Gilbert C. White

A Prospective Study of Human Immunodeficiency Virus Type 1 Infection and the Development of AIDS in Subjects with Hemophilia

We evaluated a multicenter cohort of 1219 subjects with hemophilia or related disorders prospectively, focusing on 319 subjects with documented dates of seroconversion to human immunodeficiency virus type 1 (HIV-1). The incidence rate of the acquired immunodeficiency syndrome (AIDS) after seroconversion was 2.67 per 100 person-years and was directly related to age (from 0.83 in persons 1 to 11 years old up to 5.66 in persons 35 to 70 years old; Ptrend = 0.00003). The annual incidence of AIDS ranged from zero during the first year after seroconversion to 7 percent during the eighth year, with eight-year cumulative rates (+/- SE) of 13.3 +/- 5.3 percent for ages 1 to 17, 26.8 +/- 6.4 percent for ages 18 to 34, and 43.7 +/- 16.4 percent for ages 35 to 70. Serial immunologic and virologic markers (total numbers of CD4 lymphocytes, presence of serum interferon or HIV-1 p24 antigen, and low or absent serum levels of anti-p24 or anti-gp120) predicted a high risk for the subsequent development of AIDS. Adults 35 to 70 years old had a higher incidence of low CD4 counts than younger subjects (P less than or equal to 0.005), whereas adolescents had a low rate of anti-p24 loss (P = 0.0007) and subjects 1 to 17 years old had a lower incidence of AIDS after loss of anti-p24 (P = 0.03). These findings not only demonstrate that the risk of AIDS is related directly to age but also suggest that older adults are disproportionately affected during the earlier phases of HIV disease, that adolescents may have a low replication rate of HIV, and that children and adolescents may tolerate severe immunodeficiency better because they have fewer other infections or because of some unmeasured, age-dependent cofactor or immune alteration in the later phase of HIV disease.

Bleeding due to disruption of a cargo-specific ER-to-Golgi transport complex.

Mutations in LMAN1 (also called ERGIC-53) result in combined deficiency of factor V and factor VIII (F5F8D), an autosomal recessive bleeding disorder characterized by coordinate reduction of both clotting proteins. LMAN1 is a mannose-binding type 1 transmembrane protein localized to the endoplasmic reticulum–Golgi intermediate compartment (ERGIC; refs. 2,3), suggesting that F5F8D could result from a defect in secretion of factor V and factor VIII (ref. 4). Correctly folded proteins destined for secretion are packaged in the ER into COPII-coated vesicles, which subsequently fuse to form the ERGIC. Secretion of certain abundant proteins suggests a default pathway requiring no export signals (bulk flow; refs. 6,7). An alternative mechanism involves selective packaging of secreted proteins with the help of specific cargo receptors. The latter model would be consistent with mutations in LMAN1 causing a selective block to export of factor V and factor VIII. But ∼30% of individuals with F5F8D have normal levels of LMAN1, suggesting that mutations in another gene may also be associated with F5F8D. Here we show that inactivating mutations in MCFD2 cause F5F8D with a phenotype indistinguishable from that caused by mutations in LMAN1. MCFD2 is localized to the ERGIC through a direct, calcium-dependent interaction with LMAN1. These findings suggest that the MCFD2-LMAN1 complex forms a specific cargo receptor for the ER-to-Golgi transport of selected proteins.

Rap1b is required for normal platelet function and hemostasis in mice

Rap1b, an abundant small GTPase in platelets, becomes rapidly activated upon stimulation with agonists. Though it has been implicated to act downstream from G protein-coupled receptors (GPCRs) and upstream of integrin alpha IIbbeta3, the precise role of Rap1b in platelet function has been elusive. Here we report the generation of a murine rap1b knockout and show that Rap1b deficiency results in a bleeding defect due to defective platelet function. Aggregation of Rap1b-null platelets is reduced in response to stimulation with both GPCR-linked and GPCR-independent agonists. Underlying the defective Rap1b-null platelet function is decreased activation of integrin alphaIIbbeta3 in response to stimulation with agonists and signaling downstream from the integrin alpha IIbbeta3. In vivo, Rap1b-null mice are protected from arterial thrombosis. These data provide genetic evidence that Rap1b is involved in a common pathway of integrin activation, is required for normal hemostasis in vivo, and may be a clinically relevant antithrombotic therapy target.

