Cathepsin K knockout mice develop osteopetrosis due to a deficit in matrix degradation but not demineralization.

Cathepsin K is a cysteine protease expressed predominantly in osteoclasts. Activated cathepsin K cleaves key bone matrix proteins and is believed to play an important role in degrading the organic phase of bone during bone resorption. Mutations in the human cathepsin K gene have been demonstrated to be associated with a rare skeletal dysplasia, pycnodysostosis. The degree of functional activity of the mutated forms of cathepsin K in these individuals has not been elucidated, but is predicted to be low or absent. To study the role of cathepsin K in bone resorption, we have generated mice deficient in the cathepsin K gene. Histologic and radiographic analysis of the mice revealed osteopetrosis of the long bones and vertebrae, and abnormal joint morphology. X-ray microcomputerized tomography images allowed quantitation of the increase in bone volume, trabecular thickness, and trabecular number in both the primary spongiosa and the metaphysis of the proximal tibiae. Not all bones were similarly affected. Chondrocyte differentiation was normal. The mice also had abnormalities in hematopoietic compartments, particularly decreased bone marrow cellularity and splenomegaly. The heterozygous animals appeared normal. Close histologic examination of bone histology revealed fully differentiated osteoclasts apposed to small regions of demineralized bone. This strongly suggests that cathepsin K-deficient osteoclasts are capable of demineralizing the extracellular matrix but are unable to adequately remove the demineralized bone. This is entirely consistent with the proposed function of cathepsin K as a matrix-degrading proteinase in bone resorption.

Cloning and characterization of soluble and transmembrane isoforms of a novel component of the murine type I interferon receptor, IFNAR 2.

This report describes the cloning of cDNAs encoding transmembrane and soluble isoforms of a novel chain of the murine type I interferon (IFN) receptor and characterization of its capability to bind ligand and transduce signals. The transmembrane receptor (murine IFNAR 2c) has an extracellular domain of 215 amino acids and an intracellular domain of 250 amino acids, with 48% amino acid and 71% nucleotide identity with human IFNAR 2c. The cDNA for the soluble murine receptor (IFNAR 2a) encodes a 221-amino acid polypeptide identical to the first 210 amino acids of IFNAR 2c plus a novel 11 amino acids. Northern blot analyses show that murine IFNAR 2 is expressed as two transcripts of 4 kilobases encoding the transmembrane isoform and 1.5 kilobases encoding the more abundant soluble isoform. Studies using primary murine cells that lack IFNAR 1 show that IFNAR 2 is expressed, and cells bind type I IFN ligand, but do not transduce signals as detected by electrophoretic mobility shift assays of ISGF3 or GAF complexes binding to their cognate oligonucleotides. These cells show no effects on the ability of IFNgamma to activate these complexes. These studies demonstrate that the IFNAR 2 transmembrane (2c) and soluble (2a) isoforms are conserved between the human and mouse and that IFNAR 2c has intrinsic ligand binding activity, but no intrinsic signal transducing activity as measured in this study.

Analysis of heat shock protein 70 in human chromosome 21 containing hybrids.

An Hsp70 gene, HspA3, has been given provisional assignment to chromosome 21 based on the heat induced expression of a 70 kDa protein in a Chinese hamster ovary-human hybrid cell line. This assignment has not been supported by hybridization data or by cloning of the gene. The aim of the current study is to clarify this localization. We have analysed a series of Chinese hamster ovary-human hybrid lines containing human chromosome 21 by two-dimensional gel electrophoresis and Western blot analysis with anti-Hsp70 antibodies. Only one of these, hybrid 72532-X6, was found to contain an additional Hsp70 protein. Three other hybrid cell lines spanning different parts of chromosome 21 did not contain any additional Hsp70 proteins. The Hsp70 protein in 72532-X6 is constitutively expressed and is not heat inducible. Southern blot analysis indicates that this protein is not the major human cognate protein, Hsp73 (Hsp70-8), but may be one of the other cognate Hsp70s. Our data indicate that hybrid cell lines containing human chromosome 21 do not express a human Hsp70, as has been reported previously. The recent report that the hybrid cell line used to make this claim also contains other human chromosome fragments leads us to conclude that an Hsp70 gene is not localized on human chromosome.

