or segments, can form. But temporal or spatial periodicities in concentration will tend to arise for any molecule that is positively autoregu‐latory. It is therefore proposed that segmentation is a ‘generic’ property of metazoan organisms, and that metamerism would be expected to have emerged numerous times during evolution. A simple model of segmentation, based solely on differential adhesion and periodic regulation of adhesion, can account for segment properties as disparate as those seen in long and short germ band insects, and for diverse experimental results on boundary regeneration in the chick hind brain and the insect cuticle. It is suggested that the complex, multicom‐ponent segment‐forming systems found in contemporary organisms (e.g., Drosophila) are the products of evolutionary recruitment of molecular cues such as homeobox gene products, that increase the reliability and stability of metameric patterns originally templated by generic self‐organizing properties of tissues.