Aberrant gene expression in cultured mammalian bone cells demonstrates an osteoblast defect in osteopetrosis

Osteopetrosis is a skeletal condition in which a generalized radioopacity of bone is caused by reduced resorption of bone by osteoclasts. However, it has recently been shown that during skeletal development in several osteopetrotic rat mutations specific aberrations occur in gene expression reflecting the activity of the bone forming cells, osteoblasts, and the development of tissue organization. To evaluate their pathogenetic significance, progressive osteoblast differentiation was studied in vitro. Primary cultures of normal osteoblasts undergo a sequential expression a cell growth and tissue-related genes associated with development of skeletal tissue. We report that osteoblast cultures can be established from one of these mutants, toothless; that these cells in vitro exhibit similar aberrations in gene expression during cell proliferation and extracellular matrix formation and mineralization observed in vivo; and that an accelerated maturation sequence by mutant osteoblasts mimics the characteristic skeletal sclerosis of this disease. These data are the first direct evidence for an intrinsic osteoblast defect in osteopetrosis and establish an in vitro model for the study of heritable skeletal disorders. © 1994 Wiley-Liss, Inc.     

南疆束颈蝗属二新种：蝗总科：斑翅蝗科

本文记述采自新疆南部地区束颈蝗属二新种,叶城束颈蝗Ｓｐｈｉｎｇｏｎｏｔｕｓｙｅｃｈｅｎｇｅｎｓｉｓ ｓｐ．ｎｏｖ．及塔克拉玛束颈蝗Ｓｐｈｉｎｇｏｎｏｔｕｓ ｔａｋｒａｍａｅｎｓｉｓ ｓｐ．ｎｏｖ．模式标本保存于陕西范大学动物研究所标本室。     

The replication map of the chromosome ofMycobacterium phlei

It was the aim of the present work to construct the replication map of the chromosome ofMycobacterium phlei. The method of mutagenesis of the replication point by N-methyl-N-nitroso-N’-nitroguanidine in synchronously dividing populations and the method of analysis of gene frequency were applied. The order of replication of 19 genes on the chromosome was determined by means of induction of back mutations and forward mutations in auxotrophic mutants PAleu and PAmet and in double auxotrophic mutants with methionine as a reference marker.     

The vitamin K-dependent synthesis of gamma-carboxyglutamic acid by bone microsomes

Microsomes prepared from embryonic chick bone contain a vitamin K-dependent carboxylating system which post-translationally converts glutamic acid residues in peptides to gamma-carboxyglutamic acid (gamma-CGlu). Glutamic acid residues in both endogenous chick bone microsomal protein and in the synthetic peptide Phe Leu-Glu-Glu-Val are gamma-carboxylated. These data suggest that bone cells have the capacity for de novo gamma-CGlu synthesis and may be responsible for synthesis of osteocalcin, the major gamma-CGlu protein in bone.     

Use of spin label and the flow-induced ESR spectral difference for studying erythrocyte deformation

ESR spin-labeling method is expanded to measure the macroscopic visco-elastic properties of erythrocytes. A suspension of erythrocytes with an incorporated fatty acid spin label was forced to flow through a flat ESR sample cells, and the ESR spectral change caused by the shear flow was utilized to assess the cell deformability. Chemical cross-linking or heat denaturation of membrane proteins to make the cells less deformable without any morphological change was found to reduce the relative spectral difference (delta h/h). This result indicates that the spectral difference is related to the cell deformation that accompanies the orientation of the cells in the shear flow. In addition, the average decay time (tau av) for the spectral difference observed when the flow was abruptly interrupted became shorter with an increase in the degree of cross-linking or heat-denaturation abruptly interrupted became shorter with an increase in the degree of cross-linking or heat-denaturation at 49 degrees C. Since the observed tau av is much shorter than the expected rotational correlation time for the erythrocyte, the decay is attributed to the deformation recovery process. It is demonstrated that the measurements of both delta h/h and tau av by ESR spectroscopy give qualitative information on the viscosity and the elasticity of the cell membrane system.     

Use of nalidixic acid for constructing the replication map of theMycobacterium phlei chromosome

Nalidixic acid was used for describing more accurately the terminal replication region of theMycobacterium phlei chromosome. Cell division in synchronized cultures was not sensitive to this acid any more between 185–190 min,i.e. about 10 min after replication of theser gene the last of 24 genes of the replication map described so far. The replication of the chromosome was controlled by determining the position of thebac gene. Microscopic studies in phase contrast of the cells that were subjected for long time periods to nalidixic acid treatment at a bactericidal concentration showed elongated cells. The electron-microscopic observation showed that a portion of the population influenced by nalidixic acid lyzes, whereas other cells remain intact and resemble control cells.     

Calcium ion effects on guanylate cyclase of brain.

Soluble guanylate cyclase activity of brain is stimulated by Ca²⁺ in the presence of low concentrations of Mn²⁺. Unlike Ca²⁺ stimulation of adenylate cyclase, the effect does not depend upon interaction of guanylate cyclase with a specific high-affinity Ca²⁺-binding protein. In the presence of Mg²⁺, Ca²⁺ inhibits soluble guanylate cyclase as well as the particulate enzyme. The concept that stimulation of brain cells results in increased cyclic GMP concentration secondary to Ca²⁺ influx merits additional critical study.     

Widespread differentiation stage-specific expression of the gene encoding phosphoprotein p19 (metablastin) in mammalian cells

p19 is a highly conserved 19 kD cytosolic protein that undergoes phosphorylation in response to diverse extracellular factors in mammalian cells. Its expression is abundant in brain and testis and is developmentally regulated. To gain insights regarding its function, we analyzed the expression of p19 mRNA in a variety of cell types during induction of differentiation. Murine erythroleukemia cells showed a moderate increase followed by a marked decrease in the abundance of p19 mRNA during induction of differentiation. In murine C2 myoblasts and primary fetal rat osteoblasts, p19 mRNA was abundant in replicating cells and decreased to undetectable levels during differentiation. In resting human peripheral blood lymphocytes, p19 mRNA was virtually undetectable but was strongly induced during blast transformation of both B and T cells. In rat liver, p19 mRNA was abundant on embryonic day 17 and decreased during early postnatal development. Upon fractionation of adult rat liver cells by centrifugal elutriation, p19 mRNA was not detected in hepatocytes while a low level was observed in a fraction enriched in non-parenchymal epithelial cells. CCl4-induced liver regeneration resulted in induction of p19 mRNA in hepatocytes. Primary cultures of embryonic and neonatal rat brain were analyzed by indirect immunofluorescence using co-staining with stage-specific markers. p19 expression was restricted to immature neurons and oligodendrocyte precursors. In contrast to the other cell types examined, the neuronal and glial precursors that express p19 were shown, using BrdU labeling, to be postmitotic both in primary culture and in vivo. The data demonstrate widespread, stage-specific expression of p19 and suggest that the protein exerts a general, lineage-independent function during induction of differentiation of mammalian cells. In view of the available evidence on the stimulation of serine phosphorylation of p19 by several growth factors, our working hypothesis is that phosphorylation of p19 may be involved in the mechanism by which growth factors control cell differentiation.