Induction of sweat glands by epidermal growth factor in murine X-linked anhidrotic ectodermal dysplasia

Tabby (Ta), a murine X-linked mutant gene, produces a syndrome of ectodermal dysplasia including anhidrosis (absence of sweat glands). Development of sweat glands is related to that of dermal ridges (dermatoglyphics) and abnormal ridges may be associated with absence of sweat glands in the human syndrome of hypohidrotic ectodermal dysplasia (HED). We have found that dermal ridges occur in normal mice but are lacking in Ta mutants. Previously we showed that epidermal growth factor (EGF) reverses delayed eyelid opening and incisor eruption in Ta mice. We now report that EGF induces development of dermal ridges and functional sweat glands in Ta/Y hemizygotes, indicating a role in mammalian morphogenesis. Ta seems to be genetically homologous to human X-linked HED, as Ta maps close to loci homologous to linkage markers of HED and the two syndromes share many traits, including absence of all or most sweat glands. Absence of these glands causes hyperpyrexia, a clinical emergency in infants with HED; reversal of the trait in the mouse homologue of the disease indicates that an important genetically determined congenital defect in humans may become treatable.     

Functions of FGF signalling from the apical ectodermal ridge in limb development

To determine the role of fibroblast growth factor (FGF) signalling from the apical ectodermal ridge (AER), we inactivated Fgf4 and Fgf8 in AER cells or their precursors at different stages of mouse limb development. We show that FGF4 and FGF8 regulate cell number in the nascent limb bud and are required for survival of cells located far from the AER. On the basis of the skeletal phenotypes observed, we conclude that these functions are essential to ensure that sufficient progenitor cells are available to form the normal complement of skeletal elements, and perhaps other limb tissues. In the complete absence of both FGF4 and FGF8 activities, limb development fails. We present a model to explain how the mutant phenotypes arise from FGF-mediated effects on limb bud size and cell survival.     

Nanoindentation. Simulation of defect nucleation in a crystal

Nanoindentation is the penetration of a surface to nanometre depths using an indenting device. It can be simulated using the Bragg bubble-raft model, in which a close-packed array of soap bubbles corresponds to the equilibrium positions of atoms in a crystalline solid. Here we show that homogeneous defect nucleation occurs within a crystal when its surface roughness is comparable to the radius of the indenter tip, and that the depth of the nucleation site below the surface is proportional to the half-width of the contact. Our results may explain the unusually high local stress required for defect nucleation in nano-indented face-centred cubic crystals.     

Suppression of a myosin defect by a kinesin-related gene.

Motor proteins in cells include myosin, which is actin-based, and kinesin, dynein and dynamin, which are microtubule-based. Several proteins have recently been identified that have amino-acid sequences with similarity to the motor domains of either myosin or kinesin, but are otherwise dissimilar. This has led to the suggestion that these may all be motor proteins, but that they are specialized for moving different cargos. Genetic analysis can address the question of the different functions of these new proteins. Studies of a temperature-sensitive mutation (myo2-66) in a gene of the myosin superfamily (MYO2) have implicated the Myo2 protein (Myo2p) in the process of polarized secretion in yeast (Saccharomyces cerevisiae). To understand more about the role of Myo2p, we have looked for 'multicopy suppressors' (heterologous genes that, when overexpressed, can correct the temperature sensitivity of the myo2-66 mutant). Here we report the identification of such a suppressor (SMY1) that (surprisingly) encodes a predicted polypeptide sharing sequence similarity with the motor portion of proteins in the kinesin superfamily.     

Linking a genetic defect to its cellular phenotype in a cardiac arrhythmia.

Advances in genetics and molecular biology have provided an extensive body of information on the structure and function of the elementary building blocks of living systems. Genetic defects in membrane ion channels can disrupt the delicate balance of dynamic interactions between the ion channels and the cellular environment, leading to altered cell function. As ion-channel defects are typically studied in isolated expression systems, away from the cellular environment where they function physiologically, a connection between molecular findings and the physiology and pathophysiology of the cell is rarely established. Here we describe a single-channel-based Markovian modelling approach that bridges this gap. We achieve this by determining the cellular arrhythmogenic consequences of a mutation in the cardiac sodium channel that can lead to a clinical arrhythmogenic disorder (the long-QT syndrome) and sudden cardiac death.     

