Five year follow-up of non-psychotic adults with frequent auditory verbal hallucinations: are they still healthy?

BACKGROUND: Previously, we described 103 adults (mean age 41 years) who experienced frequent, auditory verbal hallucinations (AVH), in the absence of a need for mental healthcare. Importantly, these adults were largely past the peak incidence age for psychosis (15-35 years). It is unclear if these older individuals with AVH are still at increased risk for psychosis or other psychopathology. To address this question, we conducted a 5-year follow-up of previously included individuals (103 with AVH, 60 controls). METHOD: Eighty-one adults with AVH (78.6%) and forty-nine controls (81.7%) could be contacted and were willing to participate. Participants were screened for psychosis and a need for mental healthcare at follow-up using the Comprehensive Assessment of Symptoms and History interview (CASH). Need for mental healthcare was defined as a clinical diagnosis as identified using the CASH and/or treatment by a mental healthcare specialist. Phenomenology of AVH was assessed with the PSYRATS Auditory Hallucinations Rating Scale. RESULTS: Five individuals with AVH (6.2%) had developed psychosis and 32 (39.5%) had developed a need for mental healthcare. Voice-related distress at baseline significantly predicted need for mental healthcare. AVH persisted in most individuals (86.4%), without significant changes in phenomenology. None of the controls had developed psychotic symptoms, and need for mental healthcare (n = 6, 12.2%) was significantly lower in this group. CONCLUSIONS: These findings suggest that frequent AVH in non-psychotic adults past the peak incidence age for psychosis constitute a rather static symptom and that individuals with AVH may be best viewed as situated on a need for care continuum.

An assay to quantify the two plasma isoforms of factor V.

Blood coagulation factor V (FV) circulates in the blood in two forms designated FV1 and FV2. In model systems containing purified proteins FV1 appears to be more thrombogenic than FV2. Recently, we reported that in plasma from carriers of the R2 haplotype, a polymorphism which encodes several amino acid changes in FV and which is associated with an increased risk of thrombosis, the FV1/FV2 ratio is shifted in favor of the more thrombogenic form FV1. Here we describe in detail the assay that enables quantification of the plasma levels of FV1 and FV2. FV present in highly diluted plasma samples was activated with thrombin and the FVa generated was subsequently quantified in two prothrombinase-based assay systems. In the first assay, which is performed at saturating amounts of FXa and phospholipid vesicles with a high mole fraction phosphatidylserine, FVa1 and FVa2 express the same cofactor activity in prothrombin activation. Hence, this assay quantifies the total FV level (FV1 + FV2) present in plasma. In the second assay, which is performed at suboptimal amounts of FXa and phospholipid vesicles with a low mole fraction phosphatidylserine, FVa2 has approximately an 8-fold higher cofactor activity than FVa1. Therefore, the response in this assay depends on the relative amounts of FV1 and FV2 in the plasma sample. Calibration curves made with samples containing known concentrations of purified FVa1 and FVa2 subsequently allowed calculation of the amounts of FV1 and FV2 present in plasma.

Functional properties of factor V and factor Va encoded by the R2-gene.

Carriership of the factor V (FV) gene marked by the R2-haplotype, a series of linked polymorphisms encoding several amino acid changes in FV, is associated with mild resistance to activated protein C (APC) and with an increased risk of thrombosis. We compared the functional properties of normal FV(a) and R2-FV(a) in model systems and in plasma. FV and R2-FV were equally well activated by thrombin and expressed identical cofactor activities in prothrombin activation. Rate constants of APC-catalyzed inactivation of FVa and R2-FVa were similar both with and without protein S. However, significant differences were observed between haemostatic parameters determined in plasma from homozygous carriers of the R2-gene (n = 5) and age-matched non-carriers (n = 19). Plasma from R2-carriers contained significantly lower FV levels and the ratio of the two FV isoforms (FV1 and FV2) was shifted in favor of FV1. The FV2/FV1 ratio was 1.4 (95% CI = 1.3-1.5) in homozygous carriers of R2 and 2.8 (95% CI = 2.5-3.1) in controls (p < 0.00001). In an APC resistance test which quantifies the cofactor activity of FV in APC-catalyzed FVIII(a) inactivation, homozygous R2-carriers had significantly lower (p < 0.00001) APC sensitivity ratios (APCsr = 1.54, 95% CI = 1.48-1.60) than controls (APCsr = 2.17, 95% CI = 2.05-2.28). This indicates that R2-FV has reduced cofactor activity in APC-catalyzed FVIII(a) inactivation. The changes of the relative amounts of FV1 and FV2 in carriers of the R2-gene will result in increased thrombin formation in the presence of APC and may provide a mechanistic explanation for the increased thrombotic risk associated with the R2-haplotype.

