Insulin and related peptides are key hormonal integrators of growth and metabolism in vertebrates. There is little biochemical evidence for insulin-related peptides in invertebrates, apart from insects for which definitive structural information on these peptides (prothoracicotropic hormone, PTTH) has recently been obtained. We report here the first complete complementary DNA-derived primary structure of a preproinsulin-related protein from identified neurons in an invertebrate, the mollusc Lymnaea stagnalis. We have demonstrated by in situ hybridization that transcription of the gene for this molluscan insulin-related peptide (MIP) occurs in the cerebral light-green cells, giant neuroendocrine cells involved in the control of growth, as well as in a pair of neuroendocrine cells called the canopy cells. The insulin-related peptide precursor has the same overall structure as its vertebrate counterparts. The discovery of insulin-related peptides in invertebrates substantiates the evidence for a widespread and early evolutionary origin of the insulin superfamily.
SummaryTwo Devon Rex cats from the same litter, which had no evidence of liver disease, malabsorption of vitamin K or chronic ingestion of coumarin derivatives, were found to have plasma deficiencies of factors II, VII, IX and X. Oral treatment with vitamin K1 resulted in the normalization of these coagulation factors. After taking liver biopsies it was demonstrated that the coagulation abnormality was accompanied by a defective γ-glutamyl-carboxylase, which had a decreased affinity for both vitamin K hydroquinone and propeptide. This observation prompted us to study in a well-defined in vitro system the possible allosteric interaction between the propeptide binding site and the vitamin K hydroquinone binding site on carboxylase. It was shown that by the binding of a propeptide-containing substrate to γ-glutamylcarboxylase the apparent K
M for vitamin K hydroquinone is decreased about 20-fold. On the basis of these in vitro data the observed defect in the Devon Rex cats can be fully explained.
Insulin and related peptides are key hormonal integrators of growth and metabolism in vertebrates. Recently, the amino acid and DNA sequences of insulin-related peptides in invertebrates have become available. The discovery of such peptides in insects and molluscs substantiates the evidence for an early origin and widespread evolution of the insulin superfamily.In the silkworm Bombyx (Insecta) the prothoracicotropic hormones (bombyxins 1, II, and III; previously called PTTH) are produced in the brain and may stimulate synthesis and release of ecdysone; thus they play a central role in insect development. In the freshwater snail Lymnaea (Mollusca), a growth stimulating hormone (molluscan insulin-related peptide; MIP) is produced in the brain, and two other insulin-related peptides are produced in the digestive system. The MIPs are involved in body and shell growth and energy metabolism. The finding that bombyxin and MIP are involved in the control of growth fits with ideas being developed in the vertebrate field that the role of insulin is not confined to glucose metabolism, but is also related to growth.
We report the purification of a minor Bordetella pertussis fimbrial subunit, designated FimD, and the identification of its gene (fimD). FimD could be purified from the bulk of major fimbrial subunits by exploiting the fact that major subunit-subunit interactions are more stable in the presence of SDS than minor-major subunit interactions. To locate the gene for FimD, internal peptides of FimD were generated, purified and sequenced. Subsequently, an oligonucleotide probe, based on the primary sequence of one peptide, was used to clone fimD. The primary structure of FimD, derived from the DNA sequence of its gene, showed homology with a number of fimbrial adhesins. Most pronounced homology was observed with MrkD, a fimbrial adhesin derived from Klebsiella pneumoniae. These observations suggest that FimD may represent a B. pertussis fimbrial adhesin. With a fimD-specific probe we detected the presence of a fimD homologue in Bordetella parapertussis and Bordetella bronchiseptica but not in Bordetella avium. Cloning and sequencing revealed that the B. parapertussis and B. bronchiseptica fimD product differed from the B. pertussis fimD product in 20 and 1 amino acid residues, respectively. Since B. bronchiseptica is normally not a human pathogen, but causes respiratory disease in a wide range of non-human mammalian species, this may suggest that FimD recognizes a receptor that is well conserved in mammalian species. An in-frame deletion in fimD completely abolished FimD expression and also affected the expression of the major subunits Fim2 and Fim3 suggesting that, in contrast to other adhesins that are minor components of fimbriae, FimD is required for formation of the fimbrial structure.
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