SH2- and SH3-mediated Interactions between Focal Adhesion Kinase and Src

Intramolecular SH2 and SH3 interactions mediate enzymatic repression of the Src kinases. One mechanism of activation is disruption of these interactions by the formation of higher affinity SH2 and SH3 interactions with specific ligands. We show that a consensus Src SH3-binding site residing upstream of the Src SH2-binding site in FAK can function as a ligand for the Src SH3 domain. Surface plasmon resonance experiments indicate that a FAK peptide containing both the Src SH2- and SH3-binding sites exhibits increased affinity for Src. Furthermore, the presence of both sites in vitro more potently activates c-Src. A FAK mutant (FAKPro-2) with substitutions destroying the SH3-binding site shows reduced binding to Src in vivo. This mutation also reduces Src-dependent tyrosine phosphorylation on the mutant itself and downstream substrates, such as paxillin. These observations suggest that an SH3-mediated interaction between Src-like kinases and FAK may be important for complex formation and downstream signaling in vivo.

HIV-1 infection in a man homozygous for CCR5▵32

clone differed considerably from that of JRFL and contained substitutions found in strains displaying the syncytium inducing (SI) phenotype. Consensus V3 sequences are presented in the figure. Results obtained using a V3-specific heteroduplex mobility assay were consistent with the viral sequence data; virus in the 1986 sample was relatively homogeneous and substantially different from JRFL, consistent with an SI strain. SI strains do not require CCR5 and can use CXCR4 as a coreceptor. The presence of SI strains may explain this individual’s rapid loss of CD4 lymphocytes, as SI strains are more virulent than NSI strains and their presence may abrogate the clinical advantage of CCR5 32 heterozygosity. None of twelve other CCR5 32 homozygotes identified from MHCS were HIV-1 infected. Furthermore, although that genotype occurs in only 1% of whites, it was present in five (29%) of 17 MHCS individuals who remained HIV-1uninfected despite heavy blood product exposure. Thus, CCR5 32 homozygosity provides strong relative resistance to parenterally acquired HIV-1 infection. In this exceptional case, the subject appears to have been infected with an HIV-1 strain that can use an alternative coreceptor.

The Malmö International Brother Study (MIBS): further support for genetic predisposition to inhibitor development in hemophilia patients.

The issue of factors predisposing for inhibitor development in haemophilia patients is still largely unresolved. In an attempt to address this problem, we initiated a registry in 1996 of siblings with haemophilia and with or without a history of inhibitors. Four hundred and sixty families have accrued, of whom 388 suffer from haemophilia A and 72 haemophilia B. Twenty‐five of the brother pairs are twins. The inhibitor incidence in all families with severe haemophilia A was 31.7%. The corresponding figure in the caucasian patients was 27.4%, whereas a higher incidence of inhibitors was reported in the black subjects (55.6%). Twins were reported in six of the 100 inhibitor families, for whom monozygocity was confirmed in three cases. In 32 families (32%), at least two brothers had a history of inhibitors. In 22 (69%) of these families, the inhibitor was also of the same type, i.e. either high‐ or low‐responding. The overall concordance within the severe haemophilia A families was found to be 78.3% (195/249) compared to an expected figure of 68.0% and 58.0% using an inhibitor incidence of 20 and 30%, respectively (P < 0.0001). The corresponding figure for the twins was 88.2% (15/17). Moreover, the risk for inhibitor development in families with a previous inhibitor history was found to be 48% (95% confidence interval [CI] 35–62%), whereas the risk in families with no previous known inhibitor was only 15% (95% CI 11–21%) corresponding to a relative risk of 3.2 (95% CI 2.1–4.9). Immune‐tolerance induction was reported in 24 families, of whom 13 siblings were successfully treated. Our data clearly support the concept that a genetic predisposition for inhibitor development exists. However, the markers of this predisposition remain to be elucidated and we believe that the MIBS registry will be useful for this purpose.

