High-Grade B-cell Lymphoma, Not Otherwise Specified: A Multi-Institutional Retrospective Study

In this multi-institutional retrospective study, we examined the characteristics and outcomes of 160 patients with high-grade B-cell lymphoma, not otherwise specified (HGBL-NOS)-a rare category defined by high-grade morphologic features and lack of MYC rearrangements with BCL2 and/or BCL6 rearrangements ( double hit ). Our results show that HGBL-NOS tumors are heterogeneous: 83% of patients had a germinal center B-cell immunophenotype, 37% a dual-expressor immunophenotype (MYC and BCL2 expression), 28% MYC rearrangement, 13% BCL2 rearrangement, and 11% BCL6 rearrangement. Most patients presented with stage IV disease, a high serum lactate dehydrogenase, and other high-risk clinical factors. Most frequent first-line regimens included dose-adjusted cyclophosphamide, doxorubicin, vincristine, and etoposide, with rituximab and prednisone (DA-EPOCH-R; 43%); rituximab, cyclophosphamide, doxorubicin, vincristine, and prednisone (R-CHOP; 33%); or other intensive chemotherapy programs. We found no significant differences in the rates of complete response (CR), progression-free survival (PFS), or overall survival (OS) between these chemotherapy regimens. CR was attained by 69% of patients. PFS at 2 years was 55.2% and OS was 68.1%. In a multivariable model, the main prognostic factors for PFS and OS were poor performance status, lactate dehydrogenase \u3e3 × upper limit of normal, and a dual-expressor immunophenotype. Age \u3e60 years or presence of MYC rearrangement were not prognostic, but patients with TP53 alterations had a dismal PFS. Presence of MYC rearrangement was not predictive of better PFS in patients treated with DA-EPOCH-R vs R-CHOP. Improvements in the diagnostic criteria and therapeutic approaches beyond dose-intense chemotherapy are needed to overcome the unfavorable prognosis of patients with HGBL-NOS

Structure-Based Analysis of the Herpes Simplex Virus Glycoprotein D Binding Site Present on Herpesvirus Entry Mediator HveA (HVEM)

Binding of herpes simplex virus (HSV) envelope glycoprotein D (gD) to a cell surface receptor is an essential step of virus entry. We recently determined the crystal structure of gD bound to one receptor, HveA. HveA is a member of the tumor necrosis factor receptor family and contains four characteristic cysteine-rich domains (CRDs). The first two CRDs of HveA are necessary and sufficient for gD binding. The structure of the gD-HveA complex reveals that 17 amino acids in HveA CRD1 and 4 amino acids in HveA CRD2 directly contact gD. To determine the contribution of these 21 HveA residues to virus entry, we constructed forms of HveA mutated in each of these contact residues. We determined the ability of the mutant proteins to bind gD, facilitate virus entry, and form HveA oligomers. Our results point to a binding hot spot centered around HveA-Y23, a residue that protrudes into a crevice on the surface of gD. Both the hydroxyl group and phenyl group of HveA-Y23 contribute to HSV entry. Our results also suggest that an intermolecular β-sheet formed between gD and HveA residues 35 to 37 contributes to binding and that a C37-C19 disulfide bond in CRD1 is a critical component of HveA structure necessary for gD binding. The results argue that CRD2 is required for gD binding mainly to provide structural support for a gD binding site in CRD1. Only one mutant, HveA-R75A, exhibited enhanced gD binding. While some mutations influenced complex formation, the majority did not affect HSV entry, suggesting that most contact residues contribute to HveA receptor function collectively rather than individually. This structure-based dissection of the gD-HveA binding site highlights the contribution of key residues within HveA to gD binding and HSV entry and defines a target region for the design of small-molecule inhibitors

Structure-Based Mutagenesis of Herpes Simplex Virus Glycoprotein D Defines Three Critical Regions at the gD-HveA/HVEM Binding Interface

