A cluster of three single nucleotide polymorphisms in the 3'-untranslated region of human glycoprotein PC-1 gene stabilizes PC-1 mRNA and is associated with increased PC-1 protein content and insulin resistance-related abnormalities.

Glycoprotein PC-1 inhibits insulin signaling and, when overexpressed, plays a role in human insulin resistance. Mechanisms of PC-1 overexpression are unknown. We have identified a haplotype in the 3'-untranslated region of the PC-1 gene that may modulate PC-1 expression and confer an increased risk for insulin resistance. Individuals from Sicily, Italy, carrying the "P" haplotype (i.e., a cluster of three single nucleotide polymorphisms: G2897A, G2906C, and C2948T) were at higher risk (P < 0.01) for insulin resistance and had higher (P < 0.05) levels of plasma glucose and insulin during an oral glucose tolerance test and higher levels of cholesterol, HDL cholesterol, and systolic blood pressure. They also had higher (P < 0.05-0.01) PC-1 protein content in both skeletal muscle and cultured skin fibroblasts. In CHO cells transfected with either P or wild-type cDNA, specific PC-1 mRNA half-life was increased for those transfected with P (t/2 = 3.73 +/- 1.0 vs. 1.57 +/- 0.2 h; P < 0.01). In a population of different ethnicity (Gargano, East Coast Italy), patients with type 2 diabetes (the most likely clinical outcome of insulin resistance) had a higher P haplotype frequency than healthy control subjects (7.8 vs. 1.5%, P < 0.01), thus replicating the association between the P allele and the insulin resistance-related abnormalities observed among Sicilians. In conclusion, we have identified a possible molecular mechanism for PC-1 overexpression that confers an increased risk for insulin resistance-related abnormalities.

Replicase complex genes of Semliki Forest virus confer lethal neurovirulence.

Semliki Forest virus (SFV) is a mosquito-transmitted pathogen of small rodents, and infection of adult mice with SFV4, a neurovirulent strain of SFV, leads to lethal encephalitis in a few days, whereas mice infected with the avirulent A7(74) strain remain asymptomatic. In adult neurons, A7(74) is unable to form virions and hence does not reach a critical threshold of neuronal damage. To elucidate the molecular mechanisms of neurovirulence, we have cloned and sequenced the entire 11,758-nucleotide genome of A7(74) and compared it to the highly neurovirulent SFV4 virus. We found several sequence differences and sought to localize determinants conferring the neuropathogenicity by using a panel of chimeras between SFV4 and a cloned recombinant, rA774. We first localized virulence determinants in the nonstructural region by showing that rA774 structural genes combined with the SFV4 nonstructural genome produced a highly virulent virus, while a reciprocal recombinant was asymptomatic. In addition to several amino acid mutations in the nonstructural region, the nsp3 gene of rA774 displayed an opal termination codon and an in-frame 21-nucleotide deletion close to the nsp4 junction. Replacement in rA774 of the entire nsp3 gene with that of SFV4 reconstituted the virulent phenotype, whereas an arginine at the opal position significantly increased virulence, leading to clinical symptoms in mice. Completion of the nsp3 deletion in rA774 did not increase virulence. We conclude that the opal codon and amino acid mutations other than the deleted residues are mainly responsible for the attenuation of A7(74) and that the attenuating determinants reside entirely in the nonstructural region.

The significance of the 3'-nontranslated region and E2 amino acid mutations in the virulence of Semliki Forest virus in mice.

