Formation of a complex of human plasma myeloperoxidase and opsonins

Human neutrophil myeloperoxidase adsorbs on immobilized fibronectin or IgG under conditions approaching the physiological ones. Immobilized myeloperoxidase binds liquid-phase plasma fibronectins and thermoaggregated IgG, but not native IgG. Protein-myeloperoxidase interaction is thought to be the mechanism arming phagocytes with this enzyme in the course of phagocytosis of pathogenic microorganisms and to be one means of preventing tissue injury by oxidants generated by extracellular myeloperoxidase. Translated fromByulleten' Eksperimental'noi Biologii i Meditsiny, Vol. 120, N ^o . 9, pp. 320–322, September, 1995 Presented by A. N. Klimov. Member of the Russian Academy of Medical Sciences     

Variola and camelpox virus-specific sequences are part of a single large open reading frame identified in two German cowpox virus strains

A large open reading frame (ORF) has been identified in two German cowpox virus strains. The ORFs (5676 and 5679 nt, respectively) differ in 10 nucleotides, resulting in an amino acid homology of 99.8%. In searching GenBank nucleotide sequences (>90% identity) were present in several small ORFs in variola major, variola minor and camelpox virus genomes. Alignments revealed that these small ORFs are fragments of a large ORF. However, sequences of the ORF described here are entirely absent in the two cowpox virus reference strains. Databank analysis revealed amino acid identities (ranging from 25 to 39%) with so-called B22R-like poxviral proteins with unknown function encoded by several chordopoxviruses. Further sequencing of one cowpox virus strain under study identified an ORF (5790 nt) which displays high levels of nucleotide identity to ORFs present in several orthopoxvirus species. Taken together, the two cowpox viruses analyzed here contain one large ORF which is conserved within the genus Orthopoxvirus and a unique, more distantly related ORF of similar size, which is conserved in the subfamily Chordopoxvirinae.     

Content of Autoantibodies to Bradykinin and β-Amyloid1-42 as a Criterion for Biochemical Differences between Alzheimer's Dementias

We measured serum content of autoantibodies to -amyloid protein A_1-42, its neurotoxic fragment A_25-35, vasopressin, bradykinin, thrombin, antithrombin III, ₂-macroglobulin, and angiotensin II in patients with various forms of Alzheimer's dementias, including presenile and senile dementias of the Alzheimer type. The ratio of antibradykinin and anti-A_1-42 autoantibody contents differed by 39% in these patients. Our results can be used for the development of a new biochemical method for differential diagnostics of dementias of the Alzheimer type.     

Role of group A streptococcal IgG-binding proteins in triggering experimental glomerulonephritis in the rabbit

Our previous studies have indicated that the IgG-binding M-family proteins (IgGBP) of group A streptococci may be involved in eliciting experimental acute poststreptococcal glomerulonephritis (APSGN) in the rabbit. These surface proteins were also found to trigger production of anti-IgG, which might conceivably act to enhance renal deposition of immune complexes (IC). In the present study, a clinical isolate of serotype M22 (strain AL168), an isogenic double mutant deficient for both the IgGBPs Mrp and Emm, as well as mutants deficient in only one of the proteins were tested for capacity to induce glomerulonephritis. Streptococci to be used for injecting rabbits were heat-killed. Surface-bound IgG was removed by 1 M KSCN and cells were then repeatedly washed in PBS before use. Rabbits were injected intravenously with 109 cells three times a week for 8 weeks and, following one month of rest, for another 6 weeks. Deposits of IgG and C3 as well as induced chemokines TNF-alpha, IL-1beta and IL-6 were traced in cryostat sections using specific antibodies and appropriate peroxidase-labelled anti-antibodies. In four rabbits immunized with the double mutant strain, no deposits were found, and as examined by TEM, only subtle and transient renal changes were observed. In contrast, the original strain AL168 induced pronounced inflammatory and degenerative glomerular changes in all four rabbits injected, and deposits of TNF-alpha, IL-1beta and IL-6 were found in mesangial and endothelial cells. Similar deposits and glomerular changes were seen in all eight rabbits injected with the mrp-emm+ mutant and in four out of seven animals receiving the mrp+emm- mutant. There was a highly significant correlation between high levels of circulating anti-IgG and development of APSGN. These results confirm an important role of streptococcal IgGBP in triggering experimental APSGN as earlier proposed by our group.     

