Assignment of the gene locus for severe congenital neutropenia to chromosome 1q22 in the original Kostmann family from Northern Sweden.

Autosomal recessive severe congenital neutropenia (SCN) or Kostmann syndrome is characterised by reduced neutrophil counts and subsequent recurrent bacterial infections. The disease was originally described in a large consanguineous pedigree from Northern Sweden. A genome-wide autozygosity scan was initiated on samples from four individuals in the original pedigree using high density single nucleotide polymorphism (SNP) genotyping arrays in order to map the disease locus. Thirty candidate regions were identified and the ascertainment of samples from two additional patients confirmed a single haplotype with significant association to the disorder (p<0.01) on chromosome 1q22. One affected individual from the original Kostmann pedigree was confirmed as a phenocopy. The minimal haplotype shared by affected individuals spans a candidate region of 1.2 Mb, containing several potential candidate genes.

Characterization of the biosynthesis, processing, and sorting of human HBP/CAP37/azurocidin.

Azurocidin is a multifunctional endotoxin-binding serine protease homolog synthesized during the promyelocytic stage of neutrophil development. To characterize the biosynthesis and processing of azurocidin, cDNA encoding human preproazurocidin was stably transfected to the rat basophilic leukemia cell line RBL-1 and the murine myeloblast-like cell line 32D cl3; cell lines previously utilized to study the related proteins cathepsin G and proteinase 3. After 30 min of pulse radiolabeling, two forms of newly synthesized proazurocidin (34.5 and 37 kDa), differing in carbohydrate content but with protein cores of identical sizes, were recognized. With time, the 34.5-kDa form disappeared, while the 37-kDa form was further processed proteolytically, as judged by digestion with N-glycosidase F. Conversion of high-mannose oligosaccharides into complex forms was shown by acquisition of complete resistance to endoglycosidase H. Radiosequence analysis demonstrated that the amino-terminal seven amino acid propeptide of proazurocidin was removed in a stepwise manner during processing; initial removal of five amino acids was followed by cleavage of a dipeptide. Presence of the protease inhibitors Gly-Phe-diazomethyl ketone, bestatin, or leupeptin inhibited only the cleavage of the dipeptide, thus indicating the involvement of at least two amino-terminal processing enzymes. Translocation of azurocidin to granules was shown by subcellular fractionation. Similar results, with efficient biosynthesis, processing, and targeting to granules in both cell lines, were obtained with a mutant form of human preproazurocidin lacking the amino-terminal heptapropeptide. In conclusion, this investigation is an important addition to our previous studies on related azurophil granule proteins, and provides novel information concerning the biosynthesis and distinctive amino-terminal processing of human azurocidin.

Processing and targeting of granule proteins in human neutrophils.

Neutrophils contain an assembly of granules destined for regulated secretion, each granule type with distinct constituents formed before terminal differentiation. The earliest granules are designated azurophil (primary), followed in time by specific (secondary), and gelatinase granules as well as secretory vesicles. Transcription factors regulate the genes for the granule proteins to ensure that expression of the gene products to be stored in different organelles is separated in time. Similar to lysosomal enzymes, many granule proteins, in particular those of the heterogeneous azurophil granules, are trimmed by proteolytic processing into mature proteins. Rodent myeloid cell lines have been utilized for research on the processing and targeting of human granule proteins after transfection of cDNA. Results from extensive work on the hematopoietic serine proteases of azurophil granules, employing in vitro mutagenesis, indicate that both an immature and a mature conformation are compatible with targeting for storage in granules. On the other hand, the amino-terminal propeptide of myeloperoxidase facilitates both the export from the endoplasmic reticulum and targeting for storage in granules. Similarly, targeting of defensins rely on an intact propeptide. The proteolytic processing into mature granule protein is most commonly a post-sorting event. Mis-sorting of specific granule proteins into azurophil or lysosome-like granules can result in premature activation and degradation, but represents a potential for manipulating the composition and function of neutrophil granules.

On the role of the proform-conformation for processing and intracellular sorting of human cathepsin G.