Genetic hypertension in rats is accompanied by a defect in renal prostaglandin catabolism.

Noradrenaline releases prostaglandins in the kidney, and in rats these augment rather than reduce vasoconstriction produced by the amine. Homogenates of kidneys of New Zealand rats inbred for hypertension exhibit lower prostaglandin inactivation by 15-hydroxydehydrogenase than controls. At the same time, augmentation of noradrenaline vasoconstriction by the released prostaglandin is exaggerated. This biochemical defect could be the inherited abnormality primarily responsible for the development of hypertension in these animals.     

Ganglion cell death during development of ipsilateral retino-collicular projection in golden hamster

In rats and hamsters all parts of the superior colliculus (SC) receive a topographically organized projection from the retina of the contralateral eye, and the rostral part also has a direct input from the lower temporal crescent of the ipsilateral retina, which views the central, binocular portion of the visual field. Initially the uncrossed projection covers the entire SC, but over the first 2 weeks of postnatal life it becomes progressively restricted to its adult distribution. However, if the opposite eye is removed at birth there is a persistent widespread uncrossed projection to the SC. We have used short- and long-term retrogradely transported neuronal markers to examine the distribution and fate of the ganglion cells of origin of the uncrossed retino-collicular projection throughout postnatal development. We conclude that the withdrawal of the early exuberant projection to the caudal SC is associated with death of ganglion cells and their virtual elimination outside the temporal crescent of the ipsilateral retina. Early enucleation of the other eye rescues many of these cells.     

Mutations in the channel domain alter desensitization of a neuronal nicotinic receptor.

A variety of ligand-gated ion channels undergo a fast activation process after the rapid application of agonist and also a slower transition towards desensitized or inactivated closed channel states when exposure to agonist is prolonged. Desensitization involves at least two distinct closed states in the acetylcholine receptor, each with an affinity for agonists higher than those of the resting or active conformations. Here we investigate how structural elements could be involved in the desensitization of the acetylcholine-gated ion channel from the chick brain alpha-bungarotoxin sensitive homo-oligomeric alpha 7 receptor, using site-directed mutagenesis and expression in Xenopus oocytes. Mutations of the highly conserved leucine 247 residue from the uncharged MII segment of alpha 7 suppress inhibition by the open-channel blocker QX-222, indicating that this residue, like others from MII, faces the lumen of the channel. But, unexpectedly, the same mutations decrease the rate of desensitization of the response, increase the apparent affinity for acetylcholine and abolish current rectification. Moreover, unlike wild-type alpha 7, which has channels with a single conductance level, the leucine-to-threonine mutant has an additional conducting state active at low acetylcholine concentrations. It is possible that mutation of Leu 247 renders conductive one of the high-affinity desensitized states of the receptor.     

基因组中基因间的关联

根据基因中核苷关联短程为主性（Ｄ２为主）的概念,通过比较基因间的Ｄ２,定义基因组中的基因关联Ｆ,Ｆ取值的主要范围为０和１间,Ｆ￣１ 强关联,Ｆ￣０表示关联是无规的,以酵母基因组为例,研究了酵母各条染色体上的基因关联,发现Ｆ的最可几值一般在０．８￣０．９,证明了基因间存在较强的关联,比较编码区和非编码区,发现非编码区间的关联,非编区和编码区的关联编码区间的磁联为弱,Ｆ值低１０％左右。     

Phagocytosis promotes programmed cell death in C. elegans.