Lack of responses to a beta3-adrenergic agonist in lipoatrophic A-ZIP/F-1 mice

Stimulation of beta3-adrenergic receptors increases metabolic rate via lipolysis in white adipose tissue (WAT) and thermogenesis in brown adipose tissue (BAT). Other acute effects include decreased gastrointestinal motility and food intake and increased insulin secretion. Chronic treatment with a beta3 agonist ameliorates diabetes and obesity in rodents. We studied the effects of beta3 stimulation in A-ZIP/F-1 mice, which have virtually no WAT, a reduced amount of BAT, severe insulin resistance, and diabetes. In contrast with wild-type mice, treatment of A-ZIP/F-1 mice with CL316243, a beta3-adrenergic agonist, did not increase O2 consumption. A single dose of CL316243 produced a 2-fold increase in serum free fatty acids, a 53-fold increase in insulin, and a 2.4-fold decrease in glucose levels in wild-type mice but no change in A-ZIP/F-1 animals. The A-ZIP/F-1 mice also did not show reduced gastrointestinal motility or 24-h food intake during beta3 stimulation. Chronic administration of CL316243 to the A-ZIP/F-1 mice did not improve their thermogenesis, hyperglycemia, or hyperinsulinemia. Thus, all of the beta3 effects studied were absent in the lipoatrophic A-ZIP/F-1 mice, including the effects on nonadipose tissues. From these results, we suggest that all of the effects of beta3 agonists are initiated at the adipocyte with the nonadipose effects being secondary events presumably mediated by signals from adipose tissue.     

Alternative Gnas gene products have opposite effects on glucose and lipid metabolism

Gnas is an imprinted gene with multiple gene products resulting from alternative splicing of different first exons onto a common exon 2. These products include stimulatory G protein alpha-subunit (G(s)alpha), the G protein required for receptor-stimulated cAMP production; extralarge G(s)alpha (XLalphas), a paternally expressed G(s)alpha isoform; and neuroendocrine-specific protein (NESP55), a maternally expressed chromogranin-like protein. G(s)alpha undergoes tissue-specific imprinting, being expressed primarily from the maternal allele in certain tissues. Heterozygous mutation of exon 2 on the maternal (E2m-/+) or paternal (E2+/p-) allele results in opposite effects on energy metabolism. E2m-/+ mice are obese and hypometabolic, whereas E2+/p- mice are lean and hypermetabolic. We now studied the effects of G(s)alpha deficiency without disrupting other Gnas gene products by deleting G(s)alpha exon 1 (E1). E1+/p- mice lacked the E2+/p- phenotype and developed obesity and insulin resistance. The lean, hypermetabolic, and insulin-sensitive E2+/p- phenotype appears to result from XLalphas deficiency, whereas loss of paternal-specific G(s)alpha expression in E1+/p- mice leads to an opposite metabolic phenotype. Thus, alternative Gnas gene products have opposing effects on glucose and lipid metabolism. Like E2m-/+ mice, E1m-/+ mice had s.c. edema at birth, presumably due to loss of maternal G(s)alpha expression. However, E1m-/+ mice differed from E2m-/+ mice in other respects, raising the possibility for the presence of other maternal-specific gene products. E1m-/+ mice had more severe obesity and insulin resistance and lower metabolic rate relative to E1+/p- mice. Differences between E1m-/+ and E1+/p- mice presumably result from differential effects on G(s)alpha expression in tissues where G(s)alpha is normally imprinted.     

Adrenalectomy improves diabetes in A-ZIP/F-1 lipoatrophic mice by increasing both liver and muscle insulin sensitivity

The virtually fatless A-ZIP/F-1 mouse is profoundly insulin resistant, diabetic, and a good model for humans with severe generalized lipoatrophy. Like a number of other mouse models of diabetes, the A-ZIP/F-1 mouse has elevated serum corticosterone levels. Leptin infusion lowers the corticosterone levels, suggesting that leptin deficiency contributes to the hypercorticosteronemic state. To test the hypothesis that the increased glucocorticoids contribute to the diabetes and insulin resistance, we examined the effect of adrenalectomy on A-ZIP/F-1 mice. Adrenalectomy significantly decreased the blood glucose, serum insulin, and glycated hemoglobin levels. Hyperinsulinemic-euglycemic clamps were performed to characterize the changes in whole-body and tissue insulin sensitivity. The adrenalectomized A-ZIP/F-1 mice displayed a marked improvement in insulin-induced suppression of endogenous glucose production, indicating increased hepatic insulin sensitivity. Adrenalectomy also increased muscle glucose uptake and glycogen synthesis. These results suggest that the chronically increased serum corticosterone levels contribute to the diabetes of the A-ZIP/F-1 mice and that removal of the glucocorticoid excess improves the insulin sensitivity in both muscle and liver.     

The growth hormone-insulin like growth factor axis revisited: lessons from IGF-1 and IGF-1 receptor gene targeting

We have created a liver-specific igf1 gene-deletion mouse model (LID) with markedly reduced circulating IGF-I levels. They demonstrate that while they have normal growth and development they develop insulin resistance secondary to the elevation of circulating growth hormone. When mated with an acid-labile subunit (ALS) gene-deleted mouse they also show osteopenia suggesting that circulating IGF-I levels play a significant role in bone formation. In a separate transgenic mouse we created a model of severe insulin resistance and type 2 diabetes by the overexpression of a dominant-negative IGF-I receptor in skeletal muscle. In this model we show that lipotoxicity plays a major role in the progression of the disease and is affected by treatment with a fibrate, which reverses the insulin resistance and diabetic state. These models are therefore very useful in studying human physiology and disease states.This work was presented in part at the IPNA Seventh Symposium on Growth and Development in Children with Chronic Kidney Disease: The Molecular Basis of Skeletal Growth, 1–3 April 2004, Heidelberg, Germany