Dose effect and efficacy of rFVIIa in the treatment of haemophilia patients with inhibitors: analysis from the Hemophilia and Thrombosis Research Society Registry

Summary.  Recombinant activated factor VII (rFVIIa), licensed in 1999 for treatment of haemophilia patients with inhibitors (HI), represents an important advance in the therapeutic armamentarium. Standard bolus dosing ranges from 90 to 120 mcg kg−1 every 2–3 h until arrest of bleeding. As licensure, clinical use of rFVIIa has increased and broadened. Clinicians now use a wide dose range, 90–300 mcg kg−1. High‐dose regimens may optimize thrombin generation or burst, and may allow for prolonged dose interval. The Hemophilia and Thrombosis Research Society (HTRS) maintains a registry database to study haemophilia treatment and related disorders, particularly treatment of acute bleeding in HI, acquired haemophilia, FVII deficiency and von Willebrands disease (VWD). To assess the effect of rFVIIa dose on efficacy and safety in the treatment of acute bleeding in HI, data from the HTRS database from January 2000 through June 2002 were analysed. Bleeding episodes were grouped by bolus rFVIIa dose range: <100, 100–150, 150–200 and >200 mcg kg−1. Investigator‐reported efficacy for the first 72 h of treatment was evaluated. Thirty‐eight congenital HI patients were treated for 555 bleeding episodes. Patient age range was 1–55 years (median: 14). Bleeding episodes were spontaneous (45%), caused by trauma (38%), or because of surgery, dental, diagnostic, or medical procedures (17%); bleeding occurred in joint, muscle, and intra/extracranial sites. Treatment location included: 80% at home, 12% at other facilities (treatment centres, ER, inpatient and OR), and 8% at both home/other facilities. Median total dose given over 72 h was 360 mcg kg−1 (range: 40–4281, mean: 537). Bleeding stopped in 87% of the episodes. Bleeding cessation rate was 84% for the three lower dose groups, and 97% for the highest dose group (P < 0.001). Five patients experienced nine adverse events (AEs). AE rates were <1% for <100, 5% for 100–150, 0% for 150–200, <1% for >200 mcg kg−1 dose group. Decreased therapeutic response accounted for eight of the nine AEs. These data, which represent the most comprehensive report of rFVIIa use since the USA licensure, demonstrate that bleeding episodes in HI patients can be treated safely and effectively at home and that doses up to 346 mcg kg−1 appear to be well‐tolerated. Additionally, rFVIIa doses >200 mcg kg−1 appear to significantly increase efficacy (97% in the high‐dose group, compared with 84% in the lower dose groups). Optimal dosing remains to be determined; specifically, what the lowest effective dose is and whether a single high‐dose bolus eliminates the need for repeated dosing. Recombinant FVIIa appears to have a wide safety margin that may allow dose escalation to address these questions.

Use of Recombinant Antihemophilic Factor in the Treatment of Two Patients with Classic Hemophilia

COMMERCIAL concentrates of human antihemophilic factor (factor VIII) have been available for nearly 20 years and have resulted in dramatic changes in the treatment of classic hemophilia. Home thera...

How we treat a hemophilia A patient with a factor VIII inhibitor

The most significant complication of treatment in patients with hemophilia A is the development of alloantibodies that inhibit factor VIII activity. In the presence of inhibitory antibodies, replacement of the missing clotting factor by infusion of factor VIII becomes less effective. Once replacement therapy is ineffective, acute management of bleeding requires agents that bypass factor VIII activity. Long-term management consists of eradicating the inhibitor through immune tolerance. Despite success in the treatment of acute bleeding and inhibitor eradication, there remains an inability to predict or prevent inhibitor formation. Ideally, prediction and ultimately prevention will come with an improved understanding of how patient-specific and treatment-related factors work together to influence anti-factor VIII antibody production.

Identification of a Novel RalGDS-related Protein as a Candidate Effector for Ras and Rap1

Although Ras and Rap1 share interaction with common candidate effector proteins, Rap1 lacks the transforming activity exhibited by Ras proteins. It has been speculated that Rap antagonizes Ras transformation through the formation of nonproductive complexes with critical Ras effector targets. To understand further the distinct biological functions of these two closely related proteins, we searched for Rap1b-binding proteins by yeast two-hybrid screening. We identified multiple clones that encode the COOH-terminal sequences of a protein that shares sequence identity with RalGDS and RGL, which we have designated RGL2. A 158-amino acid COOH-terminal fragment of RGL2 (RGL2 C-158) bound to Ras superfamily proteins which shared identical effector domain sequences with Rap1 (Ha-Ras, R-Ras, and TC21). RGL2 C-158 binding was impaired by effector domain mutations in Rap1b and Ha-Ras. Furthermore, RGL2 C-158 bound exclusively to the GTP-, but not the GDP-bound form of Ha-Ras. Finally, coexpression of RGL2 C-158 impaired oncogenic Ras activation of transcription from a Ras-responsive promoter element and focus-forming activity in NIH 3T3 cells. We conclude that RGL2 may be an effector for Ras and/or Rap proteins.