A hitchhiker's guide to the human Hsp70 family.

The human Hsp70 family encompasses at least 11 genes which encode a group of highly related proteins. These proteins include both cognate and highly inducible members, at least some of which act as molecular chaperones. The location of cognate Hsp70s within all the major subcellular compartments is an indication of the importance of these proteins. The expression of several inducible Hsp70 genes is also an indication of the importance of these proteins in the stress response. The existence of multiple genes and protein isoforms has created confusion in the identification and naming of particular family members. We have compiled, from the literature, a list of genes and genetic loci and produced a two-dimensional protein map of the known human Hsp70 family members. This will enable researchers in the field to quickly and reliably identify human Hsp70s. We have also devised a more rational nomenclature for these genes and gene products which, subject to general acceptance, could be extended to Hsp70 families from other species.

Localization of the gene encoding the human heat shock cognate protein, HSP73, to chromosome 11.

The heat shock cognate protein HSP73 (or HSC70) is a member of the HSP70 multigene family. This protein has several functions, including binding to nascent polypeptides to facilitate correct folding and the uncoating of clathrin-coated vesicles. Analysis of somatic cell hybrids by two-dimensional protein gel electrophoresis revealed the presence of a 73-kDa protein in two hybrids containing human chromosomes 5, 6, 9, and 11 in common. Using Western blot analysis, we demonstrate that this protein is a member of the HSP70 family and, by Southern blot analysis, that the HSP73 gene is located on human chromosome 11. Fluorescence in situ hybridization further localized HSP73 to the region 11q23.3-q25. This region is involved in a number of genetic rearrangements and is associated with several well-characterized tumours.

Nucleotide and deduced amino acid sequences of the non-structural protein, NS1, of Australian and South African bluetongue virus serotype 1.

The sequence of the sense strand of RNA segment 5 of both Australian and South African bluetongue virus (BTV) serotype 1 has been determined and found to be 1771 and 1773 nucleotides in length, respectively. Both coding sequences of 1656 nucleotides were flanked by a 5' non-coding sequence of 34 nucleotides and 3' non-coding regions of 78 and 80 nucleotides, respectively. The methionine codons at residues 35-37 were assumed to initiate the synthesis of 64.6 or 64.415 kDa proteins which had calculated net charges of +5 or +4 at neutral pH, respectively. The encoded NS1 proteins had a very high molar ratio of cysteine residues. A variable region of approximately 45 nucleotides at the 3'-terminus of RNA segment 5 of South African and Australian BTV-1 and the RNA segment 6 of the North American BTV-10 was shown to be unusually rich in A + T residues (approximately 80-82%) compared with other BTV gene segments so far sequenced which have between 52 and 56% A + T. These regions were thought to be responsible for the variable migration of RNA 5 segments on electrophoresis in polyacrylamide gels in the presence of urea. This variability in the apparent molecular weight of RNA 5 segments was not restricted to BTV amongst Australian orbiviruses tested, nor was the apparent molecular weight for RNA 5 identical for different isolates of the same BTV serotype, indicating that this A + T rich region was highly variable. Comparison of the nucleotide and amino acid sequence divergence of the Australian and South African BTV RNA segments 5 to that for the North American BTV-10 RNA segment 6 (which codes for NS1) revealed the same relationships as those found for the core protein VP3 gene sequences, in that although all NS1 proteins were very similar in their amino acid sequences, their genes were more variable. The Australian NS1 sequence differed from both the South African and North American genes by 20% at the nucleotide level, whereas the North American and South African sequences diverged by only 11%. Hybridization analyses showed that RNA segment 5 DNA probes were capable of delineating the geographical origin of a BTV isolate, as had been observed for VP3 probes; however, other probes were also generated which were capable of unambiguously differentiating BTV isolates from other orbiviruses tested.