We have recently shown that the 3'-nontranslated region (3'-NTR) of the avirulent Semliki Forest virus A7(74) [SFVA7(74)] contains a unique sequence of 101 nucleotides and five repetitive nucleotide units whereas the 3'-NTR of the neurovirulent SFV4 has only two repeats. A chimeric virus was constructed by replacing the entire 3'-NTR of the SFV4 clone with the A7(74) 3'-NTR. The hybrid replicated efficiently in the central nervous system (CNS) of adult Balb/c mice and, similarly to SFV4, led to high mortality after intraperitoneal inoculation. In contrast, another chimeric virus, CME2, containing the E2 gene of the avirulent SFVA7(74) virus in the SFV4 clone was recently shown to be avirulent for mice. Several derivatives with single-site or a constellation of amino acid mutations were constructed. Two single-site E2 mutants, Val37lle and Asn212Ser, displayed an attenuated phenotype in mice with mortality reduced from 90 to 48 and 43%, respectively. None of the multiple site mutants were significantly attenuated. Adult female mice showed a greater resistance to SFV infection than male mice. The SFV hybrid viruses, CM3NTR and CME2, reached the CNS similarly to the parental viruses, but the single-site E2 mutants were only sporadically found in the CNS. We conclude that in mice the 3'-NTR does not play a significant role in the pathogenesis of Semliki Forest virus and that specific E2 amino acid mutations reduce the virulence, especially in female mice. The results additionally suggest that individual amino acid mutations in the E2 glycoprotein affect the efficiency of migration into the CNS.

The Semliki Forest virus E2 gene as a virulence determinant.

We have determined the nucleotide sequences of the capsid, E3, E2 and 6K genes of the avirulent Semliki Forest virus variant A774 (SFV A7). The sequence analysis revealed a nucleotide identity of 98% for capsid, 98% for E3, 97% for E2 and 98% for 6K genes, as compared with the prototype SFV strain L10. At the protein level, the capsid and E3 polypeptides of SFV A7 both exhibited two amino acid substitutions, whereas point mutations in the 6K gene did not alter the amino acid sequence. In the E2 gene of SFV A7, seven of the 34 point mutations led to an amino acid difference as compared with the L10 strain. Replacement of the E2 glycoprotein gene of the virulent SFV4 clone with the corresponding region of SFV A7 resulted in a new plasmid construct, pME2, that gave rise to infectious virus CME2. CME2 and SFV4 replicated similarly in an immortalized mouse brain cell line (MBA 13). Intraperitoneal injection of 10(6) p.f.u. of CME2 into 4- to 6-week-old BALB/c mice caused mild clinical signs in some mice, whereas the majority of the infected animals remained asymptomatic, similar to infection with the avirulent SFV A7. In contrast, infection with the parental SFV4, a derivative of the virulent L10 strain, was lethal in 80% of mice. Virus titres in blood and brain tissue specimens of BALB/c mice were similar after infection with CME2 or A7 viruses. The results suggest that amino acid differences in the E2 glycoprotein individually or in concert cause the attenuation of CME2.

Multiple repeating motifs are found in the 3'-terminal non-translated region of Semliki Forest virus A7 variant genome.

We have analysed the cDNA coding for the envelope glycoprotein (E1) gene and the terminal non-translated regions (NTRs) of the avirulent Semliki Forest virus (SFV) A774 (A7) variant. The E1 gene exhibited 98.5% identify to the SFV prototype strain L10 (WT) sequence at the nucleotide level. Of the 34 single base substitutions, six led to a change in the deduced amino acid sequence. The 3' NTR of A7 consisted of a 101 nucleotide sequence, not found in WT, followed by five tandemly arranged sequence motifs, two of which were truncated forms of the others. One full-length and one truncated repeat are found at the 3' NTR of WT. The repeats of A7 were followed by a non-repeating sequence, very similar to the equivalent region in WT. Owing to the unique sequence motif and the tandem repeats, the 3' NTR of A7 is 334 nucleotides longer than that of WT. Each of the repeats had an internal 12 nucleotide motif complementary to a conserved sequence in the 5'-terminal non-structural protein 1-encoding region, thought to be important in alphavirus RNA replication. In the 5' NTR, three point mutations were found. The conserved sequence binding to the repeated 3' motifs was identical in A7 and WT.

Seroprevalence to some TORCH agents in a Sicilian female population of fertile age.

The seroprevalence to Toxoplasma gondii (41.1%), rubella virus (88.2%), cytomegalovirus (86.0%), and herpes simplex virus (80.0%) has been evaluated in fertile women living in Catania (Sicily). The population group studied was divided into four age groups to quantify the risk of primary infection in each age group.