The serine protease cathepsin G is synthesized during the promyelomonocytic stage of neutrophil and monocyte differentiation. After processing, including removal of an amino-terminal propeptide from the catalytically inactive proform, the active protease acquires a mature conformation and is stored in azurophil granules. To investigate the importance of the proform-conformation for targeting to granules, a cDNA encoding a double-mutant form of human preprocathepsin G lacking functional catalytic site and amino-terminal prodipeptide (CatG/Gly201/triangle upGly19Glu20) was constructed, because we were not able to stably express a mutant lacking only the propeptide. Transfection of the cDNA to the rat basophilic leukemia RBL-1 and the murine myeloblast-like 32D cl3 cell lines resulted in stable, protein-expressing clones. In contrast to wild-type proenzyme, CatG/Gly201/triangle upGly19Glu20 adopted a mature conformation cotranslationally, as judged by the early acquisition of affinity to the serine protease inhibitor aprotinin, appearing before the carboxyl-terminal processing and also in the presence of the Golgi-disrupting agent brefeldin A. The presence of a mature amino-terminus was confirmed by amino-terminal radiosequencing. As with wild-type proenzyme, CatG/Gly201/triangle upGly19Glu20 was proteolytically processed carboxyl-terminally and glycosylated with asparagine-linked carbohydrates that were converted into complex forms. Furthermore, it was targeted to granules, as determined by subcellular fractionation. Our results show that the initial proform-conformation is not critical for intracellular sorting of human cathepsin G. Moreover, we demonstrate that double-mutant cathepsin G can achieve a mature conformation before carboxyl-terminal processing of the proform.

Biosynthesis, processing and sorting of neutrophil proteins: insight into neutrophil granule development.

Neutrophil granulocytes are specialized phagocytic cells that carry a collection of granules for regulated secretion, each with distinct constituents. The granules can be classified as azurophil (primary), developed first, followed in time by specific (secondary) granules gelatinase granules, and secretory vesicles. Stage- and tissue-specific transcription factors govern the successive expression of genes for granule proteins to allow storage of the gene products in these organelle categories whose packaging is separated in time. Many of the granule proteins, in particular those of the heterogeneous lysosome-like azurophil granules, are subject to extensive post-translational proteolytic processing into mature proteins, most commonly as a post-sorting event. A selective aggregation of proteins destined for storage in granules, as discussed in this review, would facilitate their retention and eliminate a need for distinct sorting motifs on each granule protein. Aggregation of granule proteins, that are often cationic, would be assisted by the anionic serglycin proteoglycans present in neutrophils. The antibacterial granule proteins can serve as models for antibiotics and some of them possess a potentially useful therapeutic ability to bind and neutralize endotoxin. Because aberrant expression of transcription factors regulating the synthesis of granule proteins is often found in leukemia, the clarification of mechanisms regulating the timed expression of granule proteins will shed light on the maturation block in myeloid leukemias.

Characterization of the processing and granular targeting of human proteinase 3 after transfection to the rat RBL or the murine 32D leukemic cell lines.

Proteinase 3 (PR3) is a neutrophil serine protease stored in the azurophil granules of the promyelocyte and its successors. The protease has been identified as an autoantigen for anti-neutrophil cytoplasmic autoantibodies (ANCA) occurring in patients with Wegener's granulomatosis. To characterize the biosynthesis and processing of human PR3 in a transgenic cellular model, cDNA encoding human pre-proproteinase 3 cloned from U-937 cells was transfected to the rat basophilic/mast cell line RBL-1 and the murine myeloblast-like cell line 32D c13. The stable expression of transgenic proteinase 3 was characterized by biosynthetic labeling, followed by immunoprecipitation, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and fluorography. After pulse labeling for 30 min two proforms of PR3 (32 and 35 kDa), differing in carbohydrate content but with protein cores of identical size, were demonstrated. Chase of the label resulted in a processed 32-kDa form clearly visible in RBL, but only faintly in 32D cells, probably indicating delayed intracellular transfer in the latter cell line. Partial digestion with N-glycosidase F showed that both potential N-glycosylation sites on PR3 were occupied and conversion of the oligosaccharide side chains into complex forms was demonstrated by acquisition of resistance to endoglycosidase H. Translocation of PR3 to granules was shown by subcellular fractionation and immunocytochemistry. Enzymatic activation of PR3 was suggested by affinity to diisopropylfluorophosphate and removal of an amino-terminal propeptide. Cells transfected with PR3 showed positive immunofluorescence for ANCA-containing sera from patients with Wegener's granulomatosis. Our results show that human PR3 transfected to RBL or 32D cells is synthesized as a 29-kDa protein core glycosylated on two distinct sites. Oligosaccharide trimming and proteolytic processing occur and the protein is targeted for granular storage in a form antigenic for ANCA.

Rapid subgenus identification of human adenovirus isolates by a general PCR.