In the nematode Caenorhabditis elegans programmed cell death requires the killer genes egl-1, ced-4 and ced-3 (refs 1 and 2), and the engulfment of dying cells requires the genes ced-1, ced-2, ced-5, ced-6, ced-7, ced-10 and ced-12 (refs 3,4,5). Here we show that engulfment promotes programmed cell death. Mutations that cause partial loss of function of killer genes allow the survival of some cells that are programmed to die, and mutations in engulfment genes enhance the frequency of this cell survival. Furthermore, mutations in engulfment genes alone allow the survival and differentiation of some cells that would normally die. Engulfment genes probably act in engulfing cells to promote death, as the expression in engulfing cells of ced-1, which encodes a receptor that recognizes cell corpses, rescues the cell-killing defects of ced-1 mutants. We propose that engulfing cells act to ensure that cells triggered to undergo programmed cell death by the CED-3 caspase die rather than recover after the initial stages of death.     

Four-helical-bundle structure of the cytoplasmic domain of a serine chemotaxis receptor.

The bacterial chemotaxis receptors are transmembrane receptors with a simple signalling pathway which has elements relevant to the general understanding of signal recognition and transduction across membranes, how signals are relayed between molecules in a pathway, and how adaptation to a persistent signal is achieved. In contrast to many mammalian receptors which signal by oligomerizing upon ligand binding, the chemotaxis receptors are dimeric even in the absence of their ligands, and their signalling does not depend on a monomer-dimer equilibrium. Bacterial chemotaxis receptors are composed of a ligand-binding domain, a transmembrane domain consisting of two helices TM1 and TM2, and a cytoplasmic domain. All known bacterial chemotaxis receptors have a highly conserved cytoplasmic domain, which unites signals from different ligand domains into a single signalling pathway to flagella motors. Here we report the crystal structure of the cytoplasmic domain of a serine chemotaxis receptor of Escherichia coli, which reveals a 200 A-long coiled-coil of two antiparallel helices connected by a 'U-turn'. Two of these domains form a long, supercoiled, four-helical bundle in the cytoplasmic portion of the receptor.     

Crystal structure of a Src-homology 3 (SH3) domain.

The Src-homologous SH3 domain is a small domain present in a large number of proteins that are involved in signal transduction, such as the Src protein tyrosine kinase, or in membrane-cytoskeleton interactions, but the function of SH3 is still unknown (reviewed in refs 1-3). Here we report the three-dimensional structure at 1.8 A resolution of the SH3 domain of the cytoskeletal protein spectrin expressed in Escherichia coli. The domain is a compact beta-barrel made of five antiparallel beta-strands. The amino acids that are conserved in the SH3 sequences are located close to each other on one side of the molecule. This surface is rich in aromatic and carboxylic amino acids, and is distal to the region of the molecule where the N and C termini reside and where SH3 inserts into the alpha-spectrin chain. We suggest that a protein ligand binds to this conserved surface of SH3.     

Genetic defect in secretion of complement C5 in mice.

A genetic deficiency of the fifth (C5) component of complement1-3, a serum glycoprotein of molecular weight (MW) 220,000 (ref. 4), has been found in 39% of inbred strains of mice3. Sera of deficient mice lack detectable C5 activity and protein2,3. In addition deficient mice produce antibody to mouse C5 when injected with sera from C5 sufficient (normal) strains. Levy et al.5 showed that somatic cell hybrids between C5 deficient (B10.D2/old line) macrophages and either C5 sufficient (B10.D2/new line) mouse kidney or chicken erythroblasts secreted haemolytically active mouse C5 in vitro. Several possible molecular mechanisms to account for the findings were considered, but insufficient direct data were available to choose among them. We recently reported that mouse (CD.1 strain) peritoneal cells in culture synthesise and secrete a single chain precursor, pro-C5 (MW approximately 210,000), of the two-chain (alpha chain, 125,000 and beta chain 83,000 MW) C5 protein6. Radiolabelled precursor C5 was contained within the cells and was secreted into the tissue culture media. Using similar methods, we now find that C5 deficiency in each of five different mouse strains (AKR, SWR, DBA/2J8 A/HeJ and B10.D2/old line) is due to a failure in secretion of C5 protein and not to a failure in biosynthesis of pro-C5.