Role of the α1β1 integrin complex in collagen gel contraction in vitro by fibroblasts

Matrix remodeling, critical to embryonic morphogenesis and wound healing, is dependent on the expression of matrix components, their receptors, and matrix proteases. The collagen gel assay has provided an effective model for the examination of the functional role(s) of each of these groups of molecules in matrix remodeling. Previous investigations have indicated that collagen gel contraction involves the β1 integrin family of matrix receptors and is stimulated by several growth factors, including TGF-β, PDGF, and angiotensin II. In particular, collagen gel remodeling by human cells involves the α2β1 and, to a lesser extent the α1β1 integrin complexes. The present studies were undertaken to determine the role of the α1 integrin chain, a collagen/laminin receptor, in collagen gel contration by rodent and avian fibroblasts. A high degree of correlation was found between the expression of the α1β1 integrin complex and the relative ability of cells to contract collagen gels. Further studies using antibodies and antisense oligonucleotides against the α1 integrin indicated a significant role for this integrin chain in contraction of collagen gels by rat cardiac fibroblasts. In addition, antibodies to the α1 integrin chain inhibited migration of these fibroblasts on a collagen substratum, suggesting that at least one role of this integrin is in migration of cells in collagen gels. These results indicate that the α1β integrin complex plays a significant role in cellular interactions with interstital collagen that are involved in matrix remodeling such as is seen during morphogenesis and wound healing. © 1995 Wiley-Liss, Inc.     

Epitope mapping of two isoforms of a trans Golgi network specific integral membrane protein TGN38/41.

TGN38/41 is an integral membrane protein predominantly located in the trans Golgi network (TGN) of rat (NRK) cells. We have used a cDNA expression system to map the epitopes recognised by a panel of antibodies raised to TGN38/41 as a preliminary step in the accurate identification of the region(s) of the molecule responsible for its correct intracellular location. These studies have confirmed the predicted topology of the molecule, and have identified a region in the cytoplasmic domain which is immunologically (and hence potentially functionally) conserved between species.     

Ultrastructural immunocytochemical characterization of isotocin,vasotocin and neurophysin neurons in the magnocellular preoptic nucleus of the goldfish

Summary We describe the ultrastructural localization of isotocin, vasotocin and neurophysin in the magnocellular preoptic nucleus of the goldfish. With the aid of immunocytochemical techniques, we see staining both in classical neurosecretory granules and in diffuse agranular form throughout somata and processes. Signs of cellular and synaptic interactions between chemically identified neurons include axon terminals which contain vasotocin immunoreactivity and membrane specializations (puncta adhaerentia) between adjacent somata. Our investigations provide an anatomical basis for neuroendocrine and neurotransmitter-like functions of peptidergic neurons in the teleost preoptic nucleus.     

Control of P1 plasmid replication by iterons

The incA locus of plasmid P1 controls plasmid copy number by inhibiting the replication origin, oriR . Both loci contain repeat sequences (iterons) that bind the P1 RepA protein. Regulation appears to occur by contact of incA and oriR loci of daughter plasmids mediated by RepA-bound iterons. Synthetic incA iteron arrays were constructed with altered numbers, sequences or spacing of iterons. Using these in in vitro and in vivo assays, we examined two models: (i) that the origin and incA loci form a stable 1:1 complex in which multiple iterons of each locus are paired with those of the other, and (ii) that individual incA iterons act as freely diffusing nucleoprotein units that contact origin iterons in a random and dynamic fashion. The data presented here strongly favour the latter case. The origin, with its five iterons, acts as a target but not as an effector of regulation. We present a model for replication control based on random, dynamic contacts between incA iterons and the origin. This system would display randomness with respect to choice of templates and timing of initiation if multiple replicon copies were present, but would tend to act in a machine-like fashion in concert with the cell cycle if just two copies were present in a dividing cell.