Herpes simplex virus (HSV) entry into cells requires the binding of glycoprotein D (gD) to one of several cell surface receptors. The crystal structure of gD bound to one of these receptors, HveA/HVEM, reveals that the core of gD comprises an immunoglobulin fold flanked by a long C-terminal extension and an N-terminal hairpin loop. HveA is a member of the tumor necrosis factor receptor family and contains four cysteine-rich domains (CRDs) characteristic of this family. Fourteen amino acids within the gD N-terminal loop comprise the entire binding site for HveA. To determine the contribution of each gD contact residue to virus entry, we constructed gD molecules mutated in these amino acids. We determined the abilities of the gD mutants to bind receptors, facilitate virus entry, and mediate cell-cell fusion. Seven of the gD mutants exhibited wild-type levels of receptor binding and gD function. Results from the other seven gD mutants revealed three critical regions at the gD-HveA interface. (i) Several gD residues that participate in an intermolecular β-sheet with HveA were found to be crucial for HveA binding and entry into HveA-expressing cells. (ii) Two gD residues that contact HveA-Y23 contributed to HveA binding but were not required for mediating entry into cells. HveA-Y23 fits into a crevice on the surface of gD and was previously shown to be essential for gD binding. (iii) CRD2 was previously shown to contribute to gD binding, and this study shows that one gD residue that contacts CRD2 contributes to HveA binding. None of the gD mutations prevented interaction with nectin-1, another gD receptor. However, when cotransfected with the other glycoproteins required for fusion, two gD mutants gained the ability to mediate fusion of cells expressing nectin-2, a gD receptor that interacts with several laboratory-derived gD mutants but not with wild-type gD. Thus, results from this panel of gD mutants as well as those of previous studies (A. Carfi, S. H. Willis, J. C. Whitbeck, C. Krummenacher, G. H. Cohen, R. J. Eisenberg, and D. C. Wiley, Mol. Cell 8:169-179, 2001, and S. A. Connolly, D. J. Landsburg, A. Carfi, D. C. Wiley, R. J. Eisenberg, and G. H. Cohen, J. Virol. 76:10894-10904, 2002) provide a detailed picture of the gD-HveA interface and the contacts required for functional interaction. The results demonstrate that of the 35 gD and HveA contact residues that comprise the gD-HveA interface, only a handful are critical for complex formation

Intraventricular Brain Injection of Adeno-Associated Virus Type 1 (AAV1) in Neonatal Mice Results in Complementary Patterns of Neuronal Transduction to AAV2 and Total Long-Term Correction of Storage Lesions in the Brains of β-Glucuronidase-Deficient Mice

Inherited metabolic disorders that affect the central nervous system typically result in pathology throughout the brain; thus, gene therapy strategies need to achieve widespread delivery. We previously found that although intraventricular injection of the neonatal mouse brain with adeno-associated virus serotype 2 (AAV2) results in dispersed gene delivery, many brain structures were poorly transduced. This limitation may be overcome by using different AAV serotypes because the capsid proteins use different cellular receptors for entry, which may allow enhanced global targeting of the brain. We tested this with AAV1 and AAV5 vectors. AAV5 showed very limited brain transduction after neonatal injection, even though it has different transduction patterns than AAV2 in adult brain injections. In contrast, AAV1 vectors, which have not been tested in the brain, showed robust widespread transduction. Complementary patterns of transduction between AAV1 and AAV2 were established and maintained in the adult brain after neonatal injection. In the majority of structures, AAV1 transduced many more cells than AAV2. Both vectors transduced mostly neurons, indicating that differential expression of receptors on the surfaces of neurons occurs in the developing brain. The number of cells positive for a vector-encoded secreted enzyme (β-glucuronidase) was notably greater and more widespread in AAV1-injected brains. A comprehensive analysis of AAV1-treated brains from β-glucuronidase-deficient mice (mucopolysaccharidosis type VII) showed complete reversal of pathology in all areas of the brain for at least 1 year, demonstrating that the combination of this serotype and experimental strategy is therapeutically effective for treating global neurometabolic disorders