In most clinical situations involving adenovirus infection, subgenus (subgroup) identification of an adenovirus isolate is as informative as a finer identification by serotype. A PCR method which allows the identification of human adenovirus isolates as members of subgenera A, B:1, B:2, C, D, E, or F is described. It is based on a simple (nonnested) PCR using primers which bind to regions immediately flanking the VA RNA-encoding regions of human adenovirus genomes. The PCR allows amplification of DNA from all 49 human adenovirus prototype strains so far described. Since there are differences in the lengths of the VA RNA-encoding regions in adenoviruses of different subgenera, it is possible to differentiate some subgenera according to the size of the PCR product determined by electrophoresis. This forms the basis of an initial broad categorization of isolates as belonging to either (i) subgenus B:1, C, D, or E or (ii) subgenus A, B:2, or F. Subgenus identification is completed by a one-step restriction enzyme digestion and gel electrophoresis. The method was assessed by blind subgenus identification of 200 miscellaneous primate adenovirus isolates prepared by the reference laboratory at Bilthoven, The Netherlands. Identification at the subgenus level by PCR correlated 91.5% with the results of serotyping. A further 5.5% of isolates were correctly identified as belonging to one of two specified subgenera. Six of the 200 identifications (3%) were unsuccessful for various reasons, including weak PCR products, intermediate strains, and mistaken primate host. The method should serve as a rapid means of confirming adenovirus cytopathic effects in laboratories performing virus culture, with simultaneous subgenus identification of the isolate. It will also have relevance as an aid to conventional serotyping for epidemiological purposes, since for all adenoviruses except those belonging to subgenus D, neutralization tests need only involve a maximum of four type-specific antisera.

Human cathepsin G lacking functional glycosylation site is proteolytically processed and targeted for storage in granules after transfection to the rat basophilic/mast cell line RBL or the murine myeloid cell line 32D.

The neutral protease cathepsin G belongs to a family of hematopoietic serine proteases stored in the azurophil granules of the neutrophil granulocyte. To investigate the function of asparagine-linked carbohydrates in neutrophil serine proteases, we constructed a mutant cDNA, coding for human cathepsin G deficient of a functional glycosylation site, for use in a transgenic cellular model. Wild type and mutant cDNA were stably expressed in the rat basophilic/mast cell line RBL and in the murine myeloblast-like cell line 32D. Biosynthetic labeling, followed by immunoprecipitation, SDS-polyacrylamide gel electrophoresis, and fluorography, showed that carbohydrate-deficient cathepsin G was synthesized as a 29-kDa proform in both cell lines. The proform was proteolytically processed into a stable form with an apparent molecular mass of 27.5 kDa, indicating removal of the carboxyl-terminal prodomain. The mutant cathepsin G was enzymatically activated as determined by acquisition of affinity to aprotinin, a serine protease inhibitor. As for wild type cathepsin G, small amounts of the unprocessed form of the mutated enzyme were released from the cells, while the major part was transferred to a granular compartment as demonstrated by subcellular fractionation. Thus, neither processing leading to enzymatic activation nor granular sorting was obviously affected by the lack of oligosaccharides on the mutant cathepsin G. Our results therefore indicate that glycosylation is not essential for these processes. In addition to the previously utilized cell line RBL, we propose the 32D cell line as a suitable cellular model for transgenic expression of human neutrophil serine proteases.

Human and simian adenoviruses: phylogenetic inferences from analysis of VA RNA genes.

Adenovirus VA RNA genes have primary sequence constraints due to internal promoter regions and a high degree of secondary structure in the RNA product. To determine the relationships between human and simian adenoviruses, the VA RNA genes of several primate adenoviruses were characterized and compared to those sequences already published. Human adenoviruses of subgenera A, B:2, and F have only one VA RNA gene, whereas human adenoviruses of subgenera B:1, C, D, and E have two. The genomes of 12 monkey adenoviruses were found to have only one VA RNA gene, whereas the genomes of six representative chimpanzee adenoviruses were each found to have two VA RNA genes. Phylogenetic analysis of representative VA RNA gene sequences individually, irrespective of their strain of origin or partnering VA RNA gene, gave the following inferences. (1) The single VA RNA genes of human adenovirus subgenera A and F are most closely related to those of monkey adenoviruses. (2) The VA RNAI genes of human adenoviruses in subgenera B:1, D, and E, and also the single VA RNA genes of subgenus B:2 probably diverged from a common ancestral VA RNA gene. (3) This ancestral gene most likely reduplicated to give the precursor of all VA RNAII genes, the evidence for which has been almost totally lost in subgenus B:2 adenoviruses. (4) The two VA RNA genes of human subgenus C adenoviruses are relatively distant from each other phylogenetically. Since the Ad2 and Ad5 VA RNAI genes have a higher identity to the single VA RNA gene of SAV13 (SV36) than to those of any of the other human adenoviruses, these genes may have entered the human subgenus C adenovirus genome by substitution involving recombination with a simian adenovirus. The results of this study suggest that a renewed appraisal of VA RNA function in adenoviruses other than Ad2 and Ad5 may be necessary.