The Cayapa Indians of Ecuador: a genetically isolated group with unexpected complement C7 M/N allele frequencies

The Cayapa Indians live in north-western Ecuador in close proximity to a Black population of African ancestry. C7 M/N allotyping has proved to be a good technique for plasma genetic analysis in several populations. Investigation of 124 Cayapa plasma samples revealed the highest allele frequency of C7(*)N observed in any population examined so far (0.36 versus 0.225 or lower). The marked difference in frequency compared with several Oriental populations, which are believed to have been derived from the same Asian population as native Amerindians, may reflect the effect of a small founder population followed by a high degree of genetic isolation. The allele frequency of 0.12 for C7(*)N determined for the neighbouring Black population supports the conclusion that there has been a lack of genetic admixture of Cayapas with other populations, confirming the results of ethnohistorical investigations and other protein polymorphism studies

The Cayapa Indians of Ecuador: a genetically isolated group with unexpected complement C7 M/N allele frequencies

The Cayapa Indians live in north-western Ecuador in close proximity to a Black population of African ancestry. C7 M/N allotyping has proved to be a good technique for plasma genetic analysis in several populations. Investigation of 124 Cayapa plasma samples revealed the highest allele frequency of C7(*)N observed in any population examined so far (0.36 versus 0.225 or lower). The marked difference in frequency compared with several Oriental populations, which are believed to have been derived from the same Asian population as native Amerindians, may reflect the effect of a small founder population followed by a high degree of genetic isolation. The allele frequency of 0.12 for C7(*)N determined for the neighbouring Black population supports the conclusion that there has been a lack of genetic admixture of Cayapas with other populations, confirming the results of ethnohistorical investigations and other protein polymorphism studies

Molecular cloning of the cDNA coding for properdin, a positive regulator of the alternative pathway of human complement.

Northern blot analysis indicated that the mRNA for human properdin is approximately 1.5 kb long and that its level in U-937 cells is increased by pretreating the cells with phorbol 12-myristate 13-acetate (PMA). Using a human genomic probe clones coding for human properdin were isolated from a lambda gt10 cDNA library derived from PMA-treated U-937 cells. The sequence of the 1474-bp cDNA insert of the longest clone revealed an open reading fram of 1326 bp coding for the entire 442 amino acids of the mature form of human properdin and 67 bp coding for 22 amino acids of typical, but incomplete leader sequence. Polymerase chain reaction "RACE" experiments identified the start site ATG and revealed the complete, 27-amino acid-long, leader peptide sequence. Within the 81-bp 3' non-translated extension a polyadenylation signal was identified 41 bp downstream from the stop codon, TAA, and 12 bp upstream of a 19 nucleotide long poly(A) tail. The amino acid sequence of human properdin is clearly divided into three distinct regions: a 49 residue-long N-terminal region, a 32 residue-long C-terminal region and a middle region, covering residues 50 to 411, composed of six tandemly repeated thrombospondin repeat (TSR) motifs of the type first described in the adhesive glycoprotein thrombospondin and also known to be present in the C6, C7, C8 alpha, C8 beta and C9 terminal components of complement. Human and mouse properdin sequences show a high (approximately 76%) degree of identity with almost complete conservation of the relatively large number of Cys (44) and Trp (20) residues

Complement induction and complement evasion in patients with cerebral aspergillosis

Cerebral aspergillosis is a mostly lethal infection of the central nervous system. Former results identified low cerebral complement levels as one cause for insufficient immune reaction. Therefore we studied cerebral complement expression after fungal invasion and investigated putative mechanisms of Aspergillus spp to cope with the complement-induced selection pressure. Brain tissue derived from patients with cerebral aspergillosis or non-infected individuals was analyzed immunohistochemically for complement synthesis. Correlations between expression levels were determined statistically. Increased complement synthesis, a prerequisite for strengthened antifungal potency, was visible in resident astrocytes, neurons, oligodendrocytes as well as in infiltrating macrophages after fungal infection. Surprisingly, microglia, although regarded as major immune cells, only marginally participated in synthesis of most complement proteins. Several evasion mechanisms were found that help the fungus to establish a cerebral infection even in the presence of complement: Fungal hyphae limit the surface deposition of C3 and thus interfere with complement-dependent phagocytosis. Furthermore, the "sealing off" in brain abscesses not only inhibits fungal spreading but also forms protection shields against complement attack. Complement indeed seems to represent an important selection pressure and evokes the development of fungal evasion mechanisms. Counteractions for these evasion processes might represent interesting therapeutic approaches