Bone density of first and second segments of normal and dysmorphic sacra.

BACKGROUND: Iliosacral screw fixation is safe and effective but can be complicated by loss of fixation, particularly in patients with osteopenic bone. Sacral morphology dictates where iliosacral screws may be placed when stabilizing pelvic ring injuries. In dysmorphic sacra, the safe osseous corridor of the upper sacral segment (S1) is smaller and lacks a transsacral corridor, increasing the need for fixation in the second sacral segment (S2). Previous evidence suggests that S2 is less dense than S1. The aim of this cross-sectional study is to further evaluate bone mineral density (BMD) of the S1 and S2 iliosacral osseous pathways through morphology stratification into normal and dysmorphic sacra. MATERIALS AND METHODS: Pelvic computed tomography scans of 50 consecutive trauma patients, aged 18 to 50 years, from a level 1 trauma center were analyzed prospectively. Five radiographic features (upper sacral segment not recessed in the pelvis, mammillary bodies, acute alar slope, residual S1 disk, and misshapen sacral foramen) were used to identify dysmorphic characteristics, and sacra with four or five features were classified as dysmorphic. Hounsfield unit values were used to estimate the regional BMD of S1 and S2. Student's t-test was utilized to compare the mean values at each segment, with statistical significance being set at p < 0.05. No change in clinical management occurred as a result of inclusion in this study. RESULTS: A statistical difference in BMD was appreciated between S1 and S2 in both normal and dysmorphic sacra (p < 0.0001), with 28.4% lower density in S2 than S1. Further, S1 in dysmorphic sacra tended to be 4% less dense than S1 in normal sacra (p = 0.047). No difference in density was appreciated at S2 based on morphology. CONCLUSIONS: Our results would indicate that, based on BMD alone, fixation should be maximized in S1 prior to fixation in S2. In cases where S2 fixation is required, we recommend that transsacral fixation should be strongly considered if possible to bypass the S2 body and achieve fixation in the cortical bone of the ilium and sacrum. LEVEL OF EVIDENCE: Level III.

CCR5 interactions with the variable 3 loop of gp120.

The G-protein coupled receptor CCR5 functions pathologically as the primary co-receptor for macrophage tropic (R5) strains of HIV-1. The interactions responsible for co-receptor activity are unknown. Molecular-dynamics simulations of the extracellular and adjacent transmembrane domains of CCR5 were performed with explicit solvation utilizing a rhodopsin-based homology model. The functional unit of co-receptor binding was constructed via docking and molecular-dynamics simulation of CCR5 and the variable 3 loop of gp120, which is a dominant determinant of co-receptor utilization. The variable 3 loop was demonstrated to interact primarily with the amino terminus and the second extracellular loop of CCR5, providing novel structural information regarding the co-receptor-binding site. Alanine mutants that alter chemokine binding and co-receptor activity were examined. Molecular-dynamics simulations with and without the variable 3 loop of gp120 were able to rationalize the activities of these mutants successfully, providing support for the proposed model. Based on these results, the global complex of CCR5, gp120 including the V3 loop and CD4, was investigated. The utilization of computational analysis, in combination with molecular biological data, provides a powerful approach for understanding the use of CCR5 as a co-receptor by HIV-1.

Restricted variable residues in the C-terminal segment of HIV-1 V3 loop regulate the molecular anatomy of CCR5 utilization.

The V3 loop of the HIV-1 envelope glycoprotein (Env) is the major determinant for coreceptor utilization, but the structural basis for this specificity remains to be defined. By characterizing a set of naturally occurring R5 Env variants, we demonstrate that Asp324 in the conserved IIGDIR motif of the V3 loop (CTRPN(300)NNTRKSIHIGP(311)GRAFYTTGEIIGD(324)IRQAHC) C-terminal segment regulates the molecular anatomy of CCR5 utilization. Whereas gp120 subunits with Asp or Asn at position 324 were fusogenic with coreceptor chimeras containing either the N-terminal domain or the body of CCR5, substitution of charged (Glu, Lys) or small hydrophobic (Gly, Ala) residues resulted in complete loss of fusogenic activity with the N terminus and markedly reduced utilization of the body of CCR5, although their ability to use wild-type CCR5 was unchanged. This phenotypic conversion was confirmed in both gain and loss of function experiments using Env from multiple subtypes. Alignment of sequences of R5 V3 loops (n=599) from the HIV database revealed that the mutation of Asp324 in the conserved IIGDIR motif is restricted to Asn324, with proportions of 71.5% and 28%, respectively. Infection of primary CD4(+)T cells demonstrated that Env bearing Asp324 was less sensitive to RANTES, suggesting that Asp or Asn in this position may be crucial for viral fitness. The CD4-dependent gp120 binding to CCR5 was decreased when Asp324 was replaced with a charged or hydrophobic residue, but unchanged when replaced with Asn. Molecular modeling analyses predicted that Asp/Asn324 forms a critical H-bond with Asn300. These findings indicate that Asp or Asn at position 324 of the V3 stem stabilizes the conformation of V3 loop and hence influences the intensities of interaction between CD4-activated gp120 and CCR5 which results in viral entry.