Mutations in the R2 FV gene affect the ratio between the two FV isoforms in plasma.

Molecular genetics and biochemical studies were performed in homozygotes for the R2 allele (4070G) in the factor V gene, most of them affected by coronary artery disease. Novel polymorphisms (G642T, 156Ser; T1328C, 385Met/Thr), among which a functional candidate (A6755G, 2194Asp/Gly) located in the C2 domain of FV, were identified in the R2 gene. In chromatographic studies R2 FV appeared qualitatively identical to normal FV. However, a relative increase of the more thrombogenic and more glycosylated FV isoform (FV1) was observed in plasma of 2194Gly homozygotes (mean FV1/FV2 ratio 0.71, 95% CI 0.66-0.77) as compared to R2-free controls (0.37, 95% CI 0.34-0.40). We conclude that carriership of the R2 FV gene is associated with an imbalance between the two functionally different FV isoforms, and propose that genetically determined differential glycosylation of FV could represent a novel mechanism of thrombotic disease.

Human factor Va1 and factor Va2: properties in the procoagulant and anticoagulant pathways.

Human plasma factor V is heterogeneous and yields two forms of activated factor V that bind with low (factor Va1) and high affinity (factor Va2) to phospholipids. The properties of factor Va1 and factor Va2 in the anticoagulant and procoagulant pathways were evaluated by comparing their sensitivity for inactivation by APC and their ability to act as cofactor in prothrombin activation. At low phospholipid concentrations and on membranes containing low amounts of phosphatidylserine (PS), factor Va1 was inactivated by APC at 15-fold lower rates than factor Va2, both in the absence and in the presence of protein S. At high phospholipid concentrations and on membranes with more than 15 mol % PS, factor Va1 and factor Va2 were inactivated with equal efficiency. Differences between cofactor activities of factor Va1 and factor Va2 in prothrombin activation were only observed on membranes with less than 7.5 mol % PS. Due to the different phospholipid requirements of APC-catalyzed factor Va inactivation and of expression of factor Va cofactor activity in prothrombin activation, the thrombin-forming capacity of factor V1 was 7-fold higher than that of factor V2 in a reaction system containing factor Xa, prothrombin, APC, protein S, vesicles with a phospholipid composition resembling that of activated platelets, and traces of thrombin to initiate prothrombin activation. This shows that in the process of generation, expression, and down-regulation of factor Va cofactor activity on physiological membranes, the overall procoagulant activity of factor V1 can considerably exceed that of factor V2.

Effects of protein S and factor Xa on peptide bond cleavages during inactivation of factor Va and factor VaR506Q by activated protein C.

Inactivation of membrane-bound factor Va by activated protein C (APC) proceeds via a biphasic reaction that consists of a rapid and a slow phase, which are associated with cleavages at Arg506 and Arg306 of the heavy chain of factor Va, respectively. We have investigated the effects of protein S and factor Xa on APC-catalyzed factor Va inactivation. Protein S accelerates factor Va inactivation by selectively promoting the slow cleavage at Arg306 (20-fold). Factor Xa protects factor Va from inactivation by APC by selectively blocking cleavage at Arg506. Inactivation of factor VaR506Q, which was isolated from the plasma of a homozygous APC-resistant patient and which lacks the Arg506 cleavage site, was also stimulated by protein S but was not affected by factor Xa. This confirms that the target sites of protein S and factor Xa involve Arg306 and Arg506, respectively. Factor Xa completely blocked APC-catalyzed cleavage at Arg506 in normal factor Va (1 nM) with a half-maximal effect (K1/2Xa) at 1.9 nM factor Xa. Expression of cofactor activity of factor Va in prothrombin activation required much lower factor Xa concentrations (K1/2Xa = 0.08 nM). When the ability of factor Xa to protect factor Va from inactivation by APC was determined at low factor Va concentrations during prothrombin activation much lower amounts of factor Xa were required (K1/2Xa = 0.03 nM). This indicates 1) that factor Va is optimally protected from inactivation by APC by incorporation into the prothrombinase complex during ongoing prothrombin activation, and 2) that the formation of a catalytically active prothrombinase complex and protection of factor Va from inactivation by APC likely involves the same interaction of factor Xa with factor Va. In accordance with the proposed mechanisms of action of protein S and factor Xa, we observed that the large differences between the rates of APC-catalyzed inactivation of normal factor Va and factor VaR506Q were almost annihilated in the presence of factor Xa and protein S. This observation may explain why, in the absence of other risk factors, APC resistance only results in a weak prothrombotic condition.